Modes of genetic adaptations underlying functional innovations in the rumen

Authors

Xiangyu Pan, Northwest A&F University
Yudong Cai, Northwest A&F University
Zongjun Li, Northwest A&F University
Xianqing Chen, Northwestern Polytechnical University
Rasmus Heller, Københavns Universitet
Nini Wang, Northwest A&F University
Yu Wang, Northwest A&F University
Chen Zhao, Northwest A&F UniversityFollow
Yong Wang, University of Chinese Academy of Sciences
Han Xu, Northwest A&F UniversityFollow
Songhai Li, Chinese Academy of Sciences
Ming Li, Northwest A&F University
Cunyuan Li, Shihezi University
Shengwei Hu, Shihezi University
Hui Li, Northwest A&F University
Kun Wang, Northwestern Polytechnical UniversityFollow
Lei Chen, Northwestern Polytechnical UniversityFollow
Bin Wei, Northwest A&F University
Zhuqing Zheng, Northwest A&F UniversityFollow
Weiwei Fu, Northwest A&F University
Yue Yang, Northwestern Polytechnical University
Tingting Zhang, Northwest A&F University
Zhuoting Hou, Northwestern Polytechnical University
Yueyang Yan, Northwest A&F University
Xiaoyang Lv, Yangzhou University
Wei Sun, Yangzhou University
Xinyu Li, Guangzhou Medical University
Shisheng Huang, ShanghaiTech University
Lixiang Liu, Nanjing Agricultural University
Shengyong Mao, Nanjing Agricultural University
Wenqing Liu, Northwest A&F University
Jinlian Hua, Northwest A&F University
Zhipeng Li, Chinese Academy of Agricultural Sciences

Abstract

The rumen is the hallmark organ of ruminants and hosts a diverse ecosystem of microorganisms that facilitates efficient digestion of plant fibers. We analyzed 897 transcriptomes from three Cetartiodactyla lineages: ruminants, camels and cetaceans, as well as data from ruminant comparative genomics and functional assays to explore the genetic basis of rumen functional innovations. We identified genes with relatively high expression in the rumen, of which many appeared to be recruited from other tissues. These genes show functional enrichment in ketone body metabolism, regulation of microbial community, and epithelium absorption, which are the most prominent biological processes involved in rumen innovations. Several modes of genetic change underlying rumen functional innovations were uncovered, including coding mutations, genes newly evolved, and changes of regulatory elements. We validated that the key ketogenesis rate-limiting gene (HMGCS2) with five ruminant-specific mutations was under positive selection and exhibits higher synthesis activity than those of other mammals. Two newly evolved genes (LYZ1 and DEFB1) are resistant to Gram-positive bacteria and thereby may regulate microbial community equilibrium. Furthermore, we confirmed that the changes of regulatory elements accounted for the majority of rumen gene recruitment. These results greatly improve our understanding of rumen evolution and organ evo-devo in general.

Publication Title

Science China Life Sciences

Recommended Citation

Pan, X., Cai, Y., Li, Z., Chen, X., Heller, R., Wang, N., Wang, Y., Zhao, C., Wang, Y., Xu, H., Li, S., Li, M., Li, C., Hu, S., Li, H., Wang, K., Chen, L., Wei, B., Zheng, Z., Fu, W., Yang, Y., Zhang, T., Hou, Z., Yan, Y., Lv, X., Sun, W., Li, X., Huang, S., Liu, L., Mao, S., Liu, W., Hua, J., & Li, Z. (2021). Modes of genetic adaptations underlying functional innovations in the rumen. Science China Life Sciences, 64 (1), 1-21. https://doi.org/10.1007/s11427-020-1828-8