Glycolytic fast‐twitch muscle fiber restoration counters adverse age‐related changes in body composition and metabolism

Aging is associated with the development of insulin resistance, increased adiposity, and accumulation of ectopic lipid deposits in tissues and organs. Starting in mid‐life there is a progressive decline in lean muscle mass associated with the preferential loss of glycolytic, fast‐twitch myofibers. However, it is not known to what extent muscle loss and metabolic dysfunction are causally related or whether they are independent epiphenomena of the aging process. Here, we utilized a skeletal‐muscle‐specific, conditional transgenic mouse expressing a constitutively active form of Akt1 to examine the consequences of glycolytic, fast‐twitch muscle growth in young vs. middle‐aged animals fed standard low‐fat chow diets. Activation of the Akt1 transgene led to selective skeletal muscle hypertrophy, reversing the loss of lean muscle mass observed upon aging. The Akt1‐mediated increase in muscle mass led to reductions in fat mass and hepatic steatosis in older animals, and corrected age‐associated impairments in glucose metabolism. These results indicate that the loss of lean muscle mass is a significant contributor to the development of age‐related metabolic dysfunction and that interventions that preserve or restore fast/glycolytic muscle may delay the onset of metabolic disease.     

Acute bioenergetic insulin sensitivity of skeletal muscle cells: ATP-demand-provoked glycolysis contributes to stimulation of ATP supply

Skeletal muscle takes up glucose in an insulin-sensitive manner and is thus important for the maintenance of blood glucose homeostasis. Insulin resistance during development of type 2 diabetes is associated with decreased ATP synthesis, but the causality of this association is controversial. In this paper, we report real-time oxygen uptake and medium acidification data that we use to quantify acute insulin effects on intracellular ATP supply and ATP demand in rat and human skeletal muscle cells. We demonstrate that insulin increases overall cellular ATP supply by stimulating the rate of glycolytic ATP synthesis. Stimulation is immediate and achieved directly by increased glycolytic capacity, and indirectly by elevated ATP demand from protein synthesis. Raised glycolytic capacity does not result from augmented glucose uptake. Notably, insulin-sensitive glucose uptake is increased synergistically by nitrite. While nitrite has a similar stimulatory effect on glycolytic ATP supply as insulin, it does not amplify insulin stimulation. These data highlight the multifarious nature of acute bioenergetic insulin sensitivity of skeletal muscle cells, and are thus important for the interpretation of changes in energy metabolism that are seen in insulin-resistant muscle.     

Increased lipid accumulation and insulin resistance in transgenic mice expressing DGAT2 in glycolytic (type II) muscle

Insulin resistance and type 2 diabetes are frequently accompanied by lipid accumulation in skeletal muscle. However, it is unknown whether primary lipid deposition in skeletal muscle is sufficient to cause insulin resistance or whether the type of muscle fiber, oxidative or glycolytic fiber, is an important determinant of lipid-mediated insulin resistance. Here we utilized transgenic mice to test the hypothesis that lipid accumulation specifically in glycolytic muscle promotes insulin resistance. Overexpression of DGAT2, which encodes an acyl-CoA:diacylglycerol acyltransferase that catalyzes triacylglycerol (TG) synthesis, in glycolytic muscle of mice increased the content of TG, ceramides, and unsaturated long-chain fatty acyl-CoAs in young adult mice. This lipid accumulation was accompanied by impaired insulin signaling and insulin-mediated glucose uptake in glycolytic muscle and impaired whole body glucose and insulin tolerance. We conclude that DGAT2-mediated lipid deposition specifically in glycolytic muscle promotes insulin resistance in this tissue and may contribute to the development of diabetes.     

Attenuation of insulin resistance by chronic beta2-adrenergic agonist treatment possible muscle specific contributions

A possible mechanism by which chronic clenbuterol treatment causes multiple physiological changes in skeletal muscle that leads to reduced insulin resistance in the obese Zucker rat (falfa) was investigated. Animals were gavaged with clenbuterol (CB) (0.8 mg x kg(-1) day(-1)), terbutaline (TB) (1.0 mg x kg(-1)day(-1)), or control (CT) vehicle for six weeks. Oral glucose tolerance and insulin responses were markedly improved in CB rats and impaired in TB rats. CB treatment caused a 24-34% gain in muscle mass in all muscle fiber types, and increases in 3-O-methyglucose transport (2-fold) and GLUT4 concentration (57%) in fast twitch glycolytic (FG) muscle. Oxidative capacity was reduced in both FG (47%) and fast twitch oxidative (FO) muscle (30%), but not in slow twitch oxidative (SO) muscle. Null model analysis for receptor occlusion demonstrated that most functional beta-adrenoceptors were lost in FO (82%) and FG (89%) fibers, but not in SO fibers. We propose that hypertrophy is the result of continuous direct activation of beta-adrenoceptors while loss in oxidative capacity may be the result of receptor down regulation. Improvements in insulin resistance may have been due, in part, to both increases in lean body mass and specific adaptations in FG muscle.     

