Genome-wide identification of Gramineae histone modification genes and their potential roles in regulating wheat and maize growth and stress responses

• Published in: BMC plant biology Vol. 21; no. 1; p. 543
• Main Authors: Zheng, Liwei, Ma, Shengjie, Shen, Dandan, Fu, Hong, Wang, Yue, Liu, Ying, Shah, Kamran, Yue, Caipeng, Huang, Jinyong
• Format: Journal Article
• Language: English
• Published: England BioMed Central Ltd 20.11.2021; BioMed Central; BMC
• Subjects: Abiotic stress; Activated carbon; Activated charcoal; Adaptation; Adaptation, Physiological - genetics; Arabidopsis; Barley; Cadmium; Charcoal; Chromosomes; Corn; Crops, Agricultural - genetics; Crops, Agricultural - growth & development; Drought; Gene expression; Gene Expression Regulation, Plant; Genes; Genes, Plant; Genetic aspects; Genetic Variation; Genome-Wide Association Study; Genomes; Genotype; Gibberellins; Grain; Gramineae; Growth (Plants); Growth and development; Hardiness; Histone Code; Histone modification; Histones; HM gene; Hordeum vulgare; Identification and classification; Insects; Leaves; Nucleotides; Oryza sativa; Pathogens; Phylogenetics; Phylogeny; Physiological aspects; Plant growth; Plant stress; Plants; Poaceae - genetics; Proteins; Seeds; Setaria italica; Setaria viridis; Sorghum; Sorghum bicolor; Stress; Synteny; Transcription; Transcriptomes; Triticum - genetics; Triticum - growth & development; Triticum aestivum; Wheat; Wheat and maize; Zea mays; Zea mays - genetics; Zea mays - growth & development; China; Growth and development; Histone modification; Wheat and maize; Stress
• ISSN: 1471-2229; 1471-2229
• DOI: 10.1186/s12870-021-03332-8

In plants, histone modification (HM) genes participate in various developmental and defense processes. Gramineae plants (e.g., Triticum aestivum, Hordeum vulgare, Sorghum bicolor, Setaria italica, Setaria viridis, and Zea mays) are important crop species worldwide. However, little information on HM genes is in Gramineae species. Here, we identified 245 TaHMs, 72 HvHMs, 84 SbHMs, 93 SvHMs, 90 SiHMs, and 90 ZmHMs in the above six Gramineae species, respectively. Detailed information on their chromosome locations, conserved domains, phylogenetic trees, synteny, promoter elements, and gene structures were determined. Among the HMs, most motifs were conserved, but several unique motifs were also identified. Our results also suggested that gene and genome duplications potentially impacted the evolution and expansion of HMs in wheat. The number of orthologous gene pairs between rice (Oryza sativa) and each Gramineae species was much greater than that between Arabidopsis and each Gramineae species, indicating that the dicotyledons shared common ancestors. Moreover, all identified HM gene pairs likely underwent purifying selection based on to their non-synonymous (Ka)/synonymous (Ks) nucleotide substitutions. Using published transcriptome data, changes in TaHM gene expression in developing wheat grains treated with brassinosteroid, brassinazole, or activated charcoal were investigated. In addition, the transcription models of ZmHMs in developing maize seeds and after gibberellin treatment were also identified. We also examined plant stress responses and found that heat, drought, salt, insect feeding, nitrogen, and cadmium stress influenced many TaHMs, and drought altered the expression of several ZmHMs. Thus, these findings indicate their important functions in plant growth and stress adaptations. Based on a comprehensive analysis of Gramineae HMs, we found that TaHMs play potential roles in grain development, brassinosteroid- and brassinazole-mediated root growth, activated charcoal-mediated root and leaf growth, and biotic and abiotic adaptations. Furthermore, ZmHMs likely participate in seed development, gibberellin-mediated leaf growth, and drought adaptation.