American Chestnut (Castanea dentata): recovery strategy 2019

Official title: Recovery Strategy for the American Chestnut (Castanea dentata) in Canada 2019

Species at Risk Act
Recovery strategy series
Adopted under section 44 of SARA

American Chestnut
American Chestnut
Document information

Recommended citation: Environment and Climate Change Canada. 2019. Recovery Strategy for the American Chestnut (Castanea dentata) in Canada. Species at Risk Act Recovery Strategy Series. Environment and Climate Change Canada, Ottawa. 3 parts, 37 pp. + vi + 43 pp. + 5 pp.

For copies of the recovery strategy, or for additional information on species at risk, including the Committee on the Status of Endangered Wildlife in Canada (COSEWIC) Status Reports, residence descriptions, action plans, and other related recovery documents, please visit the Species at Risk (SAR) Public Registry.

Cover illustration: © John D. Ambrose

Également disponible en français sous le titre « Programme de rétablissement du châtaignier d’Amérique (Castanea dentata) au Canada »

Content (excluding the illustrations) may be used without permission, with appropriate credit to the source.

Under the Accord for the Protection of Species at Risk (1996), the federal, provincial, and territorial governments agreed to work together on legislation, programs, and policies to protect wildlife species at risk throughout Canada.

In the spirit of cooperation of the Accord, the Government of Ontario has given permission to the Government of Canada to adopt the Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario (Part 2) and the American Chestnut – Ontario Government Response Statement (Part 3) under Section 44 of the Species at Risk Act (SARA).Environment and Climate Change Canada has included a federal addition (Part 1) which completes the SARA requirements for this recovery strategy.

The federal recovery strategy for the American Chestnut in Canada consists of three parts:

Part 1 – Federal Addition to the Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario, prepared by Environment and Climate Change Canada.

Part 2 – Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario, prepared for the Ontario Ministry of Natural ResourcesFootnote 1.

Part 3 – American Chestnut – Ontario Government Response Statement, prepared by the Ontario Ministry of Natural Resources.

Part 1 – Federal Addition to the Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario, prepared by Environment and Climate Change Canada

Preface

The federal, provincial, and territorial government signatories under the Accord for the Protection of Species at Risk (1996) agreed to establish complementary legislation and programs that provide for effective protection of species at risk throughout Canada. Under the Species at Risk Act (S.C. 2002, c.29) (SARA), the federal competent ministers are responsible for the preparation of recovery strategies for listed Extirpated, Endangered, and Threatened species and are required to report on progress within five years after the publication of the final document on the SAR Public Registry.

The Minister of Environment and Climate Change is the competent minister under SARA for the American Chestnut and has prepared the federal component of this recovery strategy (Part 1), as per section 37 of SARA. SARA section 44 allows the Minister to adopt all or part of an existing plan for the species if it meets the requirements under SARA for content (sub-sections 41(1) or (2)). The Ontario Ministry of Natural Resources (now the Ontario Ministry of Natural Resources and Forestry) led the development of the attached recovery strategy for the American Chestnut (Part 2) in cooperation with Environment and Climate Change Canada. The Province of Ontario also led the development of the attached Government Response Statement (Part 3), which is the Ontario Government’s policy response to its provincial recovery strategy and summarizes the prioritized actions that the Ontario government intends to take and support.

Success in the recovery of this species depends on the commitment and cooperation of many different constituencies that will be involved in implementing the directions set out in this strategy and will not be achieved by Environment and Climate Change Canada, or any other jurisdiction alone. All Canadians are invited to join in supporting and implementing this strategy for the benefit of the American Chestnut and Canadian society as a whole.

This recovery strategy will be followed by one or more action plans that will provide information on recovery measures to be taken by Environment and Climate Change Canada and other jurisdictions and/or organizations involved in the conservation of the species. Implementation of this strategy is subject to appropriations, priorities, and budgetary constraints of the participating jurisdictions and organizations.

The recovery strategy sets the strategic direction to arrest or reverse the decline of the species, including identification of critical habitat to the extent possible. It provides all Canadians with information to help take action on species conservation. When critical habitat is identified, either in a recovery strategy or an action plan, SARA requires that critical habitat then be protected.

In the case of critical habitat identified for terrestrial species including migratory birds SARA requires that critical habitat identified in a federally protected areaFootnote 2 be described in the Canada Gazette within 90 days after the recovery strategy or action plan that identified the critical habitat is included in the public registry. A prohibition against destruction of critical habitat under ss. 58(1) will apply 90 days after the description of the critical habitat is published in the Canada Gazette.

For critical habitat located on other federal lands, the competent minister must either make a statement on existing legal protection or make an order so that the prohibition against destruction of critical habitat applies.

If the critical habitat for a migratory bird is not within a federal protected area and is not on federal land, within the exclusive economic zone or on the continental shelf of Canada, the prohibition against destruction can only apply to those portions of the critical habitat that are habitat to which the Migratory Birds Convention Act, 1994 applies as per SARA ss. 58(5.1) and ss. 58(5.2).

For any part of critical habitat located on non-federal lands, if the competent minister forms the opinion that any portion of critical habitat is not protected by provisions in or measures under SARA or other Acts of Parliament, or the laws of the province or territory, SARA requires that the Minister recommend that the Governor in Council make an order to prohibit destruction of critical habitat. The discretion to protect critical habitat on non-federal lands that is not otherwise protected rests with the Governor in Council.

Acknowledgments

The initial draft of the federal addition was prepared by Holly Bickerton (Consulting Ecologist, Ottawa). Additional preparation and review of the document was completed by Angela McConnell, Krista Holmes, Marie-Claude Archambault and Lee Voisin (Environment and Climate Change Canada, Canadian Wildlife Service – Ontario) Justine Mannion and Marsha Smith (formerly Environment and Climate Change Canada, Canadian Wildlife Service – Ontario). Kathy St. Laurent, Rachel deCatanzaro, Lesley Dunn (Environment and Climate Change Canada, Canadian Wildlife Service – Ontario), Veronique Brondex (Environment and Climate Change Canada, Canadian Wildlife Service – National Capital Region), Vivian Brownell, Aileen Wheeldon, Eric Snyder and Michelle Collins (Ontario Ministry of Natural Resources and Forestry) and Clint Jacobs (Walpole Island Heritage Centre) reviewed and provided comments and advice during the development of this document.

Acknowledgement and thanks are given to all other parties that provided advice and input used to help inform the development of this recovery strategy including various Indigenous organizations and individuals, landowners, citizens and stakeholders who provided input and/or participated in consultation meetings.

Additions and modifications to the adopted document

The following sections have been included to address specific requirements of the federal Species at Risk Act (SARA) that are not addressed in the Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario (Part 2 of this document, referred to henceforth as “the provincial recovery strategy”) and/or to provide updates or additional information.

Environment and Climate Change Canada is adopting the provincial recovery strategy (Part 2) with the exception of section 2, Recovery. In place of section 2, Environment and Climate Change Canada has established its own performance indicators and population and distribution objectives that are consistent with the provincial recovery goal, and is adopting the government-led and government-supported actions set out in the American Chestnut – Ontario Government Response StatementFootnote 3 (Part 3) as the broad strategies and general approaches to meet the population and distribution objectives.

Under SARA, there are specific requirements and processes set out regarding the protection of critical habitat. Therefore, statements in the provincial recovery strategy referring to protection of the species’ habitat may not directly correspond to federal requirements. Recovery measures dealing with the protection of habitat are adopted; however, whether these measures will result in protection of critical habitat under SARA will be assessed following publication of the final federal recovery strategy.

1 Species Status Information

The American Chestnut is listed as EndangeredFootnote 4 on Schedule 1 of SARA. In Ontario, the American Chestnut is listed as EndangeredFootnote 5 under the provincial Endangered Species Act, 2007 (ESA).

The global conservation status for American Chestnut is Apparently Secure (G4) (Appendix A). Its national conservation status is Imperilled (N2) in Canada and Apparently Secure (N4) in the United States (Appendix A). The species is ranked as Imperilled (S2) in Ontario, the only Canadian province where it occurs, while its status ranges from Secure to Extirpated (S5 – SX) in the 29 American states where it occurs (NatureServe 2014; Appendix A).

It is estimated that less than 5% of the American Chestnut’s global range occurs in Canada.

2 Recovery feasibility summary

Based on the following four criteria that Environment and Climate Change Canada uses to establish recovery feasibility, there are unknowns regarding the feasibility of recovery of the American Chestnut. In keeping with the precautionary principle, a recovery strategy has been prepared as per section 41(1) of SARA, as would be done when recovery is determined to be technically and biologically feasible. This recovery strategy addresses the unknowns surrounding the feasibility of recovery.

1. Individuals of the wildlife species that are capable of reproduction are available now or in the foreseeable future to sustain the population or improve its abundance.

Unknown. The naturally occurring American Chestnut population in Ontario is unlikely to become self-sustaining without effective measures to control or halt the impact of chestnut blight. Less than 1 percent of the original population remains in southwestern Ontario. Although there are several hundred naturally occurring trees remaining across southwestern Ontario, the vast majority of these are immature or survive as remnant stumps that produce shoots. Large mature trees are considered extremely rare. In a survey of over 600 naturally occurring Ontario trees, Tindall et al. (2004) found that only 14 percent were reproductive. No trees were found with viable seed (i.e., filled nuts), and no evidence of seedlings was detected within 20 m plots surrounding any of the trees assessed. Across the former range of the species, the introduced chestnut blight fungus (Cryphonectria parasitica) limits the possibility of sexual reproduction, and in the United States, sprouts also rarely grow to reproductive maturity or produce viable seed (Paillet 2002). It is highly uncertain whether a sufficient number of individuals capable of reproduction currently exist to sustain the current population, or improve its abundance in the future. Non-reproductive sprouts exist and even spread vegetatively in parts of the species range (Paillet 2002), although vegetative propagation from cuttings is reportedly very difficult (Elkins et al. 1980). Efforts to establish blight resistance in American Chestnut are underway in Canada and the United States through the production of a modified American Chestnut with genes from a blight-resistant or blight-tolerant Chestnut species (to create resistant backcrossedFootnote 6 individuals (at least 94% genetically similar to C. dentata)), and these blight-resistant trees may be available within a few years (American Chestnut Foundation 2014; Boland et al. 2012; Canadian Chestnut Council 2017). However, the long-term success of this technique has not been proven, and there remains considerable uncertainty whether backcrossed trees will be able to support a sustainable American Chestnut population in Ontario. However, it is likely that planted trees will contribute to sustaining population abundance in the future. American Chestnut and other chestnut species are planted throughout Ontario as ornamental trees and to contribute to habitat restoration. While planted trees are not included in the objective of this strategy, planted American Chestnut trees that are healthy and capable of reproducing may contribute to the recovery of the species in the future.

2. Sufficient suitable habitat is available to support the species or could be made available through habitat management or restoration.

Yes. Sufficient habitat is available to support the species. Although loss of the Ontario Carolinian forest has been extensive, the predominant threat to this species, is an introduced fungal pathogen that causes chestnut blight. American Chestnut is not considered a habitat specialist, and has been found in over twenty different vegetation communities in southern Ontario (Boland et al. 2012). Many sites where American Chestnut trees occur exist within larger natural areas with additional suitable, but unoccupied habitat. There are also several large natural forested areas on upland, sandy soils within the range of the American Chestnut (e.g., especially within the Turkey Point - St. Williams Conservation Reserve area) that contain large amounts of unoccupied but potentially suitable habitat. Despite the availability of suitable habitat across the landscape, habitat fragmentation has led to isolation of individuals which hinders and prevents flowers from being successfully pollinatedFootnote 7 and seeds from being dispersed. Enhancement of remaining Carolinian woodlots, through management and stewardship, could provide suitable microsites for establishment and growth of new trees, reducing the isolation of American Chestnut individuals.

3. The primary threats to the species or its habitat (including threats outside Canada) can be avoided or mitigated.

Unknown. American Chestnut was a dominant forest tree species in northeastern North America until the early 1900’s when populations were devastated by an introduced fungal pathogen that causes chestnut blight. Chestnut blight continues to be the greatest threat to American Chestnut in Ontario, infecting trees in cycles of infection, dieback, and re-infection (Boland et al. 2012). The fungus survives on sprouts and many alternative hosts, including many common overstoryFootnote 8 and understoryFootnote 9 species (Mooij 1997). It may be possible that the threat posed by chestnut blight can be partially or entirely mitigated by the introduction of artificially cultivated blight-resistant Chestnut in the coming years, or through other research techniques in development (e.g., hypovirulenceFootnote 10). However, it is not yet known if these techniques will be successful. Other threats include the loss and degradation of habitat, hybridization and insect pests. Non-native chestnuts may pollinate nearby American Chestnut trees leading to hybridization. This threat can be avoided through education and stewardship. Loss of individuals (i.e. from logging or land clearing) and insect pests can be avoided or mitigated through management and stewardship activities.

4. Recovery techniques exist to achieve the population and distribution objectives or can be expected to be developed within a reasonable timeframe.

Unknown. Extensive breeding programs initiated by the Canadian Chestnut Council and American Chestnut Foundation are underway, in which American Chestnut is backcrossed with the blight-resistant Chinese Chestnut in order to introduce resistance, while preserving the original genome. It is hoped that the first resistant stock will be ready for planting within a few years (Boland et al. 2012; American Chestnut Foundation 2014). However, re-introduction efforts have not yet begun or been proven to provide long-term resistance resulting in reproductively sustainable populations. The use of hypovirulence as a potential biological control on the chestnut blight fungus is also being examined in Canada (Boland et al. 2012). Hypovirulent samples have been collected from self-healing cankers at Ontario populations, tested, and used to inoculate cankers on infected trees. Early results have not been encouraging, but observation will continue. It is unknown if recovery techniques currently in development will achieve the population and distribution objectives. At this time, recovery efforts focus on continued collaboration with the province of Ontario on American Chestnut priorities which includes research into various blight control measures, as well as by supporting the conservation and enhancement of American Chestnut genetic diversity, promoting blight tolerance and preventing the spread of disease.

3 Species information

3.1 Species population and distribution

The Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario (2012) identifies 135 sitesFootnote 11 containing American Chestnut in 13 counties of southwestern Ontario, 10 more sites than previously reported in the 2004 COSEWIC Assessment and Update Status Report, likely due to an increased survey effort. A standardized survey protocol now exists (Tindall et al.  2004); however, it should be noted that surveys conducted in years prior to the development of the survey protocol have differing methodologies and are not directly comparable.

Since the development of the Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario (2012), 36 new locations of American Chestnut have been found. This information has not yet been incorporated by the Natural Heritage Information Centre (NHIC) into Ontario’s provincially-tracked species database. The NHIC reports 165 element occurrences (EOs)Footnote 12 of American Chestnut in Ontario (NHIC 2014) based on observations up to 2007. Of these, 90 were identified as historic, 10 extirpated and the remaining 65 were considered extant. The impact blight has had on some of these populations is not known and their status is expected to change. Once these new locations have been assessed, it will likely result in the establishment of new EOs and/or modifications to existing EOs. This recovery strategy is based on all available observations of American Chestnut up to 2014. More current information on EOs and/or sub-populations is required to have a better understanding of the current status of American Chestnut in Ontario. In the future, the enumeration of American Chestnut populations (and locations identified as critical habitat (Section 6.0)) may better align with the provincial records of American Chestnut.

Of the 165 EOs previously recorded, 26 EOs (including some extant and some historical) indicated the presence of blight. It is possible these trees may no longer exist and further information is needed to assess the current population status (See Section 6.2, Table 1). There is limited information on the size of the Canadian population of American Chestnut since the introduction of the blight. The abundance and distribution estimates (more than 600 individuals in southern Ontario) largely reflect accessible sites on public lands, and these numbers are thought to under-represent the true population size of American Chestnut in Canada by as much as 30-70% (Boland et al. 2012).  Accurate estimates of the population and distribution may continue to be challenging due to the number of potential locations and the difficulty in accessing sites on private lands for inventory. It is likely that additional American Chestnut trees may be discovered in the future with increased surveys.

4 Population and distribution objectives

Under SARA, a population and distribution objective for the species must be established. Consistent with the goal set out in the Government of Ontario’s Government Response Statement, Environment and Climate Change Canada’s population and distribution objective for the American Chestnut in Canada is to:

  • Maintain and if feasible increase the current abundance and area of occupancyFootnote 13 of the American Chestnut in Canada

This objective is consistent with the province of Ontario’s Government Response Statement developed under the provincial Endangered Species Act, which outlines the provincial government’s goal for the recovery of the species and summarizes the prioritized actions the government intends to take (see Part 3 for more information). The Government Response Statement for the province of Ontario lists the following goal for the recovery of the American Chestnut in Ontario:

  • The government’s goal for the recovery of American Chestnut is to retain the current population level and distribution in Ontario while increasing genetic diversity and reproductive success, and where possible, explore the feasibility of implementing blight control measures to restore the species to a self-sustaining state

The American Chestnut population distribution can be measured by the Index of area of occupancy, estimated by COSEWIC (2004) to be 12 km2. although would likely now be larger due to new sites located since 2004. Tindall et al. (2004) and Boland et al. (2012) indicate the current population level or abundance in Canada to be greater than 600 individuals. There is limited information on how the blight continues to impact the distribution and overall size of the Canadian population of the American Chestnut. The loss of several large trees that were previously reproductive and healthy in the last few decades is a concern; whether they are being replaced by recruitment is inconclusive (COSEWIC 2004). Because of the lack of accurate population information, the focus of this recovery strategy is to improve current baseline information on distribution and abundance in Canada and halt the population decline in order to maintain the overall population and distribution (i.e., abundance and area of occupancy) of the species in Canada.

Further, Environment and Climate Change Canada supports increasing genetic diversity and reproductive success of the American Chestnut, and investigating the feasibility of implementing blight control measures to restore the species to a self-sustaining state. Implementing the broad strategies adopted from the American Chestnut – Ontario Government Response Statement (Part 3) will aid the recovery of this species, including the use of targeted surveys to obtain accurate information about the current distribution, abundance, and health of the species in Canada.

As research into blight control measures, such as hybridization, progresses and new information on the current status of trees emerges, the population and distribution objectives may be re-evaluated and updated in an amended recovery strategy.

American Chestnuts that were planted for purposes other than species recovery, ecological restoration/rehabilitation or habitat creation, are not currently being considered as existing populations (or portions thereof) in the above objective. Many American Chestnuts have been planted within the natural range of the species, as well as outside it. For example, between 1998 and 1999, approximately 1,300 American Chestnuts were planted at 24 demonstration sites, in a program undertaken by the Ontario Soil and Crop Improvement Association. American Chestnuts planted at these demonstration sites are not considered in the above objectives until such a time that they have showcased results on their contribution to a viable native population. Life expectancy and reproductive success of planted trees can be variable. These trees would have to be considered healthy, stable and most likely viable for reproduction to be considered (e.g., as new populations or portions of existing populations) under the above objective.

5 Broad strategies and general approaches to meet objectives

The government-led and government-supported actions from American Chestnut – Ontario Government Response Statement (Part 3) are adopted as the broad strategies and general approaches to address the threats and meet the population and distribution objectives. Environment and Climate Change Canada is not adopting the approaches identified in section 2 of the Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario (Part 2) that are inconsistent with the Ontario Government Response Statement.

6 Critical habitat

6.1 Identification of the species’ critical habitat

Section 41 (1)(c) of SARA requires that recovery strategies include an identification of the species’ critical habitat, to the extent possible, as well as examples of activities that are likely to result in its destruction. Under SARA, critical habitat is “the habitat that is necessary for the survival or recovery of a listed wildlife species and that is identified as the species’ critical habitat in the recovery strategy or in an action plan for the species”.

Identification of critical habitat is not a component of the provincial recovery strategy under the Province of Ontario's ESA. Under the ESA, when a species becomes listed as Endangered or Threatened on the Species at Risk in Ontario List, it automatically receives general habitat protection. The American Chestnut currently receives general habitat protection under the ESA; however, a description of the general habitat has not yet been developed. In some cases, a habitat regulation may be developed that replaces the general habitat protection. A habitat regulation is a legal instrument that prescribes an area that will be protected as the habitat of the species by the Province of Ontario. A habitat regulation has not been developed for American Chestnut under the ESA; however, the provincial recovery strategy (Part 2) contains a recommendation on the area for consideration in developing a habitat regulation.

This federal recovery strategy identifies critical habitat for the American Chestnut in Canada to the extent possible, based on this recommendation and on the best available information as of December 2014. Critical habitat is identified for 64 (of the 65) assessed extant populationsFootnote 14 and 90 historical populations. Critical habitat is also identified for an additional 31 (of 36) locations (i.e., locations not currently assessed for the provincial record of American Chestnut populations) (Appendix B). It is recognized that the critical habitat identified may be insufficient to achieve the population and distribution objectives for the species; there is a lack of certainty in the data of some individual tree locations, and details on the size and status of populations, especially where blight has been observed, is poor. A schedule of studies outlines the activities necessary to complete the identification of critical habitat (see Section 6.2). The identification of critical habitat will be updated when the information becomes available, either in a revised recovery strategy or action plan(s).

