Kinetic analysis of two closely related receptor-like protein-tyrosine-phosphatases, PTP alpha and PTP epsilon.

Among transmembrane protein-tyrosine-phosphatases, the membrane distal catalytic domain (D2) of protein-tyrosine-phosphatase alpha (PTP alpha) is unusual in having low but detectable activity in the absence of the membrane proximal catalytic domain (D1). To investigate the catalytic properties of PTP alpha D2 in association with D1, kinetic parameters of activity were established for PTP alpha D1D2 proteins containing an inactivating point mutation in D1 and/or D2. In this context, D2 activity was unchanged by the presence (N-terminal or C-terminal) or absence of inactive D1, and the presence or absence of inactive D2 affected the velocity but not the Km of D1 catalysis. While D1 appears to be the major catalytic contributor to PTP alpha activity, D2 possesses a significantly higher substrate-specific activity relative to wild-type D1D2 than the D2 domains of other protein-tyrosine-phosphatases. Also, PTP alpha D2 is an active phosphatase with comparable or better efficiency, on the basis of k(cat)/Km criteria, to some of the dual specificity phosphatases. Kinetic parameters of a closely related receptor-like protein-tyrosine-phosphatase, PTP epsilon, were determined. PTP epsilon D1 is the major, if not the only, catalytic moiety of PTP epsilon, and has much higher turnover numbers than D1 of PTP alpha. The PTP epsilon D2 activity is insignificant compared to that of PTP epsilon-D1D2, with lower turnover numbers than PTP alpha D2. Thus, the intrinsic activity of PTP alpha D2 is high compared to other D2 domains and, more outstandingly, its activity relative to D1 appears unique. These are also apparent upon in vitro assay of full-length PTP alpha catalytic mutants expressed in mammalian cells. Together. these results suggest potential catalytic and regulatory roles for PTP alpha D2, and that PTP alpha may be an optimal model transmembrane protein-tyrosine-phosphatase for investigating the former within the cell.