Postmortem metabolism in porcine skeletal muscle

England, Eric M.

21 July 2015

Once an animal is harvested for meat, skeletal muscle attempts to maintain ATP at or near antemortem levels. To maintain ATP levels postmortem, stored glycogen is catabolized to produce ATP through glycolysis and possibly oxidative metabolism. Hydrolysis of the produced ATP acidifies muscle until an ultimate pH is reached. The ultimate pH of meat directly impacts the quality characteristics of color, texture, and water holding capacity. Therefore, our research intends to describe the contributions glycolysis and oxidative metabolism play in determining ultimate pH and fresh meat quality. Traditionally, glycogen content at death was thought to be responsible for dictating ultimate pH. This was especially true in oxidative muscle with limited glycogen stores. Yet, our research indicated that in the presence of excess glycogen, oxidative muscle maintains a high ultimate pH. Rather, pH inactivation of phosphofructokinase is responsible for terminating postmortem glycolysis and brackets ultimate pH between 5.9 – 5.5. Meat with a pH below this range is uncommon. However, AMPK γ3R200Q mutant pigs produce meat with an ultimate pH near 5.3. Due to lower AMP deaminase abundance in their muscle, AMP levels are elevated late postmortem. Because AMP is a potent activator of phosphofructokinase, the aberrant meat quality from AMPK γ3R200Q mutant pigs is caused by extended postmortem glycolysis. Combined, these data further our understanding of the factors that contribute to the formation of fresh meat quality. We also characterized AMPK γ3R200Q muscle by investigating antemortem skeletal muscle lactate transport. Lactate is transported in or out of tissues by proton-linked iii monocarboxylate transporters (MCTs). Previous reports indicated that acute activation of AMPK increased monocarboxylate transporter expression in skeletal muscle of other species. Yet, it was unknown the impact chronic activation of AMPK will have on MCT1, MCT2, and MCT4 expression in pigs. Compared to wild-type pigs, the longissimus lumborum of AMPK γ3R200Q pigs increased both MCT2 and MCT4 protein expression. Our data suggest glycolytic skeletal muscle from the AMPK γ3R200Q pigs has increased capacity for antemortem lactate export from muscle and possibly increased pyruvate transport into the mitochondria. / Ph. D.

pork quality

skeletal muscle

ultimate pH

mitochondria

AMPK γ3R200Q

Do Probiotics Protect Against the Deleterious Effects of a High-Fat Diet?

Fundaro, Gabrielle F.

27 June 2014

High-fat diets and obesity have been linked to unfavorable changes in gut bacteria and increased leakage of bacterially-derived lipopolysaccharide (endotoxin) from the intestinal tract into circulation, which is associated with low-grade inflammation, metabolic dysregulation and degradation of tight-junction proteins between intestinal cells. Probiotic supplementation is the practice of ingesting live strains of bacteria that are proposed to have a beneficial effect on the host by enriching the intestine with healthy bacteria. The purpose of this project was to determine if probiotic supplementation would prevent increased inflammatory tone, decreased oxidative capacity, and decreased tight-junction protein expression associated with high-fat feeding and elevated endogenous endotoxin. Male C57BL/6J mice were fed either a control (CD, 10% fat) or high-fat (HFD, 60% fat) diet for 4 weeks while receiving a daily oral gavage of water (C-VSL#3, HF-VSL#3) or probiotics (C+VSL#3, HF+VSL#3) equivalent to 1.2 billion live cultures. Changes in body weight, body composition, respiratory exchange ratio, energy expenditure, and glucose and insulin tolerance were measured in live mice. Markers of metabolic function were measured in whole muscle homgenates and mitochondria isolated from red and white skeletal muscle. Plasma endotoxin was measured in blood collected from fasted mice at the time of euthanization. The large and small intestines were collected and mRNA levels of tight-junction proteins and markers of nutrient sensing were measured. To determine a possible protective effect against endogenous LPS, a second cohort of mice were given an intraperitoneal injection of 0.1µg/kg LPS or saline to induce endotoxemia after four weeks of the aforementioned feeding protocol. Markers of metabolic function and inflammation were measured in mitochondria, skeletal muscle and liver. VSL#3 supplementation improved glucose homeostasis and markers of inflammation while enhancing nutrient sensing in the gut. / Ph. D.

