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The Microbiome and Metagenomics Catherine Lozupone CPBS 7711 September 25, 2014 What is the microbiome? • “The ecological community of commensal, symbiotic, and pathogenic microorganisms that share our body space” • Microbiota: “collection of organisms” Microbiome: “collection of genes” • Bacteria, Archaea, microbial eukaryotes (e.g. fungi or protists) and viruses. • Body Sites – Important roles in health and disease: Gut, Mouth, Vagina, Skin (diverse sites:Nasal epithelial) – Important roles in disease: Lung, blood, liver, urine The big tree • Majority of life’s diversity is microbial • Majority of microbial life cannot be grown in pure culture Pace, N.R.,The Universal Nature of Biochemistry. PNAS Vol 98(3) pp 805-808. The Human Gut Microbiota • 100 trillion microbial cells: outnumber human cells 10 to 1! • Most gut microbes are harmless or beneficial. – Protect against enteropathogens – Extract dietary calories and vitamins – Prevent immune disorders • List of diseases associated with dysbiosis ever growing – – – – Inflammatory Diseases: IBD, IBS Metabolic Diseases: Obesity, Malnutrition Neurological Disorders Cancer What do we want to understand? • What does a healthy microbiome look like? – How diverse is it? – What types of bacteria are there? – What is their function? • How variable is the microbiome? – Over time within an individual? – Across individuals? – Functionally? • What are driving factors of variability? – Age, culture, physiological state (pregnancy) • How do changes affect disease? – What properties (taxa, amount of diversity) change with disease? – Cause or affect? – Functional consequences of dysbiosis • Host Interactions – Evolution/adaptation to the host over time. – Immune system Culture-independent studies revolutionized our understanding of gut bacteria • Culture-based studies over-emphasized the importance of easily culturable organisms (e.g. E. coli). Culture-independent surveys 1. Extract DNA from environmental samples. 2.PCR amplify SSU rRNA gene (which species?) Sequence random fragments (which function?) 3. Evaluate Sequences Gut microbiota has simple composition at the phylum level Data from: Yatsunenko et. al. 2012. Nature. Different phyla: Animals and plants Diversity of Firmicutes in 2 healthy adults • Each person harbors > 1000 species. • Some species are unique (red and blue) • Some shared (purple) • We know very little about what most of these species do! Sequencing technology renaissance enabled more complex study designs • Sanger Sequencing (thousands) • Pyrosequencing (millions) • Illumina (billions!) Metagenomics • The study of metagenomes, genetic material recovered directly from environmental samples. • Marker gene – PCR amplify a gene of interest – Tells you what types of organisms are there – Bacteria/Archaea (16S rRNA), Microbial Euks (18S rRNA), Fungi (ITS), Virus (no good marker) • Shotgun – Fragment DNA and sequence randomly. – Tells you what kind of functions are there. Small Subunit Ribosomal RNA • Present in all known life forms • Highly conserved • Resistant to horizontal transfer events 16S rRNA secondary structure Other ‘Omics • MetaTranscriptomics (sequence version of microarray) – – – – Isolate all RNA Deplete rRNA Sequence all transcripts Sometimes phenotype only seen in activity of the microbiota • Metabolomics – What metabolites does a community produce? – E.g. in feces or urine • MetaProteomics – What proteins does a community produce? Integrating Data Types • 16S rRNA -> shotgun metagenomics – What gene differences cannot be explained by 16S? – Selection by HGT • 16S/ genomics -> transcriptomics-> metabolomics – What species or genes (or combination of species or genes), when expressed, are responsible for producing a given metabolite? Sequencing Technologies • Sanger -> 454 Pyrosequencing -> Illumina Short reads (pyrosequencing) can recapture the result. • UW UniFrac clustering with Arb parsimony insertion of 100 bp reads extending from primer R357. • Assignment of short reads to an existing phylogeny (e.g. greengenes coreset) allows for the analysis of very large datasets. Liu Z, Lozupone C, Hamady M, Bushman FD & Knight R (2007) Short pyrosequencing reads suffice for accurate microbial community analysis. Nucleic Acids Res 35: e120.