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624.00 ₪
Global Climate Change and Terrestrial Invertebrates
624.00 ₪
ISBN13
9781119070900
יצא לאור ב
Hoboken
זמן אספקה
21 ימי עסקים
עמודים
416
פורמט
Hardback
תאריך יציאה לאור
3 בפבר׳ 2017
Invertebrates perform such vital roles in global ecosystems and so strongly influence human wellbeing that biologist E.O. Wilson was prompted to describe them as little things that run the world.
Invertebrates perform such vital roles in global ecosystems and so strongly influence human wellbeing that biologist E.O. Wilson was prompted to describe them as little things that run the world. As they are such powerful shapers of the world around us, their response to global climate change is also pivotal in meeting myriad challenges looming on the horizon everything from food security and biodiversity to human disease control. This book presents a comprehensive overview of the latest scientific knowledge and contemporary theory relating to global climate change and terrestrial invertebrates. Featuring contributions from top international experts, this book explores how changes to invertebrate populations will affect human decision making processes across a number of crucial issues, including agriculture, disease control, conservation planning, and resource allocation.
Topics covered include methodologies and approaches to predict invertebrate responses, outcomes for disease vectors and ecosystem service providers, underlying mechanisms for community level responses to global climate change, evolutionary consequences and likely effects on interactions among organisms, and many more. Timely and thought-provoking, Global Climate Change and Terrestrial Invertebrates offers illuminating insights into the profound influence the simplest of organisms may have on the very future of our fragile world.
| עמודים | 416 |
|---|---|
| פורמט | Hardback |
| ISBN10 | 1119070902 |
| יצא לאור ב | Hoboken |
| תאריך יציאה לאור | 3 בפבר׳ 2017 |
| תוכן עניינים | List of Contributors xiii Preface xvii 1 Introduction to Global Climate Change and Terrestrial Invertebrates 1 Scott N. Johnson and T. Hefin Jones 1.1 Background 1 1.2 Predictions for Climate and Atmospheric Change 2 1.3 General Mechanisms for Climate Change Impacts on Invertebrates 2 1.3.1 Direct Impacts on Physiology, Performance and Behaviour 3 1.3.2 Indirect Impacts on Habitats, Resources and Interacting Organisms 3 1.4 Themes of the Book 4 1.4.1 Methods for Studying Invertebrates and Global Climate Change 4 1.4.2 Friends and Foes: Ecosystem Service Providers and Vectors of Disease 4 1.4.3 Multi-Trophic Interactions and Invertebrate Communities 5 1.4.4 Evolution, Intervention and Emerging Perspectives 6 Acknowledgements 7 References 7 Part I Methods for Studying Invertebrates and Climate Change 9 2 Using Historical Data for Studying Range Changes 11 Georgina Palmer and Jane K. Hill Summary 11 2.1 Introduction 11 2.2 Review of Historical Data Sets on Species Distributions 13 2.3 Methods for Using Historical Data to Estimate Species Range Changes 15 2.3.1 Measuring Changes in Distribution Size 16 2.3.2 Measuring Change in the Location of Species Ranges 16 2.3.3 An Invertebrate Example: Quantifying Range Shift by the Comma Butterfly Polygonia c-album in Britain 17 2.4 Challenges and Biases in Historical Data 19 2.4.1 Taxonomic Bias 19 2.4.2 Spatial and Temporal Biases 20 2.4.3 Accounting for Temporal and Spatial