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Biology of the prokaryotes [[electronic resource] /] / edited by Joseph W. Lengeler, Gerhart Drews, Hans G. Schlegel
| Biology of the prokaryotes [[electronic resource] /] / edited by Joseph W. Lengeler, Gerhart Drews, Hans G. Schlegel |
| Pubbl/distr/stampa | Stuttgart ; ; New York, : Thieme |
| Descrizione fisica | 1 online resource (986 p.) |
| Disciplina | 579.3 |
| Altri autori (Persone) |
LengelerJoseph W
DrewsG (Gerhart) SchlegelHans Günter <1924-> |
| Soggetto topico |
Prokaryotes
Microorganisms Procariotes Bacteris |
| Soggetto genere / forma | Llibres electrònics |
| ISBN |
1-282-68308-X
9786612683084 1-61344-556-3 1-4443-1331-2 1-4443-1330-4 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Biology of the Prokaryotes; Contents; 1: Bacteriology Paved the Way to Cell Biology: a Historical Account; 1.1 New Concepts and Experimental Approaches Paved the Way for Progress; 1.2 Observations and Speculation Lead to the First Concept of the Existence of Living Infectious Agents; 1.3 Bacteria are Members of a New, Large Group of Independent Organisms; 1.4 The Introduction of Solid, Defined Media and Pure-Culture Methods Marks a True Revolution; 1.5 The New Bacteriological Methods Proved that the Causative Agents of Infectious Diseases are Bacteria
1.6 Studies on Fermentation Founded Bacterial Physiology and Biochemistry1.7 Lithoautotrophy Is the Ability of Bacteria to Obtain Energy from the Oxidation of Inorganic Compounds and Carbon from Carbon Dioxide; 1.8 Light-Dependent Processes such as Phototaxis, Light-Induced Energy Transduction, and Photoassimilation of Carbon Dioxide Took a long Time to be Understood; 1.9 Dinitrogen Fixation Is Unique to the Prokaryotes; 1.10 The Analysis of Anabolic and Catabolic Metabolism Lead to the Discovery of Substrates, Products, Apoenzymes, and Coenzymes, and, in the end, of Metabolic Pathways 1.11 Studies on Inclusion Bodies and the Structures and Functions of Cell Envelopes Revealed the Organization of the Bacterial Cell1.12 Bacterial Adaptation was Well Recognized Before the Genetic Approach Revealed the Basis of Molecular Mechanisms of Regulation; 1.13 Studies on the Metabolic Types of Bacteria Revealed Their Functions in the Biosphere; 1.14 The Goals and Methods of the Classification of Bacteria Have Changed; 1.15 Bacterial Viruses (Bacteriophages) Were Detected as Lytic Principles 1.16 Studies on Heredity in Bacteria Provided the Decisive Principles and Concepts for the Promotion of Modern Biology Including Gene Technology1.17 Epilogue; Section I: The Prokaryotic Cell; 2: Cellular and Subcellular Organization of Prokaryotes; 2.1 Prokaryotes, Though Small, Contain all Structural Elements Necessary for Survival and Multiplication; 2.2 Cellular Structures Can Be Made Visible or Identified by Numerous Methods; 2.3 Prokaryotes May Occur as Single Cells or as Cell Associations 2.4 The Structural Components of Prokaryotic Cell Envelopes Are Organized as Barriers and Interfaces2.5 The Setup of the Intracellular Structures Reflects the High Degree of Organization in the Prokaryotic Cell; 2.6 Cell Appendages Serve for Locomotion and Cell Recognition; 2.7 Bacteria May Form Spores and Other Resting Cells; Section II: Basic Prerequisites for Cellular Life; 3: Substrate-Level Phosphorylation; 3.1 ATP Synthesis Is Coupled to Exergonic Reactions; 3.2 The ATP Yield Is a Function of the Free Energy of the Driving Reaction 3.3 Coupling of ATP Synthesis to Glucose Degradation Requires C-C Cleavage and Subsequent Oxidation |
| Record Nr. | UNINA-9910139784403321 |
| Stuttgart ; ; New York, : Thieme | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Biology of the prokaryotes [[electronic resource] /] / edited by Joseph W. Lengeler, Gerhart Drews, Hans G. Schlegel
| Biology of the prokaryotes [[electronic resource] /] / edited by Joseph W. Lengeler, Gerhart Drews, Hans G. Schlegel |
| Pubbl/distr/stampa | Stuttgart ; ; New York, : Thieme |
| Descrizione fisica | 1 online resource (986 p.) |
| Disciplina | 579.3 |
| Altri autori (Persone) |
LengelerJoseph W
DrewsG (Gerhart) SchlegelHans Günter <1924-> |
| Soggetto topico |
Prokaryotes
Microorganisms Procariotes Bacteris |
