Muscle Metabolic Adaptations Research Articles

The effect of exercise and physical activity on skeletal muscle epigenetics and metabolic adaptations.

Physical activity (PA) and exercise elicit adaptations and physiological responses in skeletal muscle, which are advantageous for preserving health and minimizing chronic illnesses. The complicated atmosphere of the exercise response can be attributed to hereditary and environmental variables. The primary cause of these adaptations and physiological responses is the transcriptional reactions that follow exercise, whether endurance- (ET) or resistance- training (RT). As a result, the essential metabolic and regulatory pathways and myogenic genes associated with skeletal muscle alter in response to acute and chronic exercise. Epigenetics is the study of the relationship between genetics and the environment. Exercise evokes signaling pathways that strongly alter myofiber metabolism and skeletal muscle physiological and contractile properties. Epigenetic modifications have recently come to light as essential regulators of exercise adaptations. Research has shown various epigenetic markers linked to PA and exercise. The most critical epigenetic alterations in gene transcription identified are DNA methylation and histone modifications, which are associated with the transcriptional response of skeletal muscle to exercise and facilitate the modification to exercise. Other changes in the epigenetic markers are starting to emerge as essential processes for gene transcription, including acetylation as a new epigenetic modification, mediated changes by methylation, phosphorylation, and micro-RNA (miRNA). This review briefly introduces PA and exercise and associated benefits, provides a summary of epigenetic modifications, and a fundamental review of skeletal muscle physiology. The objectives of this review are 1) to discuss exercise-induced adaptations related to epigenetics and 2) to examine the interaction between exercise metabolism and epigenetics.

High-intensity interval training with blood-flow restriction enhances sprint and maximal aerobic power in male endurance athletes.

We investigated the concurrent impact of HIIT and blood-flow restriction (BFR) as a novel approach to further enhance maximal aerobic and anaerobic physiology and performances in trained athletes. In a randomized controlled trial, eighteen endurance-trained males (V ̇O2peak 65.6±5.1 ml.min-1.kg-1) included three sessions of HIIT per week (sets of 15-s efforts at 100% maximal aerobic power, interspersed by 15-s recovery) into their usual training for three weeks, either with restriction imposed on both lower limbs at 50-70% of arterial occlusion pressure (BFR group, n=10) or without (CTL group, n=8), and were tested for sprint and endurance exercise performance. The total mechanical work developed during a 30-sec Wingate test increased only in BFR (3.6%, P=0.02). During the Wingate, changes in near-infrared spectroscopy-derived vastus lateralis muscle oxygenation (Δ(deoxy[Hb+Mb]), % arterial occlusion) were attenuated after BFR training (-8.8%, P=0.04). The maximal aerobic power measured during an incremental cycling test increased only in BFR (4.5%, P=0.0004), but there was no change in V ̇O2peak among groups. Both groups improved 5-km cycling time trial performance, but BFR displayed a concomitant greater elevation in [H+] (11%, P=0.02). Changes in other blood variables (e.g., pH, lactate, bicarbonate and potassium ion concentration, hemoglobin) were not different between groups. Combining short-duration HIIT performed at 100% aerobic power with BFR elicited greater changes in sprint performance and maximal aerobic power in endurance athletes, associated with locomotor muscle metabolic adaptations but no meaningful effect on cardiorespiratory fitness.

Repeated sprint training in hypoxia induces specific skeletal muscle adaptations through S100A protein signaling.

Athletes increasingly engage in repeated sprint training consisting in repeated short all-out efforts interspersed by short recoveries. When performed in hypoxia (RSH), it may lead to greater training effects than in normoxia (RSN); however, the underlying molecular mechanisms remain unclear. This study aimed at elucidating the effects of RSH on skeletal muscle metabolic adaptations as compared to RSN. Sixteen healthy young men performed nine repeated sprint training sessions in either normoxia (FIO2 = 0.209, RSN, n = 7) or normobaric hypoxia (FIO2 = 0.136, RSH, n = 9). Before and after the training period, exercise performance was assessed by using repeated sprint ability (RSA) and Wingate tests. Vastus lateralis muscle biopsies were performed to investigate muscle metabolic adaptations using proteomics combined with western blot analysis. Similar improvements were observed in RSA and Wingate tests in both RSN and RSH groups. At the muscle level, RSN and RSH reduced oxidative phosphorylation protein content but triggered an increase in mitochondrial biogenesis proteins. Proteomics showed an increase in several S100A family proteins in the RSH group, among which S100A13 most strongly. We confirmed a significant increase in S100A13 protein by western blot in RSH, which was associated with increased Akt phosphorylation and its downstream targets regulating protein synthesis. Altogether our data indicate that RSH may activate an S100A/Akt pathway to trigger specific adaptations as compared to RSN.

