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2. Pharmacological but not physiological GDF15 suppresses feeding and the motivation to exercise

Author

Klein, Anders B., Nicolaisen, Trine S., Ørtenblad, Niels, Gejl, Kasper D., Jensen, Rasmus, Fritzen, Andreas M., Larsen, Emil L., Karstoft, Kristian, Poulsen, Henrik E., Morville, Thomas, Sahl, Ronni E., Helge, Jørn W., Lund, Jens, Falk, Sarah, Lyngbæk, Mark, Ellingsgaard, Helga, Pedersen, Bente K., Lu, Wei, Finan, Brian, Jørgensen, Sebastian B., Seeley, Randy J., Kleinert, Maximilian, Kiens, Bente, Richter, Erik A., and Clemmensen, Christoffer

Published
2021
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6. Short term intensified training temporarily impairs mitochondrial respiratory capacity in elite endurance athletes.

Author

Cardinale, Daniele A., Gejl, Kasper D, Petersen, Kristine Grøsfjeld, Nielsen, Joachim, Ørtenblad, Niels, Larsen, Filip J, Cardinale, Daniele A., Gejl, Kasper D, Petersen, Kristine Grøsfjeld, Nielsen, Joachim, Ørtenblad, Niels, and Larsen, Filip J

Abstract

AIM: The maintenance of healthy and functional mitochondria is the result of a complex mitochondrial turnover and herein quality-control program which includes both mitochondrial biogenesis and autophagy of mitochondria. The aim of this study was to examine the effect of an intensified training load on skeletal muscle mitochondrial quality control in relation to changes in mitochondrial oxidative capacity, maximal oxygen consumption and performance in highly trained endurance athletes. METHODS: 27 elite endurance athletes performed high intensity interval exercise followed by moderate intensity continuous exercise 3 days per week for 4 weeks in addition to their usual volume of training. Mitochondrial oxidative capacity, abundance of mitochondrial proteins, markers of autophagy and antioxidant capacity of skeletal muscle were assessed in skeletal muscle biopsies before and after the intensified training period. RESULTS: The intensified training period increased several autophagy markers suggesting an increased turnover of mitochondrial and cytosolic proteins. In permeabilized muscle fibers, mitochondrial respiration was ~20 % lower after training although some markers of mitochondrial density increased by 5-50%, indicative of a reduced mitochondrial quality by the intensified training intervention. The antioxidative proteins UCP3, ANT1, and SOD2 were increased after training, whereas we found an inactivation of aconitase. In agreement with the lower aconitase activity, the amount of mitochondrial LON protease that selectively degrades oxidized aconitase, was doubled. CONCLUSION: Together, this suggests that mitochondrial respiratory function is impaired during the initial recovery from a period of intensified endurance training while mitochondrial quality control is slightly activated in highly trained skeletal muscle.

Published
2021
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7. Comment on: 'Changes in Skeletal Muscle Glycogen Content in Professional Soccer Players before and after a Match by a NonInvasive MuscleSound® Technology. A Cross Sectional Pilot Study Nutrients 2020, 12(4), 971'

Author

Ørtenblad, Niels, Nielsen, Joachim, Gejl, Kasper D., Routledge, Harry E., Morton, James P., Close, Graeme L., Niemann, David C., Bone, Julia L., and Burke, Louise M.

Subjects
Adult, Male, Muscle, Skeletal/diagnostic imaging, GeneralLiterature_INTRODUCTORYANDSURVEY, Pilot Projects, lcsh:TX341-641, Glycogen/metabolism, Ultrasonography/methods, Young Adult, Cross-Sectional Studies, n/a, Athletes, Soccer, Humans, lcsh:Nutrition. Foods and food supply, ComputingMilieux_MISCELLANEOUS
Abstract

San-Millán and colleagues [...].

