Dynamics and Consequences of Potassium Shifts in Skeletal Muscle and Heart During Exercise

2000 ◽  
Vol 80 (4) ◽  
pp. 1411-1481 ◽  
Author(s):  
Ole M. Sejersted ◽  
Gisela Sjøgaard
Keyword(s):  
Skeletal Muscle ◽  
Force Production ◽  
Membrane Conductance ◽  
Cell Swelling ◽  
Modifying Factors ◽  
Fast Twitch Muscle ◽  
T Tubules ◽  
Exercise Induced ◽  
Fast Twitch ◽  
Muscle Excitability

Since it became clear that K+shifts with exercise are extensive and can cause more than a doubling of the extracellular [K+] ([K+]s) as reviewed here, it has been suggested that these shifts may cause fatigue through the effect on muscle excitability and action potentials (AP). The cause of the K+shifts is a transient or long-lasting mismatch between outward repolarizing K+currents and K+influx carried by the Na+-K+pump. Several factors modify the effect of raised [K+]sduring exercise on membrane potential ( Em) and force production. 1) Membrane conductance to K+is variable and controlled by various K+channels. Low relative K+conductance will reduce the contribution of [K+]sto the Em. In addition, high Cl−conductance may stabilize the Emduring brief periods of large K+shifts. 2) The Na+-K+pump contributes with a hyperpolarizing current. 3) Cell swelling accompanies muscle contractions especially in fast-twitch muscle, although little in the heart. This will contribute considerably to the lowering of intracellular [K+] ([K+]c) and will attenuate the exercise-induced rise of intracellular [Na+] ([Na+]c). 4) The rise of [Na+]cis sufficient to activate the Na+-K+pump to completely compensate increased K+release in the heart, yet not in skeletal muscle. In skeletal muscle there is strong evidence for control of pump activity not only through hormones, but through a hitherto unidentified mechanism. 5) Ionic shifts within the skeletal muscle t tubules and in the heart in extracellular clefts may markedly affect excitation-contraction coupling. 6) Age and state of training together with nutritional state modify muscle K+content and the abundance of Na+-K+pumps. We conclude that despite modifying factors coming into play during muscle activity, the K+shifts with high-intensity exercise may contribute substantially to fatigue in skeletal muscle, whereas in the heart, except during ischemia, the K+balance is controlled much more effectively.

Alpha-actin and cytochrome c mRNAs in atrophied adult rat skeletal muscle

1988 ◽  
Vol 254 (5) ◽  
pp. C651-C656 ◽  
Author(s):  
P. Babij ◽  
F. W. Booth
Keyword(s):  
Skeletal Muscle ◽  
Cytochrome C ◽  
Muscle Atrophy ◽  
Weight Bearing ◽  
Skeletal Muscle Atrophy ◽  
Rna Content ◽  
Mrna Content ◽  
Fast Twitch Muscle ◽  
Alpha Actin ◽  
Fast Twitch

Specific complementary DNA (cDNA) hybridization probes were used to estimate the levels of alpha-actin and cytochrome c mRNAs and also 18S rRNA in three models of skeletal muscle atrophy. After 7 days of hindlimb suspension, or immobilization, or denervation, protein content decreased 26-32% in all muscles studied except suspended fast-twitch muscle, which lost only half as much protein. alpha-Actin mRNA content decreased 51-66% and cytochrome c mRNA content decreased 42-61% in slow- and fast-twitch muscles in all three models of atrophy. However, total RNA content did not show similar directional changes; RNA content decreased 27-44% in suspended and immobilized muscle but was unchanged in denervated fast-twitch muscle. The results were interpreted to suggest that loss of weight-bearing function of skeletal muscle is a major factor affecting the levels of alpha-actin and cytochrome c mRNAs during muscle atrophy.

scholarly journals Insulin-sensitive regulation of glucose transport and GLUT4 translocation in skeletal muscle of GLUT1 transgenic mice

