The physiology and biochemistry of prokaryotes:
Gespeichert in:
| 1. Verfasser: | |
|---|---|
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
New York [u.a.]
Oxford Univ. Press
2007
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| Ausgabe: | 3. ed. |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XIX, 628 S. Ill., graph. Darst. |
| ISBN: | 0195301684 9780195301687 |
Internformat
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| 100 | 1 | |a White, David |e Verfasser |4 aut | |
| 245 | 1 | 0 | |a The physiology and biochemistry of prokaryotes |c David White |
| 250 | |a 3. ed. | ||
| 264 | 1 | |a New York [u.a.] |b Oxford Univ. Press |c 2007 | |
| 300 | |a XIX, 628 S. |b Ill., graph. Darst. | ||
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| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 650 | 4 | |a Bactéries - Métabolisme | |
| 650 | 4 | |a Procaryotes - Physiologie | |
| 650 | 4 | |a Archaea |x physiology | |
| 650 | 4 | |a Bacteria |x metabolism | |
| 650 | 4 | |a Microbial metabolism | |
| 650 | 4 | |a Prokaryotes |x Physiology | |
| 650 | 4 | |a Prokaryotic Cells |x physiology | |
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Datensatz im Suchindex
| _version_ | 1804136238758756352 |
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| adam_text | THE PHYSIOLOGY AND BIOCHEMISTRY OF PROKARYOTES THIRD EDITION DAVID WHITE
INDIANA UNIVERSITY UI . ITI?L :;IU- UR.:I L.ANDES- B I B I I O T H E K D
A R M S *;;;: D T BIBLIOTHEK CIOICRJIA HV.-NR. OXFORD OXFORD UNIVERSITY
PRESS 2007 CONTENTS BOXED MATERIAL PREFACE SYMBOLS CONVERSION FACTORS,
EQUATIONS, AND UNITS OF ENERGY DEFINITIONS X XI XIII XV XVII CHAPTER 1.
STRUCTURE AND FUNCTION 1.1 PHYLOGENY 1.2 CELL STRUCTURE 1.3 SUMMARY
STUDY QUESTIONS 1 3 6 44 45 CHAPTER 2. GROWTH AND CELL DIVISION 2.1
MEASUREMENT OF GROWTH 2.2 GROWTH PHYSIOLOGY 2.3 CELL DIVISION . - 2.4
GROWTH YIELDS 2.5 GROWTH KINETICS 2.6 STEADY STATE GROWTH AND CONTINUOUS
GROWTH 2.7 SUMMARY STUDY QUESTIONS 53 53 55 64 70 71 73 74 75 CHAPTER 3
. MEMBRANE BIOENERGETICS: THE PROTON POTENTIAL 3.1 THE CHEMIOSMOTIC
THEORY 3.2 ELECTROCHEMICAL ENERGY 3.3 THE CONTRIBUTIONS OF THE A*F AND
THE APH TO THE OVERALL AP IN NEUTROPHILES, ACIDOPHILES, AND ALKALIPHILES
3.4 IONOPHORES 3.5 MEASUREMENT OF THE AP 3.6 USE OF THE AP TO DO WORK
3:7 EXERGONIC REACTIONS THAT GENERATE A AP 3.8 OTHER MECHANISMS FOR
CREATING A AT OR A AP 3.9 HALORHODOPSIN, A LIGHT-DRIVEN CHLORIDE PUMP
3.10 THE AP AND ATP SYNTHESIS IN ALKALIPHILES 3.11 SUMMARY * STUDY
QUESTIONS 83 83 84 90 91 93 94 98 102 112 112 112 114 VI CONTENTS
CHAPTER 4. ELECTRON TRANSPORT 120 4.1 AEROBIC AND ANAEROBIC RESPIRATION
121 4.2 THE ELECTRON CARRIERS 121 4.3 ORGANIZATION OF THE ELECTRON
CARRIERS IN MITOCHONDRIA 125 4.4 ORGANIZATION OF THE ELECTRON CARRIERS
IN BACTERIA 128 4.5 COUPLING SITES 130 4.6 HOW A PROTON POTENTIAL MIGHT