Abstract 382: Pancreatic cancer-derived organoids alter muscle fiber type and increased energy consumption leading to cachexia

Abstract Cachexia, marked by continuous skeletal muscle mass loss and severe metabolic disturbances, presents a substantial challenge for pancreatic ductal adenocarcinoma (PDAC) patients. Despite its prevalence and the adverse impact on quality of life and survival rates, effective clinical treatments for cachexia remain elusive. This study aims to bridge this gap by employing innovative in vitro models to investigate the underlying mechanisms of cachexia and identify potential therapeutic targets. To enhance the relevance of cell culture models, modifications were introduced to replicate in vivo conditions, where the muscle is exposed to the ongoing kinetics of constant tumor secretion of active factors. Patient-derived PDAC cells were cultured in a dense 3D stiffness extracellular matrix (ECM) to mimic the hypoxic desmoplastic tumor microenvironment. The conditioned medium from prolonged cultured patient-derived organoids (PDOs) was then used to supplement C2C12-derived myotubes. The investigation focuses on dynamic adaptations in muscle fiber type and metabolism when exposed to tumor paracrine factors. Metabolomic investigations of PDO-conditioned medium (PDO CM) on myotubes revealed distinct metabolic differences compared to non-treatment controls. Discriminatory metabolites included those associated with glycolysis, lipid, amino acid, and fatty acid metabolism. PDO CM induced a significant shift in muscle fiber type from slow-twitch to fast-twitch phenotypes, accompanied by de novel expression of embryonic and neonatal Myosin Heavy Chain (MyHC) isoforms. Fast fiber (F59) staining also confirmed the protein expression. Concurrently, PGC-1a, a master regulator of mitochondrial biogenesis and oxidative metabolism, significantly decreased, along with reduced ATP and Mito tracker staining, indicating a metabolic switch under the influence of tumor paracrine factors. Metabolome results on C2C12 myotubes treated with PDO CM also revealed significantly changed ABC transporter-related pathways, an adaptive process required to optimize substrate use under the influence of tumor secretome. However, the genes involved in the proteasome degradation process, such as MAFbx and MuRF1, did not show altered expression. The establishment of an in vitro cachexia model, focusing on changes in energy metabolism and utilizing muscle fiber type alterations as markers, will deepen our understanding of the mechanisms of cancer-associated cachexia. The insights gained may pave the way for identifying potential therapeutic targets to mitigate muscle wasting in PDAC patients and improve overall outcomes. Citation Format: Bo Han, Shuqing Zhao, zhi Yang, Jose Trevino, Steven Grossman, Heinz-Josef Lenz, Ba Xuan Hoang. Pancreatic cancer-derived organoids alter muscle fiber type and increased energy consumption leading to cachexia [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 382.

The impact of bed rest on human skeletal muscle metabolism

Insulin sensitivity and metabolic flexibility decrease in response to bed rest, but the temporal and causal adaptations in human skeletal muscle metabolism are not fully defined. Here, we use an integrative approach to assess human skeletal muscle metabolism during bed rest and provide a multi-system analysis of how skeletal muscle and the circulatory system adapt to short- and long-term bed rest (German Clinical Trials: DRKS00015677). We uncover that intracellular glycogen accumulation after short-term bed rest accompanies a rapid reduction in systemic insulin sensitivity and less GLUT4 localization at the muscle cell membrane, preventing further intracellular glycogen deposition after long-term bed rest. We provide evidence of a temporal link between the accumulation of intracellular triglycerides, lipotoxic ceramides, and sphingomyelins and an altered skeletal muscle mitochondrial structure and function after long-term bed rest. An intracellular nutrient overload therefore represents a crucial determinant for rapid skeletal muscle insulin insensitivity and mitochondrial alterations after prolonged bed rest.

