Abstract
BACKGROUND: The NAC (NAM, ATAF1/2, and CUC2) transcription factors (TFs), which play a vital role in plant growth and development, stress response, and disease resistance, have been extensively analyzed in various plant species. However, there is limited knowledge regarding the NAC family in Rhododendron delavayi, an important ornamental flower. RESULT: In this study, a total of 102 RdNAC genes were identified from the R. delavayi genome. Phylogenetic analysis divided these genes into seven subfamilies, each characterized by similar conserved motifs. Chromosomal mapping revealed an uneven distribution of RdNACs across all 13 chromosomes, with gene family expansion driven primarily by dispersed duplication (110 gene pairs) and, to a lesser extent, tandem duplication (17 pairs). Intraspecific synteny analysis detected 26 pairs of duplicated RdNAC genes, while interspecific collinearity with Arabidopsis thaliana uncovered 83 orthologous pairs, indicating both lineage-specific diversification and conserved evolutionary relationships. Ka/Ks ratio calculations for both intra-RdNAC duplicates and RdNAC-AtNAC orthologs yielded values below 0.5, reflecting strong purifying selection. Conserved-motif and domain analyses identified ten distinct motifs and 35 structural domains, with the NAM and MIT CorA-like superfamily domains being the most prevalent. Promoter analysis of 2 kb upstream regions revealed a high abundance of abiotic stress-related cis-acting elements (e.g., ABRE, ARE, CGTCA-motif, LTR). Finally, qRT-PCR demonstrated that under drought (20% PEG) and salt (200 mM NaCl) treatments, multiple RdNACs, particularly RdNAC022 and RdNAC099, were significantly upregulated, underscoring their potential roles in stress response. CONCLUSION: This study provides a comprehensive identification of the RdNAC TF family in R. delavayi, contributing to a better understanding of these transcription factors in this species. The findings also serve as a reference for analyzing stress responses, particularly concerning drought and salt stress in R. delavayi.