Critical habitat is currently identified for populations containing evidence of blight, until such time the population is assessed as no longer viable. Although the blight fungus is a threat to the American Chestnut, blighted trees may contribute to recovery of the species by persisting for many years and producing offspring which could be healthy or blight resistant (Anagnostakis 1992; Griffin 2000). If these infected trees are isolated, planting healthy trees in nearby suitable habitat may allow these trees to produce healthy offspring thereby, contributing to the recovery of the species in Canada. The American Chestnut generation time is estimated at 20 years (COSEWIC 2004); however, due to infection with the blight fungus, many trees fail to reach reproductive maturity. Trees noted as having evidence of blight will require additional surveys to confirm their persistence and reproductive potential.

At this time, critical habitat is not identified for trees that were planted as part of a restoration effort until there are measures to determine if the planting is a success (e.g., monitoring protocol). As new information becomes available, critical habitat may be added in the future. Though critical habitat is not being identified for planted individuals, these trees may contain important genetic material for recovery. Individual trees are protected under the Species at Risk Act (SARA) and the Endangered Species Act, 2007 (ESA).

Critical habitat for the American Chestnut is based on two criteria: habitat occupancy and habitat suitability, which are discussed in detail below.

6.1.1 Habitat occupancy

This criterion refers to areas where there is a reasonable degree of certainty of current use by the species.

Habitat is considered occupied when:

  • One or more naturally occurring American Chestnut individuals have been observed

Habitat occupancy is based on available data from reports and survey information (e.g., Ambrose and Aboud 1986, Boland et al. 1997, COSEWIC 2004, Melzer and Boland 2004, NHIC 2014, Tindall et al. 2004). Records of American Chestnut may be of individual trees but more often reference a small stand or general location of trees within a larger habitat boundary (e.g., forest complex). A record must contain at least one living American Chestnut (which may include a rametFootnote 15, sapling, or tree), and may also include dead individuals or standing snags (based on visual observations) because ramets can often be found in the vicinity of individuals which otherwise appear to be dead. American Chestnut is a long-lived tree species that can live between 200 and 300 years (Zon 1904; American Chestnut Foundation 2014). As a precautionary approach, all documented records from element occurrences (extant and historic) and currently available data are considered in the occupancy criteria until a field survey by a qualified individual (e.g., forester or biologist) determines that no living American Chestnut (e.g., ramets, saplings or trees) remains.

Individual trees or groups of trees which have been planted but are not part of a recognized restoration program (such as the Guelph Arboretum) and those that have clearly been planted for ornamental purposes, such as in urban gardens, are not considered to be naturally occurring, and therefore, will not be included in this critical habitat criterion. Trees that are confirmed hybrids between native American Chestnut and another non-native chestnut species such as the Chinese Chestnut (C. molissima), Japanese Chestnut (C. crenata) or European Chestnut (C. sativa), are also not considered to be occupying habitat for the purposes of identifying critical habitat. Until such time that blight resistance can be proven, while maintaining the American Chestnut genetic purity, hybridized American Chestnuts are not included.

6.1.2 Habitat suitability

Habitat suitability relates to areas possessing a specific set of biophysical attributes that can support individuals of the species to carry out essential aspects of their lifecycle.

The American Chestnut is found in a variety of habitats with well-drained, acidic soils. In Canada, occurrences are predominately in upland forests or woodlands, or treed cliffs within the Carolinian Zone of southern Ontario, where the growing season is long and climate is moderated by the lower Great Lakes (Tindall et al. 2004). American Chestnuts are typically associated with Red Oak (Quercus rubra), Black Cherry (Prunus serotina), Sugar Maple (Acer saccharum), Red Maple (Acer rubrum), American Beech (Fagus grandifolia), White Ash (Fraxinus Americana), White Oak (Quercus alba), Sassafras (Sassafras albidum), Shagbark Hickory (Carya ovate), and Eastern White Pine (Pinus strobus) (Ambrose and Aboud 1986, COSEWIC 2004, Tindall et al. 2004). Habitat suitability is likely associated more with site conditions (e.g., canopy cover) than specific tree compositions. A well-developed tree canopyFootnote 16 (canopy greater than 70%) is an important attribute for the American Chestnut and is a condition under which the majority of American Chestnut trees are found in Ontario (Tindall et al. 2004). However, reduced canopy cover has proven to be important for seedling establishment (Jacobs 2007).

The biophysical attributes of suitable habitat include the characteristics described below:

  • Acidic to neutral soils
  • Well-drained sandy or gravelly soils
  • Well-developed canopy where canopy cover exceeds 70%

Based on the best available information, suitable habitat for the American Chestnut is currently defined as the extent of the biophysical attributes where the American Chestnut exists in Ontario. In addition, a critical function zone of 20 m (radial distance) is applied when the biophysical attributes around a tree extend for less than 20 m.

In Ontario, suitable habitat for the American Chestnut is described using the Ecological Land Classification (ELC) framework for Southern Ontario (from Lee et al. 1998). The ELC framework provides a standardized approach to the interpretation and delineation of dynamic ecosystem boundaries. The ELC approach classifies habitats not only by vegetation community but also considers soil moisture conditions and topography, and as such provides a basis for describing the ecosystem requirements (e.g., local effects of the associated hydrologic regime, canopy cover) and encompasses the biophysical attributes of suitable habitat for the American Chestnut. In addition, ELC terminology and methods are familiar to many land managers and conservation practitioners who have adopted this tool as the standard approach for Ontario.

Within the ELC system in Ontario, the ecositeFootnote 17 boundary best captures the extent of the biophysical attributes required by the species. The ecosite includes the areas occupied by the American Chestnut and the surrounding areas that provide suitable habitat conditions to carry out essential life processes for the species and should allow for natural processes related to population dynamics and reproduction (e.g., dispersal and pollination) to occur. This is especially important when reproduction success depends on pollen dispersal from nearby American Chestnut trees.

Tindall et al. (2004) and Boland et al. (2012) have described 11 ecosites for known or newly found (and accessible) American Chestnut (Appendix C). Additional habitat assessments are required to describe and map the specific ELC ecosites currently occupied by the American Chestnut in Canada.

The 20 m radial distance is based on the critical root zone radius definition, calculated as 1.5 feet of radius for each inch of the diameter at breast height (dbh) of a tree (or 18 cm per one cm of the dbh) (Johnson 2013). Given that the largest dbh for American Chestnut in Canada prior to the introduction of the chestnut blight was 100 cm (Kershaw 2001), the critical root zone radius is calculated to be 20 m (100 cm x 18 cm = 1800 cm rounded up to the nearest 5 m). The critical root zone radius defines a critical root zone area surrounding the tree to help prevent damage or disturbance (such as soil compaction) to the roots, driplineFootnote 18 and soil (Johnson 2013).

The area within the critical root zone may include both suitable and unsuitable habitat which are required to maintain individual American Chestnut trees, which may be found near the transition area/zone between suitable and unsuitable habitat (e.g., along the woodland or forest edges). At present, it is not clear at what distance physical and/or biological processes begin to negatively affect American Chestnut. Recent studies show that the magnitude and distance of edge effects will vary depending on the structure and composition of adjacent habitat types (Harper et al. 2005). This radial distance may be refined as new information on species’ habitat requirements, site-specific characteristics, and newly germinated trees becomes available.

6.1.3 Application of the criteria to identify critical habitat for American Chestnut

Critical habitat for American Chestnut is identified as the extent of suitable habitat (6.1.2) where the occupancy criterion (6.1.1) is met. In cases where the suitable habitat extends for less than 20 m around the American Chestnut, a critical function zone capturing an area within a radial distance of 20 m is also included as critical habitat.

In Ontario, as noted above, suitable habitat for the American Chestnut is most appropriately identified as the ELC ecosite. At the present time, the ecosite boundaries (and some descriptions) are not available to support the identification of critical habitat for all populations in Ontario. In the interim, where ELC ecosite boundaries are not available, ELC community seriesFootnote 19 level is identified as the area within which critical habitat is found. When ecosite boundaries become available, the identification of critical habitat will be updated.

Application of the critical habitat criteria to the best available data identifies 201 units of critical habitat for the American Chestnut in Canada (Appendix B). This identification includes critical habitat for 64 extant populations and 90 historical populations (multiple units of critical habitat may be identified for a single population) as well as additional 31 locations, not included within current population assessments. Seven locations contained inadequate information to identify critical habitat and additional surveys are required. The critical habitat identified is considered a partial identification of critical habitat and is insufficient to meet the population and distribution objectives. Specifically, more precise locational information is required for some occurrences and the current status (i.e., continued presence and health) of occurrences that showed evidence of blight during surveys is also required. A schedule of studies (section 6.2) has been developed to provide the information necessary to complete the identification of critical habitat that will be sufficient to meet the population and distribution objectives.

Until population assessments are updated, critical habitat units may be used as a baseline for the distribution of the American Chestnut in Canada.

Critical habitat for the American Chestnut is presented using 1 x 1 km standardized UTM grid squares (Appendix B: Figure B-1 and B2, and Table B-1). The UTM grid squares are part of a standardized grid system that indicates the general geographic areas containing critical habitat, which can be used for land use planning and/or environmental assessment purposes. In addition to providing these benefits, the 1 km x 1 km UTM grid respects provincial data-sharing agreements in Ontario. Critical habitat within each grid square occurs where description of habitat occupancy (section 6.1.1) and habitat suitability (section 6.1.2) are met. More detailed information on critical habitat to support protection of the species and its habitat may be requested on a need-to-know basis by contacting Environment and Climate Change Canada – Canadian Wildlife Service at ec.planificationduretablissement-recoveryplanning.ec@canada.ca.

6.2 Schedule of studies to identify critical habitat

Table 1. Schedule of studies to identify critical habitat
Description of Activity Rationale Timeline
Confirm status and abundance, and survey habitat for 7 occurrence locations where there is insufficient information (e.g., locational uncertainty). Precise locational information of element occurrences is required to delineate additional critical habitat. 2019-2029
Assess the populations’ status by completing population surveys and health assessments of American Chestnut occurrences within populations noted as having blight; and assess habitat conditions at occupied sites. Obtain a quantitative baseline of the distribution and abundance of the American Chestnut in Canada. Identify additional critical habitat as required. 2019-2029

6.3 Activities likely to result in the destruction of critical habitat

Understanding what constitutes destruction of critical habitat is necessary for the protection and management of critical habitat. Destruction is determined on a case by case basis. Destruction would result if part of the critical habitat was degraded, either permanently or temporarily, such that it would not serve its function when needed by the species. Destruction may result from a single activity or multiple activities at one point in time or from the cumulative effects of one or more activities over time. Activities described in Table 2 are examples of those likely to cause destruction of critical habitat for the species; however, destructive activities are not necessarily limited to those listed.

Table 2. Activities likely to result in the destruction of critical habitat of the American Chestnut
Description of Activity Description of effect in relation to function loss Details of effect
Development and conversion of lands (e.g., to agriculture, commercial, road ways or residential use) Development through land clearing or construction results in a direct loss of soil substrate which is required for successful germination of American Chestnut. Construction also results in a dramatic change in habitat features such as canopy structure, soil composition (e.g., alter soil pH), associated species, and hydrologya of an area which the species relies upon for basic survival, successful seed germination and seedling establishment, and may ultimately lead to its extirpationb from the site. If this activity were to occur within the bounds of critical habitat at any time of the year, effects would be direct, and would be highly likely to result in the destruction of critical habitat by altering physical and biological properties. If this activity occurs adjacent to critical habitat at any time of the year, it can result in indirect destruction of critical habitat due to habitat alteration and edge effects.
Planting or introduction of non-native chestnuts (Castanea spp.)c Planting or introduction of non-native chestnuts within critical habitat reduces or eliminates American Chestnut’s ability to successfully reproduce. Non-native chestnut pollen can act as an “environmental pollutant” of its habitat preventing successful reproduction and recruitment of the species. American Chestnut flowers pollinated by non-native chestnut species produce a seed which is no longer considered an American Chestnut, due to hybridization, and thus can eliminate recruitment for that season. If this activity occurs within the boundary of critical habitat, it may result in temporary habitat degradation. The addition of foreign pollen to the habitat prevents the species ability to successfully reproduce and therefore removes the critical habitat’s ability to provide the necessities for survival. This activity is considered temporary as the non-native chestnut tree can be removed which would restore the quality of critical habitat.

a Hydrology of an area refers to the movement, distribution, quality, and quantity of water in that area.

b Extirpation: No longer existing at a particular site.

c Backcrossed trees that are planted for the purpose of species recovery and confirmed to be blight resistant would not contribute to this activity likely to destroy critical habitat.

7 Measuring progress

The performance indicators presented below provide a way to define and measure progress toward achieving the population and distribution objective. Every five years, success of recovery strategy implementation will be measured against the following performance indicator:

  • Population abundance and area of occupancy of American Chestnut have been maintained at or above currentFootnote 20 level

8 Statement on action plans

One or more action plans will be completed for the American Chestnut and posted on the Species at Risk Public Registry by December 31, 2026.

9 Effects on the environment and other species

A strategic environmental assessment (SEA) is conducted on all SARA recovery planning documents, in accordance with the Cabinet Directive on the Environmental Assessment of Policy, Plan and Program Proposals. The purpose of a SEA is to incorporate environmental considerations into the development of public policies, plans, and program proposals to support environmentally sound decision-making and to evaluate whether the outcomes of a recovery planning document could affect any component of the environment or any of the Federal Sustainable Development Strategy’s (FSDS) goals and targets.

Recovery planning is intended to benefit species at risk and biodiversity in general. However, it is recognized that strategies may also inadvertently lead to environmental effects beyond the intended benefits. The planning process based on national guidelines directly incorporates consideration of all environmental effects, with a particular focus on possible impacts on non-target species or habitats. The results of the SEA are incorporated directly into the strategy itself, but are also summarized below in this statement.

This federal recovery strategy will clearly benefit other species and ecosystem functions within the heavily altered Carolinian Zone. Several other species at risk and rare species share a similar preferred habitat (sandy upland forests of oak and/or maple) to the American Chestnut such as Eastern Flowering Dogwood (Cornus florida, Endangered), Bird’s-foot Violet (Viola pedata, Endangered), Virginia Goat’s-rue (Tephrosia virginiana, Endangered), Spotted Wintergreen (Chimaphila maculata, Endangered) and Eastern Hog-nosed Snake (Heterodon platyrhinos, Threatened), although it is not known whether any of these have been found at the exact sites currently occupied by American Chestnut.

The potential for this recovery strategy to inadvertently lead to adverse effects on other species was considered. Currently, recovery actions for the American Chestnut include monitoring and protecting Ontario populations, identifying blight-free populations, and conducting research into methods of chestnut blight control (OMNR 2013). These activities have very little potential to lead to adverse effects on other species that may share the habitat or range of the American Chestnut. Activities with potential impacts on other species, such as habitat management and re-introduction, are not recommended at this time. Government-supported actions (see Part 3) focus exclusively on inventory and monitoring, threat management, and increasing awareness.

Consequently, the SEA concluded that this strategy will clearly benefit the environment and will not entail significant adverse effects. For further details, the reader should refer to the following sections of the adopted provincial documents, in particular: habitat needs (Part 2, section 1.4), knowledge gaps (Part 2, section 1.7) and the government-led and government-supported actions tables from American Chestnut: Ontario’s Government Response Statement for (Part 3).

References

Ambrose, J.D. and S.W. Aboud. 1986. Status Report on the American chestnut Castanea dentata in Canada. Committee on the Status of Endangered Wildlife in Canada. Ottawa. 18 pp.

Ambrose, J.D. and P.G. Kevan. 1990. Reproductive biology of rare Carolinian plants with regard to conservation management. Pages 57-63 in G.M. Allen, P.F.J. Eagles, and S.D. Price, eds., Conserving Carolinian Canada: Conservation Biology in the Deciduous Forest Region. University of Waterloo Press, Ontario.

American Chestnut Foundation. 2014. American Chestnut Foundation [accessed 12 February 2014].

Anagnostakis, S.L. 1992. Measuring resistance of chestnut trees to chestnut blight. Canadian Journal of Forest Research 22(4): 568-571.

Boland, G. J., J. Ambrose, B. Husband, K. Elliott, and M. S. Melzer. 2012. Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario. Ontario Recovery Strategy Series. Ontario Ministry of Natural Resources, Peterborough, Ontario. vi + 43 pp.

Boland, G. J., M. S. Melzer, and D. M. Mooij. 1997. Location of American chestnut trees in southern Ontario, 1994-1997. In: Biological control of chestnut blight with hypovirulence in southern Ontario. Eds. G.J. Boland, M. Melzer, and D. Mooij. Report to Ontario Forest Research Institute, Ontario Ministry of Natural Resources.

Canadian Chestnut Council. 2017. Resistance - Hope for the Future [accessed 25 August 2017].

COSEWIC 2004. COSEWIC assessment and status report on the American chestnut Castanea dentata in Canada. Committee on the Status of Endangered Wildlife in Canada. Ottawa. vi + 19 pp.

Elkins, J. R., J. B. Given, E. Vieitez, G. Bazzigher, and G. Griffin. 1980. Vegetative propagation of large, surviving American chestnut trees [Castanea dentata, chestnut blight fungus, Endothia parasitica; USA]. Annual Report-Northern NutGrowers Association (USA).

Government of Canada. 2009. Species at Risk Act Policies, Overarching Policy Framework [Draft]. Species at Risk Act Policy and Guidelines Series. Environment and Climate Change Canada. Ottawa. 38 pp.

Griffin, G.J. 2000. Blight control and restoration of the American chestnut. Journal of Forestry 98(2): 22-27.

Harper, K.A., S.E. Macdonald, P.J. Burton, J. Chen, K. D. Brosofske, S.C. Saunders, S. Euskirchen, D. Roberts, M.S. Jaitech, and P.A. Esseen. 2005. Edge influence on forest structure and composition in fragmented landscapes. Conservation Biology 19: 768-782.

Jacobs, D.F. 2007. Toward development of silvical strategies for forest restoration of American chestnut (Castanea dentata) using blight-resistant hybrids. Biological Conservation 137:497-506.

Johnson, G. R. 2013. Protecting trees from construction damage: a homeowner's guide.

Kershaw, L. 2001. Trees of Ontario. Lone Pine Publishing. Edmonton, Alberta. 240 pp.

Lee, H. T., W. D. Bakowsky, J. Riley, J. Bowles, M. Puddister, P. Uhlig, and S. McMurray. 1998. Ecological Land Classification for Southern Ontario: First Approximation and Its Application. Ontario Ministry of Natural Resources, South Central Science Section, Science Development and Transfer Branch.

Melzer, M.S. and G.J. Boland. 2004. Survey of American chestnut and chestnut blight in Ontario. Canadian plant disease survey = Inventaire des maladies des plantes au Canada 84: 118-119.

Mooij, D. L. 1997. A Prescriptive Approach to Using Hypovirulence as a Biological Control of Chestnut Blight Caused by Cryphonectria Parasitica. Thesis, University of Guelph, Guelph, Ontario.

Natural Heritage Information Centre (NHIC). 2014. Element Occurrence Data for American Chestnut. Ontario Ministry of Natural Resources; Peterborough.

NatureServe. 2014. NatureServe Explorer: An online encyclopedia of life. [accessed 21 January 2014].

Ontario Ministry of Natural Resources (OMNR). 2013. Government Response Statement for the American Chestnut (PDF).  Accessed February 25, 2015.

Paillet, F. L. 2002. Chestnut: history and ecology of a transformed species. Journal of Biogeography 29:1517-1530.

Tindall, J. R., J. A. Gerrath, M. S. Melzer, K. McKendry, B. C. Husband, and G. J. Boland. 2004. Ecological status of American chestnut (Castanea dentata) in its native range in Canada. Canadian Journal of Forest Research 34:2554-2563.

Zon, R. 1904. Chestnut in southern Maryland. US Department of Agriculture, Bureau of Forestry.

Appendix A: subnational conservation ranks of American Chestnut (Castanea dentata) in Canada and the United States

Subnational Conservation Ranks of American Chestnut (Castanea dentata) in Canada and the United States
Species Global (G) Rank National (N) Rank
(Canada)
Sub-national (S) Rank
(Canada)
National (N) Rank
(United States)
Sub-national (S) Rank
(United States)
American Chestnut
(Castanea dentata)
G4 N2 Ontario (S2) N4 Alabama (SNR), Connecticut (SNR), Delaware (S4), District of Columbia (S1S2), Florida (SX), Georgia (S3), Illinois (SX), Indiana (S3), Iowa (SNA), Kentucky (S1?), Maine (S4), Maryland (S2S3), Massachusetts (SNR), Michigan (S1S2), Mississippi (S1), Missouri (SNR), New Hampshire (SNR), New Jersey (S4), New York (S5), North Carolina (S4), Ohio (S3), Pennsylvania (S5), Rhode Island (SNR), South Carolina (SNR), Tennessee (S2S3), Vermont (SNR), Virginia (S4), West Virginia (S4), Wisconsin (SNR)

Rank Definitions (NatureServe 2014)

S1: Critically Imperilled - At very high risk of extirpation in the jurisdiction (i.e., N - nation, or S -state/province) due to very restricted range, very few populations or occurrences, very steep declines, severe threats, or other factors.

S1?: Inexact numeric ranking/Critically Imperilled: Does not meet the definition of Critically Imperilled exactly.

S1S2: Imperilled to Critically Imperilled - At a high to very high risk of extirpation in the jurisdiction due to restricted to very restricted range, few to very few populations or occurrences, steep to very steep declines, severe threats, or other factors.