Probiotics

high-fat diet

metabolic endotoxemia

skeletal muscle

The Role of Toll Like Receptor-4 in Exercise-induced Myokine Response and Regulation of Skeletal Muscle Metabolic Adaptation

Ali, Mostafa M.

27 February 2017

Toll like receptor-4 (TLR4) is a transmembrane inflammatory receptor expressed ubiquitously on the cell surface of immune cells as well as skeletal muscle and other metabolic tissues. A compelling body of evidence shows that muscle TLR4 and the downstream cytokine signaling modulate skeletal muscle metabolism. Intriguingly, skeletal muscle has been demonstrated to gain favorable inflammatory cytokine-mediated metabolic adaptations in the context of exercise training. This paradigm suggests a role for muscle TLR4 inflammatory signaling in the regulation of exercise metabolism. As such, the question arises as to whether exercise stress response follows similar inflammatory physiological pathways to those activated by other physical and pathogenic stimuli or not. Therefore, the objective of the present study was to investigate the role of muscle TLR4 signaling in modulating skeletal muscle cytokine, also known as myokine, response and metabolic adaptations to exercise. To this end, using Cre-mediated recombination, we developed a novel muscle-specific TLR4 knockout (mTLR4-/-) mouse model on C57BL/6JJ background. The differential inflammatory and metabolic responses between mTLR4-/- mice and wild type (WT) littermates were examined following exposure to either exercise or muscle stimulus. Accordingly, different exercise and muscle contraction modalities were pursued, focusing on voluntary wheel running, forced treadmill training, and in vivo electrical muscle stimulation. Overall, this study introduces a novel muscle-specific TLR4 knockout mouse model and discloses a crucial role for mTLR4 in basal systemic cytokine homeostasis. Furthermore, our findings identify mTLR4 as a major immunomodulatory effector of exercise-induced metabolic adaptations and suggest a link between mTLR4 and physiological determinants of maximal aerobic performance. / Ph. D.

skeletal muscle

toll-like receptor-4

exercise metabolism

Examining the Influence of Muscle Fiber Type on Protein Turnover Signaling in Growing Pigs

