Kooperativer Bibliotheksverbund

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Format: 1 online resource (404 p.)

Edition: 1st ed.

ISBN: 1-84755-997-2

Series Statement: RSC biomolecular sciences

Content: In recent years, there has been an explosion in knowledge and research associated with the field of enzyme catalysis and H-tunneling. Rich in its breath and depth, this introduction to modern theories and methods of study is suitable for experienced researchers those new to the subject. Edited by two leading experts, and bringing together the foremost practitioners in the field, this up-to-date account of a rapidly developing field sits at the interface between biology, chemistry and physics. It covers computational, kinetic and structural analysis of tunnelling and the synergy in combining th

Note: Description based upon print version of record. , 9780854041220_Publicity; i_iv; v_xiv; xv_xvi; xvii_xxvi; 001_017r; 018_035r; 036_078r; 079_104r; 105_131r; 132_160r; 161_178r; 179_198r; 199_218r; 219_241r; 242_267r; 268_290r; 291_313r; 314_344r; 345_377r , English

Additional Edition: ISBN 0-85404-122-2

Language: English

UID:

Format: 410 p , Online-Ressource , 97 b&w, ill

Edition: RSC eBook Collection 1968-2009

ISBN: 1847559972 , 9781847559975

Series Statement: RSC Biomolecular sciences v. 18

Content: This accessible introduction to modern theories of enzyme catalysis presents the latest methods for studying quantum tunnelling in biological systems, In recent years, there has been an explosion in knowledge and research associated with the field of enzyme catalysis and H-tunneling. Rich in its breath and depth, this introduction to modern theories and methods of study is suitable for experienced researchers those new to the subject. Edited by two leading experts, and bringing together the foremost practitioners in the field, this up-to-date account of a rapidly developing field sits at the interface between biology, chemistry and physics. It covers computational, kinetic and structural analysis of tunnelling and the synergy in combining these methods (with a major focus on H-tunneling reactions in enzyme systems). The book starts with a brief overview of proton and electron transfer history by Nobel Laureate, Rudolph A. Marcus. The reader is then guided through chapters covering almost every aspect of reactions in enzyme catalysis ranging from descriptions of the relevant quantum theory and quantum/classical theoretical methodology to the description of experimental results. The theoretical interpretation of these large systems includes both quantum mechanical and statistical mechanical computations, as well as simple more approximate models. Most of the chapters focus on enzymatic catalysis of hydride, proton and H" transfer, an example of the latter being proton coupled electron transfer. There is also a chapter on electron transfer in proteins. This is timely since the theoretical framework developed fifty years ago for treating electron transfers has now been adapted to H-transfers and electron transfers in proteins. Accessible in style, this book is suitable for a wide audience but will be particularly useful to advanced level undergraduates, postgraduates and early postdoctoral workers

