Skeletal muscle Pi transport and cellular [Pi] studied in L6 myoblasts and rabbit muscle-membrane vesicles

Phosphate uptake and PiT-1 protein expression in rat skeletal muscle

Skeletal muscle fiber types differ in their contents of total phosphate, which includes inorganic phosphate (P(i)) and high-energy organic pools of ATP and phosphocreatine (PCr). At steady state, uptake of P(i) into the cell must equal the rate of efflux, which is expected to be a function of intracellular P(i) concentration. We measured (32)P-labeled P(i) uptake rates in different muscle fiber types to determine whether they are proportional to cellular P(i) content. P(i) uptake rates in isolated, perfused rat hindlimb muscles were linear over time and highest in soleus (2.42 +/- 0.17 micromol x g(-1) x h(-1)), lower in red gastrocnemius (1.31 +/- 0.11 micromol x g(-1) x h(-1)), and lowest in white gastrocnemius (0.49 +/- 0.06 micromol x g(-1) x h(-1)). Reasonably similar rates were obtained in vivo. P(i) uptake rates at plasma P(i) concentrations of 0.3-1.7 mM confirm that the P(i) uptake process is nearly saturated at normal plasma P(i) levels. P(i) uptake rate correlated with cellular P(i) content (r = 0.99) but varied inversely with total phosphate content. Sodium-phosphate cotransporter (PiT-1) protein expression in soleus and red gastrocnemius were similar to each other and seven- to eightfold greater than PiT-1 expression in white gastrocnemius. That the PiT-1 expression pattern did not match the pattern of P(i) uptake across fiber types implies that other factors are involved in regulating P(i) uptake in skeletal muscle. Furthermore, fractional turnover of the cellular P(i) pool (0.67, 0.57, and 0.33 h(-1) in soleus, red gastrocnemius, and white gastrocnemius, respectively) varies among fiber types, indicating differential management of intracellular P(i), likely due to differences in resistance to P(i) efflux from the fiber.

Na+-K+ Pump Regulation and Skeletal Muscle Contractility

Clausen, Torben. Na+-K+ Pump Regulation and Skeletal Muscle Contractility. Physiol Rev 83: 1269-1324, 2003; 10.1152/physrev.00011.2003.—In skeletal muscle, excitation may cause loss of K+, increased extracellular K+ ([K+]o), intracellular Na+ ([Na+]i), and depolarization. Since these events interfere with excitability, the processes of excitation can be self-limiting. During work, therefore, the impending loss of excitability has to be counterbalanced by prompt restoration of Na+-K+ gradients. Since this is the major function of the Na+-K+ pumps, it is crucial that their activity and capacity are adequate. This is achieved in two ways: 1) by acute activation of the Na+-K+ pumps and 2) by long-term regulation of Na+-K+ pump content or capacity. 1) Depending on frequency of stimulation, excitation may activate up to all of the Na+-K+ pumps available within 10 s, causing up to 22-fold increase in Na+ efflux. Activation of the Na+-K+ pumps by hormones is slower and less pronounced. When muscles are inhibited by high [K+]o or low [Na+]o, acute hormone- or excitation-induced activation of the Na+-K+ pumps can restore excitability and contractile force in 10-20 min. Conversely, inhibition of the Na+-K+ pumps by ouabain leads to progressive loss of contractility and endurance. 2) Na+-K+ pump content is upregulated by training, thyroid hormones, insulin, glucocorticoids, and K+ overload. Downregulation is seen during immobilization, K+ deficiency, hypoxia, heart failure, hypothyroidism, starvation, diabetes, alcoholism, myotonic dystrophy, and McArdle disease. Reduced Na+-K+ pump content leads to loss of contractility and endurance, possibly contributing to the fatigue associated with several of these conditions. Increasing excitation-induced Na+ influx by augmenting the open-time or the content of Na+ channels reduces contractile endurance. Excitability and contractility depend on the ratio between passive Na+-K+ leaks and Na+-K+ pump activity, the passive leaks often playing a dominant role. The Na+-K+ pump is a central target for regulation of Na+-K+ distribution and excitability, essential for second-to-second ongoing maintenance of excitability during work.

Impaired system A amino acid transport mimics the catabolic effects of acid in L6 cells

BACKGROUND

Metabolic acidaemia stimulates protein catabolism in skeletal muscle cells, leading to muscle wasting. As this occurs without decreasing cytosolic pH, the initial signal is unclear. A possible explanation is that extracellular pH acts on solute transporters at the cell surface, inhibiting nutrient influx.

DESIGN

Influx through glucose and Pi transporters and System A amino acid transporters into L6 skeletal muscle cells was assessed using 3H-2-deoxyglucose (2-DG), 33Pi and 14C-methylaminoisobutyrate (MeAIB), respectively. Protein degradation (PD) was assessed from 14C efflux from cells prelabelled with 14C-Phe. Branched-chain amino acids and Phe were assayed by selective fluorimetric assays.

