113Cd NMR. Arsenate binding to Cd(II) alkaline phosphatase.

Abstract

Alkaline phosphatase from Escherichia coli contains three metal binding sites (A, B, and C) located at sites forming a triangle with sides of 4, 5, and 7 A (Wyckoff, H.W., Handschumacher, M., Murthy, K., and Sowadski, J.M. (1983) Adv. Enzymol. 55, 453). When all three sites are occupied by Cd(II) the enzyme has a very low turnover; at least 10(3) slower than the native Zn(II) enzyme. The slow turnover number has made the Cd(II) enzyme useful in NMR studies of the mechanism of alkaline phosphatase. The binding of arsenate to two forms of Cd(II) alkaline phosphatase (Cd(II)2alkaline phosphatase and Cd(II)6alkaline phosphatase) has been studied by 113Cd NMR. Cd(II)2alkaline phosphatase, pH 6.3, binds arsenate at only one monomer of the dimeric enzyme and causes migration of Cd(II) from the A site of one monomer to the B site of the arsenylated monomer. This same migration has previously been observed to accompany metal ion-dependent phosphate binding, but is much more rapid in the case of arsenate. The acceleration of migration induced by arsenate supports the conclusion based on the phosphate data that the substrate anion binds to the A site metal ion of one monomer prior to migration and that only the metal ion at A site is required for phosphorylation (arsenylation) of serine 102. The 113Cd chemical shifts of A and B site metal ions are very sensitive to the form of the bound arsenate, i.e. covalent (E-As) or noncovalent (E X As) complex. Like the analogous phosphate derivatives, the change of chemical shift of A site (to which phosphate is coordinated in the E X P complex) is much greater than that of the B site metal ion, when the arsenate shifts between the two intermediates, suggesting that arsenate is also coordinated to A site in the E X As intermediate. The chemical shifts of A and B site 113Cd(II) ions are considerably different in the arsenate and phosphate derivatives, while the C site 113Cd(II) ions have nearly identical chemical shifts. Thus the substrate appears to interact closely with both A and B sites, while C site appears relatively unimportant in phosphomonoester hydrolysis. The analogous behavior of arsenate and phosphate at the active center as evaluated by 113Cd NMR supports the validity of using the heavier arsenate derivative in x-ray diffraction studies.