Coevolution of a marine gastropod predator and its dangerous bivalve prey

Coevolution of a marine gastropod predator and its dangerous bivalve prey

The fossil record of the interaction between the predatory whelk Sinistrofulgur and its dangerous hard‐shelled bivalve prey Mercenaria in the Plio‐Pleistocene of Florida was examined to evaluate the hypothesis that coevolution was a major driving force shaping the species interaction. Whelks use the...

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Bibliographic Details
Published in:Biological journal of the Linnean Society Vol. 80; no. 3; pp. 409 - 436
Main Author: DIETL, GREGORY P.
Format: Journal Article
Language:English
Published: Oxford, UK Blackwell Science Ltd 01-11-2003
Blackwell
Subjects:
arms race
Biological and medical sciences
Biological evolution
busyconine
escalation
Fundamental and applied biological sciences. Psychology
Gastropoda
Genetics of eukaryotes. Biological and molecular evolution
Marine
Mercenaria
predator-prey interaction
shell repair
Sinistrofulgur
USA, Florida
Marine environment
Prey
Biological evolution
Gastropoda
Predator
Invertebrata
Mollusca
Coevolution
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Summary:The fossil record of the interaction between the predatory whelk Sinistrofulgur and its dangerous hard‐shelled bivalve prey Mercenaria in the Plio‐Pleistocene of Florida was examined to evaluate the hypothesis that coevolution was a major driving force shaping the species interaction. Whelks use their shell lip to chip open the shell of their prey, often resulting in breakage to their own shells, as well as to their prey. Mercenaria evolved a larger shell in response to an intensifying level of whelk predation. Reciprocally, an increase in attack success (ratio of successful to unsuccessful attacks) and degree of stereotypy of attack position by the predator suggest reciprocal adaptation by Sinistrofulgur to increase efficiency in exploiting hard‐shelled prey. A decrease in prey effectiveness (ratio of unsuccessful to total whelk predation attempts) and an increase in the minimum boundary of a size refuge from whelk predation for Mercenaria may indicate that predator adaptation has outpaced prey antipredatory adaptation. Evolutionary size increase in Sinistrofulgur most likely occurred in response to prey adaptation to decrease the likelihood of feeding‐induced shell breakage and unsuccessful predation when encounters with damage‐inducing prey occur, coupled with (or reinforced by) an evolutionary response to the whelk's own predators. Predator adaptation to Mercenaria best explains temporal changes in whelk behaviour to decrease performance loss (shell breakage) associated with feeding on hard‐shelled prey; this behavioural change limits attacks on prey to when the whelk's shell lip is thickest and most resistant to breakage. Despite evidence of reciprocal adaptation between predator and prey, the contribution of Mercenaria to Sinistrofulgur evolution is likely only a component of the predator's response to dangerous bivalve prey. This study highlights the importance of understanding the interactions among several species in order to provide the appropriate context to test evolutionary hypotheses about any specific pair of species. © 2003 The Linnean Society of London, Biological Journal of the Linnean Society, 2003, 80, 409–436.
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ark:/67375/WNG-GBCDBHCM-V
ArticleID:BIJ255
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0024-4066
1095-8312
DOI:10.1046/j.1095-8312.2003.00255.x