Your search keyword '"J.T. Pynne"' showing total 3 results

1. Southeastern Pocket Gopher (Geomys pinetis) Tunnels Provide Stable Thermal Refugia

Author

Steven B. Castleberry, Robert A. Gitzen, Andy Whelan, L. Mike Conner, Robert A. McCleery, James D. Austin, Elizabeth I. Parsons, Sarah I. Duncan, and J.T. Pynne

Subjects

0106 biological sciences, Hydrology, geography, Geomys pinetis, geography.geographical_feature_category, biology, Coastal plain, Range (biology), Microclimate, Fossorial, Vegetation, Understory, biology.organism_classification, 01 natural sciences, 010601 ecology, Environmental science, Ecology, Evolution, Behavior and Systematics, Invertebrate

Abstract

Animals living underground deal with multiple physiological challenges, such as hypoxia and hypercarbia, but may have reduced thermoregulation demands because of the more stable underground microclimate. Southeastern pocket gophers (Geomys pinetis Rafinesque) occur in the fire-adapted, open-pine forests of the southeastern Atlantic Coastal Plain where prescribed fire is commonly used to manage understory vegetation. They are almost exclusively fossorial, and their tunnels provide ecological services, including shelter, for a suite of commensal vertebrates and invertebrates. To quantify potential thermoregulation benefits of southeastern pocket gopher tunnels, we compared temperatures in active tunnels (n = 31) to aboveground temperatures during winter (December 2018–February 2019), and to aboveground temperatures during prescribed fire events (n = 16) occurring in spring (March–May 2019). During winter, tunnels provided a more stable thermal environment (average range = 6.5 ± 0.8 C; mean ± se) relative to aboveground (average range = 24.8 ± 1.8 C) temperatures. Similarly, mean tunnel temperature range (2.05 ± 0.5 C) was significantly narrower than aboveground temperature range associated with fire events (497.0 ± 101.4 C). Clearly, tunnels provide a stable thermal environment for pocket gophers and commensals that use their tunnel systems.

Published

2021

2. Eastern Fox Squirrel (Sciurus niger) Occupancy in Fragmented Montane Longleaf Pine Forests

Author

Andrew J. Edelman, J.T. Pynne, and Jonathan M. Stober

Subjects

0106 biological sciences, biology, Occupancy, Ecology, 010604 marine biology & hydrobiology, Vegetation, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Geography, Habitat, Abundance (ecology), Fire protection, Camera trap, Eastern fox squirrel, Ecology, Evolution, Behavior and Systematics, Sciurus

Abstract

Sciurus niger L. (Eastern Fox Squirrel) is associated with montane Pinus palustris Mill. (Longleaf Pine) forests in the Piedmont and Ridge and Valley, but little is known about the species' distribution and abundance within this region. We conducted an occupancy study of Eastern Fox Squirrels in montane Longleaf Pine forests of the Talladega National Forest, AL. We surveyed 73 camera trap sites for Eastern Fox Squirrels and measured surrounding vegetation and landscape features. Eastern Fox Squirrels were patchily distributed across the study area and only observed at 11% of sites. Occupancy modeling indicated Eastern Fox Squirrels had a relatively high probability of detection (0.680) but a low probability of occupancy (0.111). Eastern Fox Squirrel occupancy was negatively associated with slope steepness. This result is possibly because prescribed fire and other restoration efforts of open-pine conditions associated with Eastern Fox Squirrel habitat in Talladega National Forest are focused on logistically accessible ridges and more moderately sloped areas. Steep slopes also likely decrease accessibility and dispersion ability for Eastern Fox Squirrels. The overall low occupancy of Eastern Fox Squirrels in the Shoal Creek Ranger District of Talladega National Forest may be linked to the highly fragmented montane Longleaf Pine habitat caused by topography and past fire suppression.

Published

2020

3. Land use and cover effects on an ecosystem engineer

Author

Steven B. Castleberry, Robert A. McCleery, James D. Austin, Robert J. Fletcher, J.T. Pynne, L. Mike Conner, Sarah I. Duncan, Robert A. Gitzen, Elizabeth I. Parsons, and Michael Barbour

Subjects

0106 biological sciences, Geomys pinetis, biology, Land use, Range (biology), Ecology, Forest management, Species distribution, Forestry, Management, Monitoring, Policy and Law, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Ecosystem engineer, Geography, Urbanization, Ecosystem, 010606 plant biology & botany, Nature and Landscape Conservation

Abstract

Human induced land-use change in the form of urbanization and agriculture are rapidly transforming our planet’s terrestrial landscapes and causing the loss of species at unprecedented rates. Studies documenting the impacts of development are extensive; however, less is known about the scale at which species respond to development and specific features of altered landscapes that make them vulnerable. This shortcoming may be due to the difficulty of collecting data across large spatial extents, but filling these information gaps are critical, particularly for species that have a disproportionate influence on ecosystems, such as ecosystem engineers. One such species, the southeastern pocket gopher (Geomys pinetis), has been declining throughout its range (southeastern United States) and continued loss will likely have strong effects on the imperiled longleaf pine ecosystem in which it is closely associated. Using range-wide data from presence-absence surveys and publicly available presence-only data, we used recent advances in species distribution modeling to understand this ecosystem engineer’s associations with extensive land use and cover changes. Our study showed that pocket gophers inhabit a variety of land-use types, including regions with low levels of anthropogenic development, but are largely absent from intensely urbanized areas and closed-canopy forests. Conservation planning to reduce the spread of extensive development and forest management strategies to reduce closed-canopy systems will be instrumental in reducing the decline of the species and ultimately protection of the longleaf pine ecosystem. The approach used in this study will be increasingly beneficial for understanding species response to land-use change.

Published

2020