Constraints of tolerance: why are desiccation-tolerant organisms so small or rare?

doi:10.1242/jeb.02179

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First published online April 18, 2006
Journal of Experimental Biology 209, 1575-1584 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.02179

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Commentary

Constraints of tolerance: why are desiccation-tolerant organisms so small or rare?

Peter Alpert

Department of Biology, University of Massachusetts, Amherst, MA 01003, USA

e-mail: palpert{at}bio.umass.edu

Accepted 20 February 2006

Drying to equilibrium with the air kills nearly all animalsand flowering plants, including livestock and crops. This makesdrought a key ecological problem for terrestrial life and amajor cause of human famine. However, the ability to toleratecomplete desiccation is widespread in organisms that are either<5 mm long or found mainly where desiccation-sensitive organismsare scarce. This suggests that there is a trade-off betweendesiccation tolerance and growth. Recent molecular and biochemicalresearch shows that organisms tolerate desiccation through aset of mechanisms, including sugars that replace water and formglasses, proteins that stabilize macromolecules and membranes,and anti-oxidants that counter damage by reactive oxygen species. Theseprotections are often induced by drying, and some of the genesinvolved may be homologous in microbes, plants and animals.Understanding how mechanisms of desiccation tolerance may constraingrowth might show how to undo the constraint in some economicallyimportant macroorganisms and elucidate the much-studied butelusive relationship between tolerance of stress and productivity.

Key words: animal, desiccation, drought, growth, microbe, plant, productivity, tolerance, trade-off

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