Insects With Survival Kits for Desiccation Tolerance Under Extreme Water Deficits

Thorat, Leena; Nath, Bimalendu B.

doi:10.3389/fphys.2018.01843

Cited by 35 publications

(24 citation statements)

References 128 publications

(118 reference statements)

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“…That said, plasticity in the composition of cuticular hydrocarbons due to desiccation may be limited in ants because CHCs are critical for chemical signaling in this taxon (Martin & Drijfhout, 2009). Related, desiccation may facilitate the allocation of resources from the heat shock response toward other biomolecules associated with desiccation tolerance, such as trehalose, Late Embryonic Abundant proteins, aquaporins, or antioxidants (reviewed in Chown et al, 2011; Thorat & Nath, 2018). Dehydration may also lead to increased catabolism of nutrient reserves (Benoit et al, 2010), which may inhibit an animal's ability to mount a response to heating (Manenti et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

City limits: Heat tolerance is influenced by body size and hydration state in an urban ant community

Johnson

Stahlschmidt

2020

Ecology and Evolution

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Cities are rapidly expanding, and global warming is intensified in urban environments due to the urban heat island effect. Therefore, urban animals may be particularly susceptible to warming associated with ongoing climate change. We used a comparative and manipulative approach to test three related hypotheses about the determinants of heat tolerance or critical thermal maximum (CTmax) in urban ants—specifically, that (a) body size, (b) hydration status, and (c) chosen microenvironments influence CTmax. We further tested a fourth hypothesis that native species are particularly physiologically vulnerable in urban environments. We manipulated water access and determined CTmax for 11 species common to cities in California's Central Valley that exhibit nearly 300‐fold variation in body size. There was a moderate phylogenetic signal influencing CTmax, and inter (but not intra) specific variation in body size influenced CTmax where larger species had higher CTmax. The sensitivity of ants’ CTmax to water availability exhibited species‐specific thresholds where short‐term water limitation (8 hr) reduced CTmax and body water content in some species while longer‐term water limitation (32 hr) was required to reduce these traits in other species. However, CTmax was not related to the temperatures chosen by ants during activity. Further, we found support for our fourth hypothesis because CTmax and estimates of thermal safety margin in native species were more sensitive to water availability relative to non‐native species. In sum, we provide evidence of links between heat tolerance and water availability, which will become critically important in an increasingly warm, dry, and urbanized world that others have shown may be selecting for smaller (not larger) body size.

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Section: Discussionmentioning

confidence: 99%

City limits: Heat tolerance is influenced by body size and hydration state in an urban ant community

Johnson

Stahlschmidt

2020

Ecology and Evolution

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“…We suspect that the lack of an interaction between snow cover and extreme low temperatures in the current study is due to temperatures not falling below the critical temperature in those five years, and to the lack of sufficient combinations of temperature and snow cover to detect such interactions. There may be additional benefits of snow cover, beyond its direct effects of protection against extreme cold, such as buffering against complex interactions among desiccation, cold and survival (Elnitsky et al 2008, Thorat and Nath 2018.). Snow cover may also provide benefits for other environmental features such as host plant abundance and distribution (Björk and Molau 2007, Jonas et al 2008).…”

Section: Discussionmentioning

confidence: 99%

Spatial variation in early‐winter snow cover determines local dynamics in a network of alpine butterfly populations

2020

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Snow cover is an extremely variable but critical component of alpine environments. We use long term population data on multiple small populations of the alpine butterfly Parnassius smintheus, combined with high‐resolution satellite imagery of meadows, to show a strong link between fine‐scale spatial and temporal variation in early‐winter snow cover and annual change in butterfly population size, accounting for up to 80 percent of the variation in annual population change. Snow cover in early winter for each meadow is the best predictor of annual adult population change, despite being estimated for a relatively short time‐window in late November. We identify a means by which subpopulation response to a local, short‐term weather variable can be assessed over a large spatial extent, but also at a resolution relevant to the biology and local dynamics of this alpine species.

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“…Nevertheless, insects occupy a wide range of terrestrial micro‐niches ranging from damp environments to deserts. Insects have a variety of sophisticated mechanisms to protect their body against water loss (Thorat & Nath, 2018). Understanding these mechanisms, including at the genetic, molecular and genomic levels, is essential to predict future effects of CC on insect populations, and to allow us to meet future challenges of food security, environmental protection and disease control.…”

Section: Introductionmentioning

confidence: 99%

Eco‐genetics of desiccation resistance in Drosophila

2021

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Climate change globally perturbs water circulation thereby influencing ecosystems including cultivated land. Both harmful and beneficial species of insects are likely to be vulnerable to such changes in climate. As small animals with a disadvantageous surface area to body mass ratio, they face a risk of desiccation. A number of behavioural, physiological and genetic strategies are deployed to solve these problems during adaptation in various Drosophila species. Over 100 desiccation‐related genes have been identified in laboratory and wild populations of the cosmopolitan fruit fly Drosophila melanogaster and its sister species in large‐scale and single‐gene approaches. These genes are involved in water sensing and homeostasis, and barrier formation and function via the production and composition of surface lipids and via pigmentation. Interestingly, the genetic strategy implemented in a given population appears to be unpredictable. In part, this may be due to different experimental approaches in different studies. The observed variability may also reflect a rich standing genetic variation in Drosophila allowing a quasi‐random choice of response strategies through soft‐sweep events, although further studies are needed to unravel any underlying principles. These findings underline that D. melanogaster is a robust species well adapted to resist climate change‐related desiccation. The rich data obtained in Drosophila research provide a framework to address and understand desiccation resistance in other insects. Through the application of powerful genetic tools in the model organism D. melanogaster, the functions of desiccation‐related genes revealed by correlative studies can be tested and the underlying molecular mechanisms of desiccation tolerance understood. The combination of the wealth of available data and its genetic accessibility makes Drosophila an ideal bioindicator. Accumulation of data on desiccation resistance in Drosophila may allow us to create a world map of genetic evolution in response to climate change in an insect genome. Ultimately these efforts may provide guidelines for dealing with the effects of climate‐related perturbations on insect population dynamics in the future.

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Insects With Survival Kits for Desiccation Tolerance Under Extreme Water Deficits

Cited by 35 publications

References 128 publications

City limits: Heat tolerance is influenced by body size and hydration state in an urban ant community

City limits: Heat tolerance is influenced by body size and hydration state in an urban ant community

Spatial variation in early‐winter snow cover determines local dynamics in a network of alpine butterfly populations

Eco‐genetics of desiccation resistance in Drosophila

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