Active site titration of the tyrosine phosphatases SHP-1 and PTP1B using aromatic disulfides. Reaction with the essential cysteine residue in the active site.

Aromatic disulfides were found to inactivate truncated forms of the SHP-1 and PTP1B phosphatases by reaction with the essential active site cysteine residue. For truncated SHP-1 at pH 5.0, the reaction proceeded through an initial burst phase followed by a slower secondary phase. Our experiments demonstrated that the burst phase corresponded to the reaction of the aromatic disulfide with the active site cysteine. The magnitude of the burst phase was found to measure the active enzyme concentration, and the rate of the burst reflected the reactivity of the active site cysteine. The data were consistent with a mechanism in which an intramolecular disulfide is formed between the active site cysteine and a proximal cysteine during the burst reaction. Aromatic disulfides were found to react with the active site cysteines of full-length SHP-1 and truncated PTP1B also. Using vanadate to mask the active site cysteine, the active enzyme concentration could be assayed by comparing product yields for the reaction with aromatic disulfides in the presence and absence of vanadate at pH 8.0. These findings demonstrate the utility of aromatic disulfides as active site titrants and reactivity probes for tyrosine phosphatases.

Regulation of protein tyrosine phosphatase 1C: opposing effects of the two src homology 2 domains.

The regulatory roles of the two src homology 2 (SH2) domains of protein tyrosine phosphatase 1C were investigated by comparing recombinant full-length PTP1C with mutants in which either the N-terminal SH2 (N-SH2) domain (PTP1C delta NSH2), the C-terminal SH2 (C-SH2) domain (PTP1C delta CSH2) or both SH2 domains were deleted (PTP1C delta NSH2 delta CSH2). This revealed that the SH2 domains have opposing and independent effects on activity: strong inhibition by N-SH2 (42-fold) and weak activation by C-SH2 (2.1-fold). C-SH2 caused activation across a wide pH range while N-SH2 inhibited most at neutral and high pH through a shift of the basic limb of the pH profile of kcat/Km, apparently via perturbation of an active-site pKa value. A phosphotyrosyl peptide derived from the erythropoietin receptor caused an approximately 30-fold activation of PTP1C and PTP1C delta CSH2 but had no effect on PTP1C delta NSH2 or PTP1C delta NSH2 delta CSH2, indicating that binding of this peptide to N-SH2 abolished its inhibition. Since C-SH2 separates N-SH2 from the catalytic domain in full-length PTP1C and activation is observed for PTP1C delta CSH2, it appears that the inhibitory effect of N-SH2 is independent of the position in the sequence and that intermolecular interactions may also be possible.