Project description:Aerobic training remodels the quantity and quality (function per unit) of skeletal muscle mitochondria to promote substrate oxidation, however, there remain key gaps in understanding the underlying mechanisms during initial training adaptations. We used short-term high-intensity interval training (HIIT) to determine changes to mitochondrial respiration and regulatory pathways that occur early in remodeling. Fifteen normal-weight sedentary adults started seven sessions of HIIT over fourteen days and fourteen participants completed the intervention. We collected vastus lateralis biopsies before and 48-hours after HIIT to determine mitochondrial respiration, RNA sequencing, and western blotting for proteins of mitochondrial respiration and degradation via autophagy. HIIT increased respiration per mitochondrial protein for lipid (+23% P=0.020), complex I (+18%, P=0.0015), complex I+II (+14%, P<0.0001) and complex II (+24% P<0.0001). Transcripts that increased with HIIT identified several gene sets of mitochondrial respiration, particularly for complex I, while transcripts that decreased identified pathways of DNA and chromatin remodeling. HIIT lowered protein abundance of autophagy markers for p62 (-19%, P=0.012) and LC3 II/I (-20%, P=0.004) in whole-tissue lysates but not isolated mitochondria. Meal tolerance testing revealed HIIT increased the change in whole-body respiratory exchange ratio and lowered cumulative plasma insulin concentrations. Gene transcripts and respiratory function indicate remodeling of mitochondria within 2 weeks of HIIT. Overall changes are consistent with increased protein quality driving rapid improvements in substrate oxidation.

Project description:Elderly AA volunteers confirmed MCI assigned into a six-month program of aerobic exercise (eleven participants) underwent a 40-minute supervised-training 3-times/week and controls (eight participants) performed stretch training. Participants had maximal oxygen consumption (VO2max) test and Genome-wide methylation levels at CpG sites using the Infinium HumanMethylation450 BeadChip assay at baseline and after a six-month exercise program.

Project description:To characterize phosphorylation-based signaling events across different exercise modalities we subjected eight healthy young men (age, 26.3±1.3 years; BMI, 23.5±0.7 kg/m2; maximal oxygen uptake (VO2 max), 42.6±1.5 ml/kg/min) that did not perform regular physical activity apart from local bicycling to an acute bout of endurance (90 min ~60% of VO2 max), sprint (3 x 30-s all-out cycling), or resistance exercise (6 sets of 10 RM knee extensions) in the fasting state. All participants completed the three types of exercise in a randomized crossover design with 14 days washout between each exercise bout.

Project description:This project aimed to characterize the impact of high-intensity interval exercise (HIIE) vs. moderate-intensity continuous exercise (MICE) on immune cell proteomics. In a randomized crossover study with 23 young, recreationally active runners, we isolated peripheral blood mononuclear cells (PBMCs) before, immediately after, and 1h after HIIE and MICE, respectively. After completion of the study, PBMCs were used to (i) quantify exercise-induced immune cell shifts within the PBMC compartment via flow cytometry and to (ii) perform untargeted proteomics via LC-MS/MS. The study was prospectively registered in the German Clinical Trials Register (DRKS00017686) and was approved by the local ethics committee of the German Sport University Cologne. Recreationally active runners between 18 and 35 years were considered eligible, given they did not demonstrate any previous medical record of muscle disorders, cardiac or renal diseases, or regular intake of medication or nutritional supplements. Participants were scheduled for a total of three visits to an exercise physiology laboratory of the German Sport University Cologne: baseline testing, a HIIE session, and a MICE session. All participants were asked to arrive overnight-fasted and to refrain from alcohol and caffeine intake in the 24 hours prior to each visit. All assessments were carried out between 07:00 and 10:00 am, to account for a potential circadian impact on performance and biological outcomes. The minimum timeframe between each of the three visits was 72 hours, to prevent potential carryover effects. During baseline testing, anthropometric and demographic characteristics of the participants were assessed, and a cardiopulmonary exercise test (CPET) was performed on a treadmill. Peak oxygen uptake (V̇O2peak) was calculated as the highest 15-second interval during the CPET. To prevent sequence effects participants were then randomized into one of two exercise intervention sequences: HIIE-MICE or MICE-HIIE. The randomization was carried out as concealed allocation (1:1) following the minimization procedure by Pock and Simon (REF) with age, BMI, and V̇O2peak as stratification factors. Exercise intensities for the HIIE and MICE session were calculated as percent of V̇O2peak for each participant to ensure that all participants exercised at the same intensity. The exercise conditions were matched for duration and energy expenditure as described previously (REF) to isolate exercise intensity as the only differing variable. During MICE participants performed a warm-up for 10 min at a self-selected intensity, followed by a 5 min break. Participants then ran for 50 min at 70 % of their V̇O2peak. During HIIE, participants performed 7 min of warm-up and cool-down at 70% V̇O2peak with six bouts of high-intensity running at 90 % V̇O2peak in between. Each high-intensity bout lasted 3 min, followed by 3 min of active recovery at 50 % V̇O2peak. For each measurement timepoint 24 mL of whole blood were drawn from a median antecubital vein into EDTA tubes.