Published
2020

9. Pharmacological but not physiological GDF15 suppresses feeding and the motivation to exercise

Author

Klein, Anders B., primary, Nicolaisen, Trine S., additional, Ørtenblad, Niels, additional, Gejl, Kasper D., additional, Jensen, Rasmus, additional, Fritzen, Andreas M., additional, Larsen, Emil L., additional, Karstoft, Kristian, additional, Poulsen, Henrik E., additional, Morville, Thomas, additional, Sahl, Ronni E., additional, Helge, Jørn W., additional, Lund, Jens, additional, Falk, Sarah, additional, Lyngbæk, Mark, additional, Ellingsgaard, Helga, additional, Pedersen, Bente K., additional, Lu, Wei, additional, Finan, Brian, additional, Jørgensen, Sebastian B., additional, Seeley, Randy J., additional, Kleinert, Maximilian, additional, Kiens, Bente, additional, Richter, Erik A., additional, and Clemmensen, Christoffer, additional

Published
2020
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11. Changes in metabolism but not myocellular signaling by training with CHO-restriction in endurance athletes

Author

Gejl, Kasper D., Vissing, Kristian, Hansen, Mette, Thams, Line, Rokkedal-Lausch, Torben, Plomgaard, Peter, Lundby, Anne-Kristine Meinild, Nybo, Lars, Jensen, Kurt, Holmberg, Hans-Christer, Ørtenblad, Niels, Gejl, Kasper D., Vissing, Kristian, Hansen, Mette, Thams, Line, Rokkedal-Lausch, Torben, Plomgaard, Peter, Lundby, Anne-Kristine Meinild, Nybo, Lars, Jensen, Kurt, Holmberg, Hans-Christer, and Ørtenblad, Niels

Abstract

Carbohydrate (CHO) restricted training has been shown to increase the acute training response, whereas less is known about the acute effects after repeated CHO restricted training. On two occasions, the acute responses to CHO restriction were examined in endurance athletes. Study 1 examined cellular signaling and metabolic responses after seven training-days including CHO manipulation (n = 16). The protocol consisted of 1 h high-intensity cycling, followed by 7 h recovery, and 2 h of moderate-intensity exercise (120SS). Athletes were randomly assigned to low (LCHO: 80 g) or high (HCHO: 415 g) CHO during recovery and the 120SS. Study 2 examined unaccustomed exposure to the same training protocol (n = 12). In Study 1, muscle biopsies were obtained at rest and 1 h after 120SS, and blood samples drawn during the 120SS. In Study 2, substrate oxidation and plasma glucagon were determined. In Study 1, plasma insulin and proinsulin C-peptide were higher during the 120SS in HCHO compared to LCHO (insulin: 0 min: +37%; 60 min: +135%; 120 min: +357%, P = 0.05; proinsulin C-peptide: 0 min: +32%; 60 min: +52%; 120 min: +79%, P = 0.02), whereas plasma cholesterol was higher in LCHO (+15-17%, P = 0.03). Myocellular signaling did not differ between groups. p-AMPK and p-ACC were increased after 120SS (+35%, P = 0.03; +59%, P = 0.0004, respectively), with no alterations in p-p38, p-53, or p-CREB. In Study 2, glucagon and fat oxidation were higher in LCHO compared to HCHO during the 120SS (+26-40%, P = 0.03; +44-76%, P = 0.01 respectively). In conclusion, the clear respiratory and hematological effects of CHO restricted training were not translated into superior myocellular signaling after accustomization to CHO restriction.

Published
2018
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12. Reliability of maximal mitochondrial oxidative phosphorylation in permeabilized fibers from the vastus lateralis employing high-resolution respirometry.

Author

Cardinale, Daniele A, Gejl, Kasper D, Ørtenblad, Niels, Ekblom, Bjorn, Blomstrand, Eva, Larsen, Filip J, Cardinale, Daniele A, Gejl, Kasper D, Ørtenblad, Niels, Ekblom, Bjorn, Blomstrand, Eva, and Larsen, Filip J

Abstract

The purpose was to assess the impact of various factors on methodological errors associated with measurement of maximal oxidative phosphorylation (OXPHOS) in human skeletal muscle determined by high-resolution respirometry in saponin-permeabilized fibers. Biopsies were collected from 25 men to assess differences in OXPHOS between two muscle bundles and to assess the correlation between OXPHOS and the wet weight of the muscle bundle. Biopsies from left and right thighs of another five subjects were collected on two occasions to compare limbs and time-points. A single muscle specimen was used to assess effects of the anesthetic carbocaine and the influence of technician. The difference in OXPHOS between two fiber-bundles from the same biopsy exhibited a standard error of measurement (SEM) of 10.5 pmol · s-1 · mg-1 and a coefficient of variation (CV) of 15.2%. The differences between left and right thighs and between two different time-points had SEMs of 9.4 and 15.2 pmol · s-1 · mg-1 and CVs of 23.9% and 33.1%, respectively. The average (±SD) values obtained by two technicians monitoring different bundles of fibers from the same biopsy were 31.3 ± 7.1 and 26.3 ± 8.1 pmol · s-1 · mg-1 . The time that elapsed after collection of the biopsy (up to a least 5 h in preservation medium), wet weight of the bundle (from 0.5 to 4.5 mg) and presence of an anesthetic did not influence OXPHOS. The major source of variation in OXPHOS measurements is the sample preparation. The thigh involved, time-point of collection, size of fiber bundles, and time that elapsed after biopsy had minor or no effect.

