Description

Book Synopsis

An updated text exploring the properties of the soil microbial community

Today, the environmentally oriented specialties of microbiology are shifting from considering a single or a few microbial species to focusing on the entire microbial community and its interactions.? The third edition of Soil Microbiology has been fully revised and updated to reflect this change, with a new focus on microbial communities and how they impact global ecology.

The third edition still provides thorough coverage of basic soil microbiology principles, yet the textbook also expands students'' understanding of the role the soil microbial community plays in global environmental health and human health. They can also learn more about the techniques used to conduct analysis at this level.

Readers will benefit from the edition''s expanded use of figures and tables as well as the recommendations for further reading found within each chapter.

  • Considers the impact

    Table of Contents

    Preface xv

    Introduction 1

    1 Soil Ecosystems: Physical and Chemical Boundaries 5

    1.1 Soil as an Ecosystem 11

    1.1.1 Soil System Function 12

    1.1.2 Soil Formation and the Microbial Community 15

    1.1.3 Implications of Definition of the Soil Ecosystem 18

    1.2 The Micro-ecosystem 19

    1.2.1 Interaction of Individual Soil Components with the Biotic System 19

    1.2.2 Aboveground and Belowground Communities and Soil Ecosystem Synergistic Development 31

    1.3 The Macro-ecosystem 37

    1.4 Concluding Comments 39

    2 The Soil Ecosystem: Biological Participants 45

    2.1 The Living Soil Component 45

    2.1.1 Biological and Genetic Implications of Occurrence of Living Cells in Soil 46

    2.1.2 Implications of Microbial Properties for Handling of Soil Samples 55

    2.2 Measurement of Soil Microbial Biomass 56

    2.2.1 Direct Counting Methods 58

    2.2.2 ATP Measure of Soil Microbial Biomass 59

    2.2.3 Soil Aerobic Respiration Measurements 60

    2.2.4 Chloroform Fumigation (Extraction and Incubation) Technique 61

    2.2.5 Limitations of Microbial Biomass Measurements 64

    2.3 The Nature of Soil Inhabitants 65

    2.4 Autecology and Soil Microbiology 66

    2.4.1 Limitations to Autecological Research 67

    2.4.2 Autecological Methods 67

    2.4.3 PCR for Quantification of Soil Microbes 72

    2.4.4 Expression of Population Density per Unit of Soil 78

    2.4.5 Products of Soil Autecological Research 78

    2.5 Principles and Products of Synecological Research 79

    2.6 Interphase Between Study of Individual and Community Microbiology 80

    2.7 Concluding Comments 81

    3 Microbial Diversity of Soil Ecosystems 89

    3.1 Classical Culture-Based Studies of Soil Microbial Diversity 90

    3.1.1 Value of Culture-Based Studies of Soil Microbial Diversity 90

    3.1.2 Limitations of Culture-Based Studies of Soil Microbial Diversity 90

    3.1.3 The Challenge of Defining Bacterial Species 91

    3.1.4 Alternatives to Bacterial Strain Isolation 92

    3.2 Surrogate Measures of Soil Microbial Diversity 92

    3.3 Diversity Surrogates: Physiological Profiling 93

    3.3.1 Physiological Profiling of Isolates 93

    3.3.2 Community-Level Physiological Profiling 94

    3.3.3 Value of Community-Level Physiological Profiling 95

    3.3.4 Limitations of Community Level Physiological Profiling 95

    3.4 Diversity Surrogates: Phospholipid Fatty Acid Analysis 96

    3.4.1 PLFA Analysis of Isolates 96

    3.4.2 Community PLFA Analysis 97

    3.4.3 Value of PLFA Analysis 98

    3.4.4 Limitations of PFLA Analysis 98

    3.5 Nucleic Acid-Based Analyses of Soil Microbial Diversity 98

    3.5.1 Nucleic Acid Based Analysis of Isolates 99

    3.5.2 Community Nucleic Acid Analysis 99

    3.5.3 DNA Extraction 100

