Recovery Strategy for the Spiny Softshell (Apalone spinifera) in Canada - 2016 [Proposed]

Spiny Softshell

Spiny Softshell

2016


Recovery Strategy for the Spiny Softshell (Apalone spinifera) in Canada - 2016

Species at Risk Act
Recovery Strategy Series

Cover of publication

Recommended citation:

Environment Canada. 2016. Recovery Strategy for the Spiny Softshell (Apalone spinifera) in Canada [Proposed] Species at Risk Act Recovery Strategy Series. Environment Canada, Ottawa. xx + XX 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: Spiny Softshell: © Ryan M. Bolton

Également disponible en français sous le titre
« Programme de rétablissement de la tortue-molle à épines (Apalone spinifera) au Canada [Proposition] »

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


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 the Environment and Minister responsible for the Parks Canada Agency is the competent minister under SARA for the Spiny Softshell and has prepared this strategy, as per section 37 of SARA. To the extent possible, it has been prepared in cooperation with the Province of Ontario (Ministry of Natural Resources and ForestryFootnote1) and the Province of Quebec (Ministère des Forêts, de la Faune et des Parcs).

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 Canada, the Parks Canada Agency, or any other jurisdiction alone. All Canadians are invited to join in supporting and implementing this strategy for the benefit of the Spiny Softshell 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 Canada, the Parks Canada Agency, 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 the recovery strategy identifies critical habitat, there may be future regulatory implications, depending on where the critical habitat is identified. SARA requires that critical habitat identified within federal protected areas be described in the Canada Gazette, after which prohibitions against its destruction will apply. For critical habitat located on federal lands outside of federal protected areas, the Minister of the Environment must either make a statement on existing legal protection or make an order so that the prohibition against destruction of critical habitat applies. For critical habitat located on non-federal lands, if the Minister of the Environment forms the opinion that any portion of critical habitat is not protected by provisions in or measures under SARA or other Acts of Parliament, and not effectively protected by the laws of the province or territory, SARA requires that the Minister recommend that the Governor in Council make an order to extend the prohibition against destruction of critical habitat to that portion. The discretion to protect critical habitat on non-federal lands that is not otherwise protected rests with the Governor in Council.

This document was developed by Rachel deCatanzaro, Krista Holmes, Angela McConnell, Marie-Claude Archambault, Lauren Strybos (Environment Canada, Canadian Wildlife Service – Ontario Region), Sylvain Giguère (Environment Canada, Canadian Wildlife Service – Quebec Region), Barbara Slezak, Carollynne Smith, Bruna Peloso, Louis Gagnon, Lee Voisin and Kari Van Allen (formerly Environment Canada, Canadian Wildlife Service – Ontario Region). The Recovery Strategy benefited from input, review and suggestions from the following individuals: Madeline Austen, Elizabeth Rezek, Lesley Dunn (Environment Canada, Canadian Wildlife Service – Ontario Region), Ashley King, Wendy Dunford (Environment Canada, Canadian Wildlife Service - National Capital Region), Amelia Argue, Joe Crowley, Gillian Ferguson-Martin, Jay Fitzsimmons, Aileen Wheeldon, Dana Kinsman, Jim Saunders, Rhonda Donley (Ministry of Natural Resources and Forestry), Gary Allen, Joanne Tuckwell, Tammy Dobbie, Colin Hoag, Eileen Nolan, and Harry Szeto (Parks Canada Agency) and staff from the Ministère des Forêts, de la Faune et des Parcs.

Numerous other individuals contributed to an earlier draft multi-turtle recovery strategy including Patrick Galois (Amphibia-Nature), Gabrielle Fortin (Environment Canada, Canadian Wildlife Service – Quebec Region), David Seburn (Seburn Ecological Service), Scott Gillingwater (Upper Thames River Conservation Authority). Contributions from staff at the Ministry of Natural Resources and Forestry, Ministère des Forêts, de la Faune et des Parcs, Canadian Wildlife Service, and various universities and other organizations are also gratefully acknowledged. Further, recovery documents developed by the Équipe de rétablissement des tortues du Quebec and the Ontario Multi-Species Turtles at Risk Recovery Team formed the foundation for earlier drafts of this document and are gratefully acknowledged.

Acknowledgment 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 Aboriginal organizations and individual citizens, and stakeholders who provided input and/or participated in consultation meetings.

The Spiny Softshell (Apalone spinifera) is listed as Threatened on Schedule 1 of the Species at Risk Act (SARA). It is a medium to large-sized freshwater turtle which has a flat, leathery carapaceFootnote2 that is olive to tan in colour with ocelliFootnote3 markings. Spiny Softshells are highly aquatic, typically associated with large water bodies such as rivers, streams, or lakes, although they can also inhabit marshes, ponds, and oxbowsFootnote4. The species ventures onto land only to nest.

The species' range extends throughout the eastern half of North America, from the Great Lakes south to the Gulf of Mexico. In Canada, Spiny Softshells are found in southern Ontario and Quebec. It is estimated that roughly 1% of the global distribution of the species occurs in Canada.

The Canadian adult population of Spiny Softshell is estimated to be between 600 and 1,500 individuals. Surveys of local populations in Ontario indicate that over the past 20 years there may have been population declines of up to 50% (COSEWIC 2014).

The main threats to the Candian population of the Spiny Softshell are: shoreline and riverine habitat development; boating mortality; human subsidized predatorsFootnote5; illegal collection; exotic and invasive species; water control structures; livestock farming and ranching; fishing by-catch; and disturbance from human activities. Other threats identified include contamination and nutrient loading and climate change. The Spiny Softshell is highly vulnerable to any increases in rates of mortality of adults or older juveniles since the species has delayed sexual maturity and low reproductive rate.

There are unknowns regarding the feasibility of recovery of the Spiny Softshell. In keeping with the precautionary principle, this recovery strategy has been prepared as per section 41(1) of SARA, as would be done when recovery is determined to be feasible.

The long-term population and distribution objective (i.e., 50 years) is to maintain, and where necessary and feasible, increase the abundance and distribution of the Spiny Softshell to ensure the persistence of self-sustaining local populations in areas where it occurs in Canada. The medium term sub-objective (i.e., around 10 to 15 years) is to stabilize and, if necessary and feasible, increase population abundance in areas where local Spiny Softshell populations are suspected to be declining through increasing suitable habitat and/or mitigating threats. The broad strategies to be taken to address the threats to the survival and recovery of the species are presented in the section on Strategic Direction for Recovery (section 6.2).

Critical habitat for the Spiny Softshell is identified in this recovery strategy using three criteria: 1. habitat occupancy; 2. habitat suitability; and 3. habitat connectivity. Application of the critical habitat criteria to available data identifies 12 units that contain critical habitat for the Spiny Softshell in Canada, totaling up to ~71,404 ha. There are other locations that may still support Spiny Softshell, however, these locations have not been surveyed recently or adequately. For this reason, critical habitat for Spiny Softshell has only been partially identified in this recovery strategy. The Schedule of Studies (section 7.2) outlines the activities required to complete the identification of critical habitat in support of the population and distribution objectives. As additional information becomes available, critical habitat may be refined or more units meeting critical habitat criteria may be added.

One or more action plans will be completed for the Spiny Softshell and posted on the Species at Risk Public Registry by December 2022.

Based on the following four criteria used by Environment Canada to assess the feasibility of recovery, there are unknowns regarding the feasibility of recovery of the Spiny Softshell. In keeping with the precautionary principle, a recovery strategy has been prepared as per section 41(1) of SARA for this species, as would be done when recovery is determined to be 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.

    Yes. There are between 600 and 1,500 mature individuals within the total Canadian population of Spiny Softshell (COSEWIC 2014). In Ontario, the species occurs in the Great Lakes watershed in southwestern Ontario, with many observations being clustered in four areas (including two sites on Lake Erie and sites within two major river systems) (COSEWIC 2014). In Quebec, there is one known extant population in one lake (consisting of <100 individuals) and a possible - but unconfirmed - population at a major river system (Reference removedFootnote6). Reference removed; Reference removed). Although the species has low population densities within its Canadian range, the Spiny Softshell is considered globally secure. There are populations outside Canada, within the rest of the species range, which may be able to sustain the population or improve its abundance in Canada.
  2. Sufficient suitable habitat is available to support the species or could be made available through habitat management or restoration.

    Yes. Although many of the habitats used by the Spiny Softshell have been lost, degraded, and/or fragmented as a result of industrial, urban and agricultural development, or construction and operation of water control structures, suitable habitat remains available within the Canadian range, and more could be made available through management and restoration to support this species. Management and restoration techniques could be used to increase the amount of suitable habitat, such as wetlands and nesting habitat, available for the species and to improve connectivity between local populations.
  3. The primary threats to the species or its habitat (including threats outside Canada) can be avoided or mitigated.

    Unknown. The primary threats to the species include shoreline and riverine habitat development or alteration, boating mortality, human subsidized predators, illegal collection, exotic and invasive species, water control structures, livestock farming and ranching, fishing by-catch, and disturbance from human activities. Although much habitat loss is likely irreversible or difficult to reverse, it may be possible to restore some former habitats, and to mitigate or avoid further habitat destruction through public education, and conservation of current habitat. Public education and enforcement may also help to lessen human disturbance and illegal collection of the species. There are several available techniques to reduce the threat posed by recreational and commercial fisheries by-catch that could be implemented through best management practices (BMPs) or effective regulation, such as turtle exclusion devices (Reference removed) and seasonal regulations. To mitigate boating mortality, regulations could be implemented regarding motorized boat use in habitats with high turtle densities (Lester et al. 2013) and educating boaters about impacts of boats to aquatic wildlife. Some techniques are available to control invasive species (such as invasive Common Reed (Phragmites australis)) and to lessen the impacts of nest predation. However, it is unknown if threats can be mitigated to the extent required to meet the population and distribution objectives for the Spiny Softshell in Canada.
  4. Recovery techniques exist to achieve the population and distribution objective or can be expected to be developed within a reasonable timeframe.

    Unknown. Recovery techniques such as habitat protection through land acquisition, regulations, zoning, and landscape planning, along with stewardship techniques have been used successfully for certain local populations (Seburn and Seburn 2000). Some BMPs have been developed and implemented and it is likely that others could be developed, tested, and implemented in a reasonable timeframe to help conserve vulnerable local populations from threats such as habitat loss and accidental mortality (see 3. above). However, it is unknown how effective these practices might be at preventing population declines. Public awareness/ educational materials have been developed and will continue to be an integral part of the recovery of this species. Techniques such as use of nest cages to reduce nest predation, head-startingFootnote7, and by-catch reduction devices to reduce mortality from fishing by-catch have been successfully implemented in some locations and could be used more broadly to mitigate threats to the species (Seburn and Seburn 2000; Larocque et al. 2012b). However, given the length of time it takes to see results of techniques, it is unknown whether they will be successful in achieving the population and distribution objectives in a reasonable timeframe.

Date of Assessment: May 2002

Common Name: Spiny Softshell

Scientific Name: Apalone spinifera

COSEWIC Status: Threatened

Reason for Designation: Substantial habitat loss in the past has restricted the distribution of this species to a small part of its former range. Habitat degradation through development and recreation may be blocking access to nesting, hibernation, feeding and basking sites. Other potential threats include the partial or complete isolation of segments of the population by dams and other structures, the reduction of juvenile recruitment by high predation rates on nests and high mortality rates due to collisions with motor boats, trapping and incidental mortality from fisheries.

Canadian Occurrence: Ontario and Quebec

COSEWIC Status History: Designated Threatened in April 1991. The status was re-examined and confirmed in May 2002.

In Canada, the Spiny SoftshellFootnote8 is listed as ThreatenedFootnote9 on Schedule 1 of the Species at Risk Act (SARA). In Ontario, the species is listed as ThreatenedFootnote10 under the Endangered Species Act, 2007 (S.O. 2007, ch.6) (ESA). It is also designated as a Specially Protected Reptile under the Ontario Fish and Wildlife Conservation Act (S.O. 1997, c.41). In Quebec, it has been listed as ThreatenedFootnote11 under the Act Respecting Threatened or Vulnerable Species (R.S.Q., ch.E-12.01) (ARTVS). The Spiny Softshell is also listed in Appendix II (allows trade of a listed species only if an export permit is granted) of the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES), which controls the international trade of this species (CITES 2014). Although there are six known subspecies of Apalone spinifera, the Eastern Spiny Softshell (Apalone spinifera spinifera), is the only subspecies to occur in Canada.