N2/S2: Imperilled - At high risk of extirpation in the jurisdiction due to restricted range, few populations or occurrences, steep declines, severe threats, or other factors.

S2S3: Vulnerable/Imperilled: The risk of extirpation in the jurisdiction ranges from moderate to high due to a fairly restricted to restricted range, relatively few to few populations or occurrences, recent and widespread to steep declines, moderate to severe threats, or other factors.

S3: Vulnerable: At moderate risk of extirpation in the jurisdiction due to a fairly restricted range, relatively few populations or occurrences, recent and widespread declines, threats, or other factors.

G4/N4/S4: Apparently Secure: At a fairly low risk of extirpation in the jurisdiction due to an extensive range and/or many populations or occurrences, but with possible cause for some concern as a result of local recent declines, threats, or other factors.

S5: Secure – At very low risk of extinction or elimination due to a very extensive range, abundant populations or occurrences, and little to no concern from declines or threats.

SNR: Unranked – National or subnational conservation status not yet assessed.

SNA: Not applicable: A conservation status rank is not applicable because the species or ecosystem is not a suitable target for conservation activities.

SX: Presumed Extirpated — Species or ecosystem is believed to be extirpated from the jurisdiction (i.e., nation, or state/province). Not located despite intensive searches of historical sites and other appropriate habitat, and virtually no likelihood that it will be rediscovered.

Appendix B: critical habitat for the American Chestnut (Castanea dentata) in Canada

Figure B1
Figure B-1. Grid squares that contain critical habitat for the American Chestnut in Canada. Critical habitat for the American Chestnut occurs within these 1 x 1 km standardized UTM grid squares (red shaded squares), where the criteria described in Section 6.1 are met.
Long description

Figure B-1 shows the 345 1x1 km grid squares where critical habitat for the American Chestnut is found in Ontario. The grid squares are found in the South of Ontario between the cities of Kitchener, Niagara Falls, and London. There are three areas of high concentration. The main area has 219 grid squares distributed between Tillsonburg, Port Dover and Port Rowan. The second has 64 grid squares scattered between Kitchener, Oakville, Hamilton and Brantford. The third area has 62 grid squares scattered between St Catharines, Niagara Falls and Hagersville

Figure B2
Figure B-2. Grid squares that contain critical habitat for the American Chestnut in Canada. Critical habitat for the American Chestnut occurs within these 1 x 1 km standardized UTM grid squares (red shaded squares), where the criteria described in Section 6.1 are met.
Long description

Figure B-2 shows the 85 1x1 km grid squares where critical habitat for the American Chestnut is found in Ontario. The grid squares are found in the southwest of Ontario between the cities of Windsor and London. There are three areas of concentration. The main area has 63 grid squares scattered between Glencoe, Ridgetown and Dresden. The second concentration has15 grid squares scattered between Windsor and Leamington. The third concentration has seven grid squares scattered in the southwest of London

Table B-1 Grids square that contains critical habitat for the American Chestnut in Canada. Critical habitat for American Chestnut occurs within this 1 x 1 km standardized UTM grid where the criteria described in Section 6 are met
Critical Habitat units 1 x 1 km Standardized UTM Grid Square IDd County UTM Grid Square Coordinatese
Easting
UTM Grid Square Coordinatese
Northing
Land Tenuref
1 17TNH4713
17TNH4714
17TNH4723
17TNH4724
Brant 541000
541000
542000
542000
4773000
4774000
4773000
4774000
Non-federal Land
2 17TNH5811 Brant 551000 4781000 Non-federal Land
3 17TNH5970 Brant 557000 4790000 Non-federal Land
4 17TNH5981
17TNH5982
Brant 558000
558000
4791000
4792000
Non-federal Land
5 17TNH5839 Brant 553000 4789000 Non-federal Land
6 17TNH5971
17TNH5981
Brant 557000
558000
4791000
4791000
Non-federal Land
7 17TMH4194
17TMH4195
Elgin 449000
449000
4714000
4715000
Non-federal Land
8 17TMH5104 Elgin 450000 4714000 Non-federal Land
9 17TNH1228
17TNH1237
17TNH1238
Elgin 512000
513000
513000
4728000
4727000
4728000
Non-federal Land
10 17TNH2211
17TNH2212
17TNH2221
17TNH2222
Elgin 521000
521000
522000
522000
4721000
4722000
4721000
4722000
Non-federal Land
11 17TNH1320
17TNH1321
17TNH1330
17TNH1331
Elgin 512000
512000
513000
513000
4730000
4731000
4730000
4731000
Non-federal Land
12 17TNH9380
17TNH9390
Elgin 498000
499000
4730000
4730000
Non-federal Land
13 17TMH9371
17TMH9372
17TMH9381
17TMH9382
Elgin 497000
497000
498000
498000
4731000
4732000
4731000
4732000
Non-federal Land
14 17TNH0213
17TNH0214
Elgin 501000
501000
4723000
4724000
Non-federal Land
15 17TMH8265
17TMH8266
Elgin 486000
486000
4725000
4726000
Non-federal Land
16 17TMH9243 Elgin 494000 4723000 Non-federal Land
17 17TMH5111
17TMH5112
17TMH5121
17TMH5122
Elgin 451000
451000
452000
452000
4711000
4712000
4711000
4712000
Non-federal Land
18 17TNH2217
17TNH2218
17TNH2227
17TNH2228
Elgin 521000
521000
522000
522000
4727000
4728000
4727000
4728000
Non-federal Land
19 17TNH1257 Elgin 515000 4727000 Non-federal Land
20 17TNH9265
17TNH9275
17TNH9276
17TNH9285
Elgin 496000
497000
497000
498000
4725000
4725000
4726000
4725000
Non-federal Land
21 17TMH5124
17TMH5125
17TMH5135
Elgin 452000
452000
453000
4714000
4715000
4715000
Non-federal Land
22 17TMH8269
17TMH8279
Elgin 486000
487000
4729000
4729000
Non-federal Land
23 17TNH1286
17TNH1287
Elgin 518000
518000
4726000
4727000
Non-federal Land
24 17TNH1267 Elgin 516000 4727000 Non-federal Land
25 17TNH0279
17TNH0289
17TNH0299
17TNH0370
17TNH0380
17TNH0390
Elgin 507000
508000
509000
507000
508000
509000
4729000
4729000
4729000
4730000
4730000
4730000
Non-federal Land
26 17TNH1394
17TNH2303
17TNH2304
17TNH2314
Elgin 519000
520000
520000
521000
4734000
4733000
4734000
4734000
Non-federal Land
27 17TNH1296
17TNH1297
Elgin 519000
519000
4726000
4727000
Non-federal Land
28 17TMH4128
17TMH4129
Elgin 442000
442000
4718000
4719000
Non-federal Land
29 17TNH1294
17TNH2204
Elgin 519000
520000
4724000
4724000
Non-federal Land
30 17TMH4029 Elgin 442000 4709000 Non-federal Land
31 17TNH2300
17TNH2301
17TNH2302
17TNH2311
17TNH2312
Elgin 520000
520000
520000
521000
521000
4730000
4731000
4732000
4731000
4732000
Non-federal Land
32 17TMH4156
17TMH4157
Elgin 445000
445000
4716000
4717000
Non-federal Land
33 17TMH4165
17TMH4175
Elgin 446000
447000
4715000
4715000
Non-federal Land
34 17TMH9294
17TNH0204
Elgin 499000
500000
4724000
4724000
Non-federal Land
35 17TMH9258
17TMH9259
17TMH9268
17TMH9269
Elgin 495000
495000
496000
496000
4728000
4729000
4728000
4729000
Non-federal Land
36 17TLG4593
17TLG4594
Essex 349000
349000
4653000
4654000
Non-federal Land
37 17TLG7526 Essex 372000 4656000 Non-federal Land
38 17TLG3718 Essex 331000 4678000 Non-federal Land
39 17TLG3800
17TLG3801
Essex 330000
330000
4680000
4681000
Non-federal Land
40 17TLG2871 Essex 327000 4681000 Non-federal Land
41 17TLG6644 Essex 364000 4664000 Non-federal Land
42 17TLG7544
17TLG7545
17TLG7554
17TLG7555
Essex 374000
374000
375000
375000
4654000
4655000
4654000
4655000
Non-federal Land
43 17TLG7547 Essex 374000 4657000 Non-federal Land
44 17TLG7537
17TLG7547
Essex 373000
374000
4657000
4657000
Non-federal Land
45 17TLG7569 Essex 376000 4659000 Non-federal Land
46 17TLG7530 Essex 373000 4660000 Non-federal Land
47 17TLG4551
17TLG4552
Essex 345000
345000
4651000
4652000
Non-federal Land
48 17TLG7622 Essex 372000 4622000 Non-federal Land
49 17TNH4395
17TNH5395
Norfolk 549000
550000
4735000
4735000
Non-federal Land
50 17TNH4337
17TNH4338
Norfolk 543000
543000
4737000
4738000
Non-federal Land
51 17TNH3399
17TNH3490
17TNH3491
17TNH4390
17TNH4400
17TNH4401
Norfolk 539000
539000
539000
540000
540000
540000
4739000
4740000
4741000
4739000
4740000
4741000
Non-federal Land
52 17TNH5259
17TNH5340
17TNH5340
17TNH5351
17TNH5360
Norfolk 555000
554000
555000
555000
556000
4729000
4730000
4730000
4731000
4730000
Non-federal Land
53 17TNH4363
17TNH4364
17TNH4373
17TNH4374
17TNH4384
17TNH4394
17TNH4395
Norfolk 546000
546000
547000
547000
548000
549000
549000
4733000
4734000
4733000
4734000
4734000
4734000
4735000
Non-federal Land
54, 55 17TNH2235
17TNH2236
17TNH2276
17TNH2277
Norfolk 523000
523000
527000
527000
4725000
4726000
4726000
4727000
Non-federal Land
56 17TNH2251
17TNH2252
17TNH2261
17TNH2262
Norfolk 525000
525000
526000
526000
4721000
4722000
4721000
4722000
Non-federal Land
57 17TNH2283
17TNH2284
17TNH2293
Norfolk 528000
528000
529000
4723000
4724000
4723000
Non-federal Land
58 17TNH2241
17TNH2242
17TNH2251
17TNH2252
Norfolk 524000
524000
525000
525000
4721000
4722000
4721000
4722000
Non-federal Land
59 17TNH2199
17TNH2290
17TNH3109
Norfolk 529000
529000
530000
4719000
4720000
4719000
Non-federal Land
60 17TNH3308
17TNH3309
17TNH3319
17TNH3400
Norfolk 530000
530000
531000
530000
4738000
4739000
4739000
4740000
Non-federal Land
61 17TNH2450 Norfolk 525000 4740000 Non-federal Land
62 17TNH5475
17TNH5485
Norfolk 557000
558000
4745000
4745000
Non-federal Land
63 17TNH5578 Norfolk 557000 4758000 Non-federal Land
64 17TNH5556
17TNH5557
17TNH6631
Norfolk 555000
555000
563000
4756000
4757000
4761000
Non-federal Land
65, 66 17TNH3346
17TNH3347
17TNH3356
17TNH3357
17TNH3365
17TNH3366
17TNH3375
17TNH3376
Norfolk 534000
534000
535000
535000
536000
536000
537000
537000
4736000
4737000
4736000
4737000
4735000
4736000
4735000
4736000
Non-federal Land
67 17TNH3345
17TNH3346
Norfolk 534000
534000
4735000
4736000
Non-federal Land
68 17TNH4212
17TNH4213
17TNH4222
17TNH4223
Norfolk 541000
541000
542000
542000
4722000
4723000
4722000
4723000
Non-federal Land
69 17TNH4214
17TNH4224
17TNH4225
Norfolk 541000
542000
542000
4724000
4724000
4725000
Non-federal Land
70 17TNH4215
17TNH4216
17TNH4225
17TNH4226
Norfolk 541000
541000
542000
542000
4725000
4726000
4725000
4726000
Non-federal Land
71 17TNH3283
17TNH3293
Norfolk 538000
539000
4723000
4723000
Non-federal Land
72 17TNH3241
17TNH3242
17TNH3251
17TNH3252
17TNH3262
Norfolk 534000
534000
535000
535000
536000
4721000
4722000
4721000
4722000
4722000
Non-federal Land
73 17TNH3159
17TNH3169
17TNH3179
17TNH3250
17TNH3251
17TNH3260
17TNH3261
Norfolk 535000
536000
537000
535000
535000
536000
536000
4719000
4719000
4719000
4720000
4721000
4720000
4721000
Non-federal Land
74 17TNH4474
17TNH4475
Norfolk 547000
547000
4744000
4745000
Non-federal Land
75 17TNH5566
17TNH5567
Norfolk 556000
556000
4756000
4756000
Non-federal Land
76 17TNH4585
17TNH4595
Norfolk 548000
549000
4755000
4755000
Non-federal Land
77 17TNH4577
17TNH4578
17TNH4588
Norfolk 547000
547000
548000
4757000
4758000
4758000
Non-federal Land
78 17TNH6406 Norfolk 560000 4746000 Non-federal Land
79 17TNH5408 Norfolk 550000 4748000 Non-federal Land
80 17TNH4496
17TNH4497
17TNH5406
17TNH5407
17TNH5416
17TNH5417
Norfolk 549000
549000
550000
550000
551000
551000
4746000
4747000
4746000
4747000
4746000
4747000
Non-federal Land
81 17TNH4451
17TNH4452
Norfolk 545000
545000
4741000
4742000
Non-federal Land
83 17TNH4379
17TNH4470
17TNH4480
Norfolk 547000
547000
548000
4730000
4740000
4740000
Non-federal Land
83, 84, 85 17TNH4398
17TNH4399
17TNH4490
17TNH5308
17TNH5309
17TNH5329
17TNH5400
17TNH5420
17TNH5430
Norfolk 549000
549000
549000
550000
550000
552000
550000
552000
553000
4738000
4739000
4740000
4738000
4739000
4739000
4740000
4740000
4740000
Non-federal Land
86 17TNH5335 Norfolk 553000 4735000 Non-federal Land
87 17TNH5317
17TNH5327
Norfolk 551000
552000
4737000
4737000
Non-federal Land
88 17TNH4396
17TNH4397
17TNH5306
17TNH5307
Norfolk 549000
549000
550000
550000
4736000
4737000
4736000
4737000
Non-federal Land
89 17TNH4372
17TNH4373
Norfolk 547000
547000
4732000
4733000
Non-federal Land
90, 91 17TNH4338
17TNH4345
17TNH4346
17TNH4347
17TNH4348
17TNH4355
17TNH4357
17TNH4358
Norfolk 543000
544000
544000
544000
544000
545000
545000
545000
4738000
4735000
4736000
4737000
4738000
4735000
4737000
4738000
Non-federal Land
92 17TNH4327
17TNH4328
Norfolk 542000
542000
4737000
4738000
Non-federal Land
93 17TNH5219
17TNH5229
17TNH5310
17TNH5320
Norfolk 551000
552000
551000
552000
4729000
4729000
4730000
4730000
Non-federal Land
94 17TNH5219
17TNH5229
Norfolk 551000
552000
4729000
4729000
Non-federal Land
95 17TNH5236
17TNH5246
17TNH5247
Norfolk 553000
554000
554000
4726000
4726000
4727000
Non-federal Land
96 17TNH4284
17TNH4294
Norfolk 548000
549000
4724000
4724000
Non-federal Land
97, 98 17TNH4266
17TNH4267
17TNH4276
17TNH4277
Norfolk 546000
546000
547000
547000
4726000
4727000
4726000
4727000
Non-federal Land
99 17TNH4237
17TNH4246
17TNH4247
17TNH4248
17TNH4257
17TNH4258
Norfolk 543000
544000
544000
544000
545000
545000
4727000
4726000
4727000
4728000
4727000
4728000
Non-federal Land
100 17TNH4231
17TNH4232
Norfolk 543000
543000
4721000
4722000
Non-federal Land
101 17TNH3282 Norfolk 538000 4722000 Non-federal Land
102 17TNH3257
17TNH3266
17TNH3267
Norfolk 535000
536000
536000
4727000
4726000
4727000
Non-federal Land
103 17TNH3228
17TNH3238
17TNH3239
Norfolk 532000
533000
533000
4728000
4728000
4729000
Non-federal Land
104 17TNH3388
17TNH3398
Norfolk 538000
539000
4738000
4738000
Non-federal Land
105 17TNH3201
17TNH3202
17TNH3211
17TNH3212
Norfolk 530000
530000
531000
531000
4721000
4722000
4721000
4722000
Non-federal Land
106 17TNH2232 Norfolk 523000 4722000 Non-federal Land
107 17TNH2380
17TNH2381
17TNH2391
Norfolk 528000
528000
529000
4730000
4731000
4731000
Non-federal Land
108 17TNH4362
17TNH4363
Norfolk 546000
546000
4732000
4733000
Non-federal Land
109 17TNH3353
17TNH3354
Norfolk 535000
535000
4733000
4734000
Non-federal Land
110 17TNH2347
17TNH2348
Norfolk 524000
524000
4737000
4738000
Non-federal Land
111 17TNH2296
17TNH2297
17TNH3206
17TNH3207
Norfolk 529000
529000
530000
530000
4726000
4727000
4726000
4727000
Non-federal Land
112 17TNH2399
17TNH2490
17TNH3309
17TNH3400
Norfolk 529000
529000
530000
530000
4739000
4740000
4739000
4740000
Non-federal Land
113 17TNH5508 Norfolk 550000 4758000 Non-federal Land
114 17TNH2379
17TNH2470
Norfolk 527000
527000
4739000
4740000
Non-federal Land
115 17TNH3322
17TNH3332
Norfolk 532000
533000
4732000
4732000
Non-federal Land
116 17TNH3323
17TNH3324
17TNH3333
17TNH3334
Norfolk 532000
532000
533000
533000
4733000
4734000
4733000
4734000
Non-federal Land
117 17TPH1514
17TPH1524
Haldimand 611000
612000
4754000
4754000
Non-federal Land
118 17TPH1571 Haldimand 617000 4751000 Non-federal Land
119 17TPH0575
17TPH0576
Haldimand 607000
607000
4755000
4756000
Non-federal Land
120 17TPH1500
17TPH1510
Haldimand 610000
611000
4750000
4750000
Non-federal Land
121 17TNH9630
17TNH9631
17TNH9640
17TNH9641
Haldimand 593000
593000
594000
594000
4760000
4761000
4760000
4761000
Non-federal Land
122 17TNH8555
17TNH8556
17TNH8565
17TNH8566
Haldimand 585000
585000
586000
586000
4755000
4756000
4755000
4756000
Non-federal Land
123 17TNH9916
17TNH9917
17TNH9926
17TNH9927
Halton 591000
591000
592000
592000
4796000
4797000
4796000
4979000
Non-federal Land
124 17TNJ9008
17TNJ9017
17TNJ9018
17TNJ9027
Halton 590000
591000
591000
592000
4808000
4807000
4808000
4807000
Non-federal Land
125, 126 17TPJ0023
17TPJ0024
17TPH0034
Halton 603000
602000
603000
4803000
4804000
4804000
Non-federal Land
127, 128 17TNH8986
17TNH8996
17TNH8997
17TNH9906
17TNH9916
Halton 588000
589000
589000
590000
591000
4796000
4796000
4797000
4796000
4976000
Non-federal Land
129 17TNH9907 Halton 590000 4797000 Non-federal Land
130 17TNH7885
17TNH7886
17TNH7895
17TNH7896
17TNH7897
17TNH8805
17TNH8806
17TNH8807
17TNH8815
17TNH8816
Hamilton 578000
578000
579000
579000
579000
580000
580000
580000
581000
581000
4785000
4786000
4785000
4786000
4787000
4785000
4786000
4787000
4785000
4786000
Non-federal Land
131 17TNH7887
17TNH7888
17TNH7897
17TNH7898
Hamilton 578000
578000
579000
579000
4787000
4788000
4787000
47880000
Non-federal Land
132 17TNH7857
17TNH7867
Hamilton 475000
476000
4787000
4787000
Non-federal Land
133 17TNH8857
17TNH8856
17TNH8867
17TNH8868
Hamilton 585000
585000
586000
586000
4787000
4788000
4787000
4788000
Non-federal Land
134 17TNH7879
17TNH7889
17TNH7970
17TNH7980
Hamilton 577000
578000
577000
578000
4789000
4789000
4790000
4790000
Non-federal Land
135 17TNH8972
17TNH8982
Hamilton 587000
588000
4792000
4792000
Non-federal Land
136 17TNH8921
17TNH8922
17TNH8931
17TNH8932
Hamilton 582000
582000
583000
583000
4791000
4792000
4791000
4792000
Non-federal Land
137 17TNH8809
17TNH8819
17TNH8900
17TNH8910
17TNH8920
17TNH8921
Hamilton 580000
581000
580000
581000
582000
582000
4789000
4789000
4790000
4790000
4790000
4791000
Non-federal Land
138 17TNH7992 Hamilton 579000 4792000 Non-federal Land
139 17TNH7897
17TNH7898
17TNH8807
17TNH8808
Hamilton 579000
579000
580000.
580000
4787000
4788000
4787000
4788000
Non-federal Land
140 17TNH8865 Hamilton 586000 4785000 Non-federal Land
141 17TMH1039
17TMH1040
Chatham-Kent 413000
414000
4709000
4709000
Non-federal Land
142 17TMH2185
17TMH2186
17TMH2196
Chatham-Kent 428000
428000
429000
4715000
4716000
4716000
Non-federal Land
143 17TMH2167
17TMH2168
Chatham-Kent 426000
426000
4717000
4718000
Non-federal Land
144 17TMG4919
17TMH4010
17TMH4011
17TMH4020
17TMH4021
Chatham-Kent 441000
441000
441000
442000
442000
4699000
4700000
4701000
4700000
4701000
Non-federal Land
145 17TMH2104
17TMH2105
Chatham-Kent 420000
420000
4714000
4715000
Non-federal Land
146 17TMH1089
17TMH1099
Chatham-Kent 418000
419000
4709000
4709000
Non-federal Land
147 17TMH2087
17TMH2097
17TMH2098
Chatham-Kent 428000
429000
429000
4707000
4707000
4708000
Non-federal Land
148 17TLG7690
17TLG8600
Chatham-Kent 379000
380000
4660000
4660000
Non-federal Land
149 17TMH6521 Middlesex 462000 4751000 Non-federal Land
150 17TMH7515
17TMH7516
Middlesex 471000
471000
4755000
4756000
Non-federal Land
151 17TMH3213
17TMH3214
17TMH3223
17TMH3224
Middlesex 431000
431000
432000
432000
4723000
4724000
4723000
4724000
Non-federal Land
152 17TMH3221
17TMH3222
17TMH3223
17TMH3230
17TMH3231
17TMH3232
17TMH3233
17TMH3234
17TMH3240
17TMH3241
17TMH3242
17TMH3243
17TMH3244
17TMH3252
17TMH3253
17TMH3254
Middlesex 432000
432000
432000
433000
433000
433000
433000
433000
434000
434000
434000
434000
434000
435000
435000
435000
4721000
4722000
4723000
4720000
4721000
4722000
4723000
4724000
4720000
4721000
4722000
4723000
4724000
4722000
4723000
4724000
Non-federal Land
153 17TMH6593 Middlesex 469000 4753000 Non-federal Land
154 17TMH5572 Middlesex 457000 4752000 Non-federal Land
155 17TMH3211 Middlesex 431000 4721000 Non-federal Land
156 17TMH7544 Middlesex 474000 4754000 Non-federal Land
157 17TMH3228 Middlesex 432000 4728000 Non-federal Land
158 17TMH7545 Middlesex 474000 4755000 Non-federal Land
159   17TMH3215 Middlesex 431000 4725000 Non-federal Land
160 17TPH3615
17TPH3616
Niagara 631000
631000
4765000
4766000
Non-federal Land
161 17TPH3635
17TPH3636
Niagara 633000
633000
4765000
4766000
Non-federal Land
162 17TPH3636 Niagara 633000 4766000 Non-federal Land
163 17TPH3635 Niagara 633000 4765000 Non-federal Land
164 17TPH3668
17TPH3678
Niagara 636000
637000
4768000
4768000
Non-federal Land
165 17TPH57383
17TPH5748
Niagara 653000
654000
4778000
4778000
Non-federal Land
166 7TPH3688 Niagara 638000 4768000 Non-federal Land
167 17TPH3792
17TPH3793
17TPH3794
17TPH4702
17TPH4703
17TPH4704
Niagara 639000
639000
639000
640000
640000
640000
4772000
4773000
4774000
4772000
4773000
4774000
Non-federal Land
168 17TPH2919
17TPH2929
17TPH2610
17TPH2620
Niagara 621000
622000
621000
622000
4759000
4759000
4760000
4760000
Non-federal Land
169 17TPH3689
17TPH3770
17TPH3771
17TPH3780
17TPH3781
Niagara 638000
637000
637000
638000
638000
4769000
4770000
4771000
4770000
4771000
Non-federal Land
170 17TPH5870
17TPH5880
Niagara 657000
658000
4780000
4780000
Non-federal Land
171 17TPH5760
17TPH5761
17TPH5762
Niagara 656000
656000
656000
4770000
4771000
4772000
Non-federal Land
172 17TPH5769
17TPH5779
17TPH5760
17TPH5770
Niagara 656000
657000
656000
657000
4779000
4779000
4780000
4780000
Non-federal Land
173 17TPH5738 Niagara 653000 4778000 Non-federal Land
174 17TPH3850 Niagara 635000 4780000 Non-federal Land
175 17TPH3745
17TPH3746
Niagara 634000
634000
4775000
4776000
Non-federal Land
176 17TPH1852
17TPH1853
17TPH1862
17TPH1863
Niagara 615000
615000
616000
616000
4782000
4783000
4782000
4783000
Non-federal Land
177 17TPH1872
17TPH1881
17TPH1882
17TPH1891
Niagara 617000
618000
618000
619000
4782000
4781000
4782000
4781000
Non-federal Land
178 17TPH2800
17TPH2801
17TPH2810
Niagara 620000
620000
621000
4780000
4781000
4780000
Non-federal Land
179 17TPH2568
17TPH2569
Niagara 626000
626000
4758000
4759000
Non-federal Land
180 17TPH3642 Niagara 634000 4762000 Non-federal Land
181 17TPH3653
17TPH3654
Niagara 635000
635000
4763000
4764000
Non-federal Land
182 17TPH3636 Niagara 633000 4766000 Non-federal Land
183 17TPH3646 Niagara 634000 4766000 Non-federal Land
184 17TPH3647 Niagara 634000 4767000 Non-federal Land
185 17TPH3666 Niagara 636000 4766000 Non-federal Land
186 17TPH4605 Niagara 640000 4765000 Non-federal Land
187 17TPH4605
17TPH4606
Niagara 640000
640000
4765000
4766000
Non-federal Land
188 17TPH3669 Niagara 636000 4769000 Non-federal Land
189 17TPH3687
17TPH3697
17TPH3698
Niagara 638000
639000
639000
4767000
4767000
4768000
Non-federal Land
190 17TPH4608
17TPH4609
Niagara 640000
640000
4768000
4769000
Non-federal Land
191 17TPH3687 Niagara 638000 4767000 Non-federal Land
192 17TPH3699
17TPH4609
Niagara 639000
640000
4769000
4769000
Non-federal Land
193 17TPH4704 Niagara 640000 4774000 Non-federal Land
194 17TPH2553
17TPH2554
Niagara 625000
625000
4753000
4754000
Non-federal Land
195 17TNJ5002
17TNJ5003
17TNJ5012
17TNJ5013
Waterloo 550000
550000
551000
551000
4802000
4803000
4802000
4803000
Non-federal Land
196 17TNH5984
17TNH5985
Waterloo 558000
558000
4794000
4950000
Non-federal Land
197 17TNH5994 Waterloo 559000 4794000 Non-federal Land
198 17TNJ5094
17TNJ5095
17TNJ6004
17TNJ6005
17TNJ6006
17TNJ6015
Wellington 559000
559000
560000
560000
560000
561000
4804000
4805000
4804000
4805000
4806000
4805000
Non-federal Land
199 17TMH2162
17TMH2171
17TMH2172
17TMH2173
17TMH2181
17TMH2182
17TMH2183
17TMH2184
17TMH2192
17TMH2193
Wellington 426000
427000
427000
427000
428000
428000
428000
428000
429000
429000
4712000
4711000
4712000
4713000
4711000
4712000
4713000
4714000
4712000
4713000
Non-federal Land
200 17TNH3511
17TNH3521
Oxford 531000
532000
4751000
4751000
Non-federal Land
201 17TMH1267
17TMH1268
17TMH1277
17TMH1278
Lambton 416000
416000
417000
417000
4727000
4728000
4727000
4728000
Non-federal Land