    3.5.4 Analysis of Community DNA 101

    3.6 PCR-Based Methods 101

    3.6.1 Clone Library Sequencing 101

    3.6.2 DNA-Based Fingerprinting Techniques 102

    3.6.3 High-Throughput Amplicon Sequencing 103

    3.6.4 Limitations of PCR-Based Methods 105

    3.7 Metagenomics 105

    3.7.1 Limitations of Metagenomics 106

    3.8 Conclusions: Utility and Limitations of Diversity Analysis Procedures 107

    4 Energy Transformations Supporting Growth and Survival of Soil Microbes 115

    4.1 Microbial Growth Kinetics in Soil 116

    4.2 Microbial Growth Phases: Laboratory-Observed Microbial Growth Compared to Soil Population Dynamics 120

    4.3 Mathematical Representation of Soil Microbial Growth 126

    4.4 Uncoupling Energy Production from Microbial Biomass Synthesis 130

    4.5 Implications of Microbial Energy and Carbon Transformation Capacities for Soil Biological Processes 132

    4.5.1 Energy Acquisition in Soil Ecosystems 132

    4.5.2 Microbial Contribution to Soil Energy and Carbon Transformation 136

    4.6 Concluding Comments 143

    5 Process Control in Soil 149

    5.1 Microbial Response to Abiotic Limitations: General Considerations 151

    5.1.1 Definition of Limitations to Biological Activity 151

    5.1.2 Elucidation of Limiting Factors in Soil 153

    5.2 Impact of Individual Soil Properties on Microbial Activity 157

    5.2.1 Availability of Nutrients 158

    5.2.2 Soil Water 164

    5.2.3 Aeration 172

    5.2.4 Redox Potential 173

    5.2.5 pH 175

    5.2.6 Temperature 178

    5.3 Microbial Adaptation to Abiotic Stress 180

    5.4 Concluding Comments 181

    6 Soil Enzymes: Basic Principles and Their Applications 185

    6.1 A Philosophical Basis for the Study of Soil Enzymes 187

    6.2 Basic Soil Enzyme Properties 192

    6.3 Principles of Enzyme Assays 196

    6.4 Enzyme Kinetics 202

    6.5 Distribution of Enzymes in Soil Organic Components 206

    6.6 Ecology of Extracellular Enzymes 210

    6.7 Concluding Comments 212

    7 Microbial Interactions and Community Development and Resilience 217

    7.1 Common Concepts of Microbial Community Interaction 220

    7.2 Classes of Biological Interactions 222

    7.2.1 Neutralism 223

    7.2.2 Positive Biological Interactions 223

    7.2.3 Negative Biological Interactions 227

    7.3 Trophic Interactions and Nutrient Cycling 235

    7.3.1 Soil Flora and Fauna 235

    7.3.2 Earthworms: Mediators of Multilevel Mutualism 238

    7.4 Importance of Microbial Interactions to Overall Biological Community Development 239

    7.5 Management of Soil Microbial Populations 241

    7.6 Concluding Comments: Implications of Soil Microbial Interactions 242

    8 The Rhizosphere/Mycorrhizosphere 251

    8.1 The Rhizosphere 252

    8.1.1 The Microbial Community 254

    8.1.2 Sampling Rhizosphere Soil 256

    8.1.3 Plant Contributions to the Rhizosphere Ecosystem 258

    8.1.4 Benefits to Plants Resulting from Rhizosphere Populations 263

    8.1.5 Plant Pathogens in the Rhizosphere 264

    8.1.6 Manipulation of Rhizosphere Populations 265

    8.2 Mycorrhizal Associations 268

    8.2.1 Mycorrhizae in the Soil Community 271

    8.2.2 Symbiont Benefits from Mycorrhizal Development 273

    8.2.3 Environmental Considerations 275

    8.3 The Mycorrhizosphere 276

    8.4 Conclusion 278

    9 Introduction to the Biogeochemical Cycles 287

    9.1 Introduction to Conceptual and Mathematical Models of Biogeochemical Cycles 289

    9.1.1 Development and Utility of Conceptual Models 290

    9.1.2 Mathematical Modeling of Biogeochemical Cycles 295

    9.2 Specific Models of Biogeochemical Cycles and Their Application 297

    9.2.1 The Environmental Connection 300

    9.2.2 Interconnectedness of Biogeochemical Cycle Processes 302

    9.3 Biogeochemical Cycles as Sources of Plant Nutrients for Ecosystem Sustenance 306

