Ecological Aspects of Amphibian Metamorphosis: Nonnormal distributions of competitive ability reflect selection for facultative metamorphosis

doi:10.1126/science.182.4119.1305

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Science 28 December 1973:
Vol. 182. no. 4119, pp. 1305 - 1314
DOI: 10.1126/science.182.4119.1305

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Ecological Aspects of Amphibian Metamorphosis

Nonnormal distributions of competitive ability reflect selection for facultative metamorphosis

Henry M. Wilbur ¹ and James P. Collins ²

¹ University of Michigan Society of Fellows
² Museum of Zoology. University of Michigan, Ann Arbor 48104

A synthetic theory of the ecology of amphibian metamorphosisis founded on the observation that the large variation in lengthof larval period and body size at metamorphosis typical of aparticular species of amphibian cannot be directly explainedby differences in dates of hatching or egg sizes. It is proposedthat as development proceeds, variation in exponential growthcoefficients causes a trend from a normal distribution to askewed distribution of body sizes. The degree of skewing increasesand the median of the distribution decreases with increasinginitial densities of populations. The relative advantages ofthe largest members of a cohort may arise from a variety ofmechanisms including the production of growth inhibitors, interferencecompetition, and size-selective feeding behavior. These mechanismsresult in a nonnormal distribution of competitive ability, apossible source of the density-dependent competition coefficientfound in systems with many species (1).

In our model the rangesof body sizes and dates of metamorphosis are determined by aminimum body size that must be obtained and a maximum body sizethat will not be exceeded at metamorphosis. Between these twosize thresholds the endocrinological initiation of metamorphosisis expected to be related to the recent growth history of theindividual larva. Species that exploit uncertain environmentswill have a wide range of possible sizes at metamorphosis. Speciesexploiting relatively certain environments will have a narrowerrange. The evolution of neoteny and direct development logicallyfollow from the application of these ideas to the ecologicalcontext of the evolution of amphibian life histories. Speciesthat live in constant aquatic habitats surrounded by hostileenvironments (desert ponds, caves, high-altitude lakes) mayevolve permanent larvae genetically incapable of metamorphosis.Other populations may evolve a facultative metamorphosis suchthat populations are a mixture of neotenes and terrestrial adults.Direct development results from selection to escape the competition,predation, and environmental uncertainty characteristic of someaquatic habitats and is usually accompanied by parental care.The relation between our ecological model and the physiologicalmechanisms that initiate metamorphosis can only be suggestedand it remains an open problem for developmental biologists.

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