Tryptic inactivation of the ouabain binding site of canine kidney Na+,K+-ATPase and its effect on catalytic function

Functional coupling of phosphorylation and nucleotide binding sites in the proteolytic fragments of Na+/K(+)-ATPase

Cleavage of the alpha-subunit of Na+/K(+)-ATPase by trypsin at Arg438-Ala439 causes enzyme inhibition which has been suggested to be due to altered alignment of phosphorylation site on the 48-kDa N-terminal fragment with nucleotide binding site on the 64-kDa C-terminal fragment. Our aims were to test this hypothesis and to assess the effect of the cleavage on the enzyme's two ATP sites. Na(+)-dependent phosphorylation of the partially cleaved enzyme by ATP showed that K0.5 values of ATP for phosphorylations of intact alpha and 48-kDa peptide were the same (0.4 microM). Unchanged interactions among the residues across the cleavage site were also indicated by data showing that reaction of fluorescein isothiocyanate with the 64-kDa peptide blocked phosphorylation of the 48-kDa peptide by ATP. ATP is known to block the reaction of fluorescein isothiocyanate with the enzyme. Experiments on the partially cleaved enzyme showed that K0.5 of ATP for protection of alpha was 30-60 microM, and the value for the protection of interacting 48-kDa and 64-kDa peptides was 1-3 mM. Evidently, while the cleavage does not affect the high affinity catalytic site, it disrupts the allosteric low affinity ATP site. Experiments on reconstituted preparations showed that the cleavage abolished ATP-dependent Na+/K+ exchange, Pi+ATP-dependent Rb+/Rb+ exchange, ATP-dependent Na+/Na+ exchange, and ADP+ATP-dependent Na+/Na+ exchange activities. Selective disruption of the low affinity ATP site accounts for the inhibitions of all functions involving K+(Rb+), based on the established role of this site in the control of K+ access channels. Cleavage-induced inhibitions of other activities, however, suggest additional roles of the low affinity ATP site in the reaction cycle.

Autoregulation of the phosphointermediate of Na+/K(+)-ATPase by the amino-terminal domain of the alpha-subunit

Chymotryptic cleavage of the alpha-subunit of the canine kidney Na+/K(+)-ATPase in the presence of Na+ abolishes ATPase activity and yields an 83 kDa peptide from Ala 267 to the COOH-terminus. To test the proposal that E1 to E2 conformational transition is blocked in this modified enzyme, we have made a detailed comparison of its phosphorylation with that of the native enzyme by ATP. While phosphorylation of alpha is dependent on Na+ and prevented by K+, that of the 83 kDa peptide is modestly stimulated by Na+; and only this stimulation, but not the Na(+)-independent phosphorylation is inhibited by K+. Ouabain, which inhibits alpha-phosphorylation by ATP, activates Na(+)-independent phosphorylation of the 83 kDa peptide by ATP, and inhibits the Na(+)-stimulation of this process. While there is a ouabain-stimulated phosphorylation of alpha by Pi, the 83 kDa peptide is not phosphorylated by Pi with or without ouabain. In its sensitivity to ADP, and insensitivity to K+, the phosphopeptide is similar to the E1P of the native enzyme; however, the spontaneous decomposition rate of the phosphopeptide is orders of magnitude lower than that of the native EP. Na+ has no effect on the spontaneous decomposition of the phosphopeptide; but at high Na+ concentrations (K0.5 = 350 mM) the ADP sensitivity of the phosphopeptide is reduced. The phosphopeptide, like the native EP, is acid-stable, alkaline-labile, and sensitive to hydroxylamine and molybdate. The chymotrypsin-treated enzyme catalyzes an ADP-ATP exchange activity that is stimulated by Na+. The Na(+)-independent part of this exchange, unlike that of the native enzyme, is activated by ouabain. Our findings establish that (a) the phosphorylation process and its control by Na+, K+ and ouabain are autoregulated by the NH2-terminal domain of the alpha-subunit; and (b) the often repeated assumption that the primary role of this domain is in the regulation of E1-E2 transitions is not valid.