HMGB1 dimerization could protect nuclear DNA damage and cell death from oxidative stress

Oxidative stress can induce covalent disulfide bond formation between protein-protein thiol groups and generate hydroxyl free radicals that damage DNA. HMGB1 is a DNA chaperone and damage-associated molecular pattern molecule. As a redox-sensitive protein, HMGB1 contains three cysteine residues: Cys...

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Bibliographic Details
Published in:The Journal of immunology (1950) 2021-05, Vol.206 (1_Supplement), p.97-97.15
Main Authors: Kwak, Man Sup, Rhee, Woo Joong, Lee, Yong Joon, Kim, Hee Sue, Kim, Young Hun, Kwon, Min Kyung, Shin, Jeon-Soo
Format: Article
Language:English
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Summary:Oxidative stress can induce covalent disulfide bond formation between protein-protein thiol groups and generate hydroxyl free radicals that damage DNA. HMGB1 is a DNA chaperone and damage-associated molecular pattern molecule. As a redox-sensitive protein, HMGB1 contains three cysteine residues: Cys23, Cys45, and Cys106. In this study, we focused on the relationship between HMGB1 dimerization and DNA stabilization under oxidative stress conditions. HMGB1 dimerization was positively modulated by CuCl2 and H2O2. Mutation of the Cys106 residue blocked dimer formation. Treatment of HEK293T cells with CuCl2 and H2O2 enhanced the oxidative self-dimerization of HMGB1, whereas this dimerization was inhibited in mutant HMGB1C106A cells. Furthermore, we performed a bimolecular fluorescence complementation assay to visualize Cys106 oxidation-induced HMGB1 dimerization in live cells exposed to oxidative stress and were able to reproduce the dimerization effect of HMGB1 in fluorescence resonance energy transfer analysis. Interestingly, dimerized HMGB1 bound to DNA with higher affinity than monomeric HMGB1. Dimerized HMGB1 protected DNA from damage due to hydroxyl free radicals and prevented cell death. In conclusion, dimerized HMGB1 may play a regulatory role in DNA stabilization under oxidative stress.
ISSN:0022-1767
1550-6606
DOI:10.4049/jimmunol.206.Supp.97.15