TY - JOUR
T1 - A pro-diabetogenic mtDNA polymorphism in the mitochondrial-derived peptide, MOTS-c
AU - Zempo, Hirofumi
AU - Kim, Su Jeong
AU - Fuku, Noriyuki
AU - Nishida, Yuichiro
AU - Higaki, Yasuki
AU - Wan, Junxiang
AU - Yen, Kelvin
AU - Miller, Brendan
AU - Vicinanza, Roberto
AU - Miyamoto-Mikami, Eri
AU - Kumagai, Hiroshi
AU - Naito, Hisashi
AU - Xiao, Jialin
AU - Mehta, Hemal H.
AU - Lee, Changhan
AU - Hara, Megumi
AU - Pate, Yesha M.
AU - Setiawan, Veronica W.
AU - Moore, Timothy M.
AU - Hevener, Andrea L.
AU - Sutoh, Yoichi
AU - Shimizu, Atsushi
AU - Kojima, Kaname
AU - Kinoshita, Kengo
AU - Arai, Yasumichi
AU - Hirose, Nobuyoshi
AU - Maeda, Seiji
AU - Tanaka, Keitaro
AU - Cohen, Pinchas
N1 - Publisher Copyright:
© 2021 Zempo et al. This is an open access article distributed under the terms of the Creative Commons Attribution License
PY - 2021/1/19
Y1 - 2021/1/19
N2 - Type 2 Diabetes (T2D) is an emerging public health problem in Asia. Although ethnic specific mtDNA polymorphisms have been shown to contribute to T2D risk, the functional effects of the mtDNA polymorphisms and the therapeutic potential of mitochondrial-derived peptides at the mtDNA polymorphisms are underexplored. Here, we showed an Asian-specific mitochondrial DNA variation m.1382A>C (rs111033358) leads to a K14Q amino acid replacement in MOTS-c, an insulin sensitizing mitochondrial-derived peptide. Meta-analysis of three cohorts (n = 27,527, J-MICC, MEC, and TMM) show that males but not females with the C-allele exhibit a higher prevalence of T2D. In J-MICC, only males with the C-allele in the lowest tertile of physical activity increased their prevalence of T2D, demonstrating a kinesio-genomic interaction. High-fat fed, male mice injected with MOTS-c showed reduced weight and improved glucose tolerance, but not K14Q-MOTS-c treated mice. Like the human data, female mice were unaffected. Mechanistically, K14Q-MOTS-c leads to diminished insulin-sensitization in vitro. Thus, the m.1382A>C polymorphism is associated with susceptibility to T2D in men, possibly interacting with exercise, and contributing to the risk of T2D in sedentary males by reducing the activity of MOTS-c.
AB - Type 2 Diabetes (T2D) is an emerging public health problem in Asia. Although ethnic specific mtDNA polymorphisms have been shown to contribute to T2D risk, the functional effects of the mtDNA polymorphisms and the therapeutic potential of mitochondrial-derived peptides at the mtDNA polymorphisms are underexplored. Here, we showed an Asian-specific mitochondrial DNA variation m.1382A>C (rs111033358) leads to a K14Q amino acid replacement in MOTS-c, an insulin sensitizing mitochondrial-derived peptide. Meta-analysis of three cohorts (n = 27,527, J-MICC, MEC, and TMM) show that males but not females with the C-allele exhibit a higher prevalence of T2D. In J-MICC, only males with the C-allele in the lowest tertile of physical activity increased their prevalence of T2D, demonstrating a kinesio-genomic interaction. High-fat fed, male mice injected with MOTS-c showed reduced weight and improved glucose tolerance, but not K14Q-MOTS-c treated mice. Like the human data, female mice were unaffected. Mechanistically, K14Q-MOTS-c leads to diminished insulin-sensitization in vitro. Thus, the m.1382A>C polymorphism is associated with susceptibility to T2D in men, possibly interacting with exercise, and contributing to the risk of T2D in sedentary males by reducing the activity of MOTS-c.
KW - MOTS-c
KW - diabetes
KW - insulin resistance
KW - mitochondrial DNA
KW - polymorphism
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U2 - 10.18632/aging.202529
DO - 10.18632/aging.202529
M3 - Article
C2 - 33468709
AN - SCOPUS:85100411266
SN - 0002-0966
VL - 13
SP - 1692
EP - 1715
JO - Aging
JF - Aging
IS - 2
ER -