FOXO3A-short is a novel regulator of non-oxidative glucose metabolism associated with human longevity

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FOXO3A-short is a novel regulator of non-oxidative glucose metabolism associated with human longevity. / Santo, Evan E.; Ribel-Madsen, Rasmus; Stroeken, Peter J.; de Boer, Vincent C.J.; Hansen, Ninna S.; Commandeur, Maaike; Vaag, Allan A.; Versteeg, Rogier; Paik, Jihye; Westerhout, Ellen M.

In: Aging Cell, Vol. 22, No. 3, e13763, 2023.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Santo, EE, Ribel-Madsen, R, Stroeken, PJ, de Boer, VCJ, Hansen, NS, Commandeur, M, Vaag, AA, Versteeg, R, Paik, J & Westerhout, EM 2023, 'FOXO3A-short is a novel regulator of non-oxidative glucose metabolism associated with human longevity', Aging Cell, vol. 22, no. 3, e13763. https://doi.org/10.1111/acel.13763

APA

Santo, E. E., Ribel-Madsen, R., Stroeken, P. J., de Boer, V. C. J., Hansen, N. S., Commandeur, M., Vaag, A. A., Versteeg, R., Paik, J., & Westerhout, E. M. (2023). FOXO3A-short is a novel regulator of non-oxidative glucose metabolism associated with human longevity. Aging Cell, 22(3), [e13763]. https://doi.org/10.1111/acel.13763

Vancouver

Santo EE, Ribel-Madsen R, Stroeken PJ, de Boer VCJ, Hansen NS, Commandeur M et al. FOXO3A-short is a novel regulator of non-oxidative glucose metabolism associated with human longevity. Aging Cell. 2023;22(3). e13763. https://doi.org/10.1111/acel.13763

Author

Santo, Evan E. ; Ribel-Madsen, Rasmus ; Stroeken, Peter J. ; de Boer, Vincent C.J. ; Hansen, Ninna S. ; Commandeur, Maaike ; Vaag, Allan A. ; Versteeg, Rogier ; Paik, Jihye ; Westerhout, Ellen M. / FOXO3A-short is a novel regulator of non-oxidative glucose metabolism associated with human longevity. In: Aging Cell. 2023 ; Vol. 22, No. 3.

Bibtex

@article{ced566286bba4aa0a4cf697a5472e69d,
title = "FOXO3A-short is a novel regulator of non-oxidative glucose metabolism associated with human longevity",
abstract = "Intronic single-nucleotide polymorphisms (SNPs) in FOXO3A are associated with human longevity. Currently, it is unclear how these SNPs alter FOXO3A functionality and human physiology, thereby influencing lifespan. Here, we identify a primate-specific FOXO3A transcriptional isoform, FOXO3A-Short (FOXO3A-S), encoding a major longevity-associated SNP, rs9400239 (C or T), within its 5′ untranslated region. The FOXO3A-S mRNA is highly expressed in the skeletal muscle and has very limited expression in other tissues. We find that the rs9400239 variant influences the stability and functionality of the primarily nuclear protein(s) encoded by the FOXO3A-S mRNA. Assessment of the relationship between the FOXO3A-S polymorphism and peripheral glucose clearance during insulin infusion (Rd clamp) in a cohort of Danish twins revealed that longevity T-allele carriers have markedly faster peripheral glucose clearance rates than normal lifespan C-allele carriers. In vitro experiments in human myotube cultures utilizing overexpression of each allele showed that the C-allele represses glycolysis independently of PI3K signaling, while overexpression of the T-allele represses glycolysis only in a PI3K-inactive background. Supporting this finding inducible knockdown of the FOXO3A-S C-allele in cultured myotubes increases the glycolytic rate. We conclude that the rs9400239 polymorphism acts as a molecular switch which changes the identity of the FOXO3A-S-derived protein(s), which in turn alters the relationship between FOXO3A-S and insulin/PI3K signaling and glycolytic flux in the skeletal muscle. This critical difference endows carriers of the FOXO3A-S T-allele with consistently higher insulin-stimulated peripheral glucose clearance rates, which may contribute to their longer and healthier lifespans.",
keywords = "aging, FOXO, FOXO3A, glycolysis, insulin, PI3K, skeletal muscle, SNP",
author = "Santo, {Evan E.} and Rasmus Ribel-Madsen and Stroeken, {Peter J.} and {de Boer}, {Vincent C.J.} and Hansen, {Ninna S.} and Maaike Commandeur and Vaag, {Allan A.} and Rogier Versteeg and Jihye Paik and Westerhout, {Ellen M.}",
note = "Publisher Copyright: {\textcopyright} 2023 The Authors. Aging Cell published by Anatomical Society and John Wiley & Sons Ltd.",
year = "2023",
doi = "10.1111/acel.13763",
language = "English",
volume = "22",
journal = "Aging Cell",
issn = "1474-9718",
publisher = "Wiley-Blackwell",
number = "3",

}

RIS

TY - JOUR

T1 - FOXO3A-short is a novel regulator of non-oxidative glucose metabolism associated with human longevity

AU - Santo, Evan E.