Published
2018
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14. Local depletion of glycogen with supra-maximal exercise in human skeletal muscle fibres

Author

Gejl, Kasper D., Ørtenblad, Niels, Andersson, Erik, Plomgaard, Peter, Holmberg, Hans-Christer, and Nielsen, Joachim

Subjects
Adult, Male, Medicin och hälsovetenskap, Muscle Fibers, Skeletal/metabolism, Oxygen Consumption, electron microscopy, exercise, glycogen, Humans, muscle fatigue, Glycogen/metabolism, skeletal muscle, Medical and Health Sciences
Abstract

Key points: Glycogen is stored in local spatially distinct compartments within skeletal muscle fibres and is the main energy source during supramaximal exercise. Using quantitative electron microscopy, we show that supramaximal exercise induces a differential depletion of glycogen from these compartments and also demonstrate how this varies with fibre types. Repeated exercise alters this compartmentalized glycogen depletion. The results obtained in the present study help us understand the muscle metabolic dynamics of whole body repeated supramaximal exercise, and suggest that the muscle has a compartmentalized local adaptation to repeated exercise, which affects glycogen depletion. Abstract: Skeletal muscle glycogen is heterogeneously distributed in three separated compartments (intramyofibrillar, intermyofibrillar and subsarcolemmal). Although only constituting 3–13% of the total glycogen volume, the availability of intramyofibrillar glycogen is of particular importance to muscle function. The present study aimed to investigate the depletion of these three subcellular glycogen compartments during repeated supramaximal exercise in elite athletes. Ten elite cross-country skiers (aged 25 ± 4 years, V O2max : 65 ± 4 ml kg −1 min −1 ; mean ± SD) performed four ∼4 min supramaximal sprint time trials (STT 1–4) with 45 min of recovery. The subcellular glycogen volumes in musculus triceps brachii were quantified from electron microscopy images before and after both STT 1 and 4. During STT 1, the depletion of intramyofibrillar glycogen was higher in type 1 fibres [−52%; (−89:−15%)] than type 2 fibres [−15% (−52:22%)] (P = 0.02), whereas the depletion of intermyofibrillar glycogen [main effect: −19% (−33:0%), P = 0.006] and subsarcolemmal glycogen [main effect: −35% (−66:0%), P = 0.03] was similar between fibre types. By contrast, only intermyofibrillar glycogen volume was significantly reduced during STT 4, in both fibre types [main effect: −31% (−50:−11%), P = 0.002]. Furthermore, for each of the subcellular compartments, the depletion of glycogen during STT 1 was associated with the volumes of glycogen before STT 1. In conclusion, the depletion of spatially distinct glycogen compartments differs during supramaximal exercise. Furthermore, the depletion changes with repeated exercise and is fibre type-dependent.

Published
2017

15. Plasticity in mitochondrial cristae density allows metabolic capacity modulation in human skeletal muscle

Author

Nielsen, Joachim, Gejl, Kasper D, Hey-Mogensen, Martin, Holmberg, Hans-Christer, Suetta, Charlotte, Krustrup, Peter, Elemans, Coen P H, and Ørtenblad, Niels

Subjects
Male, Adult, Muscle, Skeletal/metabolism, electron microscopy, Idrottsvetenskap, muscle metabolism, Mitochondria, Muscle/metabolism, Middle Aged, mitochondria, oxygen uptake, Oxygen Consumption, Humans, Animals, Female, Finches, skeletal muscle, Energy Metabolism, Exercise, Sport and Fitness Sciences
Abstract