1627-P: Enhancer Regulator MLL4 Programs Skeletal Muscle Metabolic Efficiency by Limiting AMPK-Mediated Fuel Catabolism

Skeletal muscle adapts to nutrient availability and physiological demands by fine-tuning gene expression patterns and metabolism to maximize metabolic efficiency. The mechanisms that enable and mediate muscle transcriptional and metabolic responses to environmental cues remain unclear, however. We have shown previously that enhancer regulator MLL4 is required for establishing and maintaining slow type I fiber program to ensure running endurance (J Clin Invest. 2020;130(9):4710-4725). Here, we report that MLL4 plays a critical role in directing muscle metabolic transcriptional adaptation that governs metabolic efficiency and systemic metabolism. MLL4 expression is regulated by nutrient availability, and skeletal muscle-specific ablation of MLL4 protects mice against diet-induced obesity and improves systemic glucose homeostasis despite reducing exercise endurance. Combining comprehensive metabolic and genomic analysis of the MLL4-depleted muscles using multidimensional ‘omics’ technologies, we gained insight into the molecular targets and biological functions of the MLL4 protein. Specifically, this seemingly paradoxical phenotype is due to markedly enhanced fuel catabolism in MLL4 deficient muscles, a favorable metabolic reprogramming caused by the activation of muscle AMPK. Isotopic 13C-glucose tracing experiments in myocyte provided further evidence that MLL4 exerts control upon muscle fuel catabolism. Remarkably, pharmacologic targeting the MLL4 pathway activates muscle AMPK, confers resistance to diet-induced obesity and ameliorates obesity-related insulin resistance and liver steatosis. These results identify an enhancer regulator limiting AMPK-mediated muscle fuel catabolism and offer a new potential therapeutic strategy for obesity-related metabolic disorders. Disclosure L.Yang: None. L.Liu: None. C.Ding: None. T.Fu: None. Z.Zhou: None. Z.Gan: None.

The exercise-mediated metabokine Beta-aminoisobutyric acid is an exercise mimetic driving skeletal muscle metabolic and functional adaptation

Skeletal muscle integrates many of the systemic signals, which contribute to the adaptive remodeling, and beneficial effects of exercise. One mechanism through which muscle mediates the systemic effects of exercise is through muscle-derived hormones known as myokines. We identified the metabolite β-aminoisobutyric acid (BAIBA) as an exercise-mediated small molecule myokine. BAIBA is secreted from muscle in response to increased expression of the transcriptional co-regulator PGC-1α, a master regulator of the muscle adaptive response to exercise. However, how BAIBA functions to regulate the adaptive responses of skeletal muscle to exercise remains poorly understood. We show that BAIBA improves muscle metabolism, exercise efficiency and performance in mice. Oxygen consumption (VO2) and energy expenditure are increased in BAIBA-treated mice. Furthermore, BAIBA increased soleus in situ muscle contractile force, fatigue resistance, mitochondrial number and function. We found that BAIBA drives muscle fiber-type switching to an oxidative phenotype in vivo. BAIBA regulates specific fiber-type gene expression in human myocytes through PPARΔ. Our findings demonstrate that BAIBA is a key paracrine myokine, which, in part, regulates the effects of exercise to improve muscle function with resultant effects on exercise performance. H.N.D. acknowledges the support of the Biotechnology and Biological Sciences Research Council (BB/T004231/1). This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

The impact of different exercise protocols on rat soleus muscle reinnervation and recovery following peripheral nerve lesion and regeneration.

Background: Incomplete functional recovery following traumatic peripheral nerve injury is common, mainly because not all axons successfully regenerate and reinnervate target muscles. Exercise can improve functional outcomes increasing the terminal sprouting during the muscle reinnervation. However, exercise is not a panacea per se. Indeed, the type of exercise adopted dramatically impacts the outcomes of rehabilitation therapy. To gain insight into the therapeutic effects of different exercise regimens on reinnervation following traumatic nerve lesion, we evaluated the impact of different clinically transferable exercise protocols (EPs) on metabolic and functional muscle recovery following nerve crush. Methods: The reinnervation of soleus muscle in adult nerve-crushed rats was studied following 6 days of different patterns (continuous or intermittent) and intensities (slow, mid, and fast) of treadmill running EPs. The effects of EPs on muscle fiber multiple innervation, contractile properties, metabolic adaptations, atrophy, and autophagy were assessed using functional and biochemical approaches. Results: Results showed that an intermittent mid-intensity treadmill EP improves soleus muscle reinnervation, whereas a slow continuous running EP worsens the functional outcome. However, the mid-intensity intermittent EP neither enhanced the critical mediators of exercise-induced metabolic adaptations, namely, PGC-1α, nor improved muscle atrophy. Conversely, the autophagy-related marker LC3 increased exclusively in the mid-intensity intermittent EP group. Conclusion: Our results demonstrated that an EP characterized by a mid-intensity intermittent activity enhances the functional muscle recovery upon a nerve crush, thus representing a promising clinically transferable exercise paradigm to improve recovery in humans following peripheral nerve injuries.

Divergent serum metabolomic, skeletal muscle signaling, transcriptomic, and performance adaptations to fasted versus whey protein-fed sprint interval training.