Muscle oxidative capacity during IL-6-dependent cancer cachexia

Many diseases are associated with catabolic conditions that induce skeletal muscle wasting. These various catabolic states may have similar and distinct mechanisms for inducing muscle protein loss. Mechanisms related to muscle wasting may also be related to muscle metabolism since glycolytic muscle fibers have greater wasting susceptibility with several diseases. The purpose of this study was to determine the relationship between muscle oxidative capacity and muscle mass loss in red and white hindlimb muscles during cancer cachexia development in the Apc(Min/+) mouse. Gastrocnemius and soleus muscles were excised from Apc(Min/+) mice at 20 wk of age. The gastrocnemius muscle was partitioned into red and white portions. Body mass (-20%), gastrocnemius muscle mass (-41%), soleus muscle mass (-34%), and epididymal fat pad (-100%) were significantly reduced in severely cachectic mice (n = 8) compared with mildly cachectic mice (n = 6). Circulating IL-6 was fivefold higher in severely cachectic mice. Cachexia significantly reduced the mitochondrial DNA-to-nuclear DNA ratio in both red and white portions of the gastrocnemius. Cytochrome c and cytochrome-c oxidase complex subunit IV (Cox IV) protein were reduced in all three muscles with severe cachexia. Changes in muscle oxidative capacity were not associated with altered myosin heavy chain expression. PGC-1α expression was suppressed by cachexia in the red and white gastrocnemius and soleus muscles. Cachexia reduced Mfn1 and Mfn2 mRNA expression and markers of oxidative stress, while Fis1 mRNA was increased by cachexia in all muscle types. Muscle oxidative capacity, mitochondria dynamics, and markers of oxidative stress are reduced in both oxidative and glycolytic muscle with severe wasting that is associated with increased circulating IL-6 levels.     

Mechanical properties of the latissimus dorsi muscle after cyclic training.

Cardiomyoplasty is a procedure developed to improve heart performance in patients suffering from congestive heart failure. The latissimus dorsi (LD) muscle is surgically wrapped around the failing ventricles and stimulated to contract in synchrony with the heart. The LD muscle is easily fatigued and as a result is unsuitable for cardiomyoplasty. For useful operation as a cardiac-assist device, the fatigue resistance of the LD muscle must be improved while retaining a high power output. The LD muscle of rabbits was subjected to a training regime in which cyclic work was performed. Training transformed the fiber-type composition from approximately equal proportions of fast oxidative glycolytic (FOG) and fast glycolytic (FG) fibers to one composed of almost entirely of FOG with no FG, which increased fatigue resistance while retaining rapid contraction kinetics. Muscle mass and cross-sectional area increased but power output decreased, relative to control muscles. This training regime represents a significant improvement in terms of preserving muscle mass and power compared with other training regimes, while enhancing fatigue resistance, although some fiber damage occurred. The power output of the trained LD muscle was calculated to be sufficient to deliver a significant level of assistance to a failing heart during cardiomyoplasty.     

A DIGE approach for the assessment of rat soleus muscle changes during unloading: effect of acetyl-L-carnitine supplementation

After hind limb suspension, a remodeling of postural muscle phenotype is observed. This remodeling results in a shift of muscle profile from slow-oxidative to fast-glycolytic. These metabolic changes and fiber type shift increase muscle fatigability. Acetyl-L-carnitine (ALCAR) influences the skeletal muscle phenotype of soleus muscle suggesting a positive role of dietary supplementation of ALCAR during unloading. In the present study, we applied a 2-D DIGE, mass spectrometry and biochemical assays, to assess qualitative and quantitative differences in the proteome of rat slow-twitch soleus muscle subjected to disuse. Meanwhile, the effects of ALCAR administration on muscle proteomic profile in both unloading and normal-loading conditions were evaluated. The results indicate a modulation of troponin I and tropomyosin complex to regulate fiber type transition. Associated, or induced, metabolic changes with an increment of glycolytic enzymes and a decreased capacity of fat oxidation are observed. These metabolic changes appear to be counteracted by ALCAR treatment, which restores the mitochondrial mass and decreases the glycolytic enzyme expression, suggesting a normalization of the metabolic shift observed in unloaded animals. This normalization is accompanied by a maintenance of body weight and seems to prevent a switch of fiber type.     