    9.4 General Processes and Participants in Biogeochemical Cycles 307

    9.5 Measurement of Biogeochemical Processes: What Data Are Useful? 309

    9.5.1 Assessment of Biological Activities Associated with Biogeochemical Cycling 309

    9.5.2 Soil Sampling Aspects of Assessment of Biogeochemical Cycling Rates 310

    9.5.3 Environmental Impact of Nutrient Cycles 311

    9.5.4 Example of Complications in Assessing Soil Nutrient Cycling: Nitrogen Mineralization 312

    9.6 Conclusions 315

    10 The Carbon Cycle 321

    10.1 Environmental Implications of the Soil Carbon Cycle 323

    10.1.1 Soils as a Source or Sink for Carbon Dioxide and Methane 324

    10.1.2 Diffusion of Soil Carbon Dioxide to the Atmosphere 325

    10.1.3 Managing Soils to Augment Organic Matter Contents 327

    10.1.4 Carbon Recycling in Soil Systems 328

    10.2 Biochemical Aspects of the Soil Carbon Cycle 329

    10.2.1 Individual Components of Soil Organic Carbon Pools 330

    10.2.2 Analysis of Soil Organic Carbon Fractions 337

    10.2.3 Structural versus Functional Analysis 339

    10.2.4 Microbial Mediators of Soil Carbon Cycle Processes 342

    10.3 Kinetics of Soil Carbon Transformations 344

    10.4 Conclusions: Management of the Soil Carbon Cycle 348

    11 The Nitrogen Cycle: Mineralization, Immobilization, and Nitrification 355

    11.1 Nitrogen Mineralization 359

    11.1.1 Soil Organic Nitrogen Resources 359

    11.1.2 Assessment of Nitrogen Mineralization 361

    11.2 Nitrogen Immobilization 362

    11.2.1 Process Definition and Organisms Involved 362

    11.2.2 Impact of Nitrogen Immobilization Processes on Plant Communities 362

    11.2.3 Measurement of Soil Nitrogen Immobilization Rates 365

    11.3 Quantitative Description of Nitrogen Mineralization Kinetics 366

    11.4 Microbiology of Mineralization 370

    11.5 Environmental Influences on Nitrogen Mineralization 370

    11.6 Nitrification 372

    11.6.1 Identity of Bacterial Species that Nitrify 373

    11.6.2 Benefits to the Microorganism from Nitrification 374

    11.6.3 Quantification of Nitrifiers in Soil Samples 374

    11.6.4 Discrepancies between Population Enumeration Data and Field Nitrification Rates 376

    11.6.5 Sources of Ammonium and Nitrite for Nitrifiers 377

    11.6.6 Environmental Properties Limiting Nitrification 377

    11.7 Concluding Observations: Control of the Internal Soil Nitrogen Cycle 381

    12 Nitrogen Fixation: The Gateway to Soil Nitrogen Cycling 389

    12.1 Biochemistry of Nitrogen Fixation 391

    12.1.1 The Process 391

    12.1.2 The Enzyme, Nitrogenase 394

    12.1.3 Measurement of Biological Nitrogen Fixation in Culture and in the Field 396

    12.2 General Properties of Soil Diazotrophs 401

    12.2.1 Free-Living Diazotrophs 401

    12.2.2 Examples of Function of Nonsymbiotic Diazotrophs in Soil Ecosystems 404

    12.2.3 Diazotrophs in Rhizosphere Populations 404

    12.2.4 Dizaotrophs in Flooded Ecosystems 408

    12.3 Conclusions 409

    13 Biological Nitrogen Fixation 415

    13.1 Rhizobium–Legume Symbioses 416

    13.1.1 Grouping of Rhizobial Strains 416

    13.1.2 Rhizobial Contributions to Nitrogen Fixation 418

    13.1.3 Nodulation of Legumes 419

    13.1.4 Plant Control of Nodule Formation 423

    13.2 Manipulation of Rhizobium–Legume Symbioses for Ecosystem Management 424

    13.3 Rhizobial Inoculation Procedures 426

    13.3.1 Inocula Delivery Systems 426

    13.3.2 Survival of Rhizobial Inocula 427

    13.3.3 Biological Interactions in Legume Nodulation 432

    13.4 Nodule Occupants: Indigenous vs Foreign 432

    13.5 Actinorhizal Associations 434

    13.6 Conclusions 436

    14 Denitrification 447

    14.1 Pathways for Biological Reduction of Soil Nitrate 448

