磷酸化
生物
蛋白质磷酸化
染色质
细胞生物学
定量蛋白质组学
免疫系统
基因
蛋白质组学
基因表达
叶绿体
生物化学
代谢途径
蛋白质组
遗传学
基因表达调控
新陈代谢
转录组
信号转导
蛋白质-蛋白质相互作用
基因组
染色质重塑
计算生物学
通路分析
活性氧
丰度(生态学)
磷蛋白
蛋白质表达
作者
Xiaodong Gong,Jingjing Zhang,Zhihang Liu,Guibo Yin,KeXin Yin,Bin Hu,LIU Yuwei,Shouqin Gu,Jingao Dong
标识
DOI:10.1021/acs.jafc.5c08224
摘要
Northern corn leaf blight, caused by Setosphaeria turcica, poses a serious threat to global maize production. Although previous studies have documented protein expression changes during infection, the role of protein phosphorylation has remained unclear. Here, using mass spectrometry-based proteomics, we identified 2,691 phosphopeptides from 1,598 proteins, corresponding to 3,416 phosphorylation sites. Phosphorylation dynamics were largely independent of the protein abundance changes during infection. We also uncovered 21 enriched phosphorylation motifs, including a novel [LxxxxS] motif. Quantitative analysis revealed significant changes in phosphorylated proteins across infection stages, indicating a functional transition from initial metabolic and chromatin regulators to subsequent redox- and pathogen-responsive proteins. Notably, ZmRIN4b was shown to enhance the resistance by modulating reactive oxygen species and immune gene expression. Protein interaction network analysis highlighted ZmMYB2 as a central hub and implicated glycolysis/gluconeogenesis and chloroplast proteins in defense. These findings offer novel insights into the phosphorylation-mediated immune response of maize to S. turcica.
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