The global rank for the Spiny Softshell is Secure (G5) (NatureServe 2013). It is Nationally Vulnerable (N3) in Canada and Nationally Secure (N5) in the United States (NatureServe 2013). The species is ranked as Critically Imperiled in Quebec (S1) and Vulnerable (S3) in Ontario (Appendix A) (NatureServe 2013). The International Union for Conservation of Nature (IUCN) lists the Spiny Softshell as "Least Concern" (Van Dijk 2013).

Approximately 1% of the global distribution of the Spiny Softshell occurs in Canada (COSEWIC 2014).

The Spiny Softshell is a medium to large sized aquatic turtle. The species has a flat, leathery carapace, through which the turtle's spine and ribs can be felt (Reference removed). The carapace is olive to tan in colour with ocelli (circular markings resembling an eye), and has small spiny projections at the front edge which produce a sandpaper-like feel. The plastronFootnote12 is small, creamy white in colour, and offers only minimal protection (Reference removed). The head and limbs are olive to gray and patterned with dark spots and streaks (Ernst and Lovich 2009). This species has deeply webbed feet that are well adapted for swimming; a long neck; and an elongated pointed snout (COSEWIC 2002). The Spiny Softshell is able to move quickly on land and in the water, due to its streamlined, light weight shell (Reference removed).

The Spiny Softshell exhibits sexual dimorphismFootnote13. Females are typically 1.6 times larger than males (Harding 1997), reaching a maximum adult carapace size of 54 cm while males reach a maximum size of 21 cm (Ernst et al. 1994; COSEWIC 2002). Males and hatchlings have a carapace with light ocelli with a dark outline; while females have a carapace with a blotched pattern (COSEWIC 2002).

The Spiny Softshell has a life expectancy of several decades (Ernst and Lovich 2009), and it has been known to live in excess of 50 years (Reference removed). Males reach sexual maturity at 9 to 10 cm plastron length (at approximately 7 years of age), while females reach sexual maturity at 18 to 20 cm (at approximately 12 years of age) (Desroches and Rodrigue 2004; Ernst and Lovich 2009).

The Spiny Softshell's range (Figure 1) extends throughout the eastern half of North America. It can be found from the Great Lakes southward to the Gulf of Mexico with extensions into central and western parts of the USA, but occurs mainly in the Mississippi River sub basins (Arkansas/Red, Mississippi, Missouri and Ohio Rivers) and is largely absent from the eastern seaboard (Ernst and Lovich 2009).

Historically, the Spiny Softshell was more widely distributed in Canada, occurring throughout the lower Great Lakes/St. Lawrence River basin, from the upper St. Lawrence to lower Lake Huron. This included three major river systems in Quebec (Bonin 1997). Today, the Spiny Softshell populations in Canada are severely fragmented, and occur in only a few isolated areas across its historical range (Figure 2) (COSEWIC 2014). In Ontario, the Spiny Softshell has been reported primarily in southwestern Ontario within coastal areas and major rivers/ tributaries to Lake Erie, Lake St. Clair and Lake Huron. A large number of observations are clustered at four locations: two sites on Lake Erie, and sites in two major river systems. It appears that the species no longer occurs in western Lake Ontario and the Ottawa River (COSEWIC 2014). In Quebec, there are 3 extant occurrances of the species. Isolated individuals have been reported throughout the historical range in Quebec; however, these are not considered a population (Reference removed; Rioux and Desroches 2007; Reference removed; AARQ 1988). The estimated area of occupancyFootnote14 (AO) for the Spiny Softshell in Canada was 3,000 km² in 2002 (COSEWIC 2002). Since then, new data has been gathered and a new AO estimate is in development by COSEWIC (as of December 2014).

Within Canada, 40 element occurrences of Spiny Softshell have been documented. For the purposes of this report, the term 'element occurrence' is used synonymously with the term 'local population'. The population status of existing element occurrence information has been updated to reflect recent COSEWIC assessmentsFootnote15. As such, in Ontario, 12 element occurrences are considered extirpated and 13 are considered extant. An additional 7 populations may also be extant but have not been recently surveyed (i.e., historical populations). In Quebec, 5 element occurrences are presumed extirpated and 3 are considered extant. Therefore, the number of known local populations in Canada is between 16 and 23 (between 13 and 20 in Ontario and 3 in Quebec). The species is not well surveyed across its range and most of these populations are identified by only occasional records.

The total abundance and complete distribution of the Spiny Softshell is currently unknown and information on local populations consists of little more than presence/ absence data in many cases. No precise data are available on population sizes and trends, but preliminary data suggest populations are declining throughout the Canadian range, and that the estimated number of mature individuals (capable of reproduction) in Canada is between 600 to 1,500 (COSEWIC 2014). Recent surveys in southern Ontario indicate that over the last two decades the number of mature adults may have declined by as much as 50% (COSEWIC 2014). In Quebec, the number of individuals was estimated a decade ago to be in the low hundreds (Galois pers. comm. in COSEWIC 2002); today, there are believed to be fewer than 100 mature individuals in the single remaining population (COSEWIC 2014). Moreover, it is known that habitat continues to decline in quality and extent. Studies have reported a decline in the number of mature females in oviposition sites - including at three known large communal sites (References removed; Reference removed; Reference removed; COSEWIC 2014). A future increase in the population may be dependent on additional suitable habitat, which could be made available through habitat restoration and/or habitat enhancement techniques.

Figure 1. Spiny Softshell range in Canada and the United States (overall range from Ernst and Lovich (2009); Eastern Spiny Softshell subspecies range from Conant and Collins (1998)). This map represents the general range of the species (and subspecies), and does not depict detailed information on the presence and absence of observations within the range.

Long description for Figure 1

Figure 1 is a map of the Spiny Softshell’s range in Canada and the United States, including the range of the Eastern Spiny Softshell subspecies range (denoted with hatched lines). The core part of the range extends from western New York to southern Minnesota, south Texas and Georgia. There are small, isolated locations in New Jersey, North Carolina and some extensions of the main part of the range into New Mexico, Arizona, Southern California, Colorado. There is one large area of range in Montana with a small portion extending down into Wyoming. The Eastern Spiny Softshell range is primarily found south of the Great Lakes, extending from western New York to Michigan and south to northern Alabama. There is one isolated portion of the range in northern New York, extending slightly into southern Quebec.

Figure 2. Spiny Softshell range in Canada (Eastern Spiny Softshell subspecies range from Conant and Collins (1998)). This map represents the general range of the species, and does not depict detailed information on the presence and absence of observations within the range.

Long description for Figure 2

Figure 2 is a map that focusses on the range of the Eastern Spiny Softshell in Canada. The range extends from the extreme southwest part of Ontario near Windsor to Toronto in the north and Niagara Falls in the east. There is a smaller portion of the range in the extreme southern portion of Quebec where the Ottawa River enters the St. Lawrence River, and along the border with New York.

The Spiny Softshell relies primarily on aquatic habitat, and makes use of terrestrial habitat only for nesting. In Canada, the Spiny Softshell is typically associated with large bodies of water such as rivers, streams, or lakes, although it can also occur in marshes, ponds, and oxbows (Reference removed), and may use wetlands and ponds next to large bodies of water (Reference removed; Reference removed). Spiny Softshells may remain within a river (e.g., Reference removed) or move between rivers and a lake (e.g., Reference removed). They have been located in water depths of up to about 5 m, but typically stay close to shore in water less than 3 m deep, except during overwintering (Reference removed). Shallow areas with a soft substrate (mud or sand) and areas with sparse aquatic vegetation are commonly used by adults and juveniles for thermoregulation Footnote16 and predator avoidance (Reference removed; Ernst and Lovich 2009). Shallow areas allow Spiny Softshells to extend their head above water and breathe while keeping the remainder of their body buried in the substrate (Ernst and Lovich 2009). Spiny Softshells are also commonly found in association with features such as sandbars, mud flats, submerged logs and aquatic vegetation (Reference removed; Ernst and Lovich 2009).

Plummer (1976) studied Smooth Softshell Turtle (Apalone muticus) in Kansas and found that hatchlings of this species relied on a different habitat than the adults: hatchlings were usually found in small, shallow puddles created by the highly dissected shoreline of sandbars, or shallow waters on the lee end of sandbars. Currently it is unknown if hatchlings and juveniles of the Spiny Softshell are dependent on different habitats than the adults; this is recognized as an important knowledge gap and is listed in the Recovery Planning table (Table 2) as such, under the broad strategy "conduct research on population, habitat, and threats to fill knowledge gaps".

To protect themselves from freezing, Spiny Softshells overwinter in underwater hibernaculaFootnote17, usually under less than 5 to 10 cm of soft bottom substrate (e.g., sand or silt) (Ernst and Lovich 2009) from October to May. Females seem to overwinter earlier (mid-October) than males (end-November) (Dobbyn and Smith 2005).

Spiny Softshells often overwinter in the stream or lake where they spend the majority of their time during the active season. In rivers, hibernacula have been observed in pools with a minimum depth of 1 m and up to approximately 5 m deep (Reference removed; Reference removed; COSEWIC 2014). In lake environments, hibernacula have been reported, typically near stream outlets, in areas with water depths from 2 to over 7 m (Reference removed; Reference removed; Reference removed). Spiny Softshells are intolerant of sustained periods of anoxiaFootnote18 and select overwintering sites that stay well-oxygenated during winter (e.g., where water flows all winter) (Fletcher 2002; Reference removed; Reese et al. 2003; Ultsch 2006). Spiny Softshells are known to have site fidelity to their overwintering sites (Reference removed; Vermont Fish and Wildlife 2009). They are also known to overwinter communally (Reference removed; Reference removed; Reference removed; Dobbyn and Smith 2005).

In Canada, Spiny Softshells mate in the spring (late April or May), when turtles emerge from overwintering (Ernst and Lovich 2009; Reference removed). Mating usually occurs in deeper offshore waters (Harding 1997; Ontario Nature 2012), and little is known about this behaviour or the depths at which it occurs.

Female Spiny Softshells generally lay clutches of 12 to 18 eggs (Ernst et al. 1994) from early-June to mid-July (Fletcher 2002; COSEWIC 2014). Nests are usually found in areas where the substrate is mainly composed of sand or gravel and where the vegetation density and the slope are low (Reference removed; Reference removed; Reference removed). Common nesting areas include sand beaches, sand or gravel bars, or other terrestrial areas with sand, gravel, or clay banks (COSEWIC 2002; Reference removed; Bolton and Brooks 2010). Sandy soil is preferred, but nesting may also occur in clay-loam soils (Ernst and Lovich 2009). They typically select nest sites in sunlit areas (with little cover) within sight of water (COSEWIC 2002; Reference removed). Females have shown general nest-site fidelity. Reference removed states that females will use the same general nesting area each year, although not necessarily the same beach or gravel bar. Along a suitable portion of a river, Spiny Softshells may alternate nesting locations within a 2 km stretch. If nesting habitat is limited, several females may use the same nesting site (Ernst and Lovich 2009; Équipe de rétablissement des tortues du Quebec unpublished data).

Distance between aquatic habitat and nesting sites may vary greatly depending on site availability and local conditions. Nesting usually occurs close to water, with reported mean nest distances ranging from 3 to 38 m (Graham and Graham 1997; Steen et al. 2012). However, some females may move up to 100 m inland to nest (Ernst and Lovich 2009). In Ontario, nests are typically laid within 50 m of the shoreline (Bolton and Brooks 2006, 2007; Gillingwater pers. comm. 2015), while in Quebec, nests are laid much closer to water, with all known nest sites occurring in the floodplain (i.e., areas which are periodically flooded). In the single known, well-studied Quebec population, reported distances between nest and the nearest watercourse from 2009-2011 ranged from 1.1 to 4.4 m (n = 22) (Galois et al. 2010, 2011, 2012), and all nests observed in Quebec since 2009 have been found within 10 m of a watercourse (n = 59) (Galois et al. 2010, 2011, 2012; Paré pers. comm. 2015). It is likely that females do not move further from the water due to the topography and substrate of the nesting site. The banks of the waterways in the area are steep which preclude the turtles from seeing the water, which is an important factor for the species. As well, the nesting site substrate is composed of sand, gravel and cobble while the adjacent terrestrial habitat is composed of poor nesting substrate (e.g., clay soil) which would deter females from making the effort to move further from the water (Guigere pers. comm. 2015). Reference removed reported that a female Spiny Softshell in Quebec moved 7 km upstream (in water) for nesting.

