Abstract
Understanding plant adaptation is critical under intensifying global aridification. Succulence, a key drought-resistance innovation, has evolved repeatedly across plant lineages, yet its intrinsic genomic drivers remain underexplored. Integrating comprehensive evidence from genomics, ecology, and morphology, we investigate adaptation to aridity in the tree grape genus, Cyphostemma (Vitaceae), whose species span environmental gradients from rainforests to deserts and exhibit wide genomic and phenotypic variation. Utilising genome assemblies of representative Cyphostemma species, we demonstrate that specific long terminal repeat retrotransposon (LTR-RT) lineages thrived through the radiation of Cyphostemma and led to substantial intron expansion, a phenomenon rarely studied in eudicots. The intronic LTR-RT insertions likely enhanced tolerance of genome structural changes, facilitating succulence evolution. Genomes of succulents were further expanded by intergenic LTR-RTs, which exhibit recurrent evolutionary advantages in arid and seasonal habitats. Our study reveals how genomic landscapes are shaped by both intrinsic LTR-RT dynamics and extrinsic environmental forces. Critically, we suggest that stochastic dynamics of LTR-RT communities enhance genomic evolvability, enabling adaptive evolution in plants.
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Acknowledgements
We thank Bing Liu, Xiaolei Lin, Jianfei Ye, Zhangjian Shan, Chengxin Fu, Pan Li, Anna Trias-Blasi, Jun Wen, Langxing Yuan, and Viet-Cuong Dang for sample collection and/or field assistance, Daming Zhang for support in laboratory work, Yichen You and Yujie Zhao for cultivating plant materials in our greenhouse, Jian Zhang for suggestions on methylation analyses, Xiaoxue Li for helping with reviewing author checklist items, Liming Cai, Dario Cantu, Zhenchang Liang, Yingxiong Qiu, Haiping Xin, Yi Wang, and Shanshan Zhu for sharing genome assembly data, Patemoshela Kashikola for sharing the image of C. currorii, and staff from HZU, K, P, PE, US, TCD for the loan of or access to specimens.
Funding
This work was supported by National Natural Science Foundation of China 32221001 (to Z.C.) and 32270230 (to L.L.); National Key Research Development Programme of China 2022YFC2601200 (to L.L.), 2023YFF0805800 (to Z.C.); International Partnership Programme of the Chinese Academy of Sciences 063GJHZ2024053FN (to L.L.), 151853KYSB20190027 (to Z.C.); Sino-Africa Joint Research Centre and CAS International Research and Education Development Programme SAJC202527ZD01 (to Z.C.); Swedish Research Council 2024-04303 (to A.A.); Swedish Foundation for Strategic Environmental Research MISTRA Project BioPath (to A.A.); Kew Foundation (to A.A.); and CAS President’s International Fellowship Initiative (to R.L.B and A.A.).
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Yu, J., Zhou, J., Luo, S. et al. Genomic and ecological drivers of parallel arid adaptation in tree grapes (Vitaceae). Nat Commun (2026). https://doi.org/10.1038/s41467-026-74005-z
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DOI: https://doi.org/10.1038/s41467-026-74005-z
