Regulation of creatine kinase during steady-state isometric twitch contraction in rat skeletal muscle

In vivo 31P-NMR saturation transfer measurements of the creatine kinase exchange flux in the direction creatine phosphate----ATP were made in the gastrocnemius muscle of rats at rest and during steady-state isometric twitch contraction at frequencies from 0.25 to 2 Hz. There was no correlation between creatine kinase exchange flux and either free [ADP] or oxygen consumption, both of which increase with stimulation frequency. The flux was found to be nearly constant over all conditions at about 16 mM X s-1, 10-times greater than the highest estimated ATP turnover in this study. The kinetic properties of skeletal muscle creatine kinase in vivo are similar to, but not completely predictable from, the equilibrium exchange fluxes measured on the isolated enzyme. These results are not consistent with strong functional coupling between ATP synthesis and mitochondrial creatine kinase.     

31P NMR magnetization-transfer measurements of ATP turnover during steady-state isometric muscle contraction in the rat hind limb in vivo

31P NMR magnetization-transfer measurements have been used to measure the flux between ATP and inorganic phosphate during steady-state isometric muscle contraction in the rat hind limb in vivo. Steady-state contraction was obtained by supramaximal sciatic nerve stimulation. Increasing the stimulation pulse width from 10 to 90 ms, at a pulse frequency of 1 Hz, or increasing the frequency of a 10-ms pulse from 0.5 to 2 Hz resulted in an increase in the flux which was an approximately linear function of the increase in the tension-time integral. The flux showed an approximately linear dependence on the calculated free cytosolic ADP concentration up to an ADP concentration of about 90 microM. The data are consistent with control of mitochondrial ATP synthesis by the cytosolic ADP concentration and indicate that the apparent Km of the mitochondria for ADP is at least 30 microM.     

Effect of an ADP analog on isometric force and ATPase activity of active muscle fibers

The role played by ADP in modulatingcross-bridge function has been difficult to study, because it is hardto buffer ADP concentration in skinned muscle preparations. To solvethis, we used an analog of ADP, spin-labeled ADP (SL-ADP). SL-ADP bindstightly to myosin but is a very poor substrate for creatine kinase orpyruvate kinase. Thus ATP can be regenerated, allowing well-definedconcentrations of both ATP and SL-ADP. We measured isometric ATPaserate and isometric tension as a function of both [SL-ADP], 0.1-2mM, and [ATP], 0.05-0.5 mM, in skinned rabbit psoas muscle,simulating fresh or fatigued states. Saturating levels of SL-ADPincreased isometric tension (by P'), the absolute value of P' beingnearly constant, ~0.04 N/mm², in variable ATP levels, pH7. Tension decreased (50-60%) at pH 6, but upon addition ofSL-ADP, P' was still ~0.04 N/mm². The ATPase wasinhibited competitively by SL-ADP with an inhibition constant,K_i, of ~240 and 280 µM at pH 7 and 6, respectively. Isometric force and ATPase activity could both be fit bya simple model of cross-bridge kinetics.

     

31P-NMR observation of free ADP during fatiguing, repetitive contractions of murine skeletal muscle lacking AK1