Hatchlings generally emerge in late summer, after an incubation of 60 to 75 days (Fletcher 2002; COSEWIC 2014).

Turtles regulate their body temperature using the surrounding environment; they are able to modify or maintain their temperature by varying their exposure to sun (known as basking), shade and water (Bulté and Blouin-Demers 2010). Aquatic thermoregulation sites may include floating or protruding objects (e.g., rocks, logs, floating vegetation, or floating debris), and the species may sometimes thermoregulate while floating at the water surface (Reference removed; Ernst and Lovich 2009). In addition to using basking sites within the aquatic habitat, individuals may bask along riverbanks in open areas near the water, such as on mud or sandbanks (Reference removed; Ernst and Lovich 2009). Spiny Softshells have also been observed thermoregulating while buried in soft substrate (muddy/sandy) in shallow water (Gillingwater unpub. data; COSEWIC 2002).

Thermoregulating habitats differ between sexes: males are often found in mud flats under 2 to 5 cm of saturated black muck, while females are usually found in the open, often on Muskrat houses (Dobbyn and Smith 2005). Dobbyn and Smith (2005) speculate that this difference may be due to the larger size of females, which probably have a harder time burying themselves in mud.

Spiny Softshells are primarily carnivorous (Ernst and Lovich 2009) feeding primarily on crayfish, insects, and fish but may also forage on earthworms, snails, clams, isopods, cladocerans, amphibians and small snakes (Ernst and Lovich 2009). Important food items are available in lakes and in river reaches containing riffleFootnote19 areas, adjoining creeks, inlets, muddy/sandy areas and bays, and within vegetative debris and aquatic plants (COSEWIC 2014). The species may forage in waters up to 2.5 to 3 m deep (example removed) (MNRF 2014a, unpublished data).

Spiny Softshells regularly move between different aquatic habitat types to access recurrently or seasonally required resources (e.g. nesting sites, overwintering sites, food sources) (Reference removed). As a result, it is important that the different habitats they use are linked, or in reasonable proximity to one another so that individuals can move between them with ease to carry out life cycle processes. Spiny Softshells are good swimmers capable of frequent and long movements (Vermont Fish and Wildlife 2009).

Movements of more than 30 km have been observed along a river in Ontario (Reference removed) and in a lake-river system in Quebec (Reference removed). The average linear home range length observed for Spiny Softshells in Quebec is 10.8 km (Quebec Spiny Softshell Turtle Recovery team unpublished data). Some data suggest that there is a significant difference in Spiny Softshell mobility, and the chronology of movements, between the sexes; females seem to travel longer distances and are also more active than males (Reference removed). The mean annual home range area for Spiny Softshells in Quebec was 32.06 ± 30.70 km² for females (range of 1.77 to 110.28 km²) and 2.75 ± 2.99 km² for males (range of 0.44 to 6.92 km²) (Reference removed). Reference removed also found that individuals made extensive use of small areas of specific habitat types for such things as nesting and overwintering and used the rest of their home range mainly to move between these areas. It is thought that the large home ranges are due to the distance between suitable overwintering and nesting sites. Home range size for the Spiny Softshell in Ontario is unknown, although studies have shown movements of up to 30 km (References removed). This is an important knowledge gap that needs to be addressed in order to refine recovery actions.

Plummer et al. (1997) studied home ranges of Spiny Softshells in a small stream (Gin Creek) in Arkansas, USA. They calculated an annual home range area of 0.88 ha for males and 0.7 ha for females and the slightly larger home range for males was not statistically significant. They observed daily movements of up to 1,920 m and stated that the movement pattern of Spiny Softshells in a small stream was characterized by brief but long distance movements out of their home ranges, followed by their immediate return. Comparing their results with results of other studies, the authors support the notion that home range size is influenced by the size of the waterbody and by the availability of habitat features to support their different life cycle activities, such as nesting and overwintering (Schubauer et al. 1990; MNRF 2014b).

Most turtles, including Spiny Softshell, have certain common life history traits that can limit their ability to adapt to high levels of disturbance and that help explain their susceptibility to population declines (Congdon et al. 1993; Gibbons et al. 2000; Turtle Conservation Fund 2002). They have a reproductive strategy that depends on high adult survival rates to counterbalance the low recruitment rates because of:

  1. Late sexual maturity (around 12 years for females from northern populations, and life span over 50 years);
  2. high rate of natural predation on eggs and juveniles under the age of two; and,
  3. dependence on environmental conditions for the internal development of eggs
    and external incubation of eggs without parental care.

As a consequence of these life history traits, turtle populations including Spiny Softshells, cannot adjust to an increase in adult mortality rates. Long-term studies indicate that high survival rates of adults (particularly adult females) are critical to the maintenance of turtle populations. Even a 2 to 3% increase in the annual adult mortality rate over natural mortality rates could result in population declines (Congdon et al. 1993, 1994; Cunnington and Brooks 1996).

The climatic ranges within which the Spiny Softshell can survive limit its range in northern areas (Hutchinson et al. 1966; McKenney et al. 1998). Climate plays a vital role in recruitment, as Spiny Softshells rely on the external environment for incubation of eggs. Incubation time constitutes a major limitation for northern turtle populations (Brooks 2007), as the short northern summer typically makes it possible to produce only one clutch per year and reduces the likelihood that a nest will hatch in any given year. Although double clutching is known to occur in some years in Canada (COSEWIC 2014), recruitment rates can vary from one year to the next depending on weather conditions, particularly during the summer.

The Canadian population of the Spiny Softshell is at the northern limit of the species' range (Seburn and Seburn 2000). Because fewer heat-unitsFootnote21 are available the further north the species occurs, the shorter nesting and development period in Canada constitutes a limiting factor for this species (Brooks 2007; COSEWIC 2014). Another important limiting factor could also be the availability of suitable hibernation sites. The species is relatively intolerant of anoxic conditions during winter and ice cover lasts longer in the north (Ultsch and Cochran 1994).

Turtles play an important role in Aboriginal spiritual beliefs and ceremonies. To the First Nations peoples, the turtle is a teacher, possessing a great wealth of knowledge. It plays an integral role in the Creation story, by allowing the Earth to be formed on its back. For this reason, most First Nations people traditionally call North America "Turtle Island" (Bell et al. 2010).

Threats to the Spiny Softshell may vary regionally and locally across its distribution within Canada. However, the information presented in Table 1 is an overall assessment of threats to the Spiny Softshell in Canada. Where information is known on the significance of threat at the local scale, additional information is provided in the threat description below Table 1.

The threats presented in Table 1 are in overall decreasing order of concern within each threat category.

Table 1: Threat Assessment Table
Threat Information Threat Level of ConcernFootnoteb Extent Occurrence Frequency SeverityFootnotec Causal CertaintyFootnoted
Habitat Loss, Degradation, or Fragmentation Shoreline and riverine habitat development/ alteration High Widespread Historic/ Current Recurrent High High
Habitat Loss, Degradation, or Fragmentation Water control structures Medium Widespread Historic/ Current Recurrent Medium High
Habitat Loss, Degradation, or Fragmentation Livestock farming and ranching Medium Localized Current Seasonal High High
Accidental Mortality Boating mortality High Widespread Current Seasonal High High
Accidental Mortality Fishing by-catch Medium Widespread Current Seasonal Medium Medium
Changes in Ecological Dynamics or Natural Processes Human-subsidized predators High/
Medium
Localized Current Seasonal High High
Biological Resource Use Illegal collection High Widespread Current Seasonal Medium High
Exotic, Invasive, or Introduced Species Exotic and invasive species High/
Low
Localized Current/
Anticipated
Continuous Unknown/
Low
Medium/
Low
Disturbance and Harm Disturbance from human activities Medium Localized Current Seasonal Unknown Medium
Pollution Contamination and nutrient loading Medium/
Low
Localized Current Continuous/
Seasonal
Unknown Medium/
Low
Climate and Natural Disasters Climate change Low Widespread Anticipated Continuous Unknown Low

This section highlights the threats outlined in Table 1, emphasizes key points, and provides additional information. Although threats are listed individually, an important concern is the long-term cumulative effect of a variety of threats posed on local Spiny Softshell populations. It should be noted that some of these threats apply only during the active season since they lead to direct mortality, removal, mutilation, or illegal collection of individuals. Among mechanisms through which threats can impact Spiny Softshell populations, isolation through habitat loss and fragmentation is of particular concern, as it leads to a breakdown of metapopulation dynamics and limits possibility of rescue effectFootnote22. The threats are presented in decreasing order of level of concern.

Habitat loss and degradation are threats of high concern to Spiny Softshell populations. Their riparianFootnote23 and aquatic habitats have been and are being degraded by shoreline alteration; construction and maintenance of roads, bridges and dams; urbanization; intensive agricultural activity; amongst others (COSEWIC 2014). Illegal development such as stream diversion, pond excavation and boat dock installation, are also of concern, especially when at or near nesting or thermoregulation habitats.

Shoreline habitat degradation reduces the availability of suitable nesting and basking sites (Reference removed). Such habitat degradation can also reduce the number of overwintering sites and increase the number of predators (e.g., Ernst and Lovich 2009). In many areas, shorelines are reinforced to prevent erosion, often using metal or concrete walls or rip rapFootnote24. (Reference removed, Reference removed). This hardening of the shoreline prevents the Spiny Softshell from carrying out critical life functions (such as nesting, foraging, and basking) along large stretches of formerly available habitat, which will ultimately lead to a decline in population (Reference removed). For example, natural shorelines possess more emergent and aquatic vegetation than developed shorelines (Radomski and Goeman 2001), and these habitat configurations are crucial to Spiny Softshell throughout the active season (Reference removed). Construction activities associated with this type of development can also lead to direct turtle deaths.

Dredging may affect turtles directly or indirectly. Individuals may be extracted from overwintering sites and/or killed by heavy equipment during dredging. Overwintering sites might also be destroyed by dredging. Alterations in water quality (due to sediment loading in rivers) and changes in river morphology could potentially alter prey composition and availability (Bodie 2001).

The loss of habitat to development and agriculture is significant to the Spiny Softshell (COSEWIC 2014), and some of it is irreversible at this point. Infilling or draining of wetlands for such purposes effectively eliminates turtle habitat such as basking and foraging sites (Reference removed).

Some techniques commonly used for the management of streams and riparian zones, such as reduction of snags/log jams, riparian draining, channelization, reduction of sandbars and beaches, and impoundment, may cause negative effects on turtles (Bodie 2001). Spiny Softshells are particularly affected by reduction of sandbars and beaches, which reduce the availability of suitable nesting sites.

While in the water, turtles are at risk of being injured or killed by collisions with boats and/or propellers (Burger and Garber 1995; Smith et al. 2006; Reference removed; Bulté et al. 2010; Bennett et al. 2014). Turtle deaths due to impact with motorboats, even in water bodies with low to moderate (versus high) boat traffic, may lead to a decline in the local freshwater turtle population (Bulté et al. 2010). While research evaluating injury and mortality rates from motorboat strikes is not available for the Spiny Softshell in Ontario, research has been done on this threat for other aquatic turtles in Ontario. A study of the impact of recreational motor boating on populations of Northern Map Turtle in two Ontario locations found that 8.3% and 3.8% of individuals at the two locations had propeller injuries; if over 10% of these collisions result in turtle death, rapid population extirpation is possible (Bulté et al. 2010). Given the fact that Spiny Softshell and Northern Map Turtles share similar aquatic habits, this suggests that propeller strikes are likely a threat to Spiny Softshells in their Canadian range. In one Quebec location, mortality due to recreation-related accidents such as boat-propeller injuries is a concern for a population of Spiny Softshells, when added to habitat alteration and other threats the population faces (Reference removed).

Given that most nesting female Spiny Softshells in Canada occur in large waterbodies with heavy motorized boat traffic, this increasing threat is especially significant to the species, with much of the total population being affected by recreational boating (COSEWIC 2014). Also, Spiny Softshells are more vulnerable to this threat because they regularly bask just offshore by floating at the surface of the water and are at very high risk of boat collisions, compared to many other turtles that rarely or infrequently bask this way (e.g. Blanding's Turtles).

