Genetic analysis of blood molecular phenotypes reveals common properties in the regulatory networks affecting complex traits

A.A. Brown; G.N. Giordano; M. Ridderstråle; P.W. Franks; N. Atabaki-Pasdar; H. Fitipaldi; L. Groop; M. Klintenberg; H. Pomares-Millan; A. Viñuela; IMI DIRECT Consortium

doi:10.1038/s41467-023-40569-3

Genetic analysis of blood molecular phenotypes reveals common properties in the regulatory networks affecting complex traits

A.A. Brown, G.N. Giordano, M. Ridderstråle, P.W. Franks, N. Atabaki-Pasdar, H. Fitipaldi, L. Groop, M. Klintenberg, H. Pomares-Millan, A. Viñuela, IMI DIRECT Consortium

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

Abstract

We evaluate the shared genetic regulation of mRNA molecules, proteins and metabolites derived from whole blood from 3029 human donors. We find abundant allelic heterogeneity, where multiple variants regulate a particular molecular phenotype, and pleiotropy, where a single variant associates with multiple molecular phenotypes over multiple genomic regions. The highest proportion of share genetic regulation is detected between gene expression and proteins (66.6%), with a further median shared genetic associations across 49 different tissues of 78.3% and 62.4% between plasma proteins and gene expression. We represent the genetic and molecular associations in networks including 2828 known GWAS variants, showing that GWAS variants are more often connected to gene expression in trans than other molecular phenotypes in the network. Our work provides a roadmap to understanding molecular networks and deriving the underlying mechanism of action of GWAS variants using different molecular phenotypes in an accessible tissue. © 2023, Springer Nature Limited.

Original language	English
Article number	5062
Journal	Nature Communications
Volume	14
DOIs	https://doi.org/10.1038/s41467-023-40569-3
Publication status	Published - 2023

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Subject classification (UKÄ)

Medical Genetics and Genomics (including Gene Therapy)

Free keywords

Genomics
Humans
Multifactorial Inheritance
Phenotype
Research Personnel
RNA, Messenger
messenger RNA
plasma protein
protein kinase Lck
transcription factor
blood
gene expression
genetic analysis
phenotype
protein
RNA
5' untranslated region
adult
aged
Article
biochemical analysis
cohort analysis
DNA extraction
donor
exon
fasting blood glucose level
female
functional enrichment analysis
gene linkage disequilibrium
genetic association
genetic heterogeneity
genetic regulation
genetic variation
genome-wide association study
genotyping
human
impaired glucose tolerance
major clinical study
male
mitochondrion
non insulin dependent diabetes mellitus
pancreas islet
phenotypic variation
pleiotropy
proteomics
quantitative trait locus
RNA sequencing
single nucleotide polymorphism
transcription regulation
Y chromosome
genomics
multifactorial inheritance
personnel

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10.1038/s41467-023-40569-3

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Brown, A. A., Giordano, G. N., Ridderstråle, M., Franks, P. W., Atabaki-Pasdar, N., Fitipaldi, H., Groop, L., Klintenberg, M., Pomares-Millan, H., Viñuela, A., & IMI DIRECT Consortium (2023). Genetic analysis of blood molecular phenotypes reveals common properties in the regulatory networks affecting complex traits. Nature Communications, 14, Article 5062. https://doi.org/10.1038/s41467-023-40569-3

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abstract = "We evaluate the shared genetic regulation of mRNA molecules, proteins and metabolites derived from whole blood from 3029 human donors. We find abundant allelic heterogeneity, where multiple variants regulate a particular molecular phenotype, and pleiotropy, where a single variant associates with multiple molecular phenotypes over multiple genomic regions. The highest proportion of share genetic regulation is detected between gene expression and proteins (66.6\%), with a further median shared genetic associations across 49 different tissues of 78.3\% and 62.4\% between plasma proteins and gene expression. We represent the genetic and molecular associations in networks including 2828 known GWAS variants, showing that GWAS variants are more often connected to gene expression in trans than other molecular phenotypes in the network. Our work provides a roadmap to understanding molecular networks and deriving the underlying mechanism of action of GWAS variants using different molecular phenotypes in an accessible tissue. {\textcopyright} 2023, Springer Nature Limited.",