Note: Ebook , Introduction. Preface: Beyond the Historical Perspective on Hydrogen and Electron Transfers. Chapter 1: The Transition State Theory Description of Enzyme Catalysis for Classically Activated Reactions: Introduction-- Quantifying the Catalytic Activity of Enzymes-- Free Energy Analysis of Enzyme Catalysis-- Transition State Stabilisation or Ground State Destabilisation?-- Selective Stabilisation of Transition Structures by Enzymes-- Enzyme Flexibility and Dynamics. Chapter 2: Introduction to Quantum Behavior - A Primer: Introduction-- Classical Mechanics-- Quantum Mechanics-- Heisenberg Uncertainty Principle-- The Schrodinger Equation-- Electronic Structure Calculations-- Born-Oppenheimer Approximation-- Hartree-Fock Theory-- Basis sets-- Zero-point Energy-- Density Functional Theory-- DFT Calculations of Free Energies of Activation of Enzyme Models-- DFT Calculations of Kinetic Isotope Effects-- Quantum Mechanics/Molecular Mechanics Methods-- Summary and Outlook. Chapter 3: Quantum Catalysis in Enzymes: Introduction-- Theory-- Variational Transition State Theory-- The Transmission Coefficient-- One-Dimensional Tunneling-- Multidimensional Tunneling-- Ensemble Averaging-- Examples-- Liver Alcohol Dehydrogenase-- Dihydrofolate Reductase-- Soybean-Lipoxygenase-1 and Methylmalonyl-CoA Mutase-- Other Systems and Perspectives-- Concluding Remarks. Chapter 4: Selected Theoretical Models and Computational Methods for Enzymatic Tunneling: Introduction-- Vibronically Nonadiabatic Reactions: Proton-coupled Electron Transfer-- Theory-- Application to Lipoxygenase-- Predominantly Adiabatic Reactions: Proton and Hydride Transfer-- Theory-- Application to Dihydrofolate Reductase-- Emerging Concepts About Enzyme Catalysis. Chapter 5: Kinetic Isotope Effects from Hybrid Classical and Quantum Path Integral Computations: Introduction-- Theoretical Background-- Path Integral Quantum Transition State Theory-- Centroid Path Integral Simulations-- Kinetic Isotope Effects-- Sequential Centroid Path Integral and Umbrella Sampling (PI/UM)-- The PI-FEP/UM Method-- Kleinert's Variational Perturbation (KP) Theory-- Potential Energy Surface-- Combined QM/MM Potentials-- The MOVB Potential-- Computational Details-- Illustrative Examples-- Proton Transfer between Viscosity-- Multiple Reactive Configurations and a Place for Single-Molecule Measurements. Chapter 10. Computational Simulations of Tunnelling Reactions in Enzymes-- Introduction-- Molecular Mechanical Methods-- Quantum Mechanical Methods-- Combined Quantum Mechanical/Molecular Mechanical Methods-- Improving Semiempirical QM Calculations-- Calculation of Potential Energy Surfaces and Free Energy Surfaces-- Simulation of the H-tunnelling Event-- Calculation of H-tunnelling Rates and Kinetic Isotope Effects-- Analysing Molecular Dynamics Trajectories-- A Case Study: Aromatic Amine Dehydrogenase (AADH)-- Preparation of the System-- Analysis of the H-tunnelling Step in AADH-- Analysis of the Role of Promoting Motions in Driving Tunnelling-- Comparison of Short-range Motions in AADH with Long Range Motions in Dihydrofolate Reductase-- Summary. Chapter 11. Tunneling Does Not Contribute Significantly to Enzyme Catalysis, But Studying Temperature Dependence of Isotope Effects is Useful-- Introduction-- Methods-- Simulating Temperature Dependence of KIEs in Enzymes-- Concluding Remarks. Chapter 12: The Use of X-Ray Crystallography to Study Enzymic H-Tunnelling-- Introduction-- X-Ray Crystallography: A Brief Overview-- Accuracy of X-Ray Diffraction Structures-- Dynamic Information from X-Ray Crystallography-- Examples of H-tunnelling Systems Studied by Crystallography-- Crystallographic Studies of AADH Catalytic Mechanism-- Crystallographic Studies of MR-- Conclusions. Chapter 13: The Strengths and Weaknesses of Model Reactions for the Assessment of Tunneling in Enzymic Reactions-- Model Reactions for Biochemical Processes-- Model Reactions Relevant to Enzymic Tunneling-- Isotope Effect Temperature Dependences and the Configurational-Search Framework (CSF) for their Interpretation-- The Traditionally Dependent Category-- The Underdependent Tunneling Category-- The Overdependent Tunneling Category-- Example 1. Hydride Transfer in a Thermophilic Alcohol Dehydrogenase-- The Kirby-Walwyn Intramolecular Model Reaction-- The Powell-Bruice Tunneling Model Reaction-- Enzymic Tunneling in Alcohol Dehydrogenases-- Model Reactions and the Catalytic Power of Alcohol Dehydrogenase-- Example 2. Hydrogen-atom Transfer in Methylmalonyl Coenzyme A Mutase (MCM)-- Non-enzymic Tunneling in the Finke Model Reactions for MCM-- Enzymic Tunneling in MCM-- Model Reactions and MCM Catalytic Power-- The Roles of Theory in the Comparison of Model and Enzymic Reactions-- Model Reactions, Enzymic Accelerations, and Quantum Tunneling. Chapter 14: Long-Distance Electron Tunneling in Proteins: Introduction-- Electronic Coupling and Tunneling Pathways-- Direct Method-- Avoided Crossing-- Application of Koopmans' Theorem-- Generalized Mulliken-Hush Method-- The Propagator Method-- Protein Pruning-- Tunneling Pathways-- The Method of Tunneling Currents-- General Relations-- Many-Electron Picture-- Calculation of Current Density. Hartree-Fock Approximation-- Interatomic Tunneling Currents-- Many-Electron Aspects-- One Tunneling Orbital (OTO) Approximation and Polarization Effects-- The Limitation of the SCF Description of Many-Electron Tunneling-- Correlation Effects. Polarization Cloud Dynamics. Beyond Hartree-Fock Methods-- Quantum Interference Effects. Quantized Vertices-- Electron Transfer or Hole Transfer? Exchange Effects-- Dynamical Aspects.Chapter 15. Proton-coupled Electron Transfer: The Engine that Drives Radical Transport and Catalysis in Biology-- Introduction-- PCET Model Systems-- Unidirectional PCET Networks-- Bidirectional PCET Networks-- PCET Biocatalysis-- PCET in Enzymes: A Study of Ribonucleotide Reductase-- The PCET Pathway in RNR-- PCET in the ?2 Subunit of RNR-- PCET in ?2 Subunit of RNR: PhotoRNRs-- A Model for PCET in RNR-- Concluding Remarks.