RESULTS

While acid (pH 7.1) had little immediate effect on 2-DG or 33Pi influx, exposure to pH 7.1 rapidly inhibited MeAIB influx. To determine whether System A inhibition was sufficient to trigger PD, it was blocked at pH 7.5 by a saturating dose (10 mmol L(-1)) of nonmetabolisable substrate (MeAIB). Like acid, this increased PD and decreased total protein. It also mimicked the decreases in protein synthesis, DNA synthesis, glucose transport and glycolysis, and depletion of branched-chain amino acids and Phe, which are induced in L6 by acid. The onset of inhibition of PD by an extracellular Gln load was retarded at pH 7.1, and stimulation of PD by acid was negligible if PD had already been stimulated by Gln depletion. The stimulatory effect of MeAIB on PD was selectively blunted by an excess of Gln, whereas the inhibitory effect of Gln on PD was blocked by excess MeAIB.

CONCLUSIONS

The similarity of changes in response to MeAIB and acid implies that these share a common intracellular signalling pathway triggered by inhibition of System A. Even though System A is only a minor contributor to total Gln influx in L6 cells, it is suggested that blockade of System A with acid or MeAIB induces a catabolic state by denying Gln access to a key intracellular regulatory site.

Increased tetanic force and reduced myoplasmic [P(i)] following a brief series of tetani in mouse soleus muscle

Muscle performance is improved after a brief period of exercise (warm-up). One factor that is known to strongly affect force production is the myoplasmic concentration of inorganic phosphate ([P(i)]). Improved performance after warm-up may therefore be due to a reduction of [P(i)]. Herein, we show that after a warm-up protocol (15 tetani at 2-s intervals), tetanic force is increased by approximately 6% (P < 0.05) and [P(i)] is almost halved (P < 0.05) in isolated mouse soleus muscle. A warm-up protocol with longer intervals (15 tetani at 5-s intervals) reduced tetanic force and did not alter [P(i)]. We conclude that a reduction of [P(i)] contributes to the force-potentiating effect of warm-up.

Twitch characteristics and energy metabolites of mature muscle fibres of Xenopus laevis in culture

Mature, high-oxidative, skeletal muscle fibres of Xenopus laevis were kept in culture in L-(Leibovitz's)-15 medium supplemented with creatine and antibiotics and some other additions. Single fibres were mounted at a fixed sarcomere length in a flow-through culture chamber which accommodates stimulus electrodes and a force transducer. Twitch characteristics were determined daily. Depending on culture conditions, fibres remained excitable electrically for up to two weeks at 20 degrees C when foetal calf serum and/or phosphate were added to the culture medium. During the second week, fibres lost phosphocreatine and ATP, but relatively small changes (if any) in total creatine, glycogen and protein contents, fibre volume and dry weight occurred. Succinate dehydrogenase activity decreased after 9 days-when ATP was reduced already. Fibres which were inexcitable electrically contracted normally when exposed to caffeine, indicating that excitation-contraction coupling failed and that the contractile apparatus was still functional.

The regulation of total creatine content in a myoblast cell line

Total cellular creatine content is an important bioenergetic parameter in skeletal muscle. To understand its regulation we investigated creatine transport and accumulation in the G8 cultured skeletal myoblast line. Like other cell types, these contain a creatine transporter, whose activity, measured using a radiolabelling technique, was saturable (Km = 110 +/- 25 microM) and largely dependent on extracellular [Na+]. To study sustained influences on steady state creatine concentration we measured total cellular creatine content using a fluorimetric method in 48 h incubations. We found that the total cellular creatine content was relatively independent of extracellular creatine concentration, consistent with high affinity sodium-dependent uptake balanced by slow passive efflux. Accordingly, in creatine-free incubations net creatine efflux was slow (5 +/- 1% of basal creatine content per day over 6 days), while creatine content in 48 h incubations was reduced by 28 +/- 13% of control by the Na+, K(+)-ATPase inhibitor ouabain. Creatine accumulation after 48 h was stimulated by treatment with the mixed alpha- and beta-adrenergic agonist noradrenaline, the beta-adrenergic agonist isoproterenol, the beta 2-agonist clenbuterol and the cAMP analogue N6,2'-O-dibutyryladenosine 3',5'-cyclic monophosphate, but was unaffected by the alpha 1 adrenergic agonist methoxamine. The noradrenaline enhancement of creatine accumulation at 48 h was inhibited by the mixed alpha- and beta-antagonist labetalol and by the beta-antagonist propranolol, but was unaffected by the alpha 2 antagonist phentolamine; greater inhibition was caused by the beta 2 antagonist butoxamine than the beta 1 antagonist atenolol. Creatine accumulation at 48 h was increased to 230 +/- 6% of control by insulin and by 140 +/- 13% by IGF-I (both at 3 nM). Creatine accumulation at 48 h was also increased to 280 +/- 40% of control by 3,3',5-triiodothyronine (at 70 microM) and to 220 +/- 35% of control by amylin (60 nM). As 3,3', 5-triiodothyronine, amylin and isoproterenol all stimulate the Na+, K(+)-ATPase, we suggest that they stimulate Na(+)-creatine cotransport indirectly by increasing the transmembrane [Na+] concentration gradient and membrane potential.

