Range-wide differential adaptation and genomic vulnerability in critically endangered Asian rosewoods

Abstract

AbstractIn the billion-dollar global illegal wildlife trade, rosewoods have been the world’s most trafficked wild product since 20051.Dalbergia cochinchinensisandD. oliveriare the most sought-after rosewoods in the Greater Mekong Subregion2. They are exposed to significant genetic risks and the lack of knowledge on their adaptability limits the effectiveness of conservation efforts. Here we present genome assemblies and range-wide genomic scans of adaptive variation, together with predictions of genomic vulnerability to climate change. Adaptive genomic variation was differentially associated with temperature and precipitation-related variables between the species, although their natural ranges overlap. The findings are consistent with differences in pioneering ability and in drought tolerance3. We predict their genomic offsets will increase over time and with increasing carbon emission pathway but at a faster pace inD. cochinchinensisthan inD. oliveri. These results and the distinct gene-environment association in the eastern coastal edge suggest species-specific conservation actions: germplasm representation across the range inD. cochinchinensisand focused on vulnerability hotspots inD. oliveri. We translated our genomic models into a seed source matching application,seedeR, to rapidly inform restoration efforts. Our ecological genomic research uncovering contrasting selection forces acting in sympatric rosewoods is of relevance to conserving tropical trees globally and combating risks from climate change.Significant statementIn the billion-dollar global illegal wildlife trade, rosewoods have been the world’s most trafficked wild product since 2005, withDalbergia cochinchinensisandD. oliveribeing the most sought-after and endangered species in Southeast Asia. Emerging efforts for their restoration have lacked a suitable evidence base on adaptability and adaptive potential. We integrated range-wide genomic data and climate models to detect the differential adaptation betweenD. cochinchinensisandD. oliveriin relevance to temperature- and precipitation-related variables and projected their vulnerability until 2100. We highlighted the stronger local adaptation in the coastal edge of the species ranges suggesting conservation priority. We developed genomic resources including chromosome-level genome assemblies and a web-based application seedeR for genomic model-enabled assisted migration and restoration.