To the editor:
Beta 2 glycoprotein I (β2GPI) is an abundant plasma protein recognized as the major autoantigen in the antiphospholipid syndrome. Although the crystal structure of β2GPI has been resolved,1,2 its normal function remains unknown. We have been intrigued by the presence of a C-terminal cysteine (Cys326), which forms a loop-back disulfide link in the fifth domain of β2GPI. In the current study we examined β2GPI's potential to participate in thiol exchange reactions with the thiol oxidoreductases thioredoxin-1 (TRX-1) and protein disulfide isomerase (PDI).
The incorporation of free thiols into β2GPI after reaction with TRX-1 or PDI was shown by labeling the products of this reaction with the selective sulfhydryl probe Na-(3-maleimidylpropionyl) biocytin (MPB). The biotinylated proteins were visualized by Western blotting with streptavidin–horseradish peroxidase. Because β2GPI does not contain unpaired cysteines, no labeling was observed after incubation with MPB (Figure 1A). Free thiols could not be introduced into β2GPI by incubation with the reducing agent dithiothreitol (DTT) alone. However, free thiols could be introduced into β2GPI after incubation with the reduced forms of the thiol oxidoreductases TRX-1 and PDI, identifying β2GPI as a thiol oxidoreductase substrate (Figure 1A-C). An interesting effect caused by the reduction of β2GPI by TRX-1 was a marked decrease in the affinity of anti-β2GPI monoclonal and polyclonal antibodies as noted on the immunoblots.
To determine the cysteine residue(s) in the β2GPI molecule involved in thiol exchange reactions, β2GPI treated with the TRX-1/TRX-1 reductase/NADPH system and labeled with MPB was resolved on sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS-PAGE; Figure 1B). Gel bands were excised, digested, and analyzed by liquid chromatography–tandem mass spectrometry. Mass spectral data were searched using Mascot (Version 2.2; Matrix Science) or converted to MzXML file format using ReAdW (Version 4.0.2)3 and submitted to the database search program X!Tandem (Release 2008.12.01).4 The analysis revealed Cys326 to be predominantly labeled with biotin (F.H.P., S.R., M.Q., M.J.R., J.W.H.W., K.T., Y.I., J.Y.Z., R.G., J.C.Q., B.G., W.E.H., P.J.H., S.A.K., manuscript submitted). The structural features of the disulfide bond containing Cys326 and all disulfide bonds of the 2 structures of β2GPI (PDB 1C1Z and 1QUB) were determined using the disulfide bond analysis tool available at www.cancerresearch.unsw.edu.au/CRCWeb.nsf/page/Disulfide+Bond+Analysis.5 The analysis showed that the Cys288-Cys326 disulfide is a −/+ right-handed hook (−/+RHHook) configuration in both crystal structures of the protein.1,2 Although there is no other structural similarity with β2GPI, the active site disulfides of oxidoreductases like TRX-1 or PDI are +/− RHHooks. Of the 22 Cys residues in β2GPI, Cys326 stands out as being exposed to solvent. The solvent accessibility values for Cys326 are 117 (PDB ID 1C1Z) and 103 (PDB ID 1QUB) Å2 for the 2 structures. This high solvent exposure is consistent with reduction of the Cys288-Cys326 disulfide bond by thiol oxidoreductases.
Thiol oxidoreductases are becoming increasingly recognized as important mediators of platelet function.6 The prototype member, PDI, has been implicated in the activation of the fibrinogen receptor αIIbβ37 and tissue factor.8 Several novel members of the thiol isomerase family have been recently shown to translocate to the platelet surface after platelet activation.9 In the current issue of Blood, Ioannou et al have developed a sensitive and specific streptavidin-capture enzyme-linked immunosorbent assay (ELISA) to detect reduced β2GPI in plasma.10 With the same methodology β2GPI is shown to be reduced after incubation with platelets, which can be attributed partially to the TRX-1 system (Figure 1D).
This study is the first to show the potential of β2GPI to participate in thiol exchange reactions. Our finding suggests that β2GPI may participate in redox processes in vascular biology.
Authorship
Acknowledgments: The authors thank Dr I. Schousboe, University of Copenhagen, for the kind donation of native β2GPI.
Subsidized access (of M.J.R.) to the Bioanalytical Mass Spectrometry Facility of the University of New South Wales with infrastructure provided by the New South Wales government coinvestment in the National Collaborative Research Infrastructure Scheme is gratefully acknowledged.
This work was supported by research grants from the Australian National Health and Medical Research Council (to S.A.K.), by a research grant from the Foundation of the Greek Society of Hematology (to F.H.P.) and by an Arthritis Research Campaign Clinician Scientist Fellowship, United Kingdom (grant 17821 to Y.I.).
Contribution: F.H.P., S.R., and S.A.K. designed research; F.H.P., S.R., M.Q., M.J.R., K.T., and J.C.Q. performed research; R.G., J.W.H.W., P.J.H., and W.E.H. contributed new analytic tools; and F.H.P., S.R., M.J.R., J.W.H.W., Y. I., J.Y.Z., B.G., P.J.H., and S.A.K. wrote the paper.
Conflict-of-interest disclosure: The authors declare no competing financial interests.
Correspondence: Steven A. Krilis, Professor and Director, Department of Immunology, Allergy and Infectious Diseases, St George Hospital, University of New South Wales, 2 South St, Kogarah 2217, New South Wales, Australia; e-mail: [email protected].
References
Author notes
F.H.P. and S.R. contributed equally to the manuscript.