Interactions between folate intake and genetic predictors of gene expression levels associated with colorectal cancer risk

Cameron B. Haas; Yu Ru Su; Paneen Petersen; Xiaoliang Wang; Stephanie A. Bien; Yi Lin; Demetrius Albanes; Stephanie J. Weinstein; Mark A. Jenkins; Jane C. Figueiredo; Polly A. Newcomb; Graham Casey; Loic Le Marchand; Peter T. Campbell; Victor Moreno; John D. Potter; Lori C. Sakoda; Martha L. Slattery; Andrew T. Chan; Li Li; Graham G. Giles; Roger L. Milne; Stephen B. Gruber; Gad Rennert; Michael O. Woods; Steven J. Gallinger; Sonja Berndt; Richard B. Hayes; Wen Yi Huang; Alicja Wolk; Emily White; Hongmei Nan; Rami Nassir; Noralane M. Lindor; Juan P. Lewinger; Andre E. Kim; David Conti; W. James Gauderman; Daniel D. Buchanan; Ulrike Peters; Li Hsu

doi:10.1038/s41598-022-23451-y

Interactions between folate intake and genetic predictors of gene expression levels associated with colorectal cancer risk

Cameron B. Haas, Yu Ru Su, Paneen Petersen, Xiaoliang Wang, Stephanie A. Bien, Yi Lin, Demetrius Albanes, Stephanie J. Weinstein, Mark A. Jenkins, Jane C. Figueiredo, Polly A. Newcomb, Graham Casey, Loic Le Marchand, Peter T. Campbell, Victor Moreno, John D. Potter, Lori C. Sakoda, Martha L. Slattery, Andrew T. Chan, Li LiGraham G. Giles, Roger L. Milne, Stephen B. Gruber, Gad Rennert, Michael O. Woods, Steven J. Gallinger, Sonja Berndt, Richard B. Hayes, Wen Yi Huang, Alicja Wolk, Emily White, Hongmei Nan, Rami Nassir, Noralane M. Lindor, Juan P. Lewinger, Andre E. Kim, David Conti, W. James Gauderman, Daniel D. Buchanan, Ulrike Peters, Li Hsu

Research output: Contribution to journal › Article › peer-review

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Abstract

Observational studies have shown higher folate consumption to be associated with lower risk of colorectal cancer (CRC). Understanding whether and how genetic risk factors interact with folate could further elucidate the underlying mechanism. Aggregating functionally relevant genetic variants in set-based variant testing has higher power to detect gene–environment (G × E) interactions and may provide information on the underlying biological pathway. We investigated interactions between folate consumption and predicted gene expression on colorectal cancer risk across the genome. We used variant weights from the PrediXcan models of colon tissue-specific gene expression as a priori variant information for a set-based G × E approach. We harmonized total folate intake (mcg/day) based on dietary intake and supplemental use across cohort and case–control studies and calculated sex and study specific quantiles. Analyses were performed using a mixed effects score tests for interactions between folate and genetically predicted expression of 4839 genes with available genetically predicted expression. We pooled results across 23 studies for a total of 13,498 cases with colorectal tumors and 13,918 controls of European ancestry. We used a false discovery rate of 0.2 to identify genes with suggestive evidence of an interaction. We found suggestive evidence of interaction with folate intake on CRC risk for genes including glutathione S-Transferase Alpha 1 (GSTA1; p = 4.3E−4), Tonsuko Like, DNA Repair Protein (TONSL; p = 4.3E−4), and Aspartylglucosaminidase (AGA: p = 4.5E−4). We identified three genes involved in preventing or repairing DNA damage that may interact with folate consumption to alter CRC risk. Glutathione is an antioxidant, preventing cellular damage and is a downstream metabolite of homocysteine and metabolized by GSTA1. TONSL is part of a complex that functions in the recovery of double strand breaks and AGA plays a role in lysosomal breakdown of glycoprotein.

Original language	English (US)
Article number	18852
Journal	Scientific reports
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41598-022-23451-y
State	Published - Dec 2022
Externally published	Yes

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10.1038/s41598-022-23451-y

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Haas, C. B., Su, Y. R., Petersen, P., Wang, X., Bien, S. A., Lin, Y., Albanes, D., Weinstein, S. J., Jenkins, M. A., Figueiredo, J. C., Newcomb, P. A., Casey, G., Le Marchand, L., Campbell, P. T., Moreno, V., Potter, J. D., Sakoda, L. C., Slattery, M. L., Chan, A. T., ... Hsu, L. (2022). Interactions between folate intake and genetic predictors of gene expression levels associated with colorectal cancer risk. Scientific reports, 12(1), Article 18852. https://doi.org/10.1038/s41598-022-23451-y

