Structural and functional insights into S-thiolation of human serum albumins

Fumie Nakashima,Tadashi Matsushita,Claus Schneider,Ryosuke Kikuchi,Isao Ishii,Kohei Kamiya,Jun Yoshitake,Koji Uchida,Takahiro Shibata,Juan A Giménez-Bastida

doi:10.1038/s41598-018-19610-9

Abstract

Human serum albumin (HSA) is the most abundant serum protein, contributing to the maintenance of redox balance in the extracellular fluids. One single free cysteine residue at position 34 is believed to be a target of oxidation. However, the molecular details and functions of oxidized HSAs remain obscure. Here we analyzed serum samples from normal subjects and hyperlipidemia patients and observed an enhanced S-thiolation of HSA in the hyperlipidemia patients as compared to the control individuals. Both cysteine and homocysteine were identified as the low molecular weight thiols bound to the HSAs. Intriguingly, S-thiolations were observed not only at Cys34, but also at multiple cysteine residues in the disulfide bonds of HSA. When the serum albumins from genetically modified mice that exhibit high levels of total homocysteine in serum were analyzed, we observed an enhanced S-homocysteinylation at multiple cysteine residues. In addition, the cysteine residues in the disulfide bonds were also thiolated in recombinant HSA that had been treated with the disulfide molecules. These findings and the result that S-homocysteinylation mediated increased surface hydrophobicity and ligand binding activity of HSA offer new insights into structural and functional alternation of serum albumins via S-thiolation.

Highlights

Post-translational modifications of proteins are one of the most critical biological mechanisms in the dynamic regulations of gene expression, protein stability, activity and localization, and protein-protein interactions
Both peaks contained one major protein, migrating at a molecular mass of ~66 kDa in SDS-PAGE under reducing conditions (Fig. 1C, left panel), which was identical to human serum albumin (HSA)
We analyzed serum proteins from normal and hyperlipidemic subjects using anion-exchange liquid chromatography and detected a unique protein peak originating from Human serum albumin (HSA)

Summary

Introduction

Post-translational modifications of proteins are one of the most critical biological mechanisms in the dynamic regulations of gene expression, protein stability, activity and localization, and protein-protein interactions. The S-thiolation reaction proceeds under physiological as well as oxidative stress conditions via the reaction of partially oxidized protein sulfhydryls (sulfenic acid or thiyl radical intermediates) with low molecular weight thiol compounds, such as cysteine or glutathione, or by thiol/disulfide exchange reactions[3,4,5]. This modification can be regarded as a protective mechanism against the terminal or irreversible oxidation of cysteine residues and be involved in the regulation of the function and activity of proteins. These data offer new insights into S-thiolation of HSA, and provide a possible link connecting impaired serum redox balance and structural and functional alternation of serum albumins

Methods

Results

Conclusion