Biocatalysis by Gonzalo Calvo, Gonzalo de. -- Read -- Imperial Library of Trantor

Index

Cover Title Copyright Contents Preface Part I Context and Challenges for Industrial Biocatalysis

Chapter 1 An Appreciation of Biocatalysis in the Swiss Manufacturing Environment

1.1 Introduction

1.1.1 Biocatalysis in the Swiss Manufacturing Environment 1.1.2 Current Status 1.1.3 Patent Analysis

1.2 Selected Enzyme Classes Used in the Swiss Manufacturing Environment

1.2.1 Oxidoreductases EC1 1.2.2 Transferases EC2

1.3 Challenges

1.3.1 Regulation 1.3.2 Development Time 1.3.3 Technological Lock-in 1.3.4 Public Perception 1.3.5 Education

1.4 Opportunities

1.4.1 Starting Materials 1.4.2 Sustainability and Greenness 1.4.3 Swiss Industrial Biocatalysis Consortium 1.4.4 New Business Ideas

1.5 Future Directions Acknowledgements References

Chapter 2 Biocatalysis – A Greener Alternative in Synthetic Chemistry

2.1 Introduction 2.2 Motivation for Industry to Use/Research on Biocatalysis 2.3 Challenges Faced by Biocatalysis in Industry 2.4 Prospects, 2.5 Overview of Current Enzyme-based Processes Implemented/In-progress at Industrial, Commercial Scale 2.6 Our Experience in Some Chemoenzymatic Projects

2.6.1 Protease-mediated Synthesis of Valganciclovir Intermediate 2.6.2 Chemoenzymatic Synthesis of Optically Pure Rivastigmine Intermediate Using ADH from Baker’s Yeast and KRED, 2.6.3 Preparation of Deoxynojirimycin, Key Intermediate of an Anti-diabetic Drug

2.7 Potential Safety Aspects 2.8 Conclusions Abbreviations Glossary References

Chapter 3 Biocatalytic Synthesis of Small Molecules – Past, Present and Future

3.1 Introduction 3.2 Biocatalytic Conversions of Racemates

3.2.1 Biocatalytic Resolution of Racemates 3.2.2 Biocatalytic Deracemizations

3.3 Biocatalytic Desymmetrizations 3.4 Biocatalytic Asymmetric Oxidations and Reductions

3.4.1 Biocatalytic Asymmetric Oxidations 3.4.2 Biocatalytic Asymmetric Reductions

3.5 Biocatalytic Asymmetric Hydrolysis and Acylation Reactions

3.5.1 Biocatalytic Asymmetric Hydrolysis Reactions 3.5.2 Biocatalytic Asymmetric Acylation Reactions

3.6 Biocatalytic Asymmetric Transfer Reactions 3.7 Biocatalytic Asymmetric Addition and Elimination Reactions 3.8 Summary and Outlook References

Chapter 4 EntreChem: Building a Sustainable Business Case in Biotechnology: From Biocatalysis to Synthetic Biology

4.1 Introduction 4.2 Biocatalysis

4.2.1 Enantiopure Chiral Building Blocks 4.2.2 Cascade Processes Taking Advantage of Biocatalysis

4.3 Drug Development

4.3.1 Natural Products in Drug Discovery 4.3.2 EntreChem’s Approach to Natural Products Drug Discovery 4.3.3 Aureolic Acids: The Quest for Clinically Viable “Mithralogs” 4.3.4 Collismycin Analogs as Immunosuppressive and Neuroprotective Drugs 4.3.5 Glycosylated Indolocarbazoles as Potent and Selective Kinase Inhibitors

4.4 Business Models in Biocatalysis and Natural Products Drug Discovery References

Part II Biocatalysis: from Pharmaceuticals to Bulk Chemistry

Chapter 5 Bristol-Myers Squibb: Preparation of Chiral Intermediates for the Development of Drugs and APIs

5.1 Introduction 5.2 Anti-Alzheimer's Drug. Enzymatic Preparation of (R)-5,5,5-Trifluoronorvaline 5.3 Cholesterol Lowering Agents

5.3.1 Enantioselective Enzymatic Acylation of Racemic Alcohol 5.3.2 Enzymatic Synthesis of (3S,5R)-Dihydroxy-6-(benzyloxy)hexanoic Acid, Ethyl Ester

5.4 Calcitonin Gene-related Peptide Receptors Antagonists (Migraine Treatment): Enzymatic Preparation of (R)-2-Amino-3-(7-methyl-1H-indazol-5-yl)propanoic Acid 5.5 Antidiabetic Drugs