Biases 21 2.5 New Ways of Analysing Data and Future Perspectives 23 Acknowledgements 24 References 24 3 Experimental Approaches for Assessing Invertebrate Responses to Global Change Factors 30 Richard L. Lindroth and Kenneth F. Raffa Summary 30 3.1 Introduction 30 3.2 Experimental Scale: Reductionist, Holistic and Integrated Approaches 32 3.3 Experimental Design: Statistical Concerns 33 3.4 Experimental Endpoints: Match Metrics to Systems 35 3.5 Experimental Systems: Manipulations From Bottle to Field 36 3.5.1 Indoor Closed Systems 36 3.5.2 Outdoor Closed Systems 38 3.5.3 Outdoor Open Systems 39 3.6 Team Science: the Human Dimension 40 3.6.1 Personnel 41 3.6.2 Guiding Principles 41 3.6.3 Operation and Communication 41 3.7 Conclusions 41 Acknowledgements 42 References 42 4 Transplant Experiments a Powerful Method to Study Climate Change Impacts 46 Sabine S. Nooten and Nigel R. Andrew Summary 46 4.1 Global Climate Change 46 4.2 Climate Change Impacts on Species 47 4.3 Climate Change Impacts on Communities 48 4.4 Common Approaches to Study Climate Change Impacts 48 4.5 Transplant Experiments a Powerful Tool to Study Climate Change 49 4.5.1 Can Species Adapt to a Warmer Climate? 50 4.5.2 The Potential of Range Shifts 50 4.5.3 Changes in the Timing of Events 51 4.5.4 Shifts in Species Interactions 52 4.5.5 Disentangling Genotypic and Phenotypic Responses 54 4.5.6 Shifts in Communities 54 4.6 Transplant Experiment Trends Using Network Analysis 57 4.7 What s Missing in Our Current Approaches? Next Steps for Implementing Transplant Experiments 60 Acknowledgements 62 References 62 Part II Friends and Foes: Ecosystem Service Providers and Vectors of Disease 69 5 Insect Pollinators and Climate Change 71 Jessica R. K. Forrest Summary 71 5.1 Introduction 71 5.2 The Pattern: Pollinator Populations and Climate Change 72 5.2.1 Phenology 72 5.2.2 Range Shifts 75 5.2.3 Declining Populations 75 5.3 The Process: Direct Effects of Climate Change 76 5.3.1 Warmer Growing-Season Temperatures 76 5.3.2 Warmer Winters and Reductions in Snowpack 79 5.4 The Process: Indirect Effects of Climate Change 81 5.4.1 Interactions with Food Plants 81 5.4.2 Interactions with Natural Enemies 82 5.5 Synthesis, and the View Ahead 83 Acknowledgements 84 References 84 6 Climate Change Effects on Biological Control in Grasslands 92 Philippa J. Gerard and Alison J. Popay Summary 92 6.1 Introduction 92 6.2 Changes in Plant Biodiversity 94 6.3 Multitrophic Interactions and Food Webs 94 6.3.1 Warming and Predator Behaviour 97 6.3.2 Herbage Productivity and Quality 98 6.3.3 Plant Defence Compounds 98 6.3.4 Fungal Endophytes 100 6.3.5 Changes in Plant Phenology 101 6.4 Greater Exposure to Extreme Events 102 6.4.1 Changes in Precipitation 102 6.4.2 Drought Effects 103 6.5 Range Changes 103 6.6 Greater Exposure to Pest Outbreaks 104 6.7 Non-Target Impacts 104 6.8 Conclusion 105 Acknowledgements 105 References 105 7 Climate Change and Arthropod Ectoparasites and Vectors of Veterinary Importance 111 Hannah Rose Vineer, Lauren Ellse and Richard Wall Summary 111 7.1 Introduction 111 7.2 Parasite Host Interactions 113 7.3 Evidence of the Impacts of Climate on Ectoparasites and Vectors 114 7.4 Impact of Human Behaviour and Husbandry on Ectoparasitism 116 7.5 Farmer Intervention as a Density-Dependent Process 118 7.6 Predicting Future Impacts of Climate Change on Ectoparasites and Vectors 118 Acknowledgements 123 References 123 8 Climate