Sprint interval training (SIT) is a time-efficient alternative to endurance exercise, conferring beneficial skeletal muscle metabolic adaptations. Current literature has investigated the nutritional regulation of acute and chronic exercise-induced metabolic adaptations in muscle following endurance exercise, principally comparing the impact of training in fasted and carbohydrate-fed (CHO) conditions. Alternative strategies such as exercising in low CHO, protein-fed conditions remain poorly characterized, specifically pertaining to adaptations associated with SIT. Thus, this study aimed to compare the metabolic and performance adaptations to acute and short-term SIT in the fasted state with preexercise hydrolyzed (WPH) or concentrated (WPC) whey protein supplementation. In healthy males, preexercise protein ingestion did not alter exercise-induced increases in PGC-1α, PDK4, SIRT1, and PPAR-δ mRNA expression following acute SIT. However, supplementation of WPH beneficially altered acute exercise-induced CD36 mRNA expression. Preexercise protein ingestion attenuated acute exercise-induced increases in muscle pan-acetylation and PARP1 protein content compared with fasted SIT. Acute serum metabolomic differences confirmed greater preexercise amino acid delivery in protein-fed compared with fasted conditions. Following 3 wk of SIT, training-induced increases in mitochondrial enzymatic activity and exercise performance were similar across nutritional groups. Interestingly, resting muscle acetylation status was downregulated in WPH conditions following training. Such findings suggest preexercise WPC and WPH ingestion positively influences metabolic adaptations to SIT compared with fasted training, resulting in either similar or enhanced performance adaptations. Future studies investigating nutritional modulation of metabolic adaptations to exercise are warranted to build upon these novel findings.NEW & NOTEWORTHY These are the first data to show the influence of preexercise protein on serum and skeletal muscle metabolic adaptations to acute and short-term sprint interval training (SIT). Preexercise whey protein concentrate (WPC) or hydrolysate (WPH) feeding acutely affected the serum metabolome, which differentially influenced acute and chronic changes in mitochondrial gene expression, intracellular signaling (acetylation and PARylation) resulting in either similar or enhanced performance outcomes when compared with fasted training.

Development of a multiplex assay to determine the expression of mitochondrial genes in human skeletal muscle.

What is the central question of this study? Can a custom-designed multiplex gene expression assay be used to quantify expression levels of a targeted group of mitochondrial genes in human skeletal muscle? What is the main finding and its importance? A custom-designed GeXP multiplex assay was developed, and the ability to accurately quantify expression of a targeted set of mitochondrial genes in human skeletal muscle was demonstrated. It holds distinct methodological and practical advantages over other commonly used quantification methods. Skeletal muscle is an important endocrine tissue demonstrating plasticity in response to external stimuli, including exercise and nutrition. Mitochondrial biogenesis is a common hallmark of adaptations to aerobic exercise training. Furthermore, altered expression of several genes implicated in the regulation of mitochondrial biogenesis, substrate oxidation and nicotinamide adenine dinucleotide (NAD+ ) biosynthesis following acute exercise underpins longer-term muscle metabolic adaptations. Gene expression is typically measured using real-time quantitative PCR platforms. However, interest has developed in the design of multiplex gene expression assays (GeXP) using the GenomeLab GeXP™ genetic analysis system, which can simultaneously quantify gene expression of multiple targets, holding distinct advantages in terms of throughput, limiting technical error, cost effectiveness, and quantifying gene co-expression. This study describes the development of a custom-designed GeXP assay incorporating the measurement of proposed regulators of mitochondrial biogenesis, substrate oxidation, and NAD+ biosynthetic capacity in human skeletal muscle and characterises the resting gene expression (overnight fasted and non-exercised) signature within a group of young, healthy, recreationally active males. The design of GeXP-based assays provides the capacity to more accurately characterise the regulation of a targeted group of genes with specific regulatory functions, a potentially advantageous development for future investigations of the regulation of muscle metabolism by exercise and/or nutrition.

A method for calculating lactate production rate using blood lactate concentration during exercise in mice