Key points: In human skeletal muscles, the current view is that the capacity for mitochondrial energy production, and thus endurance capacity, is set by the mitochondria volume. However, increasing the mitochondrial inner membrane surface comprises an alternative mechanism for increasing the energy production capacity. In the present study, we show that mitochondrial inner membranes in leg muscles of endurance-trained athletes have an increased ratio of surface per mitochondrial volume. We show a positive correlation between this ratio and whole body oxygen uptake and muscle fibre mitochondrial content. The results obtained in the present study help us to understand modulation of mitochondrial function, as well as how mitochondria can increase their oxidative capacity with increased demand. Abstract: Mitochondrial energy production involves the movement of protons down a large electrochemical gradient via ATP synthase located on the folded inner membrane, known as cristae. In mammalian skeletal muscle, the density of cristae in mitochondria is assumed to be constant. However, recent experimental studies have shown that respiration per mitochondria varies. Modelling studies have hypothesized that this variation in respiration per mitochondria depends on plasticity in cristae density, although current evidence for such a mechanism is lacking. In the present study, we confirm this hypothesis by showing that, in human skeletal muscle, and in contrast to the current view, the mitochondrial cristae density is not constant but, instead, exhibits plasticity with long-term endurance training. Furthermore, we show that frequently recruited mitochondria-enriched fibres have significantly increased cristae density and that, at the whole-body level, muscle mitochondrial cristae density is a better predictor of maximal oxygen uptake rate than muscle mitochondrial volume. Our findings establish an elevating mitochondrial cristae density as a regulatory mechanism for increasing metabolic power in human skeletal muscle. We propose that this mechanism allows evasion of the trade-off between cell occupancy by mitochondria and other cellular constituents, as well as improved metabolic capacity and fuel catabolism during prolonged elevated energy requirements.

Published
2017

16. Is there plasticity in mitochondrial cristae density with endurance training? : Reply

Author

Nielsen, Joachim, Gejl, Kasper D., and Ørtenblad, Niels

Subjects
Idrottsvetenskap, Human muscle, Transmission electron microscopy, Sport and Fitness Sciences, Mitochondria
Abstract

This is a reply to a Letter to the Editor by Larsen et al. To read the Letter to the Editor, visit https://doi.org/10.1113/JP273793

Published
2017

17. Changes in metabolism but not myocellular signaling by training with CHO-restriction in endurance athletes

Author

Gejl, Kasper D., primary, Vissing, Kristian, additional, Hansen, Mette, additional, Thams, Line, additional, Rokkedal-Lausch, Torben, additional, Plomgaard, Peter, additional, Meinild Lundby, Anne-Kristine, additional, Nybo, Lars, additional, Jensen, Kurt, additional, Holmberg, Hans-Christer, additional, and Ørtenblad, Niels, additional

Published
2018
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23. Carbohydrate restricted recovery from long term endurance exercise does not affect gene responses involved in mitochondrial biogenesis in highly trained athletes

Author

Jensen, Line, Gejl, Kasper D., Ørtenblad, Niels, Nielsen, Jakob L., Bech, Rune D., Nygaard, Tobias, Sahlin, Kent, Frandsen, Ulrik, Jensen, Line, Gejl, Kasper D., Ørtenblad, Niels, Nielsen, Jakob L., Bech, Rune D., Nygaard, Tobias, Sahlin, Kent, and Frandsen, Ulrik

Abstract

The aim was to determine if the metabolic adaptations, particularly PGC-1a and downstream metabolic genes were affected by restricting CHO following an endurance exercise bout in trained endurance athletes. A second aim was to compare baseline expression level of these genes to untrained. Elite endurance athletes (VO2max 66 ± 2 mL·kg-1·min-1, n = 15) completed 4 h cycling at ~56% VO2max. During the first 4 h recovery subjects were provided with either CHO or only H2O and thereafter both groups received CHO. Muscle biopsies were collected before, after, and 4 and 24 h after exercise. Also, resting biopsies were collected from untrained subjects (n = 8). Exercise decreased glycogen by 67.7 ± 4.0% (from 699 ± 26.1 to 239 ± 29.5 mmol·kg-1·dw-1) with no difference between groups. Whereas 4 h of recovery with CHO partly replenished glycogen, the H2O group remained at post exercise level; nevertheless, the gene expression was not different between groups. Glycogen and most gene expression levels returned to baseline by 24 h in both CHO and H2O. Baseline mRNA expression of NRF-1, COX-IV, GLUT4 and PPAR-α gene targets were higher in trained compared to untrained. Additionally, the proportion of type I muscle fibers positively correlated with baseline mRNA for PGC-1α, TFAM, NRF-1, COX-IV, PPAR-α, and GLUT4 for both trained and untrained. CHO restriction during recovery from glycogen depleting exercise does not improve the mRNA response of markers of mitochondrial biogenesis. Further, baseline gene expression of key metabolic pathways is higher in trained than untrained.

