Keywords:
Microbial ecology.
;
Electronic books.
Description / Table of Contents:
Microbial ecology is the study of interactions among microbes in natural environments and their roles in biogeochemical cycles, food web dynamics, and the evolution of life. This book presents the basic principles of microbial ecology using examples from aquatic (freshwater and marine) and terrestrial ecosystems.
Type of Medium:
Online Resource
Pages:
1 online resource (333 pages)
Edition:
2nd ed.
ISBN:
9780192506474
URL:
https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=5447681
DDC:
579/.17
Language:
English
Note:
Cover -- Processes in Microbial Ecology -- Copyright -- Preface -- Table of Contents -- CHAPTER 1. Introduction -- What is a microbe? -- Why study microbial ecology? -- Microbes cause diseases of macroscopic organisms, including humans -- Microbes help to make our food and other useful products -- Microbes degrade and detoxify pollutants -- Microbes are models for exploring principles in ecology and evolution -- Microbes living today are models for early life on Earth and perhaps life on other planets -- Microbes mediate biogeochemical processes that affect global climate -- Microbes are everywhere, doing nearly everything -- How do we study microbes in nature? -- Separating microbes by phylogeny: the three domains of life -- Separating microbes into functional groups -- Autotroph versus heterotroph -- Phototroph versus chemotroph -- Combining structure and function -- Summary -- CHAPTER 2. Elements, biochemicals, and structures of microbes -- Elemental composition of microbes -- Elemental ratios in biogeochemical cycles .and studies -- C:N and C:P ratios for microbes -- Biochemical composition of microbes -- Variation in elemental ratios and biochemical composition -- Architecture of a microbial cell -- Membranes of microbes and active transport -- Cell walls in prokaryotes and eukaryotes -- Components of microbial cells as biomarkers -- Extracellular structures -- Extracellular polymers of microbes -- Flagella and cilia -- fimbriae and pili -- Summary -- CHAPTER 3. The physical-chemical environment of microbes -- Some important physical-chemical properties -- Water -- Temperature -- pH -- Salt and osmotic balance -- Oxygen and redox potential -- Light -- Pressure -- The consequences of being small -- Microbial life in natural aquatic habitats -- Motility and taxis -- Submicron- and micron-scale patchiness in aqueous environments.
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Microbial life in soils -- Water content of soils -- Interactions between temperature and water content in soils -- The biofilm environment -- Summary -- CHAPTER 4. Community structure of microbes in natural environments -- Taxonomy and phylogeny via genes: introduction to 16S rRNA-based methods -- The species problem -- Terms of diversity -- Patterns of diversity -- Bacterial communities are diverse but very uneven -- Uncultivated bacteria are not the same as easily cultivated bacteria -- Different bacteria are found in soils, freshwaters, and the oceans -- A few bacteria are widely distributed -- Archaea in non-extreme environments -- Ecological processes that assemble microbial communities -- Deterministic versus stochastic processes -- Everything everywhere? -- What controls diversity levels and bacterial community structure? -- Oxygen, temperature, salinity, and pH -- Moisture and soil microbial communities -- Organic material and inorganic nutrients -- Predation and viral lysis -- Community structure of fungi -- Relevance of community structure to understanding processes -- Summary -- CHAPTER 5. Genomes and meta-omics for microbes -- What are genomics and environmental genomics? -- Turning genomic sequences into genomic information -- Lessons from cultivated microbes -- Similar rRNA genes, dissimilar genomes -- Core genomes and pangenomes -- Genome size -- Organization of eukaryotic versus prokaryotic genomes -- Horizontal gene transfer -- Genomes and growth strategies for bacteria -- Specific genomic features and growth -- Streamlined genomes -- Oligotrophic versus copiotrophic bacterial genomes -- Genomes from uncultivated microbes: metagenomics -- Metagenomic approaches and linking structure with function -- Single-cell genomics -- Metatranscriptomics and metaproteomics -- Transcriptional response of oligotrophic and copiotrophic bacteria.
