When proteostasis is challenged and becomes unbalanced, unfolded proteins can accumulate in the cells. Protein unfolding causes conformational changes and subsequent differentials in side-chain solvent accessibility and reactivity. In particular, when protein unfolds, non-disulfide-bonded cysteines that are usually buried in the native state can become surface exposed and thus accessible. A series of fluorogenic dyes including tetraphenylethene maleimide (TPE-MI) and its analogs were developed to capture cysteine exposure in unfolded proteins as a measure of unfolded protein load and proteostasis capacity in cells. These dyes are inherently non-fluorescent but show fluorescence turn-on effect when conjugated to unfolded proteins via reacting with exposed cysteines on the protein. Reacting with small biothiols such as glutathione does not induce fluorescence of these dyes. Here we describe the routine workflow to characterize unfolded proteins in vitro or unfolded proteomes in cells by TPE-MIs.

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