Departments of 1Biological Chemistry and 2Exercise Science, University of California, Davis; and 3GE Medical Systems, Fremont, California
Submitted 11 March 2004 ; accepted in final form 21 October 2004
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ABSTRACT |
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myoglobin; nuclear magnetic resonance; glycogen; oxygen; exercise
From the vantage point of the current kinetic models of respiratory control, ADP or a limiting substrate regulates respiration (7). The model predicts that the product of ATP hydrolysis stimulates respiration to meet enhanced energy needs. In vivo myocardial studies, however, have failed to detect direct O2 dependence on ADP (1, 23, 33). Although
O2 rises, the ADP level remains constant. In contrast, skeletal muscle shows an ADP-dependent
O2 (2). These experiments, however, relied on whole body
O2 or arteriovenous O2 difference measurements to extrapolate the pertinent intracellular
O2. Quite clearly, the presence of myoglobin (Mb) and the numerous mediating diffusion steps from the vasculature to the mitochondria raise questions about the accuracy of the extrapolated intracellular
O2 value, on which all quantitative analysis must critically depend. Without a definitive intracellular
O2 value, the dependence of
O2 on ADP remains in question. Nevertheless, the apparent difference in myocardial and skeletal muscle
O2 regulation suggests that ADP regulates
O2 differently in skeletal and myocardial muscle. Each skeletal muscle contraction cycle can certainly elicit a significant fluctuation in ADP (10). Some researchers, however, have downplayed any significant role for a metabolic regulation of
O2 and have pointed to experiments showing a tight match between O2 supply and
O2 demand in blood-perfused muscle (51).
1H-NMR studies have presented an approach to mapping the intracellular PO2 with the Mb signals in vivo (28, 34, 38, 50). These NMR studies have reported fully saturated oxymyoglobin (MbO2) in resting muscle, implying that the resting myocyte PO2 is well above Mb P50 of 2.93 mmHg [PO2 necessary to obtain 50% O2 saturation of Mb (P50) at 39°C] and that cytochrome oxidase is most likely saturated (6). Raising only the cellular PO2 to increase the cytochrome oxidase activity cannot directly enhance O2 during muscle contraction. In fact, human gastrocnemius muscle studies have shown a decrease, not an increase, in PO2 during exercise, in agreement with the cryosection analysis of canine gracilis muscle (17, 38). Although the fall in cellular PO2 increases the O2 gradient from the capillary to the cell, O2 delivery from the cytosol to the mitochondria must increase to accommodate the increasing
O2 demand. A switch from free O2 diffusion to Mb-facilitated diffusion could serve as the compensating mechanism to enhance O2 transport, except that tissues with inhibited Mb function or without Mb do not exhibit any apparent handicap in respiration (14, 16, 19).
Because MbO2 constitutes an O2 depot in the cell, the MbO2 signal, along with the Mb in vitro O2 binding constant, provides a means of determining the intracellular PO2. Moreover, its desaturation kinetics would reflect the intracellular O2, given that Mb can also deliver O2 from the sarcolemma to the mitochondria. If blood flow can deliver O2 to match precisely the
O2 need, then MbO2 should not desaturate. Any rise in the 1H-NMR proximal histidyl N
H signal intensity of deoxymyoglobin (deoxy-Mb), which increases as cellular O2 falls, indicates a mismatch between O2 delivery and demand. The Mb desaturation kinetics can then serve as an index of intracellular O2 utilization, or
O2 (32, 34). Such measurement of intracellular
O2 overcomes the limitation with indirect calorimetry, vascular O2 extraction, or NIRS techniques, which require key assumptions to extract the intracellular
O2.
Indeed, during muscle contraction, MbO2 desaturates rapidly to a steady state with a time constant () of
30 s. Although Mb deoxygenates to different steady-state levels as a function of workload, the kinetics time constant remains unchanged. Eadie-Hofstee kinetic analysis of the Mb-derived intracellular
O2 vs. ADP reveals no ADP-dependent regulation of intracellular
O2 at the onset of muscle contraction. After Mb desaturation has reached a steady-state level, however,
O2 continues to rise. In this second phase of respiration,
O2 does show a strong dependence on ADP, consistent with observations reported in the literature (2).
Intracellular O2 provides insight into the contribution of oxidative phosphorylation during a muscle contraction cycle. Given the reported value of 0.15 mM ATP per contraction in human gastrocnemius muscle, on the basis of intracellular
O2, oxidative phosphorylation provides 36% of the energy (4). The result stands in sharp contrast to the orthodox view of muscle bioenergetics, which ascribes insignificant oxidative ATP production to any contraction cycle. However, Chung et al. (10) have raised questions about the low ATP turnover per contraction cycle and have presented experimental evidence to show that in each contraction, muscle consumes 3 mM ATP within milliseconds. At 3 mM ATP per contraction, the intracellular
O2 can supply only
2% of the energy cost. The fractional contribution of
O2 to the overall energy demand, the large demand for ATP per contraction, and the need to sustain contraction for a prolonged period thus require the presence of a dynamic energy utilization-restoration cycle, such as the one proposed in the glycogen shunt theory (46). Indeed, using steady-state
O2 as an estimate of the total ATP cost leads to an estimate of the glycogen contribution. The nonoxidative contribution from glycogenolysis represents
31% of the energy demand during a muscle contraction.
