High Value Fermentation Products, Volume 1: Human Health

Green technologies are no longer the “future” of science, but the present.  With more and more mature industries, such as the process industries, making large strides seemingly every single day, and more consumers demanding products created from green technologies, it is essential for any business in any industry to be familiar with the latest processes and technologies.  It is all part of a global effort to “go greener,” and this is nowhere more apparent than in fermentation technology.  This book describes relevant aspects of industrial-scale fermentation, an expanding area of activity, which already generates commercial values of over one third of a trillion US dollars annually, and which will most likely radically change the way we produce chemicals in the long-term future. From biofuels and bulk amino acids to monoclonal antibodies and stem cells, they all rely on mass suspension cultivation of cells in stirred bioreactors, which is the most widely used and versatile way to produce. Today, a wide array of cells can be cultivated in this way, and for most of them genetic engineering tools are also available. Examples of products, operating procedures, engineering and design aspects, economic drivers and cost, and regulatory issues are addressed. In addition, there will be a discussion of how we got to where we are today, and of the real world in industrial fermentation. This chapter is exclusively dedicated to large-scale production used in industrial settings.

Table of Contents:
Foreword xvii About the Editors xix List of Contributors xxi Preface xxv Acknowledgement xxvii 1 Introduction, Scope and Significance of Fermentation Technology 1 Saurabh Saran, Alok Malaviya and Asha Chaubey 1.1 Introduction 1 1.2 Background of Fermentation Technology 2 1.3 Market of Fermentation Products 3 1.4 Types of Fermentation 4 1.4.1 Solid State Fermentation (SSF) 4 1.4.2 Submerged Fermentation (SmF) 7 1.4.3 Solid State (SSF) vs. Submerged (SmF) Fermentation 9 1.5 Classification of Fermentation 9 1.6 Design and Parts of Fermentors 10 1.7 Types of Fermentor 15 1.7.1 Stirred Tank Fermentor 15 1.7.2 Airlift Fermentor 16 1.7.3 Bubble Column Fermentor 17 1.7.4 Fluidized Bed Fermentor 18 1.7.5 Packed Bed Fermentor 19 1.7.6 Photo Bioreactor 19 1.8 Industrial Applications of Fermentation Technology 21 1.9 Scope and Global Market of Fermentation Technology 22 1.10 Conclusions 23 References 24 2 Extraction of Bioactive Molecules through Fermentation and Enzymatic Assisted Technologies 27 Ramón Larios-Cruz, Liliana Londoño-Hernández, Ricardo Gómez-García, Ivanoe García, Leonardo Sepulveda, Raúl Rodríguez-Herrera and Cristóbal N. Aguilar 2.1 Introduction 27 2.2 Definition of Bioactives Compounds 29 2.2.1 Polyphenols and Polypeptides 29 2.2.2 Importance and Applications of Bioactive Compounds 29 2.2.3 Bioactive Peptides 31 2.3 Traditional Processes for Obtaining Bioactive Compounds 33 2.3.1 Soxhlet Extraction 33 2.3.2 Liquid-Liquid and Solid-Liquid Extraction 34 2.3.3 Maceration Extraction 35 2.4 Fermentation