Produktbild: Moonlighting Proteins

Moonlighting Proteins Novel Virulence Factors in Bacterial Infections

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Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

17.04.2017

Herausgeber

Brian Henderson

Verlag

John Wiley & Sons

Seitenzahl

472

Maße (L/B/H)

24,6/17/2,8 cm

Gewicht

1116 g

Sprache

Englisch

ISBN

978-1-118-95111-8

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

17.04.2017

Herausgeber

Brian Henderson

Verlag

John Wiley & Sons

Seitenzahl

472

Maße (L/B/H)

24,6/17/2,8 cm

Gewicht

1116 g

Sprache

Englisch

ISBN

978-1-118-95111-8

Herstelleradresse

Libri GmbH
Europaallee 1
36244 Bad Hersfeld
DE

Email: gpsr@libri.de

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  • Produktbild: Moonlighting Proteins
  • List of Contributors xv

    Preface xix

    About the Editor xxiii

    Part I Overview of Protein Moonlighting 1

    1 What is Protein Moonlighting and Why is it Important? 3
    Constance J. Jeffery

    1.1 What is Protein Moonlighting? 3

    1.2 Why is Moonlighting Important? 5

    1.2.1 Many More Proteins Might Moonlight 5

    1.2.2 Protein Structure/Evolution 5

    1.2.3 Roles in Health and Disease 8

    1.2.3.1 Humans 8

    1.2.3.2 Bacteria 10

    1.3 Current questions 11

    1.3.1 How Many More Proteins Moonlight? 11

    1.3.2 How Can We Identify Additional Proteins That Moonlight and all the Moonlighting Functions of Proteins? 11

    1.3.3 In Developing Novel Therapeutics, How Can We Target the Appropriate Function of a Moonlighting Protein and Not Affect Other Functions of the Protein? 12

    1.3.4 How do Moonlighting Proteins get Targeted to More Than One Location in the Cell? 12

    1.3.5 What Changes in Expression Patterns Have Occurred to Enable the Protein to be Available in a New Time and Place to Perform a New Function? 12

    1.4 Conclusions 13

    References 13

    2 Exploring Structure-Function Relationships in Moonlighting Proteins 21
    Sayoni Das, Ishita Khan, Daisuke Kihara, and Christine Orengo

