Description

Book Synopsis

Lactic acid bacteria (LAB) have historically been used as starter cultures for the production of fermented foods, especially dairy products. Over recent years, new areas have had a strong impact on LAB studies: the application of ?omics? tools; the study of complex microbial ecosystems, the discovery of new LAB species, and the use of LAB as powerhouses in the food and medical industries.

This second edition of Biotechnology of Lactic Acid Bacteria: Novel Applications addresses the major advances in the fields over the last five years. Thoroughly revised and updated, the book includes new chapters. Among them:

  • The current status of LAB systematics;
  • The role of LAB in the human intestinal microbiome and the intestinal tract of animals and its impact on the health and disease state of the host;
  • The involvement of LAB in fruit and vegetable fermentations;
  • The production of nutraceuticals and aroma compounds by LAB; and

  • Table of Contents

    List of Contributors xiii

    Preface xviii

    1. Updates on Metabolism in Lactic Acid Bacteria in Light of “Omic” Technologies 1
    Magdalena Kowalczyk, Baltasar Mayo, María Fernández, and Tamara Aleksandrzak-Piekarczyk

    1.1. Sugar Metabolism 1

    1.1.1. Practical Aspects of Sugar Catabolism 3

    1.2. Citrate Metabolism and Formation of Aroma Compounds 4

    1.2.1. Citrate Transport 4

    1.2.2. Conversion of Citrate into Pyruvate and Production of Aroma Compounds 6

    1.2.3. Conversion of Citrate into Succinate 6

    1.2.4. Bioenergetics of Citrate Metabolism 6

    1.3. The Proteolytic System of Lactic Acid Bacteria 6

    1.3.1. Protein Degradation 7

    1.3.2. Peptidases 8

    1.3.3. Technological Applications of the Proteolytic System 10

    1.3.4. Amino Acid Catabolism 10

    1.4. LAB Metabolism in Light of Genomics Comparative Genomics and Metagenomics 12

    1.5. Novel Aspects of Metabolism Regulation in the Post]genomic Age 12

    1.6. Functional Genomics and Metabolism 16

    1.6.1. Transcriptomics Proteomics and Metabolomics 16

    1.6.2. Global Phenotypic Characterization of Microbial Cells 17

    1.7. Systems Biology of LAB 17

    Acknowledgments 18

    References 18

    2. Systematics of Lactic Acid Bacteria: Current Status 25
    Giovanna E. Felis, Elisa Salvetti, and Sandra Torriani

    2.1. Families and Genera of Lactic Acid Bacteria 25

    2.2. A Focus on the Family Lactobacillaceae 27

    2.3. Taxonomic Tools in the Genomic Era 29

    References 30

    3. Genomic Evolution of Lactic Acid Bacteria: From Single Gene Function to the Pan]genome 32
    Grace L. Douglas, M. Andrea Azcarate-Peri,l and Todd R. Klaenhammer

    3.1. The Genomics Revolution 32

    3.2. Genomic Adaptations of LAB to the Environment 33

    3.2.1. LAB Evolution in the Dairy Environment 33

    3.2.2. LAB Evolution in Vegetable and Meat Fermentations 34

    3.2.3. Fast]evolving LAB 35

    3.2.4. LAB in the GI Tract 35

    3.3. “Probiotic Islands”? 36

    3.4. Stress Resistance and Quorum Sensing Mechanisms 39

    3.5. The Impact of Genome Sequencing on Characterization Taxonomy and Pan]genome Development of
    Lactic Acid Bacteria 40

    3.6. Functional Genomic Studies to Unveil Novel LAB Utilities 45

    3.7. Conclusions 47

    References 47

    4. Lactic Acid Bacteria: Comparative Genomic Analyses of Transport Systems 55
    Graciela L. Lorca, Taylor A. Twiddy, and Milton H. Saier Jr.

    4.1. Introduction 55

    4.2. Channel]forming Proteins 56

    4.3. The Major Facilitator Superfamily 59

    4.4. Other Large Superfamilies of Secondary Carriers 60

    4.5. ABC Transporters 64

    4.6. Heavy Metal Transporters 65

    4.7. P-type ATPases in Prokaryotes 68

    4.8. The Prokaryote-specific Phosphotransferase System (PTS) 68

    4.9. Multidrug Resistance Pumps 71

    4.10. Nutrient Transport in LAB 71

    4.11. Conclusions and Perspectives 72

    Note 73

    Acknowledgments 73

    References 73

    5. Novel Developments in Bacteriocins from Lactic Acid Bacteria 80
    Ingolf F. Nes, Christina Gabrielsen, Dag A. Brede, and Dzung B. Diep