Published
2015
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25. Local depletion of glycogen with supramaximal exercise in human skeletal muscle fibres.

Author

Gejl, Kasper D., Ørtenblad, Niels, Andersson, Erik, Plomgaard, Peter, Holmberg, Hans‐Christer, and Nielsen, Joachim

Subjects
*SKELETAL muscle, *GLYCOGEN, *ELECTRON microscopy, *ANAEROBIC exercises, *MUSCLE metabolism, *GENETICS
Abstract

Key points Glycogen is stored in local spatially distinct compartments within skeletal muscle fibres and is the main energy source during supramaximal exercise., Using quantitative electron microscopy, we show that supramaximal exercise induces a differential depletion of glycogen from these compartments and also demonstrate how this varies with fibre types., Repeated exercise alters this compartmentalized glycogen depletion., The results obtained in the present study help us understand the muscle metabolic dynamics of whole body repeated supramaximal exercise, and suggest that the muscle has a compartmentalized local adaptation to repeated exercise, which affects glycogen depletion., Abstract Skeletal muscle glycogen is heterogeneously distributed in three separated compartments (intramyofibrillar, intermyofibrillar and subsarcolemmal). Although only constituting 3-13% of the total glycogen volume, the availability of intramyofibrillar glycogen is of particular importance to muscle function. The present study aimed to investigate the depletion of these three subcellular glycogen compartments during repeated supramaximal exercise in elite athletes. Ten elite cross-country skiers (aged 25 ± 4 years [ABSTRACT FROM AUTHOR]

Published
2017
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26. Repeated sprint exercise impairs contractile force of isolated single human muscle fibers

Author

Örtenblad, Niels, Hvid, Lars G, Jensen, Rasmus, Andersson, Erik, Willis, Sarah J, Holmberg, Hans-Christer, Gejl, Kasper D, Örtenblad, Niels, Hvid, Lars G, Jensen, Rasmus, Andersson, Erik, Willis, Sarah J, Holmberg, Hans-Christer, and Gejl, Kasper D

Abstract

INTRODUCTION: The purpose of the present study was, to examine the effects of repeated sprint skiing on the contractile apparatus of single muscle fibres obtained from a group of elite skiers. We have recently demonstrated that prolonged cycling exercise impairs the contractile apparatus of single muscle fibres, and that this can be restored following recovery. However, little is known about the effect of repeated high intensity exercise on single fibre properties, as i.e. during cross-country (cc) sprint competitions. We hypothesize that repeated high intensity exercise in highly trained subjects will impair the contractile apparatus maximum force output. METHOD: Eleven elite male sprint talented cc skiers (age 24 ± 4 years; VO2max 5.1 ± 0.5 (diagonal skiing, DIA), 4.9 ± 0.5 (double pooling, DP) L·min-1)) volunteered for the study. The skiers performed a simulated intermittent classic sprint roller skiing competition on a treadmill. The sprint exercise included 4 times1300m, with 45 min recovery between sprints. Each sprint consisted of 3 DP sections (1° uphill) and 2 DIA sections (7° uphill). Muscle biopsies were obtained in arm muscle (m. biceps brachii) before and after the sprint exercises. Muscle fibre bundles were cooled and skinned in a glycerinating solution and stored until analyzed. Single muscle fibre segments (n=232) were isolated and attached to a sensitive force recording transducer, and activated by Ca2+ buffered solutions at pH 7.1 to measure mechanically properties (maximum force Po and Po/cross sectional area (CSA)) and fibre typed by the Sr2+ sensitivity (Hvid et al. 2013). RESULTS: Average sprint time was 3min 49s ± 9s, with no difference between sprints. A total of 232 fibres were analysed (150 type I and 82 type II fibres). Type II fibres had a sign. (P<0.05) higher CSA (8103 ± 2334 µm2 (type I) and 8852 ± 2288 µm2 (type II) and Po (0.82 ± 0.43 and 1.24 ± 0.50 mN) than type I fibres. Also type II fibres had a 31% higher Po/CSA (108 ± 55 vs

Published
2013

27. Comment on: "Indirect Assessment of Skeletal Muscle Glycogen Content in Professional Soccer Players Before and After a Match Through a Non-Invasive Ultrasound Technology Nutrients 2020, 12(4), 971".