    14.2 Biochemical Properties of Denitrification 450

    14.2.1 Carbon and Energy Sources for Denitrifiers 450

    14.2.2 Induction of Synthesis of Nitrogen Oxide Reductases 451

    14.3 Environmental Implications of Nitrous Oxide Formation 452

    14.4 Microbiology of Denitrification 453

    14.4.1 Assessment of Soil Denitrifier Populations 453

    14.4.2 General Traits of Denitrifiers 454

    14.4.3 Generic Identity of Denitrifiers 455

    14.5 Quantification of Nitrogen Losses from an Ecosystem via Denitrification 456

    14.5.1 Nitrogen Balance Studies 456

    14.5.2 Use of Nitrogen Isotopes to Trace Soil Nitrogen Transformations 458

    14.5.3 Soil Nitrogen Oxide Transformations 459

    14.5.4 Acetylene Block Method for Assessing Denitrification Processes in Soil 460

    14.6 Environmental Factors Controlling Denitrification Rates 462

    14.6.1 Nature and Amount of Organic Matter 462

    14.6.2 Nitrate Concentration 464

    14.6.3 Aeration/Moisture 464

    14.6.4 pH 465

    14.6.5 Temperature 466

    14.6.6 Interaction of Limitations to Denitrification in Soil Systems 467

    14.7 Conclusions 467

    15 Fundamentals of the Sulfur, Phosphorus, and Mineral Cycles 477

    15.1 Sulfur in the Soil Ecosystem 477

    15.2 Biogeochemical Cycling of Sulfur in Soil 479

    15.3 Biological Sulfur Oxidation 482

    15.3.1 Microbiology of Sulfur Oxidation 482

    15.3.2 Environmental Conditions Affecting Sulfur Oxidation 486

    15.4 Biological Sulfur Reduction 488

    15.4.1 Anaerobic Biodegradation 490

    15.4.2 Reducing Acidity of Acid Mine Drainage 490

    15.4.3 Reduction of Complications of Metal Contamination in Soil 490

    15.5 Mineralization and Assimilation of Sulfurous Substances 491

    15.6 The Phosphorus Cycle 492

    15.7 Microbially Catalyzed Soil Metal Cycling 494

    15.7.1 Interactions of Soil Metals with Living Systems 495

    15.7.2 Microbial Response to Elevated Metal Loading 497

    15.7.3 Microbial Modifications of Metal Mobility in Soils 498

    15.7.4 Managing Soils Contaminated with Toxic Metals 501

    15.8 Conclusion 502

    16 Soil Microbes: Optimizers of Soil System Sustainability and Reparation of Damaged Soils 511

    16.1 Foundational Concepts of Bioremediation 514

    16.1.1 Bioremediation Defined 514

    16.1.2 Conceptual Unity of Bioremediation Science 515

    16.1.3 Complexity of Remediation Questions 516

    16.2 The Microbiology of Bioremediation 517

    16.2.1 Microbes as Soil Remediators 518

    16.2.2 Substrate–Decomposer Interactions 519

    16.2.3 Microbial Inoculation for Bioremediation 528

    16.3 Soil Properties Controlling Bioremediation 532

    16.3.1 Physical and Chemical Delimiters of Biological Activities 532

    16.3.2 Sequestration and Sorption Limitations to Bioavailability 536

    16.4 Concluding Observations 538

    Concluding Challenge 545

    Index 549

Soil Microbiology

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A Hardback by Robert L. Tate

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    View other formats and editions of Soil Microbiology by Robert L. Tate

    Publisher: John Wiley and Sons Ltd
    Publication Date: 16/11/2020
    ISBN13: 9780470311103, 978-0470311103
    ISBN10: 047031110X
    Also in:
    Sedimentology and pedology The environment Ecological science, the Biosphere

    Description

    Book Synopsis

    An updated text exploring the properties of the soil microbial community

    Today, the environmentally oriented specialties of microbiology are shifting from considering a single or a few microbial species to focusing on the entire microbial community and its interactions.? The third edition of Soil Microbiology has been fully revised and updated to reflect this change, with a new focus on microbial communities and how they impact global ecology.