Introduction Lactate acts as an energy fuel (Brooks, 2018) and a signaling molecule for muscle metabolic adaptation such as mitochondrial biogenesis (Hashimoto et al., 2007). Lactate production rate is an important parameter for muscle metabolic adaptation but the measurement requires muscle biopsy in general. Blood lactate concentration is lower invasive and widely measured in sports. It is meaningful to establish a method to calculate lactate production rate from blood lactate concentration. The purpose of this study was to establish a method to determine the amount of lactate production from blood lactate concentration in mice. Methods C57BL6/L mice divided into two groups: a control group (CON) and an endurance treadmill training (EX) for 6 weeks (15~25 m/min; 30 min/day; 5 days/week). A lactate tolerance test was performed following i.p. injection of sodium lactate (1 g/kg of body weight). Blood lactate concentration was measured for 120 min after lactate injection, and lactate uptake capacity “k” was calculated from the following equation d[lactate]/dt = k[lactate]n Next, animals were subjected to an incremental exercise test (increasing from 10 m/min to 40 m/min) of 2 min run and 2 min rest on the treadmill, and blood lactate concentration was measured at each intensity. Lactate production at each intensity was calculated by combining the blood lactate concentration with the calculated lactate uptake capacity. We measured monocarboxylate transporter (MCT) 1 and 4 protein levels and citrate synthase (CS) activity. These are involved in lactate metabolism in skeletal muscle. To verify calculated lactate production, we measured muscle glycogen concentration after 10 bouts of 2 min run at each speed (0, 10, 20, 30 and 40 m/min) with 2 min rest using other control mice. Results We calculated “k” using time series data of lactate concentration after lactate injection. When the lactate concentration dynamics were computationally simulated with various “k”, it was found that lactate reduction rate was determined by k. However, “k” was not altered by 6 wk-endurance training. In the incremental exercise test, the blood lactate concentration in the EX group was significantly lower at 25-40 m/min than in the CON group (p<0.05). The lactate production rate in the EX group was also significantly lower at 35 and 40 m/min than in the CON group (p<0.05). These results suggest that lower lactate concentration during higher intensity exercise is attributable by lower lactate production rate in the EX group. Endurance training also decreased MCT4 protein (p<0.05), which acts release of lactate from muscle, and increased CS activity (p<0.05). These results support the lower lactate production rate in the EX group. Finally, we assessed whether the lactate production rate was valid by the measurement of muscle glycogen concentration after acute exercise at each exercise intensity. We confirmed there was a strong negative correlation between the muscle glycogen concentrations immediately after exercises and the calculated lactate production rates (r=0.99, p<0.01). [Conclusion] We established a reasonable method for calculating lactate production rate from blood lactate concentration during exercise.

Strength Training Reduces Fat Accumulation and Improves Blood Lipid Profile Even in the Absence of Skeletal Muscle Hypertrophy in High-Fat Diet-Induced Obese Condition

The aim was to investigate the effect of strength training on skeletal muscle morphology and metabolic adaptations in obese rats fed with unsaturated high-fat diet (HFD). The hypothesis was that strength training induces positive metabolic adaptations in obese rats despite impaired muscle hypertrophy. Male Wistar rats (n = 58) were randomized into two groups and fed a standard diet or a high-fat diet (HFD) containing 49.2% of fat. After induction and maintenance to obesity, the rats were divided into four groups: animals distributed in sedentary control (CS), control submitted to strength training protocol (CT), obese sedentary (ObS), and obese submitted to strength training protocol (ObT). The exercise protocol consisted of 10 weeks of training on a vertical ladder (three times a week) with a load attached to the animal’s tail. At the end of 10 weeks, strength training promoted positive changes in the body composition and metabolic parameters in obese animals. Specifically, ObT animals presented a reduction of 22.6% and 14.3% in body fat and adiposity index when compared to ObS, respectively. Furthermore, these rats had lower levels of triglycerides (ObT = 23.1 ± 9.5 vs. ObS = 30.4 ± 6.9 mg/dL) and leptin (ObT = 13.2 ± 7.2 vs. ObS = 20.5 ± 4.3 ng/mL). Training (ObT and CT) induced a greater strength gain when compared with the respective control groups. In addition, the weight of the flexor hallucis longus (FHL) muscle was higher in the ObT group than in the CT group, representing an increase of 26.1%. However, training did not promote hypertrophy as observed by a similar cross-sectional area of the FHL and plantar muscles. Based on these results, high-intensity strength training promoted an improvement of body composition and metabolic profile in obese rats that were fed a high-fat diet without skeletal muscle adaptations, becoming a relevant complementary strategy for the treatment of obesity.

The Effect of Creatine Supplementation on Muscle Function in Childhood Myositis: A Randomized, Double-blind, Placebo-controlled Feasibility Study.

