Last data update: Dec 09, 2024. (Total: 48320 publications since 2009)
Records 1-3 (of 3 Records) |
Query Trace: Hayes RB[original query] |
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A taxonomic signature of obesity in a large study of American adults
Peters BA , Shapiro JA , Church TR , Miller G , Trinh-Shevrin C , Yuen E , Friedlander C , Hayes RB , Ahn J . Sci Rep 2018 8 (1) 9749 Animal models suggest that gut microbiota contribute to obesity; however, a consistent taxonomic signature of obesity has yet to be identified in humans. We examined whether a taxonomic signature of obesity is present across two independent study populations. We assessed gut microbiome from stool for 599 adults, by 16S rRNA gene sequencing. We compared gut microbiome diversity, overall composition, and individual taxon abundance for obese (BMI >/= 30 kg/m(2)), overweight (25 </= BMI < 30), and healthy-weight participants (18.5 </= BMI < 25). We found that gut species richness was reduced (p = 0.04), and overall composition altered (p = 0.04), in obese (but not overweight) compared to healthy-weight participants. Obesity was characterized by increased abundance of class Bacilli and its families Streptococcaceae and Lactobacillaceae, and decreased abundance of several groups within class Clostridia, including Christensenellaceae, Clostridiaceae, and Dehalobacteriaceae (q < 0.05). These findings were consistent across two independent study populations. When random forest models were trained on one population and tested on the other as well as a previously published dataset, accuracy of obesity prediction was good (~70%). Our large study identified a strong and consistent taxonomic signature of obesity. Though our study is cross-sectional and causality cannot be determined, identification of microbes associated with obesity can potentially provide targets for obesity prevention and treatment. |
The gut microbiota in conventional and serrated precursors of colorectal cancer.
Peters BA , Dominianni C , Shapiro JA , Church TR , Wu J , Miller G , Yuen E , Freiman H , Lustbader I , Salik J , Friedlander C , Hayes RB , Ahn J . Microbiome 2016 4 (1) 69 BACKGROUND: Colorectal cancer is a heterogeneous disease arising from at least two precursors-the conventional adenoma (CA) and the serrated polyp. We and others have previously shown a relationship between the human gut microbiota and colorectal cancer; however, its relationship to the different early precursors of colorectal cancer is understudied. We tested, for the first time, the relationship of the gut microbiota to specific colorectal polyp types. RESULTS: Gut microbiota were assessed in 540 colonoscopy-screened adults by 16S rRNA gene sequencing of stool samples. Participants were categorized as CA cases (n = 144), serrated polyp cases (n = 73), or polyp-free controls (n = 323). CA cases were further classified as proximal (n = 87) or distal (n = 55) and as non-advanced (n = 121) or advanced (n = 22). Serrated polyp cases were further classified as hyperplastic polyp (HP; n = 40) or sessile serrated adenoma (SSA; n = 33). We compared gut microbiota diversity, overall composition, and normalized taxon abundance among these groups. CA cases had lower species richness in stool than controls (p = 0.03); in particular, this association was strongest for advanced CA cases (p = 0.004). In relation to overall microbiota composition, only distal or advanced CA cases differed significantly from controls (p = 0.02 and p = 0.002). In taxon-based analysis, stool of CA cases was depleted in a network of Clostridia operational taxonomic units from families Ruminococcaceae, Clostridiaceae, and Lachnospiraceae, and enriched in the classes Bacilli and Gammaproteobacteria, order Enterobacteriales, and genera Actinomyces and Streptococcus (all q < 0.10). SSA and HP cases did not differ in diversity or composition from controls, though sample size for these groups was small. Few taxa were differentially abundant between HP cases or SSA cases and controls; among them, class Erysipelotrichi was depleted in SSA cases. CONCLUSIONS: Our results indicate that gut microbes may play a role in the early stages of colorectal carcinogenesis through the development of CAs. Findings may have implications for developing colorectal cancer prevention therapies targeting early microbial drivers of colorectal carcinogenesis. |
Imputation and subset-based association analysis across different cancer types identifies multiple independent risk loci in the TERT-CLPTM1L region on chromosome 5p15.33.
