Movements, home range, and habitat preference assessment of bog turtles (Clemmys muhlenbergii) in southwestern Virginia

Carter, Shawn L.

January 1997

Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1997. / Title from PDF t.p. (viewed Dec. 14, 2005). Vita. Includes bibliographical references (p. 62-65).

Bog turtle Bog turtle

Using remote sensing and geographical information science to predict and delineate critical habitat for the bog turtle, Glyptemys muhlenbergii

Walton, Elizabeth M.

January 1900

Thesis (M. A.)--University of North Carolina at Greensboro, 2006. / Title from PDF title page screen. Advisor: Roy S. Stine; submitted to the Dept. of Geography. Includes bibliographical references (p. 60-65)

Ecological niche modeling as a conservation tool to predict actual and potential habitat for the bog turtle, Glyptemys muhlenbergii

Walton, Elizabeth M.

January 1900

Dissertation (Ph.D.)--The University of North Carolina at Greensboro, 2009. / Directed by Roy Stine; submitted to the Dept. of Geography. Title from PDF t.p. (viewed May 17, 2010). Includes bibliographical references (p. 115-129).

Bog Turtle (Glyptemys muhlenbergii) Population Dynamics and Response to Habitat Management in Massachusetts

Vineyard, Julia

14 November 2023

The Bog Turtle (Glyptemys muhlenbergii) is a federally threatened species that occupies isolated pockets of open-canopy fens. This long-lived species is susceptible to habitat loss and degradation; thus, the conservation of known populations and management of their habitat is critical to the species’ survival. Long-term (multi-decadal) assessment is important for determining population trends and responses to ongoing habitat management. I assessed population demographics (abundance, survival) and spatial distribution (home range) of two Bog Turtle populations in Massachusetts that have been managed since the late 1990s by treating invasive species, thinning woody vegetation, and mitigating flooding. The results of this study were compared to two previous studies conducted in 1994–1997 and 2005–2009 to evaluate the response to habitat management. Estimates of adult population abundance increased from the first study period (Site 1 X̅= 37.3 ± 10.4, Site 2 X̅= 36.2 ± 3.2) to the last study period (Site 1 X̅= 65.1 ± 17.9, Site 2 X̅= 42.5 ± 10.9) across both sites. Estimates of annual survival across all study periods remained above 90% at Site 1 and were 100% for two years at Site 2. I constructed 95% minimum convex polygon (MCP) and 95% kernel density estimation (KDE) home ranges for 71 turtles. At Site 1 there was no significant influence of the study period on home range estimates. The increase in abundance estimates, high survival, and stable home range sizes at Site 1 suggest that ongoing management has maintained quality habitat. At Site 2, the average home range size decreased by approximately half after the first study period in response to flooding but increased in the current study. Fluctuations in population abundance, and home range size at Site 2 throughout the study period reflect the cycles of habitat degradation and habitat management. My results indicate that habitat management efforts implemented since the late 1990s have provided quality habitat for the two Bog Turtle populations in Massachusetts while also mitigating long-term negative impacts on the populations. This further supports the need for long-term analysis of Bog Turtle populations, especially at sites where active habitat management is occurring.

Glyptemys muhlenbergii

bog turtle

population abundance

home range

habitat management

Assessing Changes in Bog Turtle (Glyptemys muhlenbergii) Population Abundance and Factors Influencing Nest Predation in Virginia