1998 ◽  
Vol 337 (1) ◽  
pp. 51-57 ◽  
Author(s):  
Garret J. ETGEN ◽  
William J. ZAVADOSKI ◽  
Geoffrey D. HOLMAN ◽  
E. Michael GIBBS
Keyword(s):  
Skeletal Muscle ◽  
Cell Surface ◽  
Transgenic Mice ◽  
Glucose Transport ◽  
Hind Limb ◽  
Glucose Transporter ◽  
Glut4 Translocation ◽  
Transport Activity ◽  
Fast Twitch Muscle ◽  
Fast Twitch

Skeletal muscle glucose transport was examined in transgenic mice overexpressing the glucose transporter GLUT1 using both the isolated incubated-muscle preparation and the hind-limb perfusion technique. In the absence of insulin, 2-deoxy-d-glucose uptake was increased ∼ 3–8-fold in isolated fast-twitch muscles of GLUT1 transgenic mice compared with non-transgenic siblings. Similarly, basal glucose transport activity was increased ∼ 4–14-fold in perfused fast-twitch muscles of transgenic mice. In non-transgenic mice insulin accelerated glucose transport activity ∼ 2–3-fold in isolated muscles and to a much greater extent (∼ 7–20-fold) in perfused hind-limb preparations. The observed effect of insulin on glucose transport in transgenic muscle was similarly dependent upon the technique used for measurement, as insulin had no effect on isolated fast-twitch muscle from transgenic mice, but significantly enhanced glucose transport in perfused fast-twitch muscle from transgenic mice to ∼ 50–75% of the magnitude of the increase observed in non-transgenic mice. Cell-surface glucose transporter content was assessed via 2-N-4-(l-azi-2,2,2-trifluoroethyl)benzoyl-1,3-bis-(d -mannos-4-yloxy)-2-propylamine photolabelling methodology in both isolated and perfused extensor digitorum longus (EDL). Cell-surface GLUT1 was enhanced by as much as 70-fold in both isolated and perfused EDL of transgenic mice. Insulin did not alter cell-surface GLUT1 in either transgenic or non-transgenic mice. Basal levels of cell-surface GLUT4, measured in either isolated or perfused EDL, were similar in transgenic and non-transgenic mice. Interestingly, insulin enhanced cell-surface GLUT4 ∼ 2-fold in isolated EDL and ∼ 6-fold in perfused EDL of both transgenic and non-transgenic mice. In summary, these results reveal differences between isolated muscle and perfused hind-limb techniques, with the latter method showing a more robust responsiveness to insulin. Furthermore, the results demonstrate that muscle overexpressing GLUT1 has normal insulin-induced GLUT4 translocation and the ability to augment glucose-transport activity above the elevated basal rates.

scholarly journals Skeletal muscle bioenergetics during all-out exercise: mechanistic insight into the oxygen uptake slow component and neuromuscular fatigue

2017 ◽  
Vol 122 (5) ◽  
pp. 1208-1217 ◽  
Author(s):  
Ryan M. Broxterman ◽  
Gwenael Layec ◽  
Thomas J. Hureau ◽  
Markus Amann ◽  
Russell S. Richardson
Keyword(s):  
Skeletal Muscle ◽  
Oxygen Uptake ◽  
Exercise Performance ◽  
Slow Component ◽  
Force Production ◽  
Atp Synthesis ◽  
Peripheral Fatigue ◽  
Synthesis Rate ◽  
Physiological Mechanisms ◽  
Exercise Induced