Change and the Biology of Insect Vectors of Human Pathogens 126 Luis Fernando Chaves Summary 126 8.1 Introduction 126 8.2 Interaction with Pathogens 129 8.3 Physiology, Development and Phenology 131 8.4 Population Dynamics, Life History and Interactions with Other Vector Species 132 8.5 Case Study of Forecasts for Vector Distribution Under Climate Change: The Altitudinal Range of Aedes albopictus and Aedes japonicus in Nagasaki, Japan 134 8.6 Vector Ecology and Evolution in Changing Environments 138 Acknowledgements 139 References 140 9 Climate and Atmospheric Change Impacts on Aphids as Vectors of Plant Diseases 148 James M.W. Ryalls and Richard Harrington Summary 148 9.1 The Disease Pyramid 148 9.1.1 Aphids 149 9.1.2 Host-Plants 152 9.1.3 Viruses 154 9.2 Interactions with the Pyramid 155 9.2.1 Aphid Host-Plant Interactions 155 9.2.2 Host-Plant Virus Interactions 158 9.2.3 Virus Aphid Interactions 160 9.2.4 Aphid Host-Plant Virus Interactions 162 9.3 Conclusions and Future Perspectives 162 Acknowledgements 163 References 164 Part III Multi-Trophic Interactions and Invertebrate Communities 177 10 Global Change, Herbivores and Their Natural Enemies 179 William T. Hentley and Ruth N. Wade Summary 179 10.1 Introduction 180 10.2 Global Climate Change and Insect Herbivores 181 10.3 Global Climate Change and Natural Enemies of Insect Herbivores 185 10.3.1 Elevated Atmospheric CO2 185 10.3.1.1 Prey Location 185 10.3.1.2 Prey Quality 186 10.3.2 Temperature Change 186 10.3.3 Reduction in Mean Precipitation 188 10.3.4 Extreme Events 190 10.3.5 Ozone and UV-B 190 10.4 Multiple Abiotic Factors 191 10.5 Conclusions 192 Acknowledgements 193 References 193 11 Climate Change in the Underworld: Impacts for Soil-Dwelling Invertebrates 201 Ivan Hiltpold, Scott N. Johnson, Renee-Claire Le Bayon and Uffe N. Nielsen Summary 201 11.1 Introduction 201 11.1.1 Soil Community Responses to Climate Change 202 11.1.2 Scope of the Chapter 202 11.2 Effect of Climate Change on Nematodes: Omnipresent Soil Invertebrates 203 11.2.1 Nematode Responses to eCO2 203 11.2.2 Nematode Responses to Warming 205 11.2.3 Nematode Responses to Altered Precipitation Regimes 206 11.2.4 Ecosystem Level Effects of Nematode Responses to Climate Change 207 11.3 Effect of Climate Change on Insect Root Herbivores, the Grazers of the Dark 207 11.3.1 Insect Root Herbivore Responses to eCO2 208 11.3.2 Insect Root Herbivore Responses to Warming 210 11.3.3 Insect Root Herbivore Responses to Altered Precipitation 210 11.3.4 Soil-Dwelling Insects as Modifiers of Climate Change Effects 211 11.4 Effect of Climate Change on Earthworms: the Crawling Engineers of Soil 212 11.4.1 Earthworm Responses to eCO2 212 11.4.2 Earthworm Responses to Warming and Altered Precipitation 214 11.4.3 Climate Change Modification of Earthworm Plant Microbe Interactions 214 11.4.4 Influence of Climate Change on Earthworms in Belowground Food Webs 215 11.4.5 Influence of Climate Change on Earthworm Colonization of New Habitats 215 11.5 Conclusions and Future Perspectives 216 Acknowledgements 217 References 218 12 Impacts of Atmospheric and Precipitation Change on Aboveground-Belowground Invertebrate Interactions 229 Scott N. Johnson, James M.W. Ryalls and Joanna T. Staley Summary 229 12.1 Introduction 229 12.1.1 Interactions Between Shoot and Root Herbivores 231 12.1.2 Interactions Between Herbivores and Non-Herbivorous Invertebrates 232 12.1.2.1 Detritivore Shoot