In many areas, the low density or absence of top predators and increased food availability from human sources (e.g. food handouts, garbage, crops) have led to a greater abundance of turtle predators than natural conditions would have historically supported (Mitchell and Klemens 2000). The main predators of the Spiny Softshell include Raccoon (Procyon lotor), Coyote (Canis latrans), Striped Skunk (Mephitis mephitis), and Red Fox (Vulpes vulpes) (Reference removed). Adult females are more likely to escape predation than males due to their larger size, speed, and more aggressive behaviour (Reference removed). Juvenile turtles are the most susceptible to predation and have many different predators including mammals, birds, other reptiles, amphibians, and fish (Reference removed). Spiny Softshell nests are often predated by Raccoons, Coyotes, and Red Fox (Ernst and Lovich 2009; Reference removed).

The abnormally high level of many predator populations can lead to unsustainable rates of predation on turtles (eggs, juveniles, adults). For instance, 100% predation rates on unprotected Spiny Softshell nests have been recorded in an Ontario Provincial Park (Reference removed; Reference removed). At three sites in Ontario (within a Provincial Park), the rate of egg survivorship to hatching was 85.4%, 70.8% and 30.9% for protected nests and 61% and 47.3% for natural nests at the two first locations, respectively (De Solla et al. 2003).

In Quebec, available information suggests that this threat may be of lesser concern to the local population. For example, no predators were detected during the monitoring of an important communal nesting site in the spring of 2014 (S. Giguère, pers. comm. 2015).

Methods to counteract elevated predation rates have been developed and used with varying degrees of success (Seburn 2007; Riley and Litzgus 2013). However, in many cases, it is impossible to implement these methods, such as predator exclusion devices over turtle nests, on the scale required to protect the population from this threat.

Worldwide, many turtle species are impacted by individual and large-scale systematic illegal collection for use as pets, food and traditional remedies (Thorbjarnarson et al. 2000; Bodie 2001; Reference removed; Moll and Moll 2004). The rate of export of freshwater turtles, for both pet and food trades is high in the U.S. (Mali et al. 2014). For example, between 1999 and 2014, around 700,000 individuals of Spiny Softshell were legally exported for commercial purposes, from which 13% were wild caught (U.S. Fish and Wildlife Service 2014). The Spiny Softshell was one of the common species in the United States export trade during 1989-1997 (Moll and Moll 2004). Large numbers of adults (mainly females) have been exported from the U.S. to specific markets since the late 1990s, as well as large quantities of hatchlings (Van Dijk 2013). Kopecký et al. (2013) analyzed the freshwater turtle pet-trade in the European Union: out of the 15 most marketedFootnote25 turtle species, the Spiny Softshell is ranked 8th, with an estimated 27,035 individuals imported from the United States during 2008-2012. The rate of illegal trade can be expected to also be high in Canada given the lucrative trade demand. Reptile species are more likely to be involved in the international pet trade if they are categorized as at risk than if they are not considered at risk (Bush et al. 2014), which is consistent with a general demand for rare wildlife (Courchamp et al. 2006).

In Canada, the collection, trade, and possession of Spiny Softshells is illegal under federal and provincial legislation, nevertheless, there are reports of poachers harvesting adult Spiny Softshells and their eggs for food in Ontario (Reference removed). In March 2013, a Toronto newspaper reported about a restaurant that had 31 Spiny Softshells in its freezers (The Star 2013). This type of activity may indicate a high demand for the species in the food trade.

Illegal collection of the Spiny Softshell may not directly cause mortality, but removes individuals from the population which, given the species' reproductive strategy (extreme longevity, low recruitment rates), may greatly reduce recruitment (COSEWIC 2014). The annual removal of even just a few adults from a local population can have a significant impact. The extent of illegal organized turtle harvest is poorly documented in Canada for the Spiny Softshell.

The introduction of invasive, exotic plants can alter the availability and quality of the Spiny Softshell habitats. In some areas, particularly around Lake Erie, Lake Huron, and Lake St. Clair, and along some major rivers, non-native Common Reed (Phragmites australis) has invaded wetlands, lakes, and rivers, forming a monocultureFootnote26 that has altered conditions of foraging habitat and nesting habitat, forcing female Spiny Softshells to use other egg laying sites (Bolton and Brooks 2010; Gillingwater pers. comm. 2012). Invasive plants tend to form dense encroaching stands that progressively reduce the available area of nesting sites each year (COSEWIC 2014). The expansion of road networks also facilitates the spread of invasive plant species, especially in southern Ontario (Gelbard and Belnap 2003).

Turtles nest in open, unshaded areas receiving adequate solar heat. In a study conducted along Lake Erie, Ontario, it was found that non-native Common Reed had reduced the amount of suitable nesting habitat for many turtle species because growth of the plant altered the microenvironment (particularly significant temperature reductions in nests) of turtle nests during the incubation period (Bolton and Brooks 2010). The loss of suitable nesting habitat for turtle species due to invasive plants including non-native Common Reed, Japanese Hops (Humulus japonicas), and Purple Loosestrife (Lythrum salicaria) have also been observed at many other locations throughout southern Ontario (Gillingwater pers. comm. 2012). Reed Mannagrass (Glyceria maxima) might also have an impact on Spiny Softshell.

Water control structures can impede the movement of turtles in aquatic environments, thereby increasing habitat fragmentation and preventing access to suitable habitats (Bennett et al. 2010). This is of particular concern for highly aquatic turtle species, such as the Spiny Softshell, which frequently use aquatic habitat for movement, and for which water control structure construction potentially contributes to isolation of populations (Edmonds 2002; Bennett et al. 2010). Isolation of populations has the potential to compromise rescue effect in the medium term, which would lead to a higher likelihood of elimination of local populations (Stockwell et al. 2003; Marchand and Litvaitis 2004). In the long-term, a reduced ability for successful dispersal of individuals can result in loss of genetic variation (Gray 1995). Loss of genetic variation in small, isolated populations can in turn cause loss of population fitness and adaptability, and increase the risk of extinction in the wake of a catastrophic or epidemicFootnote27 event (Frankham 1995; Reed and Frankham 2003). However, some Spiny Softshell individuals have been found to cross through lock structures (Gillingwater pers. comm. 2012), suggesting that these structures do not always form an imperviousFootnote28 barrier.

Some water control operations also impact turtle habitat by altering upstream and downstream water levels, thereby impacting depth of overwintering sites and availability of nesting, basking and foraging habitats. For example, the use of dams for flood control may negatively impact the species by reducing the scouring effects of peak flows on the shoreline (removal of vegetation on shorelines), and thus the amount of exposed soil that is suitable for nesting (Seburn 2007). Water control can also affect the downstream flow regime that alters sediment transport, thermal properties, water levels, and oxygen concentrations, all of which can affect the habitat suitability, especially during hibernation.

Fluctuation in water levels caused by water control operations can also cause direct mortality. For example, increased water levels during the spring and summer may drown nests (killing embryos), since nests are usually dug close to water and decreased water levels during the winter may lead to freezing (and death) of overwintering turtles (Ewert 1979). Flooding events aggravated by flood control structures along two major river systems have been increasingly implicated in complete loss of clutches laid in a season (COSEWIC 2014; Équipe de rétablissement de la tortue- molle à épines au Québec 2014). From 2008 to 2011, storm events resulted in all nest sites (except one, which was trampled by cattle) to remain submerged during embryo development, drowning all embryos (Ewert 1979; COSEWIC 2014).

Livestock farming and ranching are a concern in some locations where Spiny Softshells are known to occur. The presence of the livestock on or near the shoreline degrades nesting habitat through soil compaction and shoreline erosion; also, trampling might crush nests and individuals. According to COSEWIC (2014), the main known Spiny Softshell nesting sites on two major river systems are affected by this threat.

By-catch in commercial and recreational freshwater fishing is an under-appreciated but real threat to turtles (Raby et al. 2011). Turtles can be accidentally hooked on recreational fishing lines or caught in commercial or scientific fish traps or nets and drown. Because nets are often not checked for several days, the rate of drowning among turtles is high. Mortality rates are sufficient to cause extirpation of local turtle populations (Midwood et al. 2014). Those turtles that survive without drowning in nets can show signs of harm that puts them at risk of later mortality (Stoot et al. 2013).

Studies conducted in eastern Ontario and on the Mississippi River (U.S.) found that passive fishing techniques (e.g.: Fyke nets) can result in significant by-catch of turtles (e.g.: Reference removed; Carrière 2007; Larocque et al. 2012a). For example, Larocque et al. (2012b) found that within non-fish by-catch, at least 93% consisted of four species of turtle. Severe mortality (33%) of turtles has also been documented in nets set in Newboro Lake (Larocque et al. 2012c). Even when care is taken to ensure that a portion of the trap remains above water, turtles tend to travel to the last compartment, which is anchored to the bottom and therefore may be completely submerged (Thompson, pers. comm. in Seburn 2007).

In addition to the risk of by-catch in commercial fisheries' nets, turtles also risk injury and mortality from ingestion of recreational anglers' hooks, as turtles that get caught in fishing lines are often released by cutting the line, the hook remains in the turtle (Reference removed; Gillingwater 2008). The hook and nylon line can lead to serious lacerations in the digestive tract and lead weights can cause poisoning (Borkowski 1997). In 2005 alone, 3 Spiny Softshells were found with fishing line in their throats in southern Ontario (Gillingwater 2008). A study in Tennessee found that 4% of male and 6% of female Spiny Softshells had ingested fishing hooks (Steen et al. 2014).

Human activity can affect Spiny Softshells in many ways. Because they are so wary, simply approaching basking turtles can cause them to leave their basking sites and return to the water. The resulting heat loss, should the disturbance become repetitive, can delay the development of eggs in females, and affect other life cycle activities in both sexes and in all age classes (e.g.: food metabolism, spring emergence) (Bulté and Blouin-Demers 2010). Moreover, the presence of humans and/or boats can delay or interrupt nesting; and females may abandon their nest, making them more subject to predation (Horne et al. 2003; Moore and Seigel 2006; References removed). Repeated disturbance at nesting sites may also force females to use lower quality nesting sites (Moore and Seigel 2006), which in turn can slow incubation and reduce the hatching rate of the eggs (Horne et al. 2003). Species that spend much of their time in larger water bodies, particularly Spiny Softshells, may be more susceptible to disturbance or harm because recreational boating, jet skis and other water sports often occur in the Spiny Softshell's Canadian range. This species has also been found to avoid nesting in locations with evidence of human presence (References removed). Recreation on nesting beaches (e.g., use of off-road vehicles) can also lead to trampling of nests or hatchlings (Reference removed). Translocation of turtles (e.g. individuals collecting turtles to look at and returning them to the wild in a location other than where the individuals were captured) from one water body to another by humans may lead to increased stress and/or threats (e.g. road networks) when the turtle attempts to return to its area of origin or find habitats to meet its life cycle activities (e.g.: for foraging or overwintering) (Gillingwater pers. comm. 2012).

The Spiny Softshell may be subject to deliberate harassment and persecution by humans. This includes, but is not limited to, throwing rocks at turtles, shooting them with firearms, and intentionally driving over them (e.g.: Horne et al. 2003; Ashley et al. 2007; Reference removed). Observers have also witnessed the deliberate destruction of eggs (Horne et al. 2003; Gillingwater 2008).

Aquatic habitat of the Spiny Softshell can be impacted by the degradation of water quality caused by the runoff of contaminated water from agricultural (nutrients and pesticides) and industrial zones (industrial waste), roads (e.g., de-icing salt), and urban areas (e.g., heavy metals) (Mitchell and Klemens 2000; Bishop et al. 2010). Spiny Softshells could be vulnerable to contaminant accumulation, although the long-term impact is poorly understood. Individuals absorb contaminants in the environment through various physiological processes (e.g. feeding, breathing, absorption through tissues or membranes such as eggshells (Bishop et al. 1998)). Spiny Softshells are more likely to be affected by contaminants than other turtle species because of their diet and location of their habitats (St. Lawrence and Great Lakes drainage basins).