    The third edition still provides thorough coverage of basic soil microbiology principles, yet the textbook also expands students'' understanding of the role the soil microbial community plays in global environmental health and human health. They can also learn more about the techniques used to conduct analysis at this level.

    Readers will benefit from the edition''s expanded use of figures and tables as well as the recommendations for further reading found within each chapter.

    • Considers the impact

      Table of Contents

      Preface xv

      Introduction 1

      1 Soil Ecosystems: Physical and Chemical Boundaries 5

      1.1 Soil as an Ecosystem 11

      1.1.1 Soil System Function 12

      1.1.2 Soil Formation and the Microbial Community 15

      1.1.3 Implications of Definition of the Soil Ecosystem 18

      1.2 The Micro-ecosystem 19

      1.2.1 Interaction of Individual Soil Components with the Biotic System 19

      1.2.2 Aboveground and Belowground Communities and Soil Ecosystem Synergistic Development 31

      1.3 The Macro-ecosystem 37

      1.4 Concluding Comments 39

      2 The Soil Ecosystem: Biological Participants 45

      2.1 The Living Soil Component 45

      2.1.1 Biological and Genetic Implications of Occurrence of Living Cells in Soil 46

      2.1.2 Implications of Microbial Properties for Handling of Soil Samples 55

      2.2 Measurement of Soil Microbial Biomass 56

      2.2.1 Direct Counting Methods 58

      2.2.2 ATP Measure of Soil Microbial Biomass 59

      2.2.3 Soil Aerobic Respiration Measurements 60

      2.2.4 Chloroform Fumigation (Extraction and Incubation) Technique 61

      2.2.5 Limitations of Microbial Biomass Measurements 64

      2.3 The Nature of Soil Inhabitants 65

      2.4 Autecology and Soil Microbiology 66

      2.4.1 Limitations to Autecological Research 67

      2.4.2 Autecological Methods 67

      2.4.3 PCR for Quantification of Soil Microbes 72

      2.4.4 Expression of Population Density per Unit of Soil 78

      2.4.5 Products of Soil Autecological Research 78

      2.5 Principles and Products of Synecological Research 79

      2.6 Interphase Between Study of Individual and Community Microbiology 80

      2.7 Concluding Comments 81

      3 Microbial Diversity of Soil Ecosystems 89

      3.1 Classical Culture-Based Studies of Soil Microbial Diversity 90

      3.1.1 Value of Culture-Based Studies of Soil Microbial Diversity 90

      3.1.2 Limitations of Culture-Based Studies of Soil Microbial Diversity 90

      3.1.3 The Challenge of Defining Bacterial Species 91

      3.1.4 Alternatives to Bacterial Strain Isolation 92

      3.2 Surrogate Measures of Soil Microbial Diversity 92

      3.3 Diversity Surrogates: Physiological Profiling 93

      3.3.1 Physiological Profiling of Isolates 93

      3.3.2 Community-Level Physiological Profiling 94

      3.3.3 Value of Community-Level Physiological Profiling 95

      3.3.4 Limitations of Community Level Physiological Profiling 95

      3.4 Diversity Surrogates: Phospholipid Fatty Acid Analysis 96

      3.4.1 PLFA Analysis of Isolates 96

      3.4.2 Community PLFA Analysis 97

      3.4.3 Value of PLFA Analysis 98

      3.4.4 Limitations of PFLA Analysis 98

      3.5 Nucleic Acid-Based Analyses of Soil Microbial Diversity 98

      3.5.1 Nucleic Acid Based Analysis of Isolates 99

      3.5.2 Community Nucleic Acid Analysis 99

      3.5.3 DNA Extraction 100

      3.5.4 Analysis of Community DNA 101

      3.6 PCR-Based Methods 101

      3.6.1 Clone Library Sequencing 101

      3.6.2 DNA-Based Fingerprinting Techniques 102

