Kooperativer Bibliotheksverbund

UID:

Umfang: 1 online resource (xiii, 300 pages) : , illustrations (chiefly color).

Ausgabe: First edition.

ISBN: 9780429277375 , 0429277377 , 9781000090062 , 100009006X , 9781000090277 , 1000090272 , 9781000090482 , 1000090485

Serie: Evolutionary cell biology

Inhalt: "This book examines how the growing knowledge of the huge range of animal- and plant- bacterial interactions, whether in shared ecosystems or intimate symbioses, is fundamentally altering our understanding of biology. The establishment and maintenance of these interactions and their contributions to the health and survival of all partners relies on continuous cell-to-cell communication between them. This dialogue may be concerned with all aspects of the biology of both partners. The book includes chapters devoted to exploring, explaining and exposing these dialogues across a broad spectrum of plant and animal eukaryotes to a broad field of biologists"--

Weitere Ausg.: Print version: Cellular dialogues in the holobiont Boca Raton : CRC Press, 2020. ISBN 9780367228811

Sprache: Englisch

Schlagwort(e): Electronic books.

DOI: 10.1201/9780429277375

URL: https://www.taylorfrancis.com/books/9780429277375

URL: kostenfrei

UID:

Umfang: 1 online resource (315 pages)

ISBN: 9781000090062

Serie: Evolutionary Cell Biology Ser.

Inhalt: Cover -- Half Title -- Series Page -- Title Page -- Copyright Page -- Contents -- Series Preface -- Preface -- Contributors -- Chapter 1: When does symbiosis begin? Bacterial cues necessary for metamorphosis in the marine polychaete Hydroides elegans -- 1.1 The symbiosis space -- 1.2 Chemical cues mediate symbiotic interactions -- 1.3 How do specific symbiotic interactions begin? Examples from the pre-symbiosis space -- 1.4 Bacterially induced metamorphosis of marine invertebrate animals -- 1.5 Bacterial induction of metamorphosis in Hydroides elegans -- 1.6 Identification of larval metamorphic cues from biofilm bacteria -- 1.7 How variability of inductive bacteria and identified settlement cues relate to variable larval settlement and recruitment -- 1.8 Lipopolysaccharide mediates both symbiotic and pre-symbiotic interactions -- 1.9 Conclusion -- References -- Chapter 2: The language of symbiosis: Insights from protist biology -- 2.1 Introduction -- 2.2 Cytoplasm as microcosm -- 2.3 Eukaryotes inside eukaryotes (inside other eukaryotes) -- 2.4 Ectosymbiosis: It's a jungle out there -- 2.5 Microbial symbioses: Power struggles in time and space -- 2.6 Conclusion -- Acknowledgments -- References -- Chapter 3: Trichoplax and its bacteria: How many are there? Are they speaking? -- 3.1 Introduction -- 3.2 How many symbionts are known to be present and where do they occur? -- 3.3 Do all placozoans harbor both G. incantans and R. eludens? -- 3.4 Intracellular locations of the placozoan symbionts -- 3.5 Unusual mitochondria in placozoan fiber cells and their possible relationship to symbiosis -- 3.6 Molecular inferences on the nature of the Trichoplax-bacteria symbioses -- 3.7 How are the bacterial symbionts of placozoans transmitted between generations? -- 3.8 Some big questions remaining and suggestions for their resolution -- Acknowledgments.

Anmerkung: Description based on publisher supplied metadata and other sources

Weitere Ausg.: ISBN 9780367228811

Weitere Ausg.: Erscheint auch als Druck-Ausgabe ISBN 9780367228811

Sprache: Englisch

URL: lizenzpflichtig

UID:

Umfang: 1 online resource (xiii, 300 pages).

ISBN: 9781000090062 (e-book)

Serie: Evolutionary cell biology

Anmerkung: Includes index.

Weitere Ausg.: Print version: Cellular dialogues in the holobiont. Boca Raton, Florida ; London ; New York : CRC Press, c2021 ISBN 9780367228811

Sprache: Englisch

Schlagwort(e): Electronic books.

URL: Click to View

UID:

Umfang: 1 Online-Ressource (315 p.)