d Based on the standard UTM Military Grid Reference System, where the first 2 digits and letter represent the UTM Zone, the following 2 letters indicate the 100 x 100 km standardized UTM grid, followed by 2 digits to represent the 10 x 10 km standardized UTM grid. The last 2 digits represent the 1 x 1 km standardized UTM grid containing all or a portion of the critical habitat unit. This unique alphanumeric code is based on the methodology produced from the Breeding Bird Atlases of Canada.

e The listed coordinates are a cartographic representation of where critical habitat can be found, presented as the southwest corner of the 1 x 1 km standardized UTM grid square containing all or a portion of the critical habitat unit. The coordinates may not fall within critical habitat and are provided as a general location only.

f Land tenure is provided as an approximation of the types of land ownership that exist where critical habitat has been identified and should be used for guidance purposes only. Accurate land tenure will require cross referencing critical habitat boundaries with surveyed land parcel information.

Appendix C: Ecosites for known or newly found (and accessible) American Chestnut (Tindall et al. 2004; Boland et al. 2012)

Ecosites for known or newly found (and accessible) American Chestnut
ELC Community Series (ELC Code) ELC Ecosite (ELC Code)
Treed Cliff (CLT) Not applicable
Deciduous Forest (FOD)
  • Dry-fresh Oak Deciduous Forest Ecosite (FOD1)
  • Dry-fresh Oak-Maple-Hickory Deciduous Forest Ecosite (FOD2)
  • Dry-fresh Deciduous Forest Ecosite (FOD4)
  • Dry-fresh Sugar Maple Deciduous Forest Ecosite (FOD5)
  • Fresh-moist Sugar Maple Deciduous Forest Ecosite (FOD6)
  • Fresh-moist Lowland Deciduous Forest Ecosite (FOD7)
  • Fresh-moist Oak-Maple-Hickory Deciduous Forest Ecosite (FOD9)
Mixed Forest (FOM)
  • Dry-Oak-Pine Mixed Forest Ecosite (FOM1)
  • Dry-fresh White Pine-Maple-Oak Mixed Forest Ecosite (FOM2)
Coniferous Forest (FOC)
  • Dry-fresh Pine Coniferous Forest Ecosite (FOC1)

Part 2 – Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario, prepared for the Ontario Ministry of Natural Resources

About the Ontario recovery strategy series

This series presents the collection of recovery strategies that are prepared or adopted as advice to the Province of Ontario on the recommended approach to recover species at risk. The Province ensures the preparation of recovery strategies to meet its commitments to recover species at risk under the Endangered Species Act (ESA) and the Accord for the Protection of Species at Risk in Canada.

What is recovery?

Recovery of species at risk is the process by which the decline of an endangered, threatened, or extirpated species is arrested or reversed, and threats are removed or reduced to improve the likelihood of a species’ persistence in the wild.

What is a recovery strategy?

Under the ESA a recovery strategy provides the best available scientific knowledge on what is required to achieve recovery of a species. A recovery strategy outlines the habitat needs and the threats to the survival and recovery of the species. It also makes recommendations on the objectives for protection and recovery, the approaches to achieve those objectives, and the area that should be considered in the development of a habitat regulation. Sections 11 to 15 of the ESA outline the required content and timelines for developing recovery strategies published in this series.

Recovery strategies are required to be prepared for endangered and threatened species within one or two years respectively of the species being added to the Species at Risk in Ontario list. There is a transition period of five years (until June 30, 2013) to develop recovery strategies for those species listed as endangered or threatened in the schedules of the ESA. Recovery strategies are required to be prepared for extirpated species only if reintroduction is considered feasible.

What's next?

Nine months after the completion of a recovery strategy a government response statement will be published which summarizes the actions that the Government of Ontario intends to take in response to the strategy. The implementation of recovery strategies depends on the continued cooperation and actions of government agencies, individuals, communities, land users, and conservationists.

For more information

To learn more about species at risk recovery in Ontario, please visit the Ministry of Natural Resources Species at Risk webpage

Document information

Recommended citation: Boland, G.J., J. Ambrose, B. Husband, K.A. Elliott and M.S. Melzer. 2012. Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario. Ontario Recovery Strategy Series. Prepared for the Ontario Ministry of Natural Resources, Peterborough, Ontario. vi + 43 pp.

Cover illustration: Allen Woodliffe

Content (excluding the cover illustration) may be used without permission, with appropriate credit to the source.

Cette publication hautement spécialisée Recovery strategies prepared under the Endangered Species Act, 2007, n’est disponible qu’en Anglais en vertu du Règlement 411/97 qui en exempte l’application de la Loi sur les services en français. Pour obtenir de l’aide en français, veuillez communiquer avec Pamela Wesley au ministère des Richesses naturelles au 705-755-5217.

Authors

Greg Boland - University of Guelph
John Ambrose - Botanical Consultant
Brian Husband - University of Guelph
Ken A. Elliott, RPF - Ontario Ministry of Natural Resources
Melody Melzer - University of Guelph

Acknowledgments

Members of the recovery team wish to acknowledge the numerous landowners who provided access to their properties during various past inventory and monitoring projects. As well, we want to thank the Canadian Chestnut Council (CCC) for their tireless efforts to promote the importance of saving this legendary tree species and for their continuing on-the-ground work in the areas of maintaining, breeding and restoring chestnut trees. We would also like to acknowledge the field work and research conducted by Jeffrey Tindall, John Gerrath and Karen McKendry and the financial support of the World Wildlife Fund (WWF) and Canadian Wildlife Service (CWS) through the Endangered Species Recovery Fund, the Natural Sciences and Engineering Research Council of Canada and the Ontario Ministry of Natural Resources (OMNR). This assistance allowed the team to finalize the first WWF-based Recovery Plan in October 2000 and the researchers were able to finalize the 2001-2003 inventory and first ecological report (2005) under that plan. Finally we would like to thank all of our Advisory Committee Members and the many reviewers and advisors within the OMNR and the CWS who helped us through the numerous drafts and revisions to this strategy.

Declaration

The recovery strategy for the American Chestnut has been prepared in accordance with the requirements of the Endangered Species Act, 2007 (ESA). This recovery strategy has been prepared as advice to the Government of Ontario, other responsible jurisdictions and the many different constituencies that may be involved in recovering the species.

The recovery strategy does not necessarily represent the views of all of the individuals who provided advice or contributed to its preparation, or the official positions of the organizations with which the individuals are associated.

The goals, objectives and recovery approaches identified in the strategy are based on the best available knowledge and are subject to revision as new information becomes available. Implementation of this strategy is subject to appropriations, priorities and budgetary constraints of the participating jurisdictions and organizations.

Success in the recovery of this species depends on the commitment and cooperation of many different constituencies that will be involved in implementing the directions set out in this strategy.

Responsible jurisdictions

Ontario Ministry of Natural Resources
Environment Canada, Canadian Wildlife Service – Ontario Region

Executive summary

American Chestnut (Castanea dentata) was a dominant forest tree species in northeastern North America before populations were devastated by the introduction in 1904 of the fungal pathogen, Cryphonectria parasitica, which causes chestnut blight. By the 1950s, American Chestnut had been devastated throughout its native range. In southwestern Ontario, populations of American Chestnut were reduced to far less than one percent of the original 1.5 to 2.0 million trees estimated to have been present. Recent surveys in 2001 to 2003 confirmed that Ontario has at least 601 mature and immature individuals of American Chestnut, but this estimate likely represents 30 to 70 percent of the total number in Canada. The native range in Ontario accounts for 3.9 percent of the native range of American Chestnut in North America. In 1987, American Chestnut was designated as a threatened species by the Committee on the Status of Endangered Wildlife in Canada (COSEWIC) and in 2004 was re-designated as endangered. American Chestnut is listed as endangered on the Species at Risk in Ontario (SARO) List and receives protection under the Endangered Species Act, 2007 (ESA).

American Chestnut’s native range extends from southern New England to the southern Appalachian mountains. It still survives as remnant populations and individuals throughout this range, mainly by resprouting from collars of surviving root systems. During a survey conducted from 1994 to 1997, American Chestnut was identified at 135 sites in southwestern Ontario. Approximately 58 percent of the sites contained only one tree or regenerating clump. Between 2001 and 2003, 601 individuals were located at 94 sites (average of 6.5 per site); nearly 50 percent of these were less than 10 m tall and greater than 10 cm in diameter at breast height. At least 60 of the 601 individuals showed evidence of flowering or producing burs, however, these trees produced no detectable seed. Approximately one half of the sites containing surviving chestnut were located in Elgin, Haldimand and Norfolk counties.

The goal of this recovery strategy is to restore American Chestnut populations in Ontario to a self-sustaining state, whereby natural recruitment results in the maintenance or an increase of current population size throughout the species’ native range. The objectives of this recovery strategy are to:

  1. survey suitable habitat and/or formerly occupied habitat for American Chestnut, and protect and monitor known populations within the species’ native range in Ontario
  2. promote protection and public awareness of American Chestnut
  3. develop and evaluate management measures to control threats; and
  4. secure Ontario sources of germplasm originating from blight-free trees

Initiation and/or completion of these objectives will contribute to increased knowledge and conservation of remnant populations of American Chestnut in Canada and assess strategies for improved management of chestnut blight.

Chestnut blight continues to have the greatest negative impact on populations of American Chestnut. Other factors such as loss and degradation of habitat, possible hybridization with other Castanea species, and the possible introduction of oriental gall wasp (Dryocosmus kuriphilus Yasumatsu) from the United States are also of concern.

Until the impact of chestnut blight can be reduced, restoring American Chestnut to a more secure position in the Carolinian forest is unlikely. Therefore, approaches to control chestnut blight are critical. Potential approaches include hypovirulence (a viral infection that weakens the blight fungus), natural resistance to disease and breeding for disease resistance. Although hypovirulence has been successful in controlling blight in Europe, there has been less success using this approach in North America. Further research may identify factors that contribute to increased efficacy. Qualitative or complete resistance to blight has not been observed in surviving populations of American Chestnut, but concerted attempts have been and continue to be made to identify and select quantitative or incomplete resistance. Finally, breeding programs using resistance genes from Asian chestnut species are underway in the United States and more recently in Canada. Here emphasis has been placed on incorporating this resistance into germplasm adapted to environmental conditions within the native range of American Chestnut in southwestern Ontario.

It is recommended that the Ecological Land Classification (ELC) ecosite types where one or more American Chestnut trees currently occur or where one or more individuals were previously documented in written reports or surveys (for example, Ambrose and Aboud 1987, Melzer et al. 2004, Tindall et al. 2004, Natural Heritage Resource Centre database, etc.) be prescribed as habitat within a habitat regulation under the ESA. It is recommended that trees planted for horticulture, landscaping or research be exempt from the habitat regulation but should be individually assessed for genetic conservation value.

1 Background information

1.1 Species Assessment and Classification

Common name (population): American Chestnut

Scientific name: Castanea dentata

SARO List Classification: Endangered

SARO List History: Endangered (2008), Endangered – Not Regulated (2005), Threatened (2004)

COSEWIC Assessment History: Endangered (2004), Threatened (1987)

SARA Schedule 1: Endangered (August 15, 2006)

Conservation status rankings:

GRANK: G4
NRANK: N3
SRANK: S2

The glossary provides definitions for technical terms, including the abbreviations above.

1.2 Species Description and Biology

Species Description

American Chestnut (Castanea dentata) is a member of the Fagaceae or Beech family. There are up to 14 described species of trees and shrubs in the genus Castanea. These species include Chinese Chestnut (C. mollissima), European Chestnut (C. sativa), Japanese Chestnut (C. crenata), Henry Chinquapin (C. henryi), Ozark Chinquapin (C. ozarkensis), Seguin Chestnut (C. seguinii) and Allegheny Chestnut (C. pumila). Only American Chestnut is native to Canada (Farrar 1995). However, Chinese Chestnut and hybrids and to a lesser extent, European Chestnut and Japanese Chestnut have been planted within the range of American Chestnut. Over the past two centuries, American Chestnut was initially considered as a range extension of European Chestnut, then as a variety of European Chestnut, and finally as a distinct North American species (Sudworth 1892).

American Chestnut is a large, deciduous canopy tree, that can grow up to 30 m tall and have a trunk up to 1.5 m in diameter, with smooth dark brown/olive bark that separates into broad flat-topped ridges with age. Leaves are yellowish-green, alternate and simple, 15 to 28 cm long and taper to both ends. Leaves have 15 to 20 veins running parallel on each side and each vein ends in a prominent tooth. American Chestnut is monoecious and self-incompatible with male flowers occurring in catkins and female flowers occurring singly or in small clusters at the base of some catkins. Trees flower in late May to early July and are insect-pollinated (Ambrose and Kevan 1990). One to three nuts are enclosed in a spiny husk, five to eight centimetres across and are edible. Nuts usually mature by first autumn frost and are primarily dispersed by small mammals and birds that cache or bury them. American Chestnut has a faster rate of growth than other associated hardwood species and under good site conditions, mature trees can increase in diameter by up to 2.5 cm per year (Kuhlman 1978).

Species Biology

American Chestnut can begin to produce seed as early as eight years of age. The life-cycle of forest canopy trees such as American Chestnut has two critical phases: (1) establishing seedlings in the understory; and (2) attaining a favourable position in the canopy after a disturbance (Paillet, 1994). As it is shade tolerant, American Chestnut typically persists in the understory of relatively open oak-dominated forests but responds rapidly to openings that develop in the canopy. When a chestnut tree is cut or the above ground part dies from blight, the root collar typically survives and gives rise to new sprouts. However, the repeated harvesting or re-infection of stems can weaken and eventually kill the entire tree (Paillet 1994).

Ecology

Although American Chestnut still persists in some areas, it no longer persists in sufficient numbers to fulfill its former ecological role. Many organisms were directly or indirectly influenced by this tree. Most of the species that relied on American Chestnut for food were considered to be generalists including: deer, rodents, insects and bird species. It is thought that these species now browse other nuts such as acorns, walnuts, beech nuts and hickory nuts.