Author

Ørtenblad, Niels, Nielsen, Joachim, Gejl, Kasper D., Routledge, Harry E., Morton, James P., Close, Graeme L., Niemann, David C., Bone, Julia L., and Burke, Louise M.

Abstract

The article focuses on indirect assessment of skeletal muscle glycogen content in professional soccer players before and after a match through a non-invasive ultrasound technology nutrients. Topics discussed offer considerable applications in the field of team sports, and methodology is based on the correlation between skeletal muscle echogenicity (sound intensity) and the glycogen content from skeletal muscle biopsy.

Published
2020
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28. Comment on: "Changes in Skeletal Muscle Glycogen Content in Professional Soccer Players before and after a Match by a NonInvasive MuscleSound ® Technology. A Cross Sectional Pilot Study Nutrients 2020, 12(4), 971".

Author

Ørtenblad N, Nielsen J, Gejl KD, Routledge HE, Morton JP, Close GL, Niemann DC, Bone JL, and Burke LM

Subjects
Adult, Cross-Sectional Studies, Humans, Male, Pilot Projects, Young Adult, Athletes, Glycogen metabolism, Muscle, Skeletal diagnostic imaging, Muscle, Skeletal metabolism, Soccer, Ultrasonography methods
Abstract

San-Millán and colleagues [...].

Published
2020
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29. Skeletal muscle lipid droplets are resynthesized before being coated with perilipin proteins following prolonged exercise in elite male triathletes.

Author

Jevons EFP, Gejl KD, Strauss JA, Ørtenblad N, and Shepherd SO

Subjects
Adult, Bicycling physiology, Biopsy, Exercise physiology, Humans, Male, Muscle Fibers, Slow-Twitch physiology, Perilipin-2 genetics, Perilipin-2 metabolism, Perilipin-3 genetics, Perilipin-3 metabolism, Perilipin-5 genetics, Perilipin-5 metabolism, Physical Endurance, Triglycerides metabolism, Young Adult, Athletes, Lipid Droplets metabolism, Lipid Metabolism physiology, Lipids biosynthesis, Muscle, Skeletal physiology, Perilipins metabolism
Abstract

Intramuscular triglycerides (IMTG) are a key substrate during prolonged exercise, but little is known about the rate of IMTG resynthesis in the postexercise period. We investigated the hypothesis that the distribution of the lipid droplet (LD)-associated perilipin (PLIN) proteins is linked to IMTG storage following exercise. Fourteen elite male triathletes (27 ± 1 yr, 66.5 ± 1.3 mL·kg -1 ·min -1 ) completed 4 h of moderate-intensity cycling. During the first 4 h of recovery, subjects received either carbohydrate or H 2 O, after which both groups received carbohydrate. Muscle biopsies collected pre- and postexercise and 4 and 24 h postexercise were analyzed using confocal immunofluorescence microscopy for fiber type-specific IMTG content and PLIN distribution with LDs. Exercise reduced IMTG content in type I fibers (-53%, P = 0.002), with no change in type IIa fibers. During the first 4 h of recovery, IMTG content increased in type I fibers ( P = 0.014), but was not increased more after 24 h, where it was similar to baseline levels in both conditions. During recovery the number of LDs labeled with PLIN2 (70%), PLIN3 (63%), and PLIN5 (62%; all P < 0.05) all increased in type I fibers. Importantly, the increase in LDs labeled with PLIN proteins only occurred at 24 h postexercise. In conclusion, IMTG resynthesis occurs rapidly in type I fibers following prolonged exercise in highly trained individuals. Furthermore, increases in IMTG content following exercise preceded an increase in the number of LDs labeled with PLIN proteins. These data, therefore, suggest that the PLIN proteins do not play a key role in postexercise IMTG resynthesis.

Published
2020
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30. Reliability of maximal mitochondrial oxidative phosphorylation in permeabilized fibers from the vastus lateralis employing high-resolution respirometry.