ISBN: 9780429277375 , 9780367228811 , 9780367513757

Serie: Evolutionary Cell Biology

Inhalt: This book examines how the growing knowledge of the huge range of protist-, animal-, and plant-bacterial interactions, whether in shared ecosystems or intimate symbioses, is fundamentally altering our understanding of biology. The establishment and maintenance of these interactions and their contributions to the health and survival of all partners relies on continuous cell-to-cell communication between them. This dialogue may be concerned with all aspects of the biology of both partners. The book includes chapters devoted to exploring, explaining, and exposing these dialogues across a broad spectrum of plant and animal eukaryotes to a broad field of biologists. Key Features Explores the nature of the interactions between eukaryotic hosts and their microbial symbionts Examines the links between prostist, animal, and plant evolution and microbial communities Reviews specific taxa and the microbial diversity associated with these taxa Illustrates the role microbes play in the physiology and etiology of several model species Includes chapters by an international team of leading scholars

Anmerkung: English

Sprache: Unbestimmte Sprache

URL: kostenfrei

UID:

Umfang: 1 online resource (xiii, 300 pages).

Ausgabe: 1st ed.

ISBN: 0-429-27737-7 , 1-000-09006-X

Serie: Evolutionary cell biology

Anmerkung: Includes index. , Cover -- Half Title -- Series Page -- Title Page -- Copyright Page -- Contents -- Series Preface -- Preface -- Contributors -- Chapter 1: When does symbiosis begin? Bacterial cues necessary for metamorphosis in the marine polychaete Hydroides elegans -- 1.1 The symbiosis space -- 1.2 Chemical cues mediate symbiotic interactions -- 1.3 How do specific symbiotic interactions begin? Examples from the pre-symbiosis space -- 1.4 Bacterially induced metamorphosis of marine invertebrate animals -- 1.5 Bacterial induction of metamorphosis in Hydroides elegans -- 1.6 Identification of larval metamorphic cues from biofilm bacteria -- 1.7 How variability of inductive bacteria and identified settlement cues relate to variable larval settlement and recruitment -- 1.8 Lipopolysaccharide mediates both symbiotic and pre-symbiotic interactions -- 1.9 Conclusion -- References -- Chapter 2: The language of symbiosis: Insights from protist biology -- 2.1 Introduction -- 2.2 Cytoplasm as microcosm -- 2.3 Eukaryotes inside eukaryotes (inside other eukaryotes) -- 2.4 Ectosymbiosis: It's a jungle out there -- 2.5 Microbial symbioses: Power struggles in time and space -- 2.6 Conclusion -- Acknowledgments -- References -- Chapter 3: Trichoplax and its bacteria: How many are there? Are they speaking? -- 3.1 Introduction -- 3.2 How many symbionts are known to be present and where do they occur? -- 3.3 Do all placozoans harbor both G. incantans and R. eludens? -- 3.4 Intracellular locations of the placozoan symbionts -- 3.5 Unusual mitochondria in placozoan fiber cells and their possible relationship to symbiosis -- 3.6 Molecular inferences on the nature of the Trichoplax-bacteria symbioses -- 3.7 How are the bacterial symbionts of placozoans transmitted between generations? -- 3.8 Some big questions remaining and suggestions for their resolution -- Acknowledgments. , References -- Chapter 4: Decoding cellular dialogues between sponges, bacteria, and phages -- 4.1 Introduction -- 4.2 Host-bacteria dialogue -- 4.2.1 Sponge immune receptors -- 4.2.2 Microbe associated molecular patterns (MAMPs) -- 4.3 Bacteria-bacteria dialogue -- 4.3.1 Quorum sensing -- 4.3.2 Quorum quenching -- 4.4 Phage-bacteria-host dialogue -- 4.4.1 Phage diversity and host-specificity -- 4.4.2 Ankyphages aid symbionts in immune evasion -- 4.5 Conclusions and future perspectives -- Acknowledgments -- References -- Chapter 5: Symbiotic interactions in the holobiont Hydra -- 5.1 Introduction -- 5.2 Interactions between Hydra viridissima and the Chlorella photobiont -- 5.2.1 Location and transmission of the photobiont -- 5.2.2 Mutual benefits -- 5.2.3 Establishment and maintenance of the Chlorella-Hydra symbiosis -- 5.2.4 Molecular mechanisms involved in maintaining the symbiosis -- 5.3 Interactions between Hydra and symbiotic bacteria -- 5.3.1 Spatial localization of the bacteria in the Hydra host -- 5.3.2 Bacteria provide protection against fungal infection -- 5.3.3 The innate immune system shapes the host microbiome -- 5.3.4 Crosstalk between innate immunity and stem cell factors -- 5.3.5 Crosstalk between the microbiota and the nervous system -- 5.3.6 Effect of bacteria on host physiology -- 5.4 Conclusion: Hydra, an excellent model to understand inter-species interactions -- Acknowledgments -- References -- Chapter 6: Hydra and Curvibacter: An intimate crosstalk at the epithelial interface -- 6.1 Introduction -- 6.2 Hydra and Curvibacter: The ideal duo to understand inter-kingdom communications -- 6.3 Spatial localization and transmission of Curvibacter -- 6.4 Establishment and carrying capacity of Curvibacter colonization -- 6.5 Curvibacter function in the Hydra metaorganism -- 6.6 Inter-kingdom communication between Hydra and Curvibacter. , 6.7 Outlook -- Acknowledgments -- References -- Chapter 7: The coral holobiont highlights the dependence of cnidarian animal hosts on their associated microbes -- 7.1 Introduction: The coral holobiont as an ecosystem engineer and its reliance on associated microbes -- 7.2 The coral-Symbiodiniaceae relationship -- 7.2.1 Symbiodiniaceae: Micro-algal engines of the coral holobiont machinery -- 7.2.2 Innate immunity, symbiosis sensing, and cell signaling -- 7.2.3 Coral bleaching: The breakdown of the coral-Symbiodiniaceae relationship -- 7.3 Symbiodiniaceae-bacteria relationships -- 7.4 Diversity and function of microbes associated with the coral host -- 7.4.1 The host as a habitat -- 7.4.2 Diversity of coral-associated bacteria and interspecies interactions -- 7.4.3 Acquisition of bacterial associates and their roles in early coral life-stages -- 7.4.4 Coral probiotics -- 7.4.5 Contribution of bacteria to holobiont nutrient cycling -- 7.4.6 Archaea associated with the coral holobiont -- 7.4.7 Protists and fungi associated with the coral holobiont -- 7.5 Summary and Outlook -- References -- Chapter 8: Extra-intestinal regulation of the gut microbiome: The case of C. elegans TGFß/SMA signaling -- 8.1 Introduction: Caenorhabditis elegans as a model for studying the holobiont -- 8.2 The C. elegans gut microbiome and the factors that shape it -- 8.3 The intestinal niche -- 8.4 Host immunity and its role in shaping the intestinal niche -- 8.5 Multitissue contributions of TGFß signaling control anterior gut commensal abundance and function -- 8.6 TGFß signaling and cell nonautonomous regulation of intestinal function -- 8.7 Conclusions and future prospects: Convergence with other systems of host-symbiont interactions -- Acknowledgments -- References -- Chapter 9: Multiple roles of bacterially produced natural products in the bryozoan Bugula neritina. , 9.1 Introduction -- 9.2 Bryozoans, Bugula spp., and Bugula neritina -- 9.3 Bryostatins -- 9.4 Bryostatin production by the bacterial symbiont of B. neritina -- 9.5 Defensive