Integrative methods reveal multiple drivers of diversification in rice paddy snakes.

Divergence dating analyses in systematics provide a framework to develop and test biogeographic hypotheses regarding speciation. However, as molecular datasets grow from multilocus to genomic, sample sizes decrease due to computational burdens, and the testing of fine-scale biogeographic hypotheses becomes difficult. In this study, we use coalescent demographic models to investigate the diversification of poorly known rice paddy snakes from Southeast Asia (Homalopsidae: Hypsiscopus), which have conflicting dates of origin based on previous studies. We use coalescent modeling to test the hypothesis that Hypsiscopus diversified 2.5 mya during the Khorat Plateau uplift in Thailand. Additionally, we use ecological niche analyses to identify potential differences in the niche space of the two most widely distributed species in the past and present. Our results suggest Hypsiscopus diversified ~ 2.4 mya, supporting that the Khorat Plateau may have initiated the diversification of rice paddy snakes. We also find significant niche differentiation and shifts between species of Hypsiscopus, indicating that environmental differences may have sustained differentiation of this genus after the Khorat Plateau uplift. Our study expands on the diversification history of snakes in Southeast Asia, and highlights how results from smaller multilocus datasets can be useful in developing and testing biogeographic hypotheses alongside genomic datasets.

Genome-wide ultraconserved elements resolve phylogenetic relationships and biogeographic history among Neotropical leaf-nosed bats in the genus Anoura (Phyllostomidae).

AnouraGray, 1838 are Neotropical nectarivorous bats and the most speciose genus within the phyllostomid subfamily Glossophaginae. However, Anoura species limits remain debated, and phylogenetic relationships remain poorly known, because previous studies used limited Anoura taxon sampling or focused primarily on higher-level relationships. Here, we conduct the first phylogenomic study of Anoura by analyzing 2039 genome-wide ultraconserved elements (UCEs) sequenced for 42 individuals from 8 Anoura species/lineages plus two outgroups. Overall, our results based on UCEs resolved relationships in the genus and supported (1) the monophyly of small-bodied Anoura species (previously genus Lonchoglossa); (2) monotypic status of A. caudifer; and (3) nested positions of "A. carishina", A. caudifer aequatoris, and A. geoffroyi peruana specimens within A. latidens, A. caudifer and A. geoffroyi, respectively (suggesting that these taxa are not distinct species). Additionally, (4) phylogenetic networks allowing reticulate edges did not explain gene tree discordance better than the species tree (without introgression), indicating that a coalescent model accounting for discordance solely through incomplete lineage sorting fit our data well. Sensitivity analyses indicated that our species tree results were not adversely affected by varying taxon sampling across loci. Tree calibration and Bayesian coalescent analyses dated the onset of diversification within Anoura to around âˆ¼ 6-9 million years ago in the Miocene, with extant species diverging mainly within the past âˆ¼ 4 million years. We inferred a historical biogeographical scenario for Anoura of parapatric speciation fragmenting the range of a wide-ranging ancestral lineage centered in the Central to Northern Andes, along with Pliocene-Pleistocene dispersal or founder event speciation in Amazonia and the Brazilian Atlantic forest during the last âˆ¼ 2.5 million years.

Effect of land use, habitat suitability, and hurricanes on the population connectivity of an endemic insular bat.

Urbanization and natural disasters can disrupt landscape connectivity, effectively isolating populations and increasing the risk of local extirpation particularly in island systems. To understand how fragmentation affects corridors among forested areas, we used circuit theory to model the landscape connectivity of the endemic bat Stenoderma rufum within Puerto Rico. Our models combined species occurrences, land use, habitat suitability, and vegetation cover data that were used either as resistance (land use) or conductance layers (habitat suitability and vegetation cover). Urbanization affected connectivity overall from east to west and underscored protected and rustic areas for the maintenance of forest corridors. Suitable habitat provided a reliable measure of connectivity among potential movement corridors that connected more isolated areas. We found that intense hurricanes that disrupt forest integrity can affect connectivity of suitable habitat. Some of the largest protected areas in the east of Puerto Rico are at an increasing risk of becoming disconnected from more continuous forest patches. Given the increasing rate of urbanization, this pattern could also apply to other vertebrates. Our findings show the importance of maintaining forest integrity, emphasizing the considerable conservation value of rustic areas for the preservation of local biodiversity.