Free [ADP] and Aerobic Muscle Work Follow at Least Second Order Kinetics in Rat Gastrocnemius in Vivo

doi:10.1074/jbc.275.9.6129

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Free [ADP] and Aerobic Muscle Work Follow at Least Second Order Kinetics in Rat Gastrocnemius in Vivo^*

Julie H. Cieslar and Geoffrey P. Dobson

From the Department of Physiology and Pharmacology, Schools of Biomolecular and Molecular Sciences, James Cook University, Townsville, Queensland 4811, Australia

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The relationship between free cytosolic [ADP] (and [P_i]) and steady-state aerobic muscle work in rat gastrocnemius musclein vivo using ³¹P NMR was investigated. Anesthetized rats were ventilated andplaced in a custom-built cradle fitted with a force transducerthat could be placed into a 7-tesla NMR magnet. Muscle work wasinduced by supramaximal sciatic nerve stimulation that activatedall fibers. Muscles were stimulated at 0.1, 0.2, 0.3, 0.4, 0.5,0.8, 1.0, and 2.0 Hz until twitch force, phosphocreatine, andP_i were unchanged between two consecutive spectra acquired in4-min blocks (8-12 min). Parallel bench experiments were performedto measure total tissue glycogen, lactate, total creatine, andpyruvate in freeze-clamped muscles after 10 min of stimulationat each frequency. Up to 0.5 Hz, there was no significant changein muscle glycogen, lactate, and the lactate/pyruvate ratios between8-12 min. At 0.8 Hz, there was a 17% fall in glycogen and a 65%rise in the muscle lactate with a concomitant fall in pH. Abovethis frequency, glycogen fell rapidly, lactate continued to rise,and ATP and pH declined. On the basis of these force and metabolicmeasurements, we estimated the maximal mitochondrial capacity(V_max) to be 0.8 Hz. Free [ADP] was then calculated at each submaximalworkload from measuring all the reactants of the creatine kinaseequilibrium after adjusting the K'_CK to the muscle temp (30 °C),pH, and pMg. We show that ADP (and P_i) and tension-time integralfollow a Hill relationship with at least a second order function.The K_0.5 values for free [ADP] and [P_i] were 48 µM and 9 mM, respectively.Our data did not fit any form of the Michaelis-Menten equation.We therefore conclude that free cytosolic [ADP] and [P_i] couldpotentially control steady-state oxidative phosphorylation inskeletal muscle in vivo.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The control of mitochondrial respiration by free cytosolic [ADP] and [P_i] remains highly controversial. The balanced reactionfor oxidative phosphorylation is summarized in Reaction 1.

<UP>NADH2−</UP>+<UP>4H+</UP>+<UP>3ADP3−</UP>+<UP>3HPO</UP><UP>2−</UP><UP>4</UP>+<UP>0.5O2</UP>→<UP>NAD1−</UP> (Reaction 1)

+<UP>3ATP4−</UP>+<UP>4H2O</UP>

In 1952, Lardy and Wellman were among the first to propose that the rate of cellular respiration might be controlled by theproducts of ATP hydrolysis, namely free [ADP] or [P_i] (1, 2).A few years later, Chance and Williams obtained apparent K_mvalues of respiration of 20 µM and 1.0 mM for free [ADP] and [P_i],respectively, in rat liver mitochondria (3). Chance suggesteda greater role for free [ADP] than [P_i] in respiratory controlsince it would afford a greater sensitivity or gain to the systemfor a given increase in steady-state work (4-6). In 1986, Katzand colleagues challenged the importance of free [ADP] on thebasis of an invariant NMR determined [PCr]/[ATP] ratio in thein situ canine heart over a 3-5-fold increase in rate-pressureproduct, or oxygen consumption (42-46). Evidence against free [ADP]control was supported on theoretical grounds by the fact thata Michaelis-Menten function is inadequate to explain the observedhigh flux rates in vivo (7).

