Grant Details
| Grant Number: | 5R01CA273198-02 Interpret this number |
| Primary Investigator: | Peters, Ulrike |
| Organization: | Fred Hutchinson Cancer Center |
| Project Title: | An Integrative Omics Approach to Investigate Gene-Environment Interaction in Colorectal Cancer Risk |
| Fiscal Year: | 2024 |
Abstract
PROJECT SUMMARY/ABSTRACT Colorectal cancer (CRC) remains one of the leading causes of cancer-related deaths around the world. Many environmental risk factors and over 200 genetic risk variants have been identified for this complex, multifactorial disease. However, despite the strong biological rationale for the importance and abundance of gene-environment (GxE) interactions, the extent to which environmental risk factors (broadly defined here as lifestyle, diet, obesity, drug use and intermediate biomarkers) modulate genetic risk factors is poorly understood. To achieve the promise of precision prevention, we urgently need to gain a deeper understanding of GxE interactions in CRC risk. Understanding which modifiable risk factors modulate genetic risk, which is fixed, provides biological insights and actionable targets for new prevention intervention strategies. To accelerate the discovery of GxE interactions in CRC risk and to take an important next step towards translation, we propose a comprehensive innovative approach that combines single-cell multi-omics data, individual-level harmonized epidemiological and clinical data, and genome-wide data from large, well-characterized, diverse study populations, with novel computational and statistical approaches. Dramatic improvements in single-cell multimodal omics technologies, combined with new computational tools based on powerful deep-learning modeling approaches now allow us to predict the impact of genetic variants on gene regulation in a cell-type- specific holistic manner. Because simultaneously measured single-cell gene expression (scRNA-seq) and chromatin accessibility (scATAC-seq) data for normal colorectal mucosa tissue is lacking for racially and ethnically diverse samples with detailed assessment of environmental risk factors, we propose in Aim 1 to generate such data for 50 individuals. This resource, together with other single cell multi-omics compendia for colorectal tissue (like HTAN), will be leveraged to develop functional prediction scores for genetic variants across the genome. In Aim 2, we will use these functional prediction scores to boost statistical power for discovery of novel GxE interactions. We will perform genome-wide GxE scans in over 230,000 racially and ethnically diverse CRC cases and controls across key environmental risk factors, including obesity, diabetes, smoking, alcohol, drug use, dietary factors and intermediate biomarkers linked to metabolic dysregulation and chronic inflammation. To expand the number of key risk factors we can evaluate, we will utilize existing genetic instruments. In Aim 3, we will comprehensively characterize and translate GxE interactions. To do so, we will stratify GxE findings by clinical factors, including age of onset, racial and ethnic group, sex, and tumor subtypes. Additionally, we will incorporate GxE interactions and genetically predicted biomarkers in a comprehensive trans-ancestral risk prediction model to improve prediction and provide actionable information to reduce the burden of CRC. Our community advisors have stressed the importance of including the interplay between genetic and environmental risk factors in risk prediction modeling to enhance the acceptance of risk prediction models in the community.
Publications
Characterization of Additive Gene-environment Interactions For Colorectal Cancer Risk.
Authors: Thomas C.E. , Lin Y. , Kim M. , Kawaguchi E.S. , Qu C. , Um C.Y. , Lynch B.M. , Van Guelpen B. , Tsilidis K. , Carreras-Torres R. , et al. .
Source: Epidemiology (cambridge, Mass.), 2025-01-01 00:00:00.0; 36(1), p. 126-138.
EPub date: 2024-09-24 00:00:00.0.
PMID: 39316822
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Pathway Polygenic Risk Scores (pPRS) for the Analysis of Gene-environment Interaction.
Authors: Gauderman W.J. , Fu Y. , Queme B. , Kawaguchi E. , Wang Y. , Morrison J. , Brenner H. , Chan A. , Gruber S.B. , Keku T. , et al. .
Source: Biorxiv : The Preprint Server For Biology, 2024-12-19 00:00:00.0; , .
EPub date: 2024-12-19 00:00:00.0.
PMID: 39763728
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Plasma Ghrelin and Risks of Sex-Specific, Site-Specific, and Early-Onset Colorectal Cancer: A Mendelian Randomization Analysis.
Authors: Hazelwood E. , Lopez Manzano C. , Vincent E.E. , Albanes D. , Bishop D.T. , Le Marchand L. , Ulrich C.M. , Peters U. , Murphy G. , Samadder N.J. , et al. .