| Soggetto genere / forma | Llibres electrònics |
| ISBN |
1-282-68308-X
9786612683084 1-61344-556-3 1-4443-1331-2 1-4443-1330-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Biology of the Prokaryotes; Contents; 1: Bacteriology Paved the Way to Cell Biology: a Historical Account; 1.1 New Concepts and Experimental Approaches Paved the Way for Progress; 1.2 Observations and Speculation Lead to the First Concept of the Existence of Living Infectious Agents; 1.3 Bacteria are Members of a New, Large Group of Independent Organisms; 1.4 The Introduction of Solid, Defined Media and Pure-Culture Methods Marks a True Revolution; 1.5 The New Bacteriological Methods Proved that the Causative Agents of Infectious Diseases are Bacteria
1.6 Studies on Fermentation Founded Bacterial Physiology and Biochemistry1.7 Lithoautotrophy Is the Ability of Bacteria to Obtain Energy from the Oxidation of Inorganic Compounds and Carbon from Carbon Dioxide; 1.8 Light-Dependent Processes such as Phototaxis, Light-Induced Energy Transduction, and Photoassimilation of Carbon Dioxide Took a long Time to be Understood; 1.9 Dinitrogen Fixation Is Unique to the Prokaryotes; 1.10 The Analysis of Anabolic and Catabolic Metabolism Lead to the Discovery of Substrates, Products, Apoenzymes, and Coenzymes, and, in the end, of Metabolic Pathways 1.11 Studies on Inclusion Bodies and the Structures and Functions of Cell Envelopes Revealed the Organization of the Bacterial Cell1.12 Bacterial Adaptation was Well Recognized Before the Genetic Approach Revealed the Basis of Molecular Mechanisms of Regulation; 1.13 Studies on the Metabolic Types of Bacteria Revealed Their Functions in the Biosphere; 1.14 The Goals and Methods of the Classification of Bacteria Have Changed; 1.15 Bacterial Viruses (Bacteriophages) Were Detected as Lytic Principles 1.16 Studies on Heredity in Bacteria Provided the Decisive Principles and Concepts for the Promotion of Modern Biology Including Gene Technology1.17 Epilogue; Section I: The Prokaryotic Cell; 2: Cellular and Subcellular Organization of Prokaryotes; 2.1 Prokaryotes, Though Small, Contain all Structural Elements Necessary for Survival and Multiplication; 2.2 Cellular Structures Can Be Made Visible or Identified by Numerous Methods; 2.3 Prokaryotes May Occur as Single Cells or as Cell Associations 2.4 The Structural Components of Prokaryotic Cell Envelopes Are Organized as Barriers and Interfaces2.5 The Setup of the Intracellular Structures Reflects the High Degree of Organization in the Prokaryotic Cell; 2.6 Cell Appendages Serve for Locomotion and Cell Recognition; 2.7 Bacteria May Form Spores and Other Resting Cells; Section II: Basic Prerequisites for Cellular Life; 3: Substrate-Level Phosphorylation; 3.1 ATP Synthesis Is Coupled to Exergonic Reactions; 3.2 The ATP Yield Is a Function of the Free Energy of the Driving Reaction 3.3 Coupling of ATP Synthesis to Glucose Degradation Requires C-C Cleavage and Subsequent Oxidation |
| Record Nr. | UNISA-996200240203316 |
| Stuttgart ; ; New York, : Thieme | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. di Salerno | ||
| ||
Biology of the prokaryotes [[electronic resource] /] / edited by Joseph W. Lengeler, Gerhart Drews, Hans G. Schlegel
| Biology of the prokaryotes [[electronic resource] /] / edited by Joseph W. Lengeler, Gerhart Drews, Hans G. Schlegel |
| Pubbl/distr/stampa | Stuttgart ; ; New York, : Thieme |
| Descrizione fisica | 1 online resource (986 p.) |
| Disciplina | 579.3 |
| Altri autori (Persone) |
LengelerJoseph W
DrewsG (Gerhart) SchlegelHans Günter <1924-> |
| Soggetto topico |
Prokaryotes
Microorganisms Procariotes Bacteris |
| Soggetto genere / forma | Llibres electrònics |
| ISBN |
1-282-68308-X
9786612683084 1-61344-556-3 1-4443-1331-2 1-4443-1330-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Biology of the Prokaryotes; Contents; 1: Bacteriology Paved the Way to Cell Biology: a Historical Account; 1.1 New Concepts and Experimental Approaches Paved the Way for Progress; 1.2 Observations and Speculation Lead to the First Concept of the Existence of Living Infectious Agents; 1.3 Bacteria are Members of a New, Large Group of Independent Organisms; 1.4 The Introduction of Solid, Defined Media and Pure-Culture Methods Marks a True Revolution; 1.5 The New Bacteriological Methods Proved that the Causative Agents of Infectious Diseases are Bacteria