Metabolic control within skeletal muscle is designed to limit ADP accumulation even during conditions where ATP demand is out of balance with ATP synthesis. This is accomplished by the reactions of adenylate kinase (AK; ADP+ADP AMP+ATP) and AMP deaminase (AMP+H₂O NH₃+IMP), which limit ADP accumulation under these conditions. The purpose of this study was to determine whether AK deficiency (AK^–/–) would result in sufficient ADP accumulation to be visible using ³¹P-NMRS during the high energy demands of frequent in situ tetanic contractions. To do this we examined the high-energy phosphates of the gastrocnemius muscle in the knockout mouse with AK1^–/– and wild-type (WT) control muscle over the course of 64 rapid (2/s) isometric tetanic contractions. Near-complete depletion of phosphocreatine was apparent after 16 contractions in both groups. By 40 contractions, ADP was clearly visible in AK1^–/– muscle. This transient concentration of the NMR visible free ADP was estimated to be 1.7 mM, and represents the first time free ADP has been directly measured in contracting skeletal muscle. Such an increase in free ADP is severalfold greater than previously thought to occur. This large accumulation of free ADP also represents a significant reduction in energy available from ATP, and has implications on cellular processes that depend on a high yield of energy from ATP such as calcium sequestration. Remarkably, the AK1^–/– and WT muscles exhibited similar fatigue profiles. Our findings suggest that skeletal muscle is surprisingly tolerant to a large increase in ADP and by extension, a decline in energy from ATP. muscle energetics; muscle relaxation; magnetic resonance spectroscopy     

Control of mitochondrial respiration in muscle

Summary Control of mitochondrial respiration depends on ADP availability to the F₁ATPase. An electrochemical gradient of ADP and ATP across the mitochondrial inner membrane is maintained by the adenine nucleotide translocase which provides ADP to the matrix for ATP synthesis and ATP for energy-dependent processes in the cytosol. Mitochondrial respiration is responsive to the cytosolic phosphorylation potential, ATP/ADP · P_i which is in apparent equilibrium with the first two sites in the electron transport chain. Conventional measures of free adenine nucleotides is a confounding issue in determining cytosolic and mitochondrial phosphorylation potentials. The advent of phosphorus-31 nuclear magnetic resonance (P-31 NMR) allows the determination of intracellular free concentrations of ATP, creatine-P and Pi in perfused muscle in situ. In the glucose-perfused heart, there is an absence of correlation between the cytosolic phosphorylation potential as determined by P-31 NMR and cardiac oxygen consumption over a range of work loads. These data suggest that contractile work leads to increased generation of mitochondrial NADH so that ATP production keeps pace with myosin ATPase activity. The mechanism of increased ATP synthesis is referred to as stimulusre-sponse-metabolism coupling. In muscle, increased contractility is a result of interventions which increase cytosolic free Ca²⁺ concentrations. The Ca^2- signal thus generated increases glycogen breakdown and myosin ATPase in the cytosol. This signal is concomitantly transmitted to the mitochondria which respond to small increases in matrix Ca²⁺ by activation of Ca²⁺-sensitive dehydrogenases. The Ca²⁺-activated dehydrogenase activities are key rate-controlling enzymes in tricarboxylic acid cycle flux, and their activation by Ca^2- leads to increased pyridine nucleotide reduction and oxidative phosphorylation. These observations which have been consistent in preparations both in vitro and in situ do not obviate a role for ADP control of muscle respiration, but do explain, in part, the lack of dramatic fluctuations in the cytosolic phosphorylation potential over a large range of contractile activities.     

Phosphocreatine kinetics at the onset of contractions in skeletal muscle of MM creatine kinase knockout mice

Phosphocreatine (PCr) depletion duringisometric twitch stimulation at 5 Hz was measured by³¹P-NMR spectroscopy in gastrocnemius muscles ofpentobarbital-anesthetized MM creatine kinase knockout (MMKO) vs.wild-type C57B (WT) mice. PCr depletion after 2 s of stimulation,estimated from the difference between spectra gated to times 200 ms and140 s after 2-s bursts of contractions, was 2.2 ± 0.6% ofinitial PCr in MMKO muscle vs. 9.7 ± 1.6% in WT muscles(mean ± SE, n = 7, P < 0.001).Initial PCr/ATP ratio and intracellular pH were not significantlydifferent between groups, and there was no detectable change inintracellular pH or ATP in either group after 2 s. The initialdifference in net PCr depletion was maintained during the first minuteof continuous 5-Hz stimulation. However, there was no significantdifference in the quasi-steady-state PCr level approached after 80 s (MMKO 36.1 ± 3.5 vs. WT 35.5 ± 4.4% of initial PCr;n = 5-6). A kinetic model of ATPase, creatinekinase, and adenylate kinase fluxes during stimulation was consistentwith the observed PCr depletion in MMKO muscle after 2 s only ifADP-stimulated oxidative phosphorylation was included in the model.Taken together, the results suggest that cytoplasmic ADP more rapidlyincreases and oxidative phosphorylation is more rapidly activated atthe onset of contractions in MMKO compared with WT muscles.