BE CREATED AT THE COUPLING SITES: Q LOOPS, Q CYCLES, AND PROTON PUMPS
132 4.7 PATTERNS OF ELECTRON FLOW IN INDIVIDUAL BACTERIAL SPECIES 137
4.8 SUMMARY 144 STUDY QUESTIONS - 145 CHAPTERS. PHOTOSYNTHESIS 5.1 THE
PHOTOTROPHIC PROKARYOTES 5.2 THE PURPLE PHOTOSYNTHETIC BACTERIA 5.3 THE
GREEN SULFUR BACTERIA (CHLORBIACEAE) 5.4 CYANOBACTERIA AND CHLOROPLASTS
5.5 EFFICIENCY OF PHOTOSYNTHESIS 5.6 PHOTOSYNTHETIC PIGMENTS 5.7 THE
TRANSFER OF ENERGY FROM THE LIGHT-HARVESTING PIGMENTS TO THE REACTION
CENTER 5.8 THE STRUCTURE OF PHOTOSYNTHETIC MEMBRANES IN BACTERIA 5.9
SUMMARY STUDY QUESTIONS 149 149 152 157 159 161 162 168 169 169 170
CHAPTER 6. THE REGULATION OF METABOLIC PATHWAYS 6.1 PATTERNS OF
REGULATION OF METABOLIC PATHWAYS 6.2 KINETICS OF REGULATORY AND
NONREGULATORY ENZYMES 6.3 CONFORMATIONAL CHANGES IN REGULATORY ENZYMES
6.4 REGULATION BY COVALENT MODIFICATION 6.5 SUMMARY STUDY QUESTIONS 173
173 175 178 178 179 179 CHAPTER 7. BIOENERGETICS IN THE CYTOSOL 7.1
HIGH-ENERGY MOLECULES AND GROUP TRANSFER POTENTIAL 7.2 THE CENTRAL ROLE
OF GROUP TRANSFER REACTIONS IN BIOSYNTHESIS 7.3 ATP SYNTHESIS BY
SUBSTRATE LEVEL PHOSPHORYLATION 7.4 SUMMARY **...! . * STUDY QUESTIONS
181 181 186 188 194 195 CHAPTER 8. CENTRAL METABOLIC PATHWAYS 196 8.1
GLYCOLYSIS .198 8.2 THEFATEOFNADH 204 8.3 WHY WRITE NAD + INSTEAD OF
NAD, AND NADH INSTEAD OF NADH 2 ? 204 8.4 A MODIFIED EMP PATHWAY IN THE
HYPERTHERMOPHILIC ARCHAEON ; PYROCOCCUS FURIOSUS * . 204 8.5 THE
PENTOSE PHOSPHATE PATHWAY ^ : 205 8.6 THE ENTNER-DOUDOROFF PATHWAY :.
210 8.7 THE OXIDATION OF PYRUVATE TO ACETYL-COA: THE PYRUVATE
DEHYDROGENASE REACTION . * * 213 8.8 THE CITRIC ACID CYCLE . * . 214 8.9
CARBOXYLATIONS THAT REPLENISH OXALOACETATE: THE PYRUVATE AND
PHOSPHOENOLPYRUVATE CARBOXYLASES * 219 8.10 MODIFICATION OF THE CITRIC
ACID CYCLE INTO A REDUCTIVE (INCOMPLETE) CYCLE DURING FERMENTATIVE
GROWTH 220 CONTENTS VLL 8.11 CHEMISTRYOF SOME OFTHE REACTIONS IN THE
CITRIC ACID CYCLE 221 8.12 THE GLYOXYLATE CYCLE ^ 223 8.13 FORMATION OF
PHOSPHOENOLPYRUVATE * 224 8.14 FORMATION OF PYRUVATE FROM MALATE 225
8.15 SUMMARY OF THE RELATIONSHIPS BETWEEN THE PATHWAYS 226 8.16 SUMMARY
226 STUDY QUESTIONS . 228 CHAPTER 9. METABOLISM OF LIPIDS, NUCLEOTIDES,
AMINO ACIDS, AND HYDROCARBONS 230 9.1 LIPIDS . 230 9.2 NUCLEOTIDES 238
9.3 AMIN O ACIDS 243 9.4 ALIPHATIC HYDROCARBONS 248 9.5 SUMMARY 251
STUDY QUESTIONS 253 CHAPTER 10. MACROMOLECULAR SYNTHESIS * 255 10.1
DNA REPLICATION, CHROMOSOME SEPARATION, ARID CHROMOSOME PARTITIONING 255
10.2 RNA SYNTHESIS * * 280 10.3 PROTEIN SYNTHESIS R * 293 10.4 SUMMARY
306 STUDY QUESTIONS * 308 CHAPTER 11. CELL WALL AND CAPSULE
BIOSYNTHESIS 318 11.1 PEPTIDOGLYCAN 318 11.2 LIPOPOLYSACCHARIDE 323 11.3
EXTRACELLULAR POLYSACCHARIDE SYNTHESIS AND EXPORT IN GRAM-NEGATIVE
BACTERIA 328 11.4 LEVAN AND DEXTRAN SYNTHESIS 333 11.5 GLYCOGEN
SYNTHESIS * 333 11.6 SUMMARY 333 STUDY QUESTIONS 334 CHAPTER 12.