Seymour, Kacie Tinnesz

28 May 2020

Postnatal skeletal muscle growth occurs through myonuclear accretion and high protein turnover rate. While fiber type composition of the muscle could affect protein turnover rate, less is known about how fiber type influences the regulation of protein synthesis and degradation signaling pathways. Thus, the hypothesis of this work was that variation in fiber type composition will differentially affect the regulation of signaling pathways related to protein turnover in skeletal muscle hypertrophy in growing pigs. Downregulated protein synthesis signaling and reduced expression of type II MyHC isoforms have been reported in skeletal muscles of low birth weight (LBWT) neonatal pigs. Therefore, we sought to determine whether these changes are sustained until weaning and would explain the reduction in LBWT pig growth compared to their normal birth weight (NBWT) sibling at weaning. Another objective was to determine whether the regulation of protein turnover signaling pathways are correlated to fiber type differences in skeletal muscles. Our data suggest that the longissimus dorsi (LD, glycolytic) muscle of LBWT pigs experienced compensatory growth while the soleus (oxidative) remained proportionally smaller. Growth of the LD was accompanied by upregulation of translation initiation. Additionally, there was no difference in expression of MyHC isoforms between NBWT and LBWT pigs. These data suggest the rapid growth of the LD of LBWT pigs may be attributed to an upregulation of protein synthesis signaling and occurred only in glycolytic muscles. A caveat in LBWT pig model is that the reduction in type II MyHC at birth is not the only factor that could influence muscle growth, and that other factors may have confounded our results. This is why we aimed to use β-adrenergic agonist as a means to induce a shift fiber type in muscles to a more glycolytic phenotype. Our objective was to determine the influence of the β-adrenergic agonist Ractopamine (RAC) induced slow-to-fast fiber type transformation on the regulation of protein synthesis and degradation pathways. Although supplementation improved translational capacity, enhanced S6K1 phosphorylation, and reduced the abundance of calcium-dependent proteases, RAC feeding had no effect on body or muscle weights. These results suggest that a fiber type transformation without other physiological influences does not alter protein turnover signaling in favor of hypertrophy in growing pigs. / Master of Science / Skeletal muscles grow by increasing the amount of protein contained within them. The amount of protein deposited is determined by the net balance between the rates at which proteins are synthesized and degraded. However, not all skeletal muscles grow at the same rate. One factor that is thought to influence protein synthesis and degradation rates is the types of muscle fibers that are present within a muscle. These fibers can display a range of contractile and metabolic characteristics, from slow-twitch oxidative fibers to fast-twitch glycolytic fibers. In the presented studies, we sought to determine whether changes in fiber type composition result in difference to the signaling pathways the regulate protein synthesis and degradation, ultimately leading to differences in the muscle growth of young pigs. We have previously shown reduced activation of the protein synthesis pathway in the skeletal muscle of low birth weight (LBWT) newborn pigs. These pigs also had lower expression of glycolytic fibers. In experiment 1, we aimed to compare the signaling pathways regulating protein synthesis and degradation in LBWT and normal birth weight (NBWT) pigs at weaning. We also sought to determine if the regulation of these signaling pathways changed between muscles with differing fiber type compositions. The glycolytic longissimus dorsi (LD) muscle of LBWT pigs grew rapidly between birth and weaning whereas the highly oxidative soleus did not. In addition, the LD of LBWT pigs had greater protein synthesis signaling and similar expression of muscle fibers compared with NBWT pigs, suggesting the improvement in protein synthesis signaling of LBWT pigs between birth and weaning may be related to a shift in fiber type. In experiment 2, we used a compound called ractopamine hydrochloride (RAC) to promote a slow-to-fast fiber type switch in the muscle of young pigs. With this study, we sought to determine the effect of this fiber type transformation, without the influence of birth weight, on the regulation of protein synthesis and degradation pathways. Although RAC-fed pigs showed some minor changes that could improve protein synthesis and decrease protein degradation, RAC feeding had no observable effect on body weight or muscle growth. These results suggest that a fiber type transformation alone is not enough to promote muscle growth in growing pigs.

pig

muscle fiber type

skeletal muscle

protein synthesis

protein degradation

The effects of furosemide on equine skeletal muscle satellite cell myogenesis and metabolism in vitro

Helsel, Patricia J.