To evaluate the feasibility of studying creatine in juvenile dermatomyositis (JDM). Secondary objectives were to determine the effect of creatine on muscle function and metabolism, aerobic capacity, fatigue, physical activity, and quality of life (QOL), as well as its safety. We conducted a 6-month, double-blind, randomized, multiple-baseline design; patients were assigned to creatine or placebo. Feasibility was assessed using attended study visits, completed study procedures, and adherence. Muscle function, aerobic capacity, and muscle strength were assessed with standardized exercise tests. Muscle metabolism was assessed using a 31-Phosphorus Magnetic Resonance Spectroscopy protocol. Fatigue, physical activity, and QOL were assessed by questionnaires. Statistical significance was estimated using a randomization (permutation) test. Changes in outcome measures taken at baseline and end-of-study were calculated using paired t-tests. Median (range) adherence to the study drug was 88.5% (20.5-95.5%) and the proportion of subjects with 80% adherence or higher was 76.9%. There were no missed study visits. There were no statistically significant changes in muscle function, strength, aerobic capacity, disease activity, fatigue, physical activity, or QOL while subjects were receiving creatine compared to placebo. There were statistically significant adaptations in muscle metabolism (e.g., decrease in change in muscle pH following exercise, and decrease in phosphate/phosphocreatine ratio) at the end-of-study compared to baseline. There were no significant adverse effects. Creatine supplementation in children with JDM is feasible to study, and is safe and well-tolerated; it may lead to improvements in muscle metabolism.

Low-intensity exercise stimulates bioenergetics and increases fat oxidation in mitochondria of blood mononuclear cells from sedentary adults.

AimExercise training induces adaptations in muscle and other tissue mitochondrial metabolism, dynamics, and oxidative phosphorylation capacity. Mitochondrial fatty acid oxidation was shown to be pivotal for the anti‐inflammatory status of immune cells. We hypothesize that exercise training can exert effects influence mitochondrial fatty acid metabolism in peripheral blood mononuclear cells (PBMCs). The aim was to investigate the effect of exercise on the fatty acid oxidation‐dependent respiration in PBMCs.DesignTwelve fasted or fed volunteers first performed incremental‐load exercise tests to exhaustion on a cycle ergometer to determine the optimal workload ensuring maximal health benefits in volunteers with a sedentary lifestyle. In addition, the same volunteers performed 60 min of low‐intensity constant‐load exercise.ResultsIn the incremental‐load exercise, the maximal whole‐body fat oxidation rate measured by indirect calorimetry was reached at the fasted state already at a 50 W workload. At the 75–175 W workloads, the contribution of fat oxidation significantly decreased to only 11%, the heart rate increased to 185 BPM, and the study participants reached exhaustion. These results show that low‐intensity exercise (50W) is optimal for maximal whole‐body fat utilization. After low‐intensity exercise, the ROUTINE mitochondrial respiration, as well as fatty acid oxidation‐dependent respiration in PBMCs at LEAK and OXPHOS states, were significantly increased by 31%, 65%, and 76%, respectively. In addition, during 60 min of low‐intensity (50W) exercise, a 2‐fold higher lipolysis rate was observed and 13.5 ± 0.9 g of fat was metabolized, which was 57% more than the amount of fat that was metabolized during the incremental‐load exercise.ConclusionsIn individuals with a sedentary lifestyle participating in a bicycle ergometry exercise program, maximal lipolysis and whole‐body fat oxidation rate is reached in a fasted state during low‐intensity exercise. For the first time, it was demonstrated that low‐intensity exercise improves bioenergetics and increases fatty acid oxidation in PBMCs and may contribute to the anti‐inflammatory phenotype.

Co-expression network analysis predicts a key role of microRNAs in the adaptation of the porcine skeletal muscle to nutrient supply

BackgroundThe role of non-coding RNAs in the porcine muscle metabolism is poorly understood, with few studies investigating their expression patterns in response to nutrient supply. Therefore, we aimed to investigate the changes in microRNAs (miRNAs), long intergenic non-coding RNAs (lincRNAs) and mRNAs muscle expression before and after food intake.ResultsWe measured the miRNA, lincRNA and mRNA expression levels in the gluteus medius muscle of 12 gilts in a fasting condition (AL-T0) and 24 gilts fed ad libitum during either 5 h. (AL-T1, N = 12) or 7 h. (AL-T2, N = 12) prior to slaughter. The small RNA fraction was extracted from muscle samples retrieved from the 36 gilts and sequenced, whereas lincRNA and mRNA expression data were already available. In terms of mean and variance, the expression profiles of miRNAs and lincRNAs in the porcine muscle were quite different than those of mRNAs. Food intake induced the differential expression of 149 (AL-T0/AL-T1) and 435 (AL-T0/AL-T2) mRNAs, 6 (AL-T0/AL-T1) and 28 (AL-T0/AL-T2) miRNAs and none lincRNAs, while the number of differentially dispersed genes was much lower. Among the set of differentially expressed miRNAs, we identified ssc-miR-148a-3p, ssc-miR-22-3p and ssc-miR-1, which play key roles in the regulation of glucose and lipid metabolism. Besides, co-expression network analyses revealed several miRNAs that putatively interact with mRNAs playing key metabolic roles and that also showed differential expression before and after feeding. One case example was represented by seven miRNAs (ssc-miR-148a-3p, ssc-miR-151-3p, ssc-miR-30a-3p, ssc-miR-30e-3p, ssc-miR-421-5p, ssc-miR-493-5p and ssc-miR-503) which putatively interact with the PDK4 mRNA, one of the master regulators of glucose utilization and fatty acid oxidation.ConclusionsAs a whole, our results evidence that microRNAs are likely to play an important role in the porcine skeletal muscle metabolic adaptation to nutrient availability.

