Garg, Kritika M. ; Ramakrishnan, Uma (2017) Variance in Female Reproductive Success Differentially Impacts Effective Population Size in the Short-Nosed Fruit Bat, Cynopterus sphinx Evolutionary Biology, 44 (3). pp. 366-373. ISSN 0071-3260
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Official URL: http://doi.org/10.1007/s11692-017-9414-y
Related URL: http://dx.doi.org/10.1007/s11692-017-9414-y
Abstract
Effective population size (N e) quantifies the effects of micro-evolutionary processes and the rate of loss of genetic diversity in a population. Several demographic and mating parameters reduce N e. Theoretical studies elucidate the impacts of various demographic and mating system parameters on N e, while empirical studies illustrate realized N e for species with differing life histories and mating systems. However, effect of intra-specific variation in mating system on effective size remains largely unexplored. In this paper we investigated the effect of promiscuous and polygynous mating on N e in two wild populations of the short-nosed fruit bat, Cynopterus sphinx. N e/N (ratio of effective population size to census size) was lower than unity in both populations, and much lower for the polygynous population compared to promiscuous population. Elasticity analyses reveal that N e/N was sensitive to deviations in the sex ratio. Variance in female reproductive success had a higher impact on N e compared to variance in male reproductive success in the promiscuous population. However, for the polygynous population, impact of variance in male reproductive success on N e was higher than that of variance in female reproductive success. Our results suggest that depending on mating system, different populations of the same species could have alternate evolutionary trajectories. The rate of loss of genetic diversity would be lower for the promiscuous population compared to the polygynous population. Our study is the first to highlight which parameters would most significantly impact population specific N e under different mating systems.
Item Type: | Article |
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Source: | Copyright of this article belongs to Springer Nature Switzerland AG |
ID Code: | 127861 |
Deposited On: | 31 Oct 2022 04:51 |
Last Modified: | 31 Oct 2022 04:51 |
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