Adaptations in mitochondrial enzymatic activity occurs independent of genomic dosage in response to aerobic exercise training and deconditioning in human skeletal muscle

Publikation: Bidrag til tidsskriftTidsskriftartikelfagfællebedømt

Standard

Adaptations in mitochondrial enzymatic activity occurs independent of genomic dosage in response to aerobic exercise training and deconditioning in human skeletal muscle. / Fritzen, Andreas Mæchel; Thøgersen, Frank B; Thybo, Kasper; Vissing, Christoffer Rasmus; Krag, Thomas O; Ruiz-Ruiz, Cristina; Risom, Lotte; Wibrand, Flemming; Høeg, Louise Dalgas; Kiens, Bente; Duno, Morten; Vissing, John; Jeppesen, Tina Dysgaard.

I: Cells, Bind 8, Nr. 3, 237, 2019.

Publikation: Bidrag til tidsskriftTidsskriftartikelfagfællebedømt

Harvard

Fritzen, AM, Thøgersen, FB, Thybo, K, Vissing, CR, Krag, TO, Ruiz-Ruiz, C, Risom, L, Wibrand, F, Høeg, LD, Kiens, B, Duno, M, Vissing, J & Jeppesen, TD 2019, 'Adaptations in mitochondrial enzymatic activity occurs independent of genomic dosage in response to aerobic exercise training and deconditioning in human skeletal muscle', Cells, bind 8, nr. 3, 237. https://doi.org/10.3390/cells8030237

APA

Fritzen, A. M., Thøgersen, F. B., Thybo, K., Vissing, C. R., Krag, T. O., Ruiz-Ruiz, C., Risom, L., Wibrand, F., Høeg, L. D., Kiens, B., Duno, M., Vissing, J., & Jeppesen, T. D. (2019). Adaptations in mitochondrial enzymatic activity occurs independent of genomic dosage in response to aerobic exercise training and deconditioning in human skeletal muscle. Cells, 8(3), [237]. https://doi.org/10.3390/cells8030237

Vancouver

Fritzen AM, Thøgersen FB, Thybo K, Vissing CR, Krag TO, Ruiz-Ruiz C o.a. Adaptations in mitochondrial enzymatic activity occurs independent of genomic dosage in response to aerobic exercise training and deconditioning in human skeletal muscle. Cells. 2019;8(3). 237. https://doi.org/10.3390/cells8030237

Author

Fritzen, Andreas Mæchel ; Thøgersen, Frank B ; Thybo, Kasper ; Vissing, Christoffer Rasmus ; Krag, Thomas O ; Ruiz-Ruiz, Cristina ; Risom, Lotte ; Wibrand, Flemming ; Høeg, Louise Dalgas ; Kiens, Bente ; Duno, Morten ; Vissing, John ; Jeppesen, Tina Dysgaard. / Adaptations in mitochondrial enzymatic activity occurs independent of genomic dosage in response to aerobic exercise training and deconditioning in human skeletal muscle. I: Cells. 2019 ; Bind 8, Nr. 3.

Bibtex

@article{de81e776af2a4af4aef0542628c3ee80,
title = "Adaptations in mitochondrial enzymatic activity occurs independent of genomic dosage in response to aerobic exercise training and deconditioning in human skeletal muscle",
abstract = "Mitochondrial DNA (mtDNA) replication is thought to be an integral part of exercise-training-induced mitochondrial adaptations. Thus, mtDNA level is often used as an index of mitochondrial adaptations in training studies. We investigated the hypothesis that endurance exercise training-induced mitochondrial enzymatic changes are independent of genomic dosage by studying mtDNA content in skeletal muscle in response to six weeks of knee-extensor exercise training followed by four weeks of deconditioning in one leg, comparing results to the contralateral untrained leg, in 10 healthy, untrained male volunteers. Findings were compared to citrate synthase activity, mitochondrial complex activities, and content of mitochondrial membrane markers (porin and cardiolipin). One-legged knee-extensor exercise increased endurance performance by 120%, which was accompanied by increases in power output and peak oxygen uptake of 49% and 33%, respectively (p < 0.01). Citrate synthase and mitochondrial respiratory chain complex I⁻IV activities were increased by 51% and 46⁻61%, respectively, in the trained leg (p < 0.001). Despite a substantial training-induced increase in mitochondrial activity of TCA and ETC enzymes, there was no change in mtDNA and mitochondrial inner and outer membrane markers (i.e. cardiolipin and porin). Conversely, deconditioning reduced endurance capacity by 41%, muscle citrate synthase activity by 32%, and mitochondrial complex I⁻IV activities by 29⁻36% (p < 0.05), without any change in mtDNA and porin and cardiolipin content in the previously trained leg. The findings demonstrate that the adaptations in mitochondrial enzymatic activity after aerobic endurance exercise training and the opposite effects of deconditioning are independent of changes in the number of mitochondrial genomes, and likely relate to changes in the rate of transcription of mtDNA.",
keywords = "Faculty of Science, mtDNA, Mitochondria, Skeletal muscle, Exercise training, Mitochondrial biogenesis",
author = "Fritzen, {Andreas M{\ae}chel} and Th{\o}gersen, {Frank B} and Kasper Thybo and Vissing, {Christoffer Rasmus} and Krag, {Thomas O} and Cristina Ruiz-Ruiz and Lotte Risom and Flemming Wibrand and H{\o}eg, {Louise Dalgas} and Bente Kiens and Morten Duno and John Vissing and Jeppesen, {Tina Dysgaard}",
note = "CURIS 2019 NEXS 095",
year = "2019",
doi = "10.3390/cells8030237",
language = "English",
volume = "8",
journal = "Cells",
issn = "2073-4409",
publisher = "MDPI AG",
number = "3",