Wang Z , Zhu B , Zhang M , Parikh H , Jia J , Chung CC , Sampson JN , Hoskins JW , Hutchinson A , Burdette L , Ibrahim A , Hautman C , Raj PS , Abnet CC , Adjei AA , Ahlbom A , Albanes D , Allen NE , Ambrosone CB , Aldrich M , Amiano P , Amos C , Andersson U , Andriole G Jr , Andrulis IL , Arici C , Arslan AA , Austin MA , Baris D , Barkauskas DA , Bassig BA , Beane Freeman LE , Berg CD , Berndt SI , Bertazzi PA , Biritwum RB , Black A , Blot W , Boeing H , Boffetta P , Bolton K , Boutron-Ruault MC , Bracci PM , Brennan P , Brinton LA , Brotzman M , Bueno-de-Mesquita HB , Buring JE , Butler MA , Cai Q , Cancel-Tassin G , Canzian F , Cao G , Caporaso NE , Carrato A , Carreon T , Carta A , Chang GC , Chang IS , Chang-Claude J , Che X , Chen CJ , Chen CY , Chen CH , Chen C , Chen KY , Chen YM , Chokkalingam AP , Chu LW , Clavel-Chapelon F , Colditz GA , Colt JS , Conti D , Cook MB , Cortessis VK , Crawford ED , Cussenot O , Davis FG , De Vivo I , Deng X , Ding T , Dinney CP , Di Stefano AL , Diver WR , Duell EJ , Elena JW , Fan JH , Feigelson HS , Feychting M , Figueroa JD , Flanagan AM , Fraumeni JF Jr , Freedman ND , Fridley BL , Fuchs CS , Gago-Dominguez M , Gallinger S , Gao YT , Gapstur SM , Garcia-Closas M , Garcia-Closas R , Gastier-Foster JM , Gaziano JM , Gerhard DS , Giffen CA , Giles GG , Gillanders EM , Giovannucci EL , Goggins M , Gokgoz N , Goldstein AM , Gonzalez C , Gorlick R , Greene MH , Gross M , Grossman HB , Grubb R 3rd , Gu J , Guan P , Haiman CA , Hallmans G , Hankinson SE , Harris CC , Hartge P , Hattinger C , Hayes RB , He Q , Helman L , Henderson BE , Henriksson R , Hoffman-Bolton J , Hohensee C , Holly EA , Hong YC , Hoover RN , Hosgood HD 3rd , Hsiao CF , Hsing AW , Hsiung CA , Hu N , Hu W , Hu Z , Huang MS , Hunter DJ , Inskip PD , Ito H , Jacobs EJ , Jacobs KB , Jenab M , Ji BT , Johansen C , Johansson M , Johnson A , Kaaks R , Kamat AM , Kamineni A , Karagas M , Khanna C , Khaw KT , Kim C , Kim IS , Kim YH , Kim YC , Kim YT , Kang CH , Jung YJ , Kitahara CM , Klein AP , Klein R , Kogevinas M , Koh WP , Kohno T , Kolonel LN , Kooperberg C , Kratz CP , Krogh V , Kunitoh H , Kurtz RC , Kurucu N , Lan Q , Lathrop M , Lau CC , Lecanda F , Lee KM , Lee MP , Le Marchand L , Lerner SP , Li D , Liao LM , Lim WY , Lin D , Lin J , Lindstrom S , Linet MS , Lissowska J , Liu J , Ljungberg B , Lloreta J , Lu D , Ma J , Malats N , Mannisto S , Marina N , Mastrangelo G , Matsuo K , McGlynn KA , McKean-Cowdin R , McNeill LH , McWilliams RR , Melin BS , Meltzer PS , Mensah JE , Miao X , Michaud DS , Mondul AM , Moore LE , Muir K , Niwa S , Olson SH , Orr N , Panico S , Park JY , Patel AV , Patino-Garcia A , Pavanello S , Peeters PH , Peplonska B , Peters U , Petersen GM , Picci P , Pike MC , Porru S , Prescott J , Pu X , Purdue MP , Qiao YL , Rajaraman P , Riboli E , Risch HA , Rodabough RJ , Rothman N , Ruder AM , Ryu JS , Sanson M , Schned