Prolonged absence of myostatin reduces sarcopenia

Sarcopenia is a progressive age-related loss of skeletal muscle mass and strength. Parabiotic experiments show that circulating factors positively influence the proliferation and regenerative capacity of satellite cells in aged mice. In addition, we believe that negative regulators of muscle mass also serve to balance the signals that influence satellite cell activation and regeneration capacity with ageing. Myostatin, a negative regulator of pre- and postnatal myogenesis, inhibits satellite cell activation and muscle regeneration postnatally. To investigate the role of myostatin during age-related sarcopenia, we examined muscle mass and regeneration in young and old myostatin-null mice. Young myostatin-null muscle fibers were characterized by massive hypertrophy and hyperplasia and an increase in type IIB fibers, resulting in a more glycolytic muscle. With ageing, wild-type muscle became increasingly oxidative and fiber atrophy was prominent. In contrast no fiber type switching was observed and atrophy was minimal in aged myostatin-null muscle. The effect of ageing on satellite cell numbers appeared minimal, however, satellite cell activation declined significantly in both wild-type and myostatin-null muscles. In young mice, lack of myostatin resulted in increased satellite cell number and activation compared to wild-type, suggesting a greater propensity to undergo myogenesis, a difference maintained in the aged mice. In addition, muscle regeneration of myostatin-null muscle following notexin injury was accelerated and fiber hypertrophy and type were recovered with regeneration, unlike in wild-type muscle. In conclusion, a lack of myostatin appears to reduce age-related sarcopenia and loss of muscle regenerative capacity.     

Large energetic adaptations of elderly muscle to resistance and endurance training.

This study determined the cellular energetic and structural adaptations of elderly muscle to exercise training. Forty male and female subjects (69.2 +/- 0.6 yr) were assigned to a control group or 6 mo of endurance (ET) or resistance training (RT). We used magnetic resonance spectroscopy and imaging to characterize energetic properties and size of the quadriceps femoris muscle. The phosphocreatine and pH changes during exercise yielded the muscle oxidative properties, glycolytic ATP synthesis, and contractile ATP demand. Muscle biopsies taken from the same site as the magnetic resonance measurements were used to determine myosin heavy chain isoforms, metabolite concentrations, and mitochondrial volume densities. The ET group showed changes in all energetic pathways: oxidative capacity (+31%), contractile ATP demand (-21%), and glycolytic ATP supply (-56%). The RT group had a large increase in oxidative capacity (57%). Only the RT group exhibited change in structural properties: a rise in mitochondrial volume density (31%) and muscle size (10%). These results demonstrate large energetic, but smaller structural, adaptations by elderly muscle with exercise training. The rise in oxidative properties with both ET and RT suggests that the aerobic pathway is particularly sensitive to exercise training in elderly muscle. Thus elderly muscle remains adaptable to chronic exercise, with large energetic changes accompanying both ET and RT.     

Lässt sich altersbedingter Muskelschwund stoppen?

Molecular mechanisms of age‐related muscle wasting Sarcopenia is the age‐related loss of muscle mass and contractile force and characterized by the severely reduced regenerative capacity of aged muscle fibres and excitation‐contraction uncoupling between motor neuron and muscle. The application of comparative proteomics to study muscle aging has revealed interesting new pathobiochemical insights. Aging associated muscle weakness is characterized by secondary fast‐to‐slow transitions in the contractile apparatus and glycolytic‐to‐oxidative changes in energy metabolism. The identification of new protein biomarkers of muscle aging represents a substantial advance in the establishment of new diagnostic methods and therapeutic approaches for the lessening of the effects of the fragility syndrome.     

Metabolic and physiologic characteristics of skeletal muscle determine its response to clenbuterol treatment

beta-Adrenoceptor agonists are reported to induce skeletal muscle hypertrophy and hence serve as valuable adjunct to the treatment of wasting disorders. In the present study, we attempted to find out whether metabolic and physiologic characteristics of fibres are important in determining skeletal muscle response to clenbuterol (an adrenergic receptor agonist) therapy, as proposed in the treatment of wasting disorders. The treatment of mice with clenbuterol (2 mg/kg body wt for 30 days) resulted in skeletal muscle hypertrophy, more common amongst fast-twitch glycolytic fibres/muscle, with increase in body mass and a parallel rise in muscle mass to body mass ratio. Measurement of fibre diameters in soleus (rich in slow-twitch oxidative fibres), ALD or anterior latissimus dorsi (with a predominance of fast-twitch glycolytic fibres) and gastrocnemius (a mixed-type of muscle) from clenbuterol-treated mice for 30 days revealed noticeable increase in the per cent population of narrow slow-twitch fibre and a corresponding decline in white-type or fast-twitch glycolytic fibres in gastrocnemius and ALD. As revealed by counting of muscle cells in soleus, narrow red fibres declined with corresponding increase in white-type glycolytic fibres population. A significant decline in the succinic dehydrogenase activity was observed, thereby suggesting abnormality in oxidative activity of skeletal muscles in response to clenbuterol therapy.     

