Find in Library

Growth-regulating factors (GRFs) play an important role in regulating plant organ development, acting primarily as positive regulators of cell proliferation. However, research on the evolutionary history and expression patterns of the moso bamboo GRF family has been limited. In this study, a total of 24 GRFs have been identified in the Moso bamboo genome, and they have been categorized into four subfamilies. Estimation of the divergence time of paralogous gene pairs provided evidence supporting the significant contribution of recent whole-genome duplication events in the expansion of the GRF gene family. Sliding window analysis revealed that coding regions of a few <i>PheGRFs</i>, including the WRC and QLQ domains, may have undergone positive selection, possibly due to the redundant functions of paralogous genes. Coexpression network analysis further revealed the regulatory role of <i>miR396</i> and various <i>lncRNAs</i> in controlling PheGRF expression. Based on the analysis of tissue-specific expression patterns using transcriptome sequencing, qRT-PCR results, and in situ hybridization, it was observed that most GRFs, particularly <i>PheGRF6a</i> and <i>PheGRF9b</i>, exhibited high levels of accumulation in the moso bamboo shoot. This suggests that the involvement of most PheGRF genes may be crucial for the growth and development of the bamboo shoot. A yeast two-hybrid screening revealed interactions between PheGRF9b and several proteins associated with plant growth and development, including PH02Gene11097.t1 (GIF3), PH02Gene37618.t (Phytochrome B), and PH02Gene01921.t3 (WD40). Based on transcriptome expression analysis, it was observed that a substantial number of <i>PheGRFs</i> exhibited significant variations under cold or drought stress treatments, and most of these genes were found to be downregulated, suggesting their role as abiotic stress-responsive genes. Our findings offer new insights into the GRF family of moso bamboo and provide some experimental evidence to support further gene functional validation research of PheGRF.