     

Regulation analysis of contractile ATPase flux in skeletal muscle

The [Ca²⁺] regulation of contractile ATPase flux, J _p, in skeletal muscle was analysed by computation of the Response R ^Jp _Ca2+ for a 10 Hz range of electrical stimulation frequencies. Results of our analysis of the kinetic controls in ATP free energy metabolism in a network model of contracting muscle (J.A.L. Jeneson, H.V. Westerhoff and M.J. Kushmerick (2000) Am. J. Physiol. 279, C813–C832) formed the basis for the computations of R ^Jp _Ca2+. We found that neural regulation of sustained force generation via simple [Ca²⁺]_cyto frequency encoding in the network was robust for frequencies up to 2 Hz. Above 2 Hz, however, this regulation design broke down because of a shift in contractile ATPase flux control from the Ca²⁺-sensitive contractile filaments to mitochondria with low Ca²⁺ sensitivity. The role of glyco(geno)lytic ATP production at high contraction workloads is discussed in the context of this result     

Regulation of glycolytic flux in an energetically controlled cell-free system: the effects of adenine nucleotide ratios, inorganic phosphate, pH, and citrate

A soluble extract from rat skeletal muscles has been used with purified mitochondrial ATPase (F₁) to develop steady states with respect to glycolytic flux, the concentrations of glycolytic intermediates and inorganic phosphate, and the concentrations and ratios of adenine nucleotides. Incubations were carried out in media resembling the ionic composition in the cell cytoplasm, in an attempt to evaluate the quantitative contributions of various effectors to the overall control mechanism under simulated in vivo conditions. The primary control reaction of glycolytic flux under the conditions studied could be identified with phosphofructokinase, followed by secondary control of the reaction catalyzed by hexokinase. Glycolytic flux was increased with increasing pH over the range 6.6–7.6, both in the absence and presence of ATPase. Without other added effectors, the glycolyzing extract maintained an ATP/ADP ratio of about 50 in the pH range 7.0–7.6, and phosphofructokinase was incompletely suppressed. Addition of increasing amounts of ATPase markedly stimulated glycolytic flux coincident with lowered steady-state ATP/ADP ratios, and decreased accumulation of hexose monophosphates. Control of flux by the ATP/ADP ratio (and simultaneously altered AMP concentration) was less effective if pH (7.3 to 7.6) or phosphate concentration (2 to 20 mm) was increased. Flux through phosphofructokinase was controlled principally when the ATP/ADP ratios were varied in the range between > 50 and 15. The inhibitory effect of citrate was evaluated. Suppression of glycolytic flux and accumulation of hexose monophosphates were dependent on incubation conditions. If the pH was 7.3 or less, and the phosphate concentration low (2 mm), flux through phosphofructokinase was significantly suppressed even at citrate concentrations less than 50 μm. Simultaneous decrease in the steady-state ATP/ADP ratio and elevation of AMP was ineffective in reversing this inhibition. At higher pH and, more dramatically, when the phosphate concentration was increased, sensitivity to citrate inhibition was markedly diminished. These data, taken together with studies of respiratory control with isolated mitochondria (21., 24.), J. Biol. Chem.250, 2275–2282) strongly suggest that adenine nucleotide control of both glycolysis and respiration is exerted when the ratio of free nucleotides (not protein bound) in the cytosol is in the range of 15 to > 50. The data further suggest that citrate plays an important role in the regulation of glycolysis in muscle when the ATP/ADP ratio is high (and the phosphate concentration is correspondingly low), but that this inhibition is overcome by liberation of inorganic phosphate during muscle contraction.     