and Enzymatic Technologies for Obtaining Bioactive Compounds 35 2.4.1 Soft Chemistry in Bioactive Compounds 35 2.4.2 Biotransformation of Bioactive Compounds 36 2.4.3 Enzymatic and Fermentation Technologies 39 2.5 Use of Agroindustrial Waste in the Fermentation Process 45 2.5.1 Cereal Wastes 46 2.5.2 Fruit and Plant Waste 46 2.6 General Parameters in the Optimization of Fermentation Processes 49 2.6.1 Response Surface Methodology 49 2.6.2 First-Order Model 49 2.6.3 Second-Order Model 49 2.7 Final Comments 52 Acknowledgements 52 References 52 3 Antibiotics Against Gram Positive Bacteria 61 Rahul Vikram Singh, Hitesh Sharma, Anshela Koul and Vikash Babu 3.1 Introduction 61 3.2 Target of Antibiotics Against Gram Positive Bacteria 64 3.2.1 Cell Wall Synthesis Inhibition 65 3.2.2 Protein Synthesis Inhibition 70 3.2.3 DNA Synthesis Inhibition 72 3.3 Antibiotics Production Processes 72 3.4 Conclusion 75 References 76 4 Antibiotic Against Gram-Negative Bacteria 79 Maryam Faiyaz, Shikha Gupta and Divya Gupta 4.1 Introduction 79 4.2 Gram-Negative Bacteria and Antibiotics 80 4.2.1 β-Lactam Drugs 81 4.2.2 Macrolide 82 4.2.3 Aminoglycosides 84 4.2.4 Fluoroquinolones 84 4.3 Production of Antibiotics 85 4.3.1 Strain Development 85 4.3.2 Media Formulation and Optimization 88 4.3.3 Fermentation 90 4.3.4 Downstream Processing and Purification 92 4.3.5 Quality Control 95 4.4 Conclusion 95 References 96 5 Role of Antifungal Drugs in Combating Invasive Fungal Diseases 103 Kakoli Dutt 5.1 Introduction 103 5.2 Antifungal Agents 105 5.2.1 Azoles 114 5.2.2 Polyenes 115 5.2.3 Allylamine/Thiocarbonates 116 5.2.4 Other Antifungal Agents 117 5.3 Targets of Antifungal Agents 120 5.3.1 Cell Wall Biosynthesis Inhibitors 120 5.3.2 Sphingolipid Synthesis Inhibitors 123 5.3.3 Ergosterol Synthesis Inhibitors 125 5.3.4 Protein Synthesis Inhibitors 126 5.3.5 Novel Targets 128 5.4 Development of Resistance towards Antifungal Agents 130 5.4.1 Minimum Inhibitory Concentration 130 5.4.2 Antifungal-Drug-Resistance Mechanisms 131 5.5 Market and Drug Development 134 5.6 Conclusions 136 Acknowledgement 137 References 137 6 Current Update on Rapamycin Production and Its Potential Clinical Implications 145 Girijesh K. Patel, Ruchika Goyal1 and Syed M. Waheed 6.1 Introduction 145 6.2 Biosynthesis of Rapamycin 146 6.2.1 Microbial Strain 147 6.2.2 Optimization of Carbon, Nitrogen Sources and Salts 147 6.2.3 Strain Manipulation to Improve Rapamycin Production 148 6.3 Organic Synthesis of Rapamycin 152 6.4 Extraction and Quantification of Rapamycin 152 6.5 Physiological Factors Affecting Rapamycin Biosynthesis 153 6.5.1 Effect of Media Components 153 6.5.2 Effect of pH on Rapamycin Production 153 6.5.3 Effect of Physical Gravity 154 6.5.4 Effect of Morphological Changes 154 6.5.5 Effect of Dissolved Oxygen (DO) and Carbon Dioxide (DCO2) 154 6.6 Production of Rapamycin Analogs 154 6.7 Mechanism of Action of Rapamycin 155 6.8 Use of Rapamycin in Medicine 157 6.8.1 Anti-Fungal Agent 157 6.8.2 Immunosuppression 158 6.8.3 Anti-Cancer Agent 158 6.8.4 Anti-Aging Agent 158 6.8.5 Role in HIV Treatment 