# Biogeography and Climate Drive Population Divergence and Genomic Vulnerability in High Altitude Endemic Bird

**Authors:** Nan Wang, Prashant Ghimire, Pritam Chhetri, Nishma Dahal, Cheng Yi, Tong Zhang, Suonan Zhuoga, Zhaxi Jiangyong, Sangeet Lamichhaney

PMC · DOI: 10.1111/mec.70274 · 2026-02-21

## TL;DR

This study explores how geography and climate shape the genetic diversity and vulnerability of a high-altitude bird species in the Himalayas.

## Contribution

The study integrates genomic, ecological, and climatic data to show how biogeography and climate jointly influence population divergence and vulnerability in a high-altitude bird.

## Key findings

- Biogeographic barriers and climatic gradients drive rapid population divergence in Perdix hodgsoniae, reflected in distinct morphological and genetic traits.
- Populations in arid western regions adapt to temperature, while those in humid northeastern regions adapt to precipitation, leading to differing levels of vulnerability.
- Arid landscapes limit gene flow and diversity, increasing sensitivity to climate change, whereas humid regions maintain higher genetic diversity and connectivity.

## Abstract

High‐elevation systems support species adapted to extreme conditions, and their rugged terrain and variable microclimates strongly shape evolution and persistence. Yet few studies have evaluated how geography and climate jointly shape genetic diversity, local adaptation and vulnerability to environmental change. Here, we investigate these processes in the Tibetan Partridge (
Perdix hodgsoniae
), a high‐altitude endemic distributed across arid western and humid northeastern regions of the Sino‐Himalayan landscape. This region's complex topography and contrasting climatic conditions provide a natural setting for examining population divergence, climate‐associated adaptation and future resilience. We integrated whole‐genome sequencing, ecological, climatic, landscape and morphological data to examine current patterns of local adaptation and forecast climate‐induced risks. Our findings show that both biogeographic barriers and climatic gradients drive rapid population divergence in 
P. hodgsoniae
, reflected in distinct morphological traits and population genetic structure. Populations in dry, fragmented western landscapes show adaptation to temperature, whereas those in humid northeastern regions exhibit adaptation primarily to precipitation. These contrasting adaptive trajectories lead to varying levels of vulnerability, with arid, isolated landscapes limiting gene flow and genetic diversity, thereby heightening sensitivity to future climate change. In contrast, humid regions maintain stronger connectivity and larger effective population sizes, supporting higher genetic diversity and facilitating precipitation‐linked adaptation. Together, we demonstrate that mountain landscapes function as a ‘double‐edged sword’ by simultaneously generating and limiting biodiversity through isolation, and by constraining persistence within microclimatic refugia. This study underscores the value of integrating genomic, ecological, climate and landscape data to uncover mechanisms of divergence and inform conservation planning under rapid environmental change.

## Linked entities

- **Species:** Perdix hodgsoniae (taxon 573593), Mus musculus (taxon 10090)

## Full-text entities

- **Chemicals:** carbon (MESH:D002244)
- **Species:** Parus monticolus (species) [taxon 156542], Ithaginis cruentus (blood pheasant, species) [taxon 83285], Perdix hodgsoniae (Tibetan partridge, species) [taxon 573593], Onychostruthus taczanowskii (white-rumped snowfinch, species) [taxon 356909], Pyrgilauda ruficollis (rufous-necked snowfinch, species) [taxon 221976], Phasianus colchicus (common pheasant, species) [taxon 9054], Crossoptilon harmani (Tibetan eared-pheasant, species) [taxon 242522], Crossoptilon crossoptilon (Szechuan white-eared pheasant, species) [taxon 30408], Ochotona curzoniae (black-lipped pika, species) [taxon 130825]

## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12924089/full.md

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Source: https://tomesphere.com/paper/PMC12924089