A , Schumacher FR , Schwartz AG , Schwartz KL , Schwenn M , Scotlandi K , Seow A , Serra C , Serra M , Sesso HD , Severi G , Shen H , Shen M , Shete S , Shiraishi K , Shu XO , Siddiq A , Sierrasesumaga L , Sierri S , Sihoe AD , Silverman DT , Simon M , Southey MC , Spector L , Spitz M , Stampfer M , Stattin P , Stern MC , Stevens VL , Stolzenberg-Solomon RZ , Stram DO , Strom SS , Su WC , Sund M , Sung SW , Swerdlow A , Tan W , Tanaka H , Tang W , Tang ZZ , Tardon A , Tay E , Taylor PR , Tettey Y , Thomas DM , Tirabosco R , Tjonneland A , Tobias GS , Toro JR , Travis RC , Trichopoulos D , Troisi R , Truelove A , Tsai YH , Tucker MA , Tumino R , Van Den Berg D , Van Den Eeden SK , Vermeulen R , Vineis P , Visvanathan K , Vogel U , Wang C , Wang C , Wang J , Wang SS , Weiderpass E , Weinstein SJ , Wentzensen N , Wheeler W , White E , Wiencke JK , Wolk A , Wolpin BM , Wong MP , Wrensch M , Wu C , Wu T , Wu X , Wu YL , Wunder JS , Xiang YB , Xu J , Yang HP , Yang PC , Yatabe Y , Ye Y , Yeboah ED , Yin Z , Ying C , Yu CJ , Yu K , Yuan JM , Zanetti KA , Zeleniuch-Jacquotte A , Zheng W , Zhou B , Mirabello L , Savage SA , Kraft P , Chanock SJ , Yeager M , Landi MT , Shi J , Chatterjee N , Amundadottir LT . Hum Mol Genet 2014 23 (24) 6616-33 Genome-wide association studies (GWAS) have mapped risk alleles for at least ten distinct cancers to a small region of 63,000 bp on chromosome 5p15.33. This region harbors the TERT and CLPTM1L genes; the former encodes the catalytic subunit of telomerase reverse transcriptase and the latter may play a role in apoptosis. To investigate further the genetic architecture of common susceptibility alleles in this region, we conducted an agnostic subset-based meta-analysis (ASSET) across six distinct cancers in 34,248 cases and 45,036 controls. Based on sequential conditional analysis, we identified as many as six independent risk loci marked by common single nucleotide polymorphisms (SNPs): five in the TERT gene (region 1: rs7726159, P=2.10x10-39; region 3: rs2853677, P=3.30x10-36 and PConditional=2.36x10-8; region 4: rs2736098, P=3.87x10-12 and PConditional=5.19x10-6, region 5: rs13172201, P=0.041 and PConditional=2.04x10-6; and region 6: rs10069690, P=7.49x10-15 and PConditional=5.35x10-7) and one in the neighboring CLPTM1L gene (region 2: rs451360; P=1.90x10-18 and PConditional=7.06x10-16). Between three and five cancers mapped to each independent locus with both risk-enhancing and protective effects. Allele specific effects on DNA methylation were seen for a subset of risk loci indicating that methylation and subsequent effects on gene expression may contribute to the biology of risk variants on 5p15.33. Our results provide strong support for extensive pleiotropy across this region of 5p15.33, to an extent not previously observed in other cancer susceptibility loci. |
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