Recent studies indicate that there is little effect of reliance on benthic food chain on mercury accumulation in Painted and Musk Turtles (Reference removed) and that concentration of mercury in blood and scutes does not affect parasitism level in Painted Turtles (Slevan-Tremblay 2013). However, mercury exposure could be detrimental to the immune system by reducing the number of lymphocytes. Similar, if not increased, effects might be impacting Spiny Softshells. Two studies, undertaken in the Great Lakes basin, detected several industrial-based contaminants in Snapping Turtle eggs. It was also noted that abnormal embryo development increased with exposure to polychlorinated aromatic hydrocarbons (Bishop et al. 1998; Van Meter et al. 2006). Although these studies focused on other species, the potential for similar effects on the Spiny Softshell exists as they share similar habitats and behaviours.

Inputs of sediments and organic matter through erosion and runoff (e.g., from farm fields) can also alter water quality and habitat structure and threaten local populations of the Spiny Softshell (Reference removed). Declines and/or extirpation of turtle populations have been attributed to siltation (the continual deposit of silt) in several studies (Bodie 2001), such as the decline and possible extirpation of Smooth Softshell (Apalone mutica) and Illinois Mud Turtles (Kinosternon flavescens ssp. spooneri) in Illinois (Moll 1980), declines of Map Turtles (Graptemys geographica) and Softshells (Apalone sp.) in Missouri (Johnson 1992) as well as in Kansas (Plummer 1976). Inputs of organic matter and nutrients can increase water turbidity and reduce dissolved oxygen content, which could affect respiration in winter. To what extent such conditions could affect the Spiny Softshell is not known.

The augmentation of nutrient loads associated with human activity can lead to blue-green algal blooms in waters frequented by turtles (Carpenter et al. 1998), and this can threaten turtles through ingestion of toxins from the algae. In addition, nutrient loading can lead to increased oxygen consumption by bacteria, which, in turn, can result in periods of low dissolved oxygen levels (hypoxia) or even a total absence of oxygen (anoxia) during winter. Spiny Softshells are anoxia-intolerant (Reese et al. 2003); therefore, if they hibernate in areas where oxygen levels are decreased, they could be at risk of dying during hibernation due to hypoxia or anoxia.

Groundwater contamination related to discharge at overwintering sites is also of concern. Studies to determine the extent of the effects of nutrient loading on Spiny Softshells are needed to help identify the level of risk to a population.

Climate is the main limiting factor of the distribution of turtles in the northern part of their range. Given the effect of climate on recruitment rates, it seems likely that global climate change will have an impact on turtle populations, although the overall nature and extent of the impact is unclear. An increase in the annual average temperature in Ontario of 2.5 to 3.7°C by 2050 (compared to 1961-1990) is expected, along with changes in seasonal precipitation patterns (Expert Panel on Climate Change Adaptation 2009).

Hydrological effects could be marked by lower water levels during summer (Lemmen et al. 2008), and these lower levels could in turn increase the availability of nesting sites. However, in the absence of increased precipitation, higher temperatures and increased evaporation could lead to low water runoff (Expert Panel on Climate Change Adaptation 2009) and dry out wetlands that were once permanent. Decreasing water levels in the Great Lakes may result in significant loss of coastal wetland habitats utilized by the Spiny Softshell Turtle. As well, lower water depth in Great Lakes wetlands containing overwintering sites may result in increased mortality of hibernating turtles.

Hydrological effects could also be marked by an increase of extreme rainfall events, which would cause more flooding of eggs on the shoreline. One nesting site monitored regularly in Quebec is already regularly flooded. If the frequency and intensity of extreme rainfall events increase in the future as predicted (Expert Panel on Climate Change Adaptation 2009), there is a risk that the nesting site will be flooded even more often. That would further reduce hatching success and impact the recruitment in the population (Équipe de rétablissement de la tortue- molle à épines au Québec 2014).

The long-term population and distribution objective (i.e., 50 years) is:

To work towards achieving the long term population and distribution objective, the following medium term sub-objective (i.e., 10 to 15 years) has been identified:

The total abundance and complete distribution of the Spiny Softshell in Canada is currently unknown and, in many cases, information on local populations consists of only presence/absence data. Preliminary data suggest populations are declining throughout the Canadian range, and that the estimated number of mature individuals in Canada is between 600 to 1,500 (COSEWIC 2014). The main objective of this recovery strategy is to stop the population decline by stabilizing the current Canadian population and maintaining or increasing local populations to self-sustaining levels. Some examples of local populations where it may be necessary to work towards an increase in the abundance include: those that have data showing a clear population decline, where suitable habitat is being lost/degraded, and/or where threats are documented to be high and negatively affecting populations. Examples of local Spiny Softshell populations where it may be feasible to increase abundance in Canada may include populations where: recruitment is extremely low, threats are evident and not irreversible, and proven recovery techniques can mitigate the threats (and threat mitigation measures may be put in place).

In order to understand the complete distribution and abundance of this species, it is necessary to understand age class distribution and habitat use at each life stage, much of which is poorly understood in Canada. As a result, it is not possible to set a quantitative population and distribution objective for this species. However, the maintenance of the current population will help ensure persistence of existing local populations until additional information is obtained. This long-lived species has specific ecological requirements, complex life cycle needs, and a limited ability to compensate for the loss of individuals through reproduction or through recruitment from adjacent populations. As a result, broad strategies and general approaches, undertaken on several fronts and over large regions, will be required to achieve this population and distribution objective. These approaches and strategies include legislative and administrative tools; reduction in individual mortality; protection, management, and restoration of habitat; improved recruitment; communication, outreach, and stewardship; surveys and monitoring; and research.

Sufficient suitable habitat and habitat linkages (movement corridors) are critical to ensuring local populations have the necessary elements required for survival and recovery. Without movement corridors, individuals may not be able to access different habitats within their home range to complete necessary life cycle activities (e.g., nesting, overwintering) or to migrate to neighbouring populations, which supports rescue effect and gene flow. The broad strategies along with the identification of critical habitat will help ensure such habitat is maintained.

At the national scale, the Canadian Herpetology Society (CHS) is the main non-profit organization devoted to the conservation of amphibians and reptiles, including turtles, and conducts the following activities: scientific investigations, public education programs and community projects, compilation and analysis of historical data and the undertaking of projects that support conservation or habitat restoration.

Environment Canada has been funding projects related to turtle conservation throughout Quebec and Ontario through the Habitat Stewardship Program (HSP) and Aboriginal Fund for Species at Risk (AFSAR) since 2001 and the Interdepartmental Recovery Fund (IRF) since 2004. Projects have included activities such as: undertaking targeted surveys for the species; identifying important habitat of local populations; studying the severity of and/or mitigating threats; soliciting observations/ encouraging public reporting of sightings; and educating landowners and/or the public on species identification, threats, and stewardship options.

An Ontario Multi-Species Turtles at Risk Recovery Team was established in the early 2000s by a group of people interested in turtle recovery. This group focused on 6 turtle species at risk: Blanding's Turtle (Emydoidea blandingii); Eastern Musk Turtle (Sternotherus odoratus); Northern Map Turtle (Graptemys geographica), Spiny Softshell (Apalone spinifera); Spotted Turtle (Clemmys guttata); and Wood Turtle (Glyptemys insculpta). This group has coordinated and initiated a number of recovery efforts including conducting educational and outreach programs on reptiles and various management initiatives such as nest protection projects and nest site rehabilitation projects (Seburn 2007).

The Ministry of Natural Resources and Forestry (MNRF) has funded numerous turtle conservation and stewardship projects across Ontario through the Ontario Species at Risk Stewardship Fund and other provincial funding programs.

Since 2009, Ontario Nature has been coordinating the development of a new Ontario Reptile and Amphibian Atlas (www.ontarionature.org/atlas) and is working with the Natural Heritage Information Centre (NHIC) and other organizations. By soliciting occurrence records from the public, researchers, government and non-government organizations, this project is improving our knowledge of the distribution and status of reptiles and amphibians, including the Spiny Softshell, in Ontario (Ontario Nature 2012; Crowley pers. comm. 2012).

There have been several large-scale inventory, survey, or monitoring programs targeting turtles, including Spiny Softshell, in Ontario (e.g., Ontario Turtle Tally (Toronto Zoo), Kawartha Turtle Watch (Trent University), survey or monitoring initiatives from Nature Conservancy of Canada) as well as some local survey and monitoring programs for Spiny Softshell (e.g., by the Upper Thames River Conservation Authority). In addition, research has been conducted on Spiny Softshell in Ontario to fill knowledge gaps, including studies on home ranges, population sizes, predation, demographics, habitat use, and ecology of nesting have been conducted in various parts of Ontario (e.g., Daigle and St-Hilaire 2000; Daigle et al. 2002b; De Solla et al. 2003; Galois et al. 2002, 2005, 2006, 2007, 2008, 2010, 2011, 2012; Bolton and Brooks 2006, 2007, 2010; Galois and Ouellet 2007; Rioux and Desroches 2007).

There are many organizations and agencies that offer outreach/educational programs about turtle species at risk to school groups, First Nations, and the general public (e.g., Scales Nature Park, Reptiles at Risk on the Road Project, Georgian Bay Biosphere Reserve (and previously the Georgian Bay Reptile Awareness Program), Ontario Nature, MNRF, Ontario Parks, Upper Thames River Conservation Authority). In addition, the National Parks and Historic Canals provide opportunities to their visitors to learn about the Spiny Softshell and other at risk turtles across Ontario. The Toronto Zoo Adopt-a-Pond Programme (www.torontozoo.com/adoptapond) is one of several projects that have developed turtle conservation curricula for schools, while the Toronto Zoo Turtle Island Conservation program (www.torontozoo.com/conservation/tic.asp) promotes turtle conservation and awareness among First Nation and non-aboriginal groups. Turtle SHELL (Safety, Habitat, Education and Long Life) has prepared booklets and installed turtle crossing signs. In 2004, the Upper Thames River Conservation Authority produced the Stewardship of the Spiny Softshell Turtle, a guide targeting landowners with property next to turtle habitat.

Various habitat restoration, threat mitigation, and other conservation initiatives have been undertaken in Ontario to benefit the Spiny Softshell. For example, the Upper Thames River Conservation Authority has carried out extensive recovery and stewardship work for the Spiny Softshell, including locating and protecting nests. The Kawartha Turtle Trauma Centre (KTTC) in Peterborough rehabilitates wild turtles that were injured in the hopes of recovering and releasing them.

Many projects are being carried out as a requirement under the Ontario Endangered Species Act, 2007 that are directly benefitting turtle populations. For example, turtle fencing and ecopassages are now incorporated into the design of most new highways whenever they bisect at-risk turtle habitat (Ontario Road Ecology Group 2010; OMNR 2013).

Turtle recovery teams were established by the Province of Quebec as early as 1996 (Équipe de rétablissement de la tortue-molle à épines [Spiny Softshell Recovery Team]) and have evolved in scope from single to five species (Équipe de rétablissement de cinq espèces de tortues du Québec [Recovery Team for Five Turtle Species in Quebec]). An implementation team is also in place to work on implementing recovery actions set forth in a recovery plan for this species (Groupe de mise en oeuvre pour le rétablissement de la tortue-molle à épines [Implementation team for the recovery of the Spiny Softshell]).

An amphibian and reptile database (Atlas des Amphibiens et des Reptiles du Québec) exists and is managed by the Société d'Histoire Naturelle de la Vallée du Saint-Laurent (SHNVSL). The Atlas des Amphibiens et des Reptiles du Québec is a source database of the Centre de données sur le patrimoine naturel du Québec (CDPNQ), which is held by MFFP for the data on threatened or vulnerable faunal species, including the Spiny Softshell. CDPNQ is currently mapping the element occurrences for the Spiny Softshell in Quebec.

Since 1996, inventories across the historical distribution (e.g. Reference removed, Reference removed, Reference removed, Reference removed, Reference removed), research on the ecology (Reference removed, Reference removed), habitat use and movements (Reference removed, Reference removed, Reference removed, Reference removed, Reference removed), genetics (Reference removed), threats such as boat mortality and injuries (Reference removed), and potential alteration of overwintering habitat (Reference removed) have been conducted in the province.