    2.1 Introduction 21

    2.2 Multiple Facets of Protein Function 22

    2.3 The Protein Structure-Function Paradigm 23

    2.4 Computational Approaches for Identifying Moonlighting Proteins 25

    2.5 Classification of Moonlighting Proteins 26

    2.5.1 Proteins with Distinct Sites for Different Functions in the Same Domain 27

    2.5.1.1 ¿?]Enolase, Streptococcus pneumonia 27

    2.5.1.2 Albaflavenone monooxygenase, Streptomyces coelicolor A3(2) 29

    2.5.1.3 MAPK1/ERK2, Homo sapiens 30

    2.5.2 Proteins with Distinct Sites for Different Functions in More Than One Domain 30

    2.5.2.1 Malate synthase, Mycobacterium tuberculosis 31

    2.5.2.2 BirA, Escherichia coli 31

    2.5.2.3 MRDI, Homo sapiens 33

    2.5.3 Proteins Using the Same Residues for Different Functions 33

    2.5.3.1 GAPDH E. coli 33

    2.5.3.2 Leukotriene A4 hydrolase, Homo sapiens 33

    2.5.4 Proteins Using Different Residues in the Same/Overlapping Site for Different Functions 34

    2.5.4.1 Phosphoglucose isomerase, Oryctolagus cuniculus, Mus musculus, Homo sapiens 34

    2.5.4.2 Aldolase, Plasmodium falciparum 36

    2.5.5 Proteins with Different Structural Conformations for Different Functions 36

    2.5.5.1 RfaH, E. coli 36

    2.6 Conclusions 37

    References 39

    Part II Proteins Moonlighting in Prokarya 45

    3 Overview of Protein Moonlighting in Bacterial Virulence 47
    Brian Henderson

    3.1 Introduction 47

    3.2 The Meaning of Bacterial Virulence and Virulence Factors 47

    3.3 Affinity as a Measure of the Biological Importance of Proteins 49

    3.4 Moonlighting Bacterial Virulence Proteins 50

    3.4.1 Bacterial Proteins Moonlighting as Adhesins 52

    3.4.2 Bacterial Moonlighting Proteins That Act as Invasins 59

    3.4.3 Bacterial Moonlighting Proteins Involved in Nutrient Acquisition 59

    3.4.4 Bacterial Moonlighting Proteins Functioning as Evasins 60

    3.4.5 Bacterial Moonlighting Proteins with Toxin?]like Actions 63

    3.5 Bacterial Moonlighting Proteins Conclusively Shown to be Virulence Factors 64

    3.6 Eukaryotic Moonlighting Proteins That Aid in Bacterial Virulence 66

    3.7 Conclusions 67

    References 68

    4 Moonlighting Proteins as Cross?]Reactive Auto?]Antigens 81
    Willem van Eden

    4.1 Autoimmunity and Conservation 81

    4.2 Immunogenicity of Conserved Proteins 82

    4.3 HSP Co?]induction, Food, Microbiota, and T-cell Regulation 84

    4.3.1 HSP as Targets for T?]Cell Regulation 85

    4.4 The Contribution of Moonlighting Virulence Factors to Immunological Tolerance 87

    References 88

    Part III Proteins Moonlighting in Bacterial Virulence 93

    Part 3.1 Chaperonins: A Family of Proteins with Widespread Virulence Properties 95

    5 Chaperonin 60 Paralogs in Mycobacterium tuberculosis and Tubercle Formation 97
    Brian Henderson

    5.1 Introduction 97

    5.2 Tuberculosis and the Tuberculoid Granuloma 97

    5.3 Mycobacterial Factors Responsible for Granuloma Formation 98

    5.4 Mycobacterium tuberculosis Chaperonin 60 Proteins, Macrophage Function, and Granuloma Formation 100

    5.4.1 Mycobacterium tuberculosis has Two Chaperonin 60 Proteins 100

    5.4.2 Moonlighting Actions of Mycobacterial Chaperonin 60 Proteins 101

    5.4.3 Actions of Mycobacterial Chaperonin 60 Proteins Compatible with the Pathology of Tuberculosis 102

    5.4.4 Identification of the Myeloid?]Cell?]Activating Site in M. tuberculosis Chaperonin 60.1 105

    5.5 Conclusions 106

    References 106

    Legionella pneumophila Chaperonin 60, an Extra?] and Intra?]Cellular Moonlighting Virulence?]Related Factor 111
    Karla N. Valenzuela?]Valderas, Angela L. Riveroll, Peter Robertson, Lois E. Murray, and Rafael A. Garduno

    6.1 Background 111

    6.2 HtpB is an Essential Chaperonin with Protein?]folding Activity 112

    6.3 Experimental Approaches to Elucidate the Functional Mechanisms of HtpB 112

    6.3.1 The Intracellular Signaling Mechanism of HtpB in Yeast 113

    6.3.2 Yeast Two?]Hybrid Screens 118

    6.4 Secretion Mechanisms Potentially Responsible for Transporting HtpB to Extracytoplasmic Locations 120

    6.4.1 Ability of GroEL and HtpB to Associate with Membranes 121

    6.4.2 Ongoing Mechanistic Investigations on Chaperonins Secretion 122

    6.5 Identifying Functionally Important Amino Acid Positions in HtpB 124

    6.5.1 Site?]Directed Mutagenesis 125

    6.6 Functional Evolution of HtpB 126

    6.7 Concluding Remarks 127

    References 129

    Part 3.2 Peptidylprolyl Isomerases, Bacterial Virulence, and Targets for Therapy 135

    7 An Overview of Peptidylprolyl Isomerases (PPIs) in Bacterial Virulence 137
    Brian Henderson

    7.1 Introduction 137

    7.2 Proline and PPIs 137

    7.3 Host PPIs and Responses to Bacteria and Bacterial Toxins 138

    7.4 Bacterial PPIs as Virulence Factors 138

    7.4.1 Proposed Mechanism of Virulence of Legionella pneumophila Mip 140

    7.5 Other Bacterial PPIs Involved in Virulence 140

    7.6 Conclusions 142

    References 142

    Part 3.3 Glyceraldehyde 3?]Phosphate Dehydrogenase (GAPDH): A Multifunctional Virulence Factor 147