INORGANIC METABOLISM 336 12.1 ASSIMILATION OF NITRATE AND SULFATE 336
12.2 DISSIMILATION OF NITRATE AND SULFATE 338 12.3 NITROGEN FIXATION
341 12.4 LITHOTROPHY 345 12.5 SUMMARY 355 STUDY QUESTIONS 356 CHAPTER
13. C, METABOLISM 359 13.1 JCARBON DIOXIDE FIXATION SYSTEMS 359 13.2
GROWTH ON Q COMPOUNDS OTHER THAN CO 2 : THE METHYLOTROPHS 375 13.3
SUMMARY , 378 STUDY QUESTIONS . , 380 CHAPTER 14. FERMENTATIONS 383 14.1
OXYGEN TOXICITY -. 383 14.2 ENERGY CONSERVATION BY ANAEROBIC BACTERIA
384 14.3 ELECTRON SINKS 386 14.4 THE ANAEROBIC FOOD CHAIN .-* * * 386
14.5 HOW TO BALANCE A FERMENTATION . : 387 14.6 PROPIONATE FERMENTATION
VIA THE ACRYLATE PATHWAY 388 14.7 PROPIONATE FERMENTATION VIA THE
SUCCINATE-PROPIONATE PATHWAY 389 VLLL CONTENTS 14.8 ACETATE
FERMENTATION (ACETOGENESIS) . 391 14.9 LACTATE FERMENTATION ^ 392 14.10
MIXED-ACID AND BUTANEDIOL FERMENTATION 394 14.11 BUTYRATE FERMENTATION
397 14.12 RUMINOCOCCUS ALBUS 400 14.13 SUMMARY 401 STUDY QUESTIONS , 402
CHAPTER 15. HOMEOSTASIS . 404 15.1 MAINTAINING A APH - 404 15.2 OSMOTIC
PRESSURE AND OSMOTIC POTENTIAL 407 15.3 SUMMARY 413 STUDY QUESTIONS 414
CHAPTER 16. SOLUTE TRANSPORT 417 16.1 THE USE OF PROTEOLIPOSOMES TO
STUDY SOLUTE TRANSPORT 417 16.2 KINETICS OF SOLUTE UPTAKE 418 16.3
ENERGY-DEPENDENT TRANSPORT * 419 16.4 HOW TO DETERMINE THE SOURCE OF
ENERGY FOR TRANSPORT * 429 16.5 DRUG-EXPORT SYSTEMS 430 16.6 BACTERIAL
TRANSPORT SYSTEMS IN SUMMARY 431 16.7 SUMMARY 431 STUDY QUESTIONS 434
CHAPTER 17. PROTEIN TRANSPORT 438 17.1 THE SEC SYSTEM 439 17.2 THE
TRANSLOCATION OF MEMBRANE-BOUND PROTEINS 443 17.3 THE E. COLI SRP 445
17.4 PROTEIN TRANSLOCATION OF FOLDED PROTEINS; THE TAT SYSTEM 445 17:5
EXTRACELLULAR PROTEIN SECRETION 447 17.6 FOLDING OF PERIPLASMIC PROTEINS
457 17.7 SUMMARY 459 STUDY QUESTIONS 460 CHAPTER 18. MICROBIAL
DEVELOPMENT AND PHYSIOLOGICAL ADAPTATION: VARIED RESPONSES TO
ENVIRONMENTAL CUES AND INTERCELLULAR SIGNALS 467 18.1 INTRODUCTION TO
TWO-COMPONENT SIGNALING SYSTEMS 469 18.2 RESPONSES BY FACULTATIVE
ANAEROBES TO ANAEROBIOSIS 474 18.3 RESPONSE TO NITRATE AND NITRITE: THE
NAR REGULATORY SYSTEM 480 18.4 RESPONSE TO NITROGEN SUPPLY: THE NTR
REGULON 484 18.5 RESPONSE TO INORGANIC PHOSPHATE SUPPLY: THE PHO REGULON
489 18.6 EFFECT OF OXYGEN AND LIGHT ON THE EXPRESSION OF PHOTOSYNTHETIC
GENES IN THE PURPLE PHOTOSYNTHETIC BACTERIUM RHODOBACTER CAPSULATUS 491
18.7 RESPONSE TO OSMOTIC PRESSURE AND TEMPERATURE: REGULATION OF PORIN
SYNTHESIS 492 18.8 RESPONSE TO POTASSIUM ION AND EXTERNAL OSMOLARITY:
STIMULATION OF TRANSCRIPTION OF THE KDPABC OPERON BY A TWO-COMPONENT