      3.6.3 High-Throughput Amplicon Sequencing 103

      3.6.4 Limitations of PCR-Based Methods 105

      3.7 Metagenomics 105

      3.7.1 Limitations of Metagenomics 106

      3.8 Conclusions: Utility and Limitations of Diversity Analysis Procedures 107

      4 Energy Transformations Supporting Growth and Survival of Soil Microbes 115

      4.1 Microbial Growth Kinetics in Soil 116

      4.2 Microbial Growth Phases: Laboratory-Observed Microbial Growth Compared to Soil Population Dynamics 120

      4.3 Mathematical Representation of Soil Microbial Growth 126

      4.4 Uncoupling Energy Production from Microbial Biomass Synthesis 130

      4.5 Implications of Microbial Energy and Carbon Transformation Capacities for Soil Biological Processes 132

      4.5.1 Energy Acquisition in Soil Ecosystems 132

      4.5.2 Microbial Contribution to Soil Energy and Carbon Transformation 136

      4.6 Concluding Comments 143

      5 Process Control in Soil 149

      5.1 Microbial Response to Abiotic Limitations: General Considerations 151

      5.1.1 Definition of Limitations to Biological Activity 151

      5.1.2 Elucidation of Limiting Factors in Soil 153

      5.2 Impact of Individual Soil Properties on Microbial Activity 157

      5.2.1 Availability of Nutrients 158

      5.2.2 Soil Water 164

      5.2.3 Aeration 172

      5.2.4 Redox Potential 173

      5.2.5 pH 175

      5.2.6 Temperature 178

      5.3 Microbial Adaptation to Abiotic Stress 180

      5.4 Concluding Comments 181

      6 Soil Enzymes: Basic Principles and Their Applications 185

      6.1 A Philosophical Basis for the Study of Soil Enzymes 187

      6.2 Basic Soil Enzyme Properties 192

      6.3 Principles of Enzyme Assays 196

      6.4 Enzyme Kinetics 202

      6.5 Distribution of Enzymes in Soil Organic Components 206

      6.6 Ecology of Extracellular Enzymes 210

      6.7 Concluding Comments 212

      7 Microbial Interactions and Community Development and Resilience 217

      7.1 Common Concepts of Microbial Community Interaction 220

      7.2 Classes of Biological Interactions 222

      7.2.1 Neutralism 223

      7.2.2 Positive Biological Interactions 223

      7.2.3 Negative Biological Interactions 227

      7.3 Trophic Interactions and Nutrient Cycling 235

      7.3.1 Soil Flora and Fauna 235

      7.3.2 Earthworms: Mediators of Multilevel Mutualism 238

      7.4 Importance of Microbial Interactions to Overall Biological Community Development 239

      7.5 Management of Soil Microbial Populations 241

      7.6 Concluding Comments: Implications of Soil Microbial Interactions 242

      8 The Rhizosphere/Mycorrhizosphere 251

      8.1 The Rhizosphere 252

      8.1.1 The Microbial Community 254

      8.1.2 Sampling Rhizosphere Soil 256

      8.1.3 Plant Contributions to the Rhizosphere Ecosystem 258

      8.1.4 Benefits to Plants Resulting from Rhizosphere Populations 263

      8.1.5 Plant Pathogens in the Rhizosphere 264

      8.1.6 Manipulation of Rhizosphere Populations 265

      8.2 Mycorrhizal Associations 268

      8.2.1 Mycorrhizae in the Soil Community 271

      8.2.2 Symbiont Benefits from Mycorrhizal Development 273

      8.2.3 Environmental Considerations 275

      8.3 The Mycorrhizosphere 276

      8.4 Conclusion 278

      9 Introduction to the Biogeochemical Cycles 287

      9.1 Introduction to Conceptual and Mathematical Models of Biogeochemical Cycles 289

      9.1.1 Development and Utility of Conceptual Models 290

      9.1.2 Mathematical Modeling of Biogeochemical Cycles 295

