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5 - Seedling herbivory and the temporal niche

Published online by Cambridge University Press:  18 December 2013

Mick E. Hanley
Affiliation:
University of Plymouth
Rebecca J. Sykes
Affiliation:
Ecological Planning & Research Ltd
Colleen K. Kelly
Affiliation:
University of Oxford
Michael G. Bowler
Affiliation:
University of Oxford
Gordon A. Fox
Affiliation:
University of South Florida
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Summary

Seedlings and the temporal niche

The facilitation of plant coexistence via temporal variation in plant recruitment is increasingly studied (see this volume plus Pake and Venable 1996, Chesson and Huntly 1997, Kelly and Bowler 2002, Verhulst et al. 2008). For the most part however, corroborating studies have examined fluctuations in abiotic factors and the role of biotic agents has been largely overlooked. This omission is symptomatic of the plant coexistence literature in general; the role of predators, herbivores, pathogens and parasites in maintaining species coexistence is more often assumed than demonstrated (but see Kelly and Bowler 2009a). Nonetheless, while a number of agents, biotic and abiotic, result in the death of entire seedling cohorts, foremost among the factors limiting seedling recruitment is herbivory (Moles and Westoby 2004, Fenner and Thompson 2005). Herbivore attack has obvious effects on seedling demography (Lindquist and Carroll 2004, Maron and Crone 2006, Maron and Kauffman 2006), but even beyond population-level considerations, selective seedling removal also exerts long-lasting effects on plant community composition. We propose that temporal fluctuation in herbivore populations, and consequently variation in the intensity of herbivory experienced by plants during their regeneration phase, exerts a powerful influence over plant species contribution to the established community.

There are four necessary conditions of any temporal dynamic involving herbivory. First, seedling herbivores must be capable of moderating plant community composition in established vegetation. Second, herbivores should select preferred seedlings on the basis of readily apparent ecophysiological characteristics. Third, and related to the previous assumption, any variation in seedling susceptibility to herbivore attack (i.e. defensive traits) will most probably correlate with competitive ability. Finally, herbivore populations must show fluctuations in numbers and therefore variation in their influence on regenerating plants. Consequently, before it is possible to develop any conceptual framework to explain how temporal variation in seedling herbivory influences species coexistence, we must first evaluate the evidence for these conditions.

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Publisher: Cambridge University Press
Print publication year: 2014

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