Although all-out exercise protocols are commonly used, the physiological mechanisms underlying all-out exercise performance are still unclear, and an in-depth assessment of skeletal muscle bioenergetics is lacking. Therefore, phosphorus magnetic resonance spectroscopy (31P-MRS) was utilized to assess skeletal muscle bioenergetics during a 5-min all-out intermittent isometric knee-extensor protocol in eight healthy men. Metabolic perturbation, adenosine triphosphate (ATP) synthesis rates, ATP cost of contraction, and mitochondrial capacity were determined from intramuscular concentrations of phosphocreatine (PCr), inorganic phosphate (Pi), diprotonated phosphate ([Formula: see text]), and pH. Peripheral fatigue was determined by exercise-induced alterations in potentiated quadriceps twitch force (Qtw) evoked by supramaximal electrical femoral nerve stimulation. The oxidative ATP synthesis rate (ATPOX) attained and then maintained peak values throughout the protocol, despite an ~63% decrease in quadriceps maximal force production. ThusATPOX normalized to force production (ATPOX gain) significantly increased throughout the exercise (1st min: 0.02 ± 0.01, 5th min: 0.04 ± 0.01 mM·min−1·N−1), as did the ATP cost of contraction (1st min: 0.048 ± 0.019, 5th min: 0.052 ± 0.015 mM·min−1·N−1). Additionally, the pre- to postexercise change in Qtw (−52 ± 26%) was significantly correlated with the exercise-induced change in intramuscular pH ( r = 0.75) and [Formula: see text] concentration ( r = 0.77). In conclusion, the all-out exercise protocol utilized in the present study elicited a “slow component-like” increase in intramuscular ATPOX gain as well as a progressive increase in the phosphate cost of contraction. Furthermore, the development of peripheral fatigue was closely related to the perturbation of specific fatigue-inducing intramuscular factors (i.e., pH and [Formula: see text] concentration). NEW & NOTEWORTHY The physiological mechanisms and skeletal muscle bioenergetics underlying all-out exercise performance are unclear. This study revealed an increase in oxidative ATP synthesis rate gain and the ATP cost of contraction during all-out exercise. Furthermore, peripheral fatigue was related to the perturbation in pH and deprotonated phosphate ion. These findings support the concept that the oxygen uptake slow component arises from within active skeletal muscle and that skeletal muscle force generating capacity is linked to the intramuscular metabolic milieu.

scholarly journals IL-6 increases muscle insulin sensitivity only at superphysiological levels

2007 ◽  
Vol 292 (6) ◽  
pp. E1842-E1846 ◽  
Author(s):  
Paige C. Geiger ◽  
Chad Hancock ◽  
David C. Wright ◽  
Dong-Ho Han ◽  
John O. Holloszy
Keyword(s):  
Insulin Sensitivity ◽  
Protein Kinase ◽  
Glucose Transport ◽  
Physiological Effects ◽  
Ampk Phosphorylation ◽  
Fast Twitch Muscle ◽  
Acute Increase ◽  
Exercise Induced ◽  
Amp Activated Protein Kinase ◽  
Fast Twitch

Exercise induces an increase in glucose transport in muscle. As the acute increase in glucose transport reverses, it is replaced by an increase in insulin sensitivity. Interleukin-6 (IL-6) increases with exercise and has been reported to activate AMP-activated protein kinase (AMPK). Based on this information, we hypothesized that IL-6 would result in an increase in muscle insulin sensitivity. Rat epitrochlearis and soleus muscles were incubated with 120 ng/ml IL-6. Exposure to IL-6 induced a modest acute increase in glucose transport and was followed 3.5 h later by an increase in insulin sensitivity in epitrochlearis but not soleus muscles. IL-6 also brought about an increase in AMPK phosphorylation in epitrochlearis muscles. We conclude that exposure of fast-twitch muscle to 120 ng/ml IL-6 increases insulin sensitivity by activating AMPK. However, exposure of epitrochlearis muscles to 10 ng/ml IL-6, a concentration >100-fold higher than that attained in plasma during exercise, had no effect on glucose transport or insulin sensitivity. These findings provide evidence that the increases in glucose transport and insulin sensitivity induced by IL-6 are pharmacological rather than physiological effects. We interpret our results as evidence that the increase in IL-6 during exercise does not play a role in the exercise-induced increases in muscle glucose uptake and insulin sensitivity.

scholarly journals Biomechanical Properties of the Sarcolemma and Costameres of Skeletal Muscle Lacking Desmin