5.5.1 Saxagliptin: Enzymatic Synthesis of (S)-N-Boc-3-hydroxyadamantylglycine 5.5.2 Saxagliptin: Enzymatic Synthesis of N-Cbz-4,5-dehydro-L-prolineamide and N-Boc-4,5-dehydro-L-prolineamide 5.5.3 Saxagliptin: Enzymatic Ammonolysis of (5S)-4,5-Dihydro-1H-pyrrole-1,5-dicarboxylic Acid, 1-(1,1-Dimethylethyl)-5-ethyl Ester 5.5.4 GLP-1 Receptor Agonists: Enzymatic Preparation of (S)-Amino-3-[3-{6-(2-methylphenyl)}pyridyl]-propionic Acid

5.6 Antihypertensive Drugs

5.6.1 Enzymatic Synthesis of (S)-6-Hydroxynorleucine 5.6.2 Vanlev: Enzymatic Synthesis of Allysine Ethylene Acetal 5.6.3 Vanlev: Enzymatic Synthesis of Thiazepine 5.6.4 Captopril: Enzymatic Preparation of (S)-3-Benzoylthio-2-methylpropanoic Acid

5.7 Antiviral Drugs. Case Study: Atazanavir

5.7.1 Atazanavir: Enzymatic Synthesis of (S)-Tertiary-leucine 5.7.2 Atazanavir: Enzymatic Preparation of (1S,2R)-[3-Chloro-2-hydroxy-1-(phenylmethyl)propyl]carbamic Acid, 1,1-Dimethyl-ethyl Ester

5.8 Antianxiety Drug. Buspirones: Enzymatic Preparation of 6-Hydroxybuspirone 5.9 Antiviral Drugs. Hepatitis B Viral (HBV) Inhibitor: Enzymatic Asymmetric Hydrolysis and Acetylation 5.10 Chemokine Receptor Modulators: Enzymatic Desymmetrization of Dimethyl Ester 5.11 Anticancer Drugs

5.11.1 Paclitaxel Semisynthetic Process 5.11.2 Water-soluble Taxane Derivatives 5.11.3 Epothilones: Epothilone B and Epothilone F 5.11.4 IGF-1 Receptor Inhibitor: Enzymatic Preparation of (S)-2-Chloro-1-(3-chlorophenyl)ethanol 5.11.5 Retinoic Acid Receptor Agonist: Enzymatic Preparation of 2-(R)-Hydroxy-2-(1′,2′,3′,4′-tetrahydro-1′,1′,4′,4′-tetramethyl-6′-naphthalenyl)acetate

5.12 Microbial Hydroxylation of Mutilin and Pleuromutilin 5.13 Conclusions Acknowledgements References

Chapter 6 Johnson Matthey: A Technology Provider Perspective to Biocatalysis in the Fine Chemicals Industry

6.1 Introduction 6.2 Commercial Considerations

6.2.1 Technology Value 6.2.2 Manufacturing 6.2.3 Market Analysis 6.2.4 Catalyst Portfolio

6.3 Technical Considerations

6.3.1 Enzyme Recruitment 6.3.2 Enzyme Engineering 6.3.3 Process Improvement

6.4 Conclusions Acknowledgements References

Chapter 7 EnzymeWorks: Recent Advances in Enzyme Engineering for Chemical Synthesis

7.1 Introduction to EnzymeWorks

7.1.1 Current Status of Biocatalyst Development

7.2 Biocatalysis in the Food and Beverage Industry

7.2.1 Introduction of Stevia Development 7.2.2 Plant Family 1 UDP-glycosyltransferase Applications 7.2.3 Chemoenzymatic Synthesis of Rebaudioside M 7.2.4 Enzyme Immobilization and Whole Cell Biosynthesis Development 7.2.5 Future Perspectives on Biocatalysis in the Food and Beverage Industry

7.3 Ketoreductase (KRED) Applications

7.3.1 Ibrutinib Development 7.3.2 Future Perspectives on Ketoreductase (KRED) Biocatalysis

7.4 Biocatalysis in the Antibiotic Industry

7.4.1 Introduction to Cephalosporin C Acylase (CCA) 7.4.2 Gene Expression, Structure and Catalytic Mechanism of Acylases 7.4.3 Recent Advances in Cephalosporin C Acylase (CCA) Development 7.4.4 Future Perspectives on Acylase Biocatalysis 7.4.5 Introduction to Deacetoxycephalosporin C Synthase 7.4.6 Deacetoxycephalosporin C Synthase Structure and Mechanism 7.4.7 Recent Advances in Deacetoxycephalosporin C Synthase Development 7.4.8 Future Perspectives of Antibiotic Biocatalysis