    5.1. Introduction 80

    5.2. Characteristics and Classification of Bacteriocins 80

    5.2.1. Class Ia: Lantibiotics 81

    5.2.2. Class II: The Non-lantibiotics 81

    5.3. Mode of Action 84

    5.4. Bacteriocin Resistance 86

    5.5. Applications 88

    5.5.1. Opportunities and Hurdles in Application of Bacteriocins 88

    5.5.2. Application of Bacteriocins in Medical-related and Personal Hygiene Products 88

    5.5.3. Bacteriocin]producing Probiotics 90

    5.6. Future Perspectives 92

    References 93

    6. Bacteriophages of Lactic Acid Bacteria and Biotechnological Tools 100
    Beatriz Martínez, Pilar García, Ana Rodríguez, Mariana Piuri, and Raúl R. Raya

    6.1. Introduction 100

    6.2. Bacteriophages of Lactic Acid Bacteria 101

    6.2.1. Classification of Lactococcal Phages 103

    6.3. Antiphage Strategies 103

    6.3.1. Natural Mechanisms of Phage Resistance 103

    6.3.2. Genetically Engineered Antiphage Systems 105

    6.4. Phage-Based Molecular Tools 106

    6.4.1. Phage Integrases and Integration Vectors 106

    6.4.2. CRISPR Applications 108

    6.4.3. Recombineering 110

    6.5. LAB Phages as Biocontrol Tools 113

    6.6. Conclusions 113

    References 113

    7. Lactic Acid Bacteria and the Human Intestinal Microbiome 120
    François P. Douillard and Willem M. de Vos

    7.1. Introduction 120

    7.2. Ecology of the Human Intestinal Tract 121

    7.2.1. The Human Microbiome in the Upper and Lower Intestinal Tract 121

    7.2.2. Lactic Acid Bacteria Associated with the Human Intestine 122

    7.2.3. Metagenomic Studies of the Intestine in Relation to LAB 123

    7.3. A Case Study: The Lactobacillus rhamnosus Species 124

    7.3.1. Genomic Diversity of Lact. rhamnosus and Intestinal Adaptation 124

    7.3.2. Lact. rhamnosus Metabolism and Adaptation to the Intestine 126

    7.3.3. Host Interaction Factors in Lact. rhamnosus 127

    7.3.4. The Lact. rhamnosus Species: Autochthonous or Allochthonous in the Human Intestine? 127

    7.4. Concluding Perspectives and Future Directions 129

    Acknowledgments 130

    References 130

    8. Probiotics and Functional Foods in Immunosupressed Hosts 134
    Ivanna Novotny Nuñez, Martin Manuel, Palomar Alejandra de Moreno de LeBlanc, Carolina Maldonado Galdeano, and Gabriela Perdigón

    8.1. Introduction 134

    8.2. Probiotic Fermented Milk in a Malnutrition Model 135

    8.3. Probiotic Administration in Stress Process 138

    8.4. Conclusions 140

    Acknowledgments 141

    References 141

    9. Lactic Acid Bacteria in Animal Production and Health 144
    Damien Bouchard, Sergine Even, and Yves Le Loir

    9.1. Introduction 144

    9.2. Lactic Acid Bacteria and Probiotics 145

    9.3. Classifications and Regulatory Criteria of Probiotics in Animal Health 146

    9.4. Probiotic LAB and Animal Production Sectors 147

    9.4.1. Probiotics in Ruminants 147

    9.4.2. Probiotics in Pigs 150

    9.4.3. Probiotics in Poultry 152

    9.5. Conclusions 154

    References 154

    10. Proteomics for Studying Probiotic Traits 159
    Rosa Anna Siciliano and Maria Fiorella Mazzeo

    10.1. Introduction 159

    10.2. Mass Spectrometric Methodologies in Proteomics 160

    10.2.1. The Classical Approach: 2-DE Separation and Protein Identification by Mass Spectrometry 160

    10.2.2. Gel-Free Proteomic Approaches 160

    10.3. Proteomics for Studying Molecular Mechanisms of Probiotic Action 161

    10.3.1. Adaptation Mechanisms to the GIT Environment 161

    10.3.2. Adhesion Mechanisms to the Host Mucosa 162

    10.3.3. Molecular Mechanisms of Probiotic Immunomodulatory Effects 164

    10.3.4. Probiotics and Prebiotics 164

    10.4. Concluding Remarks and Future Directions 165

    References 166

    11. Engineering Lactic Acid Bacteria and Bifidobacteria for Mucosal Delivery of Health Molecules 170
    Thibault Allain, Camille Aubry, Jane M. Natividad, Jean-Marc Chatel, Philippe Langella, and Luis G. Bermúdez-Humarán

