Allosteric Disulfide Bridges in Integrins:the Molecular Switches of Redox Regulation of Integrin-Mediated Cell Functions
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Abstract
Almost every cell of a multicellular organism is in contact with the extracellular matrix (ECM), which provides the shape and mechanic stability of tissue, organs and the entire body. At the molecular level, cells contact the ECM via integrins. Integrins are transmembrane cell adhesion molecules that connect the ECM and the cytoskeleton, which they bind with their extracellular and intracellular domains, respectively. Cysteine residues are abundant in both integrin subunits, α and β. If pairwise oxidized into disulfide bridges, they stabilize the folding and molecular structure of the integrin. However, despite the oxidative environment of the extracellular space, not all pairs of cysteines in the extracellular integrin domains are permanently engaged in disulfide bridges. Rather, the reversible and temporary closure to cystine bridge of these cysteine pairs by oxidation or their reductive cleavage can cause major conformational changes within the integrin, thereby changing ligand binding affinity and altering cellular functions, such as adhesion and migration. Recent years have characterized several oxidoreductases and thiol isomerases, which target such allosteric disulfide bridges. This outlines much better, albeit not fully comprehensively the role that such thiol switches play in redox regulation of integrins. The platelet integrin, αIIIbβ3, is the best examined example so far. Mostly referring to this integrin, this review will provide insights into the thiol switch-based redox regulation of integrins, the known effects of their allosteric disulfide bridge on conformational changes and cell functions, as well as on the machinery of redox-modifying enzymes that contribute to the redox regulation of cell contacts with the ECM.
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- last seen: 2026-05-20T01:45:00.602351+00:00