Altered glycolytic and oxidative capacities of skeletal muscle contribute to insulin resistance in NIDDM

Simoneau, Jean-Aimé, and David E. Kelley. Alteredglycolytic and oxidative capacities of skeletal muscle contribute toinsulin resistance in NIDDM. J. Appl.Physiol. 83(1): 166-171, 1997.The insulinresistance of skeletal muscle in glucose-tolerant obese individuals isassociated with reduced activity of oxidative enzymes and adisproportionate increase in activity of glycolytic enzymes. Becausenon-insulin-dependent diabetes mellitus (NIDDM) is a disordercharacterized by even more severe insulin resistance of skeletal muscleand because many individuals with NIDDM are obese, the present studywas undertaken to examine whether decreased oxidative and increasedglycolytic enzyme activities are also present in NIDDM. Percutaneousbiopsy of vatus lateralis muscle was obtained in eight lean (L) andeight obese (O) nondiabetic subjects and in eight obese NIDDM subjectsand was assayed for marker enzymes of the glycolytic[phosphofructokinase, glyceraldehyde phosphate dehydrogenase,hexokinase (HK)] and oxidative pathways [citrate synthase(CS), cytochrome-c oxidase], aswell as for a glycogenolytic enzyme (glycogen phosphorylase) and amarker of anaerobic ATP resynthesis (creatine kinase). Insulinsensitivity was measured by using the euglycemic clamp technique.Activity for glycolytic enzymes (phosphofructokinase, glyceraldehyephosphate dehydrogenase, HK) was highest in subjects with subjects with NIDDM, following the order of NIDDM > O > L, whereas maximumvelocity for oxidative enzymes (CS,cytochrome-c oxidase) was lowest in subjects with NIDDM. The ratio between glycolytic andoxidative enzyme activities within skeletal muscle correlatednegatively with insulin sensitivity. The HK/CS ratio had the strongestcorrelation (r = 0.60, P < 0.01) with insulinsensitivity. In summary, an imbalance between glycolytic and oxidativeenzyme capacities is present in NIDDM subjects and is more severe thanin obese or lean glucose-tolerant subjects. The altered ratio betweenglycolytic and oxidative enzyme activities found in skeletal muscle ofindividuals with NIDDM suggests that a dysregulation betweenmitochondrial oxidative capacity and capacity for glycolysis is animportant component of the expression of insulin resistance.

     

Aerobic performance: role of oxygen delivery and utilization, glycolytic flux

Oxygen delivery to muscle, its consumption and glycolytic flux, all of each affect and restrict aerobic performance, are discussed. Energy supply of intensive exercise till exhaustion lasting 3 to 4 min is provided mainly by oxidative metabolism, simultaneously glycolytic flux may be increased considerably. Other conditions being equal, capacity of oxygen delivery determines oxygen partial pressure in myoplasm of exercising/contracting muscle. With PO2 in myoplasm increasing from 0 to 1-2 mm Hg oxygen consumption (VO2) in mitochondria enhances dramatically, with further increase of PO2 its rise slows down. At the ascending part of VO2-PO2 relationship for mitochondria the increase of VO2 is noticeably restricted by oxygen delivery to contracting muscle. When PO2 approaches plateau of the VO2-PO2 relationship, an increase of VO2 is restricted by mitochondria capacity to accumulate oxygen and augmented oxygen delivery will not lead to a significant increase of muscle VO2. On the other hand considerable accumulation of glycolytic metabolites in contracting muscle causes a decrease of contractility which in its turn may restrict aerobic performance. Noteworthy no strict relationship between glycolytic flux and PO2 in myoplasm exists. That is why correct evaluation of factors limiting aerobic performance presupposes simultaneous evaluation of both glycolytic flux and oxygen consumption in muscle which in its turn depends on oxygen delivery to mitochondria and its utilization.     

