The E2P-like state induced by magnesium fluoride complexes in the Na,K-ATPase. Kinetics of formation and interaction with Rb+

The first X-ray crystal structures of the Na,K-ATPase were obtained in the presence of magnesium and fluoride as E2(K₂)Mg–MgF₄, an E2∙Pi-like state capable to occlude K⁺ (or Rb⁺). This work presents a functional characterization of the crystallized form of the enzyme and proposes a model to explain the interaction between magnesium, fluoride and Rb⁺ with the Na,K-ATPase. We studied the effect of magnesium and magnesium fluoride complexes on the E1–E2 conformational transition and the kinetics of Rb⁺ exchange between the medium and the E2(Rb₂)Mg–MgF₄ state. Our results show that both in the absence and in the presence of Rb⁺, simultaneous addition of magnesium and fluoride stabilizes the Na,K-ATPase in an E2 conformation, presumably the E2Mg–MgF₄ complex, that is unable to shift to E1 upon addition of Na⁺. The time course of conformational change suggests the action of fluoride and magnesium at different steps of the E2Mg–MgF₄ formation. Increasing concentrations of fluoride revert along a sigmoid curve the drop in the level of occluded Rb⁺ caused by Mg^2 +. Na⁺-induced release of Rb⁺ from E2(Rb₂)Mg–MgF₄ occurs at the same rate as from E2(Rb₂) but is insensitive to ADP. The rate of Rb⁺ occlusion into the E2Mg–MgF₄ state is 5–8 times lower than that described for the E2Mg–vanadate complex. Since the E2Mg–MgF₄ and E2Mg–vanadate complexes represent different intermediates in the E2-P → E2 dephosphorylation sequence, the variation in occlusion rate could provide a tool to discriminate between these intermediates.     

Ion Selectivity of the Cytoplasmic Binding Sites of the Na,K-ATPase: I. Sodium Binding is Associated with a Conformational Rearrangement

To investigate Na⁺ binding to the ion-binding sites presented on the cytoplasmic side of the Na,K-ATPase, equilibrium Na⁺-titration experiments were performed using two fluorescent dyes, RH421 and FITC, to detect protein-specific actions. Fluorescence changes upon addition of Na⁺ in the presence of various Mg²⁺ concentrations were similar and could be fitted with a Hill function. The half-saturating concentrations and Hill coefficients determined were almost identical. As RH421 responds to binding of a Na⁺ ion to the third neutral site whereas FITC monitors conformational changes in the ATP-binding site or its environment, this result implies that electrogenic binding of the third Na⁺ ion is the trigger for a structural rearrangement of the ATP-binding moiety. This enables enzyme phosphorylation, which is accompanied by a fast occlusion of the Na⁺ ions and followed by the conformational transition E₁/E₂ of the protein. The coordinated action both at the ion and the nucleotide binding sites allows for the first time a detailed formulation of the mechanism of enzyme phosphorylation that occurs only when three Na⁺ ions are bound. Received: 8 October 1998/Revised: 29 December 1998     

Mapping of the Na+, K+-ATPase subunit α 2 (ATP1A2) and muscle phosphofructokinase (PFKM) genes in pig by somatic cell hybrid analysis

Two expressed sequence tags were isolated from a porcine skeletal muscle cDNA library and identified as the putative partial cDNAs of the porcine Na⁺, K⁺-ATPase subunit α 2 ( ATP1A2 ) and muscle phosphofructokinase ( PFKM ) genes after sequencing and homology search. Results of analysis of a pig–rodent somatic cell hybrid panel by PCR allowed the assignments of ATP1A2 to porcine chromosome (chr) 4 and of PFKM to porcine chr 5. These assignments support previously observed conservation of syntenic relationships between human chr 1 and porcine chr 4 and between human chr 12 and porcine chr 5.