role of bryostatins -- 9.6 Impacts of symbiont and symbiont-produced metabolites on host physiology -- 9.7 Bryostatins and symbionts in closely related genera -- 9.8 Future directions -- Acknowledgments -- References -- Chapter 10: The molecular dialogue through ontogeny between a squid host and its luminous symbiont -- 10.1 Introduction -- 10.2 Features of the Euprymna scolopes-Vibrio fischeri association as a model symbiosis -- 10.3 Host activities before symbiont colonization: Embryogenesis and early posthatching -- 10.4 Early posthatching activity that mediates species and strain specificity of the association -- 10.5 Colonization and early development -- 10.6 The basis of a stable symbiosis: Daily rhythms and maturation of the symbiotic organ -- 10.7 Conclusions -- Acknowledgments -- References -- Chapter 11: Evolving integrated multipartite symbioses between plant-sap feeding insects (Hemiptera) and their endosymbionts -- 11.1 Introduction -- 11.2 Roles of Hemipteran symbionts: Nutrition and beyond -- 11.3 Genome evolution in Hemipteran symbionts -- 11.4 Symbiont bearing organs: Transmission and development -- 11.4.1 Intracellular symbioses: Transovarial transmission and bacteriome development -- 11.4.2 Extracellular symbioses: External transmission and the midgut -- 11.5 Maintaining and regulating microbial symbionts -- 11.5.1 Evolution of mechanisms to maintain and regulate symbionts -- 11.5.2 Symbiont self-help and self-regulation -- 11.5.3 Symbiont-symbiont support -- 11.5.4 Host support and regulation of nutritional synthesis in symbionts -- 11.5.5 Host support and regulation of other symbiont cell functions -- 11.6 Conclusion -- References. , Chapter 12: Symbiosis for insect cuticle formation -- 12.1 Introduction -- 12.2 Weevil-Nardonella endosymbiosis -- 12.3 Nardonella genome is extremely reduced and specialized for tyrosine synthesis -- 12.4 Nardonella endosymbiotic system in Pachyrhynchus infernalis -- 12.5 Nardonella-harboring bacteriome as a tyrosine-producing organ -- 12.6 Suppression of Nardonella by antibiotic and its effects on tyrosine and DOPA provisioning -- 12.7 Contribution of Nardonella to adult cuticle formation in Pachyrhynchus infernalis -- 12.8 Incomplete tyrosine synthesis pathway of Nardonella and complementation by host genes -- 12.9 Insights from weevil-Nardonella symbiosis: Host's final step control over symbiont's metabolic pathway -- 12.10 Insights from weevil-Nardonella symbiosis: How do symbiont replacements proceed? -- 12.11 Symbiosis for insect cuticle formation: General phenomena across diverse insect taxa -- 12.12 Conclusion and perspective -- Acknowledgments -- References -- Chapter 13: Microbial determinants of folivory in insects -- 13.1 Introduction -- 13.2 Deconstructing the plant cell wall -- 13.3 Symbiont-mediated evasion of plant defenses -- 13.4 Niche preservation -- 13.5 Conclusions -- References -- Chapter 14: Right on cue: Microbiota promote plasticity of zebrafish digestive tract -- 14.1 Introduction -- 14.2 Development under immune surveillance -- 14.3 Developmental plasticity at the luminal interface -- 14.4 Beyond the lumen: A secreted bacterial protein impacts pancreas development -- 14.5 Conclusions -- References -- Chapter 15: Uncovering the history of intestinal host-microbiome interactions through vertebrate comparative genomics -- 15.1 Introduction -- 15.2 A history of symbiotic interactions captured within microbial and host genomes -- 15.3 Capturing symbiotic signals within coding regions of the host genome. , 15.4 Uncovering specific symbiotic signals in host transcriptional programs.