Role of phosphocreatine in energy transport in skeletal muscle of bullfrog studied by 31P-NMR

To evaluate the energy-shuttle hypothesis of the phosphocreatine/creatine kinase system, diffusion rates for ATP, phosphocreatine and flux through the creatine kinase reaction were determined by 31P-NMR in resting bullfrog biceps muscle. The diffusion coefficient of phosphocreatine measured by 31P-pulsed gradient NMR was 1.4-times larger than ATP in the muscle, indicating the advantage of phosphocreatine molecules for the intracellular energy transport. The flux of the creatine kinase reaction measured by 31P-saturation transfer NMR was 3.6 mmol/kg wet wt. per s in the resting muscle. The flux is equal to the turnover rate of ATP, ADP, phosphocreatine and creatine molecules, therefore, the life-times of these substrates and the average distance traversed after the life-times by the diffusing molecules were calculated using the diffusion coefficients obtained by 31P-NMR. The mean square length of one-dimensional diffusion was 22 microns in ATP molecules and the minimum diffusion length was 1.8 microns in ADP molecules. The latter was calculated using free ADP concentration, 30 mumol/kg wet wt., obtained from the equilibrium constant of the creatine kinase reaction and the diffusion coefficient assumed to be the same of ATP in muscle. Similar diffusion lengths of ADP were calculated using the reported values for the flux of the creatine kinase reaction in heart and smooth-muscle. The diffusion lengths of all substrates involved in the creatine kinase reaction were larger than the radii of myofibrils. Therefore, in the muscles with an alternating arrangement of mitochondria and myofibrils, such as heart and certain skeletal muscles, ATP and ADP molecules can move freely between myofibrils and mitochondria without the aid of the creatine kinase reaction; thus, we conclude that the energy-shuttle hypothesis is not obligatory for energy transport between the mitochondria and the myofibrils.     

Efficiency of human skeletal muscle in vivo: comparison of isometric, concentric, and eccentric muscle action

Ryschon, T. W., Fowler, R. E. Wysong, A.-R. Anthony, and R. S. Balaban. Efficiency of human skeletal muscle in vivo: comparison of isometric, concentric, and eccentric muscle action. J. Appl. Physiol. 83(3): 867-874, 1997.The purpose of this study was to estimate the efficiency of ATPutilization for concentric, eccentric, and isometric muscle action inthe human tibialis anterior and extensor digitorum longus in vivo. Adynamometer was used to quantitate muscle work, or tension, whilesimultaneous ³¹P-nuclear magneticresonance data were collected to monitor ATP, phosphocreatine,inorganic phosphate, and pH. The relative efficiency of the actions wasestimated in two ways: steady-state effects on high-energyphosphates and a direct comparison of ATP synthesis rates with work. Inthe steady state, the cytosolic free energy dropped to the lowest valuewith concentric activity, followed by eccentric and isometric actionfor comparative muscle tensions. Estimates of ATP synthesis ratesrevealed a mechanochemical efficiency [i.e., ATP productionrate/work (both in J/s)] of 15.0 ± 1.3% in concentric and34.7 ± 6.1% in eccentric activity. The estimated maximum ATPproduction rate was highest in concentric action, suggesting anactivation of energy metabolism under these conditions. By using directmeasures of metabolic strain and ATP turnover, these data demonstrate adecreasing metabolic efficiency in human muscle action from isometric,to eccentric, to concentric action.