1.6 Studies on Fermentation Founded Bacterial Physiology and Biochemistry1.7 Lithoautotrophy Is the Ability of Bacteria to Obtain Energy from the Oxidation of Inorganic Compounds and Carbon from Carbon Dioxide; 1.8 Light-Dependent Processes such as Phototaxis, Light-Induced Energy Transduction, and Photoassimilation of Carbon Dioxide Took a long Time to be Understood; 1.9 Dinitrogen Fixation Is Unique to the Prokaryotes; 1.10 The Analysis of Anabolic and Catabolic Metabolism Lead to the Discovery of Substrates, Products, Apoenzymes, and Coenzymes, and, in the end, of Metabolic Pathways 1.11 Studies on Inclusion Bodies and the Structures and Functions of Cell Envelopes Revealed the Organization of the Bacterial Cell1.12 Bacterial Adaptation was Well Recognized Before the Genetic Approach Revealed the Basis of Molecular Mechanisms of Regulation; 1.13 Studies on the Metabolic Types of Bacteria Revealed Their Functions in the Biosphere; 1.14 The Goals and Methods of the Classification of Bacteria Have Changed; 1.15 Bacterial Viruses (Bacteriophages) Were Detected as Lytic Principles 1.16 Studies on Heredity in Bacteria Provided the Decisive Principles and Concepts for the Promotion of Modern Biology Including Gene Technology1.17 Epilogue; Section I: The Prokaryotic Cell; 2: Cellular and Subcellular Organization of Prokaryotes; 2.1 Prokaryotes, Though Small, Contain all Structural Elements Necessary for Survival and Multiplication; 2.2 Cellular Structures Can Be Made Visible or Identified by Numerous Methods; 2.3 Prokaryotes May Occur as Single Cells or as Cell Associations 2.4 The Structural Components of Prokaryotic Cell Envelopes Are Organized as Barriers and Interfaces2.5 The Setup of the Intracellular Structures Reflects the High Degree of Organization in the Prokaryotic Cell; 2.6 Cell Appendages Serve for Locomotion and Cell Recognition; 2.7 Bacteria May Form Spores and Other Resting Cells; Section II: Basic Prerequisites for Cellular Life; 3: Substrate-Level Phosphorylation; 3.1 ATP Synthesis Is Coupled to Exergonic Reactions; 3.2 The ATP Yield Is a Function of the Free Energy of the Driving Reaction 3.3 Coupling of ATP Synthesis to Glucose Degradation Requires C-C Cleavage and Subsequent Oxidation |
| Record Nr. | UNINA-9910829944803321 |
| Stuttgart ; ; New York, : Thieme | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Biology of the prokaryotes / / edited by Joseph W. Lengeler, Gerhart Drews, Hans G. Schlegel
| Biology of the prokaryotes / / edited by Joseph W. Lengeler, Gerhart Drews, Hans G. Schlegel |
| Pubbl/distr/stampa | Stuttgart ; ; New York, : Thieme |
| Descrizione fisica | 1 online resource (986 p.) |
| Disciplina | 579.3 |
| Altri autori (Persone) |
LengelerJoseph W
DrewsG (Gerhart) SchlegelHans Gunter <1924-> |
| Soggetto topico |
Prokaryotes
Microorganisms |
| ISBN |
1-282-68308-X
9786612683084 1-61344-556-3 1-4443-1331-2 1-4443-1330-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Biology of the Prokaryotes; Contents; 1: Bacteriology Paved the Way to Cell Biology: a Historical Account; 1.1 New Concepts and Experimental Approaches Paved the Way for Progress; 1.2 Observations and Speculation Lead to the First Concept of the Existence of Living Infectious Agents; 1.3 Bacteria are Members of a New, Large Group of Independent Organisms; 1.4 The Introduction of Solid, Defined Media and Pure-Culture Methods Marks a True Revolution; 1.5 The New Bacteriological Methods Proved that the Causative Agents of Infectious Diseases are Bacteria