    8 GAPDH: A Multifunctional Moonlighting Protein in Eukaryotes and Prokaryotes 149
    Michael A. Sirover

    8.1 Introduction 149

    8.2 GAPDH Membrane Function and Bacterial Virulence 150

    8.2.1 Bacterial GAPDH Virulence 151

    8.2.2 GAPDH and Iron Metabolism in Bacterial Virulence 153

    8.3 Role of Nitric Oxide in GAPDH Bacterial Virulence 153

    8.3.1 Nitric Oxide in Bacterial Virulence: Evasion of the Immune Response 154

    8.3.2 Formation of GAPDH cys NO by Bacterial NO Synthases 155

    8.3.3 GAPDH cys NO in Bacterial Virulence: Induction of Macrophage Apoptosis 155

    8.3.4 GAPDH cys NO in Bacterial Virulence: Inhibition of Macrophage iNOS Activity 156

    8.3.5 GAPDH cys NO in Bacterial Virulence: Transnitrosylation to Acceptor Proteins 157

    8.4 GAPDH Control of Gene Expression and Bacterial Virulence 158

    8.4.1 Bacterial GAPDH Virulence 159

    8.5 Discussion 160

    Acknowledgements 162

    References 162

    Streptococcus pyogenes GAPDH: A Cell?]Surface Major Virulence Determinant 169
    Vijay Pancholi

    9.1 Introduction and Early Discovery 169

    9.2 GAS GAPDH: A Major Surface Protein with Multiple Binding Activities 170

    9.3 AutoADP?]Ribosylation of SDH and Other Post?]Translational Modifications 172

    9.4 Implications of the Binding of SDH to Mammalian Proteins for Cell Signaling and Virulence Mechanisms 173

    9.5 Surface Export of SDH/GAPDH: A Cause or Effect? 178

    9.6 SDH: The GAS Virulence Factor?]Regulating Virulence Factor 180

    9.7 Concluding Remarks and Future Perspectives 183

    References 183

    10 Group B Streptococcus GAPDH and Immune Evasion 195
    Paula Ferreira and Patrick Trieu?]Cuot

    10.1 The Bacterium GBS 195

    10.2 Neonates are More Susceptible to GBS Infection than Adults 195

    10.3 IL?]10 Production Facilitates Bacterial Infection 196

    10.4 GBS Glyceraldehyde?]3?]Phosphate Dehydrogenase Induces IL?]10 Production 197

    10.5 Summary 199

    References 200

    11 Mycobacterium tuberculosis Cell?]Surface GAPDH Functions as a Transferrin Receptor 205
    Vishant M. Boradia, Manoj Raje, and Chaaya Iyengar Raje