29 January 2020

Thoroughbred racehorses undergo strenuous exercise which often leads to the occurrence of exercise-induced pulmonary hemorrhage (EIPH), in which capillaries rupture within the alveoli in the lungs causing bleeding. Severe cases of EIPH lead to epistaxis and may result in fatality. Presently, the loop diuretic furosemide is the only medication approved to mitigate the effects of EIPH. Often regarded in the racing industry as "performance enhancing" due to 4% weight loss ensued by its diuretic effect, it is unknown what effects furosemide may have on muscle recovery. Therefore, the objective of this study was to determine the effects various doses of furosemide may have on equine satellite cell (eqSC) myogenesis and metabolism. Mitotic index was increased (P<0.05) as a result of treatment with 100 µg/mL furosemide, a 10-fold pharmacological dose, in comparison to vehicle, but was not different (P>0.05) compared to the physiological dose of 10 µg/mL furosemide. Average cell number decreased (P<0.05) in the excess furosemide group compared to all other groups. Pax7 expression did not differ (P>0.05) between groups. Expression of the differentiation transcription factor myogenin, and embryonic sarcomeric myosin heavy chain decreased (P<0.05) when cells were treated with 100 µg/mL furosemide. Fusion index and myotube area decreased (P<0.05) as a result of treatment with excess furosemide. Glycogen concentration in myotubes was lower (P<0.05) following treatment with 100 µg/mL furosemide, while IGF-1 was unsuccessful in rescuing the effects of furosemide. Excess furosemide decreased expression of muscle creatine kinase while increasing expression of phosphoglucomutase 1, glycogen synthase 1, and glycogen branching enzyme 1 (P<0.05). Excess furosemide decreased basal oxygen consumption rate (OCR) and increased OCR after addition of oligomycin (P<0.05). Excess furosemide did not affect myotube glycolysis rates in vitro. In conclusion, furosemide inhibits muscle differentiation and oxidative metabolism in eqSCs. / Master of Science / Thoroughbred racehorses often bleed from the lungs as a result of high-intensity exercise. This condition can oftentimes be fatal depending on severity. Furosemide, is used in the industry to reduce blood pressure within the lungs during racing to prevent bleeding. Furosemide, a diuretic given four hours prior to a race, causes a horse to excrete up to 4% of its body weight. This effect of furosemide decreases the weight a horse must carry during a race, thus allowing the horse to run faster. Therefore, deemed as a performance enhancing drug due to its effects on the kidney, to our knowledge, no research has been conducted on what effects furosemide might have on muscle generation. High-intensity exercise causes massive muscle damage and therefore must be repaired to prepare for the next bout of exercise. Muscle generation is called myogenesis. Stem cells, or satellite cells, that lie within the muscle become activated, recognizing the need for muscle repair. Satellite cells divide, increasing in cell number and then fuse together, forming new muscle fibers. Satellite cells undergo different types of metabolism depending on their state of development. For example, proliferating cells require glucose for energy, while cells fusing together forming myotubes, require oxidative metabolism for long-lasting energy. Therefore, the objective of this study was to determine the effects furosemide might have on muscle formation and metabolism. The excess furosemide dose (100 µg/mL) decreased cell proliferation. The expression of regulatory factors responsible for forming myotubes at different stages of muscle development are decreased when cells were treated with the defined excess furosemide dose. Furosemide decreased the ability of satellite cells to generate myotubes. Glycogen concentration was also decreased as a result of excess furosemide treatment. Gene expression of enzymes involved in glycogen synthesis were increased from treatment with our excess furosemide dose. No effect of furosemide was seen on glycolysis, whereas oxidative metabolism suffered as a result of treatment with excess furosemide. In conclusion, furosemide does indeed affect muscle generation and oxidative metabolism.

EIPH

furosemide

skeletal muscle

satellite cells

myogenesis

metabolism

Low load endurance activity and green tea extract represent potential therapies for Duchenne muscular dystrophy

Call, Jarrod Alan

16 October 2007

Duchenne muscular dystrophy (DMD) is a progressive muscle wasting disease affecting 1 in every 3500 boys. The disease is characterized by the absence of the dystrophin protein from the sarcolemma of muscle cells. Muscle cells lacking dystrophin go through cycles of degeneration and regeneration and are considered susceptible to contraction-induced injury 144. Eventually, the satellite cell proliferative capacity is exhausted and the muscle fibers are replaced by connective and adipose tissue that yields a progressive loss of force generating capability. DMD patients typically die by their early 20's, primarily due to respiratory or cardiac failure. The precise role of dystrophin is not presently known. However, its absence suggests that it may play a role in both cellular calcium regulation and oxidative stress 152. Recent studies suggest increased reactive oxygen species (ROS) may precede the initial wave of wasting that marks disease onset 49. Therefore, it is possible oxidative stress may contribute as a pathogenic mechanism of DMD. Strategies to reduce the deleterious effects of oxidative stress could be an effective therapeutic approach. Regular exercise is known to increase antioxidant capacity in humans and mice 146. Green tea extract (GTE) is a powerful antioxidant that is easily supplemented in the diet 83. The purpose of this study was to test the hypotheses that (1) voluntary endurance exercise alone, (2) a diet supplemented with 0.05% (wt/wt) GTE alone, or exercise and GTE combined will blunt the effects of ROS and improve muscle strength and endurance in young mdx mice. Male mdx mice at age 21-days were randomly divided into one of 4 treatment groups: Run Normal diet (RunNorm; n=8), Sedentary Normal diet (SedNorm; n=8), Run GTE diet (RunGTE; n=10), and Sedentary GTE diet (SedGTE; n=8). RunNorm and RunGTE mice were given free access to a running wheel for 3 weeks while SedNorm and SedGTE mice were restricted to normal cage movement. At the end of 3 weeks, mice in each treatment group were sacrificed and assessed for daily and weekly running distances, content of actin and myosin proteins and fiber type distribution (tibialis anterior), contractile/mechanical and fatigue properties (extensor digitorum longus), creatine kinase levels and antioxidant capacity (serum), lipid peroxidation (gastrocnemius), and citrate synthase and beta-hydroxyacyl-CoA dehydrogenase activities (quadriceps and soleus). The key findings of this study were: In normal diet running mice (RunNorm), average daily distance run was increased 300% (from 0.5 to 2.1 km/d, P<0.05) from week 1 to week 3. In GTE diet (RunGTE) compared to RunNorm mice, total distance over the 3 weeks was markedly improved 128% (61.2 vs. 26.8 km, P<0.0001). Running, independent of diet increased EDL muscle tetanic stress (18%), serum antioxidant capacity (22%), citrate synthase activity (35%), and beta-oxidation (37%; all P<0.05). GTE, independent of running decreased lipid peroxidation (gastrocnemius:-64%; heart: -29%) and serum creatine kinase (-36%), and increased citrate synthase activity (59%; all P<0.05). These findings in dystrophic mice suggest that voluntary endurance exercise with or without GTE supplementation blunted the deleterious effects of ROS. If similar positive effects are evident in human DMD patients, then these approaches may be beneficial therapies either alone or in combination. / Master of Science