The Implementation Team for the Recovery of Spiny Softshell also produced protection plans for the main habitats used by the species in Quebec. In association with these plans, several land acquisition projects have been implemented to protect habitats used by the Spiny Softshell in Quebec. Over 270 ha of habitat have been protected by partners such as the Nature Conservancy Canada (Reference removed). Also, several stewardship and communication initiatives have been put forward to protect Spiny Softshells and their habitat (signs and navigational buoys indicating the presence of protection zones, distribution of brochures and pamphlets to the public, presentations in schools, television and newspaper reports, and development of a web page). A nest monitoring and protection program has also been ongoing since 2008. Through annual nesting surveys, a total of 59 nests have been located to date, which have been protected through relocation and predation mitigation measures (e.g., fencing) (Galois et al. 2010, 2011, 2012). To increase the nesting success in Quebec, a project of artificial egg incubation, followed by the release of hatchlings, has been implemented by the Implementation Team for the Recovery of Spiny Softshell in 2009 (Reference removed). Moreover, a communication strategy is also currently in development to promote the Spiny Softshell as a regional animal emblem of the protection of biodiversity and environment. All these actions have been conducted by government organizations, zoological institutions, conservation organizations and watershed organizations. One of the main nesting sites used by Spiny Softshells in Quebec has been closely monitored since 2003 by volunteers.

To work towards achieving the population and distribution objectives, seven broad strategies for recovery have been established. The broad strategies are:

  1. Use legislative and administrative tools to conserve Spiny Softshell individuals and habitat;
  2. Reduce individual mortality, injury, and illegal collection across the range of the Spiny Softshell in Canada;
  3. Protect, manage, and restore habitat across the range of the Spiny Softshell in Canada;
  4. Improve recruitment in locations where local Spiny Softshell populations are in decline or viability is deemed compromised;
  5. Conduct communication, outreach, and stewardship activities;
  6. Survey and monitor local Spiny Softshell populations, habitat, and threats; and
  7. Conduct research on population demographics, habitat characterization and
    use, and threats/threat mitigation to fill knowledge gaps.

Research and management approaches are recommended for each strategy (Table 2). Threats/limitations in the first column are numbered as follows for concise presentation:

  1. Shoreline and riverine habitat development;
  2. Boating mortality;
  3. Human-subsidized predators;
  4. Illegal collection;
  5. Exotic and invasive species;
  6. Water control structures;
  7. Livestock farming and ranching;
  8. Fishing by-catch;
  9. Disturbance from human activities;
  10. Contamination and nutrient loading; and
  11. Climate change.
Table 2. Recovery Planning Table
Threat or
Limitation
Broad Strategy for Recovery PriorityFootnotee General Description of Research and Management Approaches
1,4,6,7 Legislative and administrative tools to conserve Spiny Softshell individuals and habitat High
  • Enforce existing provincial and federal laws, regulations, policies, and prohibitions applicable to Spiny Softshell individuals and their habitat.
  • Promote the integration of approved BMPs into the policies and practices of responsible agencies, First Nations, jurisdictions, and industry.
2,3,4,7,8,9 Reduce individual mortality, injury, and illegal collection High
  • Continue to develop and implement mitigation techniques (e.g., BMPs and alternatives to traditional development) to reduce Spiny Softshell adult mortality and injury. Promote the implementation of approved BMPs, development alternatives, and mitigation techniques to the general public, First Nations, landowners, land managers, and industry, which address priority threats through stewardship, funding and other techniques.
  • Develop and implement a federal/provincial strategy to address collection.
1,3,5,6,7, 9,10 Protect, Manage or Restore Habitat High
  • Protect areas large enough to maintain viable populations and increase connectivity through stewardship, development of BMPs, and/or land conservation.
  • Assess habitat restoration needs at locations where habitat loss, degradation, and fragmentation are threatening local Spiny Softshell populations.
  • Identify, develop and implement restoration techniques at priority sites and monitor use by Spiny Softshell.
  • Determine disturbance threshold levels for activities that are likely to destroy critical habitat.
  • Continue to encourage stewardship activities, including financial support through available funding programs.
1-10 Improve recruitment in locations where Spiny Softshell is declining or viability is deemed compromised High

This strategy must be implemented concurrently with two aforementioned broad strategies: "Reduce Individual Mortality, Injury, and Illegal Collection" and "Protect, Manage or Restore Habitat"

  • Document recruitment needs to determine places where Spiny Softshell is declining or viability is deemed compromised.
  • Implement, evaluate, adapt and improve recruitment techniques in accordance with results obtained and Spiny Softshell ecology. An example of a priority recruitment technique is:
    • Developing a cost effective head-starting protocol/program (including nest monitoring, artificial incubation of eggs, and release of juveniles).
All Threats Communication, Outreach and Stewardship Medium
  • Develop and implement a communication and outreach strategy or continue to implement existing communication and outreach tools to help address threats to the Spiny Softshell.
  • Develop outreach/education material, with an emphasis on turtle harvest and trade, for groups most often associated with the use of this species. Produce and distribute these materials in the language of the target audience.
  • Encourage the transfer, use and archiving of information and tools, including Traditional Ecological Knowledge (TEK).
  • Improve and maintain cooperation among stakeholders (e.g., engage partners and promote collaborative work with multiple jurisdictions).
  • Promote and engage partners (e.g., academics, government, non-government organizations, First Nations) in research initiatives necessary to fill knowledge gaps.
All Threats Survey and Monitoring Medium
  • Prioritize sites with suitable habitat and historical or potential populations for surveying to determine if Spiny Softshells are present.
  • Develop and promote the appropriate use of standardized protocols for survey, monitoring, and databases (e.g., data collection, handling, marking).
  • Using standardized protocols, monitor extant populations and their habitat.
  • Encourage the submission of records for the Spiny Softshell to provincial herpetological atlases as well as the provincial Conservation Data Centre (CDC); validate the records when feasible.
All Threats Conduct research on population, habitat, and threats to fill knowledge gaps Medium
  • Conduct viability assessments, to determine the viability and dynamics of priority local populations.
  • Further characterize and define the habitats (e.g., nesting, feeding, and overwintering sites) used while carrying out various life cycle activities, particularly by hatchlings and juveniles.
  • Conduct research to evaluate the severity of known threats to populations and document frequency, extent, and causal certainty of threats.
  • Conduct intensive demographic and genetic studies in selected sites across the range to expand knowledge of population discreteness, size, age composition, and sex ratios.

Considering the Spiny Softshell's reproductive strategy (see section 3.4), maintaining the highest possible adult survival rate, especially for females, remains the primary need of the species to achieve recovery. Unfortunately, some biological traits of the Spiny Softshell (i.e., aquatic habits, basking by floating on the surface of the water, nesting in beaches) make it very sensitive to many human activities (e.g., water sports, boating, illegal collection, recreational activities at beaches) so it will be important that a proactive, integrated approach be taken to limit threats on adult Spiny Softshells.

Such approaches should focus primarily on where and when most of the adult mortality occurs. Habitat protection, management, and restoration are also key to recovery since such approaches contribute to maintaining, improving or creating suitable habitat, and also contributing to reducing adult mortality (i.e., reducing threat severity). Habitat protection and restoration should focus primarily on the aquatic zone and shorelines identified as critical habitat (see section 7) where most of the adults are found. These approaches must be implemented via an integrated approach engaging various groups (e.g., land owners, land users, land planners, First Nations, non-government organizations, and governments). In order to inform these groups, as well as begin to mitigate specific threats (e.g., boating mortality, and fishing by-catch), specific communication and outreach approaches need to be undertaken. Population surveys and monitoring are also necessary to help gather information on the species in order to help inform further conservation efforts. It is also necessary to fill the knowledge gaps which surround this species through a wide range of specific studies to help meet the population and distribution objectives. Along with approaches highlighted in Table 2 some knowledge gaps will also be filled via the Schedule of studies to identify critical habitat (Table 4).

Under SARA, critical habitat is defined as "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". 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.

This federal recovery strategy identifies critical habitat to the extent possible, based on the best available information for the Spiny Softshell as of December 2013. Critical habitat for the Spiny Softshell in Canada is identified for 14 populations (13 in Ontario and 1 in Quebec). It is recognized that the critical habitat identified may be insufficient to achieve the population and distribution objectives for the species. A schedule of studies has been included to outline the activities necessary to complete the identification of critical habitat (see section 7.2). Following the publication of this strategy additional critical habitat may be identified if new information supports the inclusion of areas beyond those currently identified. In some of the areas identified as critical habitat, the quality of the habitat will need to be improved to support recovery.

Critical habitat for the Spiny Softshell is based on three general criteria: habitat occupancy, habitat suitability, and habitat connectivity (between occupied areas), which are described below.

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

Habitat is considered occupied when:

A 40-year period has been chosen for the habitat occupancy criteria. It is appropriate given the long generation timeFootnote31 of the species (approximately 35 years) (COSEWIC 2014). This longevity trait makes the entire life span of the species difficult to study, by complicating the acquisition of an adequate amount of accurate life history data. The species is not well surveyed across its range. Application of a 40 year timeframe allows for the inclusion of local populations that likely persist but for which Spiny Softshell individuals may not have been detected in recent years. Habitat quality (indicated through multiple occupancy) is targeted by the habitat occupancy criteria to increase confidence that the habitat will contribute to the maintenance of a local Spiny Softshell population. This is appropriate as Spiny Softshells are highly visible (and not often misidentified), have relatively large home ranges and travel over large distances. Site fidelity is considered because Spiny Softshells are shown to exhibit high fidelity to their overwintering and nesting sites (see section 3.3).

Habitat occupancy is based on professional surveys and telemetry studies, nest site and overwintering site observations, observations of dead individuals, and incidental sightings of the Spiny Softshell. These observational data must be spatially precise (≤ 150 m) or provide enough detail to be associated to a specific suitable water feature (e.g., a river, lake or wetland) to be considered adequate to identify critical habitat. Because Spiny Softshell terrestrial movements are limited and they remain close to water (Graham and Graham 1997; Steen et al. 2012) it is usually possible to associate the observation with a corresponding suitable aquatic habitat feature. Critical habitat is not identified for locations where sufficient survey efforts following appropriate timing and methods have been carried out over multiple years but have failed to confirm Spiny Softshell persistence or habitat use and local extinction is presumed (e.g., Lake Ontario, Ottawa River).

The habitat occupancy criterion is applied after considerations for species dispersal (connectivity; see section 7.1.3); a location with a single occurrence record and that is within a dispersal distance from another location with a single occurrence record is identified as critical habitat (i.e., meets multiple occupancy criteria). This conservative approach is appropriate because most locations have not been intensively surveyed and there is a higher probability that more Spiny Softshells reside within proximity to known observations.

Habitat suitability refers to areas possessing a specific set of biophysical attributes that allow individuals to carry out essential life cycle activities (i.e., overwintering, mating, thermoregulation, nesting, foraging) as well as their movements. It is important that all required habitat areas are linked aquatically or semi-aquatically, and are in reasonable proximity to one another so that turtles can move between them with ease. Suitable habitat for the Spiny Softshell can therefore be described as a mosaic of aquatic and terrestrial habitats, in which specific biophysical attributes can be associated with essential life cycle activities. Within the area of suitable habitat, the biophysical attributes required by the Spiny Softshell will vary over space and time with the dynamic nature of ecosystems. In addition, particular biophysical attributes will be of greater importance to turtles at different points in time (e.g., during different life processes or at various times over the year). The biophysical attributes of suitable habitat for the Spiny Softshell are detailed in Table 3.

Given the lack of information on the amount of habitat that is required for the Spiny Softshell to complete its life cycle activities within a home range, the following approach has been used to identify an extent of suitable habitat for the Spiny Softshell. The description of suitable habitat reflects the fact that certain biophysical attributes do not need to be immediately adjacent to each other, as long they remain connected so that the individuals can move between them easily to meet all their biological needs and respond to or avoid disturbance. The distances determining the extent of suitable habitat are specific to the Spiny Softshell and based on the species' biological and behavioural requirements (see section 3.3).

