Investigating the influence of mtDNA and nuclear encoded mitochondrial variants on high intensity interval training outcomes

N. R. Harvey; S. Voisin; R. A. Lea; X. Yan; M. C. Benton; I. D. Papadimitriou; M. Jacques; L. M. Haupt; K. J. Ashton; N. Eynon; L. R. Griffiths

doi:10.1038/s41598-020-67870-1

Investigating the influence of mtDNA and nuclear encoded mitochondrial variants on high intensity interval training outcomes

N. R. Harvey, S. Voisin, R. A. Lea, X. Yan, M. C. Benton, I. D. Papadimitriou, M. Jacques, L. M. Haupt, K. J. Ashton, N. Eynon, L. R. Griffiths

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

7 Citations (Scopus)

Abstract

Mitochondria supply intracellular energy requirements during exercise. Specific mitochondrial haplogroups and mitochondrial genetic variants have been associated with athletic performance, and exercise responses. However, these associations were discovered using underpowered, candidate gene approaches, and consequently have not been replicated. Here, we used whole-mitochondrial genome sequencing, in conjunction with high-throughput genotyping arrays, to discover novel genetic variants associated with exercise responses in the Gene SMART (Skeletal Muscle Adaptive Response to Training) cohort (n = 62 completed). We performed a Principal Component Analysis of cohort aerobic fitness measures to build composite traits and test for variants associated with exercise outcomes. None of the mitochondrial genetic variants but eight nuclear encoded variants in seven separate genes were found to be associated with exercise responses (FDR < 0.05) (rs11061368: DIABLO, rs113400963: FAM185A, rs6062129 and rs6121949: MTG2, rs7231304: AFG3L2, rs2041840: NDUFAF7, rs7085433: TIMM23, rs1063271: SPTLC2). Additionally, we outline potential mechanisms by which these variants may be contributing to exercise phenotypes. Our data suggest novel nuclear-encoded SNPs and mitochondrial pathways associated with exercise response phenotypes. Future studies should focus on validating these variants across different cohorts and ethnicities.

Original language	English
Article number	11089
Number of pages	11
Journal	Scientific Reports
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41598-020-67870-1
Publication status	Published - 6 Jul 2020
Externally published	Yes

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Harvey, N. R., Voisin, S., Lea, R. A., Yan, X., Benton, M. C., Papadimitriou, I. D., Jacques, M., Haupt, L. M., Ashton, K. J., Eynon, N., & Griffiths, L. R. (2020). Investigating the influence of mtDNA and nuclear encoded mitochondrial variants on high intensity interval training outcomes. Scientific Reports, 10(1), Article 11089. https://doi.org/10.1038/s41598-020-67870-1

@article{8b3380dcd9f84f589c331f971fe75b10,

title = "Investigating the influence of mtDNA and nuclear encoded mitochondrial variants on high intensity interval training outcomes",

abstract = "Mitochondria supply intracellular energy requirements during exercise. Specific mitochondrial haplogroups and mitochondrial genetic variants have been associated with athletic performance, and exercise responses. However, these associations were discovered using underpowered, candidate gene approaches, and consequently have not been replicated. Here, we used whole-mitochondrial genome sequencing, in conjunction with high-throughput genotyping arrays, to discover novel genetic variants associated with exercise responses in the Gene SMART (Skeletal Muscle Adaptive Response to Training) cohort (n = 62 completed). We performed a Principal Component Analysis of cohort aerobic fitness measures to build composite traits and test for variants associated with exercise outcomes. None of the mitochondrial genetic variants but eight nuclear encoded variants in seven separate genes were found to be associated with exercise responses (FDR < 0.05) (rs11061368: DIABLO, rs113400963: FAM185A, rs6062129 and rs6121949: MTG2, rs7231304: AFG3L2, rs2041840: NDUFAF7, rs7085433: TIMM23, rs1063271: SPTLC2). Additionally, we outline potential mechanisms by which these variants may be contributing to exercise phenotypes. Our data suggest novel nuclear-encoded SNPs and mitochondrial pathways associated with exercise response phenotypes. Future studies should focus on validating these variants across different cohorts and ethnicities.",

author = "Harvey, {N. R.} and S. Voisin and Lea, {R. A.} and X. Yan and Benton, {M. C.} and Papadimitriou, {I. D.} and M. Jacques and Haupt, {L. M.} and Ashton, {K. J.} and N. Eynon and Griffiths, {L. R.}",