In an attempt to clarify what has become a very complex subject, Chance and colleagues proposed a modified Michaelis-Mentenequation showing how control of cell respiration in vivo may beshared among the reactants in Reaction 1 (5). Chance furtherpostulated that the relative contribution of each controller wasdependent on the energetic state of the tissue (5). Notwithstandingthe mounting evidence against free [ADP], its importance in thecontrol of mitochondrial respiration has recently resurfaced withthe ³¹P NMR finding that the apparent kinetic order of [ADP] transductionis at least second order in intact human forearm (8). Thatfree [ADP] and submaximal muscle work does not obey Michaelis-Mentenkinetics has sparked a great deal of controversy (8, 33).The aim of our study was to determine the relationship betweenfree cytosolic [ADP] (and P_i) and tension-time integral (TTI)¹ in the rat gastrocnemius muscle in vivo. We show that free [ADP](and P_i) and TTI followed an apparent second order function andthat our data do not fit a Michaelis-Mentenrelationship.

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Animal Preparation-- Male Sprague-Dawley rats (350-400 g body weight) were obtained from Animal Resources Center, Canningvale, Western Australia,Australia. Animals were housed in the James Cook University smallanimal facility with free access to food and water. Animals wereanesthetized with an intraperitoneal injection of pentobarbitalsodium (60 mg/kg), tracheotomized, and ventilated at the rateof 75 breaths/min with a tidal volume of ~25 ml to maintain arterialpH (7.4 ± 0.5), pCO₂ (40 ± 5 mmHg), and pO₂ (90 ± 10 mmHg) (S.E.).Blood pH and gas tensions were analyzed using a Ciba-Corning 865series analyzer. The right carotid artery was cannulated withheparinized (100 units/ml) polyethylene tubing connected to aStatham P23 XL pressure transducer coupled to a MacLab for continuousmeasurement of arterial blood pressure. Anesthesia was maintainedby delivering 1% isofluorane in compressed air via artificialventilation at a rate of 0.5 liter/min. The entire surgical procedurewas performed on a thermostatically regulated heating pad (37°C).

Muscle Stimulation and Force Measurements-- The right hindlimb was shaved, and two brass pins were driven through the calcaneum and tibial head with an electric drill.The animal was transferred to a purpose-built cradle pre-fittedwith a 37 °C water-heated pad, and the limb was immobilized byclamping the pins onto a mechanical ground in the cradle. Formuscle stimulation, bipolar electrodes were attached to the rightsciatic nerve exposed by blunt dissection of overlying tissue.The nerve was then severed distal to the electrodes. The tendonof the gastrocnemius muscle was freed from the leg and attachedto a calibrated ultra precision mini load cell (Transducer Techniques,MDB10) with non-compliant 2.0 silk string. Isometric force development(newtons) was continuously displayed on a MacLab. The muscle wascarefully denuded of overlying tissue avoiding arteries and veins,and covered with plastic film to prevent the exposed tissue fromdrying out. Muscles under these conditions maintained a constantinternal temperature of 30 ± 1 °C throughout the experiment (n= 5). Muscle temperature was measured in separate experimentsusing a YSI 500 series micro-implantable thermistorprobe.

The muscle was adjusted to the length at which maximum twitch force was developed during a supramaximal contraction in responseto a square-wave pulse (0.1 ms, 5-15 V). The TTI, defined as thesum of the area under the twitches over the acquisition periodin the NMR spectra, was used as an index of muscle work with unitsof Newtons second (Ns). The twitch tension-time integral was foundto be a linear function of stimulation frequency during steady-stateaerobic work (data not shown). The equation to the line was TTI= 46.98 stimulation frequency +2.26 R² = 0.99, giving a TTI at 0 Hz of 1.37 Ns. Each animal served asits own control precluding the need to normalize the data by musclevolume. The whole apparatus was introduced into the bore of anOxford Instruments horizontal NMRmagnet.

