Yoshikazu Tahara scite author profile

Protein fractions of a higher-oligomer (H), (alphabeta)(2)-diprotomer (D) and alphabeta-protomer (P) were separated from dog kidney Na(+)/K(+)-ATPase solubilized in the presence of NaCl and KCl. Na(+)/K(+)-dependent interconversion of the oligomers was analysed using HPLC at 0 degrees C. With increasing KCl concentrations, the content or amount of D increased from 27.6 to 54.3% of total protein, i.e. DeltaC(max) = 26.7%. DeltaC(max) for the sum of D and H was equivalent to the absolute value of DeltaC(max) for P, regardless of the anion present, indicating that K(+) induced the conversion of P into D and/or H, and Na(+) had the opposite effect. When enzymes that had been denatured to varying degrees by aging were solubilized, DeltaC(max) increased linearly with the remaining ATPase activity. The magnitude of the interconversion could be explained based on an equilibrium of D <==> 2P, assuming 50-fold difference in the K(d) between KCl and NaCl, and coexistence of unconvertible oligomers, which comprised as much as 39% of the eluted protein. Oligomeric interconversion, determined as a function of the KCl or NaCl concentration, showed K(0.5)s of 64.8 microM and 6.50 mM for KCl and NaCl, respectively, implying that oligomeric interconversion was coupled with Na(+)/K(+)-binding to their active transport sites.

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Epigallocatechin-3-gallate is an inhibitor of Na+,K+-ATPase by favoring the E1 conformation

Ochiai

Takeda

Soeda

et al. 2009

Biochemical Pharmacology

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Functional signal peptide reduces bilayer thickness of phosphatidylcholine liposomes

Tahara¹,

Murata²,

Ohnishi³

et al. 1992

Biochemistry

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To investigate the interaction between a signal peptide and the lipid bilayer, two kinds of peptides, L8-M5 (L8 = MRL8PLAALG, M5 = KVFER) and L14-M5 (L14 = MRL14PLAALG), were examined in membranes composed of dioleoylphosphatidylcholine (DOPC). Peptides L8 and L14 are artificially designed signal sequences, and M5 is the N-terminal five residues of human lysozyme; L8 mediated effective secretion of human lysozyme in yeast, while L14 did not [Yamamoto, Y., et al. (1987) Biochem. Biophys. Res. Commun. 149, 431-436]. DOPC liposomes incorporating L8-M5 or L14-M5 were observed by electron cryomicroscopy as pairs of concentric circles, and the separation of the bilayer was measured along the membrane. Peptide L8-M5 was found to reduce the bilayer thickness, but L14-M5 did not. CD measurements revealed that L8-M5 adopted an alpha-helical conformation with random coil in the liposome membranes and that L14-M5 adopted a more helical and less random conformation than L8-M5. Fluorescence spectroscopy using both aqueous and membranous probes revealed that L8-M5 destabilized the lipid bilayer more strongly than L14-M5. These results suggest that functional L8-M5 reduces the bilayer thickness and destabilizes the lipid bilayer and that these activities are important for signal peptide function.

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Evaluation of the electrocardiographic transitional zone by cardiac computed tomography

Tahara

Mizuno

Ono

et al. 1991

Journal of Electrocardiology

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