Inertia in physiological traits: Embryonopsis halticella caterpillars (Yponomeutidae) across the Antarctic Polar Frontal Zone

Geographic variation is characteristic of many physiological traits at the population and species levels. However, several recent studies have suggested that population-level variation is either limited or that it is mostly a consequence of phenotypic plasticity. Here we show that there is considera...

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Bibliographic Details
Published in:Journal of Insect Physiology
Main Authors: Klok C.J., Chown S.L.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2005
Subjects:
adaptation
cold tolerance
desiccation
ecophysiology
phenotypic plasticity
animal
Antarctica
article
cold
demography
environment
food deprivation
genetic variability
genetics
larva
moth
physiology
Animals
Antarctic Regions
Moths
Variation (Genetics)
Heard Island
Heard Island and McDonald Islands
Indian Ocean
Indian Ocean islands
Marion Island
oceanic regions
Prince Edward Islands
World
Embryonopsis
Embryonopsis halticella
Lepidoptera
Phacelia congesta
Yponomeutidae
Antarctic
Heard
Indian
McDonald Islands
The Antarctic
Antarc*
Online Access:http://hdl.handle.net/10019.1/11287
https://doi.org/10.1016/j.jinsphys.2004.11.011
Description
Summary:Geographic variation is characteristic of many physiological traits at the population and species levels. However, several recent studies have suggested that population-level variation is either limited or that it is mostly a consequence of phenotypic plasticity. Here we show that there is considerable physiological inertia in cold hardiness, upper thermal tolerance limits and desiccation resistance in caterpillars of the sub-Antarctic moth Embryonopsis halticella Eaton, such that populations from two climatically different islands are physiologically very similar. Both populations are moderately chill tolerant, with no difference in the supercooling points of caterpillars (-17 to -20°C). Within their host plants caterpillars of both populations freeze at substantially higher, and statistically equivalent temperatures (-9.5 to -11.5°C). The populations also have similar upper lethal limits (38°C), and survival times of dry conditions (6-170 h depending on mass). The previously inexplicably low freezing point of caterpillars at the climatically less severe Marion Island seems likely a consequence of physiological inertia given that the freezing point of caterpillars within their hosts is only a few degrees below absolute minima at the older, and colder, Heard Island. Lack of adaptive geographic variation in physiological traits has consequences for models of range limits, and highlights the importance of exploring phenotypic plasticity as a response to climatic variation. © 2005 Elsevier Ltd. All rights reserved. Article

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