Suitable habitat for the Spiny Softshell consists of overwintering, mating, thermoregulation, nesting, and foraging habitat, and habitat for movement (commuting and dispersal) between these areas and is defined as:

In addition, suitable habitat includes confirmed nesting sites wherever they occur (regardless of the distance to the nearest suitable aquatic feature), as defined by:

Spiny Softshells are highly aquatic, rarely leave the water, and most home ranges are associated to a permanent waterbody, watercourse, or wetland, although they may move to adjacent or connected streams, ponds and wetlands. Spiny Softshells have large home ranges and can make extensive movements in river habitats over the course of a year. The 10 km distance is selected based on the average linear home range length observed for Spiny Softshells in Quebec (10.8 km; Quebec Spiny Softshell Turtle Recovery team, unpublished data). This distance creates a 20 km site length, capturing the typical upstream and downstream movement distances observed for Spiny Softshell (females) in Canada (Reference removed; Fletcher 1996). The terrestrial distance captured along watercourses, waterbodies, and wetlands represents the maximum documented nesting distance in Ontario and Quebec (see section 3.3), and is set by province. The single Quebec population has been intensively surveyed since 1990. It is probable, given the climatic and other differences between the Ontario and Quebec subpopulations, that the turtles have, or will develop, different adaptations in the two areas (COSEWIC 2014). The terrestrial distance of 50 m in Ontario captures the maximum distance from a nest site to water at the majority of studied sites (References removed; Gillingwater pers. comm. 2015). In Quebec, the 10 m distance includes all nest sites reported to date (Galois et al. 2010, 2011, 2012; Paré pers. comm. 2015). Thus, these distances will capture the vast majority of potential nesting habitat, which is important considering few precise locations are known. These distances may also capture some adjacent or connected streams, ponds and wetland containing suitable habitat for Spiny Softshells as well as the habitat suitable for movement to access them.

Nest site availability and selection are likely to be especially important for local population persistence given the nature of known factors limiting the Spiny Softshell (e.g., long-term reproductive success strategy, climatic conditions - see section 3.4). Due to the rarity of these habitats, confirmed nesting sites are also identified as critical habitat wherever they occur, including the suitable terrestrial and aquatic habitat for Spiny Softshell within a 50 m radial distance around valid nesting observations. This area allows for nesting and staging and may also provide for a protective movement corridor for females and hatchlings to migrate from and to suitable aquatic habitat.

Table 3: Detailed biophysical attributes of suitable habitat for specific life cycle activities of the Spiny Softshell in Canada.
[Biophysical Attributes] Habitat Feature(s) Characteristics Life Cycle Activities Reference
Suitable Aquatic Habitat Biophysical Attributes Watercourses (e.g., rivers, streams), waterbodies (e.g., lakes, oxbows ponds), or wetlands (e.g., marsh)
  • adequate water depth (1-7 m); and
  • well-oxygenated; and
  • does not freeze to the bottom; and
  • soft substrates (e.g., sand, mud) or gravel bottom
Overwintering/
Mating
Reference removed; Fletcher (2002); References removed; Ernst and Lovich (2009)
Suitable Aquatic Habitat Biophysical Attributes Watercourses (e.g., rivers, streams), waterbodies (e.g., lakes, oxbows ponds), or wetlands (e.g., marsh)
  • aquatic habitats with water up to 7 m in depth; and
  • soft substrate such as sand or organic mud or gravel bottom; and
  • aquatic vegetation and/or vegetative debris; OR
  • floating/ emergent logs and/or rocks
Foraging/ Thermoregulation/ Reference removed; Reference removed; Reference removed; Ernst and Lovich (2009); Vermont Fish and Wildlife (2009)ont Fish and Wildlife (2009)
Suitable Aquatic Habitat Biophysical Attributes Watercourses (e.g., rivers, streams), waterbodies (e.g., lakes, oxbows ponds), or wetlands (e.g., marsh)
  • aquatic habitats with water up to 7 m in depth; and
  • permeable to Spiny Softshell (no barriers to movement)Footnotef
Commuting and dispersal movements Reference removed; Reference removed; Ernst and Lovich (2009); Vermont Fish and Wildlife (2009)
Suitable Terrestrial Habitat Biophysical Attributes Mostly unvegetated areas and/ or shoreline areas (e.g., sand bars, beaches, mud flats, rocky outcrops, islands).
  • sand, gravel, mud or clay substrate, receiving sunlight for large portions of the day
Nesting/ Thermoregulation COSEWIC (2002); Reference removed; Ernst and Lovich (2009); Vermont Fish and Wildlife (2009)
Suitable Terrestrial Habitat Biophysical Attributes Shoreline and terrestrial habitat (e.g., river banks, beaches)
  • permeable to Spiny Softshell (no barriers to movement)Footnoteg
Commuting/ Disperal movement Ernst and Lovich 2009

Maintaining the natural linkages between habitat types required by the Spiny Softshell is necessary for the persistence of local populations. Connectivity between local populations is required for immigration and emigration (movement into and out of local populations, respectively) which increases gene flow (maintaining genetic diversity within and between local populations), allows for rescue effect which will help support the local populations, and allows the species to react to environmental stressors (e.g., water level changes, pollution, anoxic environments) by moving to another location. In Canada, habitat loss and fragmentation is a threat to local Spiny Softshell populations (see 4.2; COSEWIC 2002). This threat can result in the loss of dispersal corridors, isolating local populations, and causing reductions in genetic diversity.

To allow short-distance movements needed to carry out Spiny Softshell life cycle activities (commuting habitat), connectivity is provided within the defined areas of suitable habitat (seasonal movements between habitats as required to complete an annual life cycle) (section 7.1.2, see also Table 3, Figure 3). To allow long-distance movements such as immigration or emigration (dispersal movement – see section 3.3), the habitat connectivity criterion connects local populations by their hydrological corridors based on the documented tendencies of the Spiny Softshell to undertake aquatic movements for dispersal (Reference removed; Reference removed; Reference removed).

The habitat connectivity criterion is defined as:

The 30 km distance is three times the average linear home-range length (10 km) and is based on the maximum separation distance between element occurrences recommended by NatureServe (2013) to maintain connectivity and reduce the probability of genetic isolation. The distance is also consistent with documented movements by the Spiny Softshell in one river in Ontario (30 km; Fletcher 1996, 1997).

Critical habitat for the Spiny Softshell is identified as the extent of suitable habitat (section 7.1.2), where the habitat occupancy criterion (section 7.12) is met. At the present time, suitable habitat boundaries of permanent watercourses, waterbodies and wetlands are available for most local populations in Ontario and Quebec and can be used to define the area within which critical habitat is found, herein referred to as the critical habitat unit. Where the habitat connectivity criterion is applied (in cases where two valid observation records are within a network of continuous surface water features and are separated by a maximum distance of 30 km) the critical habitat unit is extended to identify a larger aquatic habitat complex for the Spiny Softshell (see Figure 3). Thus, the critical habitat unit represents the maximum extent of critical habitat at a given location. Urban areas and/or human-made structures do not possess the biophysical attributes of suitable habitat for the Spiny Softshell (Section 7.1.2) and are therefore not identified as critical habitat.

Application of the critical habitat criteria to available data identifies 12 units that contain critical habitat for 15 local populations of Spiny Softshell in Canada: 13 in Ontario (including 9 extant and 4 historical populations) and 2 in Quebec, totaling up to ~71,404 ha. This is considered a partial identification of critical habitat as there are 7 locations (6 in Ontario, 1 in Quebec) that have not been surveyed recently or adequately and/or where there is a lack of certainty in the data needed to identify critical habitat or where data sharing agreements are required. A schedule of studies (section 7.2) 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.

Due to the sensitivity of Spiny Softshell to illegal collection, critical habitat has been presented using 50 x 50 km Universal Transverse Mercator (UTM) grid squares (Table 4, see also Figure 4). The UTM grid squares are part of a standardized grid system that indicates the general geographic areas containing critical habitat, for land use planning and/or environmental assessment purposes. Critical habitat within each grid square occurs where the description of habitat occupancy (section 7.1.1), habitat suitability (section 7.1.2) and habitat connectivity (section 7.1.3) are met. More detailed information on the location of critical habitat, to support protection of the species and its habitat may be requested on a need-to-know basis by contacting Environment Canada – Canadian Wildlife Service at ec.planificationduretablissement-recoveryplanning.ec@canada.ca.

Figure 3. Schematic of Critical Habitat Criteria for the Spiny Softshell. A critical habitat unit is identified where the habitat occupancy criterion applies. Within the critical habitat unit, critical habitat is identified as the areas that contain the detailed biophysical attributes (described in Table 3) that are required for a specific life cycle activity. The maximum extent of biophysical attributes is determined by ecological and behavioural knowledge specific to the Spiny Softshell (i.e., the watercourse or waterbody extending to a maximum of 10 km parallel to the shoreline in both directions from an observation and the adjacent suitable habitat[s] within a province specified distance (50 m in Ontario, 10 m in Quebec) of the watercourse or waterbody; OR the wetland up to a maximum radial distance of 10 km from the valid observation and the adjacent suitable habitat[s] within a province specified distance (50 m in Ontario, 10 m in Quebec) of the wetlands; OR a known nesting site comprising an area extending a radial distance of 50 m from a valid nesting observation). The critical habitat unit is extended to include dispersal corridors where two valid observations occur within a continuous hydrological network and are separated by a maximum distance of 30 km (Habitat Connectivity Criterion).

Long description for Figure 3

Figure 3 is a schematic diagram of how critical habitat is identified for Spiny Softshell. It shows an area of lake shoreline and river leading to wetland area. Within this area, and where there are confirmed Spiny Softshell observations, within the specified distances, critical habitat is located.

Table 4: Critical Habitat for the Spiny Softshell in Canada occurs within these 50 x 50 km UTM grid squares where the description of habitat occupancy (section 7.1.1), habitat suitability (section 7.1.2) and habitat connectivity (section 7.1.3) are met.
50 x 50 km Standardized UTM grid square IDFootnoteh Province/Territory UTM Grid Square Coordinates UTM Grid Square Coordinates Footnotei
17TLBB Ontario 300000 4650000
17TLGC Ontario 350000 4600000
17TLGD Ontario 350000 4650000
17TLHC Ontario 350000 4700000
17TLHD Ontario 350000 4750000
17TMGB Ontario 400000 4650000
17TMHA Ontario 400000 4700000
17TMHB Ontario 400000 4750000
17TMHC Ontario 450000 4700000
17TMHD Ontario 450000 4750000
17TNHA Ontario 500000 4700000
17TNHB Ontario 500000 4750000
17TNHC Ontario 550000 4700000
17TNHD Ontario 550000 4750000
18TXQB Quebec 600000 4950000
18TXQD Quebec 650000 4950000
18TXRA Quebec 600000 5000000
18TXRC Quebec 650000 5000000
Figure 4. Grid squares that contain critical habitat for the Spiny Softshell in Canada. Critical habitat for the Spiny Softshell occurs within these 50 x 50 km UTM grid squares where the description of habitat occupancy (section 7.1.1), habitat suitability (section 7.1.2) and habitat connectivity (section 7.1.3) are met.

Long description for Figure 4

Figure 4 is a map of southern Ontario and Quebec that shows 50 km x 50 km grid squares that contain critical habitat. There is a grouping of 14 grid squares covering the area in southwestern Ontario from Windsor to Hamilton. There are four grid squares centred east and southeast of Montreal.

Critical habitat for the Spiny Softshell is partially identified in this recovery strategy as it may be insufficient to meet the population and distribution objectives (section 5) for the species. There are some locations (e.g., extant or historic element occurrences) that may still support Spiny Softshells but have either not been surveyed recently or adequately, or where data sharing agreements are required, and/or where there is a lack of certainty in the data needed to identify critical habitat. Studies are required to confirm whether these areas contribute to the overall local population viability.

Table 5. Schedule of studies
Description of Activity Rationale Timeline
Confirm habitat occupancy in locations where only a single observation of Spiny Softshell is available, where the validity of a record is in question (e.g., records possibly corresponding to released individuals), where data sharing agreements are required or where records are spatially imprecise or cannot be associated to specific locations. This activity is needed to complete critical habitat identification. 2015 – 2025
Conduct population surveys and habitat assessments at historical sites to confirm species' presence in areas that have received insufficient survey effort. Information on the recent presence (including nesting) is required to support the identification of critical habitat (i.e., determination of habitat occupancy). 2015 – 2025

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 or multiple activities at one point in time or from the cumulative effects of one or more activities over time.