7.5 Future Perspectives of Biocatalyst Development References

Chapter 8 Almac: An Industrial Perspective of Ene Reductase (ERED) Biocatalysis

8.1 Introduction

8.1.1 Almac Group 8.1.2 Biocatalysis at Almac 8.1.3 The Rise of Biocatalysis

8.2 Introduction to Alkene Reduction 8.3 An Introduction to Ene Reductases and How They Work 8.4 Examples of Ene Reductase Reactions Reported in the Literature

8.4.1 Ene Reductases as Part of a Reaction Sequence 8.4.2 Ene Reductases and Solvents 8.4.3 Challenges of Co-factor Recycle 8.4.4 Avoiding the Use of Nicotinamide Co-factors 8.4.5 Impact of Synthetic Biology 8.4.6 Ene Reductases in Reverse: Oxidation 8.4.7 Thermophilic Ene-reductases 8.4.8 Alternative Screening Methods

8.5 Example of Utilisation of an ERED at Industrial Scale 8.6 Transition of Ene Reductases to Mainstream Biocatalytic Use 8.7 Conclusions Acknowledgements References

Chapter 9 GSK: Biocatalyst Discovery and Optimisation

9.1 Introduction 9.2 Biocatalyst Discovery

9.2.1 Design of Enzyme Panels 9.2.2 Imine Reductase Panel – Importance and Applicability

9.3 Biocatalyst Optimisation

9.3.1 Nelarabine Case Study

9.4 Conclusions Acknowledgements References

Chapter 10 PETROBRAS: Efforts on Biocatalysis for Fuels and Chemicals Production

10.1 PETROBRAS Overview 10.2 Hydrolysis of Lignocellulosic and Starchy Biomass 10.3 Synthesis of Solvents

10.3.1 Glycerol Carbonate 10.3.2 Butyl Acetate

10.4 Synthesis and Degradation of Polymers

10.4.1 Synthesis of Polyesters 10.4.2 Depolymerization of Poly(ethylene terephthalate)

10.5 Synthesis of Biolubricants 10.6 Synthesis of Biodiesel 10.7 Concluding Remarks References

Chapter 11 MetGen: Value from Wood – Enzymatic Solutions

11.1 Introduction

11.1.1 METGEN – Masters of Enzyme Technology and Genetic Engineering 11.1.2 Biocatalysis of Wood – Motivation and Challenges

11.2 Enzymes in Pulp and Paper

11.2.1 Enzymes in Pulp & Paper Industry Sector – Business Aspect 11.2.2 Major Enzyme Components for Wood Applications 11.2.3 Enzyme Development – from Laboratory to Industry 11.2.4 MetZyme® LIGNO™ 11.2.5 MetZyme® BRILA™ 11.2.6 Concluding Remarks on Enzymes in Pulp and Paper

11.3 Biorefinery Enzymes

11.3.1 Renewable Chemical Industry Segment – Business Aspect 11.3.2 Wood Biorefinery Concept 11.3.3 Biomass Hydrolysis – Chemicals and Enzymes 11.3.4 Biomass Is Not Oil; It Is More Like Soup of the Day 11.3.5 Beyond Sugars 11.3.6 Biorefinery Enzymes – Concluding Remarks 11.3.7 Wood in Pulp and Paper and Biorefinery – Common Problems or Window for Opportunity?

Abbreviations References

Part III Biocatalyst Optimization with Industrial Perspectives

Chapter 12 LentiKat’s: Industrial Biotechnology, Experiences and Visions

12.1 Introduction 12.2 Lentikats Biotechnology

12.2.1 Potential of Lentikats Biotechnology 12.2.2 Properties of Lentikats Biotechnology 12.2.3 Production of Lentikats Biocatalyst

12.3 Experiences in Wastewater Treatment

12.3.1 Municipal Wastewater Treatment 12.3.2 Industrial Wastewater Treatment 12.3.3 Special Applications 12.3.4 Advantages of Lentikats Biotechnology in Wastewater Treatment 12.3.5 Product Lines 12.3.6 Wastewater Treatment Applications

12.4 Experiences in the Pharmaceutical & Food Industry

12.4.1 Food Technology Industry 12.4.2 Pharmaceutical Industry 12.4.3 Bio-based Chemicals Industry 12.4.4 Advantages of Lentikats Biotechnology in the Pharmaceutical & Food Industry 12.4.5 Application Examples in the Pharmaceutical & Food Industry