Language: English

Subjects: Chemistry/Pharmacy

Keywords: Quantenbiochemie ; Biokatalyse

URL: Volltext  (Deutschlandweit zugänglich)

UID:

Format: 1 online resource (xviii, 439 pages) : , illustrations.

ISBN: 0-12-815149-8 , 0-12-815148-X

Series Statement: Methods in enzymology ; Volume 608

Content: Volume 608 of the series Methods in Enzymology covers key aspects of enzyme discovery, engineering tools and platforms, and examples of applications in the enzymology of synthetic biology.Detailed methods for laboratory use of enzymes in synthetic biology applications Informative case history examples illustrating how enzyme and metabolic engineering are used to generate new products Emphasises latest developments in laboratory automation for the engineering of biology Covers many aspects of the design, build, test, learn cycle used in synthetic biology

Note: Front Cover -- Enzymes in Synthetic Biology -- Copyright -- Contents -- Contributors -- Preface -- Section I: Enzyme Discovery -- Chapter One: Enzyme Discovery: Enzyme Selection and Pathway Design -- 1. Introduction -- 2. Enzyme Selection -- 2.1. Introduction to Enzyme Selection -- 2.2. Protocol Description (Selenzyme) -- 2.2.1. Preparation Steps -- 2.2.1.1. Pathway Representation and Use of Generalized Transformations -- 2.2.2. Computing Reaction Similarity -- 2.2.2.1. Description of the General Workflow -- 2.2.2.2. Reaction Directionality -- 2.2.3. Screening, Ranking, and Selection -- 2.2.3.1. Database Screening -- 2.2.3.2. Properties Calculation -- 2.2.3.3. Ranking of Sequence Candidates -- 2.2.4. Selenzyme: Online Enzyme Selection Tool -- 2.2.4.1. Integration With RetroPath2.0 and Other Workflows -- 2.2.5. Other Applications of the Protocol -- 2.2.6. Improvements of the Protocol -- 3. Pathway Design -- 3.1. Introduction to Retrosynthesis -- 3.2. Protocol Description (RetroPath2.0) -- 3.2.1. Preparation Steps -- 3.2.1.1. Sink and Source Definition -- 3.2.1.2. Reaction Rules -- 3.2.2. Building a Retrosynthesis Network -- 3.2.2.1. General Workflow Presentation -- 3.2.2.2. Remark: Rule Scoring by Enzyme Sequence Consistency -- 3.2.3. Pathway Enumeration Between Two Pools of Compounds -- 3.2.3.1. Computing the Scope -- 3.2.3.2. Enumerating Pathways -- 3.3. Use Case: 1,4-Butanediol Pathways Prediction Using RetroPath2.0 -- 3.3.1.1. Materials and Methods -- 3.4. Other Applications of the Protocol -- 4. Summary and Conclusion -- Acknowledgments -- References -- Section II: Enzyme Engineering Tools and Platforms -- Chapter Two: Cell-Free Synthetic Biology for Pathway Prototyping -- 1. Introduction -- 1.1. The State of Metabolic Engineering -- 1.2. Emerging Cell-Free Biotechnology -- 1.2.1. Purified Enzyme Systems -- 1.2.2. Crude Cell Lysate Systems. , 2. The Cell-Free Metabolic Engineering Framework -- 3. S12 Lysate Preparation for Cell-Free Metabolic Engineering -- 3.1. Materials -- 3.1.1. Equipment -- 3.1.2. Media -- 3.1.3. Media Supplements -- 3.1.4. Bacterial Strains and Plasmids (See Table 1) -- 3.1.5. Buffers and Reagents -- 3.2. Procedure -- 3.2.1. Cell Preparation and Expression -- 3.2.2. Extract Preparation -- 3.2.3. Extract Quantification of Total Protein by Bradford Assay -- 3.2.4. Overexpressed Protein Quantification by Densitometry -- 4. Mix-and-Match Cell-Free Metabolic Engineering -- 4.1. Materials -- 4.1.1. Equipment -- 4.1.2. Buffers and Reagents -- 4.2. Procedure -- 