Sex‐biased gene flow and colonization in the Formosan lesser horseshoe bat: inference from nuclear and mitochondrial markers

Chen, Shiang-Fan; Jones, Gareth; Rossiter, Stephen J.

doi:10.1111/j.1469-7998.2007.00391.x

Cited by 33 publications

(27 citation statements)

References 60 publications

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“…The difference between AMOVA patterns for mtDNA and microsatellites could reflect the lower effective size for mtDNA, allowing differentiation to accumulate more rapidly [27]. Conflicting patterns for mtDNA and nuclear DNA are common for mammals with female philopatry and male-biased dispersal [28]. In contrast to females, male tigers have large home ranges and are capable of dispersing up to 280 km [58].…”

Section: Discussionmentioning

confidence: 99%

“…Further, since genetic variation is often geographically structured and can be modified by species-specific behavioural patterns [27,28], the effects of local extinctions on range-wide genetic variation can exceed that predicted by population size change alone, resulting in a non-additive loss of unique genetic variants and an increase in genetic structure [29][30][31]. However, to understand the impact of habitat loss not only on genetic variation, but also on its partitioning, knowledge of the time period through which changes in habitat took place is important.…”

Section: Introductionmentioning

confidence: 99%

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Demographic loss, genetic structure and the conservation implications for Indian tigers

2013

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India is home to approximately 60 per cent of the world's remaining wild tigers, a species that has declined in the last few centuries to occupy less than 7 per cent of its former geographical range. While Indian tiger numbers have somewhat stabilized in recent years, they remain low and populations are highly fragmented. Therefore, the application of evidence-based demographic and genetic management to enhance the remaining populations is a priority. In this context, and using genetic data from historical and modern tigers, we investigated anthropogenic impacts on genetic variation in Indian tigers using mitochondrial and nuclear genetic markers. We found a very high number of historical mitochondrial DNA variants, 93 per cent of which are not detected in modern populations. Population differentiation was higher in modern tigers. Simulations incorporating historical data support population decline, and suggest high population structure in extant populations. Decreased connectivity and habitat loss as a result of ongoing fragmentation in the Indian subcontinent has therefore resulted in a loss of genetic variants and increased genetic differentiation among tiger populations. These results highlight that anthropogenic fragmentation and species-specific demographic processes can interact to alter the partitioning of genetic variation over very short time scales. We conclude that ongoing strategies to maximize the size of some tiger populations, at the expense of losing others, is an inadequate conservation strategy, as it could result in a loss of genetic diversity that may be of adaptive significance for this emblematic species.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Demographic loss, genetic structure and the conservation implications for Indian tigers

2013

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“…myotis, Ruedi and Castella 2003;M. bechsteinii, Kerth et al 2008) and is generally attributed to strong female philopatry and extensive, male-biased dispersal (Chen et al 2008). In addition, we found no isolation by distance pattern with mtDNA markers.…”

Section: Discussionmentioning

confidence: 97%

“…On the other hand, results from our mtDNA analyzes suggest that this high gene flow might not translate into high probabilities that restored islands will be recolonized. Strong female philopatry seems to be the rule in vespertilionid bats (e.g., Petit and Mayer 1999;Castella et al 2001;Ruedi and Castella 2003;Chen et al 2008); and when dispersal is rare, colonization of empty habitat might be even rarer (Kerth and Petit 2005). In addition, interisland gene flow can occur in ways other than individuals immigrating to an island and reproducing there.…”

Section: Conservation Implicationsmentioning

confidence: 96%

Conserving the endangered Mexican fishing bat (Myotis vivesi): genetic variation indicates extensive gene flow among islands in the Gulf of California

et al. 2009

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The endangered Mexican fishing bat, Myotis vivesi, appears to have suffered widespread extinction and population decline on islands throughout the Gulf of California, largely due to predation by introduced cats and rats. To restore populations of fishing bats and other native species, conservation efforts have focused on eradicating introduced vertebrates from several Gulf islands. These efforts assume that individuals from existing populations will recolonize islands and that continued dispersal will help sustain vulnerable populations thereafter. However, the extent of inter-island dispersal in fishing bats is unknown. In this study we analyzed patterns of genetic variation to gauge the extent of gene flow and, thus, potential dispersal among islands. DNA was sampled from 257 fishing bats on 11 Gulf islands (separated by ca. 6-685 km of open water), and individuals were genotyped at six microsatellite loci and haplotyped at a 282 bp fragment of the mtDNA control region. With microsatellites, we found weak population genetic structure and a pattern of isolation by distance, while with mtDNA we found strong structure but no isolation by distance. Our results indicate that island subpopulations separated by large expanses of open water are nonetheless capable of maintaining high genetic diversity and high rates of gene flow. Unfortunately, little is known about the spatial patterns of dispersal or mating system of fishing bats, and these behavioral factors, in particular female philopatry, might reduce the probability of the species recolonizing Gulf islands.

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“…In many ungulate species polygony and philopatry thus involves a pronounced fine-scale genetic structure (Mathews & Porter, 1993;Petit et al 1997;Purdue et al, 2000;Coltman et al, 2003;Nussey et al, 2005). Sex-biased dispersal at the subpopulation and meta-population levels has however been poorly documented (Prugnolle & de Meeus, 2002), but has recently been reported for turtles (Bowen & Karl, 2007) and bats (Chen et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Sex-biased dispersal in a northern ungulate population

Haanes

Røed

Rosef

2011

Ran

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Abstract:In most mammals dispersal is male-biased and in many polygynous ungulates female philopatry and matrilineal grouping involve small-scale genetic structure. We have through sex-related differences in microsatellite allele distribution addressed sex-biased dispersal in a spatially expanding northern ungulate population. The Norwegian red deer population (Cervus elaphus atlanticus) has the last hundred years grown substantially and expanded spatially after a major decline from 300 to 100 years ago. Previous Bayesian analyses suggest a present division of genetic variation into five geographically separated subpopulations. Among these subpopulations the overall F st values were 0.067 (SE=0.014) for males and 0.094 (SE=0.017) for females. Pairwise F st values were significantly higher for females than males, demonstrating a stronger genetic structure among females, and that dispersal has been lower in females than males. Accordingly, a higher number of male than female first generation dispersers were identified among the five subpopulations using Bayesian assignment with prior population information, but significantly so only with relaxed stringency levels of assignment. The identified male-biased dispersal distances varied from 30 to 300 kilometers suggesting male biased dispersal on a large scale in red deer.

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Sex‐biased gene flow and colonization in the Formosan lesser horseshoe bat: inference from nuclear and mitochondrial markers

Cited by 33 publications

References 60 publications

Demographic loss, genetic structure and the conservation implications for Indian tigers

Demographic loss, genetic structure and the conservation implications for Indian tigers

Conserving the endangered Mexican fishing bat (Myotis vivesi): genetic variation indicates extensive gene flow among islands in the Gulf of California

Sex-biased dispersal in a northern ungulate population

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