Pulmonary Function and Blood DNA Methylation A Multiancestry Epigenome-Wide Association Meta-analysis

Mikyeong Lee; Tianxiao Huan; Daniel L. McCartney; Geetha Chittoor; Maaike de Vries; Lies Lahousse; Jennifer N. Nguyen; Jennifer A. Brody; Juan Castillo-Fernandez; Natalie Terzikhan; Cancan Qi; Roby Joehanes; Josine L. Min; Gordon J. Smilnak; Jessica R. Shaw; Chen Xi Yang; Elena Colicino; Thanh T. Hoang; Mairead L. Bermingham; Hanfei Xu; Anne E. Justice; Cheng Jian Xu; Stephen S. Rich; Simon R. Cox; Judith M. Vonk; Ivana Prokic; Nona Sotoodehnia; Pei Chien Tsai; Joel D. Schwartz; Janice M. Leung; Sinjini Sikdar; Rosie M. Walker; Sarah E. Harris; Diana A. van der Plaat; David J. Van Den Berg; Traci M. Bartz; Tim D. Spector; Pantel S. Vokonas; Riccardo E. Marioni; Adele M. Taylor; Yongmei Liu; R. Graham Barr; Leslie A. Lange; Andrea A. Baccarelli; Maen Obeidat; Myriam Fornage; Tianyuan Wang; James M. Ward; Alison A. Motsinger-Reif; Gibran Hemani; Gerard H. Koppelman; Jordana T. Bell; Sina A. Gharib; Guy Brusselle; H. Marike Boezen; Kari E. North; Daniel Levy; Kathryn L. Evans; Josee Dupuis; Charles E. Breeze; Ani Manichaikul; Stephanie J. London

doi:10.1164/rccm.202108-1907OC

Pulmonary Function and Blood DNA Methylation A Multiancestry Epigenome-Wide Association Meta-analysis

Mikyeong Lee
, Tianxiao Huan
, Daniel L. McCartney
, Geetha Chittoor
, Maaike de Vries
, Lies Lahousse
, Jennifer N. Nguyen
, Jennifer A. Brody
, Juan Castillo-Fernandez
, Natalie Terzikhan
, Cancan Qi
, Roby Joehanes
, Josine L. Min
, Gordon J. Smilnak
, Jessica R. Shaw
, Chen Xi Yang
, Elena Colicino
, Thanh T. Hoang
, Mairead L. Bermingham
, Hanfei Xu

Anne E. Justice, Cheng Jian Xu, Stephen S. Rich, Simon R. Cox, Judith M. Vonk, Ivana Prokic, Nona Sotoodehnia, Pei Chien Tsai, Joel D. Schwartz, Janice M. Leung, Sinjini Sikdar, Rosie M. Walker, Sarah E. Harris, Diana A. van der Plaat, David J. Van Den Berg, Traci M. Bartz, Tim D. Spector, Pantel S. Vokonas, Riccardo E. Marioni, Adele M. Taylor, Yongmei Liu, R. Graham Barr, Leslie A. Lange, Andrea A. Baccarelli, Maen Obeidat, Myriam Fornage, Tianyuan Wang, James M. Ward, Alison A. Motsinger-Reif, Gibran Hemani, Gerard H. Koppelman, Jordana T. Bell, Sina A. Gharib, Guy Brusselle, H. Marike Boezen, Kari E. North, Daniel Levy, Kathryn L. Evans, Josee Dupuis, Charles E. Breeze, Ani Manichaikul, Stephanie J. London^*

^*Corresponding author for this work

Department of Biomedical Sciences (Master's Program in Clinical Trials Assessment)

Epidemiology Branch
University of Massachusetts Medical School
National Institutes of Health
Institute of Genetics and Cancer
Geisinger
University of North Carolina at Chapel Hill
University of Groningen
Ghent University
University of Virginia
University of Washington
King's College London
Department of Epidemiology
University of Bristol
University of Colorado Anschutz Medical Campus
University of British Columbia
Icahn School of Medicine at Mount Sinai
Boston University
Helmholtz Centre for Infection Research
Hannover Medical School
Radboud University Nijmegen
University of Edinburgh
Harvard University
Old Dominion University
Imperial College London
University of Southern California
Duke University
Columbia University
Colorado School of Public Health
University of Texas Health Science Center at Houston
Integrative Bioinformatics Support Group
Erasmus University Rotterdam
Altius Institute for Biomedical Sciences