158 6.8.6 Rheumatoid Arthritis 159 6.9 Side Effects of Long-term Use of Rapamycin 159 6.10 Conclusions 159 Acknowledgements 160 References 160 7 Advances in Production of Therapeutic Monoclonal Antibodies 165 Richi V Mahajan, Subhash Chand, Mahendra Pal Singh, Apurwa Kestwal and Surinder Singh 7.1 Introduction 165 7.2 Discovery and Clinical Development 166 7.3 Structure and Classification 167 7.4 Nomenclature of Monoclonal Antibodies 168 7.5 Production of Monoclonal Antibodies 170 7.5.1 Hybridoma Technology 170 7.5.2 Epstein-Barr Virus Technology 172 7.5.3 Phage Display Technology 172 7.5.4 Cell Line Based Production Techniques 173 7.5.5 Chemical Modifications of Monoclonal Antibodies 183 7.5.6 Advances in Antibody Technology 183 7.6 Conclusions 185 References 186 8 Antimicrobial Peptides from Bacterial Origin: Potential Alternative to Conventional Antibiotics 193 Lipsy Chopra, Gurdeep Singh, Ramita Taggar, Akanksha Dwivedi, Jitender Nandal, Pradeep Kumar and Debendra K. Sahoo 8.1 Introduction 193 8.2 Classification of Bacteriocins 194 8.2.1 Bacteriocins from Gram-Negative Bacteria 194 8.2.2 Bacteriocins from Gram-Positive Bacteria 194 8.3 Mode of Action 196 8.3.1 Pore-Forming Bacteriocins 196 8.3.2 Non-Pore-Forming Bacteriocins: Intracellular Targets 198 8.4 Applications 198 8.4.1 Food Bio Preservative 198 8.4.2 Food Packaging (In Packaging Films) 198 8.4.3 Hurdle Technology to Enhance Food Safety 199 8.4.4 Therapeutic Potential 200 8.4.5 Effect of Bacteriocins on Biofilms 200 8.5 Conclusions 202 Acknowledgments 202 Abbreviations 202 References 202 9 Non-Ribosomal Peptide Synthetases: Nature’s Indispensable Drug Factories 205 Richa Sharma, Ravi S. Manhas and Asha Chaubey 9.1 Introduction 205 9.1.1 Non-Ribosomal Peptides as Natural Products 205 9.1.2 Non-Ribosomal Peptides as Drugs 206 9.2 NRPS Machinery 208 9.3 Catalytic Domains of NRPSs 208 9.3.1 Adenylation (A) Domains 208 9.3.2 Thiolation (T) or PCP Domains 209 9.3.3 Condensation (C) Domains 209 9.3.4 Thioesterase (Te) Domains 209 9.4 Types of NRPS 210 9.4.1 Type A (Linear NRPS) 210 9.4.2 Type B (Iterative NRPS) 210 9.4.3 Type C (Non-linear NRPS) 210 9.5 Working of NRPSs 210 9.5.1 Priming Thiolation Domain of NRPS 211 9.5.2 Substrate Recognition and Activation 211 9.5.3 Peptide Bond Formation between NRP Monomers 211 9.5.4 Chain Termination of NRP Synthesis 212 9.5.5 NRP Tailoring 212 9.6 Sources of NRPs 213 9.7 Production of Non-Ribosomal Peptides 216 9.8 Future Scope 218 Acknowledgements 219 References 219 10 Enzymes as Therapeutic Agents in Human Disease Management 225 Babbal, Adivitiya, Shilpa Mohanty and Yogender Pal Khasa 10.1 Introduction 225 10.2 Pancreatic Enzymes 230 10.2.1 Trypsin (EC 3.4.21.4) 230 10.2.2 Pancreatic Lipase (EC 3.1.1.3) 231 10.2.3 Amylases (EC 3.2.1.1) 231 10.3 Oncolytic Enzymes 232 10.3.1 L-Asparaginase (EC 3.5.1.1) 232 10.3.2 L-Glutaminase (EC 3.5.1.2) 233 10.3.3 Arginine Deiminase (ADI) (EC 3.5.3.6) 233 10.4 Antidiabetic Enzymes 234 10.4.1 Glucokinase (EC2.7.1.1) 10.5 Liver Enzymes 235 10.5.1 Superoxide Dismutase (SOD) (EC 1.15.1.1) 235 10.5.2 Alkaline