4.2.1. Mix-and-Match Biosynthesis Reactions -- 4.2.2. Biosynthesis Analysis -- 5. Cell-Free Protein Synthesis-Driven Metabolic Engineering -- 5.1. Materials -- 5.1.1. Equipment -- 5.1.2. Buffers and Reagents -- 5.2. Procedure -- 5.2.1. CFPS-ME Reactions -- 5.2.2. Quantification of Protein Produced In Vitro via Radioactive Incorporation -- 5.2.3. Quantification of Protein Produced In Vitro via Split-GFP Construct -- 5.2.4. Metabolite Quantification -- 6. Summary and Conclusions -- Acknowledgments -- References -- Chapter Three: Fast and Flexible Synthesis of Combinatorial Libraries for Directed Evolution -- 1. Introduction -- 1.1. Mutagenesis: Introducing Sequence Variation -- 1.2. Combinatorial Libraries -- 2. Methods -- 2.1. Primer Design -- 2.1.1. Notes and Troubleshooting -- 2.2. Synthesis of Mutagenic Megaprimers by Asymmetric PCR -- 2.2.1. Equipment -- 2.2.2. Reagents and Buffers -- 2.2.3. Protocol -- 2.2.4. Notes and Troubleshooting -- 2.3. Assembly of Full-Length Gene Using Mutagenic Megaprimers -- 2.3.1. Equipment -- 2.3.2. Reagents and Buffers -- 2.3.3. Protocol -- 2.3.4. Notes and Troubleshooting -- 3. Library Ligation, Transformation, and Quality Control -- 3.1. Buffers and Reagents -- 3.2. Protocol. , 3.3. Notes and Troubleshooting -- 4. Summary and Conclusion -- Acknowledgments -- References -- Section III: Enzyme Families: Parts and Platforms for Chemical Diversity -- Chapter Four: Sesquiterpene Synthase-Catalyzed Conversion of a Farnesyl Diphosphate Analogue to a Nonnatural Terpenoid Ether -- 1. Introduction -- 2. Sesquiterpenes Production and Purification -- 2.1. Recombinant Enzyme Production and Purification -- 2.2. Determination of Optimum Catalysis Conditions -- 2.2.1. Magnesium Ion Concentration -- 2.2.2. Optimum pH -- 2.2.3. Enzyme Concentration -- 3. Enzymatic Synthesis of Cyclic Ether -- 3.1. Enzyme Activity Assay -- 3.2. Preparative Scale Incubation -- 4. Conclusion -- References -- Chapter Five: In Vivo Platforms for Terpenoid Overproduction and the Generation of Chemical Diversity -- 1. Introduction -- 2. In Vitro Reconstitution of the MVA Pathway and Targeted Engineering of Value-Added Terpenoids -- 2.1. In Vitro Reconstitution of the MVA Pathway -- 2.1.1. Protein Expression and Purification for In Vitro Reconstitution -- 2.1.2. Extraction and Detection of Farnesene -- 2.2. Targeted Engineering of Farnesene -- 2.2.1. Plasmids for the MVA Pathway and Farnesene Overexpression -- 2.2.2. Shake-Flask Fermentation and Analysis of α-Farnesene Production in Engineered Strains -- 2.3. Targeted Engineering of Lycopene -- 2.3.1. Plasmids for Lycopene Overproduction -- 2.3.2. Analysis of Lycopene Titers in Engineered Strains -- 2.4. Targeted Engineering of Astaxanthin -- 2.4.1. Plasmid Construction for Astaxanthin Overproduction -- 2.4.2. Fermentation and Quantification of Astaxanthin Produced by E. coli -- 2.5. Targeted Engineering of Taxadiene -- 2.5.1. Plasmid Construction for Taxadiene Overproduction -- 2.5.2. Overproduction and Detection of Taxadiene in E. coli. , 3. Genome Mining of Terpene Cyclases and the Generation of Chemical Diversity -- 3.1. Genome Mining of Terpene Cyclases and Exploration of the Chemical Diversity of Terpenoids -- 3.1.1. Identification of Class I Terpene Synthases -- 3.1.2. Construction of Plasmids -- 3.1.3. In Vitro Assays of Terpene Cyclases -- 3.1.4. Fermentation and Purification of Terpenoids -- 