     

Skeletal muscle contractile performance and ADP accumulation in adenylate kinase-deficient mice

The production of AMP by adenylate kinase (AK) and subsequent deamination by AMP deaminase limits ADP accumulation during conditions of high-energy demand in skeletal muscle. The goal of this study was to investigate the consequences of AK deficiency (–/–) on adenine nucleotide management and whole muscle function at high-energy demands. To do this, we examined isometric tetanic contractile performance of the gastrocnemius-plantaris-soleus (GPS) muscle group in situ in AK1^–/– mice and wild-type (WT) controls over a range of contraction frequencies (30–120 tetani/min). We found that AK1^–/– muscle exhibited a diminished inosine 5'-monophosphate formation rate (14% of WT) and an inordinate accumulation of ADP (1.5 mM) at the highest energy demands, compared with WT controls. AK-deficient muscle exhibited similar initial contractile performance (521 ± 9 and 521 ± 10 g tension in WT and AK1^–/– muscle, respectively), followed by a significant slowing of relaxation kinetics at the highest energy demands relative to WT controls. This is consistent with a depressed capacity to sequester calcium in the presence of high ADP. However, the overall pattern of fatigue in AK1^–/– mice was similar to WT control muscle. Our findings directly demonstrate the importance of AMP formation and subsequent deamination in limiting ADP accumulation. Whole muscle contractile performance was, however, remarkably tolerant of ADP accumulation markedly in excess of what normally occurs in skeletal muscle. AMP deaminase; tetanic contraction; muscle relaxation; calcium handling; cross-bridge cycling     

Metabolic adaptation of endothelial cells to substrate deprivation

Endothelial cells are known to be metabolicallyrather robust. To study the mechanisms involved, porcine aorticendothelial cells (PAEC), cultured on microcarrier beads, were perfusedwith glucose (10 mM) or with substrate-free medium. Substrate-free perfusion for 2 h induced an almost complete loss of nucleoside triphosphates (³¹P-NMR) anddecreased heat flux, a measure of total energy turnover, by >90% inparallel microcalorimetric measurements. Heat flux and nucleosidetriphosphates recovered after addition of glucose. Because proteinsynthesis is a major energy consumer in PAEC, the rate of proteinsynthesis was measured([¹⁴C]leucineincorporation). Reduction or blockade of energy supply resulted in apronounced reduction in the rate of protein synthesis (up to 80%reduction). Intracellular triglyceride stores were decreased by ~60%after 2 h of substrate-free perfusion. Under basal perfusionconditions, PAEC released ~30 pmol purine · mg protein¹ · min¹,i.e., 16% of the cellular ATP per hour, while ATP remained constant. Substrate deprivation increased the release of various purines andpyrimidines about threefold and also induced a twofold rise in purinede novo synthesis([¹⁴C]formate). Theseresults demonstrate that PAEC are capable of recovering from extendedperiods of substrate deprivation. They can do so by a massivedownregulation of their energy expenditure, particularly proteinsynthesis, while at the same time using endogenous triglycerides assubstrates and upregulating purine de novo synthesis to compensate forthe loss of purines.     

Oxidative ATP synthesis in skeletal muscle is controlled by substrate feedback

Data from ³¹P-nuclear magnetic resonance spectroscopy of human forearm flexor muscle were analyzed based on a previously developed model of mitochondrial oxidative phosphorylation (PLoS Comp Bio 1: e36, 2005) to test the hypothesis that substrate level (concentrations of ADP and inorganic phosphate) represents the primary signal governing the rate of mitochondrial ATP synthesis and maintaining the cellular ATP hydrolysis potential in skeletal muscle. Model-based predictions of cytoplasmic concentrations of phosphate metabolites (ATP, ADP, and P_i) matched data obtained from 20 healthy volunteers and indicated that as work rate is varied from rest to submaximal exercise commensurate increases in the rate of mitochondrial ATP synthesis are effected by changes in concentrations of available ADP and P_i. Additional data from patients with a defect of complex I of the respiratory chain and a patient with a deficiency in the mitochondrial adenine nucleotide translocase were also predicted the by the model by making the appropriate adjustments to the activities of the affected proteins associates with the defects, providing both further validation of the biophysical model of the control of oxidative phosphorylation and insight into the impact of these diseases on the ability of the cell to maintain its energetic state. computational model; mitochondria; cellular energetics; oxidative phosphorylation; ³¹P-NMR spectroscopy     

