Sies Helmut
Institute for Biochemistry and Molecular Biology I, Medical Faculty, Heinrich-Heine-University Düsseldorf, Düsseldorf, Germany; Leibniz Research Institute for Environmental Medicine, Düsseldorf, Germany.
Free Radic Biol Med. 2024 Nov 20;225:933-939. doi: 10.1016/j.freeradbiomed.2024.11.002. Epub 2024 Nov 2.
Cell and organ metabolism is organized through various signaling mechanisms, including redox, Ca, kinase and electrochemical pathways. Redox signaling operates at multiple levels, from interactions between individual molecules in their microenvironment to communication among subcellular organelles, single cells, organs, and the entire organism. Redox communication is a dynamic and ongoing spatiotemporal process. This article focuses on hydrogen peroxide (HO), a key second messenger that targets redox-active protein cysteine thiolates. HO gradients across cell membranes are controlled by peroxiporins, specialized aquaporins. Redox-active endosomes, known as redoxosomes, form at the plasma membrane. Cell-to-cell redox communication involves direct contacts, such as per gap junctions that connect cells for transfer of molecules via connexons. Moreover, signaling occurs through the release of redox-active molecules and enzymes into the surrounding space, as well as through various types of extracellular vesicles (EVs) that transport these signals to nearby or distant target cells.
细胞和器官代谢是通过多种信号传导机制来组织的,包括氧化还原、钙、激酶和电化学途径。氧化还原信号在多个层面发挥作用,从微环境中单个分子之间的相互作用到亚细胞器、单细胞、器官以及整个生物体之间的通讯。氧化还原通讯是一个动态且持续的时空过程。本文重点关注过氧化氢(H₂O₂),它是一种靶向氧化还原活性蛋白质半胱氨酸硫醇盐的关键第二信使。跨细胞膜的H₂O₂梯度由过氧化物孔蛋白(一种特殊的水通道蛋白)控制。被称为氧化还原体的氧化还原活性内体在质膜处形成。细胞间的氧化还原通讯涉及直接接触,如通过连接子连接细胞以进行分子转移的间隙连接。此外,信号通过将氧化还原活性分子和酶释放到周围空间以及通过各种类型的细胞外囊泡(EVs)发生,这些囊泡将这些信号传递到附近或远处的靶细胞。