The present study has established an approach to measurement of intracellular O2; has assessed the temporal interplay between metabolic demand, respiration, and hemodynamics; has identified an initial mismatch between O2 supply and demand; has provided evidence for ADP-dependent and ADP-independent
O2 in the context of current respiratory control models; has implicated a role for Mb in filling transient O2 needs; has quantitated the significant contribution of oxidative phosphorylation to the energy demand; and has implicated glycogenolysis in the dynamic energy restoration-use cycle lasting for only milliseconds.
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MATERIALS AND METHODS |
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Two sessions were required to complete this study. Session I was conducted in the Human Performance Laboratory and involved characterization of each participant's body composition, steady-state O2 at several intensities of plantar flexion exercise. A fiberglass cast (ScotchCast; 3M, Minneapolis, MN) was then formed from below the knee to the ankle. The cast was used to estimate the leg volume and as a means to calibrate the percent desaturation of the deoxy-Mb signal. Session II used an identical protocol and involved duplicate determination of metabolic phosphates using 31P-NMR and of deoxy-Mb using 1H-NMR during plantar flexion exercise (38, 50).
Plantar flexion ergometer. The ergometer consisted of a three-sided box of dimensions 25.4-cm width, 25.4-cm height, and 91.4-cm length, with a foot pedal on an axle at one end and a movable backplate at the other end. Latex rubber tubing (1.3-cm diameter, 34.3 cm/l) with a Hooke's constant of 31.12 N/cm length change was attached to the backplate and the axle of the foot pedal. Resistance to plantar flexion can be varied by the number of tubes used and/or by changing the stretch of tubing between the axle and backplate. The mechanical work of plantar flexion involved moving the pedal against a specified resistance across an arc of 3.8 cm. The pedal movement was controlled by stops for forward and reverse movements with plantar flexion and relaxation. In this study, power was incremented by varying the contraction from 4555 to 70 repetitions per minute (RPM) or between 0.751.17 Hz. The resistance and the plantar flexion arc were held constant.
Steady-state and peak O2 for plantar flexion exercise.
Indirect calorimetry first determined the energy expenditure. After resting for 10 min in a supine position, the participant breathed for 5 min through a mouthpiece and tubing connected to a Sensor Medics metabolic cart (model 2900; Sensor Medics, Anaheim, CA) for breath-by-breath measurement of resting
O2 and CO2 production (
CO2). Next, the participant performed a series of three to five exercise bouts at progressively higher intensity by varying the frequency from 45 to 70 RPM on the foot ergometer. The resistance remained constant. Each bout lasted 3 min and was followed by 6 min of rest. The calculated mean value during the last 30 s of each bout characterized the
O2,
CO2, and respiratory exchange ratio.
After a resting period of 1015 min, the individual's O2 peak was determined by holding the resistance constant and progressively increasing the contraction frequency each minute until the participant could no longer maintain the required cadence.
O2 and
CO2 were determined throughout the test as described above.
O2 was averaged over each 15-s interval. The highest
O2 was designated as the participant's
O2 peak.
1H-NMR and 31P-NMR experiments.
NMR measurements were performed on a 1-m bore diameter GE Sigma scanner (GE Medical Systems, Fremont, CA) at 1.5 T. The participant's calf muscle was centered on top of a 5-inch-diameter surface coil and was strapped down with Velcro. 1H-NMR (63.86 MHz) signal acquisition used a body coil transmit-surface coil receive configuration. Magnetic field shimming used a three-point Dixon method to improve the field homogeneity, yielding a water line width of 40 Hz (45).
A selective excitation pulse sequence was optimized to excite the deoxy-Mb and deoxy-Hb His-F8 proximal histidyl NH signals
4.6 kHz from the water resonance (50). Numerical simulation and spectroscopic experiments verified that the experimental pulse length of 800 µs had a full width at half-maximum excitation of 2 kHz. At an offset of 800 Hz or 13 parts per million (ppm) from the excitation maximum, the pulse power dropped by 25%. For the steady-state measurements, the averaging of 200 free induction decays yielded the final signal, requiring 45 s of signal averaging. The repetition time was 160 ms. The spectral width was 16 kHz, and the data block size was 512. For the transient Mb desaturation experiments, acquiring the signals for a 20-s spectrum yielded sufficient signal to noise to follow the dynamic change in cellular O2 during contraction. All spectra were referenced to the water signal as 4.60 ppm at 39°C, which in turn was calibrated against 3-(trimethylsilyl)propionic acid-D4 sodium salt as 0 ppm.