Cardiac contractile function, oxygen consumption rate and cytosolic phosphates during inhibition of electron flux by amytal--a 31P-NMR study

In order to investigate the potential role of cytosolic phosphates ([ATP], [ADP] and [Pi]) in the integration of mitochondrial respiration and mechanical function in the perfused heart, inhibition of the substrate end of the respiratory chain by amytal has been employed. A stepwise increase in amytal concentration (from 0.2 to 1.2 mM) resulted in the progressive abolition of the cardiac oxygen consumption, rate (VO2) in hearts oxidizing pyruvate (5 mM). The inhibition curve for VO2 was S-shaped, with K0.5 = 1.1 mM, and independent of the initial VO2 values varied by coronary flow and isoproterenol (Iso) addition. ADP-stimulated respiration of isolated mitochondria (malate + pyruvate) was twice as sensitive to amytal inhibition, whereas state 2 respiration (before ADP addition) had the same sensitivity as cardiac VO2. Decrease in VO2 was followed by a decline in phosphocreatine (PCr) content and augmentation of Pi at nearly constant ATP level and intracellular pH as assessed by the 31P-NMR method. These changes were associated with an elevation of cytosolic free [ADP] and a reduction of the [ATP]/[ADP] ratio and ATP affinity calculated from creatine kinase equilibrium. Concomitantly, pressure-rate product (PRP), maximal rates of contraction and relaxation fell down and the end diastolic pressure (EDP) rose at all initial loads. Amytal-inhibited hearts retained the capability to respond to Iso stimulation (0.1 microM, about 50% enhancement of PRP) even at 1 mM amytal, but their response to elevation of coronary flow was greatly diminished. Alterations in the PRP value induced by the inhibitor at a fixed coronary flow correlated negatively with cytosolic [ADP] and [Pi], and positively with [ATP]/[ADP] and A(ATP). In contrast, EDP correlated with all these parameters in the opposite manner. However, when PRP was varied by coronary flow in the absence of the inhibitor or at its fixed concentrations, such correlations were absent. These data imply that cytosolic phosphates can serve as a feedback between energy production and utilization when the control point(s) is (are) at the mitochondria. In contrast, other regulatory mechanisms should be involved when control is distributed among different steps located both in energy producing and utilizing systems.     

Force generation,but not myosin ATPase activity,declines with age in rat muscle fibers

We tested the hypothesis thatage-associated decline in muscle function is related to a change inmyosin ATPase activity. Single, glycerinated semimembranosus fibersfrom young (8-12 mo) and aged (32-37 mo) Fischer 344 × Brown Norway male rats were analyzed simultaneously for force andmyosin ATPase activity over a range of Ca²⁺ concentrations.Maximal force generation was ~20% lower in fibers from aged animals(P = 0.02), but myosin ATPase activity was not different between fibers from young and aged rats: 686 ± 46 (n = 30) and 697 ± 46 µM/s (n = 33) (P = 0.89). The apparent rate constant for thedissociation of strong-binding myosin from actin was calculated to be~30% greater in fibers from aged animals (P = 0.03),indicating that the lower force produced by fibers from aged animals isdue to a greater flux of myosin heads from the strong-binding state tothe weak-binding state during contraction. This is in agreement withour previous electron paramagnetic resonance experiments that showed areduced fraction of myosin heads in the strong-binding state during amaximal isometric contraction in fibers from older rats.

     

Coupling of "high-energy" phosphate bonds to energy transductions.