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

25 Scopus citations

Abstract

Rationale: Methylation integrates factors present at birth and modifiable across the lifespan that can influence pulmonary function. Studies are limited in scope and replication. Objectives: To conduct large-scale epigenome-wide meta-analyses of blood DNA methylation and pulmonary function. Methods: Twelve cohorts analyzed associations of methylation at cytosine-phosphate-guanine probes (CpGs), using Illumina 450K or EPIC/850K arrays, with FEV₁, FVC, and FEV₁/FVC. We performed multiancestry epigenome-wide meta-analyses (total of 17,503 individuals; 14,761 European, 2,549 African, and 193 Hispanic/Latino ancestries) and interpreted results using integrative epigenomics. Measurements and Main Results: We identified 1,267 CpGs (1,042 genes) differentially methylated (false discovery rate,,0.025) in relation to FEV₁, FVC, or FEV₁/FVC, including 1,240 novel and 73 also related to chronic obstructive pulmonary disease (1,787 cases). We found 294 CpGs unique to European or African ancestry and 395 CpGs unique to never or ever smokers. The majority of significant CpGs correlated with nearby gene expression in blood. Findings were enriched in key regulatory elements for gene function, including accessible chromatin elements, in both blood and lung. Sixty-nine implicated genes are targets of investigational or approved drugs. One example novel gene highlighted by integrative epigenomic and druggable target analysis is TNFRSF4. Mendelian randomization and colocalization analyses suggest that epigenome-wide association study signals capture causal regulatory genomic loci. Conclusions: We identified numerous novel loci differentially methylated in relation to pulmonary function; few were detected in large genome-wide association studies. Integrative analyses highlight functional relevance and potential therapeutic targets. This comprehensive discovery of potentially modifiable, novel lung function loci expands knowledge gained from genetic studies, providing insights into lung pathogenesis.

Original language	English
Pages (from-to)	321-336
Number of pages	16
Journal	American Journal of Respiratory and Critical Care Medicine
Volume	206
Issue number	3
DOIs	https://doi.org/10.1164/rccm.202108-1907OC
State	Published - 01 08 2022

Bibliographical note

Publisher Copyright:
© 2022 by the American Thoracic Society.

Keywords

chronic obstructive pulmonary disease
epigenetics
respiratory function tests
spirometry

Access to Document

10.1164/rccm.202108-1907OC

Cite this

Lee, M., Huan, T., McCartney, D. L., Chittoor, G., de Vries, M., Lahousse, L., Nguyen, J. N., Brody, J. A., Castillo-Fernandez, J., Terzikhan, N., Qi, C., Joehanes, R., Min, J. L., Smilnak, G. J., Shaw, J. R., Yang, C. X., Colicino, E., Hoang, T. T., Bermingham, M. L., ... London, S. J. (2022). Pulmonary Function and Blood DNA Methylation A Multiancestry Epigenome-Wide Association Meta-analysis. American Journal of Respiratory and Critical Care Medicine, 206(3), 321-336. https://doi.org/10.1164/rccm.202108-1907OC

@article{b2791c9285534980926e2109569b5347,

title = "Pulmonary Function and Blood DNA Methylation A Multiancestry Epigenome-Wide Association Meta-analysis",

