Genomic atlas of the human plasma proteome

Benjamin B. Sun; Joseph C. Maranville; James E. Peters; David Stacey; James R. Staley; James Blackshaw; Stephen Burgess; Tao Jiang; Ellie Paige; Praveen Surendran; Clare Oliver-Williams; Mihir A. Kamat; Bram P. Prins; Sheri K. Wilcox; Erik S. Zimmerman; An Chi; Narinder Bansal; Sarah L. Spain; Angela M. Wood; Nicholas W. Morrell; John R. Bradley; Nebojsa Janjic; David J. Roberts; Willem H. Ouwehand; John A. Todd; Nicole Soranzo; Karsten Suhre; Dirk S. Paul; Caroline S. Fox; Robert M. Plenge; John Danesh; Heiko Runz; Adam S. Butterworth

doi:10.1038/s41586-018-0175-2

Genomic atlas of the human plasma proteome

Benjamin B. Sun, Joseph C. Maranville, James E. Peters, David Stacey, James R. Staley, James Blackshaw, Stephen Burgess, Tao Jiang, Ellie Paige, Praveen Surendran, Clare Oliver-Williams, Mihir A. Kamat, Bram P. Prins, Sheri K. Wilcox, Erik S. Zimmerman, An Chi, Narinder Bansal, Sarah L. Spain, Angela M. Wood, Nicholas W. MorrellJohn R. Bradley, Nebojsa Janjic, David J. Roberts, Willem H. Ouwehand, John A. Todd, Nicole Soranzo, Karsten Suhre, Dirk S. Paul, Caroline S. Fox, Robert M. Plenge, John Danesh, Heiko Runz, Adam S. Butterworth

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Abstract

Although plasma proteins have important roles in biological processes and are the direct targets of many drugs, the genetic factors that control inter-individual variation in plasma protein levels are not well understood. Here we characterize the genetic architecture of the human plasma proteome in healthy blood donors from the INTERVAL study. We identify 1,927 genetic associations with 1,478 proteins, a fourfold increase on existing knowledge, including trans associations for 1,104 proteins. To understand the consequences of perturbations in plasma protein levels, we apply an integrated approach that links genetic variation with biological pathway, disease, and drug databases. We show that protein quantitative trait loci overlap with gene expression quantitative trait loci, as well as with disease-associated loci, and find evidence that protein biomarkers have causal roles in disease using Mendelian randomization analysis. By linking genetic factors to diseases via specific proteins, our analyses highlight potential therapeutic targets, opportunities for matching existing drugs with new disease indications, and potential safety concerns for drugs under development.

Original language	English
Pages (from-to)	73-79
Number of pages	7
Journal	Nature
Volume	558
Issue number	7708
DOIs	https://doi.org/10.1038/s41586-018-0175-2
Publication status	Published - 7 Jun 2018

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Sun, B. B., Maranville, J. C., Peters, J. E., Stacey, D., Staley, J. R., Blackshaw, J., Burgess, S., Jiang, T., Paige, E., Surendran, P., Oliver-Williams, C., Kamat, M. A., Prins, B. P., Wilcox, S. K., Zimmerman, E. S., Chi, A., Bansal, N., Spain, S. L., Wood, A. M., ... Butterworth, A. S. (2018). Genomic atlas of the human plasma proteome. Nature, 558(7708), 73-79. https://doi.org/10.1038/s41586-018-0175-2

@article{a285b148112f4f6c87f056374c3199d2,

title = "Genomic atlas of the human plasma proteome",

abstract = "Although plasma proteins have important roles in biological processes and are the direct targets of many drugs, the genetic factors that control inter-individual variation in plasma protein levels are not well understood. Here we characterize the genetic architecture of the human plasma proteome in healthy blood donors from the INTERVAL study. We identify 1,927 genetic associations with 1,478 proteins, a fourfold increase on existing knowledge, including trans associations for 1,104 proteins. To understand the consequences of perturbations in plasma protein levels, we apply an integrated approach that links genetic variation with biological pathway, disease, and drug databases. We show that protein quantitative trait loci overlap with gene expression quantitative trait loci, as well as with disease-associated loci, and find evidence that protein biomarkers have causal roles in disease using Mendelian randomization analysis. By linking genetic factors to diseases via specific proteins, our analyses highlight potential therapeutic targets, opportunities for matching existing drugs with new disease indications, and potential safety concerns for drugs under development.",

author = "Sun, {Benjamin B.} and Maranville, {Joseph C.} and Peters, {James E.} and David Stacey and Staley, {James R.} and James Blackshaw and Stephen Burgess and Tao Jiang and Ellie Paige and Praveen Surendran and Clare Oliver-Williams and Kamat, {Mihir A.} and Prins, {Bram P.} and Wilcox, {Sheri K.} and Zimmerman, {Erik S.} and An Chi and Narinder Bansal and Spain, {Sarah L.} and Wood, {Angela M.} and Morrell, {Nicholas W.} and Bradley, {John R.} and Nebojsa Janjic and Roberts, {David J.} and Ouwehand, {Willem H.} and Todd, {John A.} and Nicole Soranzo and Karsten Suhre and Paul, {Dirk S.} and Fox, {Caroline S.} and Plenge, {Robert M.} and John Danesh and Heiko Runz and Butterworth, {Adam S.}",