Nuclear Magnetic Resonance-- ³¹P NMR experiments were performed at 121.47 MHz in the 110-mm bore of an Oxford 7.05-tesla superconducting magnet. A three-turnsurface coil (14 mm outer diameter) was placed at the center ofthe gastrocnemius muscle and served as transmitter and receiver.A small latex balloon filled with a solution of 10 mM phenylphosphonicacid in saline was placed above the coil in the same geometricalarrangement as the muscle below and served as an external standard.Magnetic field homogeneity was optimized by observing the off-resonanceproton signal of muscle water. The surface coil was tuned andmatched to resonate at 121.47 MHz. All NMR experiments were performedusing a radio frequency pulse of 10-µs duration, which was transmittedat a near 90^o flip angle by the surface coil. ³¹P NMR spectra were collected as 9600 data points using a sweep-widthof 6000 Hz. The free induction decays were acquired over 0.8 swith an interpulse delay time of 1 s. The free induction decayswere multiplied by a line broadening factor equivalent to 20 Hzto improve signal-to-noise ratio. Resultant line widths for thein vivo muscle experiments were typically 40-60 Hz. The radiofrequency pulse was not synchronized with a nerve stimulation.The advantage of ³¹P NMR is that the method is noninvasive and provides continuousmeasurements of phosphorus metabolites in real time in one animal,including direct estimates of pH and free [Mg²⁺]. The limitation of the NMR technique, as with conventional metabolicanalysis, is that the measurements cannot discriminate the differentcontributions of fibertypes.

Experimental Protocol and Definition of Steady State-- Fully relaxed spectra with a relaxation delay of 20 s was collected for 30 min at the beginning of each experiment to determinethe saturation correction factors for each of the phosphorus-containingcompounds (see "Quantitation of NMR Spectra"). Control spectrawere obtained for 7 min (256 transients) before the muscle wasstimulated to contract isometrically at frequencies of 0.1, 0.2,0.3, 0.4, and 0.5 Hz and either 0.8 Hz (n = 4), 1 Hz (n = 7),or 2 Hz (n = 7). For each stimulation frequency in the three groups,spectra were acquired in 4-min blocks each with 128 transients.Muscles were allowed to recover for 20 min between each stimulationfrequency to restore the contraction force and PCr and P_i to prestimulationlevels. The total time for each of the three protocols was about3 h. The force and NMR data were then analyzed to establish asteady state in which twitch tension and PCr and P_i were constantin two consecutive spectra (9, 10). We showed that steadystate was reached between 8 and 12 min of stimulation up to 0.8Hz (see "Results").

Parallel experiments were carried out on the laboratory bench and muscles freeze-clamped following 10 min of stimulation ateach of the frequencies using aluminum tongs pre-cooled in liquidnitrogen. The freeze-clamped muscles were ground to a fine powderunder liquid nitrogen, the connective tissue was removed, andthe powder kept at $-$ 80 °C until analysis of lactate, glycogen,pyruvate, PCr, and Cr. Conversion of total tissue contents (micromoles/gwet weight) into intracellular concentrations (micromoles/ml)were carried out using our published extracellular space valuesand total tissue water contents reported for rat gastrocnemiusin vivo (11). In the present study we also measured the extracellularspaces at 1 and 2 Hz and found them to be 18% and 17%, respectively.The values were not significantly different from the 16% we reportin vivo (11).

