A proposal for the Mg2+ binding site of P-type ion motive ATPases and the mechanism of phosphoryl group transfer.

Mutations of D586 in the DPPR sequence of sodium pump decrease the enzyme's affinity for inorganic phosphate [Farley R. A., Heart, E., Kabalin, M., Putnam, D., Wang, K., Kasho, V. N., and Faller, L. D. (1997) Biochemistry 36, 941-951]. Therefore, it was proposed that D586 coordinates the Mg2+ required for catalytic activity. This hypothesis is tested (1) by determining the substrate for catalysis of 18O exchange between inorganic phosphate and water and (2) by comparing conserved amino acid sequences in P-type pumps with the primary structures of enzymes of known tertiary structure that catalyze phosphoryl group transfer. From the isotope exchange data, it is concluded that the Mg2+-dependent and Na+- and K+-stimulated ATPase binds Mg2+ before inorganic phosphate. Sequence homology is demonstrated between the conserved DPPR and MV(I,L)TGD sequences of P-type pumps and two conserved adenylate kinase sequences that coordinate Mg2+ and/or bind nucleotide in the crystal structure of the yeast enzyme. A model for the Mg2+ site of P-type pumps and the mechanism of phosphoryl group transfer is proposed and tested by demonstrating that the conserved sequences are also structurally homologous.

Na,K-ATPase subunit isoforms in human reticulocytes: evidence from reverse transcription-PCR for the presence of alpha1, alpha3, beta2, beta3, and gamma.

The objective of this study has been to determine which Na,K-ATPase isoforms are expressed in red blood cells and whether kinetic differences in the uncoupled sodium efflux mode between the human red blood cell Na,K-ATPase and other preparations can be explained by differences in the underlying subunit composition. To this end, human reticulocyte RNA was isolated, reverse transcribed, amplified by PCR and appropriate primers, and sequenced. Primers from highly conserved areas as well as isoform-specific primers were used. The alpha1 and alpha3 isoforms of the alpha subunit, and the beta2 and beta3 isoforms of the beta subunit were found. The complete coding regions of the cDNAs for the reticulocyte subunits were sequenced from overlapping PCR fragments. No difference was found between the reticulocyte isoforms and the ones already known. The fact that we found beta2 but not beta1 in reticulocyte single-stranded cDNA, and beta1 but not beta2 in a leukocyte library indicates that leukocyte contamination of our reticulocyte preparation was negligible. Analysis of a human bone marrow library showed that alpha1, alpha2, and alpha3 as well as all three beta isoforms were present. The extent to which the kinetic properties of uncoupled sodium efflux might depend on different isoform combinations is not yet known.

Kinetics of transient pump currents generated by the (H,K)-ATPase after an ATP concentration jump.

(H,K)-ATPase containing membranes from hog stomach were attached to black lipid membranes. Currents induced by an ATP concentration jump were recorded and analyzed. A sum of three exponentials (tau 1(-1) approximately 400 sec-1, tau 2(-1) approximately 100 sec-1, tau 3(-1) approximately 10 sec-1; T = 300 K, pH 6, MgCl2 3 mM, no K+) was fitted to the transient signal. The dependence of the resulting time constants and the peak current on electrolyte composition, ATP conversion rate, temperature, and membrane conductivity was recorded. The results are consistent with a reaction scheme similar to that proposed by Albers and Post for the NaK-ATPase. Based on this model the following assignments were made: tau 2 corresponds to ATP binding and exchange with caged ATP. tau 1 describes the phosphorylation reaction E1 x ATP-->E1P. The third, slowest time constant tau 3 is tentatively assigned to the E1P-->E2P transition. This is the first electrogenic step and is accelerated at high pH and by ATP via a low affinity binding site. The second electrogenic step is the transition from E2K to E1H. The E2K<==>E1H equilibrium is influenced by potassium with an apparent K0.5 of 3 mM and by the pH. Low pH and low potassium concentration stabilize the E1 conformation.