Deleterious mitochondrial heteroplasmies exhibit increased longitudinal change in variant allele fraction

Lieke M. Kuiper; Wen Shi; Joost A.M. Verlouw; Yun Soo Hong; Pascal Arp; Daniela Puiu; Linda Broer; Jiaqi Xie; Charles Newcomb; Stephen S. Rich; Kent D. Taylor; Jerome I. Rotter; Joel S. Bader; Eliseo Guallar; Joyce B.J. van Meurs; Dan E. Arking

doi:10.1016/j.isci.2025.112590

Deleterious mitochondrial heteroplasmies exhibit increased longitudinal change in variant allele fraction

Lieke M. Kuiper, Wen Shi, Joost A.M. Verlouw, Yun Soo Hong, Pascal Arp, Daniela Puiu, Linda Broer, Jiaqi Xie, Charles Newcomb, Stephen S. Rich, Kent D. Taylor, Jerome I. Rotter, Joel S. Bader, Eliseo Guallar, Joyce B.J. van Meurs, Dan E. Arking^*

^*Corresponding author for this work

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Abstract

A common feature of human aging is the acquisition of somatic mutations, and mitochondria are particularly prone to mutation, leading to a state of mitochondrial DNA heteroplasmy. Cross-sectional studies have demonstrated that detection of heteroplasmy increases with participant age, a phenomenon that has been attributed to genetic drift. In this large-scale longitudinal study, we measured heteroplasmy in two prospective cohorts (combined n = 1404) at two time points (mean time between visits, 8.6 years), demonstrating that deleterious heteroplasmies were more likely to increase in variant allele fraction (VAF). We further demonstrated that increase in VAF was associated with increased risk of overall mortality. These results challenge the claim that somatic mtDNA mutations arise mainly due to genetic drift, instead suggesting a role for positive selection for a subset of predicted deleterious mutations at the cellular level, despite a negative impact of these mutations on overall mortality.

Original language	English
Article number	112590
Journal	iScience
Volume	28
Issue number	6
DOIs	https://doi.org/10.1016/j.isci.2025.112590
Publication status	Published - 20 Jun 2025

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Kuiper, L. M., Shi, W., Verlouw, J. A. M., Hong, Y. S., Arp, P., Puiu, D., Broer, L., Xie, J., Newcomb, C., Rich, S. S., Taylor, K. D., Rotter, J. I., Bader, J. S., Guallar, E., van Meurs, J. B. J., & Arking, D. E. (2025). Deleterious mitochondrial heteroplasmies exhibit increased longitudinal change in variant allele fraction. iScience, 28(6), Article 112590. https://doi.org/10.1016/j.isci.2025.112590

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title = "Deleterious mitochondrial heteroplasmies exhibit increased longitudinal change in variant allele fraction",

abstract = "A common feature of human aging is the acquisition of somatic mutations, and mitochondria are particularly prone to mutation, leading to a state of mitochondrial DNA heteroplasmy. Cross-sectional studies have demonstrated that detection of heteroplasmy increases with participant age, a phenomenon that has been attributed to genetic drift. In this large-scale longitudinal study, we measured heteroplasmy in two prospective cohorts (combined n = 1404) at two time points (mean time between visits, 8.6 years), demonstrating that deleterious heteroplasmies were more likely to increase in variant allele fraction (VAF). We further demonstrated that increase in VAF was associated with increased risk of overall mortality. These results challenge the claim that somatic mtDNA mutations arise mainly due to genetic drift, instead suggesting a role for positive selection for a subset of predicted deleterious mutations at the cellular level, despite a negative impact of these mutations on overall mortality.",

author = "Kuiper, \{Lieke M.\} and Wen Shi and Verlouw, \{Joost A.M.\} and Hong, \{Yun Soo\} and Pascal Arp and Daniela Puiu and Linda Broer and Jiaqi Xie and Charles Newcomb and Rich, \{Stephen S.\} and Taylor, \{Kent D.\} and Rotter, \{Jerome I.\} and Bader, \{Joel S.\} and Eliseo Guallar and \{van Meurs\}, \{Joyce B.J.\} and Arking, \{Dan E.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s)",

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doi = "10.1016/j.isci.2025.112590",

language = "English",

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T1 - Deleterious mitochondrial heteroplasmies exhibit increased longitudinal change in variant allele fraction

AU - Kuiper, Lieke M.

AU - Shi, Wen

AU - Verlouw, Joost A.M.

AU - Hong, Yun Soo

AU - Arp, Pascal

AU - Puiu, Daniela

AU - Broer, Linda

AU - Xie, Jiaqi

AU - Newcomb, Charles

AU - Rich, Stephen S.

AU - Taylor, Kent D.

AU - Rotter, Jerome I.

AU - Bader, Joel S.

AU - Guallar, Eliseo

AU - van Meurs, Joyce B.J.

AU - Arking, Dan E.

PY - 2025/6/20

Y1 - 2025/6/20

N2 - A common feature of human aging is the acquisition of somatic mutations, and mitochondria are particularly prone to mutation, leading to a state of mitochondrial DNA heteroplasmy. Cross-sectional studies have demonstrated that detection of heteroplasmy increases with participant age, a phenomenon that has been attributed to genetic drift. In this large-scale longitudinal study, we measured heteroplasmy in two prospective cohorts (combined n = 1404) at two time points (mean time between visits, 8.6 years), demonstrating that deleterious heteroplasmies were more likely to increase in variant allele fraction (VAF). We further demonstrated that increase in VAF was associated with increased risk of overall mortality. These results challenge the claim that somatic mtDNA mutations arise mainly due to genetic drift, instead suggesting a role for positive selection for a subset of predicted deleterious mutations at the cellular level, despite a negative impact of these mutations on overall mortality.

AB - A common feature of human aging is the acquisition of somatic mutations, and mitochondria are particularly prone to mutation, leading to a state of mitochondrial DNA heteroplasmy. Cross-sectional studies have demonstrated that detection of heteroplasmy increases with participant age, a phenomenon that has been attributed to genetic drift. In this large-scale longitudinal study, we measured heteroplasmy in two prospective cohorts (combined n = 1404) at two time points (mean time between visits, 8.6 years), demonstrating that deleterious heteroplasmies were more likely to increase in variant allele fraction (VAF). We further demonstrated that increase in VAF was associated with increased risk of overall mortality. These results challenge the claim that somatic mtDNA mutations arise mainly due to genetic drift, instead suggesting a role for positive selection for a subset of predicted deleterious mutations at the cellular level, despite a negative impact of these mutations on overall mortality.

UR - https://www.scopus.com/pages/publications/105004919158

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SN - 2589-0042

VL - 28

JO - iScience

JF - iScience

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M1 - 112590

ER -

Deleterious mitochondrial heteroplasmies exhibit increased longitudinal change in variant allele fraction

Abstract

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