Haas, CB, Su, YR, Petersen, P, Wang, X, Bien, SA, Lin, Y, Albanes, D, Weinstein, SJ, Jenkins, MA, Figueiredo, JC, Newcomb, PA, Casey, G, Le Marchand, L, Campbell, PT, Moreno, V, Potter, JD, Sakoda, LC, Slattery, ML, Chan, AT, Li, L, Giles, GG, Milne, RL, Gruber, SB, Rennert, G, Woods, MO, Gallinger, SJ, Berndt, S, Hayes, RB, Huang, WY, Wolk, A, White, E, Nan, H, Nassir, R, Lindor, NM, Lewinger, JP, Kim, AE, Conti, D, Gauderman, WJ, Buchanan, DD, Peters, U & Hsu, L 2022, 'Interactions between folate intake and genetic predictors of gene expression levels associated with colorectal cancer risk', Scientific reports, vol. 12, no. 1, 18852. https://doi.org/10.1038/s41598-022-23451-y

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title = "Interactions between folate intake and genetic predictors of gene expression levels associated with colorectal cancer risk",

abstract = "Observational studies have shown higher folate consumption to be associated with lower risk of colorectal cancer (CRC). Understanding whether and how genetic risk factors interact with folate could further elucidate the underlying mechanism. Aggregating functionally relevant genetic variants in set-based variant testing has higher power to detect gene–environment (G × E) interactions and may provide information on the underlying biological pathway. We investigated interactions between folate consumption and predicted gene expression on colorectal cancer risk across the genome. We used variant weights from the PrediXcan models of colon tissue-specific gene expression as a priori variant information for a set-based G × E approach. We harmonized total folate intake (mcg/day) based on dietary intake and supplemental use across cohort and case–control studies and calculated sex and study specific quantiles. Analyses were performed using a mixed effects score tests for interactions between folate and genetically predicted expression of 4839 genes with available genetically predicted expression. We pooled results across 23 studies for a total of 13,498 cases with colorectal tumors and 13,918 controls of European ancestry. We used a false discovery rate of 0.2 to identify genes with suggestive evidence of an interaction. We found suggestive evidence of interaction with folate intake on CRC risk for genes including glutathione S-Transferase Alpha 1 (GSTA1; p = 4.3E−4), Tonsuko Like, DNA Repair Protein (TONSL; p = 4.3E−4), and Aspartylglucosaminidase (AGA: p = 4.5E−4). We identified three genes involved in preventing or repairing DNA damage that may interact with folate consumption to alter CRC risk. Glutathione is an antioxidant, preventing cellular damage and is a downstream metabolite of homocysteine and metabolized by GSTA1. TONSL is part of a complex that functions in the recovery of double strand breaks and AGA plays a role in lysosomal breakdown of glycoprotein.",

author = "Haas, {Cameron B.} and Su, {Yu Ru} and Paneen Petersen and Xiaoliang Wang and Bien, {Stephanie A.} and Yi Lin and Demetrius Albanes and Weinstein, {Stephanie J.} and Jenkins, {Mark A.} and Figueiredo, {Jane C.} and Newcomb, {Polly A.} and Graham Casey and {Le Marchand}, Loic and Campbell, {Peter T.} and Victor Moreno and Potter, {John D.} and Sakoda, {Lori C.} and Slattery, {Martha L.} and Chan, {Andrew T.} and Li Li and Giles, {Graham G.} and Milne, {Roger L.} and Gruber, {Stephen B.} and Gad Rennert and Woods, {Michael O.} and Gallinger, {Steven J.} and Sonja Berndt and Hayes, {Richard B.} and Huang, {Wen Yi} and Alicja Wolk and Emily White and Hongmei Nan and Rami Nassir and Lindor, {Noralane M.} and Lewinger, {Juan P.} and Kim, {Andre E.} and David Conti and Gauderman, {W. James} and Buchanan, {Daniel D.} and Ulrike Peters and Li Hsu",

note = "Publisher Copyright: {\textcopyright} 2022, The Author(s).",

year = "2022",

month = dec,

doi = "10.1038/s41598-022-23451-y",

language = "English (US)",

volume = "12",

journal = "Scientific reports",

issn = "2045-2322",

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T1 - Interactions between folate intake and genetic predictors of gene expression levels associated with colorectal cancer risk

AU - Haas, Cameron B.

AU - Su, Yu Ru

AU - Petersen, Paneen

AU - Wang, Xiaoliang

AU - Bien, Stephanie A.

AU - Lin, Yi

AU - Albanes, Demetrius

AU - Weinstein, Stephanie J.

AU - Jenkins, Mark A.

AU - Figueiredo, Jane C.

AU - Newcomb, Polly A.

AU - Casey, Graham

AU - Le Marchand, Loic

AU - Campbell, Peter T.