Recent results suggest consideration of a new concept for oxidative phosphorylation in which a prime function of energy is to bring about release of ATP formed at the catalytic site by reversal of hydrolysis. Data with submitochondrial particles include properties of an uncoupler insensitive Pi=HOH exchange, a rapid reversible formation of bound ATP in presence of uncouplers, and predictable patterns of 32-Pi incorporation into ATP in rapid mixing experiments. ADP is confirmed as the primary Pi acceptor in mitochondrial ATP synthesis, but with chloroplasts ADP is also rapidly labeled. Other findings with pyrophosphatase and with transport ATPase harmonize with the new concept. Measurements of the reversal of ATP cleavage and binding by myosin suggest that oxygen exchanges result from reversible cleavage of ATP to ADP and Pi at the catalytic site and that the principal free energy change in ATP cleavage occurs in ATP binding. Reversal of conformational changes accompanying ATP binding and cleavage is proposed to drive the actin filament in contraction. Thus energy transductions linked to ATP in both mitochondria and muscle may occur primarily through protein conformational change.     

Theoretical modelling of some spatial and temporal aspects of the mitochondrion/creatine kinase/ myofibril system in muscle

After discussing approaches to the modelling of mitochondrial regulation in muscle, we describe a model that takes account, in a simplified way, of some aspects of the metabolic and physical structure of the energy production/usage system. In this model, high-energy phosphates (ATP and phosphocreatine) and low energy metabolites (ADP and creatine) diffuse between the mitochondrion and the myofibrillar ATPase, and can be exchanged at any point by creatine kinase. Creatine kinase is not assumed to be at equilibrium, so explicit account can be taken of substantial changes in its activity of the sort that can now be achieved by transgenic technology in vivo. The ATPase rate is the input function. Oxidative ATP synthesis is controlled by juxtamitochondrial ADP concentration. To allow for possible functional coupling between the components of creatine kinase associated with the mitochondrial adenine nucleotide translocase and the myofibrillar ATPase, we define parameters and that set the fraction of the total flux carried by ATP rather than phosphocreatine out of the mitochondrial unit and into the ATPase unit, respectively. This simplification is justified by a detailed analysis of the interplay between the mitochondrial outer membrane porin proteins, mitochondrial creatine kinase and the adenine nucleotide translocase. As both processes of possible coupling are incorporated into the model as quantitative parameters, their effect on the energetics of the whole cell model can be explicitly assessed. The main findings are as follows: (1) At high creatine kinase activity, the hyperbolic relationship of oxidative ATP synthesis rate to spatially averaged ADP concentration at steady state implies also a near-linear relationship to creatine concentration, and a sigmoid relation to free energy of ATP hydrolysis. At high creatine kinase activity, the degree of functional coupling at either the mitochondrial or ATPase end has little effect on these relationships. However, lowering the creatine kinase activity raises the mean steady state ADP and creatine concentrations, and this is exaggerated when or is near unity (i.e. little coupling). (2) At high creatine kinase activity, the fraction of flow at steady state carried in the middle of the model by ATP is small, unaffected by the degree of functional coupling, but increases with ADP concentration and rate of ATP turnover. Lowering the creatine kinase activity raises this fraction, and this is exaggerated when or is near unity. (3) Both creatine and ADP concentrations show small gradients decreasing towards the mitochondrion (in the direction of their net flux), while ATP and phosphocreatine concentration show small gradients decreasing towards the myosin ATPase. Unless = 0 (i.e. complete coupling), there is a gradient of net creatine kinase flux that results from the need to transform some of the adenine nucleotide flux at the ends of the model into creatine flux in the middle; the overall net flux is small, but only zero if = . A reduction in cytosolic creatine kinase activity decreases ADP concentration at the mitochondrial end and increases it at the ATPase end. (4) During work-jump transitions, spatial average responses exhibit exponential kinetics similar to those of models of mitochondrial control that assume equilibrium conditions for creatine kinase. (5) In response to a step increase in ATPase activity, concentration changes start at the ATPase end and propagate towards the mitochondrion, damped in time and space. This simplified model embodies many important features of muscle in vivo, and accommodates a range of current theories as special cases. We end by discussing its relationship to other approaches to mitochondrial regulation in muscle, and some possible extensions of the model.     