Biochemical Assays-- All chemicals used in the metabolic assays were purchased from either Sigma or Roche Molecular Biochemicals and were of thehighest grade. Frozen tissue (~100 mg) was homogenized in equalvolumes of ice-cold 0.1 M HCl in methanol and 3.6% perchloricacid (12) using glass beads in a high speed Biospec mini-BeadBeater.The homogenate was centrifuged (9,000 × g; 2 min) and a volumeof acid-extract removed and mixed with an aliquot of KHCO₃ (0.3and 0.2 M stocks) to neutralize (pH 6-7). The supernatant wasimmediately measured either spectrophotometrically or fluorometricallyfor pyruvate, lactate, PCr, and creatine according to the methodsof Passoneau and Lowry (12). Total tissue glycogen was measuredseparately according to the method of Passoneau (13). Briefly,1 ml of 0.5 M NaOH was added to frozen tissue (~50 mg) and heatedin boiling water for 20-30 min to remove tissue free glucose.The suspension was made acidic with a known volume of 12 N HCl(pH < 3.0). An aliquot of acid extract (~50 µl) was removed andadded to 950 µl of 200 mM acetate buffer (pH 4.7) containing amylo- $alpha$ -1,4- $alpha$ -1,6-glucosidaseto digest tissue glycogen. Following 2 h of incubation, the acidextract was fluorometrically assayed for glucose (13).

Quantitation of NMR Spectra-- ³¹P NMR spectral intensities for the phosphorus-containing compounds were determined by computer integration using the VNMRXsoftware. Saturation correction factors were determined by takingthe ratio of the area under a given peak with a 20-s relaxationdelay to the area of the spectra with a 1-s relaxation delay.The mean correction factors for the 10 mM phenylphosphonic acidexternal standard, P_i, PCr, and $beta$ -ATP were 2.20 ± 0.05, 1.80 ±0.06, 1.56 ± 0.0, and 1.22 ± 0.02 (± S.E., n = 18), respectively.Intracellular concentrations of the $beta$ -ATP, PCr, and P_i were calculatedby equating the spectral intensities of the saturation-correctedphosphorus metabolites to the spectral intensity of the saturation-correctedexternal standard (10 mM).

[<UP>Pi</UP>]=<FR><NU>1.80×<UP>area</UP><UP>Pi</UP></NU><DE><UP>2.20</UP>×<UP>areaStd</UP></DE></FR>×<UP>10 m<SC>m</SC></UP> (Eq. 1)

[<UP>PCr</UP>]=<FR><NU>1.56×<UP>areaPCr</UP></NU><DE><UP>2.20</UP>×<UP>areaStd</UP></DE></FR>×<UP>10 m<SC>m</SC></UP> (Eq. 2)

[<UP>ATP</UP>]=<FR><NU>1.22×<UP>AreaATP</UP></NU><DE><UP>2.20</UP>×<UP>AreaStd</UP></DE></FR>×<UP>10 m<SC>m</SC></UP> (Eq. 3)

Intracellular pH (pH_i) was calculated from the chemical shift ( $delta$ , ppm) of P_i relative to PCr in the ³¹P spectra using the NMR version of the Henderson-Hasselbalch equation(1).

<UP>pHi</UP>=6.75+<UP>log</UP><FENCE><FR><NU>&dgr;−3.25</NU><DE>5.69−&dgr;</DE></FR></FENCE> (Eq. 4)

Intracellular free Mg²⁺ concentration ([Mg²⁺]_i) was calculated from the observed chemical shift difference ( $delta$ ) in ppmbetween $beta$ -P and $alpha$ -P resonances of ATP in the ³¹P spectra using the modified form of the London equation (14),where $alpha$ = [H⁺]/K_H and $beta$ = $alpha$ (K_D/K_D').

[<UP>Mg2+</UP>]<UP>i</UP>=KD<FENCE><FR><NU>&dgr;&agr;&bgr;(1+&agr;)−(&dgr;1+&agr;&dgr;2)</NU><DE>&dgr;3+&bgr;&dgr;4−&dgr;&agr;&bgr;(1+&bgr;)</DE></FR></FENCE> (Eq. 5)

The parameters $delta$ ₁, $delta$ ₂, $delta$ ₃, and $delta$ ₄ were assigned published values of 10.600, 11.660, 8.165, and 8.52 ppm, respectively; K_Dwas 9.0 × 10⁵ M; K_H was 3.4 × 10⁷ M; and K_D' was 7.2 × 10⁴ M (14).