REGULATORY SYSTEM 494 18.9 ACETYL-PHOSPHATE IS A POSSIBLE GLOBAL SIGNAL
IN CERTAIN TWO-COMPONENT SYSTEMS 494 18.10 RESPONSE TO CARBON SOURCES:
CATABOLITE REPRESSION, INDUCER EXPULSION, PERMEASE SYNTHESIS 496 18.11
VIRULENCE FACTORS: SYNTHESIS IN RESPONSE TO TEMPERATURE, PH, NUTRIENT,
OSMOLARITY, AND QUORUM SENSORS 502 18.12 CHEMOTAXIS - 509 18.13
PHOTORESPONSES 519 CONTENTS IX 18.14 AEROTAXIS 522 18.15 INTRODUCTION TO
BACTERIAL DEVELOPMENT AND TO QUORUM SENSING 522 18.16 MYXOBACTERIA 523
18.17 CAULOBACTER DEVELOPMENT: CONTROL OF DNA REPLICATION AND CELL CYCLE
GENES 534 18.18 SPORULATION IN BACILLUS SUBTILIS 539 18.19 COMPETENCE IN
BACILLUS SUBTILIS 550 18.20 BIOLUMINESCENCE ^ 552 18.21 SYSTEMS SIMILAR
TO LUXR/LUXI IN NONLUMINESCENT BACTERIA 561 18.22 BIOFILMS 564 18.23
SUMMARY . 570 STUDY QUESTIONS 572 CHAPTER 19. HOW BACTERIA RESPOND TO
ENVIRONMENTAL STRESS 599 19.1 HEAT-SHOCK RESPONSE 599 19.2 REPAIRING
DAMAGED DNA 603 19.3 THE SOS RESPONSE 608 19.4 OXIDATIVE STRESS 611 19.5
SUMMARY 613 STUDY QUESTIONS 614 INDEX 617 BOXED MATERIAL 1.1. PHYLOGENY
4 1.2. NONFLAGELLAR MOTILITY 8 1.3. HISTORICAL PERSPECTIVE: CHRISTIAN
GRAM 19 1.4. TUBERCULOSIS 24 1.5. LEPROSY 27 2.1. TRANSCRIPTIONAL,
TRANSLATIONAL, AND POST-TRANSLATIONAL REGULATION OF LEVELS OF RPOS 60
3.1. HISTORICAL PERSPECTIVE: OXIDATIVE PHOSPHORYLATION 84 4.1.
HISTORICAL PERSPECTIVE: CELLULAR RESPIRATION 126 7.1. HISTORICAL
PERSPECTIVE: ENERGY TRANSFER IN THE CYTOSOL 182 8.1. HISTORICAL
PERSPECTIVE: CELL-FREE YEAST FERMENTATION AND THE BEGINNINGS OF
BIOCHEMISTRY 198 8.2. VITAMINS 214 8.3. HISTORICAL PERSPECTIVE: THE
CITRIC ACID CYCLE 216 10.1. HISTORICAL PERSPECTIVE: THE DISCOVERY OF DNA
AND ITS ROLE 256 10.2. HISTORICAL PERSPECTIVE: THE STRUCTURE OF DNA 257
17.1. SRP-DEPENDENT PROTEIN TRANSLOCATION ACROSS THE ENDOPLASMIC
RETICULUM MEMBRANE IN EUKARYOTES 446 18.1. PROTEINS INVOLVED IN
FORMATION OF THE SPORE SEPTUM AND CHROMOSOME PARTITIONING 541 18.2.
SPORULATION-SPECIFIC SIGMA FACTORS 544 18.3. ACTIVATION OF THE
TWO-COMPONENT REGULATORY SYSTEM BY CSF AND COMX 553 18.4. THE
BIOCHEMISTRY OF BACTERIAL LUMINESCENCE 555 19.1. HISTORICAL PERSPECTIVE:
THE MORSE CODE 609
|
| adam_txt |
THE PHYSIOLOGY AND BIOCHEMISTRY OF PROKARYOTES THIRD EDITION DAVID WHITE
INDIANA UNIVERSITY UI\. ITI?L':;IU- UR.:I L.ANDES- B I B I I O T H E K D
A R M S *;;;: D T BIBLIOTHEK CIOICRJIA HV.-NR. OXFORD OXFORD UNIVERSITY
PRESS 2007 CONTENTS BOXED MATERIAL PREFACE SYMBOLS CONVERSION FACTORS,
EQUATIONS, AND UNITS OF ENERGY DEFINITIONS X XI XIII XV XVII CHAPTER 1.