    11.1. Introduction 170

    11.2. Lactococcus lactis: A Pioneer Bacterium 171

    11.3. Lactobacillus spp. as a Delivery Vector 171

    11.4. Bifidobacteria as a New Live Delivery Vehicle 171

    11.5. Engineering Genetic Tools for Protein and DNA Delivery 172

    11.5.1. Cloning Vectors 172

    11.5.2. Expression Systems 173

    11.6. Therapeutic Applications 176

    11.6.1. Inflammatory Bowel Disease (IBD) 176

    11.6.2. Anti-protease Enzyme-producing LAB: The Tole of Elafin 176

    11.6.3. Antioxidant Enzyme-producing Lactococci and Lactobacilli 177

    11.7. Allergy 178

    11.7.1. Use of LAB in Food Allergy 178

    11.7.2. Allergic Airways Diseases 179

    11.8. Autoimmune Diseases 180

    11.8.1. Type 1 Diabetes Mellitus 180

    11.8.2. Celiac Disease 180

    11.9. Infectious Diseases 181

    11.9.1. Mucosal Delivery of Bacterial Antigens 181

    11.9.2. Mucosal Delivery of Viral Antigens 181

    11.9.3. Parasitic Diseases 183

    References 184

    12. Lactic Acid Bacteria for Dairy Fermentations: Specialized Starter Cultures to Improve Dairy Products 191
    Domenico Carminati, Giorgio Giraffa, Miriam Zago, Mariángeles Briggiler Marcó, Daniela Guglielmotti, Ana
    Binetti, and Jorge Reinheimer

    12.1. Introduction 191

    12.2. Adjunct Cultures 191

    12.2.1. Ripening Cultures 192

    12.2.2. Protective Cultures 193

    12.2.3. Probiotic Cultures 195

    12.2.4. Exopolysaccharide-producing Starters 196

    12.3. Phage-Resistant Starters 199

    12.4. New Sources of Starter Strains 201

    12.5. Conclusions 202

    References 203

    13. Lactobacillus sakei in Meat Fermentation 209
    Marie-Christine Champomier-Vergès and Monique Zagorec

    13.1. Introduction 209

    13.2. Genomics and Diversity of the Species Lactobacillus sakei 210

    13.3. Post-genomic Vision of Meat Fitness Traits of Lactobacillus sakei 212

    13.3.1. Energy Sources 212

    13.3.2. Stress Response 213

    13.4. Conclusions 214

    References 214

    14. Vegetable and Fruit Fermentation by Lactic Acid Bacteria 216
    Raffaella Di Cagno, Pasquale Filannino, and Marco Gobbetti

