Blood-based DNA methylation captures variance in adult height

Alesha A. Hatton; Robert F. Hillary; Daniel L. McCartney; Sarah E. Harris; Simon R. Cox; Kathryn L. Evans; Rosie M. Walker; Matthew Suderman; Paul Yousefi; Allan F. McRae; Riccardo E. Marioni

doi:10.1186/s13059-025-03918-7

Blood-based DNA methylation captures variance in adult height

Alesha A. Hatton^*, Robert F. Hillary, Daniel L. McCartney, Sarah E. Harris, Simon R. Cox, Kathryn L. Evans, Rosie M. Walker, Matthew Suderman, Paul Yousefi, Allan F. McRae, Riccardo E. Marioni

^*Corresponding author for this work

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

Abstract

Background:

While height is a highly heritable trait with strong polygenic prediction, previous studies have postulated that minimal variation of its individual differences can be captured by DNA methylation (DNAm). We investigated the role of blood-based genome-wide DNAm in capturing the variance in adult height in a large population-based cohort of 7,654 unrelated individuals from Generation Scotland using DNAm profiled on the Illumina EPIC array. The posterior DNAm probe effects were used to construct a DNAm profile score (Methylation Profile Score—MPS) which was evaluated in three independent cohorts.

Results:

Genome-wide DNAm captures 25.0% (95% credible interval (CrI) 17.2–31.9) of the phenotypic variation in height when applying Bayesian penalised regression using BayesR + conditional on genetic effects. The total variation captured jointly by DNAm and genetic effects (80.3%, 95% CrI 70.1–87.2) is larger than the marginal estimate based on genetic effects only (56.3%, 95% CrI 45.8–66.8). Out-of-sample prediction shows that the MPS is weakly correlated with measured height (Pearson correlation ranging from 0.14–0.26), as well as being associated with several health and lifestyle factors in the LBC1936 that are established correlates of height.

Conclusion:

With the advent of larger sample sizes in epigenomics anticipated to improve the power to detect associations between DNAm and complex traits, we urge caution when making assumptions around “null traits” based solely on methylome-wide association study results and encourage the use of whole-genome methods to assess the proportion of variation in a trait that may be captured by DNAm.

Original language	English
Article number	37
Number of pages	15
Journal	Genome Biology
Volume	27
Issue number	1
DOIs	https://doi.org/10.1186/s13059-025-03918-7
Publication status	Published - 20 Jan 2026

Bibliographical note

Publisher Copyright:
© The Author(s) 2026.

Keywords

DNA methylation
Methylation profile score
Height

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8074 (C18281/A29019) ICEP2 - Programme Award: Towards improved casual evidence and enhanced prediction of cancer risk and survival
Martin, R. M. (Principal Investigator)
1/10/20 → 30/09/25
Project: Research

Cite this

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title = "Blood-based DNA methylation captures variance in adult height",

abstract = "Background:While height is a highly heritable trait with strong polygenic prediction, previous studies have postulated that minimal variation of its individual differences can be captured by DNA methylation (DNAm). We investigated the role of blood-based genome-wide DNAm in capturing the variance in adult height in a large population-based cohort of 7,654 unrelated individuals from Generation Scotland using DNAm profiled on the Illumina EPIC array. The posterior DNAm probe effects were used to construct a DNAm profile score (Methylation Profile Score—MPS) which was evaluated in three independent cohorts. Results:Genome-wide DNAm captures 25.0\% (95\% credible interval (CrI) 17.2–31.9) of the phenotypic variation in height when applying Bayesian penalised regression using BayesR + conditional on genetic effects. The total variation captured jointly by DNAm and genetic effects (80.3\%, 95\% CrI 70.1–87.2) is larger than the marginal estimate based on genetic effects only (56.3\%, 95\% CrI 45.8–66.8). Out-of-sample prediction shows that the MPS is weakly correlated with measured height (Pearson correlation ranging from 0.14–0.26), as well as being associated with several health and lifestyle factors in the LBC1936 that are established correlates of height. Conclusion:With the advent of larger sample sizes in epigenomics anticipated to improve the power to detect associations between DNAm and complex traits, we urge caution when making assumptions around “null traits” based solely on methylome-wide association study results and encourage the use of whole-genome methods to assess the proportion of variation in a trait that may be captured by DNAm.",

keywords = "DNA methylation, Methylation profile score, Height",

author = "Hatton, \{Alesha A.\} and Hillary, \{Robert F.\} and McCartney, \{Daniel L.\} and Harris, \{Sarah E.\} and Cox, \{Simon R.\} and Evans, \{Kathryn L.\} and Walker, \{Rosie M.\} and Matthew Suderman and Paul Yousefi and McRae, \{Allan F.\} and Marioni, \{Riccardo E.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = jan,

day = "20",

doi = "10.1186/s13059-025-03918-7",

language = "English",

volume = "27",

journal = "Genome Biology",

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T1 - Blood-based DNA methylation captures variance in adult height

AU - Hatton, Alesha A.

