Энергетика биологических мембран - Скулачев В.П.
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1384. Siemens A., Walter R., Liaw L.-H., BernsM. W. Laser-stimulated fluorescence of submicrometer regions within single mitochondria of rhodamine-treated myocardial cells in culture // Proc. Nat. Acad. Sci. US. 1982. Vol. 79. P. 466—470.
1385. Siemens H. Mitochondrial Myopathien und Enzephalomyopathien. Neu-romuskulare und zentralnervose Erkrankungen infolge von Defekten des mitochondrialen oxydativen Stoffwechsels // Monatsschr. Kinderheilk.
1985. Bd. 133. S. 798—805.
1386. Sigrist-Nelson K., AzziA. The proteolipid subunit of the chloroplast adenosine triphosphatase complex. Reconstitution and demonstration of proton-conductive properties // J. Biol. Chem. 1980. Vol. 255. P. 10638-10643.
1387. .Silhavy I. J., Benson S. A., EmrS.D. Mechanisms of protein localization // Microbiol. Rev. 1983. Vol. 47. P. 313—344.
1388. Silver S. Transport of cations and anions // Bacterial transport / Ed.
B. P. Rosen (Microbiol. Ser.: Vol. 4): N. Y., Basel: Dekker, 1978. P. 221—324.
1389. Simpson L. The kinetoplast of the hemoflagellates // Intern. Rev. Cytol.
1972. Vol. 32. P. 139_207.
1390. Simpson S. J., Bendall M. R., Egan A . F., Vink R., Rogers M. J? High-field phosphorus NMR studies of the stoichiometry of the lactate / proton carrier in Streptococcus faecalis//Europ. J. Biochem. 1983. Vol. 136. P. 63—69.
1391. Skou J. С. The influence of some cations on an adenosine triphosphatase from peripheral nerves // Biochim. et biophys. acta. 1957. Vol. 23. P. 394—401.
1392. Skou J. C. Further investigations on a Mg2+ + Na+-activated adenosi-netriphosphatase possibly related to the active, linked transport of Na+ and K+ across the nerve membrane // Ibid. 1960. Vol. 42. P. 6—23.
Список литературы
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1393. Skulachev V. P. Regulation of the coupling of oxidation and phosphorylation // Proc. V Intern.' Biochem. Congr. Moscow. 1963. Vol. 5. P. 365-374.
1394. Skulachev V. P. Electric fields in coupling membranes//FEBS Lett.
1970. Vol. 11. P. 301—319.
1395. Skulachev V. P. Energy transformation in the respiratory chain // Curr. Top. Bioenerg. 1971. Vol. 4. P. 127—190.
1396. Skulachev V. P. The driving forces and mechanisms of ion transport through coupling membranes // FEB^Symp. 1972. Vol. 28. P. 371—385.
1397. Skulachev V. P. Redox and hydrolytic generators of electric potential (Дя|)) in coupling membranes // IX FEBS Meet. Abstr. Budapest, 1973. P. 208.
1398. Skulachev V. P. Electric generators in coupling membranes: direct measurements of the electrogenic activity, molecular mechanism and some specific functions // X FEBS Meet. Abstr. Paris, 1975a. P. 225—238.
1399. Skulachev V. P. Energy coupling in biological membranes: Current state and perspectives // Energy transducing mechanisms / Ed. E. Racker. L.: Butterworth: MTP, 1975b. P. 31—73.
1400. Skulachev V. P. Three stages of the bacteriorhodopsin-mediated electrogenesis: a single turnover study II Proc. XI FEBS Meet. Kopenhasen, 1977a. Vol. 45. P. 45-59.
1401. Skulachev V. P. Transmembrane electrochemical H+-potential as a convertible energy source for the living cell // FEBS Lett. 1977b. Vol. 74. P. 1—9.
1402. Skulachev V. P. Membrane-linked energy buffering as the biological function of Na+/K+ gradient // Ibid. 1978. Vol. 87. P. 171—179.
1403. Skulachev V. P. Na /K+ gradient as an energy reservoir in bacteria // Cation flux across biomembranes / Eds. J. Mukohata, L. Packer. N. Y.; San Francisco; L.: Acad, press, 1979a. P. 303—319.
1404. Skulachev V. P. Methods for reconstitution of the electrogenic function of membrane proteins // Meth. Enzymol. 1979b. Vol. 55. P. 751—776.
1405. Skulachev V. P. Transduction of light to electric energy in bacterial photosynthesis: a study by means of orthodox electrometer techniques // Photosynthesis in relation to model systems/Ed. J. Barber. Amsterdam; N. Y.; Oxford: Elsevier, 1979c. P. 175—188.
1406. Skulachev V. P. Integrating functions of biomembranes. Problems of lateral transport of energy, metabolites and electrons // Biochim. et biophys. acta. 1980a. Yol. 604. P. 297—320.
1407. Skulachev V. P. Membrane electricity as a convertible energy currency for the cell // Canad. J. Biochem. 1980b. Vol. 58. P. 161—175.
1408. Skulachev V. P. Pathways of generation and utilization of electrochemical potential of H+ ions in biomembranes // Sovjet scientific review. Sec. D / Ed. V. P. Skulachev. Amsterdam: OPA, 1980c. Vol. 1. P. 83—156.
1409. Skulachev V. P. Membrane electricity as a convertible energy currency for the cell // XI Intern. Biochem. Congr. Toronto, 1980d. P. 1—3.
1410. Skulachev V. P. The proton cycle: history and problems of the membrane-linked energy transduction, transmission and buffering 11 Chemiosmotic proton circuits in biological membranes / Ed. V. P. Skulachev, P. C. Hinkle. L.:; Addison-Wesley, 1981. P. 3—49.
1411. Skulachev V. P. Light-induced charge separation and formation of long-lived photoproducts as two distinct functions of animal rhodopsin //II Europ. bioenerg. conf. Lyon, 1982a. P. 347—348.