Holden, Michael Thomas

10 June 2021

Across the globe, wildlife populations are facing increasing challenges, with many taxonomic groups significantly declining. Among endangered vertebrates (including birds, non-avian reptiles, fishes, mammals, and amphibians), turtles are one of the most threatened groups with over 60% of the 356 recognized species classified as threatened or worse. Bog turtles (Glyptemys muhlenbergii), are among the most imperiled of North American freshwater turtles. These small, secretive turtles have declined by up to 90% in parts of their range, which consists of the Northern Population and the Southern Population, and spans the eastern U.S. from New York to Georgia. These declines are mainly documented in the northern part of their range, but recent work in North Carolina suggests that turtles in the southern part of their range are similarly declining. Prior to this research, surveys aimed at estimating abundance had not been conducted in Virginia since the late 1990's. The research described here was conducted as part of a state-wide population assessment of bog turtles in Virginia. For my first chapter, I conducted capture-mark-recapture surveys in six wetlands in Floyd County, Virginia during 2019 and 2020, and generated abundance estimates. These wetlands had been surveyed in the same manner in 1997, which provided me the opportunity to compare recent abundance estimates with those generated from the 1997 data. My analyses suggest that turtle abundance across these six sites has declined by approximately 50% since 1997. This decline appears to be driven by, but not wholly attributable to, the alteration and loss of habitat at 2-3 of the 6 sites. Habitat loss is acknowledged as one of the major drivers of population declines throughout the range of the bog turtle, in addition to illegal collection for the international pet trade. Due to the life history traits of this species (long life span and low fecundity), the loss of an individual from any life stage from the population can have detrimental effects. While many turtle populations are not heavily impacted from periods of low reproductive success, numerous subsequent years of complete nesting failure can negatively impact population-level survival. Recent studies have suggested that anthropogenically subsidized nest predators may be playing a role in continued nest failure at certain wetlands. My second chapter investigated the factors associated with anthropogenic footprint (i.e., buildings) and infrastructure that may be driving nest predation by these subsidized predators. In 2019 and 2020, I conducted a field experiment in 35 wetlands which utilized artificial turtle nests to investigate variation in nest predation across Montgomery and Floyd Counties, Virginia. I found that increases in the percent of developed land-use and other metrics of anthropogenic disturbance significantly increased nest predation, while increases in the percent of land-use without roads or buildings significantly decreased nest predation. The findings from these two chapters are consistent with population trends documented in other parts of the bog turtle range, and build upon prior studies to investigate drivers of nest predation. These results provide information that can be used by managers to aid in the conservation of this state endangered species, and suggest further courses of research for future projects. / Master of Science / Across the globe, wildlife populations are facing increasing challenges, with many taxonomic groups significantly declining. Turtles are one of the most threatened groups of vertebrates with over 60% of the 356 species of turtle classified as threatened or endangered. Bog turtles (Glyptemys muhlenbergii), are among the most imperiled of North American freshwater turtles. These small, secretive turtles have declined by up to 90% in parts of their range, which consists of the Northern Population and the Southern Population, and spans the eastern U.S. from New York to Georgia. Prior to this research, no information on population trends was available for Virginia. To address this knowledge gap, I conducted surveys for bog turtles in six wetlands in Floyd County, Virginia during 2019 and 2020, and used the data from those surveys to estimate how many turtles were present in the wetlands. These wetlands had been surveyed in the same manner in 1997, which provided me the opportunity to compare recent estimates with those generated from the 1997 data. My analyses suggest that the total number of bog turtles present across these six sites has declined by approximately 50% since 1997. This decline appears to be caused at least in part by the alteration and loss of habitat at 2 of the 6 sites. Habitat loss is thought to be one of the major drivers of population declines throughout the range of the bog turtle, in addition to illegal collection for the international pet trade. Recent studies have suggested an additional problem, that anthropogenically subsidized nest predators may be playing a role in continued nest failure at certain wetlands. Animals such as raccoons, skunks, and bears can persist in greater numbers around human habitation, as we provide extra food sources such as garbage, bird feeders, deer feeders, etc. I investigated the factors associated with human infrastructure that may be driving nest predation by these subsidized predators. In 2019 and 2020, I conducted a field experiment in 35 wetlands using artificial turtle nests to investigate variation in nest predation across Montgomery and Floyd Counties, Virginia. I found that nest predation was significantly higher in areas with a higher percent of developed land-use. The findings from these two studies are consistent with population trends documented in other parts of the bog turtle range, and build upon prior studies to investigate drivers of nest predation. These results provide information that can be used by managers to aid in the conservation of this endangered species, and suggest further courses of research for future projects.