12.4.6 Pharmaceutical & Food Applications

12.5 Vision References

Chapter 13 EziG: A Universal Platform for Enzyme Immobilisation

13.1 Introduction 13.2 A General Methodology for Enzyme Reuse

13.2.1 The Potential of Biocatalysis by Far Exceeds Its Current Exploitation 13.2.2 Unlocking the Potential of Enzymes 13.2.3 Immobilised Enzymes for the Pharmaceutical Industry 13.2.4 The Reusable Enzyme Utopia – Enzymes Anchored in Space 13.2.5 The EziG Technology 13.2.6 Standardised Procedure for Immobilisation 13.2.7 Lower Cost Materials versus High Performance

13.3 Case Studies

13.3.1 In-reactor Enzyme Immobilisation 13.3.2 Two-phase System in Flow for in situ Product Removal 13.3.3 Candida antarctica Lipase B (CalB) 13.3.4 Co-immobilisation for Cascade Reactions

13.4 Prospects

13.4.1 Stability versus Activity – Replacing Low Cost Catalysts 13.4.2 Biocatalysis in Flow – Towards Manufacturing Processes in Continuous Mode

13.5 Conclusions Acknowledgements References

Chapter 14 Cross-linked Enzyme Aggregates (CLEAs): From Concept to Industrial Biocatalyst

14.1 Introduction: Biocatalysis is Green and Sustainable 14.2 Immobilisation of Enzymes 14.3 The CLEA Technology

14.3.1 The Concept 14.3.2 Preparation of CLEAs 14.3.3 Physical Properties of CLEAs 14.3.4 Advantages and Limitations of CLEAs 14.3.5 Reactor Design

14.4 Scope of the CLEA Technology

14.4.1 Hydrolase CLEAs 14.4.2 Oxidoreductase and Lyase CLEAs

14.5 Multi- and Combi-CLEAs 14.6 Magnetic CLEAs: The New Frontier 14.7 Applications of CLEAs, Combi-CLEAs and mCLEAs

14.7.1 1G and 2G Biofuels Production 14.7.2 Food and Beverages Processing 14.7.3 Synthesis of Semi-synthetic Penicillin and Cephalosporin Antibiotics 14.7.4 Removal of Dyes, Pharma Residues and Endocrine Disruptors from Waste Water 14.7.5 Other Potential Applications

14.8 Conclusions and Future Prospects References

Chapter 15 SynBiocat: Protein Purification, Immobilization and Continuous-flow Processes

15.1 Introduction 15.2 SynBiocat – From Protein Purification to Continuous-flow Processes

15.2.1 Enzyme Production and Purification 15.2.2 Enzyme Immobilization 15.2.3 Desktop Bioreactor Applications

15.3 Conclusion List of Abbreviations Acknowledgements References

Part IV Emerging Industrial Biocatalysis

Chapter 16 Microvi: MicroNiche Engineering™ for Biocatalysis in the Water and Chemical Industries

16.1 Introduction to Microvi 16.2 Microvi’s MicroNiche Engineering™ Platform 16.3 Case Study: MicroNiche Biocatalysts for Water Purification 16.4 Producing Case Study: MicroNiche Biocatalysts for Biobased Chemicals 16.5 Conclusions References

Chapter 17 Nofima: Peptide Recovery and Commercialization by Enzymatic Hydrolysis of Marine Biomass

17.1 Nofima: The Company 17.2 Hydrolysis of Marine Biomass

17.2.1 Chemical Hydrolysis of Marine Biomass 17.2.2 Enzymatic Hydrolysis of Marine Biomass

17.3 Enzymes Used for Bioconversion 17.4 Quality and Classification of Marine Biomass 17.5 Functional Properties and Bioactivities of Hydrolyzed Marine Biomass 17.6 Commercialization of Products from Marine Biomass 17.7 Conclusions 17.8 Case Examples

17.8.1 Marealis – Producing a Nutraceutical from Shrimp Peels 17.8.2 Polybait AS – Producing Fishing Bait from Fisheries By-products

References

Chapter 18 CO2 Solutions: A Biomimetic Approach to Mitigate CO2 Emissions – The Use of Carbonic Anhydrase in an “Industrial Lung”

18.1 Introduction 18.2 Conventional Post-combustion CO2 Capture Technologies 18.3 CSI’ Technology: An Industrial Lung 18.4 Selection and Development of a Robust CA

18.4.1 Elevated Ionic Strength 18.4.2 High pH 18.4.3 Temperatures Above 60 °C 18.4.4 Effect of High Surface Volume Ratio 18.4.5 Effect of High Shear Stress 18.4.6 Effect of Contaminants 18.4.7 Effect of Solid–Liquid Interface 18.4.8 Carbonic Anhydrase Development

18.5 Technology Validation/Demonstration at Pilot Scale 18.6 Conclusions Acknowledgements References

Subject Index

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