The free cytosolic [ADP] was calculated from the creatine kinase equilibrium (EC 2.7.3.2) using the measured componentsin the ³¹P NMR spectra.

[<UP>ADP</UP>]=<FR><NU>[<UP>ATP</UP>][<UP>Cr</UP>]</NU><DE>[<UP>PCr</UP>]K′<UP>CK</UP></DE></FR> (Eq. 6)

The Cr concentration was calculated by subtracting the NMR PCr value from the total Cr measured enzymatically where the totalCr = PCr_enz + Cr_enz. The creatine kinase equilibrium constant(K'_CK) was adjusted to muscle free [Mg²⁺]_i and pH_i during graded levels of steady-state work accordingto the method of Golding et al. (15). In addition, K'_CK wasadjusted to the temperature of the muscle (30 °C) using the methodof Teague et al. (16).

Statistical Analysis-- All values shown are means ± S.E. Unless otherwise indicated, Student's t test was applied for statistical comparisons amongbasal and stimulated values. A probability of p < 0.05 indicateda significant difference betweenvalues.

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Establishment of Steady-state and Apparent Aerobic V_max of Muscle-- Steady-state was defined in terms of relatively constant TTI and concentrations of PCr and P_i measured at the different stimulationfrequencies in consecutive spectra acquired in 4-min blocks (Fig.1). Mean values for TTI were similarly calculated in three blocksof 4 min to coincide with the NMR acquisition period. Fig. 1ashows no significant differences in TTI for the stimulation frequenciesbetween 0.1 and 0.8 Hz over the 12-min time period. Significantchanges were observed at 1 and 2 Hz. At all stimulation frequencies,PCr fell significantly during the first and second periods ofacquisition (0-8 min) (Fig. 1b). With the exception of 1 and 2Hz, metabolic steady state was reached during the period between8 and 12 min. A similar profile was found with the increase inmuscle P_i concentration at the different stimulation frequencies(Fig. 1c).

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Fig. 1. Twitch tension-time integral (a), phosphocreatine (b), and P_i (c) as a function of time for the stimulation frequencies 0.1 ( $black-square$ ), 0.2 ( $triangle$ ), 0.3 (), 0.4 ( $diamond$ ), 0.5 ( $black-triangle$ ), 0.8 ( $open circle$ ), 1 ( $black-diamond$ ), and 2 Hz (). The points on the PCr and P_i curves represent the time-averaged mean of the NMR spectra acquired in 4-min blocks. TTI values represent the sum of the area under the twitch over the acquisition period. The vertical bars represent the standard errors from the mean. The force and metabolic data from the three groups were pooled for the frequencies between 0.1 and 0.5 Hz, giving a total n value of 18.

In parallel bench experiments, muscles were freeze-clamped following 10 min of stimulation and glycogen, lactate, and pyruvatewere measured enzymatically (Table I). Up to 0.5 Hz, there wasno significant difference in muscle glycogen, lactate, and pyruvatecompared with controls. At 0.8 Hz, a significant rise in lactateand pyruvate (p < 0.05) was observed with a concomitant fall inglycogen. It was not until 1 and 2 Hz that glycogen fell as lowas 30% of control, lactate increased up to 5-fold, and lactate/pyruvateratio increased 3-fold (Table I). NMR determined cytosolic pH,also reported in Table I, was not significantly different fromcontrols up to 0.5 Hz but significantly decreased from 7.203 to7.050 at 0.8 Hz. On the basis of these changes in TTI and accompanyingmetabolic data, we estimated that the maximal mitochondrial capacityin rat gastrocnemius in situ under our conditions was around 0.8Hz.

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Table I
Total tissue concentrations of lactate, glycogen, and pyruvate determined enzymatically in freeze-clamped rat gastrocnemius muscle in vivo following 10-min stimulation
All data are expressed in micromoles/g wet weight tissue. Intracellular pH was determined in rat gastrocnemius muscle in vivo during 8-12 min of stimulation using ³¹P NMR spectroscopy.

