Structural basis of the tight binding of pyridoxal 5'-phosphate to a low molecular weight protein tyrosine phosphatase.

Pyridoxal 5'-phosphate (PLP) binds tightly to bovine low Mr protein tyrosine phosphatase (BPTP), but it is a very poor substrate for the enzyme. The structural basis of this tight binding of PLP is examined here by a variety of methods. Binding constants of a number of PLP analogues were measured with wild-type BPTP, and PLP binding constants of some site-specific mutants of BPTP were determined at pH 5.0 through the use of several independent methods. The tight binding of PLP (Ki = 7.6 microM) causes a downfield shift of the His-72 Cepsilon1H resonance in the 1H NMR spectrum of the protein, consistent with a structural alteration in the phosphate binding loop transmitted through a complex hydrogen bond network that exists between His-72 and Asn-15, which is a residue in the phosphate binding loop. 1H NMR spectroscopy with an MLEV-17 spectral editing scheme was used to monitor the aldehyde resonance of PLP during titration of a catalytically inactive C12A mutant of BPTP. The aldehydic proton resonance of PLP shifted from 10.43 to 10.26 ppm upon complex formation with the C12A mutant. This resonance occurs far from the region where a hemithioacetal hydrogen would be expected to appear, consistent with the conclusion that the Cys-17 side chain of BPTP does not add to the aldehyde group of PLP. UV-visible spectrophotometric titration also supported this conclusion. The binding constant of PLP to a C17A mutant was similar to that exhibited with wild-type protein. These results show that Cys-17 makes virtually no contribution to the tight binding of PLP by BPTP, in contrast to a published report that it is "essential" for binding PLP. On the other hand, Asp-129 of BPTP was found to be very important for binding PLP. It is concluded that Asp-129 binds to the pyridinium nitrogen of PLP and that this renders Asp-129 effectively unavailable to serve its essential catalytic role as a general acid. The interactions described here should be useful in the design of specific inhibitors of this and related phosphotyrosyl protein phosphatases.