bog turtle

wetlands

nest predation

subsidized predators

conservation

Spatially variable hydrologic regimes in relation to bog turtle (Glyptemys muhlenbergii) population density

Moore, Ryan Michael

14 December 2023

Bog turtles (Glyptemys muhlenbergii) are a small freshwater turtle ranging east of the Appalachian Mountains from New York to Georgia, in small, patchily distributed (<10ha) groundwater fed wetlands. Despite their name, these wetlands are more appropriately identified as seep meadows or fens owing to their reliance on groundwater, with bogs being typified by precipitation as the major hydrologic input. Groundwater inputs are not only important in taxonomically classifying wetland type, but also contribute in important ways to bog turtle natural history. Bog turtles ectothermically regulate body temperature by utilizing thermally buffered groundwater inputs during seasonal extremes. Perennially saturated wetland areas disrupt the establishment of facultative wetland vegetation or woody vegetation that may induce wetland succession, maintaining adequate bog turtle habitat. Further, groundwater input mechanistically contributes to microtopographic variation, providing viable nesting locations. Hydrologic studies pertaining to these wetland habitats has been limited in scope, and often attempts to define hydrologic regimes by use of a centrally placed monitoring well. Several studies that have comprehensively monitored these seep meadow wetlands show hydrologic regime variability at intrasite scales. In this thesis, I sought to confirm the spatially variable nature of hydrologic regimes in bog turtle wetlands. Finding that hydrologic conditions were location-dependent, I then tested whether a seep to non-seep hydrologic gradient, or the defining physical components therein, explained variation in bog turtle population density across a wetland. In Chapter II, I observed wetland conditions in summer extremes to categorize wetland areas based on surface saturation into seep, always wet, and sometimes wet locations. I placed multiple water level monitoring wells within these categories at six bog turtle wetlands and used observed water level data to test for spatial hydrologic variability at within- and across-site scales, finding that hydrologic regime can vary at short distances (<10m), and that alike categorized wells differed in groundwater inputs across-sites. I then used observed water level monitoring data during the growing season to test initial observer-based classifications. These classifications were then reorganized using the amount of time water remained near the soil surface, the degree of fluctuation that water level experienced, and differences in thermal exchange with ambient air temperature and thermally buffered groundwater input. I created a method to delineate spatially variable hydrologic regimes based on groundwater discharge by using several seep-associated features. Soil water temperature, depth to resistive soil layer, and specific conductivity were tested for sampling applicability across seasonal extremes, and for co-occurrence in constrained ordination with spatially explanatory covariates. I found that spatial gradients for relative measures of each seep-associated feature were largely consistent across seasons and that all seep-associated features were more often correlated than any other spatial arrangement. Constrained ordination model results were visualized to depict the seep to non-seep hydrologic gradients found within these wetlands. These gradients were then tested against observed water level data for their predictive capability, finding mixed results across seasons and that hydrologic gradients as modeled could likely be improved with additional explanatory information. Depending on where groundwater is entering a wetland, habitat conditions might vary for bog turtles. Seep