1.6 Studies on Fermentation Founded Bacterial Physiology and Biochemistry1.7 Lithoautotrophy Is the Ability of Bacteria to Obtain Energy from the Oxidation of Inorganic Compounds and Carbon from Carbon Dioxide; 1.8 Light-Dependent Processes such as Phototaxis, Light-Induced Energy Transduction, and Photoassimilation of Carbon Dioxide Took a long Time to be Understood; 1.9 Dinitrogen Fixation Is Unique to the Prokaryotes; 1.10 The Analysis of Anabolic and Catabolic Metabolism Lead to the Discovery of Substrates, Products, Apoenzymes, and Coenzymes, and, in the end, of Metabolic Pathways 1.11 Studies on Inclusion Bodies and the Structures and Functions of Cell Envelopes Revealed the Organization of the Bacterial Cell1.12 Bacterial Adaptation was Well Recognized Before the Genetic Approach Revealed the Basis of Molecular Mechanisms of Regulation; 1.13 Studies on the Metabolic Types of Bacteria Revealed Their Functions in the Biosphere; 1.14 The Goals and Methods of the Classification of Bacteria Have Changed; 1.15 Bacterial Viruses (Bacteriophages) Were Detected as Lytic Principles 1.16 Studies on Heredity in Bacteria Provided the Decisive Principles and Concepts for the Promotion of Modern Biology Including Gene Technology1.17 Epilogue; Section I: The Prokaryotic Cell; 2: Cellular and Subcellular Organization of Prokaryotes; 2.1 Prokaryotes, Though Small, Contain all Structural Elements Necessary for Survival and Multiplication; 2.2 Cellular Structures Can Be Made Visible or Identified by Numerous Methods; 2.3 Prokaryotes May Occur as Single Cells or as Cell Associations 2.4 The Structural Components of Prokaryotic Cell Envelopes Are Organized as Barriers and Interfaces2.5 The Setup of the Intracellular Structures Reflects the High Degree of Organization in the Prokaryotic Cell; 2.6 Cell Appendages Serve for Locomotion and Cell Recognition; 2.7 Bacteria May Form Spores and Other Resting Cells; Section II: Basic Prerequisites for Cellular Life; 3: Substrate-Level Phosphorylation; 3.1 ATP Synthesis Is Coupled to Exergonic Reactions; 3.2 The ATP Yield Is a Function of the Free Energy of the Driving Reaction 3.3 Coupling of ATP Synthesis to Glucose Degradation Requires C-C Cleavage and Subsequent Oxidation |
| Record Nr. | UNINA-9910876578603321 |
| Stuttgart ; ; New York, : Thieme | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Circadian rhythms in bacteria and microbiomes / / Carl Hirschie Johnson and Michael Joseph Rust (editors)
| Circadian rhythms in bacteria and microbiomes / / Carl Hirschie Johnson and Michael Joseph Rust (editors) |
| Pubbl/distr/stampa | Cham, Switzerland : , : Springer, , [2021] |
| Descrizione fisica | 1 online resource (424 pages) |
| Disciplina | 579.3 |
| Soggetto topico |
Prokaryotes
Circadian rhythms Procariotes Ritmes circadiaris |
| Soggetto genere / forma | Llibres electrònics |
| ISBN | 3-030-72158-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Intro -- Dedications -- Dedication to Dr. Carol Rae Andersson (May 5, 1965-January 24, 2009) She left us too soon! -- Dedication to Dr. Yohko Kitayama (1976-2016) -- To Takao Kondo on the Occasion of His Retirement -- Acknowledgments -- References -- Preface -- Contents -- The Bacterial Perspective on Circadian Clocks -- 1 The ``No Clocks in Proks´´ Dogma -- 2 Data Dethroned the Dogma: Circadian Rhythms in Cyanobacteria -- 3 Establishing the Synechococcus elongatus PCC 7942 Model System -- References -- Part I: The Circadian Clock System in Cyanobacteria: Pioneer of Bacterial Clocks -- Around the Circadian Clock: Review and Preview -- 1 With Duckweed -- 2 At the National Institute for Basic Biology -- 3 Plant Physiology -- 4 Cloning of the per Gene -- 5 Phototaxis of Chlamydomonas reinhardtii -- 6 Sabbatical: Toward a New Experimental System for Circadian Clocks -- 7 Meeting Dr. Susan Golden -- 8 Whispers of Bioluminescence -- 9 Japan-USA Joint Research -- 10 Design and Fabrication of Bioluminescence Measurement System -- 11 Development of LCM and LCA: With Inside Macintosh -- 12 Mutant Screening and Complementation by Library -- 13 Discovery of the KaiABC Clock Gene Cluster -- 14 Return to Nagoya University -- 15 What ``Not to Do´´ -- 16 Cyanobacterial Transcription and Translation Model: Central Dogma in a Loop? -- 17 Obligate Photoautotrophy: Key to the Circadian Paradox -- 18 Reconstitution Experiment -- 19 Perfect Circadian Oscillation -- 20 The CI-ATPase Activity of KaiC Determines the Period -- 21 Review and Preview -- 22 Inside KaiC -- 23 Harmonic and Relaxation Oscillation -- 24 About Mechanical Clocks -- 25 Dual ATPases Coupling Model for KaiC Circadian Oscillator -- 26 ATPase Measurement -- 27 What Is the ``Tension that Determines the Period?´´ -- 28 Fundamental Frequency Problem -- 29 Acknowledgment -- 30 Editors´ Note.