STRUCTURE AND FUNCTION 1.1 PHYLOGENY 1.2 CELL STRUCTURE 1.3 SUMMARY
STUDY QUESTIONS 1 3 6 44 45 CHAPTER 2. GROWTH AND CELL DIVISION 2.1
MEASUREMENT OF GROWTH 2.2 GROWTH PHYSIOLOGY 2.3 CELL DIVISION . - 2.4
GROWTH YIELDS 2.5 GROWTH KINETICS 2.6 STEADY STATE GROWTH AND CONTINUOUS
GROWTH 2.7 SUMMARY STUDY QUESTIONS 53 53 55 64 70 71 73 74 75 CHAPTER 3
. MEMBRANE BIOENERGETICS: THE PROTON POTENTIAL 3.1 THE CHEMIOSMOTIC
THEORY 3.2 ELECTROCHEMICAL ENERGY 3.3 THE CONTRIBUTIONS OF THE A*F AND
THE APH TO THE OVERALL AP IN NEUTROPHILES, ACIDOPHILES, AND ALKALIPHILES
3.4 IONOPHORES 3.5 MEASUREMENT OF THE AP 3.6 USE OF THE AP TO DO WORK
3:7 EXERGONIC REACTIONS THAT GENERATE A AP 3.8 OTHER MECHANISMS FOR
CREATING A AT OR A AP 3.9 HALORHODOPSIN, A LIGHT-DRIVEN CHLORIDE PUMP
3.10 THE AP AND ATP SYNTHESIS IN ALKALIPHILES 3.11 SUMMARY * STUDY
QUESTIONS 83 83 84 90 91 93 94 98 102 112 112 112 114 VI CONTENTS
CHAPTER 4. ELECTRON TRANSPORT 120 4.1 AEROBIC AND ANAEROBIC RESPIRATION
121 4.2 THE ELECTRON CARRIERS 121 4.3 ORGANIZATION OF THE ELECTRON
CARRIERS IN MITOCHONDRIA 125 4.4 ORGANIZATION OF THE ELECTRON CARRIERS
IN BACTERIA 128 4.5 COUPLING SITES 130 4.6 HOW A PROTON POTENTIAL MIGHT
BE CREATED AT THE COUPLING SITES: Q LOOPS, Q CYCLES, AND PROTON PUMPS
132 4.7 PATTERNS OF ELECTRON FLOW IN INDIVIDUAL BACTERIAL SPECIES 137
4.8 SUMMARY 144 STUDY QUESTIONS - 145 CHAPTERS. PHOTOSYNTHESIS 5.1 THE
PHOTOTROPHIC PROKARYOTES 5.2 THE PURPLE PHOTOSYNTHETIC BACTERIA 5.3 THE
GREEN SULFUR BACTERIA (CHLORBIACEAE) 5.4 CYANOBACTERIA AND CHLOROPLASTS
5.5 EFFICIENCY OF PHOTOSYNTHESIS 5.6 PHOTOSYNTHETIC PIGMENTS 5.7 THE
TRANSFER OF ENERGY FROM THE LIGHT-HARVESTING PIGMENTS TO THE REACTION
CENTER 5.8 THE STRUCTURE OF PHOTOSYNTHETIC MEMBRANES IN BACTERIA 5.9
SUMMARY STUDY QUESTIONS 149 149 152 157 159 161 162 168 169 169 170
CHAPTER 6. THE REGULATION OF METABOLIC PATHWAYS 6.1 PATTERNS OF
REGULATION OF METABOLIC PATHWAYS 6.2 KINETICS OF REGULATORY AND
NONREGULATORY ENZYMES 6.3 CONFORMATIONAL CHANGES IN REGULATORY ENZYMES
6.4 REGULATION BY COVALENT MODIFICATION 6.5 SUMMARY STUDY QUESTIONS 173
173 175 178 178 179 179 CHAPTER 7. BIOENERGETICS IN THE CYTOSOL 7.1
HIGH-ENERGY MOLECULES AND GROUP TRANSFER POTENTIAL 7.2 THE CENTRAL ROLE
OF GROUP TRANSFER REACTIONS IN BIOSYNTHESIS 7.3 ATP SYNTHESIS BY
SUBSTRATE LEVEL PHOSPHORYLATION 7.4 SUMMARY **.! . * STUDY QUESTIONS
181 181 186 188 194 195 CHAPTER 8. CENTRAL METABOLIC PATHWAYS 196 8.1
GLYCOLYSIS .198 8.2 THEFATEOFNADH 204 8.3 WHY WRITE NAD + INSTEAD OF
NAD, AND NADH INSTEAD OF NADH 2 ? 204 8.4 A MODIFIED EMP PATHWAY IN THE
HYPERTHERMOPHILIC ARCHAEON ; PYROCOCCUS FURIOSUS * . ' 204 8.5 THE
PENTOSE PHOSPHATE PATHWAY ^ ' : 205 8.6 THE ENTNER-DOUDOROFF PATHWAY :.