Serum endotoxin, gut permeability and skeletal muscle metabolic adaptations following a short term high fat diet in humans

BackgroundOur previous work demonstrated that a short-term high fat diet (HFD) increased fasting serum endotoxin, altered postprandial excursions of serum endotoxin, and led to metabolic and transcriptional responses in skeletal muscle in young, healthy male humans. PurposeThe purpose of the present study was to determine if a short-term high fat diet: 1) increases intestinal permeability and, in turn, fasting endotoxin concentrations and 2) decreases postprandial skeletal muscle fat oxidation. MethodsThirteen normal weight young adult males (BMI 23.1 ± 0.8 kg/m2, age 22.2 ± 0.4 years) were fed a control diet (55% carbohydrate, 30% fat, 9% of which was saturated, 15% protein) for two weeks, followed by 5 days of an isocaloric HFD (30% carbohydrate, 55% fat, 25% of which was saturated, 15% protein, isocaloric to the control diet). Intestinal permeability (via four sugar probe test) was assessed in the fasting state. Both before and after the HFD, a high fat meal challenge (HFM, 820 kcal, 25% carbohydrate, 63% fat, 26% of which was saturated, and 12% protein) was administered. After an overnight fast, blood samples were collected before and every hour for 4 h after the HFM to assess endotoxin, and other serum blood measures. Muscle biopsies were obtained from the vastus lateralis before and 4 h after the HFM in order to assess substrate oxidation (glucose, fatty acid and pyruvate) using radiolabeled techniques. Insulin sensitivity was assessed via intravenous glucose tolerance test. Intestinal permeability, blood samples and muscle biopsies were assessed in the same manner before and following the HFD. Main findingsIntestinal permeability was not affected by HFD (p > 0.05), but fasting endotoxin increased two fold following the HFD (p = 0.04). Glucose oxidation and fatty acid oxidation in skeletal muscle homogenates significantly increased after the HFM before the HFD (+97%, and +106% respectively) but declined after the HFM following 5 days of the HFD (−24% and +16% respectively). Fatty acid suppressibility of pyruvate oxidation increased significantly after the HFM (+32%) but this physiological effect was abolished following 5 days of the HFD (+7%). Insulin sensitivity did not change following the HFD. ConclusionThese findings demonstrate that in healthy young men, consuming an isocaloric HFD for 5 days increases fasting endotoxin, independent of changes in gut permeability. These changes in endotoxin are accompanied by a broad effect on skeletal muscle substrate metabolism including increases in postprandial fat oxidation. Importantly, the latter occurs independent of changes in body weight and whole-body insulin sensitivity.

Anabolic and Pro-metabolic Functions of CREB-CRTC in Skeletal Muscle: Advantages and Obstacles for Type 2 Diabetes and Cancer Cachexia.

cAMP is one of the earliest described mediators of hormone action in response to physiologic stress that allows acute stress responses and adaptation in every tissue. The classic role of cAMP signaling in metabolic tissues is to regulate nutrient partitioning. In response to acute stress, such as epinephrine released during strenuous exercise or fasting, intramuscular cAMP liberates glucose from glycogen and fatty acids from triglycerides. In the long-term, activation of Gs-coupled GPCRs stimulates muscle growth (hypertrophy) and metabolic adaptation through multiple pathways that culminate in a net increase of protein synthesis, mitochondrial biogenesis, and improved metabolic efficiency. This review focuses on regulation, function, and transcriptional targets of CREB (cAMP response element binding protein) and CRTCs (CREB regulated transcriptional coactivators) in skeletal muscle and the potential for targeting this pathway to sustain muscle mass and metabolic function in type 2 diabetes and cancer. Although the muscle-autonomous roles of these proteins might render them excellent targets for both conditions, pharmacologic targeting must be approached with caution. Gain of CREB-CRTC function is associated with excess liver glucose output in type 2 diabetes, and growing evidence implicates CREB-CRTC activation in proliferation and invasion of different types of cancer cells. We conclude that deeper investigation to identify skeletal muscle specific regulatory mechanisms that govern CREB-CRTC transcriptional activity is needed to safely take advantage of their potent effects to invigorate skeletal muscle to potentially improve health in people with type 2 diabetes and cancer.