4. Conclusion -- Acknowledgments -- References -- Chapter Six: Imine Reductases, Reductive Aminases, and Amine Oxidases for the Synthesis of Chiral Amines: Discovery, Char ... -- 1. Introduction -- 1.1. Imine Reductases and Reductive Aminases -- 1.2. Amine Oxidases -- 2. Protein Engineering -- 2.1. Introduction -- 2.2. Amine Oxidase Libraries and Screening -- 2.2.1. Introduction -- 2.2.2. Library Generation -- 2.2.3. Solid-Phase Screen -- 3. Biotransformations, Intensification, and Scale-Up -- 3.1. RedAms and IREDs -- 3.1.1. Analytical-Scale Biotransformations -- 3.1.1.1. Whole Cell -- 3.1.1.2. Cell-Free Extracts and Purified Enzyme -- 3.1.2. Intensification and Scale-Up -- 3.1.2.1. Typical Procedure for Preparative-Scale Reductive Amination Exemplified With Cyclohexanone and Allylamine -- 3.2. Amine Oxidase-Catalyzed Deracemization -- 3.2.1. Analytical-Scale Deracemization Using Whole-Cell MAO-N -- 3.2.2. Analytical-Scale Deracemization Using Purified MAO-N or MAO-N Cell Lysate -- 3.2.3. Preparative-Scale Deracemization Using Whole-Cell MAO-N -- 4. In Vitro and in vivo Cascades -- 4.1. Biocatalytic Hydrogen Borrowing -- 4.2. Amine Oxidase/IRED Cascade for Enantioselective Amine Synthesis -- 4.3. Carboxylic Acid Reductase, Transaminase, and IRED Cascade Reactions -- 5. Conclusions -- References -- Further Reading -- Chapter Seven: Experimental Protocols for Generating Focused Mutant Libraries and Screening for Thermostable Proteins -- 1. Introduction -- 2. Single Mutants Generation. , 2.1. Primer Design -- 2.1.1. Equipment -- 2.1.2. Procedure -- 2.1.3. Notes -- 2.2. QuikChange Library Creation -- 2.2.1. Equipment -- 2.2.2. Buffers and Reagents -- 2.2.3. Procedure -- 2.2.4. Notes -- 2.3. Expression and Protein Purification in a 96-Well Plate -- 2.3.1. Equipment -- 2.3.2. Buffer and Reagents -- 2.3.3. Procedure -- 2.3.4. Notes -- 2.4. Melting Temperature Screening -- 2.4.1. Equipment -- 2.4.2. Buffers and Reagents -- 2.4.3. Procedure -- 2.4.4. Notes -- 3. Combining Mutations -- 3.1. Golden Gate Gene Shuffling -- 3.1.1. Equipment -- 3.1.2. Buffers and Reagents -- 3.1.3. Procedure -- 3.1.4. Notes -- 3.2. Gibson Shuffling -- 3.2.1. Equipment -- 3.2.2. Buffers and Reagents -- 3.2.3. Procedure -- 3.2.4. Notes -- 3.3. Final Stabilized Mutant -- 3.3.1. Equipment -- 3.3.2. Buffers and Reagents -- 3.3.3. Procedure -- 4. Summary and Conclusions -- Acknowledgments -- References -- Further Reading -- Chapter Eight: Characterization of Cytochrome P450 Enzymes and Their Applications in Synthetic Biology -- 1. Introduction -- 2. Expression and Purification of Microbial Cytochrome P450 Enzymes -- 2.1. Expression and Purification of P450 BM3 (CYP102A1) -- 2.1.1. Equipment -- 2.1.2. Buffers and Reagents -- 2.1.3. Procedure -- 2.1.4. Notes -- 2.2. Expression and Purification of OleT (CYP152L1) From Jeotgalicoccus sp. ATCC 8456 -- 2.2.1. Procedure -- 2.2.2. Notes -- 3. Expression and Purification of Eukaryotic P450s in E. coli -- 3.1. P450 Construct Design -- 3.2. Routes to Overexpression of Eukaryotic CYPs in E. coli -- 3.3. Expression and Purification of Human CYP2D6 -- 3.3.1. Equipment and Reagents -- 3.3.2. Procedure -- 3.3.3. Notes -- 3.4. Purification of the Native Form of a Saccharomyces cerevisiae CYP51 Enzyme -- 3.5. Examples of Purification of Cytochrome P450 Enzymes From Other Eukaryotes. , 4. Expression and Characterization of P450 Redox Partner Systems.