Project description:The molecular transducers of benefits from different exercise modalities remain incompletely defined. Here we report that 12 weeks of high-intensity aerobic interval (HIIT), resistance (RT), and combined exercise training enhanced insulin sensitivity and lean mass, but only HIIT and combined training improved aerobic capacity and skeletal muscle mitochondrial respiration. HIIT revealed a more robust increase in gene transcripts than other exercise modalities, particularly in older adults, although little overlap with corresponding individual protein abundance was noted. HIIT reversed many age-related differences in the proteome, particularly of mitochondrial proteins in concert with increased mitochondrial protein synthesis. Both RT and HIIT enhanced proteins involved in translational machinery irrespective of age. Only small changes of methylation of DNA promoter regions were observed. We provide evidence for predominant exercise regulation at the translational level, enhancing translational capacity and proteome abundance to explain phenotypic gains in muscle mitochondrial function and hypertrophy in all ages.

Project description:High-intensity intermittent exercise training (HIIT) has been proposed as an effective approach for improving both anaerobic and aerobic capacities. However, the molecular response of muscles to HIIT remains unknown. We used microarray to examine the effects of HIIT on global gene expression in human skeletal muscle.

Project description:The increasing consumption of high-fat western foods combined with a lack of exercise is a major contributor to the burden of obesity in humans. Aerobic exercise such as running is known to provide metabolic benefits, but how the over-consumption of a high fat diet (HFD) and exercise interact is not well characterized at the molecular level. Here, we examined the plasma proteome in mice for the effects of aerobic exercise as both a treatment and as a preventative regime for animals on either HFD or a healthy control diet. This analysis detected large changes in the plasma proteome induced by the HFD intervention, such as increased abundance of SERPINA7, ALDOB, APOE, and down-regulation of SERPINA1E, CFD (adipsin), LIFR. Some of these changes were only significantly reverted using aerobic exercise as a preventative measure, but not as a treatment regime. To determine if either the intensity, or duration, of exercise influenced the outcome, we compared high-intensity interval training (HIIT) and endurance running. Endurance running slightly outperformed HIIT exercise, but overall both provided similar reversion in abundance of plasma proteins modulated by the high-fat diet including SERPINA7, APOE, SERPINA1E, and CFD. Finally, we compared the changes induced by over-consumption of HFD to previous data from mice fed an isocaloric high saturated fat (SFA) or polyunsaturated fat (PUFA) diet. This identified several common changes including increased APOC2 and APOE, but also highlighted changes specific for either over-consumption of HFD (ALDOB, SERPINA7, CFD), SFA-based diets (SERPINA1E), or PUFA-based diets (Haptoglobin - Hp). Together, these data highlight the importance of early intervention with exercise to revert HFD-induced phenotypes and suggest some of the molecular mechanisms leading to the changes in the plasma proteome generated by high fat diet consumption in both mice and humans.

Project description:Skeletal muscle tissue is a highly adaptable tissue, responding to the specific demands it is subjected to. High-intensity interval training (HIIT) has been shown to generate similar, or even greater, molecular changes in skeletal muscle as that of constant load longer-lasting endurance-type training at moderate intensities. Despite shorter exposure times, the higher intensity provided by HIIT training leads to greater metabolic perturbations and thereby larger improvements in mitochondrial content and maximal oxygen uptake. During a period of regular exercise training, the performance improvements follow a non-linear pattern with a relatively faster pace initially and a gradual ‘plateauing-off’ after weeks and months. It is believed that this ‘plateau effect’ is due to a blunting of the molecular responses to acute exercise with exercise training. In the present study we utilised an explorative global transcriptomic approach to investigate the phenomenon of transcriptional-level blunting of the acute exercise response in human skeletal muscle over the course of a three-week HIIT intervention. We hypothesize that the blunting of transcription at this time-point is specific to certain pathways, including metabolic regulation and that these genes have communal transcriptional regulation.

Project description:We profiled gene expression of pelleted material containing platelets from frozen plasma of healthy controls and ME/CFS cases for bulk RNA-seq, collected before and 24h after participants conducted a cardiopulmonary exercise test (CPET).

Project description:High intensity exercise (HIE) has become a prominent training modality used to ameliorate cardiac disease conditions. The effects of HIE training on Hypertrophic Cardiomyopathy (HCM) have not been previously studied in animal models or in patients, largely due to concerns about triggering sudden arrhythmic events. Employing a transgenic cardiac troponin (cTnT-160E or TG) preclinical murine model that closely recapitulates human HCM, we evaluated the effects of a High Intensity Interval Training (HIIT) protocol on cardiorespiratory capacity (i.e., peak oxygen consumption or pVO2), which is a significant prognostic indicator of disease trajectory. 14 month old TG male mice had lower peak VO2 than non-transgenic (NTG) male mice of the same age at baseline, but there was no difference in pVO2 in female TG compared to nTG mice. HIIT significantly improved pVO2 in both nTG female (18%) , nTG male (18%), TG female (16%) and TG male (12%) mice compared to sedentary controls. There were no changes in structure, function or LV mass as measured by echocardiography or post mortem analyses in any of the groups, and no effect of HIIT on cardiac fibrosis. HIIT led to significant increases in lean muscle mass in both nTG and TG male mice, and nTG female mice but not TG female mice. The results of our study provide foundational evidence that HIE can improve pVO2 in HCM without adverse effects on disease phenotype.