Author

Cardinale DA, Gejl KD, Ørtenblad N, Ekblom B, Blomstrand E, and Larsen FJ

Subjects
Adult, Fluorometry methods, Fluorometry standards, Humans, Male, Muscle Fibers, Skeletal metabolism, Reactive Oxygen Species analysis, Reproducibility of Results, Spectrophotometry methods, Spectrophotometry standards, Mitochondria, Muscle metabolism, Oxidative Phosphorylation
Abstract

The purpose was to assess the impact of various factors on methodological errors associated with measurement of maximal oxidative phosphorylation (OXPHOS) in human skeletal muscle determined by high-resolution respirometry in saponin-permeabilized fibers. Biopsies were collected from 25 men to assess differences in OXPHOS between two muscle bundles and to assess the correlation between OXPHOS and the wet weight of the muscle bundle. Biopsies from left and right thighs of another five subjects were collected on two occasions to compare limbs and time-points. A single muscle specimen was used to assess effects of the anesthetic carbocaine and the influence of technician. The difference in OXPHOS between two fiber-bundles from the same biopsy exhibited a standard error of measurement (SEM) of 10.5 pmol · s -1  · mg -1 and a coefficient of variation (CV) of 15.2%. The differences between left and right thighs and between two different time-points had SEMs of 9.4 and 15.2 pmol · s -1  · mg -1 and CVs of 23.9% and 33.1%, respectively. The average (±SD) values obtained by two technicians monitoring different bundles of fibers from the same biopsy were 31.3 ± 7.1 and 26.3 ± 8.1 pmol · s -1  · mg -1 . The time that elapsed after collection of the biopsy (up to a least 5 h in preservation medium), wet weight of the bundle (from 0.5 to 4.5 mg) and presence of an anesthetic did not influence OXPHOS. The major source of variation in OXPHOS measurements is the sample preparation. The thigh involved, time-point of collection, size of fiber bundles, and time that elapsed after biopsy had minor or no effect., (© 2018 The Authors. Physiological Reports published by Wiley Periodicals, Inc. on behalf of The Physiological Society and the American Physiological Society.)

Published
2018
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31. Plasticity in mitochondrial cristae density allows metabolic capacity modulation in human skeletal muscle.

Author

Nielsen J, Gejl KD, Hey-Mogensen M, Holmberg HC, Suetta C, Krustrup P, Elemans CPH, and Ørtenblad N

Subjects
Adult, Animals, Female, Finches, Humans, Male, Middle Aged, Mitochondria, Muscle metabolism, Muscle, Skeletal physiology, Muscle, Skeletal ultrastructure, Oxygen Consumption, Energy Metabolism, Exercise, Mitochondria, Muscle ultrastructure, Muscle, Skeletal metabolism
Abstract

Key Points: In human skeletal muscles, the current view is that the capacity for mitochondrial energy production, and thus endurance capacity, is set by the mitochondria volume. However, increasing the mitochondrial inner membrane surface comprises an alternative mechanism for increasing the energy production capacity. In the present study, we show that mitochondrial inner membranes in leg muscles of endurance-trained athletes have an increased ratio of surface per mitochondrial volume. We show a positive correlation between this ratio and whole body oxygen uptake and muscle fibre mitochondrial content. The results obtained in the present study help us to understand modulation of mitochondrial function, as well as how mitochondria can increase their oxidative capacity with increased demand., Abstract: Mitochondrial energy production involves the movement of protons down a large electrochemical gradient via ATP synthase located on the folded inner membrane, known as cristae. In mammalian skeletal muscle, the density of cristae in mitochondria is assumed to be constant. However, recent experimental studies have shown that respiration per mitochondria varies. Modelling studies have hypothesized that this variation in respiration per mitochondria depends on plasticity in cristae density, although current evidence for such a mechanism is lacking. In the present study, we confirm this hypothesis by showing that, in human skeletal muscle, and in contrast to the current view, the mitochondrial cristae density is not constant but, instead, exhibits plasticity with long-term endurance training. Furthermore, we show that frequently recruited mitochondria-enriched fibres have significantly increased cristae density and that, at the whole-body level, muscle mitochondrial cristae density is a better predictor of maximal oxygen uptake rate than muscle mitochondrial volume. Our findings establish an elevating mitochondrial cristae density as a regulatory mechanism for increasing metabolic power in human skeletal muscle. We propose that this mechanism allows evasion of the trade-off between cell occupancy by mitochondria and other cellular constituents, as well as improved metabolic capacity and fuel catabolism during prolonged elevated energy requirements., (© 2016 The Authors. The Journal of Physiology © 2016 The Physiological Society.)

Published
2017
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