Consequences of the global climate crisis on the cave beetle Darlingtonea Kentuckensis Valentine based on thermal tolerance and dehydration resistance

Rising temperatures and diminishing groundwater availability due to the current climate crisis are predicted to expose cave faunas in eastern North America to unprecedented environmental conditions that could prove detrimental to their unique ecosystems. Organisms that inhabit relatively stable envi...

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Bibliographic Details
Published in:Journal of caves and karst studies 2022-12, Vol.84 (4), p.119-128
Main Authors: Apostolopoulos, A.S., Philips, T. Keith
Format: Article
Language:English
Subjects:
Arthropods
Beetles
Caves
Climate
Climate adaptation
Climate change
Climate prediction
Darlingtonea kentuckensis
Dehydration
Ecosystems
Endangered & extinct species
Environmental conditions
Global climate
Groundwater
Groundwater availability
Homogeneity
Humidity
Limiting factors
Physiology
Relative humidity
Survival
Temperature
Temperature tolerance
Thermal resistance
Thermal stress
Tolerances
Tolerances (dimensional)
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Summary:Rising temperatures and diminishing groundwater availability due to the current climate crisis are predicted to expose cave faunas in eastern North America to unprecedented environmental conditions that could prove detrimental to their unique ecosystems. Organisms that inhabit relatively stable environments like caves are known to develop narrow physiological tolerances. Cave habitats with their organisms are simple ecosystems whose homogeneity offers an ideal system for testing the ability of a highly specialized fauna to tolerate abiotic changes. We tested the capability of a cave-specialized beetle in the eastern United States, Darlingtonea kentuckensis Valentine, to withstand future climatic shifts in its environment. We exposed individuals to a range of relative humidities and temperatures for 10 days. The data strongly suggest that there is a temperature threshold for the survival of D. kentuckensis, but it is a higher thermal tolerance than would be expected in an environment that has not fluctuated in recent evolutionary time and suggests remnant physiological characteristics of ancestral epigean carabids. Decreasing the relative humidity in the environment resulted in a much more dramatic decline in survival, indicating highly evolved specialization for constant high-humidity environments. The narrow humidity threshold in which troglobionts can survive may be a much more apparent limiting factor than temperature in adapting to climatic shifts within a cave environment.
ISSN:1090-6924
2331-3714
DOI:10.4311/2021LSC0132