oxidative stress

skeletal muscle

voluntary wheel running

mdx

antioxidants

Exercise

Alleviating exercise-induced muscular stress using neat and processed bee pollen: oxidative markers, mitochondrial enzymes, and myostatin expression in rats

Ketkar, S.S., Rathore, A.S., Kandhare, A., Lohidasan, S., Bodhankar, S., Paradkar, Anant R, Mahadik, K.R.

14 March 2015

Yes / The current study was designed to investigate the influence of monofloral Indian mustard bee pollen (MIMBP) and processed monofloral Indian mustard bee pollen (PMIMBP) supplementation on chronic swimming exercise-induced oxidative stress implications in the gastrocnemius muscle of Wistar rats. MIMBP was processed with an edible lipid-surfactant mixture (Captex 355:Tween 80) to increase the extraction of polyphenols and flavonoid aglycones as analyzed by UV spectroscopy and high performance liquid chromatography-photo diode array. Wistar rats in different groups were fed with MIMBP or PMIMBP supplements at a dose of 100 mg/kg, 200 mg/kg and 300 mg/kg individually, while being subjected to chronic swimming exercise for 4 weeks (5 d/wk). Various biochemical [superoxide dismutase (SOD), glutathione (GSH), malonaldehyde (MDA), nitric oxide (NO), and total protein content], mitochondrial (Complex I, II, III, and IV enzyme activity), and molecular (myostatin mRNA expression) parameters were monitored in the gastrocnemius muscle of each group. Administration of both MIMBP (300 mg/kg) and PMIMBP (100 mg/kg, 200 mg/kg, and 300 mg/kg) wielded an antioxidant effect by significantly improving SOD, GSH, MDA, NO, and total protein levels. Further MIMBP (300 mg/kg) and PMIMBP (200 mg/kg and 300 mg/kg) significantly improved impaired mitochondrial Complex I, II, III, and IV enzyme activity. Significant down-regulation of myostatin mRNA expression by MIMBP (300 mg/kg) and PMIMBP (200 mg/kg and 300 mg/kg) indicates a muscle protectant role in oxidative stress conditions. The study establishes the antioxidant, mitochondrial upregulatory, and myostatin inhibitory effects of both MIMBP and PMIMBP in exercise-induced oxidative stress conditions, suggesting their usefulness in effective management of exercise-induced muscular stress. Further, processing of MIMBP with an edible lipid-surfactant mixture was found to improve the therapeutic efficiency of pollen.