Oxidative phosphorylation K0.5ADP in vitro depends on substrate oxidative capacity: Insights from a luciferase-based assay to evaluate ADP kinetic parameters

The K_0.5ADP of oxidative phosphorylation (OxPhos) identifies the cytosolic ADP concentration which elicits one-half the maximum OxPhos rate. This kinetic parameter is commonly measured to assess mitochondrial metabolic control sensitivity. Here we describe a luciferase-based assay to evaluate the ADP kinetic parameters of mitochondrial ATP production from OxPhos, adenylate kinase (AK), and creatine kinase (CK). The high sensitivity, reproducibility, and throughput of the microplate-based assay enabled a comprehensive kinetic assessment of all three pathways in mitochondria isolated from mouse liver, kidney, heart, and skeletal muscle. Carboxyatractyloside titrations were also performed with the assay to estimate the flux control strength of the adenine nucleotide translocase (ANT) over OxPhos in human skeletal muscle mitochondria. ANT flux control coefficients were 0.91 ± 0.07, 0.83 ± 0.06, and 0.51 ± 0.07 at ADP concentrations of 6.25, 12.5, and 25 μM, respectively, an [ADP] range which spanned the K_0.5ADP. The oxidative capacity of substrate combinations added to drive OxPhos was found to dramatically influence ADP kinetics in mitochondria from several tissues. In mouse skeletal muscle ten different substrate combinations elicited a 7-fold range of OxPhos V_max, which correlated positively (R² = 0.963) with K_0.5ADP values ranging from 2.3 ± 0.2 μM to 11.9 ± 0.6 μM. We propose that substrate-enhanced capacity to generate the protonmotive force increases the OxPhos K_0.5ADP because flux control at ANT increases, thus K_0.5ADP rises toward the dissociation constant, K_dADP, of ADP-ANT binding. The findings are discussed in the context of top-down metabolic control analysis.     

Tonic contractions allow metabolic recuperation of the adductor muscle during escape responses of giant scallop Placopecten magellanicus

To escape from starfish predators, giant scallops, Placopecten magellanicus, swim using series of strong phasic contractions interrupted by tonic contractions. To investigate whether these tonic contractions allow metabolic recuperation of the adductor muscle, we sampled scallops at rest (Control), after an initial series of phasic contractions (Phasic) and after 1 min of tonic contraction following their initial phasic contractions (Phasic + Tonic) and compared muscle levels of phosphoarginine, adenylate nucleotides (ATP, ADP and AMP) and adenylate energy charge (AEC). Scallops in the two active groups did not differ in the numbers of phasic contractions or the mean phasic force production. Phosphoarginine concentrations in the adductor muscle decreased with phasic activity and remained low after 1 min of tonic contraction. ATP and ADP and total adenylate levels did not differ between the three groups, but AMP levels were higher in the scallops sampled after phasic contractions than in control scallops. The AEC was reduced by phasic contractions but returned to control levels after 1 min of tonic contraction. A significant negative correlation between AEC and the number of claps in the Phasic group disappeared in the Phasic + Tonic group. Thus, tonic contractions following phasic contractions allow partial metabolic recovery of the adductor muscle by returning AEC to control levels. However, phosphoarginine levels did not recover during tonic contractions, and a negative correlation between the number of claps and phosphoarginine levels remained in the Phasic + Tonic group. By interspersing tonic contractions between series of phasic contractions, scallops improved muscle energetic status, which should help maintain phasic force production during the remainder of the escape response.     

Locust flight metabolism studied in vivo by 31P NMR spectroscopy

Flight metabolism of locusts has been extensively studied, but biochemical and physiological methods have led to conflicting results. For this reason the non-invasive and non-destructive method of ³¹P NMR spectroscopy was used to study migratory locusts, Locusta migratoria, at rest and during flight.