A near-complete genome assembly of the allotetrapolyploid Cenchrus fungigraminus (JUJUNCAO) provides insights into its evolution and C4 photosynthesis

• Published in: Plant communications Vol. 4; no. 5; p. 100633
• Main Authors: Zheng, Huakun, Wang, Baiyu, Hua, Xiuting, Gao, Ruiting, Wang, Yuhao, Zhang, Zixin, Zhang, Yixing, Mei, Jing, Huang, Yongji, Huang, Yumin, Lin, Hui, Zhang, Xingtan, Lin, Dongmei, Lan, Siren, Liu, Zhongjian, Lu, Guodong, Wang, Zonghua, Ming, Ray, Zhang, Jisen, Lin, Zhanxi
• Format: Journal Article
• Language: English
• Published: China Elsevier Inc 11.09.2023; Elsevier
• Subjects: allotetrapolyploid; Cenchrus grass; centromere architecture; evolutionary trajectory; genome assembly; photosynthetic efficiency; centromere architecture; photosynthetic efficiency; Cenchrus grass; allotetrapolyploid; genome assembly; evolutionary trajectory
• ISSN: 2590-3462; 2590-3462
• DOI: 10.1016/j.xplc.2023.100633

JUJUNCAO (Cenchrus fungigraminus; 2n = 4x = 28) is a Cenchrus grass with the highest biomass production among cultivated plants, and it can be used for mushroom cultivation, animal feed, and biofuel production. Here, we report a nearly complete genome assembly of JUJUNCAO and reveal that JUJUNCAO is an allopolyploid that originated ∼2.7 million years ago (mya). Its genome consists of two subgenomes, and subgenome A shares high collinear synteny with pearl millet. We also investigated the genome evolution of JUJUNCAO and suggest that the ancestral karyotype of Cenchrus split into the A and B ancestral karyotypes of JUJUNCAO. Comparative transcriptome and DNA methylome analyses revealed functional divergence of homeologous gene pairs between the two subgenomes, which was a further indication of asymmetric DNA methylation. The three types of centromeric repeat in the JUJUNCAO genome (CEN137, CEN148, and CEN156) may have evolved independently within each subgenome, with some introgressions of CEN156 from the B to the A subgenome. We investigated the photosynthetic characteristics of JUJUNCAO, revealing its typical C4 Kranz anatomy and high photosynthetic efficiency. NADP-ME and PEPCK appear to cooperate in the major C4 decarboxylation reaction of JUJUNCAO, which is different from other C4 photosynthetic subtypes and may contribute to its high photosynthetic efficiency and biomass yield. Taken together, our results provide insights into the highly efficient photosynthetic mechanism of JUJUNCAO and provide a valuable reference genome for future genetic and evolutionary studies, as well as genetic improvement of Cenchrus grasses. This study reports the assembly of a gapless, T2T genome of the allotetrapolyploid Cenchrus fungigraminus (JUJUNCAO). Using the near-complete genome, the authors present a full picture of its centromere architecture, reveal the evolutionary trajectory of its genome, establish a model of the ancestral grass karyotype of its two subgenomes, and provide insights into the mechanisms that underlie its high photosynthetic efficiency.