Interspecific interactions are conditional on temperature in an Appalachian stream salamander community

Behavioral preference for microclimate conditions across elevation in Plethodon montanus

The ability to behaviorally regulate body conditions is critical for ectotherms, particularly in the face of global climate change when seeking stable refugia in a changing environment could facilitate survival. This is especially important for montane species that are limited to high elevations. In the Northern Gray-cheeked salamander (Plethodon montanus), studies have demonstrated that population demographics improve at higher elevations and physiological constraints may prevent them from moving into lower-elevation habitats. However, little is known about the species' ability to utilize microhabitats and behaviorally regulate by selecting preferable microclimates. Here, we used continuous position-sensing gradient chambers to examine the behavioral preference for temperature and relative humidity (RH) in P. montanus to better understand their microhabitat use and behavioral thermoregulation across an elevation gradient. We investigated the seasonal variation in both thermal and RH preference of P. montanus collected from different elevations. Our results suggest that most recently experienced environmental temperatures influence thermal preference in animals at high elevations but not those at lower elevations. Salamanders preferred the highest available RH conditions regardless of environmental conditions or elevation. Data on shuttling behavior (movement across the behavior arena) from the experiments suggest that while salamanders shuttled a similar number of times in both types of trials, they spent significantly less time exploring when exposed to the RH gradient compared to the thermal gradient. Together these results suggest that while thermal preference is influenced by acclimation, preference for moisture conditions is less elastic.

Distinctive Connectivities of Near-Stream and Watershed-Wide Land Uses Differentially Degrade Rural Aquatic Ecosystems

The water-quality effects of low-density rural land-use activities are understudied but important because of large rural land coverage. We review and synthesize spatially extensive studies of oligotrophic mountain streams in the rural Southern Appalachian Mountains, concluding that rural land-use activities significantly degrade water quality through altered and mostly enhanced landscape–stream connections, despite high forest retention. Some connections (insolation, organic inputs, root–channel interactions, stream–field connectivity, individual landowner discharges) are controlled by near-stream land-use activities, whereas others (reduced nitrogen uptake and cycling, enhanced biological nitrogen fixation, nutrient subsidy, runoff from compacted soils, road runoff delivery) are controlled by basin-wide land use. These connections merge to alter basal resources and shift fish, salamander, and invertebrate assemblages toward species tolerant of higher turbidity and summer temperatures and those more competitive in mesotrophic systems. Rural water quality problems could be mitigated substantially with well-known best management practices, raising socioecological governance questions about best management practice adoption.

Terrestrial Salamanders Maintain Habitat Suitability under Climate Change despite Trade-Offs between Water Loss and Gas Exchange

Physiological acclimation has the potential to improve survival during climate change by reducing sensitivity to warming. However, acclimation can produce trade-offs due to links between related physiological traits. Water loss and gas exchange are intrinsically linked by the need for respiratory surfaces to remain moist. As climates warm and dry, organisms may attempt to lower desiccation risk by limiting water loss but at a cost of inhibiting their ability to breathe. Here we used laboratory experiments to evaluate the trade-off between water loss and gas exchange in a fully terrestrial, lungless salamander (Plethodon metcalfi). We measured acclimation of resistance to water loss and metabolic rates in response to long-term exposure to temperature and humidity treatments. We then integrated the trade-off into a simulation-based species distribution model to determine the consequences of ignoring physiological trade-offs on energy balance and aerobic scope under climate change. In the laboratory, we found a close association between acclimation of resistance to water loss and metabolic rates indicative of a trade-off. After incorporating the trade-off into our simulations, we found that energy balance and aerobic scope were reduced by 49.7% and 34.3%, respectively, under contemporary climates across their geographic range. Under future warming scenarios, incorporating the trade-off lowered the number of sites predicted to experience local extirpation by 52.2% relative to simulations without the trade-off; however, the number of sites capable of supporting the energetic requirements for reproduction declined from 44.6% to 32.6% across the species' geographic range. These experiments and simulations suggest that salamanders can maintain positive energy balance across their geographic range under climate change despite the costs associated with trade-offs between water loss and gas exchange.