At the end of the 1H-NMR experiments, a pneumatic cuff above the knee was inflated to 240 mmHg to occlude blood flow to the calf muscle, and the resultant deoxy-Mb signal intensity served as the 100% Mb desaturation normalization constant (50). That value was then checked against a soft cast made for each participant's leg, from the knee down to the ankle, and was used to calibrate the area intensity of the observed Mb signal (38). The cast was prepared with ScotchCast Plus and was filled with a 0.2 mM methemoglobin solution.
A conforming flexible coil wrapped around the participant's leg was used for 31P-NMR (25.85 MHz) signal acquisition. A 50-mm slice was selected and then excited with a self-refocused 45° radiofrequency pulse. The effective echo time was set at 2.5 ms (36). The other acquisition parameters were 2.5-kHz spectral width, 2,048 data points, 820-ms acquisition time, and 2-s recycle time. For the steady-state measurements, each 31P-NMR spectrum consisted of 50 transients and required a total acquisition time of 140 s. For the transient-state measurements, signal averaging for 30 s produced spectra with adequate signal-to-noise ratios. All spectra were apodized with a 15-Hz exponential function and referenced to phosphocreatine (PCr) as 0 ppm. 31P-NMR signal intensities were normalized to the total 31P-NMR signal area to compensate for potential movement error caused by leg muscle contraction (10).
Intracellular pH was calculated from the Pi signal using the following equation:
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Intracellular PO2 and O2.
Steady-state intracellular PO2 values were calculated from the following relationship:
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The intracellular O2 calculation assumed that the initial rate of Mb desaturation arose from the cellular O2 demand at the beginning of muscle contraction. Mb served as the only O2 source. Differentiating the fitted curve of the experimental data showing the change in deoxy-Mb concentration vs. time [y = c c·exp(x/t)] and evaluating the initial rate at time 0 yielded the initial rate of dMb/dt. The derivation of the dO2/dt assumed Mb concentration of 0.4 mM. Mb desaturation kinetics during a rapid cuffing of blood flow established the resting
O2 level.
Statistical analysis.
Values reported are means ± SE. Relationships between variables were obtained by performing nonlinear line fit, least-squares regression, and correlation analyses using SigmaStat software (version 1; Jandel Scientific, San Raphael, CA) and illustrated using SigmaPlot software (version 2; Jandel Scientific). Statistical significance was accepted at P 0.05.
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RESULTS |
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DISCUSSION |
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The desaturation kinetics of MbO2 implies that the cell has rapidly increased its O2 demand, which presumably reflects the change in intracellular O2. Such an assumption appears reasonable, given the primary role of Mb either as the predominant cellular O2 store or as a facilitator of intracellular O2 transport and source of O2 to satisfy the increased demand for O2 during muscle contraction (55). If the O2 supply from blood flow and in the interstitium does not contribute significantly at the onset of contraction, then the rate of Mb desaturation reflects the change in intracellular
O2. Although the current NMR detection sensitivity cannot measure the Mb signal with finer time resolution, the data nevertheless present a lower limit estimate because the analysis presumes no contribution of free cellular or vasculature O2 until Mb desaturation reaches a steady state.
Given the cellular Mb concentration of 0.4 mM in human gastrocnemius muscle and a resting
O2 of 2.02 µM s1, dMb/dt yields intracellular
O2 ranging from 7.5 to 8.9 µM s1 at 4570 RPM (4). The observed
O2 is within the range of the NIRS-determined
O2 of 3.031.2 O2 µM s1 in forearm muscle during isometric handgrip exercise (42, 50). NIRS, however, cannot discriminate intracellular vs. vascular change in
O2.
The initial, rapid change in Mb desaturation reflects the intracellular O2 and appears to correspond to the initial phase observed in pulmonary O2 uptake experiments (54). Indeed, recent pulmonary O2 uptake measurements have extrapolated an initial 30-s O2 uptake phase consistent with a distinct 20- to 40-s initial phase in the single-myocyte intracellular PO2 at the beginning of contraction (24, 54).
O2 supply and intracellular O2.
The Mb desaturation kinetics yield insight into O2 utilization and delivery at the initiation of muscle contraction. Under resting conditions, the NMR spectra reveal no detectable deoxy-Mb signal from the proximal histidyl N
H, even though this experimental technique can detect quantitatively the deoxy-Mb signal at
10% deoxygenation in these calf muscle experiments. Given the in vitro Mb P50 of 2.93 mmHg at 39°C, the undetected deoxy-Mb signal in the resting state implies that the intracellular PO2 must saturate >90% of the Mb, or PO2 >12 mmHg. No apparent O2 limitation exists, then, in resting muscle. These results are in agreement with studies of in situ heart and skeletal muscle, which also have not revealed any detectable deoxy-Mb signal in the basal normoxic state (33, 37, 38, 56).
At the onset of exercise, the rapid deoxygenation of Mb implies a transient mismatch between O2 supply and demand. Indeed, if O2 delivery matches precisely the respiration need in human calf muscle, then Mb would not need to supply any O2 (3, 29). No Mb desaturation should occur. However, if a transient mismatch exists, then the mitochondria draw from an immediate intracellular O2 storage until convective flow or conductive diffusion can respond to the change in intracellular O2 demand.
