Comparison of Proteomic Assessment Methods in Multiple Cohort Studies

Overview

Journal Proteomics

Date 2020 May 10

PMID 32386347

Citations 78

Authors

Laura M Raffield

Hong Dang

Katherine A Pratte

Sean Jacobson

Lucas A Gillenwater

Elizabeth Ampleford

Igor Barjaktarevic

Patricia Basta

Clary B Clish

Alejandro P Comellas

Elaine Cornell

Jeffrey L Curtis

Claire Doerschuk

Peter Durda

Claire Emson

Christine M Freeman

Xiuqing Guo

Annette T Hastie

Gregory A Hawkins

Julio Herrera

W Craig Johnson

Wassim W Labaki

Yongmei Liu

Brett Masters

Michael Miller

Victor E Ortega

George Papanicolaou

Stephen Peters

Kent D Taylor

Stephen S Rich

Jerome I Rotter

Paul Auer

Alex P Reiner

Russell P Tracy

Debby Ngo

Robert E Gerszten

Wanda K ONeal

Russell P Bowler

Affiliations

Soon will be listed here.

Abstract

Novel proteomics platforms, such as the aptamer-based SOMAscan platform, can quantify large numbers of proteins efficiently and cost-effectively and are rapidly growing in popularity. However, comparisons to conventional immunoassays remain underexplored, leaving investigators unsure when cross-assay comparisons are appropriate. The correlation of results from immunoassays with relative protein quantification is explored by SOMAscan. For 63 proteins assessed in two chronic obstructive pulmonary disease (COPD) cohorts, subpopulations and intermediate outcome measures in COPD Study (SPIROMICS), and COPDGene, using myriad rules based medicine multiplex immunoassays and SOMAscan, Spearman correlation coefficients range from -0.13 to 0.97, with a median correlation coefficient of ≈0.5 and consistent results across cohorts. A similar range is observed for immunoassays in the population-based Multi-Ethnic Study of Atherosclerosis and for other assays in COPDGene and SPIROMICS. Comparisons of relative quantification from the antibody-based Olink platform and SOMAscan in a small cohort of myocardial infarction patients also show a wide correlation range. Finally, cis pQTL data, mass spectrometry aptamer confirmation, and other publicly available data are integrated to assess relationships with observed correlations. Correlation between proteomics assays shows a wide range and should be carefully considered when comparing and meta-analyzing proteomics data across assays and studies.

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