A Retrospective: On Disproving the Transcription-Translation Feedback Loop Model in Cyanobacteria -- 1 Transcription-Translation Feedback Loop Model -- 2 Beyond the TTFL Model -- 3 Establishment of the In Vitro Reconstitution System -- References -- Mechanistic Aspects of the Cyanobacterial Circadian Clock -- Bibliography -- Mechanism of the Cyanobacterial Circadian Clock Protein KaiC to Measure 24 Hours -- 1 Introduction -- 2 Clock Systems of Cyanobacteria -- 3 Characteristics of the Circadian Clock in Terms of Temperature Compensation of Period -- 4 ATPase Activity and Intramolecular Feedback of KaiC -- 5 Stable Circadian Oscillations Due to Interactions Between Two ATPase Domains of KaiC -- 6 Design of Mechanical Clocks and the Design of Circadian Clocks -- 7 Conclusions -- References -- Oscillation and Input Compensation in the Cyanobacterial Kai Proteins -- 1 The Cyanobacterial Oscillator as a Biochemical Model for Chronobiology -- 2 Phenomenology of the Cyanobacterial Oscillator -- 3 Metabolic Input and Input Compensation -- 4 Phase Plane Picture of Input Compensation and Entrainment -- 5 A Toy Model with Integral Feedback Can Decouple Period and Amplitude -- 6 Period and Amplitude in the Model -- 7 Does KaiC Phosphorylation Implement Integral Feedback? -- 8 Coexistence of a Stable Fixed Point and a Limit Cycle -- 9 Conclusion -- References -- Insights into the Evolution of Circadian Clocks Gleaned from Bacteria -- 1 Evolution of Circadian Clocks: What Can Bacterial Clocks Tell Us? -- 2 General Considerations Concerning the Evolutionary Significance of Clocks -- 3 How and Why Did Bacteria Evolve Circadian Timekeepers? -- 4 Self-Sustained Versus Damped Oscillators Versus Hourglass Timers -- 5 Testing Whether Clocks Are Adaptive -- 6 Competition Experiments and Assessment of Fitness -- 7 ``It Takes a Village:´´ Communities and Populations. 8 A Medically Important Community: The Mammalian Gut Microbiome -- 9 Clocks Are Still Evolving! -- References -- Reasons for Seeking Information on the Molecular Structure and Dynamics of Circadian Clock Components in Cyanobacteria -- 1 Introduction -- 2 Narrowing a Research Question -- 3 Transmural Hierarchy -- 4 Structural Basis of Slowness in KaiC -- 5 From Intra- to Inter-Molecular Scales -- 6 Concluding Remarks -- References -- Single-Molecule Methods Applied to Circadian Proteins with Special Emphasis on Atomic Force Microscopy -- 1 Introduction -- 2 Single-Molecule Techniques -- 2.1 Single-Channel Patch-Clamp Recording -- 2.2 Single-Molecule Fluorescence Microscopy -- 2.3 Atomic Force Microscopy -- 2.3.1 HS-AFM Imaging -- 3 Visualizing Circadian Clock Proteins by HS-AFM -- 3.1 Experimental Conditions for HS-AFM Imaging of Kai Proteins -- 3.2 KaiA-KaiC Interaction -- 3.2.1 KaiA Interaction Depends upon KaiC Phosphostatus -- 3.2.2 Synchronous Oscillation of KaiA-KaiC Affinities with In Vitro Rhythm -- 3.2.3 Reinforcement of Oscillatory Resilience with PDDA -- 3.2.4 C-Terminal Tentacles of KaiC Hexamer Co-Operationally Bind to KaiA Dimer -- 3.3 KaiB-KaiC Interaction -- 3.3.1 Cooperative Binding of KaiB Monomers to KaiC Hexamer -- 3.3.2 KaiB Interaction Depends upon KaiC Phosphostatus -- 3.4 Visualization of KaiA-KaiB-KaiC Ternary Complex -- 4 Concluding Remarks -- References -- Diversity of Timing Systems in Cyanobacteria and Beyond -- 1 Introduction -- 2 Bioinformatics Analyses Reveal Diversity of Putative Clock Components in Cyanobacteria -- 2.1 The KaiABC Oscillator -- 2.2 The Circadian Protein Network Embedding the Core Clock -- 3 The Hourglass Timer -- 4 Synechocystis sp. PCC 6803: An Example of a Cyanobacterium Harboring Multiple Kai Homologs -- 4.1 Input and Output Pathways -- 4.2 The KaiB3C3 System. 