Protein prediction for trait mapping in diverse populations

Heather Wheeler; Ryan Schubert; Elyse Geoffroy; Isabelle Gregga; Ashley J Mulford; Francois Aguet; Kristin Ardlie; Robert Gerszten; Clary B. Clish; David van den Berg; Kent D Taylor; Peter Durda; W. Craig Johnson; Elaine Cornell; Xiuqing Guo; Yongmei Liu; Tracy Russell; Matthew Conomos; Tommy Dawain Blackwell; George J. Papanicolaou; Tuuli Lappalainen; Anna Mikhaylova; Michael Cho; Christopher Gignoux,; Leslie Lange; Ethan Lange; Stephen S. Rich; Jerome I. Rotter; Manichaikul A; Hae Kyung Im

doi:10.1371/journal.pone.0264341

Protein prediction for trait mapping in diverse populations

Heather Wheeler, Ryan Schubert, Elyse Geoffroy, Isabelle Gregga, Ashley J Mulford, Francois Aguet, Kristin Ardlie, Robert Gerszten, Clary B. Clish, David van den Berg, Kent D Taylor, Peter Durda, W. Craig Johnson, Elaine Cornell, Xiuqing Guo, Yongmei Liu, Tracy Russell, Matthew Conomos, Tommy Dawain Blackwell, George J. PapanicolaouTuuli Lappalainen, Anna Mikhaylova, Michael Cho, Christopher Gignoux,, Leslie Lange, Ethan Lange, Stephen S. Rich, Jerome I. Rotter, Manichaikul A, Hae Kyung Im

Department of Biology

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

Abstract

Genetically regulated gene expression has helped elucidate the biological mechanisms underlying complex traits. Improved high-throughput technology allows similar interrogation of the genetically regulated proteome for understanding complex trait mechanisms. Here, we used the Trans-omics for Precision Medicine (TOPMed) Multi-omics pilot study, which comprises data from Multi-Ethnic Study of Atherosclerosis (MESA), to optimize genetic predictors of the plasma proteome for genetically regulated proteome-wide association studies (PWAS) in diverse populations. We built predictive models for protein abundances using data collected in TOPMed MESA, for which we have measured 1,305 proteins by a SOMAscan assay. We compared predictive models built via elastic net regression to models integrating posterior inclusion probabilities estimated by fine-mapping SNPs prior to elastic net. In order to investigate the transferability of predictive models across ancestries, we built protein prediction models in all four of the TOPMed MESA populations, African American (n = 183), Chinese (n = 71), European (n = 416), and Hispanic/Latino (n = 301), as well as in all populations combined. As expected, fine-mapping produced more significant protein prediction models, especially in African ancestries populations, potentially increasing opportunity for discovery. When we tested our TOPMed MESA models in the independent European INTERVAL study, fine-mapping improved cross-ancestries prediction for some proteins. Using GWAS summary statistics from the Population Architecture using Genomics and Epidemiology (PAGE) study, which comprises ∼50,000 Hispanic/Latinos, African Americans, Asians, Native Hawaiians, and Native Americans, we applied S-PrediXcan to perform PWAS for 28 complex traits. The most protein-trait associations were discovered, colocalized, and replicated in large independent GWAS using proteome prediction model training populations with similar ancestries to PAGE. At current training population sample sizes, performance between baseline and fine-mapped protein prediction models in PWAS was similar, highlighting the utility of elastic net

Original language	American English
Journal	PLOS ONE
DOIs	https://doi.org/10.1371/journal.pone.0264341
State	Published - Feb 24 2022

Disciplines

Biology

Access to Document

10.1371/journal.pone.0264341License: Unspecified

Cite this

Wheeler, H., Schubert, R., Geoffroy, E., Gregga, I., Mulford, A. J., Aguet, F., Ardlie, K., Gerszten, R., Clish, C. B., van den Berg, D., Taylor, K. D., Durda, P., Johnson, W. C., Cornell, E., Guo, X., Liu, Y., Russell, T., Conomos, M., Blackwell, T. D., ... Im, H. K. (2022). Protein prediction for trait mapping in diverse populations. PLOS ONE. https://doi.org/10.1371/journal.pone.0264341