Weitere Ausg.: ISBN 0-367-51375-7

Weitere Ausg.: ISBN 0-367-22881-5

Sprache: Englisch

UID:

Umfang: 1 online resource (xiii, 300 pages).

Ausgabe: 1st ed.

ISBN: 0-429-27737-7 , 1-000-09006-X

Serie: Evolutionary cell biology

Anmerkung: Includes index. , Cover -- Half Title -- Series Page -- Title Page -- Copyright Page -- Contents -- Series Preface -- Preface -- Contributors -- Chapter 1: When does symbiosis begin? Bacterial cues necessary for metamorphosis in the marine polychaete Hydroides elegans -- 1.1 The symbiosis space -- 1.2 Chemical cues mediate symbiotic interactions -- 1.3 How do specific symbiotic interactions begin? Examples from the pre-symbiosis space -- 1.4 Bacterially induced metamorphosis of marine invertebrate animals -- 1.5 Bacterial induction of metamorphosis in Hydroides elegans -- 1.6 Identification of larval metamorphic cues from biofilm bacteria -- 1.7 How variability of inductive bacteria and identified settlement cues relate to variable larval settlement and recruitment -- 1.8 Lipopolysaccharide mediates both symbiotic and pre-symbiotic interactions -- 1.9 Conclusion -- References -- Chapter 2: The language of symbiosis: Insights from protist biology -- 2.1 Introduction -- 2.2 Cytoplasm as microcosm -- 2.3 Eukaryotes inside eukaryotes (inside other eukaryotes) -- 2.4 Ectosymbiosis: It's a jungle out there -- 2.5 Microbial symbioses: Power struggles in time and space -- 2.6 Conclusion -- Acknowledgments -- References -- Chapter 3: Trichoplax and its bacteria: How many are there? Are they speaking? -- 3.1 Introduction -- 3.2 How many symbionts are known to be present and where do they occur? -- 3.3 Do all placozoans harbor both G. incantans and R. eludens? -- 3.4 Intracellular locations of the placozoan symbionts -- 3.5 Unusual mitochondria in placozoan fiber cells and their possible relationship to symbiosis -- 3.6 Molecular inferences on the nature of the Trichoplax-bacteria symbioses -- 3.7 How are the bacterial symbionts of placozoans transmitted between generations? -- 3.8 Some big questions remaining and suggestions for their resolution -- Acknowledgments. , References -- Chapter 4: Decoding cellular dialogues between sponges, bacteria, and phages -- 4.1 Introduction -- 4.2 Host-bacteria dialogue -- 4.2.1 Sponge immune receptors -- 4.2.2 Microbe associated molecular patterns (MAMPs) -- 4.3 Bacteria-bacteria dialogue -- 4.3.1 Quorum sensing -- 4.3.2 Quorum quenching -- 4.4 Phage-bacteria-host dialogue -- 4.4.1 Phage diversity and host-specificity -- 4.4.2 Ankyphages aid symbionts in immune evasion -- 4.5 Conclusions and future perspectives -- Acknowledgments -- References -- Chapter 5: Symbiotic interactions in the holobiont Hydra -- 5.1 Introduction -- 5.2 Interactions between Hydra viridissima and the Chlorella photobiont -- 5.2.1 Location and transmission of the photobiont -- 5.2.2 Mutual benefits -- 5.2.3 Establishment and maintenance of the Chlorella-Hydra symbiosis -- 5.2.4 Molecular mechanisms involved in maintaining the symbiosis -- 5.3 Interactions between Hydra and symbiotic bacteria -- 5.3.1 Spatial localization of the bacteria in the Hydra host -- 5.3.2 Bacteria provide protection against fungal infection -- 5.3.3 The innate immune system shapes the host microbiome -- 5.3.4 Crosstalk between innate immunity and stem cell factors -- 5.3.5 Crosstalk between the microbiota and the nervous system -- 5.3.6 Effect of bacteria on host physiology -- 5.4 Conclusion: Hydra, an excellent model to understand inter-species interactions -- Acknowledgments -- References -- Chapter 6: Hydra and Curvibacter: An intimate crosstalk at the epithelial interface -- 6.1 Introduction -- 6.2 Hydra and Curvibacter: The ideal duo to understand inter-kingdom communications -- 6.3 Spatial localization and transmission of Curvibacter -- 6.4 Establishment and carrying capacity of Curvibacter colonization -- 6.5 Curvibacter function in the Hydra metaorganism -- 6.6 Inter-kingdom communication between Hydra and Curvibacter. , 6.7 Outlook -- Acknowledgments -- References -- Chapter 7: The coral holobiont highlights the dependence of cnidarian animal hosts on their associated microbes -- 7.1 Introduction: The coral holobiont as an ecosystem engineer and its reliance on associated microbes -- 7.2 The coral-Symbiodiniaceae relationship -- 7.2.1 Symbiodiniaceae: Micro-algal engines of the coral holobiont machinery -- 7.2.2 Innate immunity, symbiosis sensing, and cell signaling -- 7.2.3 Coral bleaching: The breakdown of the coral-Symbiodiniaceae relationship -- 7.3 Symbiodiniaceae-bacteria relationships -- 7.4 Diversity and function of microbes associated with the coral host -- 7.4.1 The host as a habitat -- 7.4.2 Diversity of coral-associated bacteria and interspecies interactions -- 7.4.3 Acquisition of bacterial associates and their roles in