Handbook of Molecular Microbial Ecology I: Metagenomics and Complementary Approaches
July 2011, Wiley-Blackwell
The premiere two-volume reference on revelations from studying complex microbial communities in many distinct habitats
Metagenomics is an emerging field that has changed the way microbiologists study microorganisms. It involves the genomic analysis of microorganisms by extraction and cloning of DNA from a group of microorganisms, or the direct use of the purified DNA or RNA for sequencing, which allows scientists to bypass the usual protocol of isolating and culturing individual microbial species. This method is now used in laboratories across the globe to study microorganism diversity and for isolating novel medical and industrial compounds.
Handbook of Molecular Microbial Ecology is the first comprehensive two-volume reference to cover unculturable microorganisms in a large variety of habitats, which could not previously have been analyzed without metagenomic methodology. It features review articles as well as a large number of case studies, based largely on original publications and written by international experts. This first volume, Metagenomics and Complementary Approaches, covers such topics as:
Background information on DNA reassociation and use of 16 rRNA and other DNA fingerprinting approaches
Species designation in microbiology
Metagenomics: Introduction to the basic tools with examples
Consortia and databases
Complementary approaches—microarrays, metatranscriptomics, metaproteomics, metabolomics, and single cell analysis
A special feature of this volume is the highlighting of the databases and computer programs used in each study; they are listed along with their sites in order to facilitate the computer-assisted analysis of the vast amount of data generated by metagenomic studies.
Handbook of Molecular Microbial Ecology I is an invaluable reference for researchers in metagenomics, microbiology, and environmental microbiology; those working on the Human Microbiome Project; microbial geneticists; molecular microbial ecologists; and professionals in molecular microbiology and bioinformatics.
1. Introduction (Frans J. de Bruijn).
2. DNA reassociation yields broad-scale information on metagenome complexity and microbial diversity (V. Torsvik).
3. Diversity of 23S rRNA genes within individual prokaryotic genomes (Zhiheng Pei).
4. Use of the rRNA operon and genomic repetitive sequences for the identification of bacteria (A. Nascimento).
5. Use of different PCR primer-based strategies for characterization of natural microbial communities (James Prosser).
6. Horizontal gene transfer and recombination shape mesorhizobial populations in the gene center of the host plants Astragalus luteolus and Astragalus ernestii in Sichuan, China (Xiaoping Zhang).
7. Amplified rDNA restriction analysis (ARDRA)for identification and phylogenetic placement of 16S-rDNA clones (Menachim Sklarz).
8. Clustering-based peak alignment algorithm for objective and quantitative analysis of DNA fingerprinting data (Satoshi Ishii).
The Species Concept.
9. Population genomics informs our understanding of the bacterial species concept (Margaret Riley).
10. Genome analysis of Streptococcus agalactiae: Implication for the microbial “pan-genome” (R. Rappuoli).
11. Metagenomic insights into bacterial species (Kostas Konstantinidis).
12. Report of the ad hoc committee for the re-evaluation of the species definition in bacteriology (E. Stackebrandt).
13. Metagenomic Approaches for the Identification of Microbial Species (David Ward).
14. Microbial Ecology in the age of metagenomics (Jianping Xu).
15. The enduring legacy of small rRNA in microbiology (Susan Tringe).
16. Pitfalls of PCR-based rRNA gene sequence analysis: an update on some parameters (Stackebrandt).
17. Empirical testing of 16S rRNA gene PCR primer pairs reveals variance in target specificity and efficacy not suggested by in silico analysis (Sergio Morales and Bill Holben).
18. The impact of next-generation sequencing technologies on (meta)genomics (George Weinstock).
19. Accuracy and quality of massively parallel DNA pyrosequencing (Susan Huse and David Mark Welch).
20. Environmental shotgun sequencing: Its potential and challenges for studying the hidden world of microbes (Jonathan Eisen).
21. Comparison of random sequence reads versus 16S rDNA sequences for estimating the biodiversity of a metagenomic library (C. Manischan).
22. Metagenomic libraries for functional screeing (Svein Valla).
23. GC Fractionation Allows Comparative Total Microbial Community Analysis, Enhances Diversity Assessment, and Facilitates of Minority Populations of Bacteria (Bill Holben).