note = "Publisher Copyright: {\textcopyright} 2018 Macmillan Publishers Ltd., part of Springer Nature.",

year = "2018",

month = jun,

day = "7",

doi = "10.1038/s41586-018-0175-2",

language = "English",

volume = "558",

pages = "73--79",

journal = "Nature",

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Sun, BB, Maranville, JC, Peters, JE, Stacey, D, Staley, JR, Blackshaw, J, Burgess, S, Jiang, T, Paige, E, Surendran, P, Oliver-Williams, C, Kamat, MA, Prins, BP, Wilcox, SK, Zimmerman, ES, Chi, A, Bansal, N, Spain, SL, Wood, AM, Morrell, NW, Bradley, JR, Janjic, N, Roberts, DJ, Ouwehand, WH, Todd, JA, Soranzo, N, Suhre, K, Paul, DS, Fox, CS, Plenge, RM, Danesh, J, Runz, H & Butterworth, AS 2018, 'Genomic atlas of the human plasma proteome', Nature, vol. 558, no. 7708, pp. 73-79. https://doi.org/10.1038/s41586-018-0175-2

TY - JOUR

T1 - Genomic atlas of the human plasma proteome

AU - Sun, Benjamin B.

AU - Maranville, Joseph C.

AU - Peters, James E.

AU - Stacey, David

AU - Staley, James R.

AU - Blackshaw, James

AU - Burgess, Stephen

AU - Jiang, Tao

AU - Paige, Ellie

AU - Surendran, Praveen

AU - Oliver-Williams, Clare

AU - Kamat, Mihir A.

AU - Prins, Bram P.

AU - Wilcox, Sheri K.

AU - Zimmerman, Erik S.

AU - Chi, An

AU - Bansal, Narinder

AU - Spain, Sarah L.

AU - Wood, Angela M.

AU - Morrell, Nicholas W.

AU - Bradley, John R.

AU - Janjic, Nebojsa

AU - Roberts, David J.

AU - Ouwehand, Willem H.

AU - Todd, John A.

AU - Soranzo, Nicole

AU - Suhre, Karsten

AU - Paul, Dirk S.

AU - Fox, Caroline S.

AU - Plenge, Robert M.

AU - Danesh, John

AU - Runz, Heiko

AU - Butterworth, Adam S.

PY - 2018/6/7

Y1 - 2018/6/7

N2 - Although plasma proteins have important roles in biological processes and are the direct targets of many drugs, the genetic factors that control inter-individual variation in plasma protein levels are not well understood. Here we characterize the genetic architecture of the human plasma proteome in healthy blood donors from the INTERVAL study. We identify 1,927 genetic associations with 1,478 proteins, a fourfold increase on existing knowledge, including trans associations for 1,104 proteins. To understand the consequences of perturbations in plasma protein levels, we apply an integrated approach that links genetic variation with biological pathway, disease, and drug databases. We show that protein quantitative trait loci overlap with gene expression quantitative trait loci, as well as with disease-associated loci, and find evidence that protein biomarkers have causal roles in disease using Mendelian randomization analysis. By linking genetic factors to diseases via specific proteins, our analyses highlight potential therapeutic targets, opportunities for matching existing drugs with new disease indications, and potential safety concerns for drugs under development.

AB - Although plasma proteins have important roles in biological processes and are the direct targets of many drugs, the genetic factors that control inter-individual variation in plasma protein levels are not well understood. Here we characterize the genetic architecture of the human plasma proteome in healthy blood donors from the INTERVAL study. We identify 1,927 genetic associations with 1,478 proteins, a fourfold increase on existing knowledge, including trans associations for 1,104 proteins. To understand the consequences of perturbations in plasma protein levels, we apply an integrated approach that links genetic variation with biological pathway, disease, and drug databases. We show that protein quantitative trait loci overlap with gene expression quantitative trait loci, as well as with disease-associated loci, and find evidence that protein biomarkers have causal roles in disease using Mendelian randomization analysis. By linking genetic factors to diseases via specific proteins, our analyses highlight potential therapeutic targets, opportunities for matching existing drugs with new disease indications, and potential safety concerns for drugs under development.

UR - http://www.scopus.com/inward/record.url?scp=85048231672&partnerID=8YFLogxK

U2 - 10.1038/s41586-018-0175-2

DO - 10.1038/s41586-018-0175-2

M3 - Article

SN - 0028-0836

VL - 558

SP - 73

EP - 79

JO - Nature

JF - Nature

IS - 7708

ER -

Genomic atlas of the human plasma proteome

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