AU - Ribel-Madsen, Rasmus

AU - Stroeken, Peter J.

AU - de Boer, Vincent C.J.

AU - Hansen, Ninna S.

AU - Commandeur, Maaike

AU - Vaag, Allan A.

AU - Versteeg, Rogier

AU - Paik, Jihye

AU - Westerhout, Ellen M.

N1 - Publisher Copyright: © 2023 The Authors. Aging Cell published by Anatomical Society and John Wiley & Sons Ltd.

PY - 2023

Y1 - 2023

N2 - Intronic single-nucleotide polymorphisms (SNPs) in FOXO3A are associated with human longevity. Currently, it is unclear how these SNPs alter FOXO3A functionality and human physiology, thereby influencing lifespan. Here, we identify a primate-specific FOXO3A transcriptional isoform, FOXO3A-Short (FOXO3A-S), encoding a major longevity-associated SNP, rs9400239 (C or T), within its 5′ untranslated region. The FOXO3A-S mRNA is highly expressed in the skeletal muscle and has very limited expression in other tissues. We find that the rs9400239 variant influences the stability and functionality of the primarily nuclear protein(s) encoded by the FOXO3A-S mRNA. Assessment of the relationship between the FOXO3A-S polymorphism and peripheral glucose clearance during insulin infusion (Rd clamp) in a cohort of Danish twins revealed that longevity T-allele carriers have markedly faster peripheral glucose clearance rates than normal lifespan C-allele carriers. In vitro experiments in human myotube cultures utilizing overexpression of each allele showed that the C-allele represses glycolysis independently of PI3K signaling, while overexpression of the T-allele represses glycolysis only in a PI3K-inactive background. Supporting this finding inducible knockdown of the FOXO3A-S C-allele in cultured myotubes increases the glycolytic rate. We conclude that the rs9400239 polymorphism acts as a molecular switch which changes the identity of the FOXO3A-S-derived protein(s), which in turn alters the relationship between FOXO3A-S and insulin/PI3K signaling and glycolytic flux in the skeletal muscle. This critical difference endows carriers of the FOXO3A-S T-allele with consistently higher insulin-stimulated peripheral glucose clearance rates, which may contribute to their longer and healthier lifespans.

AB - Intronic single-nucleotide polymorphisms (SNPs) in FOXO3A are associated with human longevity. Currently, it is unclear how these SNPs alter FOXO3A functionality and human physiology, thereby influencing lifespan. Here, we identify a primate-specific FOXO3A transcriptional isoform, FOXO3A-Short (FOXO3A-S), encoding a major longevity-associated SNP, rs9400239 (C or T), within its 5′ untranslated region. The FOXO3A-S mRNA is highly expressed in the skeletal muscle and has very limited expression in other tissues. We find that the rs9400239 variant influences the stability and functionality of the primarily nuclear protein(s) encoded by the FOXO3A-S mRNA. Assessment of the relationship between the FOXO3A-S polymorphism and peripheral glucose clearance during insulin infusion (Rd clamp) in a cohort of Danish twins revealed that longevity T-allele carriers have markedly faster peripheral glucose clearance rates than normal lifespan C-allele carriers. In vitro experiments in human myotube cultures utilizing overexpression of each allele showed that the C-allele represses glycolysis independently of PI3K signaling, while overexpression of the T-allele represses glycolysis only in a PI3K-inactive background. Supporting this finding inducible knockdown of the FOXO3A-S C-allele in cultured myotubes increases the glycolytic rate. We conclude that the rs9400239 polymorphism acts as a molecular switch which changes the identity of the FOXO3A-S-derived protein(s), which in turn alters the relationship between FOXO3A-S and insulin/PI3K signaling and glycolytic flux in the skeletal muscle. This critical difference endows carriers of the FOXO3A-S T-allele with consistently higher insulin-stimulated peripheral glucose clearance rates, which may contribute to their longer and healthier lifespans.

KW - aging

KW - FOXO

KW - FOXO3A

KW - glycolysis

KW - insulin

KW - PI3K

KW - skeletal muscle

KW - SNP

U2 - 10.1111/acel.13763

DO - 10.1111/acel.13763

M3 - Journal article

C2 - 36617632

AN - SCOPUS:85146073629

VL - 22

JO - Aging Cell

JF - Aging Cell

SN - 1474-9718

IS - 3

M1 - e13763

ER -

ID: 333346390