Under such assumptions, the Mb desaturation kinetics thus reflects intracellular O2. This analysis assumes that all O2 originates from Mb. Free O2 does not contribute significantly until Mb has reached its deoxygenated steady state within 30 s and the vasculature has adapted its blood flow to deliver more O2. Both the undefined O2 contribution and the 20-s signal averaging of the Mb resonance suggest that Mb-derived intracellular
O2 represents a low-limit estimate.
The O2 gradient in conductive diffusion cannot immediately accommodate the sudden rise in O2. As
O2 increases 273 to 343% above its resting level, the PO2 gradient from the vasculature to the cell as reflected in the venous PO2 and the Mb-derived intracellular PO2 changes only 11.316.3% (Table 2). The modest change in the PO2 concentration gradient and the associated diffusion driving force cannot accommodate the rise in
O2. As previously reported, the vasculature requires a finite time,
30 s, to adapt, increase flow, and decrease the capillary-to-cell distance to restore the match between O2 supply and demand (20, 25). This viewpoint coincides with the observed rapid Mb desaturation to a steady-state level.
O2, however, continues to rise after Mb has desaturated to a steady-state level. The temporal sequence appears to be as follows. A cellular O2 supply-and-demand mismatch at the onset of contraction uses the Mb oxygen store to provide the immediate source for respiration. Convective-conductive diffusion then restores the O2 supply-and-demand balance to spare additional O2 loss from Mb and to allow
O2 to continue rising (30).
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Even if intracellular O2 increases with rising O2, it can regulate the cytochrome oxidase reaction only if the O2 resting concentration is near the reaction Km. If intracellular O2 saturates cytochrome oxidase, however, then any increase in O2 cannot affect the reaction velocity. In vivo experiments have determined that, at rest, the intracellular O2 concentration in the heart and skeletal muscle must exceed a PO2 of 12 mmHg, well above the P50 of 2.93 mmHg at 39°C (33, 38). Otherwise, NMR would detect a deoxy-Mb signal. In vitro enzyme studies, however, have ascribed a Km of 0.1 µM to cytochrome oxidase (53). Such a wide difference in Km values suggests that the cell must maintain a large 100:1 O2 gradient from the sarcolemma to the mitochondria if O2 is at the Km concentration range of the cytochrome oxidase reaction (8). Although previous studies have reported such an intracellular gradient, other experiments have not provided corroborative evidence (9). No significant deviation in the linear relationship between the physiological and/or metabolic indices and the percent Mb saturation has appeared, as the gradient coherence model would predict (6, 48). Moreover, a gradient that sets the O2 at the cytochrome oxidase Km can regulate respiration only if the O2 concentration at the mitochondrial level increases. The experimental data, however, show an overall decreasing intracellular PO2 level as whole body
O2 rises. Unless the large cellular PO2 gradient collapses, the declining O2 level militates against O2 as the sole determinant of
O2 during muscle contraction.
Alternatively, if such an O2 gradient does not exist, then the intracellular O2 saturates cytochrome oxidase under resting and exercising conditions. Raising the intracellular or extracellular PO2 cannot regulate the enzyme reaction velocity or respiration. Indeed, recent Xenopus fiber studies have shown that increasing the extracellular PO2 (PEO2) does not significantly alter the intracellular PO2 (PIO2) during stimulation (29).
ADP-independent O2 regulation at the initial phase of contraction.
If the O2 supply does not regulate
O2 at the initiation of contraction, then current respiratory control models would point to either ADP or NADH as the regulatory factor cast as either an equilibrium or a kinetic model. A rising level of either ADP or NADH, ADP/ATP, or NADH/NAD stimulates respiration, which in turn increases the reduction of O2 by cytochrome oxidase. Because Mb desaturation kinetics directly yield intracellular
O2, an Eadie-Hofstee kinetic analysis can readily assess any ADP-dependent rise in intracellular
O2 at the start of muscle contraction. On the basis of the assumption of a near-equilibrium CK enzyme and the approximation of the instantaneous steady state with the equilibrium state, the Eadie-Hofstee analysis of
O2 dependence on ADP reveals no discernible correlation (11). In fact, the data reveal a positive slope in the graph of
O2/ADP vs.
O2 when the Eadie-Hostee analysis demands a negative slope to show any substrate dependence in enzyme kinetics.
In phase II O2, however, the same kinetic analysis of ADP vs.
O2 indicates a clear ADP-dependent regulation of
O2, which is in excellent agreement with previous reports in the literature (2). The present experimental results suggest that the cell exerts biphasic control of respiration in which the initial phase appears to be ADP independent but the latter phase is ADP dependent.
O2-dependent ATP production during muscle contraction.
