VARIATION IN THE TIMING OF AUTONOMOUS SELFING AMONG POPULATIONS THAT DIFFER IN FLOWER SIZE, TIME TO REPRODUCTIVE MATURITY, AND CLIMATE


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Authors: Elle, E; Gillespie, S; Guindre-Parker, S; Parachnowitsch, AL
Year: 2010
Journal: American Journal of Botany 97: 1894-1902   Article Link (DOI)
Title: VARIATION IN THE TIMING OF AUTONOMOUS SELFING AMONG POPULATIONS THAT DIFFER IN FLOWER SIZE, TIME TO REPRODUCTIVE MATURITY, AND CLIMATE
Abstract: Premise of the study: Early reproductive maturity is common in dry and ephemeral habitats and often associated with smaller flowers with increased potential for within-flower (autonomous) self-pollination. We investigated whether populations from locations that differ in moisture availability, known to vary for whole-plant development rate, also varied in the timing of autonomous selfing. This timing is of interest because the modes of selfing (prior, competing, and delayed) have different fitness consequences. Methods: We measured timing of anther dehiscence, stigma receptivity, and herkogamy under pollinator-free conditions for plants from three populations of Collinsia parviflora that differed in annual precipitation, flower size, and time to sexual maturity. Using a manipulative experiment, we determined potential seed production via prior, competing, and delayed autonomous selfing for each population. Key results: Stigma receptivity, anther dehiscence, and selfing ability covaried with whole-plant development and climate. Plants from the driest site, which reached sexual maturity earliest, had receptive stigmas and dehiscent anthers in bud. Most seeds were produced via prior selfing. The population from the wettest site with slowest development was not receptive until after flowers opened. Although competing selfing was possible, all selfing was delayed. The intermediate population was between these extremes, with significant contributions from both competing and delayed selfing. Conclusions: Our results demonstrate that within-species variation in the timing of selfing occurs and is related to both environmental conditions and whole-plant development rates. We suggest that, if these results can be generalized to other species, mating systems may evolve in response to ongoing climatic change.
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