210 8.7 THE OXIDATION OF PYRUVATE TO ACETYL-COA: THE PYRUVATE
DEHYDROGENASE REACTION . * * 213 8.8 THE CITRIC ACID CYCLE . * . 214 8.9
CARBOXYLATIONS THAT REPLENISH OXALOACETATE: THE PYRUVATE AND
PHOSPHOENOLPYRUVATE CARBOXYLASES * 219 8.10 MODIFICATION OF THE CITRIC
ACID CYCLE INTO A REDUCTIVE (INCOMPLETE) CYCLE DURING FERMENTATIVE
GROWTH 220 CONTENTS VLL 8.11 CHEMISTRYOF SOME OFTHE REACTIONS IN THE
CITRIC ACID CYCLE 221 8.12 THE GLYOXYLATE CYCLE ^ 223 8.13 FORMATION OF
PHOSPHOENOLPYRUVATE * 224 8.14 FORMATION OF PYRUVATE FROM MALATE 225
8.15 SUMMARY OF THE RELATIONSHIPS BETWEEN THE PATHWAYS 226 8.16 SUMMARY
226 STUDY QUESTIONS . 228 CHAPTER 9. METABOLISM OF LIPIDS, NUCLEOTIDES,
AMINO ACIDS, AND HYDROCARBONS 230 9.1 LIPIDS . 230 9.2 NUCLEOTIDES 238
9.3 AMIN O ACIDS 243 9.4 ALIPHATIC HYDROCARBONS 248 9.5 SUMMARY 251
STUDY QUESTIONS \ 253 CHAPTER 10. MACROMOLECULAR SYNTHESIS * 255 10.1
DNA REPLICATION, CHROMOSOME SEPARATION, ARID CHROMOSOME PARTITIONING 255
10.2 RNA SYNTHESIS '* * 280 10.3 PROTEIN SYNTHESIS R * 293 10.4 SUMMARY
' 306 STUDY QUESTIONS * 308 CHAPTER 11. CELL WALL AND CAPSULE
BIOSYNTHESIS 318 11.1 PEPTIDOGLYCAN 318 11.2 LIPOPOLYSACCHARIDE 323 11.3
EXTRACELLULAR POLYSACCHARIDE SYNTHESIS AND EXPORT IN GRAM-NEGATIVE
BACTERIA 328 11.4 LEVAN AND DEXTRAN SYNTHESIS 333 11.5 GLYCOGEN
SYNTHESIS * 333 11.6 SUMMARY ' 333 STUDY QUESTIONS 334 CHAPTER 12.
INORGANIC METABOLISM 336 12.1 ASSIMILATION OF NITRATE AND SULFATE 336
12.2 DISSIMILATION OF NITRATE AND SULFATE ' 338 12.3 NITROGEN FIXATION '
341 12.4 LITHOTROPHY 345 12.5 SUMMARY 355 STUDY QUESTIONS 356 CHAPTER
13. C, METABOLISM 359 13.1 JCARBON DIOXIDE FIXATION SYSTEMS 359 13.2
GROWTH ON Q COMPOUNDS OTHER THAN CO 2 : THE METHYLOTROPHS 375 13.3
SUMMARY , 378 STUDY QUESTIONS . , 380 CHAPTER 14. FERMENTATIONS 383 14.1
OXYGEN TOXICITY -. 383 14.2 ENERGY CONSERVATION BY ANAEROBIC BACTERIA
384 14.3 ELECTRON SINKS 386 14.4 THE ANAEROBIC FOOD CHAIN .-* * * 386
14.5 HOW TO BALANCE A FERMENTATION . : 387 14.6 PROPIONATE FERMENTATION
VIA THE ACRYLATE PATHWAY 388 14.7 PROPIONATE FERMENTATION VIA THE
SUCCINATE-PROPIONATE PATHWAY 389 VLLL CONTENTS '' 14.8 ACETATE
FERMENTATION (ACETOGENESIS) . 391 14.9 LACTATE FERMENTATION ^ 392 14.10
MIXED-ACID AND BUTANEDIOL FERMENTATION 394 14.11 BUTYRATE FERMENTATION
397 14.12 RUMINOCOCCUS ALBUS 400 14.13 SUMMARY 401 STUDY QUESTIONS , 402
CHAPTER 15. HOMEOSTASIS . 404 15.1 MAINTAINING A APH - 404 15.2 OSMOTIC
PRESSURE AND OSMOTIC POTENTIAL 407 15.3 SUMMARY 413 STUDY QUESTIONS 414
CHAPTER 16. SOLUTE TRANSPORT 417 16.1 THE USE OF PROTEOLIPOSOMES TO
STUDY SOLUTE TRANSPORT 417 16.2 KINETICS OF SOLUTE UPTAKE 418 16.3
ENERGY-DEPENDENT TRANSPORT * 419 16.4 HOW TO DETERMINE THE SOURCE OF
ENERGY FOR TRANSPORT * 429 16.5 DRUG-EXPORT SYSTEMS 430 16.6 BACTERIAL
TRANSPORT SYSTEMS IN SUMMARY 431 16.7 SUMMARY 431 STUDY QUESTIONS 434
CHAPTER 17. PROTEIN TRANSPORT 438 17.1 THE SEC SYSTEM 439 17.2 THE
TRANSLOCATION OF MEMBRANE-BOUND PROTEINS 443 17.3 THE E. COLI SRP 445