Phosphatase (ALP) (EC 3.1.3.1) 236 10.6 Kidney Disorder 237 10.6.1 Uricase (EC 1.7.3.3) 237 10.6.2 Urease (EC 3.5.1.5) 238 10.7 DNA- and RNA-Based Enzymes 238 10.7.1 Dornase 239 10.7.2 Adenosine Deaminase 240 10.7.3 Ribonuclease 240 10.8 Enzymes for the Treatment of Cardiovascular Disorders 241 10.8.1 The Hemostatic System 242 10.8.2 Enzymes of the Hemostatic System 244 10.9 Lysosomal Storage Disorders 251 10.9.1 α-Galactosidase A (EC 3.2.1.22) 251 10.9.2 Glucocerebrosidase (EC 3.2.1.45) 252 10.9.3 Acid Alpha-Glucosidase (GAA) (EC 3.2.1.20) 253 10.9.4 α-L-iduronidase (Laronidase) (EC 3.2.1.76) 253 10.10 Miscellaneous Enzymes 254 10.10.1 Phenylalanine Hydroxylase (EC 1.14.16.1) 254 10.10.2 Collagenase (EC 3.4.24.3) 255 10.10.3 Hyaluronidase 256 10.10.4 Bromelain 256 10.11 Conclusions 256 References 257 11 Erythritol: A Sugar Substitute 265 Kanti N. Mihooliya, Jitender Nandal, Himanshu Verma and Debendra K. Sahoo 11.1 Introduction 265 11.1.1 Background of Erythritol 265 11.1.2 History of Erythritol 268 11.1.3 Occurrence of Erythritol 268 11.1.4 General Characteristics 268 11.2 Chemical and Physical Properties of Erythritol 271 11.3 Estimation of Erythritol 271 11.3.1 Thin Layer Chromatography (TLC) 273 11.3.2 Colorimetric Assay for Detection of Polyols 273 11.3.3 High-Performance Liquid Chromatography (HPLC) 273 11.3.4 Capillary Electrophoresis (CE) 273 11.4 Production Methods for Erythritol 274 11.4.1 Chemical Methods for Erythritol Production 274 11.4.2 Fermentative Methods for Erythritol Production 274 11.5 Optimization of Erythritol Production 275 11.5.1 One Factor at a Time 276 11.5.2 Statistical Design Approaches 277 11.6 Toxicology of Erythritol 277 11.7 Applications of Erythritol 277 11.7.1 Confectioneries 278 11.7.2 Bakery 279 11.7.3 Pharmaceuticals 279 11.7.4 Cosmetics 279 11.7.5 Beverages 279 11.8 Precautions for Erythritol Usage 279 11.9 Global Market for Erythritol 280 11.10 Conclusions 280 References 281 12 Sugar and Sugar Alcohols: Xylitol 285 Bhumica Agarwal and Lalit Kumar Singh 12.1 Introduction 285 12.1.1 Lignocellulosic Biomass 286 12.1.2 Properties of Xylitol 287 12.1.3 Occurrence and Production of Xylitol 289 12.2 Biomass Conversion Process 289 12.2.1 Pretreatment Methodologies 289 12.2.2 Enzymatic Hydrolysis 292 12.2.3 Detoxification Techniques 293 12.3 Utilization of Xylose 296 12.3.1 Microorganisms Utilizing Xylose 296 12.3.2 Metabolism of Xylose 297 12.4 Process Variables 299 12.4.1 Temperature and pH 299 12.4.2 Substrate Concentration 300 12.4.3 Aeration 301 References 303 13 Trehalose: An Anonymity Turns Into Necessity 309 Manali Datta and Dignya Desai 13.1 Introduction 309 13.2 Trehalose Metabolism Pathways 310 13.3 Physicochemical Properties and its Biological Significance 311 13.4 Trehalose Production 312 13.4.1 Enzymatic Conversion to Trehalose 312 13.4.2 Microbe Mediated Fermentation 314 13.4.3 Purification and Detection of Trehalose in Fermentation Process 316 13.5 Application of Trehalose 317 13.5.1 Role of Trehalose in Food Industries 317 13.5.2 Role of Trehalose in Cosmetics and Pharmaceutics 318 13.6 Conclusions 