Herbivore Interactions 232 12.1.2.2 Root Herbivore Pollinator Interactions 232 12.2 Atmospheric Change Elevated Carbon Dioxide Concentrations 233 12.2.1 Impacts of e[CO2] on Interactions Mediated by Plant Trait Modification 233 12.2.2 Impacts of e[CO2] and Warming on Interactions Mediated by Plant Trait Modification 234 12.2.3 Impacts of Aboveground Herbivores on Belowground Invertebrates via Deposition Pathways 234 12.3 Altered Patterns of Precipitation 236 12.3.1 Precipitation Effects on the Outcome of Above Belowground Interactions 236 12.3.1.1 Case Study Impacts of Simulated Precipitation Changes on Aboveground Belowground Interactions in the Brassicaceae 237 12.3.2 Aboveground Belowground Interactions in Mixed Plant Communities Under Altered Precipitation Scenarios 239 12.3.3 Altered Precipitation Impacts on Decomposer Herbivore Interactions 240 12.3.4 Impacts of Increased Unpredictability and Variability of Precipitation Events on the Frequency of Above Belowground Interactions 240 12.4 Conclusions and Future Directions 242 12.4.1 Redressing the Belowground Knowledge Gap 243 12.4.2 Testing Multiple Environmental Factors 243 12.4.3 New Study Systems 244 12.4.4 Closing Remarks 245 Acknowledgements 245 References 245 13 Forest Invertebrate Communities and Atmospheric Change 252 Sarah L. Facey and Andrew N. Gherlenda Summary 252 13.1 Why Are Forest Invertebrate Communities Important? 253 13.2 Atmospheric Change and Invertebrates 253 13.3 Responses of Forest Invertebrates to Elevated Carbon Dioxide Concentrations 254 13.3.1 Herbivores 254 13.3.2 Natural Enemies 259 13.3.3 Community-Level Responses 259 13.4 Responses of Forest Invertebrates to Elevated Ozone Concentrations 263 13.4.1 Herbivores 263 13.4.2 Natural Enemies 264 13.4.3 Community-Level Studies 265 13.5 Interactions Between Carbon Dioxide and Ozone 265 13.6 Conclusions and Future Directions 267 Acknowledgements 268 References 268 14 Climate Change and Freshwater Invertebrates: Their Role in Reciprocal Freshwater Terrestrial Resource Fluxes 274 Micael Jonsson and Cristina Canhoto Summary 274 14.1 Introduction 274 14.2 Climate-Change Effects on Riparian and Shoreline Vegetation 275 14.3 Climate-Change Effects on Runoff of Dissolved Organic Matter 277 14.4 Climate Change Effects on Basal Freshwater Resources Via Modified Terrestrial Inputs 278 14.5 Effects of Altered Terrestrial Resource Fluxes on Freshwater Invertebrates 279 14.6 Direct Effects of Warming on Freshwater Invertebrates 280 14.7 Impacts of Altered Freshwater Invertebrate Emergence on Terrestrial Ecosystems 282 14.8 Conclusions and Research Directions 284 14.8.1 Effects of Simultaneous Changes in Resource Quality and Temperature on Freshwater Invertebrate Secondary Production 284 14.8.2 Effects of Changed Resource Quality and Temperature on the Size Structure of Freshwater Invertebrate Communities 284 14.8.3 Effects of Changed Resource Quality on Elemental Composition (i.e., Stoichiometry, Autochthony versus Allochthony, and PUFA Content) of Freshwater Invertebrates 284 14.8.4 Effects of Changed Freshwater Invertebrate Community Composition and Secondary Production on Freshwater Insect Emergence 285 14.8.5 Effects of Changed Quality (i.e., Size Structure and Elemental Composition) of Emergent Freshwater Insects on Terrestrial Food Webs 285 14.8.6 Effects of Climate Change on Landscape-Scale Cycling of Matter Across the Freshwater Terrestrial Interface 285 