Hirotaka Ogawa scite author profile

Calcium ATPase is a member of the P-type ATPases that transport ions across the membrane against a concentration gradient. Here we have solved the crystal structure of the calcium ATPase of skeletal muscle sarcoplasmic reticulum (SERCA1a) at 2.6 A resolution with two calcium ions bound in the transmembrane domain, which comprises ten alpha-helices. The two calcium ions are located side by side and are surrounded by four transmembrane helices, two of which are unwound for efficient coordination geometry. The cytoplasmic region consists of three well separated domains, with the phosphorylation site in the central catalytic domain and the adenosine-binding site on another domain. The phosphorylation domain has the same fold as haloacid dehalogenase. Comparison with a low-resolution electron density map of the enzyme in the absence of calcium and with biochemical data suggests that large domain movements take place during active transport.

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Crystal structure of the sodium–potassium pump at 2.4 Å resolution

Shinoda

Ogawa

Cornelius

et al. 2009

Nature

584

579

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Sodium-potassium ATPase is an ATP-powered ion pump that establishes concentration gradients for Na(+) and K(+) ions across the plasma membrane in all animal cells by pumping Na(+) from the cytoplasm and K(+) from the extracellular medium. Such gradients are used in many essential processes, notably for generating action potentials. Na(+), K(+)-ATPase is a member of the P-type ATPases, which include sarcoplasmic reticulum Ca(2+)-ATPase and gastric H(+), K(+)-ATPase, among others, and is the target of cardiac glycosides. Here we describe a crystal structure of this important ion pump, from shark rectal glands, consisting of alpha- and beta-subunits and a regulatory FXYD protein, all of which are highly homologous to human ones. The ATPase was fixed in a state analogous to E2.2K(+).P(i), in which the ATPase has a high affinity for K(+) and still binds P(i), as in the first crystal structure of pig kidney enzyme at 3.5 A resolution. Clearly visualized now at 2.4 A resolution are coordination of K(+) and associated water molecules in the transmembrane binding sites and a phosphate analogue (MgF(4)(2-)) in the phosphorylation site. The crystal structure shows that the beta-subunit has a critical role in K(+) binding (although its involvement has previously been suggested) and explains, at least partially, why the homologous Ca(2+)-ATPase counter-transports H(+) rather than K(+), despite the coordinating residues being almost identical.

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Crystal structure of a Na+-bound Na+,K+-ATPase preceding the E1P state

Kanai

Ogawa

Vilsen

et al. 2013

Nature

285

366

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Na(+),K(+)-ATPase pumps three Na(+) ions out of cells in exchange for two K(+) taken up from the extracellular medium per ATP molecule hydrolysed, thereby establishing Na(+) and K(+) gradients across the membrane in all animal cells. These ion gradients are used in many fundamental processes, notably excitation of nerve cells. Here we describe 2.8 Å-resolution crystal structures of this ATPase from pig kidney with bound Na(+), ADP and aluminium fluoride, a stable phosphate analogue, with and without oligomycin that promotes Na(+) occlusion. These crystal structures represent a transition state preceding the phosphorylated intermediate (E1P) in which three Na(+) ions are occluded. Details of the Na(+)-binding sites show how this ATPase functions as a Na(+)-specific pump, rejecting K(+) and Ca(2+), even though its affinity for Na(+) is low (millimolar dissociation constant). A mechanism for sequential, cooperative Na(+) binding can now be formulated in atomic detail.

