Research article

Glutathionylation of beta-actin via a cysteinyl sulfenic acid intermediary

Magnus Johansson and Mathias Lundberg

Karolinska Institute, Department of Laboratory Medicine, Division for Clinical Microbiology, Karolinska University Hospital at Huddinge, S-141 86 Stockholm, Sweden

author email corresponding author email

BMC Biochemistry 2007, 8:26doi:10.1186/1471-2091-8-26

Published:	10 December 2007

Abstract

Background

Cysteinyl residues in actin are glutathionylated, ie. form a mixed disulfide with glutathione, even in the absence of exogenous oxidative stress. Glutathionylation inhibits actin polymerization and reversible actin glutathionylation is a redox dependent mechanism for regulation of the cytoskeleton structure. The molecular mechanism that mediates actin glutathionylation in vivo is unclear.

Results

We have studied glutathionylation of α- and β-actin in vitro using an enzyme-linked immunosorbant assay with a monoclonal anti-glutathione antibody. α- and β-actin were both glutathionylated when incubated with reduced glutathione (GSH) combined with diamide as a thiol oxidant. However, β-actin was also glutathionylated by both glutathione disulfide (GSSG) and GSH in the absence of diamide whereas α-actin was poorly glutathionylated by GSH or GSSG. Glutathionylation of β-actin by GSSG is likely to be mediated by a thiol-exchange mechanism whereas glutathionylation by GSH requires thiol oxidation. β-actin glutathionylation by GSH was inhibited by arsenite and dimedone suggesting that the mechanism involved formation of a cysteinyl sulfenic acid residue in β-actin.

Conclusion

We conclude that glutathionylation of β-actin may occur via spontaneous oxidation of a cysteinyl residue to a sulfenic acid that readily reacts with GSH to form a mixed disulfide. We also show that the reactivity and oxidation to a reactive protein thiol intermediary differ between different actin isoforms.