Division of Plant Biology, Bose Institute, P-1/12, CIT Rd, Scheme VIIM, Kolkata, West Bengal 700054, India.
Division of Plant Biology, Bose Institute, P-1/12, CIT Rd, Scheme VIIM, Kolkata, West Bengal 700054, India.
Plant Sci. 2022 Nov;324:111425. doi: 10.1016/j.plantsci.2022.111425. Epub 2022 Aug 23.
Indian mustard (Brassica juncea) faces significant yield loss due to the 'Black Spot Disease,' caused by a fungus Alternaria brassicicola. In plants, NAC transcription factors (NAC TFs) are known for their roles in development and stress tolerance. One such NAC TF, NAC 62, was induced during A. brassicicola challenge in Sinapis alba, a non-host resistant plant against this fungus. Sequence analyses of BjuNAC62 from B. juncea showed that it belonged to the membrane-bound class of transcription factors. Gene expression study revealed differential protein processing of NAC62 between B. juncea and S. alba on pathogen challenge. Furthermore, NAC62 processing to 25 kDa protein was found to be unique to the resistant plant during pathogenesis. Conditional expression of BjuNAC62ΔC, which lacks its transmembrane domain, in B. juncea showed improved tolerance to A. brassicicola. BjuNAC62ΔC processing to 25 kDa product was also observed in tolerant transgenic plants. Additionally, transgenic plants showed induced expression of genes associated with defense-related phytohormone signaling pathways on pathogen challenge. Again, altered phenotypes suggest a possible developmental effect of BjuNAC62∆C in transgenic plants. The overall results suggest that the processing of BjuNAC62 might be playing a crucial role in resistance response against Black Spot disease by modulating defense-associated genes.
印度芥菜(芥菜)由于“黑斑病”而面临重大产量损失,这种病是由真菌交链格孢菌引起的。在植物中,NAC 转录因子(NAC TF)以其在发育和应激耐受性方面的作用而闻名。在非寄主抗性植物白芥(Sinapis alba)中,一种 NAC TF,NAC62,在受到交链格孢菌挑战时被诱导。对来自芥菜的 BjuNAC62 的序列分析表明,它属于膜结合类转录因子。基因表达研究表明,在病原体挑战下,NAC62 在芥菜和白芥之间存在差异的蛋白加工。此外,发现 NAC62 在抗性植物中加工为 25 kDa 蛋白是发病过程中的独特现象。在芥菜中表达缺乏跨膜结构域的 BjuNAC62ΔC 表现出对交链格孢菌的耐受性提高。在耐受转基因植物中也观察到 BjuNAC62ΔC 加工为 25 kDa 产物。此外,转基因植物在受到病原体挑战时表现出与防御相关的植物激素信号通路相关基因的诱导表达。同样,表型的改变表明 BjuNAC62∆C 在转基因植物中可能存在发育效应。总体结果表明,BjuNAC62 的加工可能通过调节防御相关基因在抵抗黑斑病方面发挥关键作用。