From the vantage of cellular bioenergetics, any ADP control must still fit within a framework of energy fluxes, partitioned broadly into oxidative and nonoxidative components. The regulation of the respective fluxes through CK, glycolysis, glycogenolysis, and oxidative phosphorylation during muscle contraction forms a basis for the overall control of bioenergetics. On the basis of the Mb desaturation kinetics, the cell consumes 7.58.9 µM of O2 s1 at the onset of contraction, consistent with a 30-s depletion of MbO2 to a steady-state level of 3048% MbO2 saturation. Using the canonical ATP production rate per mole of O2 consumed (P:O) ratio of 3:1 yields the corresponding oxidative ATP production rate of 4554 µM s1 or
50 µM per contraction. Given the 0.36 mM (
0.3 mM) ATP g1 per contraction observed in freeze-clamp experiments with frog muscle, the initial oxidative ATP production can supply 17% of the ATP required for each contraction (27). In a recent experiment with human forearm muscle stimulated at 1 Hz, however, the investigators extrapolated from steady-state measurements a lower energy cost of 0.15 mM ATP per contraction (4). That study's experimental condition corresponds closely to the present study's exercise protocol at 70 RPM. Given ATP utilization at 1 Hz stimulation,
O2 can actually fuel 36% of the required energy. ATP from oxidative metabolism no longer has a paltry role. Instead, oxidative phosphorylation supplies a significant fraction of the energy per muscle contraction. In contrast to the orthodox view of muscle bioenergetics, which ascribes an insignificant contribution of oxidative ATP production during a contraction cycle and underscores a predominant role for PCr as a transient energy buffer, the present analysis shows a significant 36% contribution to the currently accepted energy cost per twitch.
However, some questions surround the accuracy of the currently accepted ATP use during muscle contraction. The level of ATP use per twitch originates from freeze-clamp experiments or from extrapolation of the PCr kinetics with an averaged time resolution of minutes. With freeze-clamp techniques, the time resolution is only 100 ms, whereas the muscle contraction cycle peaks in 20 ms. If a muscle contraction consumes much more ATP in <100 ms, the freeze-clamp technique cannot accurately quantitate the value (10). With the analysis of the gradual decline in PCr, the extrapolation of the energy cost per twitch from d[PCr]/dt at t = 0 presumes an insignificant restoration of ATP from oxidative phosphorylation or other metabolic pathways (15). Clearly, the present report shows that oxidative phosphorylation does contribute significantly.
Indeed, Chung et al. (10) have presented a different picture of the twitch energy cost and have hypothesized a much larger energy fluctuation. They devised a novel NMR technique to measure millisecond changes in PCr during a muscle contraction cycle and observed 3 mM ATP per contraction, which is
10 times greater than the currently accepted energy cost (10). With 3 mM ATP, oxidative phosphorylation can supply only 2% of the energy per twitch. PCr would deplete rapidly unless an energy restoration process allows PCr to recover between contractions. Another source must fuel the millisecond energy bursts during each twitch and sustain continuing contractions.
A novel glycogen shunt theory has been proposed that glycogen supplies that energy (46). However, several dozen contractions would deplete the 70 mM glucosyl unit of glycogen, which experiments have not observed. Oxidative phosphorylation must still replete the energy store in the steady state. Although
O2 at the initiation of contraction cannot supply all of the ATP contraction need,
O2 does rise as contraction proceeds, and the vasculature increases the O2 supply. The increased
O2 can then provide additional oxidative ATP to replenish PCr and allow for glycogen resynthesis.
Implication for the role of Mb in supplying O2.
The present report also casts a perspective on the role of Mb as a cellular O2 store. As a cellular O2 store, Mb sustains the myocardial aerobic demand for only a few contraction cycles. During global ischemia, Mb desaturates with a t1/2 of 0.9 min, consistent with the PCr depletion value, and during postischemic reperfusion, O2 returns rapidly to control levels (9). The O2 store in Mb does not confer any significant advantage in the cellular response to ischemia or postischemic recovery as CO inhibition and other experiments have demonstrated (Ref. 9 and Huang S et al., unpublished manuscript). However, the rapid MbO2 desaturation observed in the present study suggests that Mb also has a significant role in the transient state. Mb appears to buffer the transient energy demand by providing an immediate source of O2 at the onset of muscle contraction. These observations stimulate the continuing discussion about the transient- and steady-state roles of Mb in mammalian tissue.
An alternative view of bioenergetics of muscle contraction.
In the current respiratory control models, the analysis has focused on the influence of ADP, NADH, or O2 on O2 in either the kinetic or thermodynamic formulation, especially with respect to a rate-limiting substrate or enzyme activity. The analysis provides continuity between past and present studies but overlooks a fundamental issue: the tight interaction of cellular metabolite flux militates against a simple reduction of all enzyme reactions to a rate-limiting step. Indeed, metabolic control analysis has pointed out this weakness and has introduced control coefficient and elasticity terms to characterize metabolic flux (13).