319 References 320 14 Production of Yeast Derived Microsomal Human CYP450 Enzymes (Sacchrosomes) in High Yields, and Activities Superior to Commercially Available Microsomal Enzymes 323 Ibidapo Stephen Williams and Bhabatosh Chaudhuri 14.1 Introduction 323 14.1.1 Cytochrome P450 (CYP) Enzymes in Humans 323 14.1.2 Human Cytochrome P450 Enzymes and their Role in Drug Metabolism 324 14.1.3 Requirement of Activating Proteins to Form Functional Human CYP Enzymes 325 14.1.4 Use of Yeast Biased Codons for the Syntheses of Human Cytochrome P450 Genes 325 14.1.5 Expression of Human CYP Genes in Baker’s Yeast from an Episomal Plasmid 325 14.1.6 Expression of Human CYP Genes in Baker’s Yeast from Integrative Plasmids 327 14.1.7 The ADH2 Promoter for Production of Human CYP Enzymes in Baker’s Yeast 327 14.1.8 Growth of Yeast Cells Containing Integrated Copies of CYP Gene Expression Cassettes, Driven by the ADH2 Promoter, for Production of CYP Enzymes 328 14.2 Amounts of Microsomal CYP Enzyme Isolated from Yeast Strains Containing Chromosomally Integrated CYP Gene Expression Cassettes are far Higher than Strains Harbouring an Episomal Expression Plasmid Encoding a CYP Gene 328 14.2.1 Preparation of Microsomal CYP Enzymes 328 14.2.2 Measurement of the Amounts of Functional CYPs in Microsomes Isolated from Baker’s Yeast 329 14.2.3 Production of Functional Human CYP1A2 Microsomal Enzyme from Baker’s Yeast 330 14.2.4 Production of Functional Human CYP3A4 Microsomal Enzyme from Baker’s Yeast 330 14.2.5 Production of Functional Human CYP2D6 Microsomal Enzyme from Baker’s Yeast 331 14.2.6 Production of Functional Human CYP2C19 Microsomal Enzyme from Baker’s Yeast 332 14.2.7 Production of Functional Human CYP2C9 Microsomal Enzyme from Baker’s Yeast 333 14.2.8 Production of Functional Human CYP2E1 Microsomal Enzyme from Baker’s Yeast 333 14.2.9 Comments on the Production of Human CYP Enzymes from Baker’s Yeast 334 14.3 Comparison of CYP Enzyme Activity of Yeast-Derived Microsomes (Sacchrosomes) with Commercially Available Microsomes Isolated from Insect and Bacterial Cells 336 14.3.1 Fluorescence-based Assays for Determining CYP Enzyme Activities in Isolated Microsomes 336 14.3.2 Comparison of Enzyme Activity of CYP1A2 Sacchrosomes with Commercially Available CYP1A2 Microsomes Isolated from Insect and Bacterial Cells 336 14.3.3 Comparison of Enzyme Activity of CYP2C9 Sacchrosomes with Those of Commercially Available CYP2C9 Microsomes from Insect and Bacterial Cells 337 14.3.4 Comparison of Enzyme Activity of CYP2C19 Sacchrosomes with Those of Commercially Available CYP2C19 Microsomes from Insect and Bacterial Cells 337 14.3.5 Comparison of Enzyme Activity of CYP2D6 Sacchrosomes with Those of Commercially Available CYP2D6 Microsomes from Insect and Bacterial Cells 338 14.3.6 Comparison of Enzyme Activity of CYP3A4 Sacchrosomes with Those of Commercially Available CYP3A4 Microsomes from Insect and Bacterial Cells 338 14.3.7 Comparison of Enzyme Activity of CYP2E1 Sacchrosomes with One of the Commercial CYP2E1 Microsomes Available from Insect Cells 339 14.4 IC50 