p67phox binds to a newly identified site in Nox2 following the disengagement of an intramolecular bond-Canaan sighted?

Activation of the phagocyte NADPH oxidase involves a conformational change in Nox2. The effector in this process is p67phox and there is evidence for a change in the configuration of p67phox being required for binding to Nox2. To study this, we measured binding of p67phox to a library of Nox2 peptides and binding of NusA-Nox2 fusion proteins to p67phox . We found, serendipitously, that deletion of residues 259-279 in p67phox (p67phox Δ(259-279)), endowed it with the ability to bind selectively to Nox2 peptide 369-383 (peptide 28). There was no binding to scrambled Nox2 peptide 28 and to Nox4 peptide 28. Binding was cysteine independent and resistant to reducing and alkylating agents. Truncations of peptide 28 revealed that the actual binding site consisted of residues 375-383. Binding of p67phox Δ(259-279) to peptide 28 was mimicked by that of a (p67phox -RacGTP) chimera. Both p67phox Δ(259-279) and the (p67pho -RacGTP) chimera bound a NusA-Nox2 fusion protein, comprising residues 375-383. Specific single residue deletion mutants, within the p67phox sequence 259-279, were also bound to Nox2 peptide 28. Peptides synthesized to correspond to the 259-279 sequence in p67phox , were found to autobind p67phox , suggesting that an intramolecular bond exists in p67phox , one pole of which was located within residues 259-279. We conclude that "resting" p67phox exists in a "closed" conformation, generated by an intramolecular bond. Deletion of specific residues within the 259-279 sequence, in vitro, or interaction with RacGTP, in vivo, causes "opening" of the bond and results in binding of p67phox to a specific, previously unknown, site in Nox2.

Binding of p67phox to Nox2 is stabilized by disulfide bonds between cysteines in the 369 Cys-Gly-Cys371 triad in Nox2 and in p67phox.

A central event in the activation of the phagocyte NADPH oxidase involves binding of p67phox to the dehydrogenase region of Nox2. The identity of the binding site in Nox2 is unknown. By measuring binding of p67phox to synthetic Nox2 peptides, we previously identified a sequence corresponding to Nox2 residues 357-383, as a potential binding site. A key role was attributed to a 369 Cys-Gly-Cys371 triad, shared by peptides 357-371 (peptide 24) and 369-383 (peptide 28). In this study, we show that (1) oxidation of cysteines in peptides 24 and 28 by a variety of oxidants markedly enhances the binding of p67phox ; (2) replacing cysteines by arginine abolishes the response to oxidants and the enhanced binding of p67phox ; (3) oxidants act by generating an intramolecular disulfide bond linking cysteines 369 and 371, generating such bond during peptide synthesis reproduces the effect of oxidants; (4) for the disulfide bond to lead to enhanced binding, cysteines must be separated by an intervening residue; bonds joining adjacent cysteines, or cysteines located on two peptides, do not enhance binding; (5) dissociating disulfide bonds by reducing agents abolishes enhanced binding; (6) treating p67phox with the alkylating agent N-ethylmaleimide suppresses binding; and (7) mutating all nine cysteines in p67phox to serines abolishes binding and diminishes the ability of p67phox to support NADPH oxidase activation in vitro. Results show that the primary interaction of p67phox with Nox2 is followed by a stabilizing step, based on the establishment of disulfide bonds between cysteine(s) in the 369 Cys-Gly-Cys371 triad and cysteine(s) in p67phox .

The dehydrogenase region of the NADPH oxidase component Nox2 acts as a protein disulfide isomerase (PDI) resembling PDIA3 with a role in the binding of the activator protein p67 (phox.).

The superoxide (O(·-) 2)-generating NADPH oxidase of phagocytes consists of a membrane component, cytochrome b 558 (a heterodimer of Nox2 and p22 (phox) ), and four cytosolic components, p47 (phox) , p67 (phox) , p40 (phox) , and Rac. The catalytic component, responsible for O(·-) 2 generation, is Nox2. It is activated by the interaction of the dehydrogenase region (DHR) of Nox2 with the cytosolic components, principally with p67 (phox) . Using a peptide-protein binding assay, we found that Nox2 peptides containing a (369)CysGlyCys(371) triad (CGC) bound p67 (phox) with high affinity, dependent upon the establishment of a disulfide bond between the two cysteines. Serially truncated recombinant Nox2 DHR proteins bound p67 (phox) only when they comprised the CGC triad. CGC resembles the catalytic motif (CGHC) of protein disulfide isomerases (PDIs). This led to the hypothesis that Nox2 establishes disulfide bonds with p67 (phox) via a thiol-dilsulfide exchange reaction and, thus, functions as a PDI. Evidence for this was provided by the following: (1) Recombinant Nox2 protein, which contained the CGC triad, exhibited PDI-like disulfide reductase activity; (2) Truncation of Nox2 C-terminal to the CGC triad or mutating C369 and C371 to R, resulted in loss of PDI activity; (3) Comparison of the sequence of the DHR of Nox2 with PDI family members revealed three small regions of homology with PDIA3; (4) Two monoclonal anti-Nox2 antibodies, with epitopes corresponding to regions of Nox2/PDIA3 homology, reacted with PDIA3 but not with PDIA1; (5) A polyclonal anti-PDIA3 (but not an anti-PDIA1) antibody reacted with Nox2; (6) p67 (phox) , in which all cysteines were mutated to serines, lost its ability to bind to a Nox2 peptide containing the CGC triad and had an impaired capacity to support oxidase activity in vitro. We propose a model of oxidase assembly in which binding of p67 (phox) to Nox2 via disulfide bonds, by virtue of the intrinsic PDI activity of Nox2, stabilizes the primary interaction between the two components.