note = "Funding Information: This research was supported by Commonwealth Collaborative Research Network funding to Bond University CRN-AESS. Mr Nicholas Harvey was supported by a PhD stipend also provided by Bond University CRN-AESS. This research was also supported by infrastructure purchased with Australian Government EIF Super Science Funds as part of the Therapeutic Innovation Australia—Queensland Node project (LRG). Nir Eynon is supported by the National Health and Medical Research Council (NHMRC), Australia (NHMRC CDF# APP1140644). Sarah Voisin is also supported by the NHMRC (ECF# APP1157732) and by the Jack Brockhoff foundation. Publisher Copyright: {\textcopyright} 2020, The Author(s).",

year = "2020",

month = jul,

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doi = "10.1038/s41598-020-67870-1",

language = "English",

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T1 - Investigating the influence of mtDNA and nuclear encoded mitochondrial variants on high intensity interval training outcomes

AU - Harvey, N. R.

AU - Voisin, S.

AU - Lea, R. A.

AU - Yan, X.

AU - Benton, M. C.

AU - Papadimitriou, I. D.

AU - Jacques, M.

AU - Haupt, L. M.

AU - Ashton, K. J.

AU - Eynon, N.

AU - Griffiths, L. R.

N1 - Funding Information: This research was supported by Commonwealth Collaborative Research Network funding to Bond University CRN-AESS. Mr Nicholas Harvey was supported by a PhD stipend also provided by Bond University CRN-AESS. This research was also supported by infrastructure purchased with Australian Government EIF Super Science Funds as part of the Therapeutic Innovation Australia—Queensland Node project (LRG). Nir Eynon is supported by the National Health and Medical Research Council (NHMRC), Australia (NHMRC CDF# APP1140644). Sarah Voisin is also supported by the NHMRC (ECF# APP1157732) and by the Jack Brockhoff foundation. Publisher Copyright: © 2020, The Author(s).

PY - 2020/7/6

Y1 - 2020/7/6

N2 - Mitochondria supply intracellular energy requirements during exercise. Specific mitochondrial haplogroups and mitochondrial genetic variants have been associated with athletic performance, and exercise responses. However, these associations were discovered using underpowered, candidate gene approaches, and consequently have not been replicated. Here, we used whole-mitochondrial genome sequencing, in conjunction with high-throughput genotyping arrays, to discover novel genetic variants associated with exercise responses in the Gene SMART (Skeletal Muscle Adaptive Response to Training) cohort (n = 62 completed). We performed a Principal Component Analysis of cohort aerobic fitness measures to build composite traits and test for variants associated with exercise outcomes. None of the mitochondrial genetic variants but eight nuclear encoded variants in seven separate genes were found to be associated with exercise responses (FDR < 0.05) (rs11061368: DIABLO, rs113400963: FAM185A, rs6062129 and rs6121949: MTG2, rs7231304: AFG3L2, rs2041840: NDUFAF7, rs7085433: TIMM23, rs1063271: SPTLC2). Additionally, we outline potential mechanisms by which these variants may be contributing to exercise phenotypes. Our data suggest novel nuclear-encoded SNPs and mitochondrial pathways associated with exercise response phenotypes. Future studies should focus on validating these variants across different cohorts and ethnicities.

AB - Mitochondria supply intracellular energy requirements during exercise. Specific mitochondrial haplogroups and mitochondrial genetic variants have been associated with athletic performance, and exercise responses. However, these associations were discovered using underpowered, candidate gene approaches, and consequently have not been replicated. Here, we used whole-mitochondrial genome sequencing, in conjunction with high-throughput genotyping arrays, to discover novel genetic variants associated with exercise responses in the Gene SMART (Skeletal Muscle Adaptive Response to Training) cohort (n = 62 completed). We performed a Principal Component Analysis of cohort aerobic fitness measures to build composite traits and test for variants associated with exercise outcomes. None of the mitochondrial genetic variants but eight nuclear encoded variants in seven separate genes were found to be associated with exercise responses (FDR < 0.05) (rs11061368: DIABLO, rs113400963: FAM185A, rs6062129 and rs6121949: MTG2, rs7231304: AFG3L2, rs2041840: NDUFAF7, rs7085433: TIMM23, rs1063271: SPTLC2). Additionally, we outline potential mechanisms by which these variants may be contributing to exercise phenotypes. Our data suggest novel nuclear-encoded SNPs and mitochondrial pathways associated with exercise response phenotypes. Future studies should focus on validating these variants across different cohorts and ethnicities.

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SN - 2045-2322

VL - 10

JO - Scientific Reports

JF - Scientific Reports

IS - 1

M1 - 11089

ER -

Investigating the influence of mtDNA and nuclear encoded mitochondrial variants on high intensity interval training outcomes

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