2021 ◽  
Vol 12 ◽  
Author(s):  
Karla P. Garcia-Pelagio ◽  
Robert J. Bloch
Keyword(s):  
Skeletal Muscle ◽  
Lateral Force ◽  
Biomechanical Properties ◽  
Contractile Force ◽  
Contractile Apparatus ◽  
Force Transmission ◽  
Fast Twitch Muscle ◽  
Intracellular Organelles ◽  
Time Required ◽  
Fast Twitch

Intermediate filaments (IFs), composed primarily by desmin and keratins, link the myofibrils to each other, to intracellular organelles, and to the sarcolemma. There they may play an important role in transfer of contractile force from the Z-disks and M-lines of neighboring myofibrils to costameres at the membrane, across the membrane to the extracellular matrix, and ultimately to the tendon (“lateral force transmission”). We measured the elasticity of the sarcolemma and the connections it makes at costameres with the underlying contractile apparatus of individual fast twitch muscle fibers of desmin-null mice. By positioning a suction pipet to the surface of the sarcolemma and applying increasing pressure, we determined the pressure at which the sarcolemma separated from nearby sarcomeres, Pseparation, and the pressure at which the isolated sarcolemma burst, Pbursting. We also examined the time required for the intact sarcolemma-costamere-sarcomere complex to reach equilibrium at lower pressures. All measurements showed the desmin-null fibers to have slower equilibrium times and lower Pseparation and Pbursting than controls, suggesting that the sarcolemma and its costameric links to nearby contractile structures were weaker in the absence of desmin. Comparisons to earlier values determined for muscles lacking dystrophin or synemin suggest that the desmin-null phenotype is more stable than the former and less stable than the latter. Our results are consistent with the moderate myopathy seen in desmin-null muscles and support the idea that desmin contributes significantly to sarcolemmal stability and lateral force transmission.

scholarly journals Six1 promotes skeletal muscle thyroid hormone response through regulation of the MCT10 transporter

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
John Girgis ◽  
Dabo Yang ◽  
Imane Chakroun ◽  
Yubing Liu ◽  
Alexandre Blais
Keyword(s):  
Gene Expression ◽  
Skeletal Muscle ◽  
Thyroid Hormone ◽  
Tibialis Anterior ◽  
Molecular Mechanisms ◽  
Thyroid Hormone Receptor ◽  
Muscle Metabolism ◽  
Loss Of Function ◽  
Fast Twitch Muscle ◽  
Fast Twitch

Abstract Background The Six1 transcription factor is implicated in controlling the development of several tissue types, notably skeletal muscle. Six1 also contributes to muscle metabolism and its activity is associated with the fast-twitch, glycolytic phenotype. Six1 regulates the expression of certain genes of the fast muscle program by directly stimulating their transcription or indirectly acting through a long non-coding RNA. We hypothesized that additional mechanisms of action of Six1 might be at play. Methods A combined analysis of gene expression profiling and genome-wide location analysis data was performed. Results were validated using in vivo RNA interference loss-of-function assays followed by measurement of gene expression by RT-PCR and transcriptional reporter assays. Results The Slc16a10 gene, encoding the thyroid hormone transmembrane transporter MCT10, was identified as a gene with a transcriptional enhancer directly bound by Six1 and requiring Six1 activity for full expression in adult mouse tibialis anterior, a predominantly fast-twitch muscle. Of the various thyroid hormone transporters, MCT10 mRNA was found to be the most abundant in skeletal muscle, and to have a stronger expression in fast-twitch compared to slow-twitch muscle groups. Loss-of-function of MCT10 in the tibialis anterior recapitulated the effect of Six1 on the expression of fast-twitch muscle genes and led to lower activity of a thyroid hormone receptor-dependent reporter gene. Conclusions These results shed light on the molecular mechanisms controlling the tissue expression profile of MCT10 and identify modulation of the thyroid hormone signaling pathway as an additional mechanism by which Six1 influences skeletal muscle metabolism.