4.3 Manipulation of Clock Components as a Strategy to Switch Metabolic Routes -- 5 Potential KaiC-Based Timing Systems Outside Cyanobacteria -- 6 Conclusion -- References -- An In Vitro Approach to Elucidating Clock-Modulating Metabolites -- 1 Basics of the Circadian-Oscillating KaiC Phosphorylation -- 2 Modulating the Circadian Clock with Adenosine Diphosphate (ADP) -- 3 Resetting the Clock Through Sensing the Redox State of Quinone -- 4 Regulating the KaiC Autokinase and Autophosphatase Activities with Mg2+ -- 5 Keeping Time with KaiC Alone as an Hourglass -- 6 Future Perspectives -- References -- Damped Oscillation in the Cyanobacterial Clock System -- 1 Introduction -- 2 Hopf Bifurcation Is a Scenario for Emerging Damped Oscillations -- 3 Low-Temperature MAKES In Vitro Rhythms Dampen Through Hopf Bifurcation -- 4 Resonance of the Damped Oscillation of KaiC During Temperature Cycles -- 5 Damped Oscillation in the Absence of KaiA -- 6 Evolution of Self-Sustained Oscillation -- 7 Summary -- References -- Roles of Phosphorylation of KaiC in the Cyanobacterial Circadian Clock -- 1 Introduction -- 2 Discovery of KaiC Phosphorylation -- 3 Relationship Between KaiC Phosphorylation and the Interaction Among Kai Proteins -- 4 ATP-Binding Sites Located at the Subunit Interfaces of KaiC Hexamer -- 5 In Vitro Reconstitution of a Circadian Oscillator -- 6 Sequential Phosphorylation of S431 and T432 -- 7 Discovery of ATPase Activity of KaiC -- 8 An Unusual Mechanism of KaiC Autodephosphorylation -- 9 Structural Basis for Time-Specific Interactions Among Kai Proteins -- 10 A Link Between KaiC Phosphorylation and Circadian Gene Expression -- 11 Multiple Output Systems of the Protein-Based Oscillator -- 12 Perspective -- References -- Reprogramming Metabolic Networks and Manipulating Circadian Clocks for Biotechnological Applications -- 1 Introduction. 2 Model Cyanobacterial Strains -- 3 Synthetic and Systems Biology in Cyanobacteria -- 4 Cyanobacterial Biofuels and Chemicals -- 4.1 Derivatives from Sugar Phosphates -- 4.2 Derivatives from DHAP -- 4.3 Derivatives from Pyruvate -- 4.4 Derivatives from Acetyl-CoA -- 4.5 Derivatives from TCA Cycle Metabolites -- 4.6 Derivatives from Amino Acids -- 4.7 Biomass Conversion -- 5 Modification of Cyanobacterial Framework for Improved Performance -- 5.1 Enhancing Photosynthetic Efficiency -- 5.2 Improving Carbon Assimilation -- 5.3 Rewiring the Central Carbon Metabolism -- 6 The Circadian Clock Regulates Gene Expression and Metabolism in Wild-Type Cyanobacteria -- 6.1 The Circadian Clock Governs Oscillation of Glycogen Content -- 6.2 The Circadian Oscillator Regulates Global Gene Expression and Metabolism -- 7 Global Complementary Regulation of Gene Expression Via Manipulation of the Clock -- 8 Manipulation of the Circadian Clock for Enhancing Expression of Foreign Genes -- 9 Conclusions and Prospects -- References -- Insights from Mathematical Modeling/Simulations of the In Vitro KaiABC Clock -- 1 Introduction -- 2 Insights from Simplified Phosphoform Dynamic Models -- 3 Hexamer Models and Allosteric Transitions -- References -- Part II: Circadian Phenomena in Microbiomes/Populations and Bacteria Besides Cyanobacteria -- Basic Biology of Rhythms and the Microbiome -- 1 Introduction -- 1.1 Circadian Rhythms in Mammals -- 1.2 Diurnal Rhythms of the Mammalian Microbiota -- 2 Circadian System in Host-Microbiome Interactions -- 2.1 Host Factors Shaping Microbiota Rhythms -- 2.2 The Influence of Microbiota on Host Rhythms and Metabolism -- 2.3 Perspectives and Challenges -- References -- Disease Implications of the Circadian Clocks and Microbiota Interface -- 1 Circadian Rhythms -- 2 Circadian Disruption. 3 Implications of Circadian Disruption and the Microbiota. |
| Record Nr. | UNINA-9910485606103321 |
| Cham, Switzerland : , : Springer, , [2021] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Microbial metabolic systems initiative [[electronic resource]]
