Abstract
BACKGROUND: Cauliflower, as an important vegetable crop, the research on its curd formation mechanism and stress-responsive gene networks is of great significance for improving its quality, yield and abiotic stress tolerance. The response regulator (RR) gene family plays a crucial role in the regulation of various life processes of many organisms. In this research, a comprehensive analysis of the BoRR gene family in cauliflower was carried out. RESULTS: A Total of 57 BoRR genes were identified in cauliflower and classified into seven subtypes (type A/B-I/B-II/B-IV/C/B-PRR/Clock PRR) based on sequence homology. Chromosomal mapping showed even distribution across genomes, while physicochemical analysis revealed diverse protein properties (134-915 amino acids, pI 4.51-9.19) with predominant nuclear localization. Structural analyses found all BoRR proteins contain REC-type domains, with subtype-specific features: type A has REC_typeA_ARR, type B harbors REC_typeB_ARR domains, and Clock PRR shows circadian-related psREC_RR domains. Exon numbers range from 2 to 10, with type A BoRR genes having shorter CDS lengths. Collinearity analysis identified 28 pairs of gene duplicates (26 inter-chromosomal). Comparative analysis showed 133 collinear pairs with Brassica napus, 96 with Brassica. rapa, and only 1 with monocots specie (rice and maize). Promoter analysis identified hormone-responsive motifs (ABRE, TGACG), development-related elements (ARE), and stress-responsive sequences (e.g., MBS for drought tolerance) in the promoters of BoRR genes. GO enrichment linked BoRR genes to phosphorelay signaling, cytokinin/ethylene response, and developmental processes like meristem maintenance. Expression profiling during curd development showed type A genes (BoRR23/27/34/38/45) up-regulated in vegetative-reproductive transition, BoRR3/6/12/32/54 in curd enlargement, and several genes like BoRR49 in flower bud differentiation. Salt stress (1.5% NaCl) induced transient expression in 8 of 9 selected BoRR genes at day 1 after treatment. qRT-PCR validated their roles in developmental regulation and salt tolerance. CONCLUSION: This study provides valuable insights into the BoRR gene family in cauliflower, laying a foundation for further understanding its genetic mechanisms and potentially guiding efforts to enhance curd quality and salt tolerance in cauliflower.