areas create perennially saturated or mucky soil conditions, with locations further from groundwater discharge experiencing total or some degree of drying out in the growing season. Bog turtle habitat associations recorded in literature suggest that bog turtles are typically found in or near these soft mud or open water areas. Constant groundwater input near these seeps also leads to rivulet formation. Cool, gently flowing water weaves between hummocks of vegetation near these locations, creating pathways for easy movement, elevated platforms for turtles to bask, and muddy substrates to which turtles can retreat to. Because of the habit conditions afforded by these seep areas, I hypothesized that turtle density might be higher with seep occurrence as influenced by the underlying wetland hydrologic gradient. In Chapter III, I tested whether bog turtle population density was a function of hydrologic features across seep to non-seep gradients, relative soil water temperatures, the depth of substrate above a consolidated soil layer, and relative soil moisture conditions. In the summer of 2022, I trapped at six bog turtle wetlands and tracked 24 bog turtles with radiotelemetry. I used a spatially explicit capture mark recapture framework to estimate density and used data developed for hydrologic datasets in Chapter II to examine density associations. Bog turtle density relationships to hydrologic covariates varied across wetlands and supports the view that bog turtles in their active season are not particularly sensitive to specific hydrologic regime conditions, but rather utilize the entirety of wetland conditions. / Master of Science / Bog turtles (Glyptemys muhlenbergii) are a small freshwater turtle ranging east of the Appalachian Mountains from New York to Georgia, in small, patchily distributed (<10ha) groundwater-fed seep meadows and fens. Groundwater inputs create these wetlands and conditions necessary for bog turtle survival. Hydrologic studies in these wetland types are limited but hint towards a reliance on groundwater input as contributing to hydrologic regimes that are locationally dependent. In this thesis, I sought to confirm the spatially variable nature of hydrologic conditions in these wetlands by focusing on ground water entry points and testing whether seeps, or associated seep characteristics, influenced bog turtle population density across a wetland. In Chapter II, I used water level monitoring wells to establish that hydrologic regimes in bog turtle wetlands are spatially variable and characterized these regimes by the resulting saturated to dry surface conditions. I then selected wetland features hypothesized to be associated with groundwater discharge locations and provided evidence that these features occur together and are seasonally constant. These features were then used to delineate hydrologic gradients and tested for whether they could predict conditions observed in water level monitoring. Hydrologic gradients drawn from seep to non-seep locations had limited ability to predict observed hydrologic regimes. Ground water seeps are considered to contain necessary habitat conditions for bog turtles as thermal and predatory refugia, a mechanistic disturbance favoring herbaceous vegetation over woody vegetation, and provide processes that establish microtopographic variation favorable to bog turtle nesting behavior. In Chapter III, I used delineated gradients from the preceding chapter to assess underlying hydrologic conditions that explain where turtles are more likely to be found within their habitat, and whether these associations were shared across bog turtle populations. Bog turtle density across wetlands differed by hydrologic-associated features, and findings suggest that site-wide variability in conditions is the more important aspect of bog turtle wetlands than a specific hydrologic regime.