24. Enriching plant microbiota for a metagenomic library construction (Ying Zeng).
25. Towards Automated Phylogenomic Inference (Wu and Eisen).
26. Integron first gene cassettes: a target to find adaptive genes in metagenomes (Christine Cagnon).
27. High-resolution metagenomics: assessing specific functional types in complex microbial communities (Christoserdova).
28. Gene-targeted –metagenomics (GT-metagenomics) to explore the extensive diversity of genes of interest in microbial communities (J. Tiedje).
29. Phylogenetic screening of metagenomic libraries using homing endonuclease restriction and marker insertion (Torsten Thomas).
30. ArrayOme- & tRNAcc-facilitated mobilome discovery: comparative genomics approaches for identifying rich veins of novel bacterial DNA sequences (Hong-Yu OU).
31. Sequence-Based Characterization of Microbiomes by Serial Analysis of Ribosomal Sequence Tags (SARST) (Zhongtang Yu).
Consortia and Databases.
32. The metagenomics of plant pathogen-suppressive soils (J.D. Van Elsas).
33. Soil Metagenomic Exploration of the Rare Biosphere (Pascal Simonet and Timothy Vogel).
34. The BIOSPAS consortium: Soil Biology and agricultural production (Luis Wall).
35. The Human Microbiome Project (George Weinstock).
36. The Ribosomal Database Project: sequences and Software for high-throughput rRNA analysis (J. R. Cole, G. M. Garrity and Jim Tiedje).
37. The metagenomics RAST server- a public resource for the automatic phylogenetic and functional analysis of metagenomes (Folker Meyer).
38. The EBI Metagenomics Archive, Integration and Analysis resource (Apweiler).
Computer Assisted Analysis.
39. Comparative metagenome analysis using MEGAN (Suparna Mitra and Daniel Huson).
40. Phylogenetic binning of metagenome sequence samples (Alice C. McHardy).
41. Gene prediction in metagenomic fragments with Orphelia: A large scale machine learning approach (Katharina Hoff).
42. Binning metagenomic sequences using seeded GSOm (Sen-Lin Tang).
43. Iterative read mapping and assembly allows the use of a more distant reference in metagenomic assembly (Bas E. Dutilh).
44. Ribosomal RNA identification in metagenomic and metatranscriptomic datasets (Li).
45. SILVA: comprehensive databases for quality checked and aligned ribosomal RNA sequence data compatible with ARB (Frank Gloeckner).
46. ARB; a software environment for sequence data (Wolfgang Ludwig).
47. The Phyloware Project: A software framework for phylogenomic virtue (Daniel Frank).
48. Metasim- A sequencing simulator for genomics and metagenomics (Daniel Richter).
49. ClustScan: an integrated program package for the detection and semi-automatic annotation of secondary metabolite clusters in genomic and metagenomic DNA datasets (Daslav Hranueli).
50. MetaGene; Prediction of prokaryotic and phage genes in metagenomic sequences (Noguchi).
51. primers4clades, a web server to design lineage-specific PCR primers for gene-targeted metagenomics (Pablo Vinuesa).
52. A parsimony approach to biological pathway reconstruction/inference for genomes and metagenomes (Y. Ye).
53. ESPRIT: estimating species richness using large collections of 16S rRNA data (Yijun Sun).
54. (Meta) genomics approaches in systems biology (Manuel Ferrer).
55. Towards “focused metagenomics”: a case study combining DNA stable-isotope probing, multiple displacement amplification and metagenomics (J. Colin Murrell).
56. Galbraith, E. A., D. A. Antonopoulos, K. E. Nelson, and B. A. White . Suppressive subtractive hybridization reveals extensive horizontal transfer in the rumen metagenome (Bryan White).
57. GeoChip: A high throughout metagenomics technology for dissecting microbial community functional structure (J. Zhou).