Wheeler, H, Schubert, R, Geoffroy, E, Gregga, I, Mulford, AJ, Aguet, F, Ardlie, K, Gerszten, R, Clish, CB, van den Berg, D, Taylor, KD, Durda, P, Johnson, WC, Cornell, E, Guo, X, Liu, Y, Russell, T, Conomos, M, Blackwell, TD, Papanicolaou, GJ, Lappalainen, T, Mikhaylova, A, Cho, M, Gignoux, C, Lange, L, Lange, E, Rich, SS, Rotter, JI, A, M & Im, HK 2022, 'Protein prediction for trait mapping in diverse populations', PLOS ONE. https://doi.org/10.1371/journal.pone.0264341

@article{06b684601d0f498fab4cc422bafb7f42,

title = "Protein prediction for trait mapping in diverse populations",

abstract = " Genetically regulated gene expression has helped elucidate the biological mechanisms underlying complex traits. Improved high-throughput technology allows similar interrogation of the genetically regulated proteome for understanding complex trait mechanisms. Here, we used the Trans-omics for Precision Medicine (TOPMed) Multi-omics pilot study, which comprises data from Multi-Ethnic Study of Atherosclerosis (MESA), to optimize genetic predictors of the plasma proteome for genetically regulated proteome-wide association studies (PWAS) in diverse populations. We built predictive models for protein abundances using data collected in TOPMed MESA, for which we have measured 1,305 proteins by a SOMAscan assay. We compared predictive models built via elastic net regression to models integrating posterior inclusion probabilities estimated by fine-mapping SNPs prior to elastic net. In order to investigate the transferability of predictive models across ancestries, we built protein prediction models in all four of the TOPMed MESA populations, African American (n = 183), Chinese (n = 71), European (n = 416), and Hispanic/Latino (n = 301), as well as in all populations combined. As expected, fine-mapping produced more significant protein prediction models, especially in African ancestries populations, potentially increasing opportunity for discovery. When we tested our TOPMed MESA models in the independent European INTERVAL study, fine-mapping improved cross-ancestries prediction for some proteins. Using GWAS summary statistics from the Population Architecture using Genomics and Epidemiology (PAGE) study, which comprises ∼50,000 Hispanic/Latinos, African Americans, Asians, Native Hawaiians, and Native Americans, we applied S-PrediXcan to perform PWAS for 28 complex traits. The most protein-trait associations were discovered, colocalized, and replicated in large independent GWAS using proteome prediction model training populations with similar ancestries to PAGE. At current training population sample sizes, performance between baseline and fine-mapped protein prediction models in PWAS was similar, highlighting the utility of elastic net ",

author = "Heather Wheeler and Ryan Schubert and Elyse Geoffroy and Isabelle Gregga and Mulford, {Ashley J} and Francois Aguet and Kristin Ardlie and Robert Gerszten and Clish, {Clary B.} and {van den Berg}, David and Taylor, {Kent D} and Peter Durda and Johnson, {W. Craig} and Elaine Cornell and Xiuqing Guo and Yongmei Liu and Tracy Russell and Matthew Conomos and Blackwell, {Tommy Dawain} and Papanicolaou, {George J.} and Tuuli Lappalainen and Anna Mikhaylova and Michael Cho and Christopher Gignoux, and Leslie Lange and Ethan Lange and Rich, {Stephen S.} and Rotter, {Jerome I.} and Manichaikul A and Im, {Hae Kyung}",

year = "2022",

month = feb,

day = "24",

doi = "10.1371/journal.pone.0264341",

language = "American English",

journal = "PLOS ONE",

issn = "1932-6203",

}

TY - JOUR

T1 - Protein prediction for trait mapping in diverse populations

AU - Wheeler, Heather

AU - Schubert, Ryan

AU - Geoffroy, Elyse

AU - Gregga, Isabelle

AU - Mulford, Ashley J

AU - Aguet, Francois

AU - Ardlie, Kristin

AU - Gerszten, Robert

AU - Clish, Clary B.

AU - van den Berg, David

AU - Taylor, Kent D

AU - Durda, Peter

AU - Johnson, W. Craig

AU - Cornell, Elaine

AU - Guo, Xiuqing

AU - Liu, Yongmei

AU - Russell, Tracy

AU - Conomos, Matthew

AU - Blackwell, Tommy Dawain

AU - Papanicolaou, George J.