Source: Cancer Epidemiology, Biomarkers & Prevention : A Publication Of The American Association For Cancer Research, Cosponsored By The American Society Of Preventive Oncology, 2024-12-02 00:00:00.0; 33(12), p. 1727-1732.
PMID: 39361354
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Exploring the Chemopreventive Effect of Medication on Gene Expression Linked to Colorectal Cancer: An Observational and Mendelian Randomization Analysis in Healthy Colon Mucosa.
Authors: Moratalla-Navarro F. , Carreras-Torres R. , Díez-Obrero V. , Devall M. , Obón-Santacana M. , Díez-Villanueva A. , Guinó E. , Casey G. , Li L. , Moreno V. .
Source: International Journal Of Molecular Sciences, 2024-10-23 00:00:00.0; 25(21), .
EPub date: 2024-10-23 00:00:00.0.
PMID: 39518949
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Sex hormones and risk of lung and colorectal cancers in women: a Mendelian randomization study.
Authors: Denos M. , Sun Y.Q. , Brumpton B.M. , Li Y. , Albanes D. , Burnett-Hartman A. , Campbell P.T. , Küry S. , Li C.I. , White E. , et al. .
Source: Scientific Reports, 2024-10-12 00:00:00.0; 14(1), p. 23891.
EPub date: 2024-10-12 00:00:00.0.
PMID: 39396092
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Diet Impacts on Gene Expression in Healthy Colon Tissue: Insights from the BarcUVa-Seq Study.
Authors: Obón-Santacana M. , Moratalla-Navarro F. , Guinó E. , Carreras-Torres R. , Díez-Obrero V. , Bars-Cortina D. , Ibáñez-Sanz G. , Rodríguez-Alonso L. , Mata A. , García-Rodríguez A. , et al. .
Source: Nutrients, 2024-09-16 00:00:00.0; 16(18), .
EPub date: 2024-09-16 00:00:00.0.
PMID: 39339731
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Folate intake and colorectal cancer risk according to genetic subtypes defined by targeted tumor sequencing.
Authors: Aglago E.K. , Qu C. , Harlid S. , Phipps A.I. , Steinfelder R.S. , Ogino S. , Thomas C.E. , Hsu L. , Toland A.E. , Brenner H. , et al. .
Source: The American Journal Of Clinical Nutrition, 2024 Sep; 120(3), p. 664-673.
EPub date: 2024-07-16 00:00:00.0.
PMID: 39025327
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NON-ADDITIVE EFFECTS OF COMMON GENETIC VARIANTS HAVE A NEGLIGENT CONTRIBUTION TO CANCER HERITABILITY.
Authors: Hammermeister Suger A. , Harrison T.A. , Henning B. , Turman C. , Kraft P. , Lindström S. .
Source: Cancer Epidemiology, Biomarkers & Prevention : A Publication Of The American Association For Cancer Research, Cosponsored By The American Society Of Preventive Oncology, 2024-07-17 00:00:00.0; , .
EPub date: 2024-07-17 00:00:00.0.
PMID: 39018351
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Genome-wide interaction study of dietary intake of fibre, fruits, and vegetables with risk of colorectal cancer.
Authors: Papadimitriou N. , Kim A. , Kawaguchi E.S. , Morrison J. , Diez-Obrero V. , Albanes D. , Berndt S.I. , Bézieau S. , Bien S.A. , Bishop D.T. , et al. .
Source: Ebiomedicine, 2024 Jun; 104, p. 105146.
EPub date: 2024-05-14 00:00:00.0.
PMID: 38749303
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Two genome-wide interaction loci modify the association of nonsteroidal anti-inflammatory drugs with colorectal cancer.
Authors: Drew D.A. , Kim A.E. , Lin Y. , Qu C. , Morrison J. , Lewinger J.P. , Kawaguchi E. , Wang J. , Fu Y. , Zemlianskaia N. , et al. .
Source: Science Advances, 2024-05-31 00:00:00.0; 10(22), p. eadk3121.
EPub date: 2024-05-29 00:00:00.0.
PMID: 38809988
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Identification of potential mediators of the relationship between body mass index and colorectal cancer: a Mendelian randomization analysis.
Authors: Bouras E. , Gill D. , Zuber V. , Murphy N. , Dimou N. , Aleksandrova K. , Lewis S.J. , Martin R.M. , Yarmolinsky J. , Albanes D. , et al. .