Values are mean ± S.E.

Changes in the PCr, ATP, Cr, Free [Mg²⁺], and Calculation of Free [ADP] from the Creatine Kinase Equilibrium-- NMR determined PCr, ATP, P_i, and free Mg²⁺ in rat gastrocnemius muscle in vivo during the 8-12 min of stimulation are reportedin Table II. During submaximal steady-state work transitions,PCr fell in significantly different increments (p < 0.05) at eachstimulation frequency up to 0.8 Hz (Table II). The work-inducedfall in PCr was accompanied by a stoichiometric rise in intracellularP_i concentration (Table II). It is noteworthy that ATP began todecrease at 2Hz when PCr was about 30% of the control value (TableII). ATP was not considered part of our aerobic steady-state criteriabecause it remained constant up to and including 1.0 Hz, presumablythrough PCr hydrolysis and the activation of anaerobic glycogenolysis(Tables I and II). Free [Mg²⁺] was not significantly different up to 1 Hz but increased by50% at 2 Hz.

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Table II
Intracellular concentrations of PCr, ATP, Mg, ADP, and P_i during 8-12 min of stimulation in rat gastrocnemius muscle in vivo using ³¹P NMR spectroscopy
Total creatine concentration ([TCr]) was determined enzymatically in freeze-clamped extracts of muscle following 10 mins of stimulation. All concentrations with the exception of free cytosolic [ADP] are expressed in mM.

Values are mean ± S.E.

Free cytosolic [ADP] was 17 µM in the gastrocnemius prior to stimulation and increased with increasing stimulation frequencyand tension-time integral (Fig. 2a). The equation to the lineup to 0.8 Hz was TTI = 46.984 ([ADP]) + 2.2562 with R² = 0.9945. When free [ADP] was plotted against TTI using the Hillrelationship, given a V_max of 39 Ns at 0.8 Hz, a Hill coefficient(n_H) of 2.4 was found (Fig. 2b). The equation to the line waslog(TTI/V_max $-$ TTI) = 2.38 (log ADP) $-$ 4.00 with R² = 0.99. The apparent K_0.5 of ADP for submaximal steady-statestimulation was 48 µM. A similar analysis was performed with increasesin cytosolic [P_i]. A Hill coefficient of 2.1 was obtained. Theequation to the line was log(TTI/V_max $-$ TTI) = 2.14(log[P_i]) $-$ 2.08 with R² = 0.96 (graph not shown). The apparent K_0.5 value of free [P_i]for submaximal steady-state work was 9.4 mM. The data for freecytosolic [ADP] (and free [P_i]) and TTI did not fit any form ofthe Michaelis-Menten function, i.e. the Lineweaver-Burke plotshowed no tendency to intersect the y axis (Fig. 2c). Similarly,the Eadie-Hofstee and Hanes Plot followed no sensible form, leadingto the calculation of a kinetic V_max or apparent K_m (plotsnot shown).

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Fig. 2. TTI as a function of free [ADP] for our aerobic steady-state system in rat gastrocnemius muscle in vivo (a), expressed as a Hill plot having a linear regression equation of y = 2.3789x $-$ 4.0087 with R² = 0.9943 (b) and a Lineweaver-Burke plot (c). From our metabolic data, the mitochondrial capacity for our steady-state system (V_max) was 0.8 Hz.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