Language: English

UID:

Format: 1 online resource (xviii, 439 pages) : , illustrations.

ISBN: 0-12-815149-8 , 0-12-815148-X

Series Statement: Methods in enzymology ; Volume 608

Content: Volume 608 of the series Methods in Enzymology covers key aspects of enzyme discovery, engineering tools and platforms, and examples of applications in the enzymology of synthetic biology.Detailed methods for laboratory use of enzymes in synthetic biology applications Informative case history examples illustrating how enzyme and metabolic engineering are used to generate new products Emphasises latest developments in laboratory automation for the engineering of biology Covers many aspects of the design, build, test, learn cycle used in synthetic biology

Note: Front Cover -- Enzymes in Synthetic Biology -- Copyright -- Contents -- Contributors -- Preface -- Section I: Enzyme Discovery -- Chapter One: Enzyme Discovery: Enzyme Selection and Pathway Design -- 1. Introduction -- 2. Enzyme Selection -- 2.1. Introduction to Enzyme Selection -- 2.2. Protocol Description (Selenzyme) -- 2.2.1. Preparation Steps -- 2.2.1.1. Pathway Representation and Use of Generalized Transformations -- 2.2.2. Computing Reaction Similarity -- 2.2.2.1. Description of the General Workflow -- 2.2.2.2. Reaction Directionality -- 2.2.3. Screening, Ranking, and Selection -- 2.2.3.1. Database Screening -- 2.2.3.2. Properties Calculation -- 2.2.3.3. Ranking of Sequence Candidates -- 2.2.4. Selenzyme: Online Enzyme Selection Tool -- 2.2.4.1. Integration With RetroPath2.0 and Other Workflows -- 2.2.5. Other Applications of the Protocol -- 2.2.6. Improvements of the Protocol -- 3. Pathway Design -- 3.1. Introduction to Retrosynthesis -- 3.2. Protocol Description (RetroPath2.0) -- 3.2.1. Preparation Steps -- 3.2.1.1. Sink and Source Definition -- 3.2.1.2. Reaction Rules -- 3.2.2. Building a Retrosynthesis Network -- 3.2.2.1. General Workflow Presentation -- 3.2.2.2. Remark: Rule Scoring by Enzyme Sequence Consistency -- 3.2.3. Pathway Enumeration Between Two Pools of Compounds -- 3.2.3.1. Computing the Scope -- 3.2.3.2. Enumerating Pathways -- 3.3. Use Case: 1,4-Butanediol Pathways Prediction Using RetroPath2.0 -- 3.3.1.1. Materials and Methods -- 3.4. Other Applications of the Protocol -- 4. Summary and Conclusion -- Acknowledgments -- References -- Section II: Enzyme Engineering Tools and Platforms -- Chapter Two: Cell-Free Synthetic Biology for Pathway Prototyping -- 1. Introduction -- 1.1. The State of Metabolic Engineering -- 1.2. Emerging Cell-Free Biotechnology -- 1.2.1. Purified Enzyme Systems -- 1.2.2. Crude Cell Lysate Systems. , 2. The Cell-Free Metabolic Engineering Framework -- 3. S12 Lysate Preparation for Cell-Free Metabolic Engineering -- 3.1. Materials -- 3.1.1. Equipment -- 3.1.2. Media -- 3.1.3. Media Supplements -- 3.1.4. Bacterial Strains and Plasmids (See Table 1) -- 3.1.5. Buffers and Reagents -- 3.2. Procedure -- 3.2.1. Cell Preparation and Expression -- 3.2.2. Extract Preparation -- 3.2.3. Extract Quantification of Total Protein by Bradford Assay -- 3.2.4. Overexpressed Protein Quantification by Densitometry -- 4. Mix-and-Match Cell-Free Metabolic Engineering -- 4.1. Materials -- 4.1.1. Equipment -- 4.1.2. Buffers and Reagents -- 4.2. Procedure -- 4.2.1. Mix-and-Match Biosynthesis Reactions -- 4.2.2. Biosynthesis Analysis -- 5. Cell-Free Protein