    14.1. Introduction 216

    14.2. Lactic Acid Bacteria Microbiota of Raw Vegetables and Fruits 216

    14.3. Fermentation of Vegetable Products 218

    14.3.1. Spontaneous Fermentation 218

    14.3.2. The Autochthonous Starters 218

    14.4. Main Fermented Vegetable Products 221

    14.4.1. Sauerkrauts 221

    14.4.2. Kimchi 222

    14.4.3. Pickled Cucumbers 223

    14.5. Physiology and Biochemistry of LAB during Vegetable and Fruit Fermentation 223

    14.5.1. Metabolic Adaptation by LAB during Plant Fermentation 224

    14.6. Food Phenolic Compounds: Antimicrobial Activity and Microbial Responses 224

    14.6.1. Effect of Phenolics on the Growth and Viability of LAB 224

    14.6.2. Metabolism of Phenolics by LAB 226

    14.7. Health-promoting Properties of Fermented Vegetables and Fruits 226

    14.8. Alternative Sources of Novel Probiotics Candidates 226

    14.9. Vehicles for Delivering Probiotics 228

    14.10. Conclusions 229

    References 229

    15. Lactic Acid Bacteria and Malolactic Fermentation in Wine 231
    Aline Lonvaud-Funel

    15.1. Introduction 231

    15.2. The Lactic Acid Bacteria of Wine 231

    15.2.1. Origin 231

    15.2.2. Species 232

    15.2.3. Identification 232

    15.2.4. Typing at Strain Level 233

    15.2.5. Detection of Specific Strains 233

    15.3. The Oenococcus Oeni Species 233

    15.4. Evolution of Lactic Acid Bacteria during Winemaking 234

    15.4.1. Interactions between Wine Microorganisms 235

    15.4.2. Environmental Factors 236

    15.5. Lactic Acid Bacteria Metabolism and its Impact on Wine Quality 237

    15.5.1. Sugars 237

    15.5.2. Carboxylic Acids 237

    15.5.3. Amino Acids 240

    15.5.4. Other Metabolisms with Sensorial Impact 241

    15.6. Controlling the Malolactic Fermentation 242

    15.7. Conclusions 243

    References 244

    16. The Functional Role of Lactic Acid Bacteria in Cocoa Bean Fermentation 248
    Luc De Vuyst and Stefan Weckx

    16.1. Introduction 248

    16.2. Cocoa Crop Cultivation and Harvest 249

    16.3. The Cocoa Pulp or Fermentation Substrate 250

    16.4. Fresh Unfermented Cocoa Beans 251

    16.5. Cocoa Bean Fermentation 252

    16.5.1. Rationale 252

    16.5.2. Farming Practices 253

    16.6. Succession of Microorganisms during Cocoa Bean Fermentation 256

    16.6.1. The Spontaneous Three-phase Cocoa Bean Fermentation Process 256

    16.6.2. Yeast Fermentation 257

    16.6.3. LAB Fermentation 260

    16.6.4. AAB Fermentation 264

    16.7. Biochemical Changes in the Cocoa Beans during Fermentation and Drying 266

    16.8. Optimal Fermentation Course and End of Fermentation 268

    16.9. Further Processing of Fermented Cocoa Beans 269

    16.9.1. Drying of Fermented Cocoa Beans 269

    16.9.2. Roasting of Fermented Dry Cocoa Beans 270

    16.10. Use of Starter Cultures for Cocoa Bean Fermentation 271

    16.10.1. Rationale 271

    16.10.2. Experimental Use of Cocoa Bean Starter Cultures 271

    16.11. Concluding Remarks 273

    References 273

    17. B-Group Vitamins Production by Probiotic Lactic Acid Bacteria 279
    Jean Guy LeBlanc, Jonathan Emiliano Laiño, Marianela Juárez del Valle, Graciela Savoy de Giori, Fernando
    Sesma, and María Pía Taranto

    17.1. Introduction 279

    17.2. B-Group Vitamins 280

    17.2.1. Riboflavin (Vitamin B2 ) 281

    17.2.2. Folates (Vitamin B9) 284

    17.3. Probiotics In Situ 286

    17.3.1. Vitamin B12 (Cobalamin) 288

    17.3.2. Cobalamin Biosynthesis by Lactobacillus reuteri 289

    17.4. Conclusions 291

    Acknowledgments 292

    References 292

    18. Nutraceutics and High Value Metabolites Produced by Lactic Acid Bacteria 297
    Elvira M. Hebert, Graciela Savoy de Giori, and Fernanda Mozzi

    18.1. Introduction 297

    18.2. Nutraceutics 298

    18.2.1. Low-calorie Sugars 298

    18.2.2. Short-Chain Fatty Acids 300

    18.2.3. Conjugated Linoleic Acid (CLA) 301

    18.2.4. Bioactive Peptides 301

    18.2.5. Gamma-aminobutyric Acid (GABA) 303

    18.2.6. Vitamins 305

    18.3. Exopolysaccharides 306

    18.4. Commodity Chemicals 307

    18.5. Conclusions 308

    References 308

    19. Production of Flavor Compounds by Lactic Acid Bacteria in Fermented Foods 314
    Anne Thierry, Tomislav Pogačic, Magalie Weber, and Sylvie Lortal

    19.1. Introduction 314

    19.2. Flavor and Aroma Compounds 315

    19.2.1. Volatile Compounds: Diversity Analytical Methods 315

    19.2.2. Contribution of Volatile Aroma Compounds to Flavor 316

    19.2.3. Origin of Aroma Compounds 316

    19.3. LAB of Fermented Foods and their Role in Flavor Formation 316

    19.3.1. Biochemical Processes of Flavor Compound Formation in Food and Potential of LAB 324

    19.3.2. Flavor Compounds Produced from Carbohydrate Fermentation by LAB 324

    19.3.3. Flavor Compounds from Amino Acid Conversion by LAB 326

    19.3.4. Flavor Compounds from Lipids in LAB 327

    19.3.5. Synthesis of Esters 328

    19.3.6. Interspecies and Intraspecies Variations of Aroma Compound Production 328

    19.4. Biotic and Abiotic Factors Modulating the Contribution of LAB to Flavor Formation 331

    19.4.1. General Scheme of Flavor Formation in Fermented Foods In Situ 331

    19.4.2. Factors Modulating the Expression of the Flavor-related Activities of LAB 332

    19.4.3. Factors Determining the Real Contribution of LAB to Food Flavor 333

    19.5. Conclusions and Research Perspectives 333

    References 334

    20. Lactic Acid Bacteria Biofilms: From their Formation to their Health and Biotechnological Potential 341
    Jean-Christophe Piard and Romain Briandet

    20.1. Lactic Acid Bacteria Biofilms are Ubiquitous in a Wide Variety of Environments from Nature to
    Domesticated Settings 341

    20.2. Biofilm Life Cycle and Bacterial Factors Involved in LAB Biofilm Lifestyle 346

    20.3. Health and Biotechnological Potential of LAB Biofilms and Underlying Mechanisms 352

    20.4. Conclusions 354

    Acknowledgments 355

    References 355

    Index 362

Biotechnology of Lactic Acid Bacteria

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    A Hardback by Fernanda Mozzi, Rául R. Raya, Graciela M. Vignolo

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      View other formats and editions of Biotechnology of Lactic Acid Bacteria by Fernanda Mozzi

      Publisher: John Wiley and Sons Ltd
      Publication Date: 20/11/2015
      ISBN13: 9781118868409, 978-1118868409
      ISBN10: 1118868404
      Also in:
      Microbiology (non-medical) Science: general issues

      Description

      Book Synopsis

      Lactic acid bacteria (LAB) have historically been used as starter cultures for the production of fermented foods, especially dairy products. Over recent years, new areas have had a strong impact on LAB studies: the application of ?omics? tools; the study of complex microbial ecosystems, the discovery of new LAB species, and the use of LAB as powerhouses in the food and medical industries.