There has been much controversy in recent years about whether the relationship between oxygen consumption and free [ADP] followsa first order Michaelis-Menten function or higher order sigmoidalfunction. Our study shows that ADP and TTI follows a Hill relationshipwith at least a second order function. Before we discuss thesefindings in relation to other studies, it is important to firstdiscuss the assumptions of our model that form the basis of ourresults. The assumptions are: 1) our study applies to submaximalsteady-state levels of aerobic activity, 2) the maximal mitochondrialcapacity for aerobic work in rat gastrocnemius was in the vicinityof 0.8 Hz, and 3) the tension-time index provides a reliable estimateof oxygen consumption during steady-state work. Our first twoassumptions were supported on the basis of our force and metabolicmeasurements in the magnet and on the bench. Fig. 1 clearly showsthat no change occurred in twitch tension, PCr, and P_i betweenthe second and third spectra up to 0.8 Hz. Moreover, there wasno significant change in muscle lactate, glycogen, and pH indicatinga physiological and metabolic steady state (Tables I and II).Our study therefore differs from most in this area by experimentallydetermining the apparent maximum aerobic mitochondrial capacity(V_max) in situ not from fitting the data to a specific mathematicalrelation (8, 17-19). The third assumption, that tension-timeindex provides a reliable estimate of oxygen consumption, hasbeen shown by many studies in the past for skeletal muscle (9,10, 20-24) and heart (25, 26). For the rat hindlimb in vivo,Brindle et al. also have shown a linear function between tension-timeintegral and ATP turnover (23). Kushmerick and Paul also showeda linear relation between recovery oxygen consumption and TTIin frog sartorius (27).

Our Hill coefficient (n_H) for [ADP] and TTI of 2.4 for rat gastrocnemius in situ is consistent with the published work of2.2 for human forearm muscle (8, 19). Prior to the work ofJeneson et al. in 1996 (8), the relationship between steady-statework and free [ADP] had been assumed in vivo to follow a Michaelis-Mentenfunction in rat leg muscle (28), cat perfused biceps (29),and human arm muscle (30). Some of the problems associated withthese older kinetic analysis have been discussed by Kemp (31)and more recently by Jeneson et al. (8, 32) with a replyfrom Portman et al. (33). The present study supports the ideathat the relationship between oxygen consumption and free [ADP]follows at least a second order sigmoidalfunction.

In addition, the apparent K_0.5 of [ADP] of 48 µM for tension time index (and oxygen consumption) we report in the presentstudy is also consistent with some literature values. Again, thisis a very controversial area. In 1989, Brindle and co-workersreported an apparent K_m of at least 30 µM for rat hindlimbin situ under steady-state submaximal exercise (23). These datahave subsequently been recalculated to give an apparent K_mof about 50 µM (18, 34). Similarly, Thompson and colleaguesin 1995 studied phosphocreatine recovery in rat leg muscle invivo and reported an apparent K_m of ADP greater than30 µM. In ex vivo perfused cat biceps, Kushmerick and colleagues(29) calculated an apparent K_m for free [ADP] of 23µM, a value similar to 26 µM for rabbit gastrocnemius/soleus musclegroups in vivo (24). Better agreement is found with the workof Jeneson and co-workers (8), who calculated an apparent K_0.5of ADP of 44 µM in human forearm flexor muscle (8).

One possible concern that could be raised with our kinetic analysis is that the tension-time integral does not saturate withfree [ADP] in vivo (Fig. 2a). This is to be expected in an intactmuscle because of the recruitment of competing metabolic pathwaysand fuels to maintain ATP constant as the muscle approaches itsmaximal aerobic capacity. Indeed, in our study, ATP did not fallsignificantly until 2 Hz, which is far in excess of our estimateof aerobic V_max for rat gastrocnemius based on lactate, glycogen,and pH values (Tables I and II). Because our system does notsaturate in free [ADP] levels in situ, it does not therefore compromiseour kineticanalysis.