Synthesis-Driven Metabolic Engineering -- 5.1. Materials -- 5.1.1. Equipment -- 5.1.2. Buffers and Reagents -- 5.2. Procedure -- 5.2.1. CFPS-ME Reactions -- 5.2.2. Quantification of Protein Produced In Vitro via Radioactive Incorporation -- 5.2.3. Quantification of Protein Produced In Vitro via Split-GFP Construct -- 5.2.4. Metabolite Quantification -- 6. Summary and Conclusions -- Acknowledgments -- References -- Chapter Three: Fast and Flexible Synthesis of Combinatorial Libraries for Directed Evolution -- 1. Introduction -- 1.1. Mutagenesis: Introducing Sequence Variation -- 1.2. Combinatorial Libraries -- 2. Methods -- 2.1. Primer Design -- 2.1.1. Notes and Troubleshooting -- 2.2. Synthesis of Mutagenic Megaprimers by Asymmetric PCR -- 2.2.1. Equipment -- 2.2.2. Reagents and Buffers -- 2.2.3. Protocol -- 2.2.4. Notes and Troubleshooting -- 2.3. Assembly of Full-Length Gene Using Mutagenic Megaprimers -- 2.3.1. Equipment -- 2.3.2. Reagents and Buffers -- 2.3.3. Protocol -- 2.3.4. Notes and Troubleshooting -- 3. Library Ligation, Transformation, and Quality Control -- 3.1. Buffers and Reagents -- 3.2. Protocol. , 3.3. Notes and Troubleshooting -- 4. Summary and Conclusion -- Acknowledgments -- References -- Section III: Enzyme Families: Parts and Platforms for Chemical Diversity -- Chapter Four: Sesquiterpene Synthase-Catalyzed Conversion of a Farnesyl Diphosphate Analogue to a Nonnatural Terpenoid Ether -- 1. Introduction -- 2. Sesquiterpenes Production and Purification -- 2.1. Recombinant Enzyme Production and Purification -- 2.2. Determination of Optimum Catalysis Conditions -- 2.2.1. Magnesium Ion Concentration -- 2.2.2. Optimum pH -- 2.2.3. Enzyme Concentration -- 3. Enzymatic Synthesis of Cyclic Ether -- 3.1. Enzyme Activity Assay -- 3.2. Preparative Scale Incubation -- 4. Conclusion -- References -- Chapter Five: In Vivo Platforms for Terpenoid Overproduction and the Generation of Chemical Diversity -- 1. Introduction -- 2. In Vitro Reconstitution of the MVA Pathway and Targeted Engineering of Value-Added Terpenoids -- 2.1. In Vitro Reconstitution of the MVA Pathway -- 2.1.1. Protein Expression and Purification for In Vitro Reconstitution -- 2.1.2. Extraction and Detection of Farnesene -- 2.2. Targeted Engineering of Farnesene -- 2.2.1. Plasmids for the MVA Pathway and Farnesene Overexpression -- 2.2.2. Shake-Flask Fermentation and Analysis of α-Farnesene Production in Engineered Strains -- 2.3. Targeted Engineering of Lycopene -- 2.3.1. Plasmids for Lycopene Overproduction -- 2.3.2. Analysis of Lycopene Titers in Engineered Strains -- 2.4. Targeted Engineering of Astaxanthin -- 2.4.1. Plasmid Construction for Astaxanthin Overproduction -- 2.4.2. Fermentation and Quantification of Astaxanthin Produced by E. coli -- 2.5. Targeted Engineering of Taxadiene -- 2.5.1. Plasmid Construction for Taxadiene Overproduction -- 2.5.2. Overproduction and Detection of Taxadiene in E. coli. , 3. Genome Mining of Terpene Cyclases and the Generation of Chemical Diversity -- 3.1. Genome Mining of Terpene Cyclases and Exploration of the Chemical Diversity of Terpenoids -- 3.1.1. Identification of Class I Terpene Synthases -- 3.1.2. Construction of Plasmids -- 3.1.3. In Vitro Assays of Terpene Cyclases -- 3.1.4. Fermentation and Purification of Terpenoids -- 4. Conclusion -- Acknowledgments -- References -- Chapter Six: Imine