      9.2 Specific Models of Biogeochemical Cycles and Their Application 297

      9.2.1 The Environmental Connection 300

      9.2.2 Interconnectedness of Biogeochemical Cycle Processes 302

      9.3 Biogeochemical Cycles as Sources of Plant Nutrients for Ecosystem Sustenance 306

      9.4 General Processes and Participants in Biogeochemical Cycles 307

      9.5 Measurement of Biogeochemical Processes: What Data Are Useful? 309

      9.5.1 Assessment of Biological Activities Associated with Biogeochemical Cycling 309

      9.5.2 Soil Sampling Aspects of Assessment of Biogeochemical Cycling Rates 310

      9.5.3 Environmental Impact of Nutrient Cycles 311

      9.5.4 Example of Complications in Assessing Soil Nutrient Cycling: Nitrogen Mineralization 312

      9.6 Conclusions 315

      10 The Carbon Cycle 321

      10.1 Environmental Implications of the Soil Carbon Cycle 323

      10.1.1 Soils as a Source or Sink for Carbon Dioxide and Methane 324

      10.1.2 Diffusion of Soil Carbon Dioxide to the Atmosphere 325

      10.1.3 Managing Soils to Augment Organic Matter Contents 327

      10.1.4 Carbon Recycling in Soil Systems 328

      10.2 Biochemical Aspects of the Soil Carbon Cycle 329

      10.2.1 Individual Components of Soil Organic Carbon Pools 330

      10.2.2 Analysis of Soil Organic Carbon Fractions 337

      10.2.3 Structural versus Functional Analysis 339

      10.2.4 Microbial Mediators of Soil Carbon Cycle Processes 342

      10.3 Kinetics of Soil Carbon Transformations 344

      10.4 Conclusions: Management of the Soil Carbon Cycle 348

      11 The Nitrogen Cycle: Mineralization, Immobilization, and Nitrification 355

      11.1 Nitrogen Mineralization 359

      11.1.1 Soil Organic Nitrogen Resources 359

      11.1.2 Assessment of Nitrogen Mineralization 361

      11.2 Nitrogen Immobilization 362

      11.2.1 Process Definition and Organisms Involved 362

      11.2.2 Impact of Nitrogen Immobilization Processes on Plant Communities 362

      11.2.3 Measurement of Soil Nitrogen Immobilization Rates 365

      11.3 Quantitative Description of Nitrogen Mineralization Kinetics 366

      11.4 Microbiology of Mineralization 370

      11.5 Environmental Influences on Nitrogen Mineralization 370

      11.6 Nitrification 372

      11.6.1 Identity of Bacterial Species that Nitrify 373

      11.6.2 Benefits to the Microorganism from Nitrification 374

      11.6.3 Quantification of Nitrifiers in Soil Samples 374

      11.6.4 Discrepancies between Population Enumeration Data and Field Nitrification Rates 376

      11.6.5 Sources of Ammonium and Nitrite for Nitrifiers 377

      11.6.6 Environmental Properties Limiting Nitrification 377

      11.7 Concluding Observations: Control of the Internal Soil Nitrogen Cycle 381

      12 Nitrogen Fixation: The Gateway to Soil Nitrogen Cycling 389

      12.1 Biochemistry of Nitrogen Fixation 391

      12.1.1 The Process 391

      12.1.2 The Enzyme, Nitrogenase 394

      12.1.3 Measurement of Biological Nitrogen Fixation in Culture and in the Field 396

      12.2 General Properties of Soil Diazotrophs 401

      12.2.1 Free-Living Diazotrophs 401

      12.2.2 Examples of Function of Nonsymbiotic Diazotrophs in Soil Ecosystems 404

      12.2.3 Diazotrophs in Rhizosphere Populations 404

      12.2.4 Dizaotrophs in Flooded Ecosystems 408

      12.3 Conclusions 409

      13 Biological Nitrogen Fixation 415

      13.1 Rhizobium–Legume Symbioses 416

      13.1.1 Grouping of Rhizobial Strains 416

      13.1.2 Rhizobial Contributions to Nitrogen Fixation 418

      13.1.3 Nodulation of Legumes 419

