Reprint of: The ins and outs of water dynamics in cold tolerant soil invertebrates

Many soil invertebrates have physiological characteristics in common with freshwater animals and represent an evolutionary transition from aquatic to terrestrial life forms. Their high cuticular permeability and ability to tolerate large modifications of internal osmolality are of particular importa...

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Bibliographic Details
Published in:Journal of Thermal Biology
Main Author: Holmstrup, Martin
Format: Article in Journal/Newspaper
Language:English
Published: 2015
Subjects:
Arctic environments
Cryoprotective dehydration
Compatible osmolytes
Freeze tolerance
Soil invertebrates
COLLEMBOLAN ONYCHIURUS-ARCTICUS
NEMATODE PANAGROLAIMUS-DAVIDI
DENDROBAENA-OCTAEDRA SAVIGNY
SUBZERO TEMPERATURES
ANTARCTIC MIDGE
OVERWINTERING STRATEGIES
BELGICA-ANTARCTICA
CRYPTOPYGUS-ANTARCTICUS
TERRESTRIAL ARTHROPODS
Antarctic
Arctic
Antarc*
Antarctic midge
Antarctica
antarcticus
Belgica antarctica
Cryptopygus antarcticus
Online Access:https://pure.au.dk/portal/da/publications/reprint-of-the-ins-and-outs-of-water-dynamics-in-cold-tolerant-soil-invertebrates(50d2db4a-0e06-418e-be38-dc6c5bd1f3a7).html
https://doi.org/10.1016/j.jtherbio.2015.10.006
Description
Summary:Many soil invertebrates have physiological characteristics in common with freshwater animals and represent an evolutionary transition from aquatic to terrestrial life forms. Their high cuticular permeability and ability to tolerate large modifications of internal osmolality are of particular importance for their cold tolerance. A number of cold region species that spend some or most of their life-time in soil are in more or less intimate contact with soil ice during overwintering. Unless such species have effective barriers against cuticular water-transport, they have only two options for survival: tolerate internal freezing or dehydrate. The risk of internal ice formation may be substantial due to inoculative freezing and many species rely on freeze-tolerance for overwintering. If freezing does not occur, the desiccating power of external ice will cause the animal to dehydrate until vapor pressure equilibrium between body fluids and external ice has been reached. This cold tolerance mechanism is termed ayoprotective dehydration (CPD) and requires that the animal must be able to tolerate substantial dehydration. Even though CPD is essentially a freeze-avoidance strategy the associated physiological traits are more or less the same as those found in freeze tolerant species. The most well-known are accumulation of compatible osmolytes and molecular chaperones reducing or protecting against the stress caused by cellular dehydration. Environmental moisture levels of the habitat are important for which type of cold tolerance is employed, not only in an evolutionary context, but also within a single population. Some species use CPD under relatively dry conditions, but freeze tolerance when soil moisture is high. (C) 2015 Published by Elsevier Ltd.

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