      This second edition of Biotechnology of Lactic Acid Bacteria: Novel Applications addresses the major advances in the fields over the last five years. Thoroughly revised and updated, the book includes new chapters. Among them:

      • The current status of LAB systematics;
      • The role of LAB in the human intestinal microbiome and the intestinal tract of animals and its impact on the health and disease state of the host;
      • The involvement of LAB in fruit and vegetable fermentations;
      • The production of nutraceuticals and aroma compounds by LAB; and

      • Table of Contents

        List of Contributors xiii

        Preface xviii

        1. Updates on Metabolism in Lactic Acid Bacteria in Light of “Omic” Technologies 1
        Magdalena Kowalczyk, Baltasar Mayo, María Fernández, and Tamara Aleksandrzak-Piekarczyk

        1.1. Sugar Metabolism 1

        1.1.1. Practical Aspects of Sugar Catabolism 3

        1.2. Citrate Metabolism and Formation of Aroma Compounds 4

        1.2.1. Citrate Transport 4

        1.2.2. Conversion of Citrate into Pyruvate and Production of Aroma Compounds 6

        1.2.3. Conversion of Citrate into Succinate 6

        1.2.4. Bioenergetics of Citrate Metabolism 6

        1.3. The Proteolytic System of Lactic Acid Bacteria 6

        1.3.1. Protein Degradation 7

        1.3.2. Peptidases 8

        1.3.3. Technological Applications of the Proteolytic System 10

        1.3.4. Amino Acid Catabolism 10

        1.4. LAB Metabolism in Light of Genomics Comparative Genomics and Metagenomics 12

        1.5. Novel Aspects of Metabolism Regulation in the Post]genomic Age 12

        1.6. Functional Genomics and Metabolism 16

        1.6.1. Transcriptomics Proteomics and Metabolomics 16

        1.6.2. Global Phenotypic Characterization of Microbial Cells 17

        1.7. Systems Biology of LAB 17

        Acknowledgments 18

        References 18

        2. Systematics of Lactic Acid Bacteria: Current Status 25
        Giovanna E. Felis, Elisa Salvetti, and Sandra Torriani

        2.1. Families and Genera of Lactic Acid Bacteria 25

        2.2. A Focus on the Family Lactobacillaceae 27

        2.3. Taxonomic Tools in the Genomic Era 29

        References 30

        3. Genomic Evolution of Lactic Acid Bacteria: From Single Gene Function to the Pan]genome 32
        Grace L. Douglas, M. Andrea Azcarate-Peri,l and Todd R. Klaenhammer

        3.1. The Genomics Revolution 32

        3.2. Genomic Adaptations of LAB to the Environment 33

        3.2.1. LAB Evolution in the Dairy Environment 33

        3.2.2. LAB Evolution in Vegetable and Meat Fermentations 34

        3.2.3. Fast]evolving LAB 35

        3.2.4. LAB in the GI Tract 35

        3.3. “Probiotic Islands”? 36

        3.4. Stress Resistance and Quorum Sensing Mechanisms 39

        3.5. The Impact of Genome Sequencing on Characterization Taxonomy and Pan]genome Development of
        Lactic Acid Bacteria 40

        3.6. Functional Genomic Studies to Unveil Novel LAB Utilities 45

        3.7. Conclusions 47

        References 47

        4. Lactic Acid Bacteria: Comparative Genomic Analyses of Transport Systems 55
        Graciela L. Lorca, Taylor A. Twiddy, and Milton H. Saier Jr.

        4.1. Introduction 55

        4.2. Channel]forming Proteins 56

        4.3. The Major Facilitator Superfamily 59

        4.4. Other Large Superfamilies of Secondary Carriers 60

        4.5. ABC Transporters 64

        4.6. Heavy Metal Transporters 65

        4.7. P-type ATPases in Prokaryotes 68

        4.8. The Prokaryote-specific Phosphotransferase System (PTS) 68

        4.9. Multidrug Resistance Pumps 71

        4.10. Nutrient Transport in LAB 71

        4.11. Conclusions and Perspectives 72

        Note 73

        Acknowledgments 73

        References 73

        5. Novel Developments in Bacteriocins from Lactic Acid Bacteria 80
        Ingolf F. Nes, Christina Gabrielsen, Dag A. Brede, and Dzung B. Diep