The effects of intracellular injections of phosphate on intracellular calcium and force in single fibres of mouse skeletal muscle

Intracellular inorganic phosphate increases during muscle fatigue and may be responsible for certain of the changes in muscle function observed in fatigue. To test this hypothesis inorganic phosphate was micro-injected in single mouse muscle fibres which were also injected with indo-1 to measure intracellular Ca2+. Following phosphate injection, intracellular Ca2+, both at rest and during tetani, was reduced as was tetanic force. The rate at which the sarcoplasmic reticulum (SR) pumped Ca2+ out of the myoplasm was accelerated following phosphate injection. Intracellular Ca2+ and force recovered over 1-h. The changes in maximum Ca2+-activated force and Ca2+ sensitivity which would be expected if the phosphate remained in the myoplasm were largely absent. The most likely interpretation is that inorganic phosphate enters the SR where it precipitates with Ca2+ and thereby reduced release of Ca2+ from the SR and accelerated the rate of uptake of Ca2+ by the pump. The 1-h recovery may represent the entry of additional Ca2+ into the cell to reestablish the normal gradient of Ca2+ across the sarcolemma.

Assessment of mitochondrial function and control in normal and diseased states

Mitochondrial function in muscle in vivo can be quantitatively evaluated using 31-phosphorus nuclear magnetic resonance. In resting muscle, the concentrations of ions (e.g. H+, Na+) and two of the major bioenergetic components (inorganic phosphate and creatine) are determined by regulated transcellular transport processes. During recovery after exercise the kinetics and control of mitochondrial ATP synthesis can be established. During exercise the relative contributions to ATP synthesis of phosphocreatine (using creatine kinase), anaerobic glycogenolysis and oxidative phosphorylation are dissected and have been shown to change with time. The consequences of mitochondrial lesions and dysfunctions on these processes have been summarised.

Bioenergetics of skeletal muscle in mitochondrial myopathy

31Phosphorus nuclear magnetic resonance spectroscopy was used to examine skeletal muscle in 29 patients with mitochondrial myopathy, 9 male and 20 female. Gastrocnemius was investigated in 15 patients and 30 normal subjects and finger flexor muscle (flexor digitorum superficialis, fds) in 24 patients and 35 normal controls. Both muscles were studied in 10 of the patients. Results were abnormal (outside the full range of normal values) in all but 2 patients. In 86% of patients (25/29) abnormalities were detected in resting muscle. In most cases there was a low phosphocreatine/ATP ratio, high calculated free [ADP] and low phosphorylation potential. At rest, abnormality was detected with equal ease in fds and gastrocnemius. Exercise and recovery increased the sensitivity of MRS in detecting abnormal metabolism. Finger flexion was better tolerated by patients than plantar flexion and gave bigger changes in metabolite concentrations and intracellular pH. Thus, results from fds were more easily differentiated from normal. Exercise duration was significantly shorter than in controls while phosphocreatine depletion was more rapid than normal, consistent with a shortfall in mitochondrial ATP synthesis. Nearly all patients (25/27, 93%) showed abnormalities during recovery from exercise. [ADP] was high during exercise and its recovery was delayed, providing increased drive for oxidative phosphorylation. Phosphocreatine resynthesis during recovery (which reflects oxidative ATP synthesis) was slow both in absolute terms and in relation to [ADP]. Recovery of intracellular pH after exercise was significantly more rapid than normal, consistent with an upregulation of proton efflux.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of Pi transport in skeletal muscle by insulin and IGF-1

In vivo, skeletal muscle Pi uptake influences both muscle cellular [Pi] and plasma [Pi], and may mediate the hypophosphataemic effects of insulin and insulin-like growth factor 1 (IGF-1). These effects were investigated in the cultured mouse myoblast cell line G8 and the isolated incubated rat soleus. The low Km for Pi in G8 cells is consistent with in vivo evidence that muscle cell [Pi] is partially protected against changes in plasma [Pi]. Insulin and IGF-1 stimulated Na-dependent Pi influx: in G8 cells both increased Vmax, with no change in Km, but while the insulin response occurred within 15 min and rapidly reversed upon insulin withdrawal, the response to IGF-1 occurred only after 60 min and persisted at least 60 min following IGF-1 withdrawal. Furthermore, only the IGF-1 response was inhibited by cycloheximide. We suggest that IGF-1 operates through de novo protein synthesis, while insulin stimulates transporter recruitment to the cell surface.