| Microbial metabolic systems initiative [[electronic resource]] |
| Pubbl/distr/stampa | [Idaho Falls, Idaho] : , : Idaho National Laboratory, , [2005?] |
| Descrizione fisica | 2 unnumbered pages : digital, PDF file |
| Collana | [Fact sheet ] |
| Soggetto topico |
Prokaryotes
Microbial metabolism |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910697666803321 |
| [Idaho Falls, Idaho] : , : Idaho National Laboratory, , [2005?] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Prokaryotic Development / / Yves Brun, Lawrence J. Shimkets
| Prokaryotic Development / / Yves Brun, Lawrence J. Shimkets |
| Autore | Brun Yves |
| Pubbl/distr/stampa | Washington, D.C. : , : ASM Press, , 2000 |
| Descrizione fisica | 1 online resource (xiv, 477 pages) : illustrations |
| Disciplina | 574.876 |
| Soggetto topico |
Cell physiology
Prokaryotes |
| ISBN | 1-68367-254-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Prokaryotic development : strategies to enhance survival / Lawrence J. Shimkets and Yves V. Brun -- Actinomycete development, antibiotic production, and phylogeny : questions and challenges / Wendy Champness -- Developmental decisions during sporulation in the aerial mycelium in Streptomyces / Keith F. Chater -- Cyanobacterial phylogeny and development : questions and challenges / David G. Adams -- Heterocyst formation in Anabaena / C. Peter Wolk -- The paleobiologic record of cyanobacterial evolution / J. William Schopf -- Endospore-forming bacteria : an overview / Abraham L. Sonenshein -- Regulation of the initiation of endospore formation in Bacillus subtilis / William F. Burkholder and Alan D. Grossman -- Asymmetric division and cell fate during sporulation in Bacillus subtilis / Petra Anne Levin and Richard Losick -- Morphogenesis and properties of the bacterial spore / Adam Driks and Peter Setlow -- Introduction to the myxobacteria / Martin Dworkin Developmental aggregation and fruiting body formation in the gliding bacterium Myxococcus xanthus / Mandy J. Ward and David R. Zusman -- Cell-interactive sensing of the environment / Dale Kaiser -- Growth, sporulation, and other tough decisions / Lawrence J. Shimkets -- Development of Stigmatella / David White and Hans Ulrich Schairer -- The dimorphic life cycle of Caulobacter and stalked bacteria / Yves V. Brun and Raji Janakiraman -- Regulation of flagellum biosynthesis and motility in Caulobacter / James W. Gober and Jennifer C. England -- Signal transduction and cell cycle checkpoints in developmental regulation of Caulobacter / Noriko Ohta, Thorsten W. Grebe, and Austin Newton -- Regulation of the Caulobacter cell cycle / Dean Hung, Harley McAdams, and Lucy Shapiro -- Swarming migration by Proteus and related bacteria / Gillian M. Fraser, Richard B. Furness, and Colin Hughes -- The chlamydial developmental cycle / Daniel D. Rockey and Akira Matsumoto Developmental cycle of Coxiella burnetti / James E. Samuel -- Differentiation of free-living rhizobia into endosymbiotic bacteroids / William Margolin. |
| Record Nr. | UNINA-9910829877103321 |
Brun Yves
|
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| Washington, D.C. : , : ASM Press, , 2000 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Prokaryotology : a coherent point of view / / Sorin Sonea & Leo G. Mathieu
| Prokaryotology : a coherent point of view / / Sorin Sonea & Leo G. Mathieu |
| Autore | Sonea Sorin |
| Pubbl/distr/stampa | Presses de l’Université de Montréal, 2000 |
| Descrizione fisica | 1 online resource (106 p.) |
| Disciplina | 579.3 |
| Soggetto topico |
Prokaryotes
Prokaryotes - Genetics Bacteria - Evolution |
| Soggetto non controllato |
prokaryotes
Genetics evolution Bacterial genetics |
| ISBN |
979-1-03-651369-5
2-7606-2329-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