abstract = "Rationale: Methylation integrates factors present at birth and modifiable across the lifespan that can influence pulmonary function. Studies are limited in scope and replication. Objectives: To conduct large-scale epigenome-wide meta-analyses of blood DNA methylation and pulmonary function. Methods: Twelve cohorts analyzed associations of methylation at cytosine-phosphate-guanine probes (CpGs), using Illumina 450K or EPIC/850K arrays, with FEV1, FVC, and FEV1/FVC. We performed multiancestry epigenome-wide meta-analyses (total of 17,503 individuals; 14,761 European, 2,549 African, and 193 Hispanic/Latino ancestries) and interpreted results using integrative epigenomics. Measurements and Main Results: We identified 1,267 CpGs (1,042 genes) differentially methylated (false discovery rate,,0.025) in relation to FEV1, FVC, or FEV1/FVC, including 1,240 novel and 73 also related to chronic obstructive pulmonary disease (1,787 cases). We found 294 CpGs unique to European or African ancestry and 395 CpGs unique to never or ever smokers. The majority of significant CpGs correlated with nearby gene expression in blood. Findings were enriched in key regulatory elements for gene function, including accessible chromatin elements, in both blood and lung. Sixty-nine implicated genes are targets of investigational or approved drugs. One example novel gene highlighted by integrative epigenomic and druggable target analysis is TNFRSF4. Mendelian randomization and colocalization analyses suggest that epigenome-wide association study signals capture causal regulatory genomic loci. Conclusions: We identified numerous novel loci differentially methylated in relation to pulmonary function; few were detected in large genome-wide association studies. Integrative analyses highlight functional relevance and potential therapeutic targets. This comprehensive discovery of potentially modifiable, novel lung function loci expands knowledge gained from genetic studies, providing insights into lung pathogenesis.",

keywords = "chronic obstructive pulmonary disease, epigenetics, respiratory function tests, spirometry",

author = "Mikyeong Lee and Tianxiao Huan and McCartney, \{Daniel L.\} and Geetha Chittoor and \{de Vries\}, Maaike and Lies Lahousse and Nguyen, \{Jennifer N.\} and Brody, \{Jennifer A.\} and Juan Castillo-Fernandez and Natalie Terzikhan and Cancan Qi and Roby Joehanes and Min, \{Josine L.\} and Smilnak, \{Gordon J.\} and Shaw, \{Jessica R.\} and Yang, \{Chen Xi\} and Elena Colicino and Hoang, \{Thanh T.\} and Bermingham, \{Mairead L.\} and Hanfei Xu and Justice, \{Anne E.\} and Xu, \{Cheng Jian\} and Rich, \{Stephen S.\} and Cox, \{Simon R.\} and Vonk, \{Judith M.\} and Ivana Prokic and Nona Sotoodehnia and Tsai, \{Pei Chien\} and Schwartz, \{Joel D.\} and Leung, \{Janice M.\} and Sinjini Sikdar and Walker, \{Rosie M.\} and Harris, \{Sarah E.\} and \{van der Plaat\}, \{Diana A.\} and \{Van Den Berg\}, \{David J.\} and Bartz, \{Traci M.\} and Spector, \{Tim D.\} and Vokonas, \{Pantel S.\} and Marioni, \{Riccardo E.\} and Taylor, \{Adele M.\} and Yongmei Liu and Barr, \{R. Graham\} and Lange, \{Leslie A.\} and Baccarelli, \{Andrea A.\} and Maen Obeidat and Myriam Fornage and Tianyuan Wang and Ward, \{James M.\} and Motsinger-Reif, \{Alison A.\} and Gibran Hemani and Koppelman, \{Gerard H.\} and Bell, \{Jordana T.\} and Gharib, \{Sina A.\} and Guy Brusselle and Boezen, \{H. Marike\} and North, \{Kari E.\} and Daniel Levy and Evans, \{Kathryn L.\} and Josee Dupuis and Breeze, \{Charles E.\} and Ani Manichaikul and London, \{Stephanie J.\}",

note = "Publisher Copyright: {\textcopyright} 2022 by the American Thoracic Society.",