Values of Known CYP Inhibitors Using Sacchrosomes, Commercial Enzymes and HLMs 339 14.5 Stabilisation of Sacchrosomes through Freeze-drying 340 14.6 Conclusions 342 References 345 15 Artemisinin: A Potent Antimalarial Drug 347 Alok Malaviya, Karan Malhotra, Anil Agarwal and Katherine Saikia 15.1 Introduction 347 15.2 Biosynthesis of Artemisinin in Artemisia annua and Pathways Involved 348 15.3 Yield Enhancement Strategies in A. annua 351 15.4 Artemisinin Production Using Heterologous Hosts 352 15.4.1 Microbial Engineering 352 15.4.2 Plant Metabolic Engineering 353 15.5 Spread of Artemisinin Resistance 357 15.6 Challenges in Large-Scale Production 358 15.7 Future Prospects 360 References 360 16 Microbial Production of Flavonoids: Engineering Strategies for Improved Production 365 Aravind Madhavan, Raveendran Sindhu, KB Arun, Ashok Pandey, Parameswaran Binod and Edgard Gnansounou 16.1 Introduction 365 16.2 Flavonoids 366 16.3 Flavonoid Chemistry and Classes 366 16.4 Health Benefits of Flavonoids 367 16.5 Flavonoid Biosynthesis in Microorganism 368 16.6 Engineering of Flavonoid Biosynthesis Pathway 370 16.7 Metabolic Engineering Strategies 370 16.8 Applications of Synthetic Biology in Flavonoid Production 371 16.9 Post-modification of Flavonoids 374 16.10 Purification of Flavonoids 374 16.11 Conclusion 375 Acknowledgements 375 References 376 17 Astaxanthin: Current Advances in Metabolic Engineering of the Carotenoid 381 Manmeet Ahuja, Jayesh Varavadekar, Mansi Vora, Piyush Sethia, Harikrishna Reddy and Vidhya Rangaswamy 17.1 Introduction 381 17.1.1 Structure of Astaxanthin 382 17.1.2 Natural vs. Synthetic Astaxanthin 382 17.1.3 Uses and Market of Astaxanthin 383 17.2 Pathway of Astaxanthin 384 17.2.1 Bacteria 384 17.2.2 Algae 384 17.2.3 Yeast 385 17.2.4 Plants 386 17.3 Challenges/Current State of the Art in Fermentation/Commercial Production 386 17.4 Metabolic Engineering for Astaxanthin 388 17.4.1 Bacteria 388 17.4.2 Plants 390 17.4.3 Synechocystis 391 17.4.4 Algae 391 17.4.5 Yeast 392 17.5 Future Prospects 393 References 395 18 Exploitation of Fungal Endophytes as Bio-factories for Production of Functional Metabolites through Metabolic Engineering; Emphasizing on Taxol Production 401 Sanjog Garyali, Puja Tandon, M. Sudhakara Reddy and Yong Wang 18.1 Introduction 401 18.2 Taxol: History and Clinical Impact 403 18.3 Endophytes 403 18.3.1 Biodiversity of Endophytes 405 18.3.2 Endophyte vs. Host Plant: the Relationship 405 18.4 The Plausibility of Horizontal Gene Transfer (HGT) Hypothesis 407 18.5 Endophytes as Biological Factories of Functional Metabolites 409 18.6 Taxol Producing Endophytic Fungi 410 18.7 Molecular Basis of Taxol Production by Taxus Plants (Taxol Biosynthetic Pathway) 412 18.8 Metabolic Engineering for Synthesis of Taxol: Next Generation Tool 416 18.8.1 Plant Cell Culture 417 18.8.2 Microbial Metabolic Engineering for Synthesis of Taxol and Its Precursors 418 18.8.3 Metabolic Engineering in Heterologous Plant for Synthesis of Taxol and Its Precursors 420 18.9 Future Perspectives 421 Acknowledgements 423 References 423 Index 431