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Crystal structure of the sodium-potassium pump (Na ⁺ ,K ⁺ -ATPase) with bound potassium and ouabain

Ogawa

Shinoda

Cornelius

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

315

274

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The sodium-potassium pump (Na ؉ ,K ؉ -ATPase) is responsible for establishing Na ؉ and K ؉ concentration gradients across the plasma membrane and therefore plays an essential role in, for instance, generating action potentials. Cardiac glycosides, prescribed for congestive heart failure for more than 2 centuries, are efficient inhibitors of this ATPase. Here we describe a crystal structure of Na ؉ ,K ؉ -ATPase with bound ouabain, a representative cardiac glycoside, at 2.8 Å resolution in a state analogous to E2⅐2K ؉ ⅐Pi. Ouabain is deeply inserted into the transmembrane domain with the lactone ring very close to the bound K ؉ , in marked contrast to previous models. Due to antagonism between ouabain and K ؉ , the structure represents a low-affinity ouabain-bound state. Yet, most of the mutagenesis data obtained with the high-affinity state are readily explained by the present crystal structure, indicating that the binding site for ouabain is essentially the same. According to a homology model for the high affinity state, it is a closure of the binding cavity that confers a high affinity.cardiac glycosides ͉ crystallography

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Crystal structures of the calcium pump and sarcolipin in the Mg2+-bound E1 state

Toyoshima

Iwasawa

Ogawa

et al. 2013

Nature

209

277

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P-type ATPases are ATP-powered ion pumps that establish ion concentration gradients across biological membranes, and are distinct from other ATPases in that the reaction cycle includes an autophosphorylation step. The best studied is Ca(2+)-ATPase from muscle sarcoplasmic reticulum (SERCA1a), a Ca(2+) pump that relaxes muscle cells after contraction, and crystal structures have been determined for most of the reaction intermediates. An important outstanding structure is that of the E1 intermediate, which has empty high-affinity Ca(2+)-binding sites ready to accept new cytosolic Ca(2+). In the absence of Ca(2+) and at pH 7 or higher, the ATPase is predominantly in E1, not in E2 (low affinity for Ca(2+)), and if millimolar Mg(2+) is present, one Mg(2+) is expected to occupy one of the Ca(2+)-binding sites with a millimolar dissociation constant. This Mg(2+) accelerates the reaction cycle, not permitting phosphorylation without Ca(2+) binding. Here we describe the crystal structure of native SERCA1a (from rabbit) in this E1·Mg(2+) state at 3.0 Å resolution in addition to crystal structures of SERCA1a in E2 free from exogenous inhibitors, and address the structural basis of the activation signal for phosphoryl transfer. Unexpectedly, sarcolipin, a small regulatory membrane protein of Ca(2+)-ATPase, is bound, stabilizing the E1·Mg(2+) state. Sarcolipin is a close homologue of phospholamban, which is a critical mediator of β-adrenergic signal in Ca(2+) regulation in heart (for reviews, see, for example, refs 8-10), and seems to play an important role in muscle-based thermogenesis. We also determined the crystal structure of recombinant SERCA1a devoid of sarcolipin, and describe the structural basis of inhibition by sarcolipin/phospholamban. Thus, the crystal structures reported here fill a gap in the structural elucidation of the reaction cycle and provide a solid basis for understanding the physiological regulation of the calcium pump.

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Hirotaka Ogawa

Crystal structure of the calcium pump of sarcoplasmic reticulum at 2.6 Å resolution

Crystal structure of the sodium–potassium pump at 2.4 Å resolution

Crystal structure of a Na+-bound Na+,K+-ATPase preceding the E1P state

Crystal structure of the sodium-potassium pump (Na ⁺ ,K ⁺ -ATPase) with bound potassium and ouabain

Crystal structures of the calcium pump and sarcolipin in the Mg2+-bound E1 state

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Hirotaka Ogawa

Crystal structure of the calcium pump of sarcoplasmic reticulum at 2.6 Å resolution

Crystal structure of the sodium–potassium pump at 2.4 Å resolution

Crystal structure of a Na+-bound Na+,K+-ATPase preceding the E1P state

Crystal structure of the sodium-potassium pump (Na + ,K + -ATPase) with bound potassium and ouabain

Crystal structures of the calcium pump and sarcolipin in the Mg2+-bound E1 state

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Product

Resources

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Crystal structure of the sodium-potassium pump (Na ⁺ ,K ⁺ -ATPase) with bound potassium and ouabain