Source: International Journal Of Epidemiology, 2024-04-11 00:00:00.0; 53(3), .
PMID: 38725300
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Genome-Wide Gene-Environment Interaction Analyses to Understand the Relationship between Red Meat and Processed Meat Intake and Colorectal Cancer Risk.
Authors: Stern M.C. , Sanchez Mendez J. , Kim A.E. , Obón-Santacana M. , Moratalla-Navarro F. , Martín V. , Moreno V. , Lin Y. , Bien S.A. , Qu C. , et al. .
Source: Cancer Epidemiology, Biomarkers & Prevention : A Publication Of The American Association For Cancer Research, Cosponsored By The American Society Of Preventive Oncology, 2024-03-01 00:00:00.0; 33(3), p. 400-410.
PMID: 38112776
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Body size and risk of colorectal cancer molecular defined subtypes and pathways: Mendelian randomization analyses.
Authors: Papadimitriou N. , Qu C. , Harrison T.A. , Bever A.M. , Martin R.M. , Tsilidis K.K. , Newcomb P.A. , Thibodeau S.N. , Newton C.C. , Um C.Y. , et al. .
Source: Ebiomedicine, 2024 Mar; 101, p. 105010.
EPub date: 2024-02-12 00:00:00.0.
PMID: 38350331
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Association between circulating inflammatory markers and adult cancer risk: a Mendelian randomization analysis.
Authors: Yarmolinsky J. , Robinson J.W. , Mariosa D. , Karhunen V. , Huang J. , Dimou N. , Murphy N. , Burrows K. , Bouras E. , Smith-Byrne K. , et al. .
Source: Ebiomedicine, 2024 Feb; 100, p. 104991.
EPub date: 2024-02-01 00:00:00.0.
PMID: 38301482
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Epidemiologic factors in relation to colorectal cancer risk and survival by genotoxic colibactin mutational signature.
Authors: Thomas C.E. , Georgeson P. , Qu C. , Steinfelder R.S. , Buchanan D.D. , Song M. , Harrison T.A. , Um C.Y. , Hullar M.A. , Jenkins M.A. , et al. .
Source: Cancer Epidemiology, Biomarkers & Prevention : A Publication Of The American Association For Cancer Research, Cosponsored By The American Society Of Preventive Oncology, 2024-01-22 00:00:00.0; , .
EPub date: 2024-01-22 00:00:00.0.
PMID: 38252034
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Calcium intake and genetic variants in the calcium sensing receptor in relation to colorectal cancer mortality: an international consortium study of 18,952 patients.
Authors: Wesselink E. , Gauderman W. , Berndt S.I. , Brenner H. , Buchanan D.D. , Campbell P.T. , Chan A.T. , Chang-Claude J. , Cotterchoi M. , Gunter M.J. , et al. .
Source: Bjc Reports, 2024; 2(1), p. 63.
EPub date: 2024-09-02 00:00:00.0.
PMID: 39233917
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Genome-wide interaction analysis of folate for colorectal cancer risk.
Authors: Bouras E. , Kim A.E. , Lin Y. , Morrison J. , Du M. , Albanes D. , Barry E.L. , Baurley J.W. , Berndt S.I. , Bien S.A. , et al. .
Source: The American Journal Of Clinical Nutrition, 2023 Nov; 118(5), p. 881-891.
EPub date: 2023-08-26 00:00:00.0.
PMID: 37640106
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Combining Asian and European genome-wide association studies of colorectal cancer improves risk prediction across racial and ethnic populations.
Authors: Thomas M. , Su Y.R. , Rosenthal E.A. , Sakoda L.C. , Schmit S.L. , Timofeeva M.N. , Chen Z. , Fernandez-Rozadilla C. , Law P.J. , Murphy N. , et al. .
Source: Nature Communications, 2023-10-02 00:00:00.0; 14(1), p. 6147.
EPub date: 2023-10-02 00:00:00.0.
PMID: 37783704
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Elucidating the Risk of Colorectal Cancer for Variants in Hereditary Colorectal Cancer Genes.
Authors: Mahmood K. , Thomas M. , Qu C. , Gecco-Ccfr Consortium , Hsu L. , Buchanan D.D. , Peters U. .
Source: Gastroenterology, 2023 Oct; 165(4), p. 1070-1076.e3.
EPub date: 2023-07-14 00:00:00.0.
PMID: 37453563
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