        5.1. Introduction 80

        5.2. Characteristics and Classification of Bacteriocins 80

        5.2.1. Class Ia: Lantibiotics 81

        5.2.2. Class II: The Non-lantibiotics 81

        5.3. Mode of Action 84

        5.4. Bacteriocin Resistance 86

        5.5. Applications 88

        5.5.1. Opportunities and Hurdles in Application of Bacteriocins 88

        5.5.2. Application of Bacteriocins in Medical-related and Personal Hygiene Products 88

        5.5.3. Bacteriocin]producing Probiotics 90

        5.6. Future Perspectives 92

        References 93

        6. Bacteriophages of Lactic Acid Bacteria and Biotechnological Tools 100
        Beatriz Martínez, Pilar García, Ana Rodríguez, Mariana Piuri, and Raúl R. Raya

        6.1. Introduction 100

        6.2. Bacteriophages of Lactic Acid Bacteria 101

        6.2.1. Classification of Lactococcal Phages 103

        6.3. Antiphage Strategies 103

        6.3.1. Natural Mechanisms of Phage Resistance 103

        6.3.2. Genetically Engineered Antiphage Systems 105

        6.4. Phage-Based Molecular Tools 106

        6.4.1. Phage Integrases and Integration Vectors 106

        6.4.2. CRISPR Applications 108

        6.4.3. Recombineering 110

        6.5. LAB Phages as Biocontrol Tools 113

        6.6. Conclusions 113

        References 113

        7. Lactic Acid Bacteria and the Human Intestinal Microbiome 120
        François P. Douillard and Willem M. de Vos

        7.1. Introduction 120

        7.2. Ecology of the Human Intestinal Tract 121

        7.2.1. The Human Microbiome in the Upper and Lower Intestinal Tract 121

        7.2.2. Lactic Acid Bacteria Associated with the Human Intestine 122

        7.2.3. Metagenomic Studies of the Intestine in Relation to LAB 123

        7.3. A Case Study: The Lactobacillus rhamnosus Species 124

        7.3.1. Genomic Diversity of Lact. rhamnosus and Intestinal Adaptation 124

        7.3.2. Lact. rhamnosus Metabolism and Adaptation to the Intestine 126

        7.3.3. Host Interaction Factors in Lact. rhamnosus 127

        7.3.4. The Lact. rhamnosus Species: Autochthonous or Allochthonous in the Human Intestine? 127

        7.4. Concluding Perspectives and Future Directions 129

        Acknowledgments 130

        References 130

        8. Probiotics and Functional Foods in Immunosupressed Hosts 134
        Ivanna Novotny Nuñez, Martin Manuel, Palomar Alejandra de Moreno de LeBlanc, Carolina Maldonado Galdeano, and Gabriela Perdigón

        8.1. Introduction 134

        8.2. Probiotic Fermented Milk in a Malnutrition Model 135

        8.3. Probiotic Administration in Stress Process 138

        8.4. Conclusions 140

        Acknowledgments 141

        References 141

        9. Lactic Acid Bacteria in Animal Production and Health 144
        Damien Bouchard, Sergine Even, and Yves Le Loir

        9.1. Introduction 144

        9.2. Lactic Acid Bacteria and Probiotics 145

        9.3. Classifications and Regulatory Criteria of Probiotics in Animal Health 146

        9.4. Probiotic LAB and Animal Production Sectors 147

        9.4.1. Probiotics in Ruminants 147

        9.4.2. Probiotics in Pigs 150

        9.4.3. Probiotics in Poultry 152

        9.5. Conclusions 154

        References 154

        10. Proteomics for Studying Probiotic Traits 159
        Rosa Anna Siciliano and Maria Fiorella Mazzeo

        10.1. Introduction 159

        10.2. Mass Spectrometric Methodologies in Proteomics 160

        10.2.1. The Classical Approach: 2-DE Separation and Protein Identification by Mass Spectrometry 160

        10.2.2. Gel-Free Proteomic Approaches 160

        10.3. Proteomics for Studying Molecular Mechanisms of Probiotic Action 161

        10.3.1. Adaptation Mechanisms to the GIT Environment 161

        10.3.2. Adhesion Mechanisms to the Host Mucosa 162

        10.3.3. Molecular Mechanisms of Probiotic Immunomodulatory Effects 164

        10.3.4. Probiotics and Prebiotics 164

        10.4. Concluding Remarks and Future Directions 165

        References 166

        11. Engineering Lactic Acid Bacteria and Bifidobacteria for Mucosal Delivery of Health Molecules 170
        Thibault Allain, Camille Aubry, Jane M. Natividad, Jean-Marc Chatel, Philippe Langella, and Luis G. Bermúdez-Humarán