AU - Lappalainen, Tuuli

AU - Mikhaylova, Anna

AU - Cho, Michael

AU - Gignoux,, Christopher

AU - Lange, Leslie

AU - Lange, Ethan

AU - Rich, Stephen S.

AU - Rotter, Jerome I.

AU - A, Manichaikul

AU - Im, Hae Kyung

PY - 2022/2/24

Y1 - 2022/2/24

N2 - Genetically regulated gene expression has helped elucidate the biological mechanisms underlying complex traits. Improved high-throughput technology allows similar interrogation of the genetically regulated proteome for understanding complex trait mechanisms. Here, we used the Trans-omics for Precision Medicine (TOPMed) Multi-omics pilot study, which comprises data from Multi-Ethnic Study of Atherosclerosis (MESA), to optimize genetic predictors of the plasma proteome for genetically regulated proteome-wide association studies (PWAS) in diverse populations. We built predictive models for protein abundances using data collected in TOPMed MESA, for which we have measured 1,305 proteins by a SOMAscan assay. We compared predictive models built via elastic net regression to models integrating posterior inclusion probabilities estimated by fine-mapping SNPs prior to elastic net. In order to investigate the transferability of predictive models across ancestries, we built protein prediction models in all four of the TOPMed MESA populations, African American (n = 183), Chinese (n = 71), European (n = 416), and Hispanic/Latino (n = 301), as well as in all populations combined. As expected, fine-mapping produced more significant protein prediction models, especially in African ancestries populations, potentially increasing opportunity for discovery. When we tested our TOPMed MESA models in the independent European INTERVAL study, fine-mapping improved cross-ancestries prediction for some proteins. Using GWAS summary statistics from the Population Architecture using Genomics and Epidemiology (PAGE) study, which comprises ∼50,000 Hispanic/Latinos, African Americans, Asians, Native Hawaiians, and Native Americans, we applied S-PrediXcan to perform PWAS for 28 complex traits. The most protein-trait associations were discovered, colocalized, and replicated in large independent GWAS using proteome prediction model training populations with similar ancestries to PAGE. At current training population sample sizes, performance between baseline and fine-mapped protein prediction models in PWAS was similar, highlighting the utility of elastic net

AB - Genetically regulated gene expression has helped elucidate the biological mechanisms underlying complex traits. Improved high-throughput technology allows similar interrogation of the genetically regulated proteome for understanding complex trait mechanisms. Here, we used the Trans-omics for Precision Medicine (TOPMed) Multi-omics pilot study, which comprises data from Multi-Ethnic Study of Atherosclerosis (MESA), to optimize genetic predictors of the plasma proteome for genetically regulated proteome-wide association studies (PWAS) in diverse populations. We built predictive models for protein abundances using data collected in TOPMed MESA, for which we have measured 1,305 proteins by a SOMAscan assay. We compared predictive models built via elastic net regression to models integrating posterior inclusion probabilities estimated by fine-mapping SNPs prior to elastic net. In order to investigate the transferability of predictive models across ancestries, we built protein prediction models in all four of the TOPMed MESA populations, African American (n = 183), Chinese (n = 71), European (n = 416), and Hispanic/Latino (n = 301), as well as in all populations combined. As expected, fine-mapping produced more significant protein prediction models, especially in African ancestries populations, potentially increasing opportunity for discovery. When we tested our TOPMed MESA models in the independent European INTERVAL study, fine-mapping improved cross-ancestries prediction for some proteins. Using GWAS summary statistics from the Population Architecture using Genomics and Epidemiology (PAGE) study, which comprises ∼50,000 Hispanic/Latinos, African Americans, Asians, Native Hawaiians, and Native Americans, we applied S-PrediXcan to perform PWAS for 28 complex traits. The most protein-trait associations were discovered, colocalized, and replicated in large independent GWAS using proteome prediction model training populations with similar ancestries to PAGE. At current training population sample sizes, performance between baseline and fine-mapped protein prediction models in PWAS was similar, highlighting the utility of elastic net

U2 - 10.1371/journal.pone.0264341

DO - 10.1371/journal.pone.0264341

M3 - Article

SN - 1932-6203

JO - PLOS ONE

JF - PLOS ONE

ER -