Glyptemys muhlenbergii

bog turtle

fen

seep meadow

hydrologic regime

groundwater seep

Wetland hydrology and soils as components of Virginia bog turtle (Glyptemys muhlenbergii) habitat

Feaga, Jeffrey Brian

29 December 2010

Reptile populations are in decline worldwide, with turtle species showing some of the largest drops in population. The bog turtle (Glyptemys muhlenbergii) is considered one of the rarest North American turtle species, and this rarity is made more severe by anthropogenic factors. The wetland habitats that are used by bog turtles contain seepage areas and soil saturation that are characteristic of specific types of wetlands, suggesting that bog turtle rarity may in part be attributed to narrow habitat requirements. In this dissertation, I have sought to spatially and temporally characterize the hydrology and soils of wetlands that are used by bog turtles in an effort to determine how these factors are related to the species' habitat requirements, movement, and activity. In Chapter 1, I evaluated hydrology over a continuous 28-month period using shallow groundwater wells in six wetland fens known to be used by bog turtles for breeding and six apparently similar, but unused, wetlands. The saturated surface area near wells was measured and correlated with depth to the water table. Overall, water tables remained high, with mean monthly depth to the water table for all 12 wetlands remaining > -35 cm (depth below surface datum is negative). Bog turtle breeding wetlands had significantly higher mean water tables and surface saturation than wetlands where no turtles were encountered, particularly during and after the two-year drought occurring in 2007 and 2008. Findings of Chapter 1 suggest that relatively small differences in water table hydrology can affect bog turtle biology and use of wetlands. Bog turtles access soils and move through them to thermoregulate, find cover, and hibernate. Most wetlands used by bog turtles are also grazed by livestock that can modify soil strength. In Chapter 2, I identified dominant soil series and sampled surface soils from wetlands used by bog turtles and similar, but unused, wetlands. Samples were analyzed for organic carbon content and particle size distribution. Organic carbon content was greater in areas that were always wet (10%) than temporarily wet areas (5%). Somewhat higher organic carbon contents were present in wetlands that were used by bog turtles (8.8%) than wetlands where turtles were never encountered (5.7%). Soil textures were sandy loams and silt loams on all the study wetlands. Based on measurements of soil strength made with a static cone penetrometer, bog turtles selected wetland locations with low-strength soils. The mean and variability of soil strength were no different between grazed and ungrazed areas. The physical qualities of surface soils in bog turtle wetlands are dependent on consistently high water tables. In Chapter 3, I described three field studies in which I deployed temperature loggers to measure and contrast ambient air and soil temperatures to turtle carapace temperatures during activity and hibernation. I used temperature signatures to evaluate the timing and cues of spring emergence and to recognize thermoregulatory activities during periods of turtle activity. Mean daily turtle temperatures (n=16 turtles) during the coldest portion of two winters ranged between 1.3°C and 6.1°C, with one turtle experiencing 14 continuous days at temperatures between -1°C and 0°C when ambient temperatures dipped below -10°C. Water tables remained within 10 cm below the soil surface throughout the winter, preventing freezing temperatures for shallow hibernating turtles. Soil temperatures at 10 cm depth were a primary cue for spring emergence. Daily mean summer turtle temperature (n=8) was 20.8°C. My findings indicated that the presence of water near the surface and the ability for turtles to submerge themselves in mud are important for thermoregulation. In Chapter 4, I used radio telemetry to evaluate bog turtle activity (distance moved / hour), linear range, and the pathways used for dispersal. I also investigated bog turtle activity during sampling periods with either wet or dry hydrology. Mixed model analysis indicated that turtles were much less active between 18:30 and 09:30 relative to the daytime and that turtles were most active during times when hydrology was categorized as wet during 2008 when moderate to severe drought was the dominant condition. Sex was not a factor in turtle activity. Bog turtle paths during large movements (≥ 80 m) were mostly contained to areas within 80 m of USGS 7.5â quadrangle mapped streams. Turtles made large movements more frequently during dry conditions. Results suggested that drying conditions can stimulate bog turtles to either remain inactive in sparsely available saturation or to move long distances to find wetter conditions. Future conservation efforts should focus on allowing safe dispersal among habitats by reducing obstructions and risks to travel near streams. I n chapter 5, I used GIS-derived data to compare land cover, stream order, topographic wetness index inverse, presence of hydric soils, and presence of National Wetland Indicator (NWI) wetlands on bog turtle occupied wetlands (n=50) to the same variables on apparently unoccupied (n=48) wetlands or random areas (n=74) along streams. Occupied areas differed from random areas in having near zero values of the topographic wetness index inverse (indicating areas with low slopes and large upstream drainage areas that are more prevalent in wet portions of the landscape), the presence of > 50% low vegetation typical of non-forested agricultural areas, and presence of 3rd order streams. I used significant regression coefficients to create a GIS layer of high quality bog turtle habitat over the landscape, and tested this layer with bog turtle field survey data collected in 2009 independently of model building data. The resulting model has the potential to quickly rule out large portions of the landscape as potential bog turtle habitat. Finally, in Chapter 6, I provided general recommendations for managing bog turtle habitats in Southwestern Virginia. Managing bog turtle wetlands must emphasize the maintenance of high water tables, while avoiding inundation. Maintaining connectivity among wetlands used by bog turtles is an important aspect to consider when developing bog turtle conservations plans associated with development and other land use changes. Educating landowners and enforcing existing wetland laws are imperative for effective bog turtle management in Southwestern Virginia. / Ph. D.

bog turtle

Virginia

wetland

habitat

hydrology

soil

Temperature

GIS

activity

movement

drought

Glyptemys muhlenbergii

management