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Metatranscriptomes of eukaryotic microbes -- Summary -- CHAPTER 6. Microbial primary production and phototrophy -- Basics of primary production and photosynthesis -- The carbon dioxide-fixing enzyme -- Primary production, gross production, and net production -- Primary production by terrestrial higher plants and aquatic microbes -- The spring bloom and controls of phytoplankton growth -- Major groups of bloom-forming phytoplankton -- Diatoms -- Phaeocystis and dimethylsulfide -- Cyanobacteria and filamentous diazotrophs -- After the bloom: competition for limiting nutrients -- Primary production by coccoid cyanobacteria -- Anaerobic anoxygenic photosynthesis -- Sessile algae and microbial mats -- Summary -- CHAPTER 7. Degradation of organic matter -- Who does most of the respiration on the planet? -- Detritus and detrital food webs -- DOM and the microbial loop -- Bacterial growth efficiency and carbon use efficiency -- Mechanism of organic matter degradation -- Hydrolysis of high molecular weight organic compounds -- Uptake or mineralization of N and P? -- Degradation of lignin and other higher plant compounds -- Interactions between organic compounds: protection and priming -- Protection by adsorption or aggregation -- Priming effects -- Photoheterotrophy: energy from organic material and light -- Contribution of microbes to ancient organic carbon and SOM formation -- Degradation and microbial diversity -- Summary -- CHAPTER 8. Microbial growth, biomass production, and controls -- Are microbes alive or dead? -- Activity state of bacteria in water and soils -- Activity state of individual bacterial taxa -- Introduction to growth and biomass production -- Growth in the laboratory: batch cultures -- Growth in the laboratory: continuous cultures -- Maintenance energy -- Growth rates and biomass production in nature.
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Growth rates of phytoplankton, bacteria, and fungi -- Growth rates of individual microbial taxa -- Growth in the deep biosphere -- What sets growth by heterotrophic microbes in nature? -- Temperature effects on growth and carbon cycling -- pH effects -- Soil moisture -- Limitation by organic carbon -- Limitation by inorganic nutrients -- Co-limitation and interactions between controlling factors -- Cooperation between organisms -- Summary -- CHAPTER 9. Predation and protists -- Bacterivory in aquatic habitats -- Grazers of bacteria and fungi in soils and sediments -- Mechanism of protist grazing -- Factors a˛ecting grazing -- Prey number and predator-prey cycles -- Size relationships of predator and prey -- Chemical recognition and composition -- Grazing by larger protists: ciliates and dinoflagellates -- Ciliates as predators of bacteria, flagellates, and fungi -- Heterotrophic dinoflagellates -- Mixotrophic protists and endosymbiosis -- Protist community structure and the evolution of eukaryotes -- Exploring protist community structure -- Biogeography of protists -- Connecting protist communities with processes -- Summary -- CHAPTER 10. The ecology of viruses -- What are viruses? -- The number of viruses in natural environments -- Counting viruses by the plaque assay -- Counting viruses by microscopy -- Virus-bacteria ratio in nature -- Viral replication -- Temperate viruses and lysogeny in nature -- Host range of viruses -- Viral production, loss, and mortality of bacteria -- Percentage of infected cells -- Contribution of viruses versus grazers to bacterial mortality -- Viral decay and loss -- Viruses are not grazers -- Viral shunt and DOM production -- Population dynamics of a virus and its host -- Genetic exchange mediated by viruses -- Metagenomics of viruses -- Viral diversity -- Core, noncore, and auxiliary metabolic genes.
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Viruses of other organisms -- Mycoviruses: Viruses in fungi -- Viruses infecting algae and amoebae -- Summary -- CHAPTER 11. Processes in anoxic environments -- Introduction to anaerobic respiration -- Microbes use electron acceptors in order of redox potential -- Oxidation of organic carbon by di˛erent electron acceptors -- Limitations by concentration and supply -- Effect of physical state and chemical form -- The anaerobic food chain -- Fermentation -- Acetogenesis, interspecies hydrogen transfer, and syntrophy -- The sulfur cycle and sulfate reduction -- Electron donors for sulfate reduction -- Oxidation of reduced sulfur compounds and the rest of the sulfur cycle -- Non-phototrophic sulfur oxidation -- Sulfide oxidation by anoxygenic photosynthesis -- The carbon source for sulfur oxidizers -- Methane and methanogenesis -- Methanotrophy -- Aerobic methane degradation -- Anaerobic methane oxidation -- Anaerobic microbial eukaryotes -- Summary -- CHAPTER 12. The nitrogen cycle -- Nitrogen fixation -- Nitrogenase, the N2-fixing enzyme -- Solving the oxygen problem -- N2 fixation in nature -- Limitation of N2 fixation -- Ammonium assimilation, regeneration, and fluxes -- Ammonia oxidation and nitrification -- Aerobic ammonia oxidation by bacteria -- Ammonia oxidation by archaea -- Controls of aerobic ammonia oxidation -- The second step in nitrification: nitrite oxidation -- Complete nitrification by one organism -- Dissimilatory nitrate reduction and denitrification -- Anaerobic ammonia oxidation -- Denitrification versus anaerobic ammonia oxidation -- Sources and sinks of nitrous oxide -- Production by bacteria and archaea -- Consumption of N2O -- N budgets: global balance, local imbalances -- Summary -- CHAPTER 13. Introduction to geomicrobiology -- Cell surface charge and metal sorption -- Biomineralization by microbes.
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Iron minerals and microbes.
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