From the perspective of metabolic control, the present study's results provide a basis for partitioning the energy fluxes. At the onset of muscle contraction, the demand for ATP increases with cross-bridge movement. Given the assumption that at steady state oxidative phosphorylation provides the predominant source of energy, the whole body O2 of 13.2 ± 2.1 ml·min1·100 ml1 at 70 RPM reflects an ATP consumption rate of 589 µM/s (38). This energy consumption rate provides an estimate of the total energy demand at the onset of contraction, using the canonical 3:1 P:O ratio. The intracellular
O2 as assessed on the basis of the Mb desaturation kinetics shows an ATP production rate of 54 µM/s (9% of the energy need); PCr supplies ATP at 357 µM/s (61% of the energy need). The missing energy (30% of the energy need) must then arise from anaerobic metabolism, most notably through glycogenolysis or glycolysis. Isotope tracer studies, however, have indicated that exercising muscle consumes glucose at only 1.1 µM/s, producing ATP at only 2.2 µM/s (31, 41). Consequently, glycogenolysis must supply ATP energy at
170 µM/s, corresponding to a glycogen metabolism rate of 54 µM/s. That rate of glycogenolysis falls well within the value (120 µM/s) observed in contracting human muscle (47). Because the total muscle glycogen pool is
70 mM, glycogenolysis can sustain the missing energy need for well over 25 min.
Metabolic transient studies of rat muscle, however, have indicated that the ATP consumption rate is actually much higher, approaching 3 mM ATP/contraction or 3 mM/s, given a 1-Hz contraction rate (10). Although the muscle glycogenolysis rate could exceed 170 µM/s to accommodate the increased ATP need, the energy demand rapidly depletes the total glycogen pool within 25 contractions, which experiments have not observed. The missing energy, given the transient energy demand, implies that the intracellular O2 as reflected in the Mb desaturation kinetics underestimates the actual
O2.
An underestimate of O2 seems reasonable because the analysis relies on a 20-s time-averaged change of the deoxy-Mb proximal histidyl N
H signal to extract the Mb desaturation rate per contraction or per second. Such an analysis parallels the experimental approach to determine the change in PCr per contraction from time-averaged signals. Extrapolating from the overall time-averaged PCr kinetics during muscle stimulation can lead to the change in PCr per contraction, provided that all ATP generation pathways contribute insignificantly. As the metabolic transient study has shown, that approach underestimates the PCr/contraction (10).
The analysis also presumes that O2 in the blood or in the interstitial space contributes insignificantly during the entire contraction-relaxation cycle. The actual contraction phase, however, represents only a small fraction of the overall cycle. During the relaxation phase, O2 can readily diffuse from the interstitium or the vasculature.
On the basis of these considerations, the synergistic interaction of oxidative phosphorylation and glycogenolysis regulates the metabolic flux to meet the enhanced energy demand at the onset of contraction. CK, as a near-equilibrium enzyme, would presumably exert no significant control. Additional experiments must now be conducted to determine the transient changes in glycogen and Mb and to quantify accurately the contribution of oxidative phosphorylation and glycogenolysis in regulating energy flow during a muscle contraction cycle.
In conclusion, the present study has established a method of measuring intracellular O2 at the initiation of muscle contraction. Given the rise in intracellular
O2, no significant rise in ADP has occurred as predicted by the kinetic model in the regulation of respiration. Moreover, the intracellular O2 level decreases rapidly. On the basis of the conventional analytical model, these observations suggest that
O2 does not depend on O2 and ADP at the beginning of muscle contraction. Other regulators must intervene. Current respiration control theory points to an out-of-equilibrium, NADH-dependent reaction that modulates the redox state or the NADH level, which in turn stimulates respiration. Although PDH stimulation should increase
O2, experiments enhancing PDH activity with dichloroacetate have yielded inconsistent results (21, 26, 33, 44, 49).
On the basis of the steady-state estimate of energy requirements during muscle contraction, the energy fluxes partition as follows: O2, 9%; PCr, 61%; glycogenolysis, 30%; and glucose, negligible. Metabolic transient studies of rat muscle, however, have indicated that the ATP consumption rate is actually much higher, approaching 3 mM ATP/contraction or 3 mM/s, given a 1-Hz contraction rate (10). Glycogenolysis and
O2 thus must interact synergistically to provide energy during a muscle contraction cycle.
With the Mb-derived intracellular O2 measurement, the present results show an initial mismatch between O2 supply and demand, an ADP-dependent and -independent mode of respiratory control, a significant role for Mb in filling the transient O2 need, a significant energy contribution from glycogenolysis, and oxidative phosphorylation over a dynamic, milliseconds-duration muscle contraction cycle.
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GRANTS |
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ACKNOWLEDGMENTS |
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FOOTNOTES |
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The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
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REFERENCES |
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2. Barstow TJ, Buchthal SD, Zanconato S, and Cooper DM. Changes in potential controllers of human skeletal muscle respiration during incremental calf exercise. J Appl Physiol 77: 21692176, 1994.