719-P: Inducible Estrogen-Related Receptor Alpha Overexpression Stimulates Skeletal Muscle Oxidative Metabolism and Improves Exercise Endurance in Mice

Aerobic exercise promotes skeletal muscle insulin sensitivity by enhancing glucose uptake and storage and by increasing mitochondrial oxidative capacity. Exercise-responsive transcriptional pathways that regulate metabolism represent potential therapeutic targets to combat insulin resistance. The ERRα nuclear receptor regulates mitochondrial oxidative metabolism and is required for the skeletal muscle metabolic response to exercise. In the current study investigated whether ERRα expression is sufficient to drive exercise-induced adaptations in muscle. We generated conditional ERRα transgenic mice that overexpress human ERRα in a tetracycline-inducible and skeletal muscle-specific manner (ERRαMOEiHSA). Dox-induced ERRαMOEiHSA (versus non-induced) mice exhibited reddening in glycolytic muscles, a characteristic of oxidative muscle. Mitochondrial content was increased in these muscles, based on mtDNA quantitation and citrate synthase activity. Consistently, ERRα-overexpressing muscles had higher O2 consumption rates and increased glycogen content. To determine if these metabolic changes altered exercise capacity, run performance was assessed in untrained mice. Dox-induced ERRαMOEiHSA mice tested at constant speed (endurance test) or at increasing speeds (aerobic test) ran longer compared to controls. Post-run blood glucose levels were higher in both testing paradigms, which may be due to greater reliance on β-oxidation and higher basal glycogen stores in ERRα-expressing muscles. Using ChIP and reporters assays we showed that ERRα directly activates gene encoding the catalytic (Ppp1ca) and regulatory subunits (Ppp1r3c) of protein phosphatase 1, involved in hormonal and contractile-activity control of glycogen metabolism. Collectively, these results demonstrate that short-term ERRα activation promotes muscle metabolic adaptations and exercise performance similar to exercise training. Disclosure J. Li: None. A. Hamilton: None. J.M. Huss: None. Funding American Diabetes Association (1-18-IBS-103 to J.M.H.)

Exercise Induction of Key Transcriptional Regulators of Metabolic Adaptation in Muscle Is Preserved in Type 2 Diabetes.

Type 2 diabetes (T2D) is characterized by insulin resistance in skeletal muscle. Regular exercise improves insulin sensitivity, mitochondrial function, and energy metabolism. Thus, an impaired response to exercise may contribute to insulin resistance. We hypothesized that key transcriptional regulators of metabolic adaptation to exercise show an attenuated response in skeletal muscle in T2D. Skeletal muscle biopsies were obtained from 13 patients with T2D and 14 age- and weight-matched controls before, immediately after 1 hour acute exercise (70% maximal pulmonary oxygen uptake), and 3 hours into recovery to examine mRNA expression of key transcription factors and downstream targets and activity of key upstream kinases underlying the metabolic adaptation to exercise. Acute exercise increased gene expression of the nuclear hormone receptor 4A (NR4A) subfamily (∼4- to 36-fold) and other key transcription factors, including ATF3, EGR1, JUNB, SIK1, PPARA, and PPARG (∼1.5- to 12-fold), but with no differences between groups. The expression of NR4A1 (approximately eightfold) and NR4A3 (∼75-fold) was further increased 3 hours into recovery, whereas most muscle transcripts sustained elevated or returned to basal levels, again with no differences between groups. Muscle expression of HKII and SLC2A4 and hexokinase II protein content were reduced in patients with T2D. The phosphorylation of p38 MAPK, Erk1/2, Ca2+/calmodulin-dependent kinase II, and cAMP-responsive element-binding protein was equally increased in response to exercise and/or recovery in both groups. Acute exercise elicits a pronounced and overall similar increase in expression of key transcription factors and activation of key upstream kinases involved in muscle metabolic adaptation to exercise in patients with T2D and weight-matched controls.

PO-305 An 8-week, low carbohydrate, high fat, ketogenic diet enhanced exercise capacity through improved ketolysis and lipolysis in mice

PO-305 An 8-week, low carbohydrate, high fat, ketogenic diet enhanced exercise capacity through improved ketolysis and lipolysis in mice