Expression of hybrid isomyosins in human skeletal muscle

1996 ◽  
Vol 271 (4) ◽  
pp. C1250-C1255 ◽  
Author(s):  
M. Wada ◽  
T. Okumoto ◽  
K. Toro ◽  
K. Masuda ◽  
T. Fukubayashi ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Human Skeletal Muscle ◽  
Polyacrylamide Gel Electrophoresis ◽  
Sodium Dodecyl ◽  
Subunit Composition ◽  
Intact Muscle ◽  
Slow Twitch Muscle ◽  
Fast Twitch Muscle ◽  
Slow Twitch ◽  
Fast Twitch

Myosin of human skeletal muscles was analyzed by means of several electrophoretic techniques. Myosin heavy chain (HC)-IIa-and HC-IIb-based isomyosins were identified by pyrophosphate-polyacrylamide gel electrophoresis (PP-PAGE). The electrophoretic mobilities of these fast-twitch muscle isomyosins differed in the order HC-IIa triplets < HC-IIb triplets. To determine the subunit composition of myosin molecules that function in intact muscle, two-dimensional electrophoresis in which the first and second dimensions were PP-PAGE and sodium dodecyl sulfate-PAGE, respectively, was also performed. Slow-twitch muscle isomyosin contained, in addition to slow-twitch light chain (LC) and HC-I isoforms, appreciable amounts of LC-2f, HC-IIa, and HC-IIb isoforms, and fast-twitch muscle isomyosin consisted of LC-2s and HC-I isoforms as well as fast-twitch LC and HC isoforms. Without consideration of HC- and slow-twitch alkali LC heterodimers, at least 31 possible isomyosins are derived from these findings on the subunit composition of isomyosins in human skeletal muscle.

scholarly journals Role of physiological ClC-1 Cl− ion channel regulation for the excitability and function of working skeletal muscle

2016 ◽  
Vol 147 (4) ◽  
pp. 291-308 ◽  
Author(s):  
Thomas Holm Pedersen ◽  
Anders Riisager ◽  
Frank Vincenzo de Paoli ◽  
Tsung-Yu Chen ◽  
Ole Bækgaard Nielsen
Keyword(s):  
Skeletal Muscle ◽  
Muscle Activity ◽  
Muscle Fibers ◽  
Membrane Conductance ◽  
Membrane Properties ◽  
Equilibrium Potential ◽  
Myotonia Congenita ◽  
Clcn1 Gene ◽  
Wide Range ◽  
Muscle Excitability

Electrical membrane properties of skeletal muscle fibers have been thoroughly studied over the last five to six decades. This has shown that muscle fibers from a wide range of species, including fish, amphibians, reptiles, birds, and mammals, are all characterized by high resting membrane permeability for Cl− ions. Thus, in resting human muscle, ClC-1 Cl− ion channels account for ∼80% of the membrane conductance, and because active Cl− transport is limited in muscle fibers, the equilibrium potential for Cl− lies close to the resting membrane potential. These conditions—high membrane conductance and passive distribution—enable ClC-1 to conduct membrane current that inhibits muscle excitability. This depressing effect of ClC-1 current on muscle excitability has mostly been associated with skeletal muscle hyperexcitability in myotonia congenita, which arises from loss-of-function mutations in the CLCN1 gene. However, given that ClC-1 must be drastically inhibited (∼80%) before myotonia develops, more recent studies have explored whether acute and more subtle ClC-1 regulation contributes to controlling the excitability of working muscle. Methods were developed to measure ClC-1 function with subsecond temporal resolution in action potential firing muscle fibers. These and other techniques have revealed that ClC-1 function is controlled by multiple cellular signals during muscle activity. Thus, onset of muscle activity triggers ClC-1 inhibition via protein kinase C, intracellular acidosis, and lactate ions. This inhibition is important for preserving excitability of working muscle in the face of activity-induced elevation of extracellular K+ and accumulating inactivation of voltage-gated sodium channels. Furthermore, during prolonged activity, a marked ClC-1 activation can develop that compromises muscle excitability. Data from ClC-1 expression systems suggest that this ClC-1 activation may arise from loss of regulation by adenosine nucleotides and/or oxidation. The present review summarizes the current knowledge of the physiological factors that control ClC-1 function in active muscle.

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