        11.1. Introduction 170

        11.2. Lactococcus lactis: A Pioneer Bacterium 171

        11.3. Lactobacillus spp. as a Delivery Vector 171

        11.4. Bifidobacteria as a New Live Delivery Vehicle 171

        11.5. Engineering Genetic Tools for Protein and DNA Delivery 172

        11.5.1. Cloning Vectors 172

        11.5.2. Expression Systems 173

        11.6. Therapeutic Applications 176

        11.6.1. Inflammatory Bowel Disease (IBD) 176

        11.6.2. Anti-protease Enzyme-producing LAB: The Tole of Elafin 176

        11.6.3. Antioxidant Enzyme-producing Lactococci and Lactobacilli 177

        11.7. Allergy 178

        11.7.1. Use of LAB in Food Allergy 178

        11.7.2. Allergic Airways Diseases 179

        11.8. Autoimmune Diseases 180

        11.8.1. Type 1 Diabetes Mellitus 180

        11.8.2. Celiac Disease 180

        11.9. Infectious Diseases 181

        11.9.1. Mucosal Delivery of Bacterial Antigens 181

        11.9.2. Mucosal Delivery of Viral Antigens 181

        11.9.3. Parasitic Diseases 183

        References 184

        12. Lactic Acid Bacteria for Dairy Fermentations: Specialized Starter Cultures to Improve Dairy Products 191
        Domenico Carminati, Giorgio Giraffa, Miriam Zago, Mariángeles Briggiler Marcó, Daniela Guglielmotti, Ana
        Binetti, and Jorge Reinheimer

        12.1. Introduction 191

        12.2. Adjunct Cultures 191

        12.2.1. Ripening Cultures 192

        12.2.2. Protective Cultures 193

        12.2.3. Probiotic Cultures 195

        12.2.4. Exopolysaccharide-producing Starters 196

        12.3. Phage-Resistant Starters 199

        12.4. New Sources of Starter Strains 201

        12.5. Conclusions 202

        References 203

        13. Lactobacillus sakei in Meat Fermentation 209
        Marie-Christine Champomier-Vergès and Monique Zagorec

        13.1. Introduction 209

        13.2. Genomics and Diversity of the Species Lactobacillus sakei 210

        13.3. Post-genomic Vision of Meat Fitness Traits of Lactobacillus sakei 212

        13.3.1. Energy Sources 212

        13.3.2. Stress Response 213

        13.4. Conclusions 214

        References 214

        14. Vegetable and Fruit Fermentation by Lactic Acid Bacteria 216
        Raffaella Di Cagno, Pasquale Filannino, and Marco Gobbetti