Bee pollen

Lipid

Oxidative stress

Skeletal muscle

Surfactant

RNA-sequencing muscle plasticity to resistance exercise training and disuse in youth and older age

16 January 2023

Yes / Maintenance of skeletal muscle mass and function is critical to health and wellbeing throughout the lifespan. However, disuse through reduced physical activity (e.g., sedentarism), immobilisation, bed rest or microgravity has significant adverse effects on skeletal muscle health. Conversely, resistance exercise training (RET) induces positive muscle mass and strength adaptations. Several studies have employed microarray technology to understand the transcriptional basis of muscle atrophy and hypertrophy after disuse and RET, respectively, to devise fully effective therapeutic interventions. More recently, rapidly falling costs have seen RNA-sequencing (RNA-seq) increasingly applied in exploring muscle adaptations to RET and disuse. The aim of this review is to summarise the transcriptional responses to RET or disuse measured via RNA-seq in young and older adults. We also highlight analytical considerations to maximise the utility of RNA-seq in the context of skeletal muscle research. The limited number of muscle transcriptional signatures obtained thus far with RNA-seq are generally consistent with those obtained with microarrays. However, RNA-seq may provide additional molecular insight, particularly when combined with data-driven approaches such as correlation network analyses. In this context, it is essential to consider the most appropriate study design parameters as well as bioinformatic and statistical approaches. This will facilitate the use of RNA-seq to better understand the transcriptional regulators of skeletal muscle plasticity in response to increased or decreased use.

Ageing

Disuse

Resistance exercise training

RNA sequencing

Skeletal muscle

Transcriptomics

Myokines, Measurement, and Technical Considerations

22 November 2023

No / Skeletal muscle has long been established as a highly multifunctional organ, playing a vital role in locomotion, whole-body metabolic and energy homeostasis, and thermoregulation. More recently, emergent evidence has highlighted a potent secretory role for muscle, producing and releasing “myokine” molecules that act in autocrine, paracrine, or endocrine fashion to govern muscle physiology and regulate whole-body homeostasis via multi-tissue cross talk mechanisms. Myokines represent promising therapeutic targets in health and disease, with their discovery, measurement, and functional importance being a hotbed of research across numerous physiological contexts. Here, we provide an overview of myokines and summarize current understanding of their biological role(s). We also outline primary approaches for myokine analysis, including detailed methodology for performing omics-driven myokine prediction, while further appraising both method-specific and general technical considerations to provide an evidence-based approach for designing and conducting myokine experiments.

Skeletal muscle

Secretome

Myokine

Measurement

Analysis

Omics

Technical considerations

Adaptability to eccentric exercise training is diminished with age in female mice

22 November 2023

Yes / The ability of skeletal muscle to adapt to eccentric contractions has been suggested to be blunted in older muscle. If eccentric exercise is to be a safe and efficient training mode for older adults, preclinical studies need to establish if older muscle can effectively adapt and if not, determine the molecular signatures that are causing this impairment. The purpose of this study was to quantify the extent age impacts functional adaptations of muscle and identify genetic signatures associated with adaptation (or lack thereof). The anterior crural muscles of young (4 mo) and older (28 mo) female mice performed repeated bouts of eccentric contractions in vivo (50 contractions/wk for 5 wk) and isometric torque was measured across the initial and final bouts. Transcriptomics was completed by RNA-sequencing 1 wk following the fifth bout to identify common and differentially regulated genes. When torques post eccentric contractions were compared after the first and fifth bouts, young muscle exhibited a robust ability to adapt, increasing isometric torque 20%-36%, whereas isometric torque of older muscle decreased up to 18% (P ≤ 0.047). Using differential gene expression, young and older muscles shared some common transcriptional changes in response to eccentric exercise training, whereas other transcripts appeared to be age dependent. That is, the ability to express particular genes after repeated bouts of eccentric contractions was not the same between ages. These molecular signatures may reveal, in part, why older muscles do not appear to be as adaptive to exercise training as young muscles.NEW & NOTEWORTHY The ability to adapt to exercise training may help prevent and combat sarcopenia. Here, we demonstrate young mouse muscles get stronger whereas older mouse muscles become weaker after repeated bouts of eccentric contractions, and that numerous genes were differentially expressed between age groups following training. These results highlight that molecular and functional plasticity is not fixed in skeletal muscle with advancing age, and the ability to handle or cope with physical stress may be impaired. / The full-text of this article will be released for public view at the end of the publisher embargo on 1 Nov 2024.

Repeated bout effect

Resistance training

Skeletal muscle

Transcriptomics

Strength