Information on the diversity of phytophagous (plant-eating) insects on Castanea species in North America is not available, particularly before the introduction of chestnut blight. However, chestnut stems and blight cankers were found to harbour a large, diverse insect fauna of at least 495 insect species (Russin et al. 1984), the majority of which were from the Coleoptera and Diptera families. The pandemic of chestnut blight on American Chestnut is thought to have resulted in the decline or extinction of several phytophagous insects (Opler 1979, cited in Harvell et al. 2002). The Lesser Chestnut Weevil (Curculio sayi Gyllenhal) and Larger Chestnut Weevil (Curculio caryatrypes Boheman) are both native to North America but since the decline of American Chestnut, have become less common (Bessin 2003). The Clearwing Chestnut Moth (Synanthedon castanae Busck) was previously thought to have become extinct in the northeastern United States but was rediscovered in Connecticut in 1989 (Anagnostakis et al. 1994). Recent introductions have also occurred. For example, the Chestnut Gall Wasp (Dryocosmus kuriphilus Yasumatsu) was first reported in the United States in 1974 and is known to feed on Castanea species (Rieske 2007).

American Chestnut also has indirect ecological effects on associated species. Smock and MacGregor (1988) discovered that chestnut leaves altered the consumption rates, growth, and fecundity of shredding macro-invertebrates in headwater streams in the United States. The authors concluded that headwater streams in areas affected by chestnut blight may have experienced subtle changes at the population, community and ecosystem levels due to the demise of chestnut. Other organisms, including a diversity of fungi, bacteria and viruses, were possibly impacted by the decline of American Chestnut but there is little documentation of these possible changes.

Cultural and Economic Significance

American Chestnut had an important historical role in many rural economies. The nuts were used to fatten livestock and were stored as a winter food source. The nuts were also an important cash crop for many rural families and nuts were sent to major cities over the Christmas season to be roasted and sold by street vendors. One railroad station in West Virginia was reported to have shipped 70,300 kg of chestnuts in 1911 (Giddings 1912 as reported by Kuhlman 1978).

American Chestnut was also an excellent timber tree. Forest-grown trees grew straight and were often free of branches for 50 feet (15 m). The wood was straight-grained, easy to work and rot-resistant. The wood was used for telegraph poles, railroad ties, shingles, panelling, fencing, ship masts, coffins, fine furniture, musical instruments, pulp and plywood. Production of chestnut lumber reached a maximum in 1909 at 663.9 million board feet (Saucier 1973). The United States Forest Service’s estimated value of chestnut timber cut in 1909 was $20 million (Detwiler 1912 as reported by Kuhlman 1978). In 1924, the volume of standing chestnut saw timber was estimated at 19.3 billion board feet in the United States.

Non-timber products derived from this species included tannins extracted from the bark and wood used for tanning leather. In the United States, chestnut was the primary source of tannin for the leather industry. In 1923, over 55 tons (50 tonnes) of tannins were extracted from chestnut wood and bark (Saucier 1973).

Indigenous peoples’ use of chestnut ranged from various extractions from leaves, bark, wood and nuts to restore health, to the use of the nuts for food, including soups, puddings and bread (Moerman 2003).

American Chestnut, because of its size and canopy form, was popular in urban plantings as a shade tree. American Chestnut was, and still is, grown in plantations for commercial nut production. There is a small but growing nut industry in Ontario, comprising primarily Chinese and hybrid chestnuts.

1.3 Distribution, Abundance and Population Trends

Global Distribution and Status

Based on fossil evidence, chestnut species are estimated to have been endemic to North America for at least 17 to 20 million years. Records of chestnut pollen verify that it grew on Long Island 30,000 to 50,000 years ago. Chestnut pollen was also found in 2,000-year-old soil layers in Massachusetts (Anagnostakis and Hillman 1992).

American Chestnut, a dominant climax hardwood, comprised approximately 25 percent of the eastern deciduous forest in the United States before the introduction of chestnut blight. Its native range extended from southern New England to the southern Appalachian mountains and covered more than 80 million hectares of forest (Kuhlman 1978) (Figure 1).

Figure 1
Figure 1.  Natural range of American Chestnut (Little 1977)
Note: This range is the current and pre-blight range.  The natural range of American Chestnut has not significantly changed since the arrival of chestnut blight; however, the number of trees within the natural range has declined.
Long description

Figure 1 shows the natural range of the American Chestnut in Canada and United States. The species range extended from southern New England to the Southern Appalachian Mountains in 1977. The range showed is the current and pre-blight range. The natural range of the species has not significantly changed but the number of trees within the natural range has declined since the arrival of the chestnut blight

The distribution of American Chestnut has been affected by four important events during the past several thousand years. These events include: (1) a post-glacial migration from south to north; (2) clearing of forests for farming; (3) commercial logging; and (4) introduction of chestnut blight to North America (Hill 1994). Following the most recent glacial retreat, this species migrated north. American Chestnut was considered a slowly dispersing species because evidence of it did not appear in New England until 2,000 years ago. Whereas Eastern White Pine (Pinus strobus), American Beech (Fagus grandifolia), crab apples and elms reached New England 9,000, 7,000 and 4,000 years ago, respectively. However, others believe that chestnut was present in New England in low numbers up to 4,500 years ago (Paillet 1994).

Clearing and logging reduced much of the eastern deciduous forest to only scattered remnants of virgin forest by the time Cryphonectria parasitica, the cause of chestnut blight, was introduced to North America in the early 1900s.

American Chestnut is considered ‘apparently secure’ with a global conservation status rank of G4. While young shoots of this species are widespread and abundant in the United States, it now seldom reaches reproductive maturity due to the presence of chestnut blight. Presumably there are millions of American Chestnut trees surviving as stumps that produce shoots, but large mature trees are extremely rare and are often isolated or cultivated far from the species' natural range (Table 3). The conservation status of American Chestnut in Canada and Ontario is ranked N3 (vulnerable) and S2 (imperilled), respectively (NatureServe, 2009).

Table 3. Conservation Status Rankings for American Chestnut (NatureServe, 2009)
Level Conservation Status
Global G4
Canada N3
Ontario S2
USA N4
Alabama SNR
Connecticut SNR
Delaware SH
District of Columbia S1S2
Florida SX
Georgia S3
Illinois SX
Indiana S3
Iowa SNA
Kentucky S1?
Maine S4
Maryland S2S3
Massachusetts SNR
Michigan S1S2
Mississippi S1
Missouri SNR
New Hampshire SNR
New Jersey S4
New York S5
North Carolina S4
Ohio S3
Pennsylvania S5
Rhode Island SNR
South Carolina SNR
Tennessee S2S3
Vermont SNR
Virginia S4
West Virginia S4
Wisconsin SNR
Canadian Distribution

American Chestnut naturally occurs below the 43rd parallel in Canada (Fox 1949). This region is generally referred to as the Carolinian zone of southern Ontario and represents the northwestern limits of the native range for American Chestnut in North America.

There appear to be no significant changes in the extent of the natural distribution of American Chestnut in southern Ontario from before the introduction of chestnut blight (Moss and Hosking 1983). American Chestnut occurs in 13 counties along Lake Erie from Windsor to Niagara Falls and north to London. During a survey conducted from 1994 to 1997, American Chestnut was identified at 135 sites in southwestern Ontario. Approximately 58 percent of the sites contained only one tree or regenerating clump. Over one-half of the sites reported in a 2001 to 2003 survey (Tindall et al. 2004) occurred in Elgin, Haldimand and Norfolk Counties. American Chestnut was also reported in Brant, Essex, Halton, Hamilton-Wentworth, Chatham-Kent, Lambton, Middlesex, Niagara, Waterloo and Wellington counties (Ambrose 2004, Tindall et al. 2004). Locations of known occurrence sites are shown on the following map of southern Ontario (Figure 2).

Figure 2
Figure 2.  Known occurrence sites of American Chestnut in Ontario (Modified from Tindall et al. 2004)
Long description

Figure 2 shows the known occurrence sites of the American Chestnut in southern Ontario. The green circles represent the locations of known occurrence sites in the counties of Essex, Chatham-Kent, Lambton, Middlesex, Elgin, Norfolk, Brant, Waterloo, Wellington, Halton, Hamilton, Haldimand and Niagara

Population sizes and trends

It is estimated that there were 1.5 to 2.0 million American Chestnut trees in southern Ontario prior to the introduction of chestnut blight in the 1920s (McKeen 1995, 1997). The distribution of these populations was estimated to comprise 3.9 percent of the total area of distribution of American Chestnut in North America. The blight entered North America from Asia at New York City around 1904 (Gravatt and Gill 1930). By the mid-1940s, the Ontario populations of American Chestnut were devastated and declined dramatically. In 1947, sprouts that had regenerated from trees killed by blight were “common everywhere” but no living mature trees bearing nuts were found (Fox 1949).

There is little quantitative information on the decline of established populations of American Chestnut since the initial pandemics of chestnut blight. Surveys conducted in recent years are not comparable because of differences in methodologies, but a standardized survey protocol developed in consultation with the American Chestnut Recovery Team, was described by Tindall et al. (2004) and will enable such comparisons in the future. The most recent survey of American Chestnut populations in Ontario located 601 mature and immature individuals (Tindall et al. 2004). In this survey, blight symptoms occurred on 25 percent of all trees and in 48 of the 94 locations inspected. The number of cankers on infected trees averaged 5.7 (ranged from one to 40) and this was often associated with the presence of epicormic shoots. Individuals without blight had significantly smaller mean diameter at breast height (DBH; 12.0 cm) than trees with blight (16.9 cm) (Tindall et al. 2004). Mean height for trees without and with blight was 8.3 m and 9.0 m, respectively. Because Tindall et al. (2004) concentrated heavily on forested public lands and frequently did not sample all trees within any given location, this is likely only 30 to 70 percent of the estimated total population.

Ambrose and Aboud (1986) reported seedlings in 7 of 62 sites, whereas Tindall et al. (2004) found none within a 20 m radius of trees in 93 locations. Low recruitment is due, in part, to the fact that few regenerating sprouts survive until reproductive age. The survey by Tindall et al. (2004) found that nearly 50 percent of all trees examined had a DBH greater than 10 cm and 80 percent were less than 20 cm. Only 14 percent were reproductive (i.e., produced catkins or burrs) and no trees were observed with viable seeds (i.e., filled nuts). Low reproductive success in otherwise healthy trees may be related to the fact that these trees are often geographically isolated and therefore, rarely cross-pollinate.

In 1985, McKeen reported that 60 trees, ranging in DBH from 8 to 63 cm, were present within the original range. Other surveys by Ambrose and Aboud (1986) and Boland et al. (1997) reported 151 trees over 10 cm DBH, plus numerous uncounted smaller stump sprouts and 297 individuals, respectively. These surveys differed in objectives, search intensity and procedures and, hence, the values estimated from the three studies are not comparable and likely do not reflect a population trend. Derivation of a population estimate for the total number of chestnut stems in North America was precluded by missing data from the United States (McWilliams et al. 2005).

1.4 Habitat needs

American Chestnut occurs in a variety of habitats but is most abundant on well-drained, acidic, sand and gravel soils. In Ontario, American Chestnut most often occurs in regions where the frost-free period ranges from 140 to 180 days, extreme temperatures range from lows of -27 to -29 degrees Celsius and highs of 40 to 41 degrees Celsius, precipitation ranges from 760 to 970 mm of rain plus 89 to 178 cm of snow, with soil pH ranges from four to six (Ambrose and Aboud 1986, Tindall et al. 2004), soil sand content ranges from 50 to 90 percent and elevation ranges from 90 to 290 m (Boland et al. 1997). Most individuals occur in forest or woodland ecosites in which the canopy cover exceeds 70 percent (Tindall et al. 2004). Habitats are most often dominated by oak [predominantly White Oak (Quercus alba) and Red Oak (Q. rubra)] or maple [predominantly Red Maple (Acer rubrum) and Sugar Maple (A. saccharum)], with regular occurrences of species such as: Eastern White Pine, Shagbark Hickory (Carya ovata), Black Cherry (Prunus serotina), Sassafras (Sassafras albidum), White Ash (Fraxinus americana) and American Beech (Ambrose and Aboud 1986, Tindall et al. 2004). Under the Ecological Land Classification (ELC) system (Lee et al. 1998), American Chestnut was found predominantly in three community series: (1) mixed forest; (2) deciduous forest; and (3) treed cliffs (Tindall et al. 2004). The majority (97%) were located in forest or woodland habitats and 79 percent occurred in oak and (or) maple forest ecosites.

1.5 Limiting factors

American Chestnut is a shade tolerant species that has a self-incompatible breeding system (prevents self fertilization) and therefore requires reproductively compatible trees within pollen dispersal range to produce viable seed (Ambrose and Kevan 1990). Due to chestnut blight, single chestnut trees are geographically isolated and thus availability of compatible trees for reproduction is likely a limiting factor.

Chestnut trees produce fruit with high nutritional value that provide an important food source for birds [e.g., Wild Turkey (Meleagris gallopavo) and jays] and for mammals (e.g., squirrels, deer and bears) (Hill 1994). Today, however, due to its low numbers, chestnut is relatively unimportant to wildlife. These wildlife species, however, can be viewed as seed predators which may limit seed dispersal when there are already extremely low numbers. American Chestnuts are long-lived organisms, which limits the rate of recovery to viable, reproductively mature populations. Conversely, the woody perennial life history also allows individual plants to persist as sprouts from surviving root systems well after the initial infection.

Although habitat availability is not a limiting factor for American Chestnut, dispersal to areas that do provide suitable habitat is limited. A large portion of the remaining Carolinian woodlands provide suitable habitat that could be enhanced through management to provide light and good microsites for the establishment and growth of new American Chestnut trees. There are also ongoing programs of habitat restoration that will benefit American Chestnut and other Carolinian species.

1.6 Threats to survival and recovery

The following threats to survival and recovery of American Chestnut are listed in order of importance:

Chestnut blight

Chestnut blight is the single greatest threat to American Chestnut in Canada. The blight was first noticed at the Bronx Zoo in 1904 on nursery stock, but it likely had multiple introductions at that time. The introduction of chestnut blight, caused by the fungus C. parasitica (Murrill) M.E. Barr, devastated the American Chestnut species throughout North America including Ontario. American Chestnut has persisted in southern Ontario by resprouting from the collars of surviving root systems but regenerated sprouts continue to become re-infected by the fungal pathogen. Some trees in southern Ontario are not currently showing blight symptoms. McKeen (1985) reported that 50 percent of trees had no obvious blight and Melzer and Boland (2004) found 41 percent of trees to be free of disease symptoms. In the most recent survey (Tindall et al. 2004), 325 of 459 trees assessed for blight (71%) had no obvious blight symptoms.

Chestnut blight will continue to threaten the remaining small and isolated populations of American Chestnut because it survives on sprouts and on alternative hosts. Cryphonectria parasitica has been observed to kill some alternative hosts but it usually exists on these hosts as a weak pathogen or saprophyte. Alternative hosts of C. parasitica in the Carolinian zone of southern Ontario include: White Oak, Red Oak, Black Oak (Q. velutina), Red Maple, Staghorn Sumac (Rhus typhina), Shagbark Hickory, Bur Oak (Q. macrocarpa), Chinquapin Oak (Q. muhlenbergii), Hop Hornbeam (Ostrya virginiana), Blue Beech (Carpinus caroliniana), Tulip Tree (Liriodendron tulipifera) and Sassafras (Sassafras albidum) (Mooij 1997). Locations for new plantings of American Chestnut for restoration or nut crops should be chosen carefully as they may act as a bridge to connect diseased populations of American Chestnut to isolated populations that have escaped disease.

Loss of individuals

Loss of individuals due to clearing of forests for farming and development continues to be a threat to American Chestnut in Ontario. Several sprout clumps of chestnut occur along roadsides and are repeatedly cut back or sprayed with herbicide so they will not interfere with overhead wires. Several young trees/sprouts have been damaged or killed due to logging and others have been lost due to clearing of forests and fencerows for agriculture and urban development. While many rural land owners practice good forest management and stewardship, exceptions of poorly managed forests including unsustainable logging and even complete clearing to expand other economic activities, are having a negative impact.

Hybridization

Interbreeding between American Chestnut and three introduced chestnut species (Chinese Chestnut, Japanese Chestnut and European Chestnut) may threaten the persistence of American Chestnut in Ontario. This concern stems from the theoretical view that rare species that hybridize with a more abundant relative will by virtue of their small numbers, be assimilated into the more common genome and ultimately cease to exist as a genetically distinct taxon. Although this process has rarely been documented in other plants (Burgess and Husband 2006, Burgess et al. 2008), the potential for hybridization to affect American Chestnut may be significant. From controlled pollinations, it is clear that all four species of chestnut are inter-fertile and can produce viable hybrid offspring. In addition, Chinese Chestnut and to a lesser extent, European Chestnut and Japanese Chestnut are widely distributed and planted in southern Ontario as ornamentals and (or) for nut production. It is likely that these out-plantings are located within pollen-dispersal distance of American Chestnut populations in many locations throughout the native range.

Despite the apparent opportunities for hybridization, the actual measurable risks to American Chestnut may be quite low at this time. Cultivated trees of other Castanea species tend to be clustered together and restricted mostly to the margins (around homes or in nurseries) rather than the interior of American Chestnut habitat. The impact of hybridization would therefore be reduced because members of the same genus do not interact directly and American Chestnut remains in the majority within its own populations. The low occurrence of hybridization was confirmed by a recent genetic analysis of trees in southern Ontario (Gerrath 2006). Gerrath used Randomly Amplified Polymorphic DNA (RAPD) markers to genetically characterize known samples of each species. Then, by comparing these genotypes to those of wild species from the American Chestnut range, trees were screened for hybrid parentage. Sixty trees, many of which were selected as most likely to be hybrids, were sampled from the native range. Only one tree (2% of all trees sampled) was identified as a hybrid, with Japanese Chestnut as the most likely parent. Although many trees have not been assessed, these results indicate that hybridization may not be prevalent in natural populations at the current time and should be considered a low risk to Canadian populations of American Chestnut.

Despite the threat that non-indigenous Castanea species may pose in natural systems, it is the resistance traits that these species have evolved that may provide one of the best solutions for the recovery of American Chestnut in North America. Specifically, backcross breeding programs have been developed to incorporate the resistance component of closely related species of Castanea into the genome of American Chestnut. The details of this method are provided in section 2.3 of this recovery strategy.

Insect pests

Of the insect pests that are known to feed on American Chestnut, little is known about their biology and impacts. They are, therefore, covered in the Knowledge Gaps section (Section 1.7).

1.7 Knowledge gaps

There is sufficient literature on the biology and ecology of American Chestnut to initiate recovery. However, periodic assessment of the status of the species and additional information on the control of chestnut blight are necessary.

The effect of chestnut blight on American Chestnut is ongoing. It has increased the vulnerability of the remaining populations to potential secondary threats such as declines caused by unpredictable population dynamics or environmental disturbances and accumulation of deleterious mutations. Further study and analysis is required to determine which if any, secondary threats are affecting the species and the level and extent of threat they pose.

Hypovirulence associated with fungal viruses as a naturally-occurring biological control strategy has controlled chestnut blight well in some locations in Europe but has failed almost completely in eastern North America (Milgroom and Cortesi 2004). However, some localized results have appeared promising, particularly in Michigan and with the use of hypovirulent isolates from Europe. Research efforts are still underway in the USA to evaluate hypovirulence on a longer-term ecological scale and to identify crucial factors regulating the establishment of hypovirulence in chestnut forests.

The need to restore American Chestnut to sustainable population sizes requires the development of methods of increasing blight resistance by screening individuals in natural populations. Conservation and restoration efforts by the Canadian Chestnut Council and The American Chestnut Foundation involve selective breeding programs to enhance resistance of native American Chestnut at a faster rate than that occurring in natural populations. The various programs of ongoing research differ in specific strategy, but share the common feature of starting with an initial cross (F1) between American Chestnut and resistant individuals of Chinese Chestnut. Methods for the inoculation of trees, the identification of resistant parents and progeny and the characterization of resistance genes controlling genetic resistance are needed. This research will hopefully fill the gaps in knowledge associated with blight susceptibility and resistance in American Chestnut populations. 

Although hybridization does not currently appear to be a serious threat, its role may change particularly if populations of American Chestnut continue to decline and plantings of introduced chestnut species increase. As a result it will be important to expand the screening for hybrids to other individuals in natural populations (specifically plants with uncharacteristic leaf morphology, growth architecture and reduced blight) and to monitor plant material used in out-plantings.

Another potential threat to the American Chestnut species in Ontario is the Oriental Chestnut Gall Wasp. This wasp was introduced to North America through Georgia during 1974. It is currently found in Alabama, Georgia, Kentucky, Maryland, North Carolina, Ohio, Pennsylvania, Virginia, and Tennessee (Anon. 2009). Galls caused by these wasps suppress shoot elongation, reduce fruiting, and trees with severe infestations often die. It is not known if the Oriental Chestnut Gall Wasp can survive the colder temperatures in the northern portions of the American Chestnut’s native range.