year = "2022",

month = aug,

day = "1",

doi = "10.1164/rccm.202108-1907OC",

language = "英语",

volume = "206",

pages = "321--336",

journal = "American Journal of Respiratory and Critical Care Medicine",

issn = "1073-449X",

publisher = "American Thoracic Society",

number = "3",

}

Lee, M, Huan, T, McCartney, DL, Chittoor, G, de Vries, M, Lahousse, L, Nguyen, JN, Brody, JA, Castillo-Fernandez, J, Terzikhan, N, Qi, C, Joehanes, R, Min, JL, Smilnak, GJ, Shaw, JR, Yang, CX, Colicino, E, Hoang, TT, Bermingham, ML, Xu, H, Justice, AE, Xu, CJ, Rich, SS, Cox, SR, Vonk, JM, Prokic, I, Sotoodehnia, N, Tsai, PC, Schwartz, JD, Leung, JM, Sikdar, S, Walker, RM, Harris, SE, van der Plaat, DA, Van Den Berg, DJ, Bartz, TM, Spector, TD, Vokonas, PS, Marioni, RE, Taylor, AM, Liu, Y, Barr, RG, Lange, LA, Baccarelli, AA, Obeidat, M, Fornage, M, Wang, T, Ward, JM, Motsinger-Reif, AA, Hemani, G, Koppelman, GH, Bell, JT, Gharib, SA, Brusselle, G, Boezen, HM, North, KE, Levy, D, Evans, KL, Dupuis, J, Breeze, CE, Manichaikul, A & London, SJ 2022, 'Pulmonary Function and Blood DNA Methylation A Multiancestry Epigenome-Wide Association Meta-analysis', American Journal of Respiratory and Critical Care Medicine, vol. 206, no. 3, pp. 321-336. https://doi.org/10.1164/rccm.202108-1907OC

TY - JOUR

T1 - Pulmonary Function and Blood DNA Methylation A Multiancestry Epigenome-Wide Association Meta-analysis

AU - Lee, Mikyeong

AU - Huan, Tianxiao

AU - McCartney, Daniel L.

AU - Chittoor, Geetha

AU - de Vries, Maaike

AU - Lahousse, Lies

AU - Nguyen, Jennifer N.

AU - Brody, Jennifer A.

AU - Castillo-Fernandez, Juan

AU - Terzikhan, Natalie

AU - Qi, Cancan

AU - Joehanes, Roby

AU - Min, Josine L.

AU - Smilnak, Gordon J.

AU - Shaw, Jessica R.

AU - Yang, Chen Xi

AU - Colicino, Elena

AU - Hoang, Thanh T.

AU - Bermingham, Mairead L.

AU - Xu, Hanfei

AU - Justice, Anne E.

AU - Xu, Cheng Jian

AU - Rich, Stephen S.

AU - Cox, Simon R.

AU - Vonk, Judith M.

AU - Prokic, Ivana

AU - Sotoodehnia, Nona

AU - Tsai, Pei Chien

AU - Schwartz, Joel D.

AU - Leung, Janice M.

AU - Sikdar, Sinjini

AU - Walker, Rosie M.

AU - Harris, Sarah E.

AU - van der Plaat, Diana A.

AU - Van Den Berg, David J.

AU - Bartz, Traci M.

AU - Spector, Tim D.

AU - Vokonas, Pantel S.

AU - Marioni, Riccardo E.

AU - Taylor, Adele M.

AU - Liu, Yongmei

AU - Barr, R. Graham

AU - Lange, Leslie A.

AU - Baccarelli, Andrea A.

AU - Obeidat, Maen

AU - Fornage, Myriam

AU - Wang, Tianyuan

AU - Ward, James M.

AU - Motsinger-Reif, Alison A.

AU - Hemani, Gibran

AU - Koppelman, Gerard H.

AU - Bell, Jordana T.

AU - Gharib, Sina A.

AU - Brusselle, Guy

AU - Boezen, H. Marike

AU - North, Kari E.

AU - Levy, Daniel

AU - Evans, Kathryn L.

AU - Dupuis, Josee

AU - Breeze, Charles E.

AU - Manichaikul, Ani

AU - London, Stephanie J.