early coral life-stages -- 7.4.4 Coral probiotics -- 7.4.5 Contribution of bacteria to holobiont nutrient cycling -- 7.4.6 Archaea associated with the coral holobiont -- 7.4.7 Protists and fungi associated with the coral holobiont -- 7.5 Summary and Outlook -- References -- Chapter 8: Extra-intestinal regulation of the gut microbiome: The case of C. elegans TGFß/SMA signaling -- 8.1 Introduction: Caenorhabditis elegans as a model for studying the holobiont -- 8.2 The C. elegans gut microbiome and the factors that shape it -- 8.3 The intestinal niche -- 8.4 Host immunity and its role in shaping the intestinal niche -- 8.5 Multitissue contributions of TGFß signaling control anterior gut commensal abundance and function -- 8.6 TGFß signaling and cell nonautonomous regulation of intestinal function -- 8.7 Conclusions and future prospects: Convergence with other systems of host-symbiont interactions -- Acknowledgments -- References -- Chapter 9: Multiple roles of bacterially produced natural products in the bryozoan Bugula neritina. , 9.1 Introduction -- 9.2 Bryozoans, Bugula spp., and Bugula neritina -- 9.3 Bryostatins -- 9.4 Bryostatin production by the bacterial symbiont of B. neritina -- 9.5 Defensive role of bryostatins -- 9.6 Impacts of symbiont and symbiont-produced metabolites on host physiology -- 9.7 Bryostatins and symbionts in closely related genera -- 9.8 Future directions -- Acknowledgments -- References -- Chapter 10: The molecular dialogue through ontogeny between a squid host and its luminous symbiont -- 10.1 Introduction -- 10.2 Features of the Euprymna scolopes-Vibrio fischeri association as a model symbiosis -- 10.3 Host activities before symbiont colonization: Embryogenesis and early posthatching -- 10.4 Early posthatching activity that mediates species and strain specificity of the association -- 10.5 Colonization and early development -- 10.6 The basis of a stable symbiosis: Daily rhythms and maturation of the symbiotic organ -- 10.7 Conclusions -- Acknowledgments -- References -- Chapter 11: Evolving integrated multipartite symbioses between plant-sap feeding insects (Hemiptera) and their endosymbionts -- 11.1 Introduction -- 11.2 Roles of Hemipteran symbionts: Nutrition and beyond -- 11.3 Genome evolution in Hemipteran symbionts -- 11.4 Symbiont bearing organs: Transmission and development -- 11.4.1 Intracellular symbioses: Transovarial transmission and bacteriome development -- 11.4.2 Extracellular symbioses: External transmission and the midgut -- 11.5 Maintaining and regulating microbial symbionts -- 11.5.1 Evolution of mechanisms to maintain and regulate symbionts -- 11.5.2 Symbiont self-help and self-regulation -- 11.5.3 Symbiont-symbiont support -- 11.5.4 Host support and regulation of nutritional synthesis in symbionts -- 11.5.5 Host support and regulation of other symbiont cell functions -- 11.6 Conclusion -- References. , Chapter 12: Symbiosis for insect cuticle formation -- 12.1 Introduction -- 12.2 Weevil-Nardonella endosymbiosis -- 12.3 Nardonella genome is extremely reduced and specialized for tyrosine synthesis -- 12.4 Nardonella endosymbiotic system in Pachyrhynchus infernalis -- 12.5 Nardonella-harboring bacteriome as a tyrosine-producing organ -- 12.6 Suppression of Nardonella by antibiotic and its effects on tyrosine and DOPA provisioning -- 12.7 Contribution of Nardonella to adult cuticle formation in Pachyrhynchus infernalis -- 12.8 Incomplete tyrosine synthesis pathway of Nardonella and complementation by host genes -- 12.9 Insights from weevil-Nardonella symbiosis: Host's final step control over symbiont's metabolic pathway -- 12.10 Insights from weevil-Nardonella symbiosis: How do symbiont replacements proceed? -- 12.11 Symbiosis for insect cuticle formation: General phenomena across diverse insect taxa -- 12.12 Conclusion and perspective -- Acknowledgments -- References -- Chapter 13: Microbial determinants of folivory in insects -- 13.1 Introduction -- 13.2 Deconstructing the plant cell wall -- 13.3 Symbiont-mediated evasion of plant defenses -- 13.4 Niche preservation -- 13.5 Conclusions -- References -- Chapter 14: Right on cue: Microbiota promote plasticity of zebrafish digestive tract -- 14.1 Introduction -- 14.2 Development under immune surveillance -- 14.3 Developmental plasticity at the luminal interface -- 14.4 Beyond the lumen: A secreted bacterial protein impacts pancreas development -- 14.5 Conclusions -- References -- Chapter 15: Uncovering the history of intestinal host-microbiome interactions through vertebrate comparative genomics -- 15.1 Introduction -- 15.2 A history of symbiotic interactions captured within microbial and host genomes -- 15.3 Capturing symbiotic signals within coding regions of the host genome. , 15.4 Uncovering specific symbiotic signals in host transcriptional programs.