3. Behnke BJ, Kindig CA, Musch TI, Koga S, and Poole DC. Dynamics of microvascular oxygen pressure across the rest-exercise transition in rat skeletal muscle. Respir Physiol 126: 5363, 2001.[CrossRef][ISI][Medline]
4. Blei ML, Conley KE, and Kushmerick MJ. Separate measures of ATP utilization and recovery in human skeletal muscle. J Physiol 465: 203222, 1993.[Abstract]
5. Brändén M, Sigurdson H, Namslauer A, Gennis RB, Ädelroth P, and Brzezinski P. On the role of the K-proton transfer pathway in cytochrome c oxidase. Proc Natl Acad Sci USA 98: 50135018, 2001.
6. Chance B. Metabolic heterogeneities in rapidly metabolizing tissue. J Appl Cardiol 4: 207221, 1989.[ISI]
7. Chance B, Leigh JS Jr, Kent J, McCully K, Nioka S, Clark BJ, and Maris JM. Multiple controls of oxidative metabolism in living tissues as studied by phosphorus magnetic resonance. Proc Natl Acad Sci USA 83: 94589462, 1986.[Abstract]
8. Chance EM and Chance B. Oxygen delivery to tissue: calculation of oxygen gradients in the cardiac cell. Adv Exp Med Biol 222: 6975, 1988.[Medline]
9. Chung Y and Jue T. Cellular response to reperfused oxygen in the postischemic myocardium. Am J Physiol Heart Circ Physiol 271: H687H695, 1996.
10. Chung Y, Sharman R, Carlsen R, Unger SW, Larson D, and Jue T. Metabolic fluctuation during a muscle contraction cycle. Am J Physiol Cell Physiol 274: C846C852, 1998.
11. Connett RJ and Honig CR. Regulation of O2 in red muscle: do current biochemical hypotheses fit in vivo data? Am J Physiol Regul Integr Comp Physiol 256: R898R906, 1989.
12. Ereciska M and Wilson DF. Regulation of cellular energy metabolism. J Membr Biol 70: 114, 1982.[ISI][Medline]
13. Fell D. Understanding the Control of Metabolism. Brookfield, VT: Portland, 1997.
14. Flögel U, Merx MW, Gödecke A, Decking UKM, and Schrader J. Myoglobin: a scavenger of bioactive NO. Proc Natl Acad Sci USA 98: 735740, 2001.
15. Foley JM and Meyer RA. Energy cost of twitch and tetanic contractions of rat muscle estimated in situ by gated 31P NMR. NMR Biomed 6: 3238, 1993.[ISI][Medline]
16. Garry DJ, Ordway GA, Lorenz JN, Radford NB, Chin ER, Grange RW, Bassel-Duby R, and Williams RS. Mice without myoglobin. Nature 395: 905908, 1998.[CrossRef][ISI][Medline]
17. Gayeski TEJ and Honig CR. Intracellular PO2 in long axis of individual fibers in working dog gracilis muscle. Am J Physiol Heart Circ Physiol 254: H1179H1186, 1988.
18. Gennis RB. How does cytochrome oxidase pump protons? Proc Natl Acad Sci USA 95: 1274712749, 1998.
19. Glabe A, Chung Y, Xu D, and Jue T. Carbon monoxide inhibition of regulatory pathways in myocardium. Am J Physiol Heart Circ Physiol 274: H2143H2151, 1998.
20. Gorczynski RJ, Klitzman B, and Duling BR. Interrelations between contracting striated muscle and precapillary microvessels. Am J Physiol Heart Circ Physiol 235: H494H504, 1978.
21. Grassi B, Hogan MC, Greenhaff PL, Hamann JJ, Kelley KM, Aschenbach WG, Constantin-Teodosiu D, and Gladden LB. Oxygen uptake on-kinetics in dog gastrocnemius in situ following activation of pyruvate dehydrogenase by dichloroacetate. J Physiol 538: 195207, 2002.
22. Heineman FW and Balaban RS. Control of mitochondrial respiration in the heart in vivo. Annu Rev Physiol 52: 523542, 1990.[CrossRef][ISI][Medline]
23. Heineman FW, Kupriyanov VV, Marshall R, Fralix TA, and Balaban RS. Myocardial oxygenation in the isolated working rabbit heart as a function of work. Am J Physiol Heart Circ Physiol 262: H255H267, 1992.
24. Hogan MC. Fall in intracellular PO2 at the onset of contractions in Xenopus single skeletal muscle fibers. J Appl Physiol 90: 18711876, 2001.
25. Honig CR, Odoroff CL, and Frierson JL. Capillary recruitment in exercise: rate, extent, uniformity, and relation to blood flow. Am J Physiol Heart Circ Physiol 238: H31H42, 1980.
26. Howlett RA, Heigenhauser GJF, Hultman E, Hollidge-Horvat MG, and Spriet LL. Effects of dichloroacetate infusion on human skeletal muscle metabolism at the onset of exercise. Am J Physiol Endocrinol Metab 277: E18E25, 1999.