      13.1.4 Plant Control of Nodule Formation 423

      13.2 Manipulation of Rhizobium–Legume Symbioses for Ecosystem Management 424

      13.3 Rhizobial Inoculation Procedures 426

      13.3.1 Inocula Delivery Systems 426

      13.3.2 Survival of Rhizobial Inocula 427

      13.3.3 Biological Interactions in Legume Nodulation 432

      13.4 Nodule Occupants: Indigenous vs Foreign 432

      13.5 Actinorhizal Associations 434

      13.6 Conclusions 436

      14 Denitrification 447

      14.1 Pathways for Biological Reduction of Soil Nitrate 448

      14.2 Biochemical Properties of Denitrification 450

      14.2.1 Carbon and Energy Sources for Denitrifiers 450

      14.2.2 Induction of Synthesis of Nitrogen Oxide Reductases 451

      14.3 Environmental Implications of Nitrous Oxide Formation 452

      14.4 Microbiology of Denitrification 453

      14.4.1 Assessment of Soil Denitrifier Populations 453

      14.4.2 General Traits of Denitrifiers 454

      14.4.3 Generic Identity of Denitrifiers 455

      14.5 Quantification of Nitrogen Losses from an Ecosystem via Denitrification 456

      14.5.1 Nitrogen Balance Studies 456

      14.5.2 Use of Nitrogen Isotopes to Trace Soil Nitrogen Transformations 458

      14.5.3 Soil Nitrogen Oxide Transformations 459

      14.5.4 Acetylene Block Method for Assessing Denitrification Processes in Soil 460

      14.6 Environmental Factors Controlling Denitrification Rates 462

      14.6.1 Nature and Amount of Organic Matter 462

      14.6.2 Nitrate Concentration 464

      14.6.3 Aeration/Moisture 464

      14.6.4 pH 465

      14.6.5 Temperature 466

      14.6.6 Interaction of Limitations to Denitrification in Soil Systems 467

      14.7 Conclusions 467

      15 Fundamentals of the Sulfur, Phosphorus, and Mineral Cycles 477

      15.1 Sulfur in the Soil Ecosystem 477

      15.2 Biogeochemical Cycling of Sulfur in Soil 479

      15.3 Biological Sulfur Oxidation 482

      15.3.1 Microbiology of Sulfur Oxidation 482

      15.3.2 Environmental Conditions Affecting Sulfur Oxidation 486

      15.4 Biological Sulfur Reduction 488

      15.4.1 Anaerobic Biodegradation 490

      15.4.2 Reducing Acidity of Acid Mine Drainage 490

      15.4.3 Reduction of Complications of Metal Contamination in Soil 490

      15.5 Mineralization and Assimilation of Sulfurous Substances 491

      15.6 The Phosphorus Cycle 492

      15.7 Microbially Catalyzed Soil Metal Cycling 494

      15.7.1 Interactions of Soil Metals with Living Systems 495

      15.7.2 Microbial Response to Elevated Metal Loading 497

      15.7.3 Microbial Modifications of Metal Mobility in Soils 498

      15.7.4 Managing Soils Contaminated with Toxic Metals 501

      15.8 Conclusion 502

      16 Soil Microbes: Optimizers of Soil System Sustainability and Reparation of Damaged Soils 511

      16.1 Foundational Concepts of Bioremediation 514

      16.1.1 Bioremediation Defined 514

      16.1.2 Conceptual Unity of Bioremediation Science 515

      16.1.3 Complexity of Remediation Questions 516

      16.2 The Microbiology of Bioremediation 517

      16.2.1 Microbes as Soil Remediators 518

      16.2.2 Substrate–Decomposer Interactions 519

      16.2.3 Microbial Inoculation for Bioremediation 528

      16.3 Soil Properties Controlling Bioremediation 532

      16.3.1 Physical and Chemical Delimiters of Biological Activities 532

      16.3.2 Sequestration and Sorption Limitations to Bioavailability 536

      16.4 Concluding Observations 538

      Concluding Challenge 545

      Index 549

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