Weitere Ausg.: ISBN 0-367-51375-7

Weitere Ausg.: ISBN 0-367-22881-5

Sprache: Englisch

UID:

Umfang: 1 online resource (xiii, 300 pages).

Ausgabe: 1st ed.

ISBN: 0-429-27737-7 , 1-000-09006-X

Serie: Evolutionary cell biology

Anmerkung: Includes index. , Cover -- Half Title -- Series Page -- Title Page -- Copyright Page -- Contents -- Series Preface -- Preface -- Contributors -- Chapter 1: When does symbiosis begin? Bacterial cues necessary for metamorphosis in the marine polychaete Hydroides elegans -- 1.1 The symbiosis space -- 1.2 Chemical cues mediate symbiotic interactions -- 1.3 How do specific symbiotic interactions begin? Examples from the pre-symbiosis space -- 1.4 Bacterially induced metamorphosis of marine invertebrate animals -- 1.5 Bacterial induction of metamorphosis in Hydroides elegans -- 1.6 Identification of larval metamorphic cues from biofilm bacteria -- 1.7 How variability of inductive bacteria and identified settlement cues relate to variable larval settlement and recruitment -- 1.8 Lipopolysaccharide mediates both symbiotic and pre-symbiotic interactions -- 1.9 Conclusion -- References -- Chapter 2: The language of symbiosis: Insights from protist biology -- 2.1 Introduction -- 2.2 Cytoplasm as microcosm -- 2.3 Eukaryotes inside eukaryotes (inside other eukaryotes) -- 2.4 Ectosymbiosis: It's a jungle out there -- 2.5 Microbial symbioses: Power struggles in time and space -- 2.6 Conclusion -- Acknowledgments -- References -- Chapter 3: Trichoplax and its bacteria: How many are there? Are they speaking? -- 3.1 Introduction -- 3.2 How many symbionts are known to be present and where do they occur? -- 3.3 Do all placozoans harbor both G. incantans and R. eludens? -- 3.4 Intracellular locations of the placozoan symbionts -- 3.5 Unusual mitochondria in placozoan fiber cells and their possible relationship to symbiosis -- 3.6 Molecular inferences on the nature of the Trichoplax-bacteria symbioses -- 3.7 How are the bacterial symbionts of placozoans transmitted between generations? -- 3.8 Some big questions remaining and suggestions for their resolution -- Acknowledgments. , References -- Chapter 4: Decoding cellular dialogues between sponges, bacteria, and phages -- 4.1 Introduction -- 4.2 Host-bacteria dialogue -- 4.2.1 Sponge immune receptors -- 4.2.2 Microbe associated molecular patterns (MAMPs) -- 4.3 Bacteria-bacteria dialogue -- 4.3.1 Quorum sensing -- 4.3.2 Quorum quenching -- 4.4 Phage-bacteria-host dialogue -- 4.4.1 Phage diversity and host-specificity -- 4.4.2 Ankyphages aid symbionts in immune evasion -- 4.5 Conclusions and future perspectives -- Acknowledgments -- References -- Chapter 5: Symbiotic interactions in the holobiont Hydra -- 5.1 Introduction -- 5.2 Interactions between Hydra viridissima and the Chlorella photobiont -- 5.2.1 Location and transmission of the photobiont -- 5.2.2 Mutual benefits -- 5.2.3 Establishment and maintenance of the Chlorella-Hydra symbiosis -- 5.2.4 Molecular mechanisms involved in maintaining the symbiosis -- 5.3 Interactions between Hydra and symbiotic bacteria -- 5.3.1 Spatial localization of the bacteria in the Hydra host -- 5.3.2 Bacteria provide protection against fungal infection -- 5.3.3 The innate immune system shapes the host microbiome -- 5.3.4 Crosstalk between innate immunity and stem cell factors -- 5.3.5 Crosstalk between the microbiota and the nervous system -- 5.3.6 Effect of bacteria on host physiology -- 5.4 Conclusion: Hydra, an excellent model to understand inter-species interactions -- Acknowledgments -- References -- Chapter 6: Hydra and Curvibacter: An intimate crosstalk at the epithelial interface -- 6.1 Introduction -- 6.2 Hydra and Curvibacter: The ideal duo to understand inter-kingdom communications -- 6.3 Spatial localization and transmission of Curvibacter -- 6.4 Establishment and carrying capacity of Curvibacter colonization -- 6.5 Curvibacter function in the Hydra metaorganism -- 6.6 Inter-kingdom communication between Hydra and Curvibacter. , 6.7 Outlook -- Acknowledgments -- References -- Chapter 7: The coral holobiont highlights the dependence of cnidarian animal hosts on their associated microbes -- 7.1 Introduction: The coral holobiont as an ecosystem engineer and its reliance on associated microbes -- 7.2 The coral-Symbiodiniaceae relationship -- 7.2.1 Symbiodiniaceae: Micro-algal engines of the coral holobiont machinery -- 7.2.2 Innate immunity, symbiosis sensing, and cell signaling -- 7.2.3 Coral bleaching: The breakdown of the coral-Symbiodiniaceae relationship -- 7.3 Symbiodiniaceae-bacteria relationships -- 7.4 Diversity and function of microbes associated with the coral host -- 7.4.1 The host as a habitat -- 7.4.2 Diversity of coral-associated bacteria and interspecies interactions -- 7.4.3 Acquisition of bacterial associates and their roles in early coral life-stages -- 7.4.4 Coral