The Chestnut Weevil (Curculio elephas) native to southern and central Europe, may also pose a threat to American Chestnut. Adult female weevils deposit eggs into developing nuts. After hatching, the larvae feed in the nut for several weeks. Infested nuts drop prematurely and larvae chew their way out of the nut after it has fallen. Although there are many introductions of this weevil into North America each year, it has not been observed in the wild (Venette et al. 2003). In commercial nut production, good sanitation, cultural practices and insecticides can effectively control weevils therefore the potential threat is expected to be low.

1.8 Recovery actions completed or underway

Recent surveys of distribution in Ontario were documented by Ambrose and Aboud (1986), Boland et al. (1997) and Tindall et al. (2004). Details of chestnut reproductive biology were elucidated by Ambrose and Kevan (1990). Following the 1986 COSEWIC status report, several studies were conducted in Ontario on select chestnut blight strains that exhibited reduced virulence (Dunn and Boland 1993, McKeen 1995, Boland et al. 1997, Melzer et al. 1997 and Melzer and Boland 1999). These surveys and studies provided a framework from which to develop the recovery objectives outlined in the next section.

Several strategies may show promise for the management of chestnut blight. These strategies include sanitation measures (e.g. removal of dead twigs and stems that act as infection sites, and the removal of infested plant material that acts as sites for sporulation of the pathogen), fungicides, biological control and disease resistance. Diagnostic tests for resistance and early infection will be important for continuing research and management of nursery stock and out-plantings. See Appendix for a description of C. parasitica and symptoms of chestnut blight disease as well as steps that can be taken to prevent disease spread by humans.

Assessment of the status of American Chestnut in Ontario

To assess the population status of American Chestnut trees in southern Ontario, an extensive baseline survey of accessible, known or newly found populations was conducted between 2001 and 2003 using a standardized protocol (see Tindall et al. 2004). A total of 601 mature and immature individuals located in 94 sites across southern Ontario were inventoried, permanently labelled with metal tags, and georeferenced using GPS. The following data were generated from the inventory:

  • diameter, height, and reproductive state of each tree
  • health condition of each tree (number and kinds of cankers and degree of tree dieback)
  • habitat description, ecosystem type, other species present, canopy cover, slope and soil type, pH and texture of each site as per the ELC system protocol
  • using sanitary techniques, a very small amount of plant material in the form of leaf, bud and twig samples was collected to serve as herbarium specimens [and possibly for future gene bank (DNA) storage purposes]; and
  • taxonomic status and possibility of hybridization, based on morphological, molecular and/or physiological characters

This survey will be repeated at five to ten year intervals and the results used to assess and monitor the status of known and newly discovered populations within the species’ native range in Ontario.

Activities of agencies currently engaged in recovery efforts

The Canadian Chestnut Council founded in 1988, has played an important leadership role in public awareness and in encouraging research on American Chestnut and chestnut blight. Members of the Canadian Chestnut Council have mapped many of the remaining sites of chestnut in southern Ontario and continue to monitor many of these sites. Volunteer members have pollinated and collected nuts from isolated, mature trees and have initiated plantings of chestnut seedlings. In addition the Canadian Chestnut Council initiated a disease resistance breeding program.  It incorporates germplasm of American Chestnut from southern Ontario with known intra- and interspecific sources of disease resistance following a similar program of interspecific hybridization being used by The American Chestnut Foundation.

The American Chestnut Foundation was founded in 1983. The mission of the American Chestnut Foundation is to restore American Chestnut as an integral part of the eastern forest ecosystem. It maintains an extensive breeding program for developing resistance to chestnut blight. The goal of this program is to introduce resistance from Chinese Chestnut into American Chestnut while preserving as completely as possible the genome of the American Chestnut. Resistance in Chinese Chestnut appears to be controlled by two or three incompletely dominant genes. Therefore, the goal of this breeding program is to develop chestnuts that are homozygous for both resistance genes. Resistant Chinese Chestnuts are backcrossed to American Chestnuts at least four times resulting in crosses with a genome that is at least 15/16ths (94%) of American Chestnut origin. Progeny are tested for resistance by inoculation with virulent isolates of C. parasitica after each backcross. Final selections are intercrossed to produce the first nuts for restoration outplanting. Because the American Chestnut Foundation expects that natural selection has created populations adapted to regional conditions, it has used germplasm of American Chestnut from across the range of American Chestnut. The American Chestnut Foundation maintains breeding programs in Connecticut and Pennsylvania as well as on their main breeding farm in Virginia. The American Chestnut Foundation hopes to have its first resistant line(s) ready for planting in 2010 to 2015.

The Ontario Soil and Crop Improvement Association (OSCIA) initiated a two year project in 1998 to promote interest in the farming community in chestnut recovery and to identify farmers with suitable sites who are willing to set aside up to one acre of land to be planted with American Chestnut seedlings. In 1998 to 1999, the OSCIA coordinated the establishment of 24 demonstration sites with a total of approximately 1,300 American Chestnuts planted in southern Ontario. Ten of the 24 sites are located outside the native range of American Chestnut.

Ongoing research into the potential of using hypovirulence as a biological control strategy is being conducted by Dr. C. McKeen, the Canadian Chestnut Council and Dr. G.J. Boland, University of Guelph. Naturally-occurring healing-type cankers have been observed in southern Ontario and putatively hypovirulent isolates have been recovered from these cankers and their hypovirulence has been confirmed in laboratory tests. Hypovirulent isolates of C. parasitica from Ontario were released at several locations, including an experimental site at Skunk’s Misery in Middlesex and Lambton counties. Hypovirulent isolates compatible with virulent isolates at the site were inoculated around the perimeter of cankers. Expansion of treated cankers was measured in comparison with untreated cankers 15 months after inoculation. For the first one to two years after treatment, statistical differences were detected between treated and untreated cankers and after 15 months, hypovirulent isolates were recovered from 82 percent of the treated cankers. However, visual observations three to five years after inoculation were not as encouraging and many of the treated trees had died from blight. Observations will be continued at this site to see if there are any long-term effects from these treatments.

2 Recovery

2.1 Recovery goal

To restore American Chestnut populations in Ontario to a self-sustaining state whereby natural recruitment results in the maintenance or increase of current population size throughout the species’ native range.

2.2 Protection and recovery objectives

Table 4. Protection and recovery objectives
No. Protection or Recovery Objective
1 Survey suitable habitat and/or formerly occupied habitat for American Chestnut and protect and monitor known populations within the species’ native range in Ontario.
2 Promote protection and public awareness of American Chestnut.
3 Develop and evaluate management measures to control threats.
4 Secure Ontario sources of germplasm originating from blight-free trees.

2.3 Approaches to recovery

Table 5. Approaches to recovery of the American Chestnut in Ontario
No. Relative Priority Relative Timeframe Recovery Theme Approach to Recovery Threats or Knowledge Gaps Addressed
1. Survey suitable habitat and/or formerly occupied habitat for American Chestnut and protect and monitor known populations within the species’ native range in Ontario Critical Short-term Inventory, Monitoring and Assessment, Research 1.1 Survey and monitor status of known and newly discovered populations within the species’ native range in Ontario:
  • develop survey protocol
  • conduct detailed site habitat surveys and health assessment of all trees labelled during the 2001 to 2003 inventory
  • collect new reports of American Chestnut between surveys
  • monitor tree health every five to 10 years
  • conduct population viability analysis
  • screen for naturally-occurring hybrids
  • Status of species
  • Chestnut blight
  • Loss and degradation of habitat
1. Survey suitable habitat and/or formerly occupied habitat for American Chestnut and protect and monitor known populations within the species’ native range in Ontario Necessary On-going Inventory, Protection 1.2 Monitor and maintain planted populations located within the species’ native range in Ontario as potential sources of blight-free native germplasm:
  • locate and evaluate status of all planted populations
  • identify two sites to maintain as a potential source of blight-free germplasm for future outplanting
  • stock each site with individuals representative of variability found in southern Ontario
  • use information on existing plantations to direct locations of future American Chestnut plantations thereby reducing potential impacts on natural populations
  • Chestnut blight
2. Promote protection and public awareness of American Chestnut Necessary Short-term Communications, Stewardship, Protection 2.1 Promote protection of known populations of American Chestnut to land management authorities, private landowners and recovery teams
  • Loss and degradation of habitat
2. Promote protection and public awareness of American Chestnut Beneficial Long-term Education and Outreach, Stewardship 2.2 Promote public awareness of American Chestnut
  • Loss and degradation of habitat
3. Develop and evaluate management measures to control threats Critical Short-term Research 3.1 Investigate the effectiveness of various chestnut blight control measures in an experimental setting
  • Chestnut blight
3. Develop and evaluate management measures to control threats Critical On-going Management Monitoring 3.2 Identify, manage and monitor at least 15 American Chestnut populations of those inventoried within the species’ native range in Ontario:
  • select 15 populations from those inventoried under approach 1.1 based on their recovery potential
  • test a variety of selected management measures and develop guidelines for controlling chestnut blight
  • monitor managed populations for all threats to species using protocol from 1
  • Chestnut blight
  • Insect pests
  • Hybridization
3. Develop and evaluate management measures to control threats Critical Long-term Research 3.3 Develop techniques to decrease species’ vulnerability to chestnut blight
  • test effects of spreading hypovirulent strains of chestnut blight
  • conduct an intraspecific breeding program for blight resistance in American Chestnut
  • conduct an interspecific breeding program for blight resistance in hybrid chestnut trees
  • Chestnut blight
3. Develop and evaluate management measures to control threats Beneficial Long-term Management 3.4 Restrict inter-jurisdictional movement of all Castanea species in Canada
  • Chestnut blight
4. Secure Ontario sources of germplasm originating from blight-free trees Beneficial Short-term Protection 4.1 Locate and inventory blight-free American Chestnut stands planted in Ontario outside the species’ native range
  • Chestnut blight
4. Secure Ontario sources of germplasm originating from blight-free trees Beneficial Long-term Research 4.2 Monitor and protect at least two blight-free stands planted outside the species’ native range in Ontario
  • Chestnut blight
Supporting narrative

The approaches described in Table 5 primarily address chestnut blight, the most important threat to the species. The recommendations focus primarily on the need to develop and evaluate blight control methods. If the blight is controlled, the small immature stump-sprout saplings which currently account for a large portion of extant populations may grow to maturity, increasing numbers of fruit-bearing individuals to levels where healthy breeding and seed production can occur.

Until blight can be controlled, the greatest promise for recovery of the species lies in developing and deploying a blight-resistant locally-adapted American Chestnut genotype. As outlined in section 1.6, natural hybridization is considered a potential threat to the recovery of American Chestnut. However since chestnut blight is still the primary cause of endangerment for this species, controlled breeding with close relatives that exhibit a higher degree of resistance such as Chinese and Japanese Chestnut, may be needed to accelerate the evolution of resistance. This research is being pursued by the Canadian Chestnut Council breeding program. The intent of this program involves introducing the disease resistance of Chinese Chestnut into Ontario genotypes of American Chestnut through an initial hybrid cross, backcrossing the hybrids with Ontario genotypes over multiple generations to reduce the Chinese Chestnut genetic contribution to the target level of less than six percent and then selecting crosses that perform well in disease resistance screening tests. It is anticipated that blight-resistant trees that meet these genetic criteria and are phenotypically indistinguishable from naturally occurring genotypes could be produced within 15 years. In addition, naturally occurring individuals with lower blight susceptibility are also being assessed (intraspecific resistance). These efforts would be followed by diligent out-planting efforts to get the resistant genotype established in the network of priority populations. However, there is no information on the durability of resistance as trees mature.

Utilizing this method for recovery comes at the cost of introducing genes from interspecific crosses with other Castanea species and thus may cause some ambiguity between hybrids developed specifically for the recovery strategy versus those that occur naturally (Jacobs 2007). As indicated in section 1.6, hybridization that occurs naturally is a potential threat to American Chestnut as the genetic component of offspring that are produced is likely to be 50 percent or less American Chestnut. In contrast, the genetic component of hybrids that are produced using the rigorous methods of backcrossing for the recovery strategy will be close to 94 percent or more American Chestnut (Hebard 2005). Therefore, to avoid any ambiguity, reintroduction programs that involve backcrossed American Chestnut should clearly articulate how they differ from naturally occurring hybrids that are a potential threat.

Over time, it is anticipated that selection will favour genotypes with a combination of resistance and local adaptation. Ultimately, the survival of American Chestnut which is affected so severely by blight, may depend on this infusion of genetic variation.

Other efforts include maintaining existing populations in the wild, utilizing management techniques for controlling the blight, maintaining in-situ and ex-situ germplasm through protection and planting. Finally, species recovery efforts continue to benefit from a volunteer network assisting in pollen transfer, seed collection, seed production, tree planting and maintenance.

Approach 1.1

Existing information on the occurrence of surviving individuals and populations of American Chestnut is either incomplete or scattered among various agencies and individuals. A more detailed, standardized and frequent approach to collecting observations on American Chestnut would contribute to a sample and information database. This could possibly be maintained by the Ontario Ministry of Natural Resources or the Canadian Chestnut Council, and would provide more accurate information on the current status of this species and provide a framework for continued recovery efforts.

It is recommended that a protocol be developed for surveying all American Chestnut populations in Ontario every five to ten years, to:

  • record number and size of individuals and their state of health
  • record habitat observations (associated species and forest canopy density)
  • determine reproductive status of individuals and populations (fruiting and recruitment)
  • examine individuals for presence/severity of blight or other threats to health
  • examine individuals for hypovirulent/healing cankers
  • sample chestnut blight populations for culture collection; and
  • expand screening for naturally-occurring hybrids

These data will permit estimation of survival and recruitment rates of American Chestnut and the percentage of individuals with chestnut blight, thereby providing a measure of population viability. New observations and reports of American Chestnut will be collected between surveys and added to the survey records.

Approach 1.2

Recovery action of American Chestnut must involve careful consideration of collections and plantings of cultivated American Chestnut trees throughout the native Canadian range. Historically, American Chestnut or cultivars have been planted for the purposes of commercial nut production, landscaping and conservation. Unfortunately, these plantings have been established with little thought about their impact on naturally occurring populations of American Chestnut. There has been little coordination or regulation as to how and where planting should occur. As a result, there is a risk that out-plantings are not true American Chestnut or are not from the best suited local seed sources and that they will serve as conduits for the movement of C. parasitica among populations. At the same time, there is a need for planted trees of known composition to serve as a germplasm reserve for future restoration efforts and for research purposes. The following actions are recommended.

  • Identify existing planted populations of chestnut, American or otherwise, planted within the native range of American Chestnut and determine the genetic parentage (species, hybrid) and geographical source where possible
  • Collate and distribute information on existing plantings to the lead recovery agency (Ontario Ministry of Natural Resources) as well as major conservation interests. This document would be used for identifying potential locations for research, for developing a management plan for existing planted populations with the intent of reducing interactions with native populations and for directing and reducing the potential impacts of future planted populations
  • Identify potential locations/sponsors to maintain at least two planted populations of native American Chestnut within the native range. The locations should be located in different parts of the geographic range – such as the southwest and the northeast part of the range – and should be isolated from natural populations by at least 50 kilometres. This distance is recommended as a precautionary approach to avoid blight transference among the natural and planted populations. These planted populations can be used for a variety of purposes including: (1) germplasm reserve for future out-plantings in natural populations and (2) research on genetic variability in native populations, natural blight resistance and blight management. Planted populations used as germplasm reserves should be completely or nearly blight-free
  • Stock the designated planted populations with approximately 40 trees, representing populations from throughout the native range in Canada. These trees should be disease-free and should be characterized genetically to confirm their American Chestnut heritage

Monitor the state of all planted populations (i.e., incidence of blight; tree age/size and health) with regular updates from owners (using survey methods under approach 1.1).

Approach 2.1

Planning agencies within each municipality in which American Chestnut occurs should be made aware of all known sites within their jurisdiction to be included in their natural heritage mapping. Existing habitats need better protection by land management agencies and private land owners.

Land management authorities

Many of the known sites of surviving American Chestnut are on crown and public lands. However, accurate information is often not communicated directly to agencies and individuals involved with land planning and management. Improved communication can contribute directly to improved management of surviving populations of American Chestnut. It is recommended that planning agencies, conservation authorities, forestry consultants and municipal by-law officers be notified of the status of American Chestnut in Ontario and to work cooperatively with them to protect known populations and their habitats within their jurisdictions. Information and status of regional populations should be made available to these agencies once the inventory is complete.

Private landowners

Some of the known healthy American Chestnut populations are on private land. Consideration should be given to the stewardship or securing of such sites to ensure the protection of these trees. It is recommended that private landowners be contacted to encourage stewardship opportunities. Alternate methods for securing sites could be explored for other lands (such as those where land owners do not reside on the land or are not interested in stewardship). Communication with agencies such as the Nature Conservancy of Canada, local land trusts, and regional stewardship networks is recommended to bring about the securing of land through such mechanisms as landowner stewardship, conservation easements or acquisition. It is important to strive for open dialogue with land owners and assume willingness for good land management and stewardship. However, no action should be taken without their concurrence. Researchers and recovery workers should remember to obtain landowner permission before venturing onto any property.

Recovery teams

Maintaining communication with ecosystem-based recovery teams such as Carolinian Woodlands and watershed-based recovery teams in southern Ontario is recommended.

Approach 2.2

Public awareness of the current status and potential recovery of American Chestnut has been, and will continue to be, an important component of the recovery of this species. It is through such promotion that new sites of chestnut are located, seeds are collected and distributed and much of the enthusiasm and support surrounding this species is generated.

Awareness of the status of American Chestnut by the general public can be increased through communication with farm, forestry, naturalist, and planning organizations. The communication should be periodic highlights of recent findings and improving status of individual sites, landowner stewardship and their actions/activities that have promoted the recovery of this species and opportunities for new participants. It should also include practical information for landowners, such as identifying native chestnuts, chestnut blight cankers and healing cankers.

This outreach can be accomplished using various means including:

  • flyers
  • website
  • newspaper/magazine articles and news releases
  • booths at community events; and
  • community meetings
Approach 3.1

Several methods are professed for the effective short-term control of chestnut blight but little information is available to substantiate these claims. In addition, recent developments in fungicide technology and biological control may present new opportunities for managing this disease and pathogen. A comparative assessment of such practices may identify effective methods and/or products that can be used for future application in recovery efforts as well as by commercial chestnut growers.

It is recommended that the most effective combination of management practices be determined based on existing information and experiment results. Experiments designed to test the following management practices should be conducted in plantings, orchards or natural populations not identified in approach 3.2. Management practices to control chestnut blight might include:

  • fungicide treatment of expanding cankers and assessment of canker development and pathogen sporulation
  • mud pack treatment of expanding cankers and assessment of canker development and pathogen sporulation
  • removal of dead uninfected branches that provide infection sites for the pathogen; and
  • removal of dead branches, suckers and trees that provide pathogen sporulation sites
Approach 3.2

Existing populations of American Chestnut are largely fragmented and isolated. This presents an opportunity to manage individual sites more intensively through cultural practices, artificial pollination of trees and out-planting of seedlings. It is recommended that the 15 populations with the highest potential for recovery be identified from those inventoried under approach 1.1, based on some or all of the following criteria:

  • size of population – larger populations preferred (over half of the known sites consist of only one individual)
  • reproductive status of individuals – reproducing populations preferred
  • ownership – publicly owned land or secured private land is preferred to ensure long-term access and protection
  • blight – sites with, and without blight; and with healed or hypovirulent cankers
  • size of habitat – larger habitats with room for population expansion preferred
  • habitat characteristics – some site characteristics such as soil type have been reported to be conducive to the development of healing cankers
  • geographic location – select populations from across the native range of American Chestnut in southern Ontario; and
  • genetic composition - populations with sufficient spatial separation from known sites of other Casanea spp. or hybrids

Once the 15 populations have been selected, management measures may be initiated in 10 of the 15 populations. The remaining five populations could initially be unmanaged and serve as experimental controls. The management measures could include: (1) removing dead, sporulating chestnut tissue from the site to reduce inoculum; (2) suppressing canker development using selected treatments; (3) encouraging recruitment of new individuals through pollination; (4) transplanting uninfected individuals from other sites; and (5) thinning or other microhabitat management to improve survival and growth of seedlings. Specific strategies would be based on survey results (see approach 1.1), current research literature and results of experimental investigation of the effectiveness of various chestnut blight control measures (see approach 2.1). The results will be summarized as guidelines to managing sites where chestnut blight is present. As much as possible, recruitment should be encouraged from within each site. Additional sites can be added to the management strategy as deemed necessary. 

Finally, the protocol from approach 1.1 should be applied to monitoring of tree health, insect pests and hybridization of these 15 populations every five to 10 years to produce a population health status report.

Approach 3.3

Long-term management strategies to control chestnut blight are critical for the recovery of this species. Currently, there are three techniques with the potential to achieve this goal: (1) spread of hypovirulent strains of chestnut blight; (2) identification of natural resistance in surviving stands of American Chestnut; and (3) breeding for resistance in American Chestnut through hybridization with other Castanea species.

Approaches to the following areas of research are not presented in detail because they are continually evolving and approaches will change as new information is obtained.