17.4 PROTEIN TRANSLOCATION OF FOLDED PROTEINS; THE TAT SYSTEM 445 17:5
EXTRACELLULAR PROTEIN SECRETION 447 17.6 FOLDING OF PERIPLASMIC PROTEINS
457 17.7 SUMMARY 459 STUDY QUESTIONS 460 CHAPTER 18. MICROBIAL
DEVELOPMENT AND PHYSIOLOGICAL ADAPTATION: VARIED RESPONSES TO
ENVIRONMENTAL CUES AND INTERCELLULAR SIGNALS 467 18.1 INTRODUCTION TO
TWO-COMPONENT SIGNALING SYSTEMS " 469 18.2 RESPONSES BY FACULTATIVE
ANAEROBES TO ANAEROBIOSIS 474 18.3 RESPONSE TO NITRATE AND NITRITE: THE
NAR REGULATORY SYSTEM 480 18.4 RESPONSE TO NITROGEN SUPPLY: THE NTR
REGULON 484 18.5 RESPONSE TO INORGANIC PHOSPHATE SUPPLY: THE PHO REGULON
489 18.6 EFFECT OF OXYGEN AND LIGHT ON THE EXPRESSION OF PHOTOSYNTHETIC
GENES IN THE PURPLE PHOTOSYNTHETIC BACTERIUM RHODOBACTER CAPSULATUS 491
18.7 RESPONSE TO OSMOTIC PRESSURE AND TEMPERATURE: REGULATION OF PORIN
SYNTHESIS 492 18.8 RESPONSE TO POTASSIUM ION AND EXTERNAL OSMOLARITY:
STIMULATION OF TRANSCRIPTION OF THE KDPABC OPERON BY A TWO-COMPONENT
REGULATORY SYSTEM 494 18.9 ACETYL-PHOSPHATE IS A POSSIBLE GLOBAL SIGNAL
IN CERTAIN TWO-COMPONENT SYSTEMS 494 18.10 RESPONSE TO CARBON SOURCES:
CATABOLITE REPRESSION, INDUCER EXPULSION, PERMEASE SYNTHESIS 496 18.11
VIRULENCE FACTORS: SYNTHESIS IN RESPONSE TO TEMPERATURE, PH, NUTRIENT,
OSMOLARITY, AND QUORUM SENSORS 502 18.12 CHEMOTAXIS - 509 18.13
PHOTORESPONSES 519 CONTENTS IX 18.14 AEROTAXIS 522 18.15 INTRODUCTION TO
BACTERIAL DEVELOPMENT AND TO QUORUM SENSING 522 18.16 MYXOBACTERIA 523
18.17 CAULOBACTER DEVELOPMENT: CONTROL OF DNA REPLICATION AND CELL CYCLE
GENES 534 18.18 SPORULATION IN BACILLUS SUBTILIS 539 18.19 COMPETENCE IN
BACILLUS SUBTILIS 550 18.20 BIOLUMINESCENCE ^ 552 18.21 SYSTEMS SIMILAR
TO LUXR/LUXI IN NONLUMINESCENT BACTERIA 561 18.22 BIOFILMS 564 18.23
SUMMARY . 570 STUDY QUESTIONS 572 CHAPTER 19. HOW BACTERIA RESPOND TO
ENVIRONMENTAL STRESS 599 19.1 HEAT-SHOCK RESPONSE 599 19.2 REPAIRING
DAMAGED DNA 603 19.3 THE SOS RESPONSE 608 19.4 OXIDATIVE STRESS 611 19.5
SUMMARY 613 STUDY QUESTIONS 614 INDEX 617 BOXED MATERIAL 1.1. PHYLOGENY
4 1.2. NONFLAGELLAR MOTILITY 8 1.3. HISTORICAL PERSPECTIVE: CHRISTIAN
GRAM 19 1.4. TUBERCULOSIS 24 1.5. LEPROSY 27 2.1. TRANSCRIPTIONAL,
TRANSLATIONAL, AND POST-TRANSLATIONAL REGULATION OF LEVELS OF RPOS 60
3.1. HISTORICAL PERSPECTIVE: OXIDATIVE PHOSPHORYLATION 84 4.1.
HISTORICAL PERSPECTIVE: CELLULAR RESPIRATION 126 7.1. HISTORICAL
PERSPECTIVE: ENERGY TRANSFER IN THE CYTOSOL 182 8.1. HISTORICAL
PERSPECTIVE: CELL-FREE YEAST FERMENTATION AND THE BEGINNINGS OF
BIOCHEMISTRY 198 8.2. VITAMINS 214 8.3. HISTORICAL PERSPECTIVE: THE
CITRIC ACID CYCLE 216 10.1. HISTORICAL PERSPECTIVE: THE DISCOVERY OF DNA
AND ITS ROLE 256 10.2. HISTORICAL PERSPECTIVE: THE STRUCTURE OF DNA 257
17.1. SRP-DEPENDENT PROTEIN TRANSLOCATION ACROSS THE ENDOPLASMIC
RETICULUM MEMBRANE IN EUKARYOTES 446 18.1. PROTEINS INVOLVED IN
FORMATION OF THE SPORE SEPTUM AND CHROMOSOME PARTITIONING 541 18.2.