    11.1 Introduction 205

    11.2 Iron Acquisition by Bacteria 206

    11.2.1 Heme Uptake 206

    11.2.2 Siderophore?]Mediated Uptake 207

    11.2.3 Transferrin Iron Acquisition 207

    11.3 Iron Acquisition by Intracellular Pathogens 207

    11.4 Iron Acquisition by M. tb 208

    11.4.1 Heme Uptake 208

    11.4.2 Siderophore?]Mediated Iron Acquisition 209

    11.4.3 Transferrin?]Mediated Iron Acquisition 209

    11.5 Glyceraldehyde?]3?]Phosphate Dehydrogenase (GAPDH) 210

    11.6 Macrophage GAPDH and Iron Uptake 210

    11.6.1 Regulation 210

    11.6.2 Mechanism of Iron Uptake and Efflux 211

    11.6.3 Role of Post?]Translational Modifications 211

    11.7 Mycobacterial GAPDH and Iron Uptake 212

    11.7.1 Regulation 212

    11.7.2 Mechanism of Iron Uptake 215

    11.7.3 Uptake by Intraphagosomal M. tb 216

    11.8 Conclusions and Future Perspectives 216

    Acknowledgements 218

    References 219

    12 GAPDH and Probiotic Organisms 225
    Hideki Kinoshita

    12.1 Introduction 225

    12.2 Probiotics and Safety 225

    12.3 Potential Risk of Probiotics 227

    12.4 Plasminogen Binding and Enhancement of its Activation 228

    12.5 GAPDH as an Adhesin 229

    12.6 Binding Regions 232

    12.7 Mechanisms of Secretion and Surface Localization 234

    12.8 Other Functions 235

    12.9 Conclusion 236

    References 237

    Part 3.4 Cell?]Surface Enolase: A Complex Virulence Factor 245

    13 Impact of Streptococcal Enolase in Virulence 247
    Marcus Fulde and Simone Bergmann

    13.1 Introduction 247

    13.2 General Characteristics 248

    13.3 Expression and Surface Exposition of Enolase 249

    13.4 Streptococcal Enolase as Adhesion Cofactor 252

    13.4.1 Enolase as Plasminogen?]Binding Protein 252

    13.4.1.1 Plasminogen?]Binding Sites of Streptococcal Enolases 253

    13.4.2 Role of Enolase in Plasminogen?]Mediated Bacterial?]Host Cell Adhesion and Internalization 254

    13.4.3 Enolase as Plasminogen?]Binding Protein in Non?]Pathogenic Bacteria 255

    13.5 Enolase as Pro?]Fibrinolytic Cofactor 256

    13.5.1 Degradation of Fibrin Thrombi and Components of the Extracellular Matrix 257

    13.6 Streptococcal Enolase as Cariogenic Factor in Dental Disease 258

    13.7 Conclusion 258

    Acknowledgement 259

    References 259

    14 Streptococcal Enolase and Immune Evasion 269
    Masaya Yamaguchi and Shigetada Kawabata

    14.1 Introduction 269

    14.2 Localization and Crystal Structure 271

    14.3 Multiple Binding Activities of ¿?]Enolase 273

    14.4 Involvement of ¿?]Enolase in Gene Expression Regulation 276

    14.5 Role of Anti?]¿?]Enolase Antibodies in Host Immunity 277

    14.6 ¿?]Enolase as Potential Therapeutic Target 279

    14.7 Questions Concerning ¿?]Enolase 281

    References 281

    15 Borrelia burgdorferi Enolase and Plasminogen Binding 291
    Catherine A. Brissette

    15.1 Introduction to Lyme Disease 291

    15.2 Life Cycle 292

    15.3 Borrelia Virulence Factors 292

    15.4 Plasminogen Binding by Bacteria 293

    15.5 B. burgdorferi and Plasminogen Binding 294

    15.6 Enolase 295

    15.7 B. burgdorferi Enolase and Plasminogen Binding 297

    15.8 Concluding Thoughts 301

    Acknowledgements 301

    References 301

    Part 3.5 Other Glycolytic Enzymes Acting as Virulence Factors 309

    16 Triosephosphate Isomerase from Staphylococcus aureus and Plasminogen Receptors on Microbial Pathogens 311
    Reiko Ikeda and Tomoe Ichikawa

    16.1 Introduction 311

    16.2 Identification of Triosephosphate Isomerase on S. aureus

    as a Molecule that Binds to the Pathogenic Yeast C. neoformans 312

    16.2.1 Co?]Cultivation of S. aureus and C. neoformans 312

    16.2.2 Identification of Adhesins on S. aureus and C. neoformans 312

    16.2.3 Mechanisms of C. neoformans Cell Death 313

    16.3 Binding of Triosephosphate Isomerase with Human Plasminogen 314

    16.4 Plasminogen?]Binding Proteins on Trichosporon asahii 314

    16.5 Plasminogen Receptors on C. neoformans 316

    16.6 Conclusions 316

    References 317

    17 Moonlighting Functions of Bacterial Fructose 1,6?]Bisphosphate Aldolases 321
    Neil J. Oldfield, Fariza Shams, Karl G. Wooldridge, and David P.J. Turner

    17.1 Introduction 321

    17.2 Fructose 1,6?]bisphosphate Aldolase in Metabolism 321

    17.3 Surface Localization of Streptococcal Fructose 1,6?]bisphosphate Aldolases 322

    17.4 Pneumococcal FBA Adhesin Binds Flamingo Cadherin Receptor 323

    17.5 FBA is Required for Optimal Meningococcal Adhesion to Human Cells 324

    17.6 Mycobacterium tuberculosis FBA Binds Human Plasminogen 325

    17.7 Other Examples of FBAs with Possible Roles in Pathogenesis 326

    17.8 Conclusions 327

    References 327

    Part 3.6 Other Metabolic Enzymes Functioning in Bacterial Virulence 333

    18 Pyruvate Dehydrogenase Subunit B and Plasminogen Binding in Mycoplasma 335
    Anne Gründel, Kathleen Friedrich, Melanie Pfeiffer, Enno Jacobs, and Roger Dumke

    18.1 Introduction 335

    18.2 Binding of Human Plasminogen to M. pneumoniae 337

    18.3 Localization of PDHB on the Surface of M. pneumoniae Cells 340

    18.4 Conclusions 343

    References 344

    Part 3.7 Miscellaneous Bacterial Moonlighting Virulence Proteins 349

    19 Unexpected Interactions of Leptospiral Ef?]Tu and Enolase 351
    Natália Salazar and Angela Barbosa

    19.1 Leptospira -Host Interactions 351

    19.2 Leptospira Ef?]Tu 352

    19.3 Leptospira Enolase 353

    19.4 Conclusions 354

    References 354

    20 Mycobacterium tuberculosis Antigen 85 Family Proteins: Mycolyl Transferases and Matrix?]Binding Adhesins 357
    Christopher P. Ptak, Chih?]Jung Kuo, and Yung?]Fu Chang