AU - Moreno, Victor

AU - Potter, John D.

AU - Sakoda, Lori C.

AU - Slattery, Martha L.

AU - Chan, Andrew T.

AU - Li, Li

AU - Giles, Graham G.

AU - Milne, Roger L.

AU - Gruber, Stephen B.

AU - Rennert, Gad

AU - Woods, Michael O.

AU - Gallinger, Steven J.

AU - Berndt, Sonja

AU - Hayes, Richard B.

AU - Huang, Wen Yi

AU - Wolk, Alicja

AU - White, Emily

AU - Nan, Hongmei

AU - Nassir, Rami

AU - Lindor, Noralane M.

AU - Lewinger, Juan P.

AU - Kim, Andre E.

AU - Conti, David

AU - Gauderman, W. James

AU - Buchanan, Daniel D.

AU - Peters, Ulrike

AU - Hsu, Li

PY - 2022/12

Y1 - 2022/12

N2 - Observational studies have shown higher folate consumption to be associated with lower risk of colorectal cancer (CRC). Understanding whether and how genetic risk factors interact with folate could further elucidate the underlying mechanism. Aggregating functionally relevant genetic variants in set-based variant testing has higher power to detect gene–environment (G × E) interactions and may provide information on the underlying biological pathway. We investigated interactions between folate consumption and predicted gene expression on colorectal cancer risk across the genome. We used variant weights from the PrediXcan models of colon tissue-specific gene expression as a priori variant information for a set-based G × E approach. We harmonized total folate intake (mcg/day) based on dietary intake and supplemental use across cohort and case–control studies and calculated sex and study specific quantiles. Analyses were performed using a mixed effects score tests for interactions between folate and genetically predicted expression of 4839 genes with available genetically predicted expression. We pooled results across 23 studies for a total of 13,498 cases with colorectal tumors and 13,918 controls of European ancestry. We used a false discovery rate of 0.2 to identify genes with suggestive evidence of an interaction. We found suggestive evidence of interaction with folate intake on CRC risk for genes including glutathione S-Transferase Alpha 1 (GSTA1; p = 4.3E−4), Tonsuko Like, DNA Repair Protein (TONSL; p = 4.3E−4), and Aspartylglucosaminidase (AGA: p = 4.5E−4). We identified three genes involved in preventing or repairing DNA damage that may interact with folate consumption to alter CRC risk. Glutathione is an antioxidant, preventing cellular damage and is a downstream metabolite of homocysteine and metabolized by GSTA1. TONSL is part of a complex that functions in the recovery of double strand breaks and AGA plays a role in lysosomal breakdown of glycoprotein.

AB - Observational studies have shown higher folate consumption to be associated with lower risk of colorectal cancer (CRC). Understanding whether and how genetic risk factors interact with folate could further elucidate the underlying mechanism. Aggregating functionally relevant genetic variants in set-based variant testing has higher power to detect gene–environment (G × E) interactions and may provide information on the underlying biological pathway. We investigated interactions between folate consumption and predicted gene expression on colorectal cancer risk across the genome. We used variant weights from the PrediXcan models of colon tissue-specific gene expression as a priori variant information for a set-based G × E approach. We harmonized total folate intake (mcg/day) based on dietary intake and supplemental use across cohort and case–control studies and calculated sex and study specific quantiles. Analyses were performed using a mixed effects score tests for interactions between folate and genetically predicted expression of 4839 genes with available genetically predicted expression. We pooled results across 23 studies for a total of 13,498 cases with colorectal tumors and 13,918 controls of European ancestry. We used a false discovery rate of 0.2 to identify genes with suggestive evidence of an interaction. We found suggestive evidence of interaction with folate intake on CRC risk for genes including glutathione S-Transferase Alpha 1 (GSTA1; p = 4.3E−4), Tonsuko Like, DNA Repair Protein (TONSL; p = 4.3E−4), and Aspartylglucosaminidase (AGA: p = 4.5E−4). We identified three genes involved in preventing or repairing DNA damage that may interact with folate consumption to alter CRC risk. Glutathione is an antioxidant, preventing cellular damage and is a downstream metabolite of homocysteine and metabolized by GSTA1. TONSL is part of a complex that functions in the recovery of double strand breaks and AGA plays a role in lysosomal breakdown of glycoprotein.

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UR - http://www.scopus.com/inward/citedby.url?scp=85141394104&partnerID=8YFLogxK

U2 - 10.1038/s41598-022-23451-y

DO - 10.1038/s41598-022-23451-y

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AN - SCOPUS:85141394104

SN - 2045-2322

VL - 12

JO - Scientific reports

JF - Scientific reports

IS - 1

M1 - 18852

ER -

Interactions between folate intake and genetic predictors of gene expression levels associated with colorectal cancer risk

Abstract

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