}

RIS

TY - JOUR

T1 - Adaptations in mitochondrial enzymatic activity occurs independent of genomic dosage in response to aerobic exercise training and deconditioning in human skeletal muscle

AU - Fritzen, Andreas Mæchel

AU - Thøgersen, Frank B

AU - Thybo, Kasper

AU - Vissing, Christoffer Rasmus

AU - Krag, Thomas O

AU - Ruiz-Ruiz, Cristina

AU - Risom, Lotte

AU - Wibrand, Flemming

AU - Høeg, Louise Dalgas

AU - Kiens, Bente

AU - Duno, Morten

AU - Vissing, John

AU - Jeppesen, Tina Dysgaard

N1 - CURIS 2019 NEXS 095

PY - 2019

Y1 - 2019

N2 - Mitochondrial DNA (mtDNA) replication is thought to be an integral part of exercise-training-induced mitochondrial adaptations. Thus, mtDNA level is often used as an index of mitochondrial adaptations in training studies. We investigated the hypothesis that endurance exercise training-induced mitochondrial enzymatic changes are independent of genomic dosage by studying mtDNA content in skeletal muscle in response to six weeks of knee-extensor exercise training followed by four weeks of deconditioning in one leg, comparing results to the contralateral untrained leg, in 10 healthy, untrained male volunteers. Findings were compared to citrate synthase activity, mitochondrial complex activities, and content of mitochondrial membrane markers (porin and cardiolipin). One-legged knee-extensor exercise increased endurance performance by 120%, which was accompanied by increases in power output and peak oxygen uptake of 49% and 33%, respectively (p < 0.01). Citrate synthase and mitochondrial respiratory chain complex I⁻IV activities were increased by 51% and 46⁻61%, respectively, in the trained leg (p < 0.001). Despite a substantial training-induced increase in mitochondrial activity of TCA and ETC enzymes, there was no change in mtDNA and mitochondrial inner and outer membrane markers (i.e. cardiolipin and porin). Conversely, deconditioning reduced endurance capacity by 41%, muscle citrate synthase activity by 32%, and mitochondrial complex I⁻IV activities by 29⁻36% (p < 0.05), without any change in mtDNA and porin and cardiolipin content in the previously trained leg. The findings demonstrate that the adaptations in mitochondrial enzymatic activity after aerobic endurance exercise training and the opposite effects of deconditioning are independent of changes in the number of mitochondrial genomes, and likely relate to changes in the rate of transcription of mtDNA.

AB - Mitochondrial DNA (mtDNA) replication is thought to be an integral part of exercise-training-induced mitochondrial adaptations. Thus, mtDNA level is often used as an index of mitochondrial adaptations in training studies. We investigated the hypothesis that endurance exercise training-induced mitochondrial enzymatic changes are independent of genomic dosage by studying mtDNA content in skeletal muscle in response to six weeks of knee-extensor exercise training followed by four weeks of deconditioning in one leg, comparing results to the contralateral untrained leg, in 10 healthy, untrained male volunteers. Findings were compared to citrate synthase activity, mitochondrial complex activities, and content of mitochondrial membrane markers (porin and cardiolipin). One-legged knee-extensor exercise increased endurance performance by 120%, which was accompanied by increases in power output and peak oxygen uptake of 49% and 33%, respectively (p < 0.01). Citrate synthase and mitochondrial respiratory chain complex I⁻IV activities were increased by 51% and 46⁻61%, respectively, in the trained leg (p < 0.001). Despite a substantial training-induced increase in mitochondrial activity of TCA and ETC enzymes, there was no change in mtDNA and mitochondrial inner and outer membrane markers (i.e. cardiolipin and porin). Conversely, deconditioning reduced endurance capacity by 41%, muscle citrate synthase activity by 32%, and mitochondrial complex I⁻IV activities by 29⁻36% (p < 0.05), without any change in mtDNA and porin and cardiolipin content in the previously trained leg. The findings demonstrate that the adaptations in mitochondrial enzymatic activity after aerobic endurance exercise training and the opposite effects of deconditioning are independent of changes in the number of mitochondrial genomes, and likely relate to changes in the rate of transcription of mtDNA.

KW - Faculty of Science

KW - mtDNA

KW - Mitochondria

KW - Skeletal muscle

KW - Exercise training

KW - Mitochondrial biogenesis

U2 - 10.3390/cells8030237

DO - 10.3390/cells8030237

M3 - Journal article

C2 - 30871120

VL - 8

JO - Cells

JF - Cells

SN - 2073-4409

IS - 3

M1 - 237

ER -

ID: 215031441