    20.1 Introduction 357

    20.2 Identification of Antigen 85 358

    20.3 Antigen 85 Family Proteins: Mycolyl Transferases 359

    20.3.1 Role of the Mycomembrane 359

    20.3.2 Ag85 Family of Homologous Proteins 359

    20.3.3 Inhibition and Knockouts of Ag85 360

    20.4 Antigen 85 Family Proteins: Matrix?]Binding Adhesins 361

    20.4.1 Abundance and Location 361

    20.4.2 Ag85 a Fibronectin?]Binding Adhesin 362

    20.4.3 Ag85 an Elastin?]Binding Adhesin 363

    20.4.4 Implication in Disease 364

    20.5 Conclusion 365

    Acknowledgement 365

    References 365

    Part 3.8 Bacterial Moonlighting Proteins that Function as Cytokine Binders/Receptors 371

    21 Miscellaneous IL?]1ß?]Binding Proteins of Aggregatibacter actinomycetemcomitans 373
    Riikka Ihalin

    21.1 Introduction 373

    21.2 A. actinomycetemcomitans Biofilms Sequester IL?]1ß 374

    21.3 A. actinomycetemcomitans Cells Take in IL?]1ß 375

    21.3.1 Novel Outer Membrane Lipoprotein of A. actinomycetemcomitans Binds IL?]1ß 375

    21.3.2 IL?]1ß Localizes to the Cytosolic Face of the Inner Membrane and in the Nucleoids of A. actinomycetemcomitans 377

    21.3.3 Inner Membrane Protein ATP Synthase Subunit ß Binds IL?]1ß 377

    21.3.4 DNA?]Binding Histone?]Like Protein HU Interacts with IL?]1ß 378

    21.4 The Potential Effects of IL?]1ß on A. actinomycetemcomitans 379

    21.4.1 Biofilm Amount Increases and Metabolic Activity Decreases 379

    21.4.2 Potential Changes in Gene Expression 380

    21.5 Conclusions 381

    References 382

    Part 3.9 Moonlighting Outside of the Box 387

    22 Bacteriophage Moonlighting Proteins in the Control of Bacterial Pathogenicity 389
    Janine Z. Bowring, Alberto Marina, José R. Penadés, and Nuria Quiles?]Puchalt

    22.1 Introduction 389

    22.2 Bacteriophage T4 I?]TevI Homing Endonuclease Functions as a Transcriptional Autorepressor 391

    22.3 Capsid Psu Protein of Bacteriophage P4 Functions as a Rho Transcription Antiterminator 394

    22.4 Bacteriophage Lytic Enzymes Moonlight as Structural Proteins 398

    22.5 Moonlighting Bacteriophage Proteins De?]Repressing Phage?]Inducible Chromosomal Islands 398

    22.6 dUTPase, a Metabolic Enzyme with a Moonlighting Signalling Role 401

    22.7 Escherichia coli Thioredoxin Protein Moonlights with T7 DNA Polymerase for Enhanced T7 DNA Replication 404

    22.8 Discussion 404

    References 406

    23 Viral Entry Glycoproteins and Viral Immune Evasion 413
    Jonathan D. Cook and Jeffrey E. Lee

    23.1 Introduction 413

    23.2 Enveloped Viral Entry 414

    23.3 Moonlighting Activities of Viral Entry Glycoproteins 415

    23.3.1 Viral Entry Glycoproteins Moonlighting as Evasins 416

    23.3.2 Evading the Complement System 417

    23.3.3 Evading Antibody Surveillance 419

    23.3.3.1 The Viral Glycan Shield 419

    23.3.3.2 Shed Viral Glycoproteins: An Antibody Decoy 421

    23.3.3.3 Antigenic Variations in Viral Glycoproteins 421

    23.3.3.4 Shed Viral Glycoproteins and Immune Signal Modulation 423

    23.3.4 Evading Host Restriction Factors 423

    23.3.5 Modulation of Other Immune Pathways 424

    23.4 Viral Entry Proteins Moonlighting as Saboteurs of Cellular Pathways 427

    23.4.1 Sabotaging Signal Transduction Cascades 427

    23.4.2 Host Surface Protein Sabotage 428

    23.5 Conclusions 429

    References 429

    Index 439