Significance of Our Findings to the Control of Respiration in Vivo-- A controller of mitochondrial steady-state oxygen consumption must fulfil a number of criteria. First, the pre-exercise steady-statelevel of the controller must be set at a concentration below oraround its K_0.5 for oxygen consumption. Second, the controllermust increase as oxygen consumption increases. Third, the controllermust directly or indirectly regulate a specific rate-limitingenzyme(s) along the pathway. ADP has been a potential candidatefor a role in regulating oxygen consumption for over 45 years(1, 3). Other potential kinetic and thermodynamic controllershave been ATP (35), the [ATP]/[ADP] ratio (36-38), [ATP]/[ADP][P_i] ratio (39, 40), the energy charge (41), free [Ca²⁺] linked [NADH]/[NAD] ratios (17, 43, 44), and the oxygenconcentration at cytochrome c (38, 40).

Our present study shows that the free cytosolic [ADP] fulfils these three criteria in rat gastrocnemius in vivo. However,on the basis of our data and others, it is premature to concludethat free [ADP] is the actual controller because we also showthat free cytosolic [P_i] fulfils the same criteria. During increasingsteady-state work, P_i increased 8-fold from 3 to 16 mM up to 0.8Hz (Figs. 1 and 2 and Table II). The apparent K_0.5 was calculatedto be 9 mM and followed at least a second order relationship withtension time index. Our apparent K_0.5 for [P_i] of 9 mM for ratgastrocnemius is lower than the 19 mM reported for rabbit gastrocnemius(24). In our study neither change in free ADP or P_i concentrationwith muscle work fit a Michaelis-Menten relationship. As Jenesonet al. (32) pointed out, the possibility also exists that theapparent overall kinetic order of the ADP-TTI relationship mayalso reflect [P_i] stimulation of respiration because in our modelP_i was found to lie within its apparent K_0.5 of 9.0 mM.

Another very interesting study relevant to our work is that of Arnold and Kadenbach (38), who in 1999 showed a sigmoidalrelationship (average Hill coefficient of 2.9) between [ADP] andthe activity of cytochrome c oxidase. From this relation, theysuggested the possibility of regulation of respiration by intramitochondrial[ADP] (38). These authors, however, did not dismiss a role for[ADP] in the regulation of NADH dehydrogenase and cytochrome creductase in the overall pacemaker of cell respiration (38).One difference between our study and theirs was Arnold and Kadenbachdetermined a matrix half-maximal ADP stimulation of cytochromec oxidase of 170 µM (38). This value is over 3 times the "cytosolic"apparent K_m of [ADP] we report for tension-time index(and presumably oxygen consumption). The highest cytosolic [ADP]we measured up to 0.8 Hz stimulation frequency was around 80 µM(Table II). Arnold and Kadenbach do, however, note that mitochondrialmembrane potential and the electrogenicity of the nature of theATP/ADP carrier would result in a lower matrix ATP/ADP ratio dueto higher [ADP], which they argue would be consistent with theirkinetic work. We therefore conclude on the basis of our data thatADP and P_i could potentially control incremental increases insteady-state work in skeletal muscle in vivo.

ACKNOWLEDGEMENTS

We thank Dr. Josephine Herman for assistance with kinetic analysis and Dr. Uwe Himmelreich for discussions on quantitationof NMR peak areas using an externalstandard.

	FOOTNOTES

^* This work was supported by Australian Research Council Large Grant AO9701053 (to G. P. D.).The costs of publication of thisarticle were defrayed in part by the payment of page charges.The article must therefore be hereby marked "advertisement" inaccordance with 18 U.S.C. Section 1734 solely to indicate thisfact.

To whom correspondence should be addressed. Tel.: 61-77-81-4343 (or 4097); Fax: 61-747-81-6279; E-mail: geoffrey.dobson@jcu.edu.au.

ABBREVIATIONS

The abbreviations used are: TTI, tension-time integral; PCr, phosphocreatine; Cr, creatine.

	REFERENCES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

1.	Lardy, H. A., and Wellman, H. Y. (1952) J. Biol. Chem. 195, 215-224[Free Full Text]
2.	Kalckar, H. M. (1969) Biological Phosphorylations: Development of Concepts , Prentice-Hall Inc., Englewood Cliffs, NJ
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