蛋白质组
磷酸化
人类蛋白质组计划
泛素
细胞生物学
S-亚硝基化
半胱氨酸
功能(生物学)
蛋白质组学
化学
计算生物学
免疫系统
生物
生物化学
遗传学
酶
基因
作者
Zongmin Li,Hanlin Peng,Yaqian Huang,Boyang Lv,Chaoshu Tang,Junbao Du,Jing Yang,Ling Fu,Hongfang Jin
标识
DOI:10.1016/j.freeradbiomed.2024.08.041
摘要
Gasotransmitter-mediated cysteine post-translational modifications, including S-nitrosylation (SNO) and S-persulfidation (SSH), play crucial roles and interact in various biological processes. However, there has been a delay in appreciating the interactional rules between SNO and SSH. Here, all human S-nitrosylated and S-persulfidated proteomic data were curated, and comprehensive analyses from multiple perspectives, including sequence, structure, function, and exact protein impacts (e.g., up-/down-regulation), were performed. Although these two modifications collectively regulated a wide array of proteins to jointly maintain redox homeostasis, they also exhibited intriguing differences. First, SNO tended to be more accessible and functionally clustered in pathways associated with cell damage repair and other protein modifications, such as phosphorylation and ubiquitination. Second, SSH preferentially targeted cysteines in disulfide bonds and modulated tissue development and immune-related pathways. Finally, regardless of whether SNO and SSH occupied the same position of a given protein, their combined effect tended to be suppressive when acting synergistically; otherwise, SNO likely inhibited while SSH activated the target protein. Indeed, a side-by-side comparison of SNO and SSH shed light on their globally reciprocal effects and provided a reference for further research on gasotransmitter-mediated biological effects.
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