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Horseshoe Bat (horseshoe + bat)

Distribution by Scientific Domains

Life Sciences	100%

Selected Abstracts

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

JOURNAL OF ZOOLOGY, Issue 3 2008
S.- F. Chen
Abstract Sex-biased behaviours are expected to play an important role in partitioning genetic variance in animal populations. Comparing genetic structure at markers with different modes of inheritance provides a means of detecting these behaviours and their consequences for population genetic structure. In colonially breeding mammals, the common combination of female philopatry and male vagility can promote contrasting patterns of genetic differentiation between the sexes, both via their effects on recurrent gene flow and on colonization. We examined sex differences in gene flow and structure by comparing maternally inherited mitochondrial DNA (mtDNA) and biparentally inherited autosomal loci in the Formosan lesser horseshoe bat Rhinolophus monoceros. We found that genetic partitioning was higher at mtDNA than autosomal markers in both sexes, indicative of female-biased philopatry and male-biased dispersal. Across Taiwan, isolation-by-distance was detected for all sex/marker combinations but was steeper for mtDNA than for nuclear markers. We suggest that isolation-by-distance shown from mtDNA at large scales is likely to reflect the stepwise founding of new breeding colonies by females during colonization. In contrast, no isolation-by-distance was found at smaller distances of up to 100 km, indicating that gene flow and/or recent shared ancestry homogenises genetic structure among nearby sites. Our results highlight the value of an indirect genetic approach to understanding sex-biased behaviours and their consequences in a little-studied species. [source]

Historical male-mediated introgression in horseshoe bats revealed by multilocus DNA sequence data

MOLECULAR ECOLOGY, Issue 7 2010
XIUGUANG MAO
Abstract Instances of hybridization between mammalian taxa in the wild are rarely documented. To test for introgression between sibling species of horseshoe bat (Rhinolophus yunanensis and R. pearsoni) and two subspecies of the latter (R. p. pearsoni and R. p. chinensis), we sequenced two mtDNA and two ncDNA markers in individuals sampled from multiple localities within their overlapping ranges. The interspecific mtDNA gene tree corresponded to the expected taxonomic divisions, and coalescent-based analyses suggested divergence occurred around 4 MYA. However, these relationships strongly conflicted with those recovered from two independent nuclear gene trees, in which R. yunanensis clustered with R. p. pearsoni to the exclusion of R. p. chinensis. This geographically widespread discordance is best explained by large-scale historical introgression of ncDNA from R. yunanensis to R. pearsoni by male-mediated exchange in mixed species colonies during Pleistocene glacial periods, when ranges may have contracted and overlapped more than at present. Further species tree,gene tree conflicts were detected between R. p. pearsoni and R. p. chinensis, also indicating past and/or current introgression in their overlapping regions. However, here the patterns point to asymmetric mtDNA introgression without ncDNA introgression. Analyses of coalescence times indicate this exchange has occurred subsequent to the divergence of these subspecies from their common ancestor. Our work highlights the importance of using multiple data sets for reconstructing phylogeographic histories and resolving taxonomic relationships. [source]

Phylogeography of the greater horseshoe bat, Rhinolophus ferrumequinum: contrasting results from mitochondrial and microsatellite data

MOLECULAR ECOLOGY, Issue 2 2009
JON FLANDERS
Abstract Phylogeographical studies are typically based on haplotype data, occasionally on nuclear markers such as microsatellites, but rarely combine both. This is unfortunate because the use of markers with contrasting modes of inheritance and rates of evolution might provide a more accurate and comprehensive understanding of a species' history. Here we present a detailed study of the phylogeography of the greater horseshoe bat, Rhinolophus ferrumequinum, using 1098 bp of the mitochondrial ND2 gene from 45 localities from across its Palaearctic range to infer population history. In addition, we re-analysed a large microsatellite data set available for this species and compared the results of both markers to infer population relationships and the historical processes influencing them. We show that mtDNA, the most popular marker in phylogeography studies, yielded a misleading result, and would have led us to conclude erroneously that a single expansion had taken place in Europe. Only by combining the mitochondrial and microsatellite data sets are we able to reconstruct the species' history and show two colonization events in Europe, one before the Last Glacial Maximum (LGM) and one after it. Combining markers also revealed the importance of Asia Minor as an ancient refugium for this species and a source population for the expansion of the greater horseshoe bat into Europe before the LGM. [source]

Postnatal growth and reproductive biology of Rhinolophus hipposideros (Chiroptera: Rhinolophidae)

JOURNAL OF ZOOLOGY, Issue 3 2004
Guido Reiter
Abstract The timing of birth and postnatal growth in lesser horseshoe bats Rhinolophus hipposideros were studied during 2000 and 2001 at three maternity roosts located in the provinces of Carinthia and Salzburg, Austria. Postnatal growth curves for length of forearm and body mass were determined separately for the different colonies and years. Cooler weather during June 2001 coincided with a median birth date that was 8 days later than in 2000, whilst the difference between colonies was 4 and 5 days, respectively, for the pooled data of both years. Cool temperatures in June also coincided with a longer duration of the parturition period. Postnatal growth rates were higher than in most other bat species but differences between years and colonies were considerable. These differences may be attributed to the ambient roost temperatures, whereby the young of two cooler roosts showed significantly reduced growth rate during 8 days of cool weather in 2000. Moreover, later born and therefore smaller pups were more strongly affected by low temperatures than earlier born and larger ones. The mean length of forearm of young lesser horseshoe bats at the beginning of September equalled that of adult bats, whilst their body mass was still lower. Non-volant juveniles did not cluster following the nightly emergence of adult females, and a preferred location within the roosts could not be identified. High and very low roost temperatures, however, did have an influence on the location of non-volant young in the colonies. [source]