AU - Hillary, Robert F.

AU - McCartney, Daniel L.

AU - Harris, Sarah E.

AU - Cox, Simon R.

AU - Evans, Kathryn L.

AU - Walker, Rosie M.

AU - Suderman, Matthew

AU - Yousefi, Paul

AU - McRae, Allan F.

AU - Marioni, Riccardo E.

PY - 2026/1/20

Y1 - 2026/1/20

N2 - Background:While height is a highly heritable trait with strong polygenic prediction, previous studies have postulated that minimal variation of its individual differences can be captured by DNA methylation (DNAm). We investigated the role of blood-based genome-wide DNAm in capturing the variance in adult height in a large population-based cohort of 7,654 unrelated individuals from Generation Scotland using DNAm profiled on the Illumina EPIC array. The posterior DNAm probe effects were used to construct a DNAm profile score (Methylation Profile Score—MPS) which was evaluated in three independent cohorts. Results:Genome-wide DNAm captures 25.0% (95% credible interval (CrI) 17.2–31.9) of the phenotypic variation in height when applying Bayesian penalised regression using BayesR + conditional on genetic effects. The total variation captured jointly by DNAm and genetic effects (80.3%, 95% CrI 70.1–87.2) is larger than the marginal estimate based on genetic effects only (56.3%, 95% CrI 45.8–66.8). Out-of-sample prediction shows that the MPS is weakly correlated with measured height (Pearson correlation ranging from 0.14–0.26), as well as being associated with several health and lifestyle factors in the LBC1936 that are established correlates of height. Conclusion:With the advent of larger sample sizes in epigenomics anticipated to improve the power to detect associations between DNAm and complex traits, we urge caution when making assumptions around “null traits” based solely on methylome-wide association study results and encourage the use of whole-genome methods to assess the proportion of variation in a trait that may be captured by DNAm.

AB - Background:While height is a highly heritable trait with strong polygenic prediction, previous studies have postulated that minimal variation of its individual differences can be captured by DNA methylation (DNAm). We investigated the role of blood-based genome-wide DNAm in capturing the variance in adult height in a large population-based cohort of 7,654 unrelated individuals from Generation Scotland using DNAm profiled on the Illumina EPIC array. The posterior DNAm probe effects were used to construct a DNAm profile score (Methylation Profile Score—MPS) which was evaluated in three independent cohorts. Results:Genome-wide DNAm captures 25.0% (95% credible interval (CrI) 17.2–31.9) of the phenotypic variation in height when applying Bayesian penalised regression using BayesR + conditional on genetic effects. The total variation captured jointly by DNAm and genetic effects (80.3%, 95% CrI 70.1–87.2) is larger than the marginal estimate based on genetic effects only (56.3%, 95% CrI 45.8–66.8). Out-of-sample prediction shows that the MPS is weakly correlated with measured height (Pearson correlation ranging from 0.14–0.26), as well as being associated with several health and lifestyle factors in the LBC1936 that are established correlates of height. Conclusion:With the advent of larger sample sizes in epigenomics anticipated to improve the power to detect associations between DNAm and complex traits, we urge caution when making assumptions around “null traits” based solely on methylome-wide association study results and encourage the use of whole-genome methods to assess the proportion of variation in a trait that may be captured by DNAm.

KW - DNA methylation

KW - Methylation profile score

KW - Height

U2 - 10.1186/s13059-025-03918-7

DO - 10.1186/s13059-025-03918-7

M3 - Article (Academic Journal)

C2 - 41559797

SN - 1474-7596

VL - 27

JO - Genome Biology

JF - Genome Biology

IS - 1

M1 - 37

ER -

Blood-based DNA methylation captures variance in adult height

Abstract

Bibliographical note

Keywords

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Projects

8074 (C18281/A29019) ICEP2 - Programme Award: Towards improved casual evidence and enhanced prediction of cancer risk and survival

Cite this