probiotics -- 7.4.5 Contribution of bacteria to holobiont nutrient cycling -- 7.4.6 Archaea associated with the coral holobiont -- 7.4.7 Protists and fungi associated with the coral holobiont -- 7.5 Summary and Outlook -- References -- Chapter 8: Extra-intestinal regulation of the gut microbiome: The case of C. elegans TGFß/SMA signaling -- 8.1 Introduction: Caenorhabditis elegans as a model for studying the holobiont -- 8.2 The C. elegans gut microbiome and the factors that shape it -- 8.3 The intestinal niche -- 8.4 Host immunity and its role in shaping the intestinal niche -- 8.5 Multitissue contributions of TGFß signaling control anterior gut commensal abundance and function -- 8.6 TGFß signaling and cell nonautonomous regulation of intestinal function -- 8.7 Conclusions and future prospects: Convergence with other systems of host-symbiont interactions -- Acknowledgments -- References -- Chapter 9: Multiple roles of bacterially produced natural products in the bryozoan Bugula neritina. , 9.1 Introduction -- 9.2 Bryozoans, Bugula spp., and Bugula neritina -- 9.3 Bryostatins -- 9.4 Bryostatin production by the bacterial symbiont of B. neritina -- 9.5 Defensive role of bryostatins -- 9.6 Impacts of symbiont and symbiont-produced metabolites on host physiology -- 9.7 Bryostatins and symbionts in closely related genera -- 9.8 Future directions -- Acknowledgments -- References -- Chapter 10: The molecular dialogue through ontogeny between a squid host and its luminous symbiont -- 10.1 Introduction -- 10.2 Features of the Euprymna scolopes-Vibrio fischeri association as a model symbiosis -- 10.3 Host activities before symbiont colonization: Embryogenesis and early posthatching -- 10.4 Early posthatching activity that mediates species and strain specificity of the association -- 10.5 Colonization and early development -- 10.6 The basis of a stable symbiosis: Daily rhythms and maturation of the symbiotic organ -- 10.7 Conclusions -- Acknowledgments -- References -- Chapter 11: Evolving integrated multipartite symbioses between plant-sap feeding insects (Hemiptera) and their endosymbionts -- 11.1 Introduction -- 11.2 Roles of Hemipteran symbionts: Nutrition and beyond -- 11.3 Genome evolution in Hemipteran symbionts -- 11.4 Symbiont bearing organs: Transmission and development -- 11.4.1 Intracellular symbioses: Transovarial transmission and bacteriome development -- 11.4.2 Extracellular symbioses: External transmission and the midgut -- 11.5 Maintaining and regulating microbial symbionts -- 11.5.1 Evolution of mechanisms to maintain and regulate symbionts -- 11.5.2 Symbiont self-help and self-regulation -- 11.5.3 Symbiont-symbiont support -- 11.5.4 Host support and regulation of nutritional synthesis in symbionts -- 11.5.5 Host support and regulation of other symbiont cell functions -- 11.6 Conclusion -- References. , Chapter 12: Symbiosis for insect cuticle formation -- 12.1 Introduction -- 12.2 Weevil-Nardonella endosymbiosis -- 12.3 Nardonella genome is extremely reduced and specialized for tyrosine synthesis -- 12.4 Nardonella endosymbiotic system in Pachyrhynchus infernalis -- 12.5 Nardonella-harboring bacteriome as a tyrosine-producing organ -- 12.6 Suppression of Nardonella by antibiotic and its effects on tyrosine and DOPA provisioning -- 12.7 Contribution of Nardonella to adult cuticle formation in Pachyrhynchus infernalis -- 12.8 Incomplete tyrosine synthesis pathway of Nardonella and complementation by host genes -- 12.9 Insights from weevil-Nardonella symbiosis: Host's final step control over symbiont's metabolic pathway -- 12.10 Insights from weevil-Nardonella symbiosis: How do symbiont replacements proceed? -- 12.11 Symbiosis for insect cuticle formation: General phenomena across diverse insect taxa -- 12.12 Conclusion and perspective -- Acknowledgments -- References -- Chapter 13: Microbial determinants of folivory in insects -- 13.1 Introduction -- 13.2 Deconstructing the plant cell wall -- 13.3 Symbiont-mediated evasion of plant defenses -- 13.4 Niche preservation -- 13.5 Conclusions -- References -- Chapter 14: Right on cue: Microbiota promote plasticity of zebrafish digestive tract -- 14.1 Introduction -- 14.2 Development under immune surveillance -- 14.3 Developmental plasticity at the luminal interface -- 14.4 Beyond the lumen: A secreted bacterial protein impacts pancreas development -- 14.5 Conclusions -- References -- Chapter 15: Uncovering the history of intestinal host-microbiome interactions through vertebrate comparative genomics -- 15.1 Introduction -- 15.2 A history of symbiotic interactions captured within microbial and host genomes -- 15.3 Capturing symbiotic signals within coding regions of the host genome. , 15.4 Uncovering specific symbiotic signals in host transcriptional programs.

Weitere Ausg.: ISBN 0-367-51375-7

Weitere Ausg.: ISBN 0-367-22881-5

Sprache: Englisch