Acknowledgements 286 References 286 15 Climatic Impacts on Invertebrates as Food for Vertebrates 295 Robert J. Thomas, James O. Vafidis and Renata J. Medeiros Summary 295 15.1 Introduction 295 15.2 Changes in the Abundance of Vertebrates 296 15.2.1 Variation in Demography and Population Size 296 15.2.2 Local Extinctions 299 15.2.3 Global Extinctions 299 15.3 Changes in the Distribution of Vertebrates 300 15.3.1 Geographical Range Shifts 300 15.3.2 Altitudinal Range Shifts 301 15.3.3 Depth Range Shifts 302 15.3.4 Food-Mediated Mechanisms and Trophic Consequences of Range Shifts 302 15.4 Changes in Phenology of Vertebrates, and Their Invertebrate Prey 303 15.4.1 Consequences of Phenological Changes for Trophic Relationships 303 15.4.2 Phenological Mismatches in Marine Ecosystems 303 15.4.3 Phenological Mismatches in Terrestrial Ecosystems 304 15.4.3.1 Behaviour and Ecology of the Vertebrates 305 15.4.3.2 Habitat Differences in Prey Phenology 306 15.5 Conclusions 307 15.6 Postscript: Beyond the Year 2100 308 Acknowledgements 308 References 308 Part IV Evolution, Intervention and Emerging Perspectives 317 16 Evolutionary Responses of Invertebrates to Global Climate Change: the Role of Life-History Trade-Offs and Multidecadal Climate Shifts 319 Jofre Carnicer, Chris Wheat, Maria Vives, Andreu Ubach, Cristina Domingo, S oren Nylin, Constanti Stefanescu, Roger Vila, Christer Wiklund and Josep Penuelas Summary 319 16.1 Introduction 319 16.2 Fundamental Trade-Offs Mediating Invertebrate Evolutionary Responses to Global Warming 327 16.2.1 Background 327 16.2.2 Mechanisms Underpinning Trade-Offs 328 16.2.2.1 Endocrine Hormone-Signalling Pathway Antagonistic Pleiotropy Trade-Off Hypothesis 330 16.2.2.2 The Thermal Stability Kinetic Efficiency Trade-Off Hypothesis 330 16.2.2.3 Resource-Allocation Trade-Off Hypothesis 331 16.2.2.4 Enzymatic-Multifunctionality (Moonlighting) Hypothesis 331 16.2.2.5 Respiratory Water Loss Total Gas Exchange Hypothesis 332 16.2.2.6 Water-Loss Trade-Off Hypotheses 332 16.3 The Roles of Multi-Annual Extreme Droughts and Multidecadal Shifts in Drought Regimens in Driving Large-Scale Responses of Insect Populations 333 16.4 Conclusions and New Research Directions 337 Acknowledgements 339 References 339 17 Conservation of Insects in the Face of Global Climate Change 349 Paula Arribas, Pedro Abellan, Josefa Velasco, Andres Millan and David Sanchez-Fernandez Summary 349 17.1 Introduction 349 17.1.1 Insect Biodiversity 349 17.1.2 Insect Biodiversity and Climate Change: the Research Landscape 350 17.2 Vulnerability Drivers of Insect Species Under Climate Change 352 17.3 Assessment of Insect Species Vulnerability to Climate Change 353 17.4 Management Strategies for Insect Conservation Under Climate Change 355 17.5 Protected Areas and Climate Change 357 17.6 Perspectives on Insect Conservation Facing Climate Change 359 Acknowledgements 360 References 361 18 Emerging Issues and Future Perspectives for Global Climate Change and Invertebrates 368 Scott N. Johnson and T. Hefin Jones 18.1 Preamble 368 18.2 Multiple Organisms, Asynchrony and Adaptation in Climate Change Studies 368 18.3 Multiple Climatic Factors in Research 369 18.4 Research Into Extreme Climatic Events 371 18.5 Climate change and Invertebrate Biosecurity 372 18.6 Concluding Remarks 374 References 374 Species Index 379 Subject Index 385 |
| זמן אספקה | 21 ימי עסקים |
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