Fisher
Jenny C.
Fisher
Jenny C.
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ArticleA single genus in the gut microbiome reflects host preference and specificity(Nature Publishing Group, 2014-06-17) Eren, A. Murat ; Sogin, Mitchell L. ; Morrison, Hilary G. ; Vineis, Joseph H. ; Fisher, Jenny C. ; Newton, Ryan J. ; McLellan, Sandra L.Delineating differences in gut microbiomes of human and animal hosts contributes towards understanding human health and enables new strategies for detecting reservoirs of waterborne human pathogens. We focused upon Blautia, a single microbial genus that is important for nutrient assimilation as preliminary work suggested host-related patterns within members of this genus. In our dataset of 57 M sequence reads of the V6 region of the 16S ribosomal RNA gene in samples collected from seven host species, we identified 200 high-resolution taxonomic units within Blautia using oligotyping. Our analysis revealed 13 host-specific oligotypes that occurred exclusively in fecal samples of humans (three oligotypes), swine (six oligotypes), cows (one oligotype), deer (one oligotype), or chickens (two oligotypes). We identified an additional 171 oligotypes that exhibited differential abundance patterns among all the host species. Blautia oligotypes in the human population obtained from sewage and fecal samples displayed remarkable continuity. Oligotypes from only 10 Brazilian human fecal samples collected from individuals in a rural village encompassed 97% of all Blautia oligotypes found in a Brazilian sewage sample from a city of three million people. Further, 75% of the oligotypes in Brazilian human fecal samples matched those in US sewage samples, implying that a universal set of Blautia strains may be shared among culturally and geographically distinct human populations. Such strains can serve as universal markers to assess human fecal contamination in environmental samples. Our results indicate that host-specificity and host-preference patterns of organisms within this genus are driven by host physiology more than dietary habits.
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PreprintIdentification of specialists and abundance-occupancy relationships among intestinal bacteria of Aves, Mammalia, and Actinopterygii( 2015-12-16) Green, Hyatt C. ; Fisher, Jenny C. ; McLellan, Sandra L. ; Sogin, Mitchell L. ; Shanks, Orin C.The coalescence of next generation DNA sequencing methods, ecological perspectives, and bioinformatics analysis tools is rapidly advancing our understanding of the evolution and function of vertebrate-associated bacterial communities. Delineating host-microbial associations has applied benefits ranging from clinical treatments to protecting our natural waters. Microbial communities follow some broad-scale patterns observed for macro-organisms, but it remains unclear how specialization of intestinal vertebrate-associated communities to a particular host environment influences broad-scale patterns in microbial abundance and distribution. We analyzed the V6 region of 16S rRNA gene amplified from 106 fecal samples spanning Aves, Mammalia, and Actinopterygii (ray-finned fish). The interspecific abundance-occupancy relationship—where widespread taxa tend to be more abundant than narrowly distributed taxa—among operational taxonomic units (OTUs) was investigated within and among host species. In a separate analysis, specialists OTUs that were highly abundant in a single host and rare in all other hosts were identified using a multinomial model without excluding under-sampled OTUs a priori. We also show that intestinal microbes in humans and other vertebrates studied follow a similar interspecific abundance-occupancy relationship compared to plants and animals, as well as microbes in ocean and soil environments; but because intestinal host-associated communities have undergone intense specialization, this trend is violated by a disproportionately large number of specialist taxa. Although it is difficult to distinguish the effects of dispersal limitations, host selection, historical contingency, and stochastic processes on community assembly, results suggest bacterial taxa can be shared among diverse vertebrate hosts in ways similar to those of ‘free-living’ bacteria.