Destruction of critical habitat for the Spiny Softshell can happen at a variety of scales and in both aquatic and terrestrial habitats. It may occur from an activity taking place either within or outside of the critical habitat boundary, and may occur in any season of the year. Within the critical habitat boundary, activities may affect habitats that provide suitable conditions for mating, nesting, foraging, thermoregulation, or overwintering. Certain activities may also affect dispersal and commuting corridors that connect these habitats. Within these corridors it is most important to maintain habitat permeability (movement through connective habitat to access adjacent suitable habitats) and, as a result, certain activities that are likely to cause destruction in habitats suitable for mating, foraging, overwintering, nesting and thermoregulation may not cause destruction in corridors as long as sufficient habitat permeability is maintained. In general, activities taking place outside of the critical habitat boundary are less likely to cause destruction of critical habitat than those taking place within the critical habitat boundary.

Activities described in Table 6 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 6: Examples of activities likely to result in the destruction of critical habitat
Description of Activity

Description of Effect

Location of the Activity Likely to Destroy Critical Habitat

Within Critical habitat

Nesting, foraging, mating, overwintering or thermoregulation habitat

Location of the Activity Likely to Destroy Critical Habitat

Within Critical habitat

Commuting and/or dispersal habitat

Location of the Activity Likely to Destroy Critical Habitat

Outside Critical Habitat

Activities that result in the alteration of hydrology (such as drainage) or filling of wetlands Complete or partial draining or filling of wetlands at any time of the year is likely to cause permanent or temporary loss of mating, thermoregulation, overwintering, movement and foraging habitat(s). Even activities conducted outside of the critical habitat boundary may indirectly drain wetlands that form part of the critical habitat. If these activities were to occur outside the bounds of critical habitat, it could result in destruction of critical habitat if the wetland characteristics that contribute to critical habitat suitability are not maintained (e.g., hydrology of critical habitat). A single event could cause critical habitat destruction. X X X
Activities such as residential and/or industrial development; habitat conversion for agriculture Complete or partial conversion of shoreline habitats or terrestrial habitats for other uses (e.g., development, agriculture) at any time of year may cause permanent loss or degradation of thermoregulation, nesting, and/or foraging habitat(s). Such conversion may also remove or degrade commuting or disperal habitat, thus potentially reducing access to key areas (e.g., nesting sites) as well as isolating populations. A single event could cause critical habitat destruction. If these activities were to occur outside the bounds of critical habitat, it could indirectly result in destruction of critical habitat if the characteristics that contribute to critical habitat suitability are not maintained (e.g., hydrology of critical habitat). Currently, all such activities within critical habitat are likely to result in destruction of critical habitat. A single event could cause critical habitat destruction. X X X
Activities that alter water flow and/or fragment aquatic habitat, such as the creation and operation of water control structures

Alteration/ disruption of water flow, such as through the creation and operation of dams or other water control structures, may lead to temporary or permanent degradation or elimination of nesting, overwintering, foraging, and thermoregulation habitat(s). Stabilization of water levels may permanently diminish flood plain habitat availability (e.g., wetlands, open shoreline areas) upon which the Spiny Softshell relies for nesting, foraging and/or thermoregulation. High water levels can saturate nesting substrates, thereby affecting the possibility of successfully using the site. Recurrent low water levels can promote the growth of vegetation on nesting sites, preventing their use for egg laying. Destruction of overwintering habitat can result if water depth is altered to a point where overwintering requirements are no longer met.

Additionally, the construction and operation of water control structures is likely to create a barrier that impedes movements of the Spiny Softshell, thereby fragmenting habitat and preventing the species from accessing suitable habitat areas within a home range, as well as preventing dispersal to adjacent populations.

The creation and operation of water control structures within and outside the bounds of critical habitat could result in destruction of critical habitat if the water levels that contribute to critical habitat suitability are not maintained (i.e., hydrology of critical habitat). There is an increased likelihood that such activities could result in the destruction of critical habitat during the nesting and overwintering periods. Further studies are required to set thresholds/conditions to which such activities within and outside of critical habitat are likely to result in habitat destruction.

X X X
Construction of roads and bridges Construction of roads or bridges at any time of year may degrade or permanently destroy suitable nesting, overwintering, or movement habitat. Such construction can compact areas of nesting habitat and cover areas with rip rap and other foreign materials which are unsuitable as nesting sites. If construction or maintenance of water crossings (culverts, bridges, etc.) is conducted in the winter, there is the possibility of negatively impacting overwintering sites through the use of cofferdams to remove water from an area as well as the use of heavy machinery which can impact suitable habitat below the high water mark. Construction of roads may also impede commuting movement (e.g., access to nesting sites). A single event could cause destruction of critical habitat. Such activities would have to occur within the boundaries of critical habitat to impact the habitat. X X -
Shoreline alteration (e.g., re-profiling, linearization or hardening of stream banks) Changes to the structure and composition of shores/banks (e.g., excessive removal of native vegetation, addition of stabilizing materials such as concrete, loss of meanders and associated fine and coarse substrates) at any time of year may create permanent unsuitable conditions for nesting, thermoregulation, and foraging habitat(s). Shoreline hardening may also impede movement. A single event could cause critical habitat destruction. If these activities were to occur within the boundaries of critical habitat, they would directly destroy or degrade the habitat. If these activities were to occur outside the boundaries and upstream, they could indirectly impact the habitat, for example through sediment loading. Currently, all shoreline development within critical habitat is likely to result in destruction of critical habitat. X X -
Intensive farming practices (e.g., field corn) Intensive farming practices (e.g., field corn) at any time of year may lead to siltation of nearby waterbodies, impairing feeding opportunities; it could also lead to removal of native vegetation and natural bare ground areas, causing temporary or permanent alteration of nesting and thermoregulation habitat. Increased use of pesticides and fertilizers may degrade or permanently alter overwintering and foraging habitat directly (e.g., through impairments to water quality) and indirectly (e.g., changes to food availability). If these activities were to occur outside the bounds of critical habitat, it could result in destruction or degradation of critical habitat if the characteristics that contribute to critical habitat suitability are not maintained. A single event could cause critical habitat destruction. Studies are necessary to set thresholds/conditions regarding proximity to critical habitat, and at what level of intensification would result in critical habitat destruction. X X X
Livestock farming and ranching Farming practices such as allowing livestock to graze within critical habitat or to access waterways within critical habitat can also degrade or destroy nesting, foraging, thermoregulation, and overwintering habitat. Livestock trample the habitat and remove natural vegetation which can temporarily or permanently alter the structure of the habitat. Livestock accessing the waterway can also kick up the substrate and cause siltation downstream which could degrade foraging habitat downstream. If these activities were to occur outside the bounds of critical habitat, it could result in destruction or degradation of critical habitat if the characteristics that contribute to critical habitat suitability are not maintained. A single event within critical habitat could lead to habitat destruction. Currently, all farming practices allowing livestock to enter critical habitat is likely to result in destruction of critical habitat.

X

X X
Activities that cause degradation of water quality Discharges of domestic, commercial, industrial or municipal liquid or solid waste in water are some of the activities that could contaminate water with hazardous chemical and biological materials or heavy metals or lead to eutrophication. Activities leading to siltation or runoff of pesticides and fertilizers (e.g., agricultural activities) can also degrade water quality. The degradation of water quality and/or reduction of oxygen levels (creating anoxic conditions) in aquatic habitats within or outside critical habitat, at any time of the year, could temporarily or permanently alter or destroy foraging, overwintering, and thermoregulation habitats. Continuous, sporadic, or recurrent episodes of such discharges could lead to habitat destruction. Studies are necessary to set thresholds/conditions for these activities.

X

- X
Activities that introduce exotic and/or invasive species (e.g., planting of non-native plant species, moving fill) The introduction of exotic and/or invasive species may lead to degradation or complete loss of habitat through the reduction of nesting, foraging, thermoregulation, overwintering, and movement habitat. For example, dense stands of non-native Common Reed can overgrow nesting sites thereby preventing turtles from nesting, and/or can impede movements to and from nesting, overwintering, or foraging habitats. They can also decrease level of sun exposure, altering thermoregulation habitat. A single event within critical habitat could lead to habitat destruction because once seeds are introduced it can lead to rapid expansion of invasive species. X X X

The performance indicators presented below provide a way to define and measure progress toward achieving the population and distribution objectives.

Long-term performance indicator (50 years):

Medium-term performance indicator (15 years):

One or more action plans will be posted on the SAR Public Registry for the Spiny Softshell by December 2022.

Due to the vulnerability of some species to illegal collection, specific references providing sensitive information have been removed from this version of the recovery strategy. To support protection of the species and its habitat, the exhaustive list of references may be requested on a need-to-know basis by contacting Environment Canada's Recovery Planning section at ec.planificationduretablissement-recoveryplanning.ec@canada.ca

Table A-1 – Ranks of Spiny Softshell in Canada and the United States. (NatureServe2013)
Global (G) Rank National (N) Rank (Canada) Sub-national (S) Rank (Canada) National (N) Rank (United States) Sub-national (S) Rank
(United States)
G5 N3 Quebec (S1)
Ontario (S3)
N5 Alabama (S3), Arizona (SNA), Arkansas (SNR), Colorado (S4), California (SNA), Florida (S3), Georgia (S5), Illinois (S5), Indiana (SNR), Iowa (SNR), Kansas (S5), Kentucky (S5), Louisiana (S5), Maryland (S1), Michigan (S4), Minnesota (S5), Mississippi (S5), Missouri (SNR), Montana (S3), Nebraska (S5), Nevada (SNA), North Carolina (S3), New Jersey (SNR), New Mexico (S4),
New York (S2S3), Ohio (SNR), Oklahoma (S5),
Pennsylvania (S4), South Dakota (S2), South Carolina (SNR), Tennessee (S5), Texas (S5), Utah (SNA), Vermont (S1), Virginia (S2), West Virginia (S4), Wisconsin (S4S5); Wyoming (S4)

Rank Definitions (NatureServe 2013)

S1: Critically Imperilled: At very high risk of extirpation in the jurisdiction due to very restricted range, very few populations or occurrences, very steep declines, severe threats, or other factors.

S2: Imperilled: At high risk of extirpation in the jursidction 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.

N3/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.

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.

S4S5: Secure/Apparently Secure: At no risk to fairly low risk of extirpation in the jurisdiction due to an extensive to very extensive range, abundant populations or occurrences, with little to some concern as a result of local recent declines, threats or other factors.

G5/N5/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).

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

SNR: Unranked: Subnational conservation status not yet assessed.

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 would 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 upon 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.

Most activities undertaken to protect the Spiny Softshell and its habitat will also be beneficial to other species that use similar habitat. The protection of aquatic habitats will contribute to maintaining the rich biodiversity supported by those habitats. Moreover, threat reduction and mitigation measures targeting the Spiny Softshell can contribute to reduce mortality in other animal species (e.g. efforts to eliminate pollution from aquatic environments, implement mitigation techniques to reduce fishing by-catch, etc). Some of these measures are likely to be found in other recovery documents, particularly those that deal with aquatic and riparian species. Table B-1 presents examples of species that may benefit from the recovery of the Spiny Softshell population in Canada.

Table B-1. Some of the species at risk that may benefit from conservation and management of Spiny Softshell turtle habitat.
Common Name Scientific Name SARA Status
Eastern Foxsnake Pantherophis gloydi Endangered
Fowler's Toad Anaxyrus fowleri Endangered
King Rail Rallus elegans Endangered
Lake Erie Watersnake Nerodia sipedon insularum Endangered
Least Bittern Ixobrychus exilis Threatened
Eastern Hog-nosed snake Heterodon platirhinos Threatened
Eastern Musk Turtle Sternotherus odoratus Threatened
Eastern Sand Darter Ammocrypta pellucida Threatened
American Eel Anguilla rostrata Threatened
Northern Map Turtle Graptemys geographica Special Concern
Snapping Turtle Chelydra serpentina Special Concern
Milksnake Lampropeltis triangulum Special Concern
Eastern Ribbonsnake Thamnophis sauritus Special Concern
Bridle Shiner Notropis bifrenatus Special Concern
Grass Pickerel Esox americanus vermiculatus Special Concern

These examples do not represent an exhaustive list. Given that specific needs may differ between species, implementation of recovery actions should be evaluated for impacts on the co-occurring species. Wherever possible, natural ecosystem processes should be maintained and allowed to evolve without human interference, because these are the processes to which species are adapted.

The possibility that the present recovery strategy inadvertently generates negative effects on the environment and on other species was considered. The recommended actions are non-intrusive in nature, including surveys and outreach. It was therefore concluded that the present management plan is unlikely to produce significant negative effects.


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