        14.1. Introduction 216

        14.2. Lactic Acid Bacteria Microbiota of Raw Vegetables and Fruits 216

        14.3. Fermentation of Vegetable Products 218

        14.3.1. Spontaneous Fermentation 218

        14.3.2. The Autochthonous Starters 218

        14.4. Main Fermented Vegetable Products 221

        14.4.1. Sauerkrauts 221

        14.4.2. Kimchi 222

        14.4.3. Pickled Cucumbers 223

        14.5. Physiology and Biochemistry of LAB during Vegetable and Fruit Fermentation 223

        14.5.1. Metabolic Adaptation by LAB during Plant Fermentation 224

        14.6. Food Phenolic Compounds: Antimicrobial Activity and Microbial Responses 224

        14.6.1. Effect of Phenolics on the Growth and Viability of LAB 224

        14.6.2. Metabolism of Phenolics by LAB 226

        14.7. Health-promoting Properties of Fermented Vegetables and Fruits 226

        14.8. Alternative Sources of Novel Probiotics Candidates 226

        14.9. Vehicles for Delivering Probiotics 228

        14.10. Conclusions 229

        References 229

        15. Lactic Acid Bacteria and Malolactic Fermentation in Wine 231
        Aline Lonvaud-Funel

        15.1. Introduction 231

        15.2. The Lactic Acid Bacteria of Wine 231

        15.2.1. Origin 231

        15.2.2. Species 232

        15.2.3. Identification 232

        15.2.4. Typing at Strain Level 233

        15.2.5. Detection of Specific Strains 233

        15.3. The Oenococcus Oeni Species 233

        15.4. Evolution of Lactic Acid Bacteria during Winemaking 234

        15.4.1. Interactions between Wine Microorganisms 235

        15.4.2. Environmental Factors 236

        15.5. Lactic Acid Bacteria Metabolism and its Impact on Wine Quality 237

        15.5.1. Sugars 237

        15.5.2. Carboxylic Acids 237

        15.5.3. Amino Acids 240

        15.5.4. Other Metabolisms with Sensorial Impact 241

        15.6. Controlling the Malolactic Fermentation 242

        15.7. Conclusions 243

        References 244

        16. The Functional Role of Lactic Acid Bacteria in Cocoa Bean Fermentation 248
        Luc De Vuyst and Stefan Weckx

        16.1. Introduction 248

        16.2. Cocoa Crop Cultivation and Harvest 249

        16.3. The Cocoa Pulp or Fermentation Substrate 250

        16.4. Fresh Unfermented Cocoa Beans 251

        16.5. Cocoa Bean Fermentation 252

        16.5.1. Rationale 252

        16.5.2. Farming Practices 253

        16.6. Succession of Microorganisms during Cocoa Bean Fermentation 256

        16.6.1. The Spontaneous Three-phase Cocoa Bean Fermentation Process 256

        16.6.2. Yeast Fermentation 257

        16.6.3. LAB Fermentation 260

        16.6.4. AAB Fermentation 264

        16.7. Biochemical Changes in the Cocoa Beans during Fermentation and Drying 266

        16.8. Optimal Fermentation Course and End of Fermentation 268

        16.9. Further Processing of Fermented Cocoa Beans 269

        16.9.1. Drying of Fermented Cocoa Beans 269

        16.9.2. Roasting of Fermented Dry Cocoa Beans 270

        16.10. Use of Starter Cultures for Cocoa Bean Fermentation 271

        16.10.1. Rationale 271

        16.10.2. Experimental Use of Cocoa Bean Starter Cultures 271

        16.11. Concluding Remarks 273

        References 273

        17. B-Group Vitamins Production by Probiotic Lactic Acid Bacteria 279
        Jean Guy LeBlanc, Jonathan Emiliano Laiño, Marianela Juárez del Valle, Graciela Savoy de Giori, Fernando
        Sesma, and María Pía Taranto

        17.1. Introduction 279

        17.2. B-Group Vitamins 280

        17.2.1. Riboflavin (Vitamin B2 ) 281

        17.2.2. Folates (Vitamin B9) 284

        17.3. Probiotics In Situ 286

        17.3.1. Vitamin B12 (Cobalamin) 288

        17.3.2. Cobalamin Biosynthesis by Lactobacillus reuteri 289

        17.4. Conclusions 291

        Acknowledgments 292

        References 292

        18. Nutraceutics and High Value Metabolites Produced by Lactic Acid Bacteria 297
        Elvira M. Hebert, Graciela Savoy de Giori, and Fernanda Mozzi

        18.1. Introduction 297

        18.2. Nutraceutics 298

        18.2.1. Low-calorie Sugars 298

        18.2.2. Short-Chain Fatty Acids 300

        18.2.3. Conjugated Linoleic Acid (CLA) 301

        18.2.4. Bioactive Peptides 301

        18.2.5. Gamma-aminobutyric Acid (GABA) 303

        18.2.6. Vitamins 305

        18.3. Exopolysaccharides 306

        18.4. Commodity Chemicals 307

        18.5. Conclusions 308

        References 308

        19. Production of Flavor Compounds by Lactic Acid Bacteria in Fermented Foods 314
        Anne Thierry, Tomislav Pogačic, Magalie Weber, and Sylvie Lortal

        19.1. Introduction 314

        19.2. Flavor and Aroma Compounds 315

        19.2.1. Volatile Compounds: Diversity Analytical Methods 315

        19.2.2. Contribution of Volatile Aroma Compounds to Flavor 316

        19.2.3. Origin of Aroma Compounds 316

        19.3. LAB of Fermented Foods and their Role in Flavor Formation 316

        19.3.1. Biochemical Processes of Flavor Compound Formation in Food and Potential of LAB 324

        19.3.2. Flavor Compounds Produced from Carbohydrate Fermentation by LAB 324

        19.3.3. Flavor Compounds from Amino Acid Conversion by LAB 326

        19.3.4. Flavor Compounds from Lipids in LAB 327

        19.3.5. Synthesis of Esters 328

        19.3.6. Interspecies and Intraspecies Variations of Aroma Compound Production 328

        19.4. Biotic and Abiotic Factors Modulating the Contribution of LAB to Flavor Formation 331

        19.4.1. General Scheme of Flavor Formation in Fermented Foods In Situ 331

        19.4.2. Factors Modulating the Expression of the Flavor-related Activities of LAB 332

        19.4.3. Factors Determining the Real Contribution of LAB to Food Flavor 333

        19.5. Conclusions and Research Perspectives 333

        References 334

        20. Lactic Acid Bacteria Biofilms: From their Formation to their Health and Biotechnological Potential 341
        Jean-Christophe Piard and Romain Briandet

        20.1. Lactic Acid Bacteria Biofilms are Ubiquitous in a Wide Variety of Environments from Nature to
        Domesticated Settings 341

        20.2. Biofilm Life Cycle and Bacterial Factors Involved in LAB Biofilm Lifestyle 346

        20.3. Health and Biotechnological Potential of LAB Biofilms and Underlying Mechanisms 352

        20.4. Conclusions 354

        Acknowledgments 355

        References 355

        Index 362

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