Atrophy of the soleus muscle by hindlimb unweighting

The unweighting model is a unique whole animal model that will permit the future delineation of the mechanism(s) by which gravity maintains contractile mass in postural (slow-twitch) skeletal muscle. Since the origination of the model of rodent hindlimb unweighting almost one decade ago, about half of the 59 refereed articles in which this model was utilized have been published in the Journal of Applied Physiology. Thus the purpose of this review is to provide, for those researchers with an interest in the hindlimb unweighting model, a summation of the data derived from this model to data and hopefully to stimulate research interest in aspects of the model for which data are lacking. The stress response of the animal to hindlimb unweighting is transient, minimal in magnitude, and somewhat variable. After 1 wk of unweighting, the animal exhibits no chronic signs of stress. The atrophy of the soleus muscle, a predominantly slow-twitch muscle, is emphasized because unweighting preferentially affects it compared with other calf muscles, which are mainly fast-twitch muscles. The review considers the following information about the unweighted soleus muscle: electromyogram activity, amount and type of protein lost, capillarization, oxidative capacity, glycolytic enzyme activities, fiber cross section, contractile properties, glucose uptake, sensitivity to insulin, protein synthesis and degradation rates, glucocorticoid receptor numbers, responses of specific mRNAs, and changes in metabolite concentrations.     

Regulation of muscle carbohydrate metabolism during exercise.

This review examines the mechanisms that regulate muscle carbohydrate metabolism during exercise. Muscle carbohydrate utilization is regulated primarily by two factors, namely, delivery of substrate to the glycolytic pathway either from glycogenolysis or from transport of extracellular glucose into the fibers, and formation of triosephosphate by phosphofructokinase. The regulation involves the integration of the glycolytic controls with other metabolic controls and the needs of the whole muscle in meeting the physiological demand. The controls operating in the glycolytic sequence in vivo appear to couple glycolytic recruitment to signals from the rate of energy demand, the TCA cycle state, and the mitochondrial redox state so as to satisfy the major regulatory goal of maintaining the supply of ATP for tension development.     

Proteomics of skeletal muscle glycolysis

Glycolysis represents one of the best-understood and most ancient metabolic pathways. In skeletal muscle fibres, energy for contraction is supplied by adenosine triphosphate via anaerobic glycolysis, the phosphocreatine shuttle and oxidative phosphorylation. In this respect, the anaerobic glycolytic pathway supports short duration performances of contractile tissues of high intensity. The catalytic elements associated with glycolysis are altered during development, muscle differentiation, physiological adaptations and many pathological mechanisms, such as muscular dystrophy, diabetes mellitus and age-related muscle weakness. Although gel electrophoresis-based proteomics is afflicted with various biological and technical problems, it is an ideal analytical tool for studying the abundant and mostly soluble enzymes that constitute the glycolytic system. This review critically examines the proteomic findings of recent large-scale studies of glycolytic enzymes and associated components in normal, transforming and degenerating muscle tissues. In the long term, proteins belonging to the glycolytic pathway may be useful as biomarkers of muscle adaptations and pathophysiological mechanisms and can be employed to improve diagnostics and in the identification of novel therapeutic targets in neuromuscular disorders.     

Effect of endurance running on cardiac and skeletal muscle in rats

We studied the effect of resistance running on left cardiac ventricle size and rectus femoris muscle fiber composition. Ten male Wistar rats were trained on a treadmill 6 days per week for 12 weeks. Ten rats remained sedentary and served as controls. A higher endurance time (40%) and cardiac hypertrophy in the trained animals were indicators of training efficiency. Morphometric analysis of the left ventricle cross-sectional area, left ventricular wall, and left ventricular cavity were evaluated. The endurance-running group demonstrated a hypertrophy of the ventricular wall (22%) and an increase in the ventricular cavity (25%); (p<0.0001). Semi-quantitative analysis of rectus femoris fiber-type composition and of the oxidative and glycolytic capacity was histochemically performed. Endurance running demonstrated a significant (p<0.01) increase in the relative frequency of Type I (24%), Type IIA (8%) and Type IIX (16%) oxidative fibers, and a decrease in Type IIB (20%) glycolytic fibers. There was a hypertrophy of both oxidative and glycolytic fiber types. The relative cross-sectional area analysis demonstrated an increase in oxidative fibers and a decrease in glycolytic fibers (p<0.0001). Changes were especially evident for Type IIX oxidative-glycolytic fibers. The results of this study indicate that the left ventricle adapts to endurance running by increasing wall thickness and enlargement of the ventricular cavity. Skeletal muscle adapts to training by increasing oxidative fiber Type. This increase may be related to fiber transformation from Type IIB glycolytic to Type IIX oxidative fibers. These results open the possibility for the use of this type of exercise to prevent muscular atrophy associated with age or post-immobilization.