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140122 ||| eng |
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|a 9783642729782
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|a Skulachev, Vladimir P.
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|a Membrane Bioenergetics
|h Elektronische Ressource
|c by Vladimir P. Skulachev
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|a 1st ed. 1988
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|a Berlin, Heidelberg
|b Springer Berlin Heidelberg
|c 1988, 1988
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|a XIV, 442 p. 44 illus
|b online resource
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|a 4.6 Interrelation of Various Functions of H+-ATPase -- 5 ??¯H Consumers -- 5.1 ??¯H-Driven Chemical Work -- 5.2 ??¯H-Driven Osmotic Work -- 5.3 ??¯H-Driven Mechanical Work: Bacterial Motility -- 5.4 ??¯H as an Energy Source for Heat Production -- 6 ??¯H Regulation, Transmission and Buffering -- 6.1 Regulation of ??¯H -- 6.2 ??¯H Transmission -- 6.3 ??¯H Buffering -- 7 The Sodium World -- 7.1 ??¯Na Generators -- 7.2 Utilization of ??¯Na Produced by Primary ??¯Na Generators -- 7.3 How Often is the Na+ Cycle Used by Living Cells? -- 7.4 Probable Evolutionary Relationships of the Protonic and Sodium Worlds -- 7.5 Na+/H+ Antiport in the Animal Cell: H+ as a Secondary Messenger -- 7.6 A General Scheme of Interrelations of Protonic and Sodium Cycles -- 7.7 Membrane-Linked Energy Transductions whenNeither H+ nor Na+ is Involved -- 8 Membrane Bioenergetics Studies: An Outlook -- 8.1 Some Prospects for Fundamental Research -- 8.2 Towards Applied Membrane Bioenergetics --
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|a 1 Introduction -- 1.1 A “Biology Building” and the Place of Bioenergetics -- 1.2 Essential Definitions -- 1.3 ??¯H, ?p, ??¯Na and ?s -- 1.4 Adenosine Triphosphate -- 1.5 Membrane Lipids -- 1.6 Lipid Bilayer -- 1.7 Membrane Proteins -- 2 Specific Methods of Membrane Bioenergetics -- 2.1 Membrane Potential Measurement -- 2.2 ?pH Measurement -- 2.3 Measurement of Fast H+ Dissociation-Association -- 3 Primary ??¯H Generators -- 3.1 The Cyclic Photoredox Chain of Purple Bacteria -- 3.2 The Non-Cyclic Photoredox Chain of Green Bacteria -- 3.3 The Non-Cyclic Photoredox Chain of Chloroplasts and Cyanobacteria -- 3.4 The Respiratory Chain -- 3.5 Bacteriorhodopsin -- 3.6 Primary ??¯H Generators: Overview -- 4 Secondary ??¯H Generators: H+-ATPases -- 4.1 Definition and Classification -- 4.2 H+-ATPasesof Obligate Anaerobic Bacteria -- 4.3 H+-ATPase of the Plant and Fungal Outer Cell Membrane -- 4.4 H+-ATPase of Tonoplast -- 4.5 Non-Mitochondrial H+-ATPase in Animal Cells --
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|a 9 Membrane Bioenergetics: A Look into History -- 9.1 The First Ideas and Observations. Chemiosmotic Hypothesis -- 9.2 Uncouplers -- 9.3 ??¯H Across Natural Membranes -- 9.4 ??¯H Across Reconstituted Membranes -- 9.5 ATP Formation Supported by an Artifically Imposed ??¯H -- 9.6 Bacteriorhodopsin and Chimerical Proteoliposomes -- 9.7 The Latest History -- 9.8 Membrane Bioenergeticists and Their Outstanding Predecessors -- 10 References -- 11 Subject Index
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|a Biochemistry
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|a Biophysics
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|a eng
|2 ISO 639-2
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|b SBA
|a Springer Book Archives -2004
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|a 10.1007/978-3-642-72978-2
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|u https://doi.org/10.1007/978-3-642-72978-2?nosfx=y
|x Verlag
|3 Volltext
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|a 572
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|a Membrane bioenergetics is one of the most rapidly growing areas within physico-chemical biology. Main aspects treated in this book include energy conservation and utilization by membrane-linked molecular mechanisms such as intracellular respiration, photosynthesis, transport phenomena, rotation of bacterial flagella, and the regulation of heat production
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