""CONTENTS""; ""FOREWORD""; ""CHAPTER I: UNEVEN DEVELOPMENT OF THE SCIENCE OF BACTERIOLOGY""; ""1. The importance of pathogenic bacteria in the early developments of bacteriology""; ""2. Progressive discovery of solidarity among prokaryotes""; ""a) Mixed communities with division of labor""; ""b) Horizontal gene exchanges""; ""3. Modifying the old concept of bacteria""; ""4. Changes in the perception of prokaryotes' evolution""; ""5. Discovery of the Archaebacteria (Archaea)""; ""6. The prokaryotic world: a unified and essential element of life on our planet""
""7. Many biologists are not sufficiently aware of the unique characteristics of the prokaryotic world""""CHAPTER II: MAJOR CHARACTERISTICS OF THE PROKARYOTIC WORLD""; ""1. Prokaryotic cell structure and functions""; ""a) The cell wall of prokaryotes""; ""b) The prokaryotic plasmic (inner) membrane is a multi-purpose organ""; ""c) Prokaryotic ribosomes differ from those of eukaryotes""; ""d) Capsules and glycocalyces""; ""e) DNA in the prokaryotic cell""; ""f) Prokaryotic spores are a survival form of extraordinary resistance"" ""2. Dominant role of generalized solidarity in the life of prokaryotes""""a) Mutually-supportive associations among different prokaryotic cells in local communities""; ""b) Scope and importance of gene exchanges between different prokaryotic cells: A general way of solving problems and adapting to temporary changes""; ""3. The prokaryotic entity forms one planetary biologic system or superorganism""; ""CHAPTER III: ORIGINAL, NON-DARWINIAN EVOLUTION OF PROKARYOTES""; ""1. Ways in which errors in the division of the earliest cells could be prevented or compensated for"" ""2. Variety and diversification inside the early prokaryotic clone""""3. Prokaryotic cells evolved together towards both high specialization and complementarity""; ""4. The appearance of the prokaryotic cell wall and of transformation""; ""5. Small replicons became the most efficient basic elements of a prokaryotic global communication system""; ""6. The prokaryotic superorganism (or biologic system) as a unique type of clonal entity; there are no prokaryotic species""; ""7. Role of prokaryotes in the origin and subsequent evolution of eukaryotes"" ""8. The prokaryotes started as and remain the most influential biological factor in the development and the maintenance of our biosphere""""CONCLUSION""; ""REFERENCES""; ""INDEX""; ""A""; ""B""; ""C""; ""D""; ""E""; ""F""; ""G""; ""H""; ""I""; ""K""; ""L""; ""M""; ""N""; ""O""; ""P""; ""R""; ""S""; ""T""; ""V""; ""X"" |
| Record Nr. | UNINA-9910279745003321 |
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Sonea Sorin
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| Presses de l’Université de Montréal, 2000 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Thiol biochemistry of prokaryotes [[electronic resource] ] : final technical report / / Robert C. Fahey
| Thiol biochemistry of prokaryotes [[electronic resource] ] : final technical report / / Robert C. Fahey |
| Autore | Fahey Robert C |
| Pubbl/distr/stampa | [Washington, D.C.] : , : National Aeronautics and Space Administration, , [1987] |
| Descrizione fisica | 1 volume |
| Collana | NASA-CR |
| Soggetto topico |
Biochemistry
Evolution (development) Metabolism Prokaryotes Thiols |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Altri titoli varianti | Thiol biochemistry of prokaryotes |
| Record Nr. | UNINA-9910698825903321 |
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Fahey Robert C
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| [Washington, D.C.] : , : National Aeronautics and Space Administration, , [1987] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Soggetto topico
-
Prokaryotes
(9)
- Microorganisms (4)
- Procariotes (4)
- Bacteris (3)
- Bacteria - Evolution (1)