Hypovirulence

The purpose of this technique is to promote the development and spread of hypovirulent strains of chestnut blight amongst existing populations of American Chestnut. Following survey results (see approach 1.1), three or more populations with healing cankers and/or hypovirulent isolates of chestnut blight could be selected to conduct research on the effectiveness of this technique in controlling chestnut blight. The goal for these sites would focus on increasing recruitment of American Chestnut to provide susceptible hosts for the continued growth and possible spread of hypovirulent isolates of chestnut blight. Recruitment of American Chestnut could be increased where possible, through cross-pollination among individuals within a site. Alternatively pollen, seed or seedlings can be imported from other sites with similar characteristics. As much as possible, recruitment should be encouraged from within each site and seedlings should be protected from herbivores. No other blight control measures should be used in these populations so that virulent and hypovirulent isolates can continue to interact on living and dead chestnut tissues.

Other locations in southern Ontario should be monitored for the presence of naturally occurring hypovirulent blight strains. Emphasis should be placed on identifying hypovirulent isolates that are associated with healing and healed cankers and are prevalent or spreading within the native range of American Chestnut. Continuing research will identify additional factors associated with the spread and efficacy of hypovirulent strains of C. parasitica.

Intraspecific breeding for disease resistance

Using species and disease severity information collected from native populations of American Chestnut under approach 1.1 and possibly from populations established outside the species’ native range (see approach 3.1), individuals with putative resistance to chestnut blight should be identified for outplanting and/or inclusion in breeding programs.

Where feasible, it is recommended that nurseries of putatively resistant American Chestnut be established and the degree of resistance of these trees to chestnut blight be assessed. Resistant individuals could then be cross-pollinated, to assess the progeny’s degree of blight resistance. Intraspecific breeding may identify individuals of American Chestnut with measurable levels of disease resistance. To date, no significant resistance to chestnut blight has been identified in surviving populations of American Chestnut but differences in susceptibility have been reported.

Interspecific breeding for disease resistance

This technique involves the identification of highly resistant individuals in other Castanea species, such as Chinese Chestnut for use in an on-going backcross breeding program with a representative selection of locally adapted American Chestnut.

It is recommended that efforts be continued to establish nurseries of potentially resistant hybrid Castanea species and assess the degree of resistance to chestnut blight, as well as backcrossing resistant individuals to American Chestnut and assessing resulting progeny for blight resistance. Backcrossing should continue for five or more generations, until the genetic background is at least 94 percent American Chestnut. Such interspecific breeding aims to yield individuals: (1) whose genetic composition is predominantly American Chestnut; (2) have high levels of resistance to chestnut blight; and (3) are adapted to local environmental conditions.

Approach 3.4

To ensure that known sites of American Chestnut outside of the native range of chestnut blight remain free of disease, it is important to prevent the introduction of blight into these regions through the movement of nursery stock of Castanea species. Thus, it is recommended that inter-provincial and international trade of Castanea species be restricted to prevent the introduction and/or spread of chestnut blight from infested/infected seed and/or seedlings of Castanea species.

To that end, a proposal in accordance with the Plant Protection Regulations of the Plant Protection Act should be developed and submitted to the Canadian Food Inspection Agency of Agriculture and Agri-Food Canada regarding the monitoring of nurseries and certification of disease-free stock or restriction of shipments if this cannot be done with certainty. This proposal should also address the introduction of chestnut blight on Castanea species from Ontario to other provinces of Canada or countries where American Chestnut is known to occur.

Approach 4.1:

In a parallel approach to collecting more detailed information and samples from individual sites within the native range of American Chestnut (see approaches 1.1 and 1.2), it is recommended that American Chestnut populations in Canada - but outside of the Ontario native range - also be inventoried. Much of this work would be conducted in collaboration with local organizations and individuals. These populations can serve as ex-situ sources of germplasm for possible transplant into the species native range.

This approach first involves locating populations of American Chestnut occurring outside their native range. Landowners should be contacted before entering sites and offered the opportunity to participate if interested. Collecting information on the origin of plantings is especially important. Once these populations have been located they should be inventoried using the survey protocol outlined in Tindall et al (2004) and summarized in this recovery strategy in section 1.8.

Approach 4.2

Sites of American Chestnut located outside of the native range of southern Ontario represent an important source of germplasm of this species that is located outside of the known distribution of chestnut blight. It is recommended that at least two populations each having a minimum of 40 trees, be selected by 2015. These trees should have origins representative of American Chestnut’s native geographic range in Ontario. Suitable planted populations should be established if they do not currently exist. These plantings should be maintained as an important source of disease-free germplasm for potential future out-plantings. Existing individuals of American Chestnut outside of the native range may also be useful as a source of germplasm if the parentage can be confirmed. Every effort should be taken to keep these planted populations blight-free.

2.4 Performance measures

Table 6. Performance measures for evaluating the achievement of recovery of the American Chestnut in Ontario
Recovery Objectives Performance Measures Target date
1. Survey suitable habitat and/or formerly occupied habitat for American Chestnut and protect and monitor known populations within the species’ native range in Ontario.
  • Standardized survey protocol developed
  • All known sites surveyed to assess tree health and habitat characteristics
  • Inventoried populations remain extant and showing recruitment (compared to previous surveys)
  • Planted populations are identified and surveyed
  • Recruitment and importance for long-term survival estimated
  • Two planted populations of at least 40 individuals representing the native range in Ontario remain blight-free
2015
2. Promote protection and public awareness of American Chestnut
  • Partners in protection have been identified and contacted
  • Outreach materials have been produced and distributed
2015
3. Develop and evaluate management measures to control threats
  • Testing of management measures have been completed, and most successful measures for controlling chestnut blight identified
  • Guidelines for managing sites where chestnut blight is present developed
  • Population health status report produced for 15 selected study populations
  • All threats were monitored
  • Methods to decrease species vulnerability to blight developed (hypovirulence techniques developed and evaluated, intra- and inter-specific breeding programs established)
  • Potential threats from hybridization, secondary threats and insect pests were evaluated
2015
3. Develop and evaluate management measures to control threats
  • Long-term chestnut blight control measures have been developed
2025
4. Secure Ontario sources of germplasm originating from blight-free trees
  • Populations outside the species’ native range have been located and assessed
  • At least two of these planted populations, each with a minimum of 40 trees, have been selected and monitored
2015
4. Secure Ontario sources of germplasm originating from blight-free trees
  • Movement of chestnut species has been restricted (by legislation or other means)
2015

2.5 Area for consideration in developing a habitat regulation

Under the ESA, a recovery strategy must include a recommendation to the Minister of Natural Resources on the area that should be considered in developing a habitat regulation. A habitat regulation is a legal instrument that prescribes an area that will be protected as the habitat of the species. The recommendation provided below by the recovery team will be one of many sources considered by the Minister when developing the habitat regulation for this species.

The area to be prescribed as habitat in a habitat regulation for American Chestnut should include all areas in the counties of Essex, Chatham-Kent, Lambton, Elgin, Middlesex, Norfolk, Brant, Haldimand, Niagara, Hamilton-Wentworth, Waterloo, Wellington and Halton where 1) one or more individuals of the species occur or 2) one or more individuals were previously documented in written reports or surveys (e.g., Ambrose and Aboud 1987, Melzer et al. 2004, Tindall et al. 2004, Natural Heritage Resource Centre database). Research at occupied sites has been conducted by the recovery team to identify which Ecological Land Classification (ELC) ecosites (as defined by Lee et al. 1998) support American Chestnut. With this knowledge, it is recommended that the area prescribed as habitat is restricted to only the contiguous ELC ecosite polygons where there are extant or historic occurrences of American Chestnut. If an individual is close to the polygon edge, a minimum distance of 30 m from the stem of the tree (or sprouting stump) is recommended for inclusion in the area prescribed as habitat in the habitat regulation. This is a precautionary measure to ensure that a minimum distance is met for any ground disturbance that could affect mature trees.

The following ELC ecosite and vegetation classifications were recorded in a status assessment of accessible, known or newly found American Chestnut populations that was undertaken by the University of Guelph between 2001 and 2003 using a standardized protocol (Tindall et al. 2004):

Treed Cliff (CLT)

Deciduous Forest (FOD)

  • Dry-fresh Oak Deciduous Forest Ecosite (FOD1)
  • Dry-fresh Red Oak Deciduous Forest Type (FOD1-1)
  • Dry-fresh White Oak Deciduous Forest type (FOD1-2)
  • Dry-fresh Oak-Maple-Hickory Deciduous Forest Ecosite (FOD2)
  • Dry-fresh-Red Maple Deciduous Forest type (FOD2-1 )
  • Dry-fresh Oak-Red Maple Deciduous Forest Type (FOD2-2)
  • Dry-fresh Poplar Deciduous Forest type (FOD3-1)
  • Dry-fresh Deciduous Forest Ecosite (FOD4)
  • Dry-fresh White Ash Deciduous Forest Type (FOD4-2)
  • Dry-fresh Sugar Maple Deciduous Forest Ecosite (FOD5)
  • Dry-fresh Sugar Maple Deciduous Forest Type (FOD5-1)
  • Dry-fresh Sugar Maple-Beech Deciduous Forest type (FOD5-2)
  • Dry-fresh Sugar Maple-Oak Deciduous Forest Ecosite (FOD5-3)
  • Fresh-moist Sugar Maple Deciduous Forest Ecosite (FOD6)
  • Dry-fresh Sugar Maple-White Ash Deciduous Forest Type (FOD5-8)
  • Dry-fresh Sugar Maple-Red Maple Deciduous Forest Type (FOD5-9)
  • Fresh-moist Lowland Deciduous Forest Ecosite (FOD7)
  • Fresh-moist Sassafras Deciduous Forest Type (FOD8-2)
  • Fresh-moist Oak-Maple-Hickory Deciduous Forest Ecosite (FOD9)

Mixed Forest (FOM)

  • Dry-Oak-Pine Mixed Forest Ecosite (FOM1)
  • Dry-fresh White Pine-Maple-Oak Mixed Forest Ecosite (FOM2)
  • Dry-fresh Hardwood-Hemlock Mixed Forest type (FOM3-1)

Coniferous Forest (FOC)

  • Dry-fresh Pine Coniferous Forest Ecosite (FOC1)

Prescribing habitat based on the vegetation community will help to preserve the ecological function of the area and the ecological conditions required for the persistence of American Chestnut.

Since the greatest threat to the species is the chestnut blight, isolated planted individuals may be important for maintaining and recovering the species. It is recommended that emphasis be placed on all American Chestnut individuals in natural populations. Trees planted for horticulture, landscaping or research should be exempt from the habitat regulation but can be individually assessed for possible genetic conservation value.

If future scientific studies indicate that additional areas of habitat are necessary to achieve the recovery goals for this species, the habitat regulation should be updated accordingly.

Glossary

Anastomosis: Fusion of two cells or hyphae in contact that reabsorb their walls and fuse into one.

Committee on the Status of Endangered Wildlife in Canada (COSEWIC): The committee responsible for assessing and classifying species at risk in Canada.

Committee on the Status of Species at Risk in Ontario (COSSARO): The committee established under section 3 of the Endangered Species Act, 2007 that is responsible for assessing and classifying species at risk in Ontario.

Conidium: Asexual, non-motile spores of a fungus; they are also called mitospores due to the way they are generated through the cellular process of mitosis.

Conservation status rank: A rank assigned to a species or ecological community that primarily conveys the degree of rarity of the species or community at the global (G), national (N) or subnational (S) level. These ranks, termed G-rank, N-rank and S-rank, are not legal designations. The conservation status of a species or ecosystem is designated by a number from 1 to 5, preceded by the letter G, N or S reflecting the appropriate geographic scale of the assessment. The numbers mean the following:
1 = critically imperilled
2 = imperilled
3 = vulnerable
4 = apparently secure
5 = secure
H = possibly extinct or extirpated
NA = a conservation status rank is not applicable because the species is not a suitable target for conservation activities
NR = rank not yet assessed
X = presumed extinct or extirpated

Demographic stochasticity: Fluctuations in population growth rates due to random variation in survival and reproduction among individuals.

Endangered Species Act, 2007 (ESA): The provincial legislation that provides protection to species at risk in Ontario.

Environmental stochasticity: Variation in population growth due to fluctuations in environment over time.

Epicormic shoots: Stems that emerge from dormant buds along the trunk of a tree

Ex situ: Not situated in the original, natural or existing place or position.

Extant: In existence; still existing; not destroyed or lost.

GRANK: See “Conservation status rank”

Germplasm: The sum of all genetic material that an individual can transfer to successive generations.

Hypha: A long, branching filamentous cell of a fungus that is the main mode of vegetative growth in fungi.

Hypovirulence: Having less virulent characteristics.

In situ: Situated in the original, natural or existing place or position.

Isolate: A strain or an individual selected from a population of a micro-organism, often maintained in pure culture in laboratory conditions.

Monoecious: Individuals with male and female flowers on the same plant but borne separately.

Mutation accumulation: Rise in frequency of deleterious mutations in small populations due to chance

Mycelium: The entire mass of hyphae that constitutes the vegetative body or thallus of a fungus

NRANK: See “Conservation status rank”

Phytophagous: Feeds on plants

SRANK: See “Conservation status rank”

Self-incompatible: Self-pollinations do not yield seed owing to a physiological rejection.

Species at Risk Act (SARA): The federal legislation that provides protection to species at risk in Canada. This act establishes Schedule 1 as the legal list of wildlife species at risk to which the SARA provisions apply. Schedules 2 and 3 contain lists of species that at the time the act came into force needed to be reassessed. After species on Schedule 2 and 3 are reassessed and found to be at risk, they undergo the SARA listing process to be included in Schedule 1.

Species at Risk in Ontario (SARO) List: The regulation made under section 7 of the Endangered Species Act, 2007 that provides the official status classification of species at risk in Ontario. This list was first published in 2004 as a policy and became a regulation in 2008.

Thallus: The vegetative body of a fungus.

Virulent: The degree or measure of pathogenicity of a microbe; the relative ability of a microbe to cause disease

References

Ambrose, J.D. 2004. Assessment and Update Status Report on American Chestnut (Castanea dentata) in Canada. Committee on the Status of Endangered Wildlife in Canada, Ottawa. 19 pp.

Ambrose, J.D. and S.W. Aboud. 1987. Status Report on the American Chestnut, Castanea dentata in Canada. Committee on the Status of Endangered Wildlife in Canada. Ottawa,.18 pp.

Ambrose, J.D. and P.G. Kevan. 1990. Reproductive biology of rare Carolinian plants with regard to conservation management. Pages 57-63 in G.M. Allen, P.F.J. Eagles, and S.D. Price, eds., Conserving Carolinian Canada: Conservation Biology in the Deciduous Forest Region. University of Waterloo Press, Ontario.

Anagnostakis, S.L. and B. Hillman. 1992. Evolution of the chestnut tree and its blight. Arnoldia 52:2-10.

Anagnostakis, S.L., K.M. Welch, J.W. Snow, K. Scarborough and T.D. Eichlin. 1994. The rediscovery of the Clearwing chestnut moth, Synanthedon castaneae (Busck) (Lepidoptera: Sesiidae) in Connecticut. Journal of the New York Entomological Society 102: 111-112.

Anonymous. 2009. Oriental chestnut gall wasp. University of Missouri Extension.

Bessin, R. 2003. Nut Weevils. University of Kentucky, Cooperative Extension Service, EntFact 206.

Boland, G.J., M.S. Melzer and D.L. Mooij. 1997. Biological Control of Chestnut Blight with Hypovirulence in Southern Ontario. Ontario Forest Research Institute, Ontario Ministry of Natural Resources.

Brewer, L.G. 1995. Ecology of survival and recovery from blight in American chestnut trees (Castanea dentata (Marsh.) Borkh.) in Michigan. Bulletin of the Torrey Botanical Club 122:40-57.

Burgess, K.S. and B.C. Husband. 2006. Habitat differentiation and the ecological cost of hybridization. Journal of Ecology 94:1061-1069.

Burgess, K.S., M. Morgan and B.C. Husband. 2008. Interspecific seed discounting and the fertility cost of hybridization in an endangered species. New Phytologist 177:276-284.

Dunn, M.M. and G.J. Boland. 1993. Hypovirulent isolates of Cryphonectria parasitica in southern Ontario. Canadian Journal of Plant Pathology 15:245-252.

Farrar, J.L. 1995. Trees in Canada. Fitzhenry and Whiteside Ltd., Markham, Ontario. 502 pp.

Fox, W.S. 1949. Present state of the chestnut, Castanea dentata (Marsh.) Borkh. in Ontario. The Canadian Field-Naturalist 63:88-89.

Gerrath, J. 2006. Detection of Hybridization Between Castanea dentata (Marsh.) Borkh. and Non-native Congeners in Ontario. M.Sc. Thesis. University of Guelph, Guelph, Ontario.

Gravatt, G.F. and L.S. Gill. 1930. Chestnut Blight. U.S. Department of Agriculture Farmers’ Bulletin No. 1641. 18 pp.

Griffin, G.J. 1989. Incidence of chestnut blight and survival of American chestnut in forest clearcut and neighboring understory sites. Plant Disease 73:123-127.

Griffin, G.J. 2000. Blight control and restoration of the American Chestnut. Journal of Forestry 98(2):22-27.

Griffin, G.J., H.C. Smith, A. Dietz and J.R. Elkins. 1991. Importance of hardwood competition to American chestnut survival, growth, and blight development in forest clearcuts. Canadian Journal of Botany 69:1804-1809.

Harvell, C.D., C.E. Mitchell, J.R. Ward, S. Altizer, A.P. Dobson, R.S. Ostfeld and M.D. Samuel. 2002. Climate warming and disease risks for terrestrial and marine biota. Science 296:2158-2162.

Heald, F.D. and M.W. Gardner. 1914. Longevity of pycnospores of the chestnut blight fungus in soil. Journal of Agricultural Research 2:67-75.

Heald, F.D., M.W. Gardner and R.A. Studhalter. 1915. Air and wind dissemination of ascospores of the chestnut blight fungus. Journal of Agricultural Research 3:493-526.

Hebard, F.V. 2005.  The backcross breeding program of the American Chestnut Foundation. In, Proceeding of Conference on Restoration of American Chestnut to Forest Lands (PDF). Steiner, K.C. and J.E. Carlson (eds.).

Hill, J.M. 1994. Wildlife value of Castanea dentata past and present, the historical decline of the chestnut and its future use in restoration of natural areas. Pages 186-193 in M.L. Double and W.L. MacDonald, eds., Proceedings of the International Chestnut Conference. West Virginia University Press, Morgantown.

Ingram, D.S. 1998. Biodiversity and plant pathogens and conservation. Presentation at 7th International Congress of Plant Pathology, Edinburgh, Scotland.

Jacobs, D.F. 2007. Toward development of silvical strategies for forest restoration of American chestnut (Castanea dentata) using blight-resistant hybrids. Biological Conservation 137:497-506

Kuhlman, E.G. 1978. The devastation of American chestnut by blight. Pages 1-3 in W.L. MacDonald, F.C. Cech, J. Luchoc and C. Smith, eds., Proceedings of the American Chestnut Symposium. West Virginia University Books, Morgantown, West Virginia. 122 pp.

Lee, H.T., W.D. Bakowsky, J. Riley, J. Bowles, M. Puddister, P. Uhlig and S. McMurray. 1998.  Ecological Land Classification for Southern Ontario: First Approximation and Its Application. Ontario Ministry of Natural Resources, Southcentral Science Section, Science Development and Transfer Branch. SCSS Field Guide FG-02.

Little, E.L., Jr. 1977, Atlas of United States Trees, Volume 4. Minor Eastern Hardwoods. U.S. Department of Agriculture Miscellaneous Publication 1342. Washington, D.C. 17 pp. 230 maps.

McKeen, C.D. 1995. Chestnut blight in Ontario: past and present status. Canadian Journal of Plant Pathology 17:295-304.

McKeen, C.D. 1985. Chestnut blight and the survival of Castanea dentata in southern Ontario. Canadian Journal of Plant Pathology 7:446

McWilliams, W.H., T.W. Lister, E.B. LaPoint, A.K. Rose and J.S. Vissage. 2005. Current status of chestnut in eastern US forests. In Proceedings of the Conference on Restoration of American Chestnut to Forest Lands. Steiner, K.C. and J.E. Carlson (eds).

Melzer, M.S. and G.J. Boland. 1999. CHV3-type dsRNAs and the GH2 genotype in a population of Cryphonectria parasitica in Ontario. Canadian Journal of Plant Pathology 21:248-255.

Melzer, M.S. and G.J. Boland. 2004. Survey of American chestnut and chestnut blight in Ontario. Canadian Plant Disease Survey 84:118-119.

Melzer, M.S., M. Dunn, T. Zhou and G.J. Boland. 1997. Assessment of hypovirulent isolates of Cryphonectria parasitica for potential in biological control of chestnut blight. Canadian Journal of Plant Pathology 19:69-77.

Milgroom, M.G and P. Cortesi. 2004. Biological control of Chestnut blight with hypovirulence: A critical analysis. Annual Review of Phytopathology 42: 311-338.

Moerman, D. Native American Ethnobotany Database. 2003.

Moss, M.R. and P.L. Hosking. 1983. Forest associations in extreme southern Ontario ca 1817: a biogeographical analysis of Gourlay’s statistical account. Canadian Geographer 27:184-193.

NatureServe. 2009. NatureServe Explorer: An online encyclopedia of Version 7.1. NatureServe, Arlington, Virginia.

Opler, P.A. 1979. Insects of American Chestnut: Possible importance and conservation concern. Pages 83-85 in: Proceedings of the American Chestnut Symposium, W. McDonald, ed. University of West Virginia Press, Morgantown, West Virginia.