58. Phylogenetic microarrays (PhyloChips) for analysis of complex microbial communities (Eoin Brodie).
59. Phenomics and Phenotype MicroArrays: Applications Complementing Metagenomics (Barry Bochner).
60. Microbial persistence in low biomass, extreme environments: The great unknown (Kasthuri Venkateswaran).
61. Application of phylogenetic oligonucleotide microarrays in microbial analysis (Nian Wang).
62. Isolation of mRNA from environmental microbial communities for metatranscriptomic analyses (P. Schenk).
63. Comparative day/night metatrancriptomic analysis of microbial communities in the North Pacific subtropical gyre (Rachel Poretski).
64. The “double RNA” approach to simultaneously assess the structure and function of environmental microbial communities by meta-transcriptomics (Tim Urich and Christa Schleper).
65. Soil eukaryotic diversity, a metatranscriptomic approach (Marmeisse).
66. Proteomics for the analysis of environmental stress responses in prokaryotes (Mark Suter).
67. Microbial community proteomics (Paul Wilmes).
68. Synchronicity between population structure and proteome profiles: A metaproteomic analysis of Chesapeake Bay bacterial communities (Feng Chen).
69. High-Throughput Cyanobacterial Proteomics: Systems-level Proteome Identification and Quantitation (Phillip Wright).
70. Protein Expression Profile of an Environmentally Important Bacterial Strain: the Chromate Response of Arthrobacter sp. strain FB24 (K. Henne).
71. The small molecule dimension: Mass spectrometry based metabolomics, enzyme assays, and imaging (Trent R. Northen).
72. Metabolomics: high resolution tools offer to follow bacterial growth on a molecular level (Lucio Marianna and Philipp Schmitt-Kopplin).
73. Metabolic profiling of plant tissues by electrospray mass spectrometry (Heather Walker).
74. Metabolite identification, pathways and omic integration using online databases and tools (Matthew Davey).
Single cell analysis.
75. Application of cytomics to separate natural microbial communities by their physiological properties (Susann Müller).
76. Capturing microbial populations for environmental genomics (A. Pernthaler/Wendeberg).
77. Microscopic single-cell isolation and multiple displacement amplification of genomes from uncultured prokaryotes (Peter Westermann).
“Handbook of Molecular Microbial Ecology I is an invaluable reference for researchers in metagenomics, microbiology, and environmental microbiology; those working on the Human Microbiome Project; microbial geneticists; molecular microbial ecologists; and professionals in molecular microbiology and bioinformatics.” (Bois et Forets des Tropiques, 2011)
"Handbook of Molecular Microbial Ecology I is an invaluable reference for researchers in metagenomics, microbiology, and environmental microbiology; those working on the Human Microbiome Project; microbial geneticists; molecular microbial ecologists; and professionals in molecular microbiology and bioinformatics." (TMCnet.com, 8 November 2011)
From the vents of the ocean floor to deep within the human gut they leave no corner of Earth’s biosphere untouched. They represent such an overwhelming majority of life on earth that no other organism can lay claim to their total omnipresence as they maintain the living world around us. Microbes may be the smallest of living creatures, but they are unrivalled as the most important.
In a new two volume set, the Handbook of Molecular Microbial Ecology, Professor Frans J. de Bruijn reveals how the field of microbiology has been transformed by the recent emergence of metagenomics, a discipline which allows microbiologists to study uncultured microbes directly from the environment.
“Before metagenomics the main problem with studying microbes was the assumption that microorganisms needed to be culturable in order to classify them and study their metabolic and organismal diversity,” said de Bruijn. “Now we know that the unculturable world is far greater than the culturable one. In fact, the number of prokaryotic genomes has been estimated from 2000 to 18,000 genomes in a single gram of soil.”
Handbook of Molecular Microbial Ecology is a premiere two-volume reference which explores complex microbial communities in many distinct habitats. From genomic analysis to the direct use of DNA and RNA for sequencing, the two volumes outline the latest methods now used in laboratories across the globe to study microorganisms.
Together the handbooks offer the first comprehensive reference to cover unculturable microorganisms which could not be analyzed without metagenomic methodology. Both volumes feature review articles as well as a large number of case studies based on original publications and written by international experts.
“Metagenomics provides answers to the questions: ‘who exactly is out there and what are they doing’ by analysing the megasequence data that is produced,” concluded de Bruijn. “Using this methodology entire genomes have been assembled as the knowledge about the physiology of new species improves and the invisible force of microbes which maintain our world becomes a little more visible.”