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author = "A.A. Brown and G.N. Giordano and M. Ridderstr{\aa}le and P.W. Franks and N. Atabaki-Pasdar and H. Fitipaldi and L. Groop and M. Klintenberg and H. Pomares-Millan and A. Vi{\~n}uela and \{IMI DIRECT Consortium\}",

year = "2023",

doi = "10.1038/s41467-023-40569-3",

language = "English",

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journal = "Nature Communications",

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Brown, AA, Giordano, GN, Ridderstråle, M, Franks, PW , Atabaki-Pasdar, N , Fitipaldi, H, Groop, L, Klintenberg, M, Pomares-Millan, H, Viñuela, A & IMI DIRECT Consortium 2023, 'Genetic analysis of blood molecular phenotypes reveals common properties in the regulatory networks affecting complex traits', Nature Communications, vol. 14, 5062. https://doi.org/10.1038/s41467-023-40569-3

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AU - Brown, A.A.

AU - Giordano, G.N.

AU - Ridderstråle, M.

AU - Franks, P.W.

AU - Atabaki-Pasdar, N.

AU - Fitipaldi, H.

AU - Groop, L.

AU - Klintenberg, M.

AU - Pomares-Millan, H.

AU - Viñuela, A.

AU - IMI DIRECT Consortium

PY - 2023

Y1 - 2023

N2 - We evaluate the shared genetic regulation of mRNA molecules, proteins and metabolites derived from whole blood from 3029 human donors. We find abundant allelic heterogeneity, where multiple variants regulate a particular molecular phenotype, and pleiotropy, where a single variant associates with multiple molecular phenotypes over multiple genomic regions. The highest proportion of share genetic regulation is detected between gene expression and proteins (66.6%), with a further median shared genetic associations across 49 different tissues of 78.3% and 62.4% between plasma proteins and gene expression. We represent the genetic and molecular associations in networks including 2828 known GWAS variants, showing that GWAS variants are more often connected to gene expression in trans than other molecular phenotypes in the network. Our work provides a roadmap to understanding molecular networks and deriving the underlying mechanism of action of GWAS variants using different molecular phenotypes in an accessible tissue. © 2023, Springer Nature Limited.

AB - We evaluate the shared genetic regulation of mRNA molecules, proteins and metabolites derived from whole blood from 3029 human donors. We find abundant allelic heterogeneity, where multiple variants regulate a particular molecular phenotype, and pleiotropy, where a single variant associates with multiple molecular phenotypes over multiple genomic regions. The highest proportion of share genetic regulation is detected between gene expression and proteins (66.6%), with a further median shared genetic associations across 49 different tissues of 78.3% and 62.4% between plasma proteins and gene expression. We represent the genetic and molecular associations in networks including 2828 known GWAS variants, showing that GWAS variants are more often connected to gene expression in trans than other molecular phenotypes in the network. Our work provides a roadmap to understanding molecular networks and deriving the underlying mechanism of action of GWAS variants using different molecular phenotypes in an accessible tissue. © 2023, Springer Nature Limited.

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KW - Multifactorial Inheritance

KW - Phenotype

KW - Research Personnel

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KW - pleiotropy

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KW - RNA sequencing

KW - single nucleotide polymorphism

KW - transcription regulation

KW - Y chromosome

KW - genomics

KW - multifactorial inheritance

KW - personnel

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DO - 10.1038/s41467-023-40569-3

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SN - 2041-1723

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JO - Nature Communications

JF - Nature Communications

M1 - 5062

ER -

Genetic analysis of blood molecular phenotypes reveals common properties in the regulatory networks affecting complex traits

Abstract

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