PY - 2022/8/1

Y1 - 2022/8/1

N2 - Rationale: Methylation integrates factors present at birth and modifiable across the lifespan that can influence pulmonary function. Studies are limited in scope and replication. Objectives: To conduct large-scale epigenome-wide meta-analyses of blood DNA methylation and pulmonary function. Methods: Twelve cohorts analyzed associations of methylation at cytosine-phosphate-guanine probes (CpGs), using Illumina 450K or EPIC/850K arrays, with FEV1, FVC, and FEV1/FVC. We performed multiancestry epigenome-wide meta-analyses (total of 17,503 individuals; 14,761 European, 2,549 African, and 193 Hispanic/Latino ancestries) and interpreted results using integrative epigenomics. Measurements and Main Results: We identified 1,267 CpGs (1,042 genes) differentially methylated (false discovery rate,,0.025) in relation to FEV1, FVC, or FEV1/FVC, including 1,240 novel and 73 also related to chronic obstructive pulmonary disease (1,787 cases). We found 294 CpGs unique to European or African ancestry and 395 CpGs unique to never or ever smokers. The majority of significant CpGs correlated with nearby gene expression in blood. Findings were enriched in key regulatory elements for gene function, including accessible chromatin elements, in both blood and lung. Sixty-nine implicated genes are targets of investigational or approved drugs. One example novel gene highlighted by integrative epigenomic and druggable target analysis is TNFRSF4. Mendelian randomization and colocalization analyses suggest that epigenome-wide association study signals capture causal regulatory genomic loci. Conclusions: We identified numerous novel loci differentially methylated in relation to pulmonary function; few were detected in large genome-wide association studies. Integrative analyses highlight functional relevance and potential therapeutic targets. This comprehensive discovery of potentially modifiable, novel lung function loci expands knowledge gained from genetic studies, providing insights into lung pathogenesis.

AB - Rationale: Methylation integrates factors present at birth and modifiable across the lifespan that can influence pulmonary function. Studies are limited in scope and replication. Objectives: To conduct large-scale epigenome-wide meta-analyses of blood DNA methylation and pulmonary function. Methods: Twelve cohorts analyzed associations of methylation at cytosine-phosphate-guanine probes (CpGs), using Illumina 450K or EPIC/850K arrays, with FEV1, FVC, and FEV1/FVC. We performed multiancestry epigenome-wide meta-analyses (total of 17,503 individuals; 14,761 European, 2,549 African, and 193 Hispanic/Latino ancestries) and interpreted results using integrative epigenomics. Measurements and Main Results: We identified 1,267 CpGs (1,042 genes) differentially methylated (false discovery rate,,0.025) in relation to FEV1, FVC, or FEV1/FVC, including 1,240 novel and 73 also related to chronic obstructive pulmonary disease (1,787 cases). We found 294 CpGs unique to European or African ancestry and 395 CpGs unique to never or ever smokers. The majority of significant CpGs correlated with nearby gene expression in blood. Findings were enriched in key regulatory elements for gene function, including accessible chromatin elements, in both blood and lung. Sixty-nine implicated genes are targets of investigational or approved drugs. One example novel gene highlighted by integrative epigenomic and druggable target analysis is TNFRSF4. Mendelian randomization and colocalization analyses suggest that epigenome-wide association study signals capture causal regulatory genomic loci. Conclusions: We identified numerous novel loci differentially methylated in relation to pulmonary function; few were detected in large genome-wide association studies. Integrative analyses highlight functional relevance and potential therapeutic targets. This comprehensive discovery of potentially modifiable, novel lung function loci expands knowledge gained from genetic studies, providing insights into lung pathogenesis.

KW - chronic obstructive pulmonary disease

KW - epigenetics

KW - respiratory function tests

KW - spirometry

UR - https://www.scopus.com/pages/publications/85135398333

U2 - 10.1164/rccm.202108-1907OC

DO - 10.1164/rccm.202108-1907OC

M3 - 文章

C2 - 35536696

AN - SCOPUS:85135398333

SN - 1073-449X

VL - 206

SP - 321

EP - 336

JO - American Journal of Respiratory and Critical Care Medicine

JF - American Journal of Respiratory and Critical Care Medicine

IS - 3

ER -

Pulmonary Function and Blood DNA Methylation A Multiancestry Epigenome-Wide Association Meta-analysis

Abstract

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Keywords

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