Paillet, F. 1994. Ecology and paleoecology of American chestnut in eastern North America. Pages 178-183 in: Proceedings of the International Chestnut Conference. M.L. Double and W.L. MacDonald, eds., West Virginia University Press, Morgantown, West Virginia.

Rieske, L.K. 2007. Success of an exotic gallmaker, Dryocosmus kuriphilus, on chestnut in the USA: a historical account. OEPP/EPPO Bulletin 37:172–174.

Russin, J.S., L. Shain and G.L. Nordin. 1984. Insects as carriers of virulent and cytoplasmic hypovirulent isolates of the chestnut blight fungus. Journal of Economic Entomology 77 (4):838-846.

Saucier, J.R. 1973. American Chestnut...an American wood. FS-230, U.S. Department of Agriculture, Forest Service. Washington, D.C. 6pp.

Smock, L.A. and C.M. MacGregor. 1988. Impact of the American chestnut blight on aquatic shredding macroinvertebrates. Journal of the North American Benthological Society 7:212-221.

Sudworth, G.B. 1892. On the name of the American chestnut. Bulletin of the Torrey Botanical Club 19:152-154.

Tindall, J.R., J.A. Gerrath, M. Melzer, K. McKendry, B. Husband and G.J. Boland. 2004. Ecological status of American chestnut (Castanea dentata) in its native range in Canada. Canadian Journal of Forest Research 34:2554-2563.

Venette, R.C., E.E. Davis, H. Heisler and M. Larson. 2003. Mini risk assessment Chestnut weevil, Curculio elephans (Gyllenhal).

Recovery strategy development team members

Recovery Strategy Development Team
Name Affiliation and Location
John Ambrose (Co-chair) Botanical Consultant, Guelph, Ontario
Greg Boland (Co-chair) University of Guelph, Guelph, Ontario
Ken A. Elliott, RPF Ontario Ministry of Natural Resources, London, ON
Brian Husband University of Guelph, Guelph, Ontario
Melody Melzer University of Guelph, Guelph, Ontario
Advisors
Name Affiliation and Location
Tannis Beardsmore Canadian Forest Service - Atlantic Forestry Centre
Barb Boysen Forest Gene Conservation Association, Peterborough, Ontario
Paul Catling Agriculture and Agri-food Canada, Ottawa, Ontario
Christopher Cunliffe Society of Ontario Nut Growers (SONG)
Andrew Graham Ontario Soil and Crop Improvement Association (OSCIA)
Colin McKeen Canadian Chestnut Council
Martin Neumann Grand River Conservation Authority
Lindsay Rodger Parks Canada, Gatineau, Quebec
Gerry Waldron Consulting Ecologist, Harrow, Ontario

Appendix 1. Chestnut blight

Description of Cryphonectria parasitica and Symptoms of Chestnut Blight

The chestnut blight fungus, Cryphonectria parasitica, has orange myceliumFootnote 21, fruiting bodies, and spores. Symptoms of chestnut blight include bark cankers, wilting of distal foliage (furthest away from the main trunk), and formation of epicormic shoots below cankers. On young trees, cankers are sunken and orange, and are most easily seen if the bark is wet. Cankers are not easily seen on trees with mature bark and can most easily be located by the epicormic shoots that form below the cankers. The fungus kills chestnut trees when cankers on the trunk girdle the tree and interrupt the vascular flow between roots and crown.

The asexual spores of C. parasitica, termed conidia, are wet spores and are dispersed by rain, insects, birds, and mammals. Conidia can survive freezing, drying and flooding. In the drip zone of infected trees there can be up to several million viable conidia per gram of soil. Conidia in soil are replenished with each rainfall. Numbers of conidia gradually decrease between periods of rain and conidia survive up to four months of desiccation in soil. These results suggest that there are always viable conidia present in soil under infected trees (Heald and Gardner 1914).

The sexual spores of C. parasitica, termed ascospores, are dry spores and are predominantly wind dispersed. Ascospores are released during periods of rain and for up to several hours after rain has ended. Ascospores released during rain are predominately washed to the ground but those released after rain are wind dispersed. In one study, 23 to 50 ascospores per square inch were counted from water traps exposed for 5 days 300 to 400 feet (91-122 m) from the nearest ascospore source (Heald et al. 1915). Infections by ascospores and conidiaFootnote 22 occur at wounds or branch scars.

Insect Transmission

Many insects have been implicated in the transmission of chestnut blight through non-specific transferral of conidia between trees. One post-epidemic study confirmed that chestnut stems and blight cankers harboured a large, diverse insect fauna (Russin et al. 1984). The majority of 495 captured insect species were from the Coleoptera and Diptera families, and C. parasitica was isolated from 69 insect species (mostly Coleoptera) representing four orders. To date we have not found any evidence that American Chestnut had a strong connection to any individual pollinator species and that no pollinator was solely dependent on chestnut flowers.

Precautions to Prevent Disease Spread by Humans

Extreme care must be taken not to move chestnut blight between populations of American Chestnut. All surfaces in the drip zone of the tree are potentially covered with spores of the pathogen, especially the trunk and forest floor. Vehicles should be parked at least 20 metres from the nearest chestnut tree. When approaching a tree, prior to entering the drip zone, shoe/boot covers should be placed over footwear. Disposable gloves should be worn if any contact is made with any surface in the drip zone of the tree. Care should be taken not to allow clothing to contact surfaces, especially if other trees will be visited before the clothing is laundered. Disposable coveralls may be necessary. Just outside of the drip zone, equipment that has touched surfaces must be disinfected with 0.5% sodium hypochlorite. Gloves and shoe covers should be removed and placed in a plastic bag for disposal. Gloves and shoe covers should only be used once.

Disease Management Strategies

Several strategies have shown promise for the management of chestnut blight. These strategies include sanitation measures, fungicides, biological control, and disease resistance.

Sanitation measures include the removal of dead twigs and stems that act as infection sites, and the removal of infested plant material that acts as sites for sporulation of the pathogen. In Europe, these measures are primarily practiced in chestnut orchards grown for nut production (Milgroom and Cortesi 2004). They are considered to reduce the amount of inoculum of the pathogen but, alone, has a relatively small effect on disease progress and is most effective when used within an integrated management program.

In North America, little sanitation of infected plant material is practiced in natural forests. Previous attempts at using such practices met with relatively limited success, particularly during the height of the pandemic when inoculum of the pathogen was abundant within populations of chestnut. However, the surviving populations of chestnut and chestnut blight have become fragmented and isolated, and many sites no longer appear to contain the pathogen. Therefore, cultural practices that reduce the number of infection sites on susceptible trees or reduce populations of the pathogen may prove more effective now.

Thinning around sprouting chestnuts may promote vigorous growth and reduce their susceptibility to blight infection (Griffin 2000). A recent survey in Ontario also showed a reduced amount of blight infection where the canopy was more open (Tindall et al. 2004). In contrast, removal of the overstory resulted in an increase of disease from 5 percent to 100 percent within five years (Paillet 1994). When thinning around American Chestnut, great care must be taken not to cause wounding because the blight pathogen is a wound pathogen. In sites where alternative hosts are present, thinning of such species within a 20 to 40 metre radius should be considered, particularly if any symptoms of blight are present.

The application of selected fungicides for management of blight cankers has met with limited success. Difficulties in selecting fungicides and formulations that can penetrate to the site of infection in the vascular cambium of woody tissues, and the development of resistance to selected fungicides, appear to be the primary limiting factors to efficacy. Emphasis in previous studies was placed on slowing canker development and/or eliminating the pathogen from infected tissues. Recent developments in fungicide chemistry and formulations may have identified new opportunities for management of plant diseases associated with woody cankers. In addition, the use of fungicides for suppressing sporulation by the pathogen on the surface of diseased tissues has not been examined. Such an epidemiological approach to the management of chestnut blight could contribute to a reduction in the populations of the pathogen over time. Fungicides are regulated compounds in Canada and, if available for use, would be most suitable for protecting individual trees considered to be of high-value, such as orchard trees being used for nut production, grafted trees, etc., and would primarily be effective for relatively brief periods of time. Application of fungicides is not practical in forest settings.

Hypovirulent isolates (i.e., isolates with reduced virulenceFootnote 23 due to the presence of a fungal virus) of chestnut blight have shown considerable success in Europe for biological control. Hypovirulence in isolates of the chestnut blight pathogen not only cause a marked reduction in virulence, or the ability to cause disease, but the specific fungal viruses that interfere with virulence can be transmitted to virulent isolates through physical contact or anastomosisFootnote 24 between isolates. In Europe, where chestnut populations were also devastated by the blight, naturally occurring hypovirulent isolates were found that produced superficial cankers that eventually healed instead of killing the tree. Natural and assisted transmission of hypovirulence through the C. parasitica population in Europe has resulted in extensive regeneration of populations of chestnut in the forests there.

Hypovirulence has not been as effective in North America as in Europe, despite the presence of hypovirulent isolates in various regions of the United States and Canada. Several of these isolates have been studied extensively in the United States but there is little evidence that they have successfully reduced the severity of chestnut blight (Milgroom and Cortesi 2004). In Ontario, promising hypovirulent isolates of C. parasitica were characterized from several locations, and assessment of these isolates for biological control efficacy was initiated. Results from field inoculations to date have not been encouraging but additional study and intervention into processes affecting the spread and distribution of hypovirulence may identify factors restricting the efficacy of this approach in North America.

Critical analyses of using hypovirulence for biological control of chestnut blight have concluded that effective control has been observed in Europe and in Michigan but that almost all other attempts in North America have failed, particularly at the population level (Milgroom and Cortesi 2004). Medium or large-scale experiments have been completed in West Virginia, Connecticut, Virginia and Wisconsin where up to hundreds of trees and thousands of cankers were inoculated with hypovirulent isolates, with little evidence of effective biological control of blight. Various characteristics of the fungal viruses, the pathogen, and the trees are thought to determine the success or failure of hypovirulence (Milgroom and Cortesi 2004). Knowledge of these factors, such as tree, site, and climate characteristics, and their influence on the epidemiological aspects of blight are often poorly understood (Griffin 1989, Griffin et al. 1991, Brewer 1995).

Hypovirulent isolates have been found in various locations in North America, but the only region where hypovirulence has been effective is in Michigan where it occurs naturally and in some places trees are remarkably healthy (Milgroom and Cortesi 2004). Populations of chestnut and blight in Michigan are similar to those in Ontario, where one hypovirulence-associated virus, CHV-3, has been associated with healing cankers and infected isolates of the pathogen (Melzer and Boland 1999). However, the role of hypovirulence in Ontario is less clear than in Michigan.

Other strategies for the biological control of chestnut blight have also been evaluated. The use of mud packs directly on cankers is thought to be effective because of the activity of micro-organisms in the soil that affect growth and development of the pathogen in the canker. These micro-organisms may offer an opportunity for alternative approaches to biological control.

There is considerable interest in the potential for identifying or breeding American Chestnut that is resistant to chestnut blight. Evolutionary theory suggests that some resistant trees may be present in an otherwise susceptible population of a species, and that these resistant trees may survive in remnant populations following pandemic diseases. Naturally-occurring resistant trees would be an important discovery for the recovery of this species, and differences in susceptibility have been observed among some individuals (Griffin 2000). Unfortunately, it can be difficult to distinguish between resistant trees and trees that have simply escaped disease and there have been no confirmed examples of American Chestnut that are resistant to chestnut blight. The relatively high proportion of trees in southern Ontario that do not have symptoms of chestnut blight is encouraging.

There is also considerable interest in breeding resistant American Chestnut trees through interspecific hybridization with Chinese and Japanese Chestnuts, followed by recurrent back-crossing to the American species and selection of resistant individuals. It is anticipated that this procedure will result in progeny that are highly resistant to chestnut blight and are at least 94 percent American Chestnut in other characteristics. While this is expected to produce blight resistant trees for planting, there is no information on the durability of resistance as trees mature. The American Chestnut Foundation has a large and established program in breeding for disease resistance in chestnut and outplanted seeds from their breeding program to test for blight resistance in three national forests in 2008. Breeding programs are also established at several universities and government research stations in the United States. The Canadian Chestnut Council has initiated a disease resistance breeding program in southern Ontario that hopes to build on the efforts of the American Chestnut Foundation and other institutions and to incorporate germplasm that is adapted to this region with disease resistant American Chestnut breeding material. In addition to this traditional approach to breeding resistant chestnut, scientists in the United States are evaluating the potential for genetic engineering of American Chestnut with disease resistance genes from other organisms.

Part 3 – American Chestnut – Ontario Government Response Statement, prepared by the Ontario Ministry of Natural Resources

American Chestnut is a large, deciduous canopy tree that can grow up to 30 metres tall and have a trunk up to 1.5 metres in diameter with smooth dark brown/olive bark that separates into broad flat-topped ridges as it ages. Trees flower in late May to early July and are wind and insect-pollinated.

Protecting and recovering Species at Risk in Ontario

Species at risk recovery is a key part of protecting Ontario's biodiversity. Biodiversity – the variety of living organisms on Earth – provides us with clean air and water, food, fibre, medicine and other resources that we need to survive.

The Endangered Species Act, 2007 (ESA) is the Government of Ontario's legislative commitment to protecting and recovering species at risk and their habitats. As soon as a species is listed as extirpated, endangered or threatened under the ESA, it is automatically protected from harm or harassment. Also, immediately upon listing, the habitats of endangered and threatened species are protected from damage or destruction.

Under the ESA, the Ministry of Natural Resources (the Ministry) must ensure that a recovery strategy is prepared for each species that is listed as endangered or threatened. A recovery strategy provides science-based advice to government on what is required to achieve recovery of a species.

Government response statements

Within nine months after a recovery strategy is prepared, the ESA requires the Ministry to publish a statement summarizing the government's intended actions and priorities in response to the recovery strategy. The recovery strategy for American Chestnut (Castanea dentata) was published on June 15, 2012 (American chestnut).

The response statement is the government's policy response to the scientific advice provided in the recovery strategy. All recommendations provided in the recovery strategy were considered and this response statement identifies those that are considered to be appropriate and necessary for the protection and recovery of the species. In addition to the strategy, the response statement is based on input from stakeholders, other jurisdictions, Aboriginal communities and members of the public. It reflects the best available traditional, local and scientific knowledge at this time and may be adapted if new information becomes available. In implementing the actions in the response statement, the ESA allows the Ministry to determine what is feasible, taking into account social and economic factors.

Moving forward to protect and recover American Chestnut

American Chestnut is listed as an endangered species under the ESA. The ESA prohibits harm or harassment of the species without authorization. Such authorization would require that conditions established by the Ministry be met. The American Chestnut's habitat will be protected from damage or destruction under the Act by June 30, 2013.

American Chestnut was a dominant forest tree species in northeastern North America until the early 1900s when populations were devastated by a fungal pathogen that causes chestnut blight. Chestnut blight continues to be the greatest threat to American Chestnut in Ontario, as well as loss and degradation of habitat. In southwestern Ontario, American Chestnut populations have been reduced to less than one percent of the original 1.5 to 2 million trees. The species' native range in Ontario accounts for less than five percent of its native range in North America, which extends from southern New England to the southern Appalachian mountains. Historically, American Chestnut held significant economic and cultural importance in North America for indigenous and for non-indigenous peoples.

American Chestnut populations in Ontario are gravely threatened by chestnut blight, with many trees surviving only as stumps with coppice shootsFootnote 25, while large mature trees are considered extremely rare. The Ontario population is unlikely to become self-sustaining without effective measures to control or halt the impact of chestnut blight. At this time, however, there remains a significant amount of uncertainty around the feasibility and effectiveness of blight control measures and appropriate methods of intervention. To date, recovery actions targeted at weakening the blight virus on affected trees and finding disease-resistant American Chestnuts have not been found to be effective in Ontario. The recovery action with the greater potential to establish blight resistance in American Chestnut in a reasonable time appears to be the production of a modified American Chestnut with genes from blight-resistant or blight-tolerant Chestnut species (e.g., Chinese Chestnut). At this time recovery efforts will focus on the continued support of research into various blight control measures, as well as on ensuring the persistence of the existing American Chestnuts in Ontario by supporting the conservation and enhancement of their genetic diversity, promoting blight tolerance, and preventing the spread of the disease.

The government's goal for the recovery of American Chestnut is to retain the current population level and distribution in Ontario while increasing genetic diversity and reproductive success, and where possible, explore the feasibility of implementing blight control measures to restore the species to a self-sustaining state.

As research into blight control measures, such as inter-breeding, progresses over the next five years, the government's goal for the recovery of American Chestnut may be re-evaluated as the potential feasibility and policy options of implementing blight control measures evolve.

Protecting and recovering species at risk is a shared responsibility. No single agency or organization has the knowledge, authority or financial resources to protect and recover all of Ontario's species at risk. Successful recovery requires inter-governmental co-operation and the involvement of many individuals, organizations and communities.

In developing the government response statement, the Ministry considered what actions are feasible for the government to lead directly and what actions are feasible for the government to support its conservation partners to undertake.

Government-led actions

To help protect and recover American Chestnut, the government will directly undertake the following actions

  • Undertake and consult on an evaluation of when and how intervention, such as inter-breeding to create blight resistant American Chestnuts, is appropriate for the purposes of recovery. Although in some cases these types of actions may be the only viable method of recovery, the role of species at risk that have been genetically modified raises policy questions that require further investigation and analysis
  • Educate other agencies and authorities involved in planning and environmental assessment processes on the protection requirements under the ESA
  • Encourage the submission of American Chestnut data to the Ministry's central repository at the Natural Heritage Information Centre
  • Undertake communications and outreach to increase public awareness of species at risk in Ontario
  • Protect American Chestnut and its habitat through the ESA. Apply and implement habitat protection provisions of the Act by June 30, 2013
  • Support conservation, agency, municipal, industry partners and Aboriginal communities to undertake activities to protect and recover the American Chestnut. Support will be provided through funding, agreements, permits (including conditions) and advisory services
  • Establish and communicate annual priority actions for government support in order to encourage collaboration and reduce duplication of efforts

Government-supported actions

The government endorses the following actions as being necessary for the protection and recovery of the American Chestnut. Actions identified as "high" will be given priority consideration for funding or for authorizations under the ESA. The government will focus its support on these high-priority actions over the next five years.

Focus area: Inventory and monitoring

Objective: Survey and monitor known American Chestnut populations and habitat in Ontario.

Actions:

1. (High) Develop and implement a standardized survey monitoring program for naturally-occurring populations of American Chestnut to:

  • detect undiscovered occurrences
  • regularly complete population surveys and health assessments of American Chestnut occurrences; and
  • assess habitat conditions at occupied sites

2. Identify and assess planted populations of American Chestnut across Ontario to:

  • determine the genetic parentage (i.e., which one or more species of chestnut the tree is derived from) and geographical source of the trees, where possible
  • act as potential sources of genetically-resistant trees for future restoration efforts and research purposes; and
  • reduce the risk of spreading blight from planted chestnut trees to naturally-occurring American Chestnuts

Focus area: Threat management

Objective: Develop and evaluate management measures to control the threat of chestnut blight.

Actions:

3. (High) Conserve and enhance genetic diversity of American Chestnuts through the establishment of quarantined plantations (e.g., from seed or clones) and facilitated propagation (e.g., cross pollination) in naturally-occurring populations.

4. (High) Investigate the effectiveness of producing a modified American Chestnut with genes from blight-resistant or blight-tolerant Chestnut species (e.g., Chinese Chestnut).

5. Investigate the effectiveness of breeding American Chestnut with other American Chestnuts for blight resistance.

6. Investigate the effectiveness of inoculating the species with a viral infection to weaken the blight fungus and decrease the species' vulnerability to the disease.

Focus area: Awareness

Objective: Increase public awareness about chestnut blight and the need to protect American Chestnuts.

Actions:

7. Promote awareness among land management authorities, private landowners, conservation partners, and Aboriginal communities of the need to increase protection of American Chestnut, reduce the movement of all chestnut species, and limit the spread of blight.

The planting or moving of American Chestnuts without appropriate precautions may introduce chestnut blight into populations that may not yet have been exposed, thus increasing the risks to the species' survival and recovery.

Implementing actions

Financial support for the implementation of actions may be available through the Species at Risk Stewardship Fund, Species at Risk Research Fund for Ontario, Species at Risk Farm Incentive Program or Community Fisheries and Wildlife Involvement Program. Conservation partners are encouraged to discuss project proposals related to the actions in this response statement with the Ministry. The Ministry can also advise if any authorizations under the ESA or other legislation may be required to undertake the project.

Implementation of the actions may be subject to changing priorities across the multitude of species at risk, available resources and the capacity of partners to undertake recovery activities. Where appropriate, the implementation of actions for multiple species will be co-ordinated across government response statements.

Reviewing progress

The ESA requires the Ministry to conduct a review of progress towards protecting and recovering a species not later than five years from the publication of this response statement. The review will help identify if adjustments are needed to achieve the protection and recovery of the American Chestnut.

Acknowledgement

We would like to thank all those who participated in the development of the "Recovery Strategy for the American Chestnut (Castanea dentata) in Ontario" for their dedication to protecting and recovering species at risk.

For additional information:

Visit the species at risk website
Contact your MNR district office
Contact the Natural Resources Information Centre
1-800-667-1940
TTY 1-866-686-6072
mnr.nric.mnr@ontario.ca
Ministry of Natural Resources and Forestry

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