Reductases, Reductive Aminases, and Amine Oxidases for the Synthesis of Chiral Amines: Discovery, Char ... -- 1. Introduction -- 1.1. Imine Reductases and Reductive Aminases -- 1.2. Amine Oxidases -- 2. Protein Engineering -- 2.1. Introduction -- 2.2. Amine Oxidase Libraries and Screening -- 2.2.1. Introduction -- 2.2.2. Library Generation -- 2.2.3. Solid-Phase Screen -- 3. Biotransformations, Intensification, and Scale-Up -- 3.1. RedAms and IREDs -- 3.1.1. Analytical-Scale Biotransformations -- 3.1.1.1. Whole Cell -- 3.1.1.2. Cell-Free Extracts and Purified Enzyme -- 3.1.2. Intensification and Scale-Up -- 3.1.2.1. Typical Procedure for Preparative-Scale Reductive Amination Exemplified With Cyclohexanone and Allylamine -- 3.2. Amine Oxidase-Catalyzed Deracemization -- 3.2.1. Analytical-Scale Deracemization Using Whole-Cell MAO-N -- 3.2.2. Analytical-Scale Deracemization Using Purified MAO-N or MAO-N Cell Lysate -- 3.2.3. Preparative-Scale Deracemization Using Whole-Cell MAO-N -- 4. In Vitro and in vivo Cascades -- 4.1. Biocatalytic Hydrogen Borrowing -- 4.2. Amine Oxidase/IRED Cascade for Enantioselective Amine Synthesis -- 4.3. Carboxylic Acid Reductase, Transaminase, and IRED Cascade Reactions -- 5. Conclusions -- References -- Further Reading -- Chapter Seven: Experimental Protocols for Generating Focused Mutant Libraries and Screening for Thermostable Proteins -- 1. Introduction -- 2. Single Mutants Generation. , 2.1. Primer Design -- 2.1.1. Equipment -- 2.1.2. Procedure -- 2.1.3. Notes -- 2.2. QuikChange Library Creation -- 2.2.1. Equipment -- 2.2.2. Buffers and Reagents -- 2.2.3. Procedure -- 2.2.4. Notes -- 2.3. Expression and Protein Purification in a 96-Well Plate -- 2.3.1. Equipment -- 2.3.2. Buffer and Reagents -- 2.3.3. Procedure -- 2.3.4. Notes -- 2.4. Melting Temperature Screening -- 2.4.1. Equipment -- 2.4.2. Buffers and Reagents -- 2.4.3. Procedure -- 2.4.4. Notes -- 3. Combining Mutations -- 3.1. Golden Gate Gene Shuffling -- 3.1.1. Equipment -- 3.1.2. Buffers and Reagents -- 3.1.3. Procedure -- 3.1.4. Notes -- 3.2. Gibson Shuffling -- 3.2.1. Equipment -- 3.2.2. Buffers and Reagents -- 3.2.3. Procedure -- 3.2.4. Notes -- 3.3. Final Stabilized Mutant -- 3.3.1. Equipment -- 3.3.2. Buffers and Reagents -- 3.3.3. Procedure -- 4. Summary and Conclusions -- Acknowledgments -- References -- Further Reading -- Chapter Eight: Characterization of Cytochrome P450 Enzymes and Their Applications in Synthetic Biology -- 1. Introduction -- 2. Expression and Purification of Microbial Cytochrome P450 Enzymes -- 2.1. Expression and Purification of P450 BM3 (CYP102A1) -- 2.1.1. Equipment -- 2.1.2. Buffers and Reagents -- 2.1.3. Procedure -- 2.1.4. Notes -- 2.2. Expression and Purification of OleT (CYP152L1) From Jeotgalicoccus sp. ATCC 8456 -- 2.2.1. Procedure -- 2.2.2. Notes -- 3. Expression and Purification of Eukaryotic P450s in E. coli -- 3.1. P450 Construct Design -- 3.2. Routes to Overexpression of Eukaryotic CYPs in E. coli -- 3.3. Expression and Purification of Human CYP2D6 -- 3.3.1. Equipment and Reagents -- 3.3.2. Procedure -- 3.3.3. Notes -- 3.4. Purification of the Native Form of a Saccharomyces cerevisiae CYP51 Enzyme -- 3.5. Examples of Purification of Cytochrome P450 Enzymes From Other Eukaryotes. , 4. Expression and Characterization of P450 Redox Partner Systems.

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