Integrating genomics and biogeography to unravel the origin of a mountain biota: The case of a reptile endemicity hotspot in Arabia.

Advances in genomics have greatly enhanced our understanding of mountain biodiversity, providing new insights into the complex and dynamic mechanisms that drive the formation of mountain biotas. These span from broad biogeographic patterns to population dynamics and adaptations to these environments. However, significant challenges remain in integrating large-scale and fine-scale findings to develop a comprehensive understanding of mountain biodiversity. One significant challenge is the lack of genomic data, particularly in historically understudied arid regions where reptiles are a particularly diverse vertebrate group. In the present study, we assembled a de novo genome-wide SNP dataset for the complete endemic reptile fauna of a mountain range (19 described species with more than 600 specimens sequenced), and integrated state-of-the-art biogeographic analyses at the population, species, and community level. Thus, we provide a holistic integration of how a whole endemic reptile community has originated, diversified and dispersed through a mountain system. Our results show that reptiles independently colonized the Hajar Mountains of southeastern Arabia 11 times. After colonization, species delimitation methods suggest high levels of within-mountain diversification, supporting up to 49 deep lineages. This diversity is strongly structured following local topography, with the highest peaks acting as a broad barrier to gene flow among the entire community. Interestingly, orogenic events do not seem key drivers of the biogeographic history of reptiles in this system. Instead, past climatic events seem to have had a major role in this community assemblage. We observe an increase of vicariant events from Late Pliocene onwards, coinciding with an unstable climatic period of rapid shifts between hyper-arid and semiarid conditions that led to the ongoing desertification of Arabia. We conclude that paleoclimate, and particularly extreme aridification, acted as a main driver of diversification in arid mountain systems which is tangled with the generation of highly adapted endemicity. Overall, our study does not only provide a valuable contribution to understanding the evolution of mountain biodiversity, but also offers a flexible and scalable approach that can be reproduced into any taxonomic group and at any discrete environment.

First evaluation of the population structure, genetic diversity and landscape connectivity of the Endangered Arabian tahr.

The Arabian tahr (Arabitragus jayakari) occurs only in the mountains of northern Oman and the United Arab Emirates. The species is classified as Endangered due to its small declining population. In this study, we combined genetic and landscape ecology techniques in order to inform landscape scale conservation and genetic management of Arabian tahr. Using 540 base pairs of mitochondrial control region in a dataset of 53 samples, we found eight haplotypes, which fell into two haplogroups. Population genetic analysis using a panel of 14 microsatellite loci also showed a weak, but significant division. Analyses of landscape connectivity supported the genetic results showing poor connectivity between populations in the far south of the study area and those in the north. The most likely location of corridors connecting Arabian tahr populations were identified. Many corridors between tahr populations are impeded by multi-lane highways and restoration of these connections is required to maintain population viability of Arabian tahr. Owing to limited genetic samples outside of Wadi Sareen, further sampling is needed to elucidate both mtDNA and the nuclear structure of Arabian tahr more fully. Our study provides a toolkit that may be used for future genetic and connectivity monitoring of the Arabian tahr population.

Dispersal beyond geographic barriers: a contribution to the phylogeny and demographic history of Pristurus rupestris Blanford, 1874 (Squamata: Sphaerodactylidae) from southern Iran.

Pristurus rupestris is a member of Semaphore geckos with a wide distribution range. Recently, 14 candidate species of P. rupestris rupestris have been identified in the Hajar Mountains (Arabia), yet the knowledge on the Iranian counterparts is limited. The present study elucidates the phylogenetic position of the Iranian P. rupestris and investigates the hypothesis on its historical colonization from Oman to Iran and the associated islands. Therefore, 20 Iranian specimens along with 115 individuals from Oman were examined using two mitochondrial genes including the Cytochrome b and the 12S ribosomal RNA. The molecular phylogenetic analyses revealed that the individuals collected from Iran are well nested within the candidate Species 3 of P. r. rupestris, demonstrating a single population with high gene flow. Additionally, the molecular analyses showed that the genetic diversity within the Iranian Blanford's Semaphore geckos is low and that the candidate Species 3 experienced a recent expansion approximately 17 thousand years ago (Kya). The historical demographic analyses (BSP) showed a mild increase in the effective population size between 15-20 Kya. These time estimations coincide with the Last Glacial Maximum, when the Persian Gulf was almost dry, reinforcing the hypothesis that the species might have colonized southern Iran from Oman through the Persian Gulf. In addition, we propose P. r. iranicus to be synonymized with P. r. rupestris.