SPORULATION-SPECIFIC SIGMA FACTORS 544 18.3. ACTIVATION OF THE
TWO-COMPONENT REGULATORY SYSTEM BY CSF AND COMX 553 18.4. THE
BIOCHEMISTRY OF BACTERIAL LUMINESCENCE 555 19.1. HISTORICAL PERSPECTIVE:
THE MORSE CODE 609 |
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| building | Verbundindex |
| bvnumber | BV022245149 |
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| callnumber-raw | QR88 |
| callnumber-search | QR88 |
| callnumber-sort | QR 288 |
| callnumber-subject | QR - Microbiology |
| classification_rvk | WF 1350 WF 5200 WD 4000 |
| ctrlnum | (OCoLC)60414377 (DE-599)BVBBV022245149 |
| dewey-full | 571.2/93 |
| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 571 - Physiology & related subjects |
| dewey-raw | 571.2/93 |
| dewey-search | 571.2/93 |
| dewey-sort | 3571.2 293 |
| dewey-tens | 570 - Biology |
| discipline | Biologie |
| discipline_str_mv | Biologie |
| edition | 3. ed. |
| format | Book |
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| id | DE-604.BV022245149 |
| illustrated | Illustrated |
| index_date | 2024-07-02T16:37:26Z |
| indexdate | 2024-07-09T20:53:14Z |
| institution | BVB |
| isbn | 0195301684 9780195301687 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-015456021 |
| oclc_num | 60414377 |
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| owner_facet | DE-20 DE-703 DE-19 DE-BY-UBM DE-526 DE-11 |
| physical | XIX, 628 S. Ill., graph. Darst. |
| publishDate | 2007 |
| publishDateSearch | 2007 |
| publishDateSort | 2007 |
| publisher | Oxford Univ. Press |
| record_format | marc |
| spelling | White, David Verfasser aut The physiology and biochemistry of prokaryotes David White 3. ed. New York [u.a.] Oxford Univ. Press 2007 XIX, 628 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Bactéries - Métabolisme Procaryotes - Physiologie Archaea physiology Bacteria metabolism Microbial metabolism Prokaryotes Physiology Prokaryotic Cells physiology Bakterien (DE-588)4004296-0 gnd rswk-swf Prokaryoten (DE-588)4201051-2 gnd rswk-swf Physiologie (DE-588)4045981-0 gnd rswk-swf Biochemie (DE-588)4006777-4 gnd rswk-swf Prokaryoten (DE-588)4201051-2 s Biochemie (DE-588)4006777-4 s DE-604 Physiologie (DE-588)4045981-0 s Bakterien (DE-588)4004296-0 s HEBIS Datenaustausch Darmstadt application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015456021&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | White, David The physiology and biochemistry of prokaryotes Bactéries - Métabolisme Procaryotes - Physiologie Archaea physiology Bacteria metabolism Microbial metabolism Prokaryotes Physiology Prokaryotic Cells physiology Bakterien (DE-588)4004296-0 gnd Prokaryoten (DE-588)4201051-2 gnd Physiologie (DE-588)4045981-0 gnd Biochemie (DE-588)4006777-4 gnd |
| subject_GND | (DE-588)4004296-0 (DE-588)4201051-2 (DE-588)4045981-0 (DE-588)4006777-4 |
| title | The physiology and biochemistry of prokaryotes |
| title_auth | The physiology and biochemistry of prokaryotes |
| title_exact_search | The physiology and biochemistry of prokaryotes |
| title_exact_search_txtP | The physiology and biochemistry of prokaryotes |
| title_full | The physiology and biochemistry of prokaryotes David White |
| title_fullStr | The physiology and biochemistry of prokaryotes David White |
| title_full_unstemmed | The physiology and biochemistry of prokaryotes David White |
| title_short | The physiology and biochemistry of prokaryotes |
| title_sort | the physiology and biochemistry of prokaryotes |
| topic | Bactéries - Métabolisme Procaryotes - Physiologie Archaea physiology Bacteria metabolism Microbial metabolism Prokaryotes Physiology Prokaryotic Cells physiology Bakterien (DE-588)4004296-0 gnd Prokaryoten (DE-588)4201051-2 gnd Physiologie (DE-588)4045981-0 gnd Biochemie (DE-588)4006777-4 gnd |
| topic_facet | Bactéries - Métabolisme Procaryotes - Physiologie Archaea physiology Bacteria metabolism Microbial metabolism Prokaryotes Physiology Prokaryotic Cells physiology Bakterien Prokaryoten Physiologie Biochemie |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015456021&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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