Physiological mechanisms of seasonal and rapid cold‐hardening in insects
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TLDR
A synthesis of the current literature suggests that these two forms of cold‐hardening may be more mechanistically distinct than originally anticipated.Abstract:
Insects have evolved a number of physiological mechanisms for coping with the detrimental effects of low temperature. As autumn progresses, insects use environmental signals such as shortening day lengths and gradually decreasing temperatures to trigger seasonal cold-hardening adaptations. These mechanisms include dramatic changes in biochemistry, cell function and gene expression that permit improved cell function and viability at low temperature. Insects are also capable of enhancing cold tolerance on a much shorter time scale, in a process called rapid cold-hardening (RCH). Rapid cold-hardening allows insects to improve cold tolerance almost instantaneously (i.e. within minutes to hours) to cope with sudden cold snaps and regularly-occurring diurnal drops in temperature. Initially, it was assumed that RCH would share many of the same basic mechanisms as seasonal cold-hardening, albeit on a shorter time scale. Although there is some evidence supporting this, recent work has called into question some of the original hypotheses concerning the mechanisms of RCH. Also, some mechanisms important for seasonal cold-hardening, such as up-regulation of stress proteins, are unlikely to function at the temperatures and time scales at which RCH occurs. In the present review, the current understanding of the physiological mechanisms governing both seasonal cold-hardening and RCH are summarized. A synthesis of the current literature suggests that these two forms of cold-hardening may be more mechanistically distinct than originally anticipated.read more
Citations
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Insects in Fluctuating Thermal Environments
TL;DR: Fuctuating temperatures could be used to enhance or weaken insects in applied rearing programs, and any prediction of insect performance in the field-including models of climate change or population performance-must account for the effect of fluctuating temperatures.
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The Integrative Physiology of Insect Chill Tolerance
TL;DR: A physiological model is outlined that integrates several of the adaptation and acclimation responses that allow some insects to tolerate low temperatures and discusses how they collectively help to preserve cellular, organ, and organismal homeostasis at low temperature.
Journal ArticleDOI
An invitation to measure insect cold tolerance: Methods, approaches, and workflow.
TL;DR: The 'tried and true' measures of insect cold tolerance, the equipment necessary for these measurement, and the ecological and biological significance of each are covered, and a framework and workflow for measuring cold tolerance and low temperature performance in insects is suggested.
Journal ArticleDOI
Cold acclimation wholly reorganizes the Drosophila melanogaster transcriptome and metabolome.
Heath A. MacMillan,Jose M. Knee,Alice B. Dennis,Hiroko Udaka,Hiroko Udaka,Katie E. Marshall,Katie E. Marshall,Thomas J.S. Merritt,Brent J. Sinclair +8 more
TL;DR: The results are consistent with and extend the current understanding of the mechanisms of insect chilling tolerance, with proline and glutathione metabolism being the most strongly-supported metabolic pathways associated with increased cold tolerance.
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Seasonal cues induce phenotypic plasticity of Drosophila suzukii to enhance winter survival
Peter W. Shearer,Jessica D. West,Vaughn M. Walton,Preston H. Brown,Nicolas Svetec,Joanna C. Chiu +5 more
TL;DR: Investigating D. suzukii phenology and seasonal adaptations can lead to a better understanding of the mechanisms through which insects express phenotypic plasticity, which likely enables invasive species to successfully colonize a wide range of environments.
References
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Combined transcriptomic and metabolomic approach uncovers molecular mechanisms of cold tolerance in a temperate flesh fly
Nicholas M. Teets,Justin T. Peyton,Gregory J. Ragland,Gregory J. Ragland,Hervé Colinet,Hervé Colinet,David Renault,Daniel A. Hahn,David L. Denlinger +8 more
TL;DR: While RCH had very minor effects on gene expression, recovery from cold shock elicits sweeping changes in gene expression and metabolism along numerous cell signaling and biochemical pathways, indicating that coordinated changes in Gene Expression and metabolism contribute to recovery fromcold shock.
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Upregulation of two actin genes and redistribution of actin during diapause and cold stress in the northern house mosquito, Culex pipiens
TL;DR: Changes in gene expression and actin distribution suggest a role for actins in enhancing survival of diapausing adults during the low temperatures of winter by fortification of the cytoskeleton.
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Rapid cold-hardening increases the freezing tolerance of the Antarctic midge Belgica antarctica.
Richard E. Lee,Michael A. Elnitsky,Joseph P. Rinehart,Scott A. L. Hayward,Scott A. L. Hayward,Luke H. Sandro,David L. Denlinger +6 more
TL;DR: It is shown that RCH not only protects against non-freezing injury but also increases freeze tolerance in an Antarctic midge, Belgica antarctica.
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A nonprotein thermal hysteresis-producing xylomannan antifreeze in the freeze-tolerant Alaskan beetle Upis ceramboides
TL;DR: This xylomannan is the first TH-producing antifreeze isolated from a freeze-tolerant animal and the first in a new class of highly active THFs that contain little or no protein.
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Gene expression of heat-shock proteins (Hsp23, Hsp70 and Hsp90) during and after larval diapause in the blow fly Lucilia sericata.
TL;DR: Results indicate that Hsp90 may serve as an early marker to predict diapause termination in this species, and genes encoding heat-shock protein 23, Hsp70 and HSp90 were cloned from Lucilia sericata to examine whether their expression is related to the regulation of its larval diappause.