27. Infante AA, Klaupiks D, and Davies RE. Phosphorylcreatine consumption during single-working contractions of isolated muscle. Biochim Biophys Acta 94: 504515, 1965.[ISI][Medline]
28. Jue T and Anderson S. 1H NMR observation of tissue myoglobin: an indicator of cellular oxygenation in vivo. Magn Reson Med 13: 524528, 1990.[ISI][Medline]
29. Kindig CA, Howlett RA, and Hogan MC. Effect of extracellular PO2 on the fall in intracellular PO2 in contracting single myocytes. J Appl Physiol 94: 19641970, 2003.
30. Kindig CA, Kelley KM, Howlett RA, Stary CM, and Hogan MC. Assessment of O2 uptake dynamics in isolated single skeletal myocytes. J Appl Physiol 94: 353357, 2003.
31. Kjaer M, Kiens B, Hargreaves M, and Richter EA. Influence of active muscle mass on glucose homeostasis during exercise in humans. J Appl Physiol 71: 552557, 1991.
32. Kreutzer U and Jue T. 1H nuclear magnetic resonance deoxymyoglobin signal as indicator of intracellular oxygenation in myocardium. Am J Physiol Heart Circ Physiol 261: H2091H2097, 1991.
33. Kreutzer U, Mekhamer Y, Chung Y, and Jue T. Oxygen supply and oxidative phosphorylation limitation in rat myocardium in situ. Am J Physiol Heart Circ Physiol 280: H2030H2037, 2001.
34. Kreutzer U, Wang DS, and Jue T. Observing the 1H NMR signal of the myoglobin Val-E11 in myocardium: an index of cellular oxygenation. Proc Natl Acad Sci USA 89: 47314733, 1992.
35. Lawson JWR and Veech RL. Effects of pH and free Mg2+ the Keq of the creatine kinase reaction and other phosphate hydrolyses and phosphate transfer reactions. J Biol Chem 254: 65286537, 1979.[Abstract]
36. Lim KO, Pauly J, Webb P, Hurd R, and Macovski A. Short TE phosphorus spectroscopy using a spin-echo pulse. Magn Reson Med 32: 98103, 1994.[ISI][Medline]
37. Mancini DM, Wilson JR, Bolinger L, Li H, Kendrick K, Chance B, and Leigh JS. In vivo magnetic resonance spectroscopy measurement of deoxymyoglobin during exercise in patients with heart failure: demonstration of abnormal muscle metabolism despite adequate oxygenation. Circulation 90: 500508, 1994.[Abstract]
38. Molé PA, Chung Y, Tran TK, Sailasuta N, Hurd R, and Jue T. Myoglobin desaturation with exercise intensity in human gastrocnemius muscle. Am J Physiol Regul Integr Comp Physiol 277: R173R180, 1999.
39. Paganini AT, Foley JM, and Meyer RA. Linear dependence of muscle phosphocreatine kinetics on oxidative capacity. Am J Physiol Cell Physiol 272: C501C510, 1997.
40. Paterson DH and Whipp BJ. Asymmetries of oxygen uptake transients at the on- and offset of heavy exercise in humans. J Physiol 443: 575586, 1991.[Abstract]
41. Roepstorff C, Steffensen CH, Madsen M, Stallknecht B, Kanstrup IL, Richter EA, and Kiens B. Gender differences in substrate utilization during submaximal exercise in endurance-trained subjects. Am J Physiol Endocrinol Metab 282: E435E447, 2002.
42. Sako T, Hamaoka T, Higuchi H, Kurosawa Y, and Katsumura T. Validity of NIR spectroscopy for quantitatively measuring muscle oxidative metabolic rate in exercise. J Appl Physiol 90: 338344, 2001.
43. Saltin B, Gagge AP, and Stolwijk JAJ. Muscle temperature during submaximal exercise in man. J Appl Physiol 25: 679688, 1968.
44. Savasi I, Evans MK, Heigenhauser GJF, and Spriet LL. Skeletal muscle metabolism is unaffected by DCA infusion and hyperoxia after onset of intense aerobic exercise. Am J Physiol Endocrinol Metab 283: E108E115, 2002.
45. Schneider E and Glover G. Rapid in vivo proton shimming. Magn Reson Med 18: 335347, 1991.[ISI][Medline]
46. Shulman RG and Rothman DL. The "glycogen shunt" in exercising muscle: a role for glycogen in muscle energetics and fatigue. Proc Natl Acad Sci USA 98: 457461, 2001.
47. Shulman RG, Rothman DL, and Price TB. Nuclear magnetic resonance studies of muscle and applications to exercise and diabetes. Diabetes 45, Suppl 1: S93S98, 1996.[ISI][Medline]
48. Takahashi E, Endoh H, and Doi K. Intracellular gradients of O2 supply to mitochondria in actively respiring single cardiomyocyte of rats. Am J Physiol Heart Circ Physiol 276: H718H724, 1999.
49. Timmons JA, Gustafsson T, Sundberg CJ, Jansson E, and Greenhaff PL. Muscle acetyl group availability is a major determinant of oxygen deficit in humans during submaximal exercise. Am J Physiol Endocrinol Metab 274: E377E380, 1998.
50. Tran TK, Sailasuta N, Kreutzer U, Hurd R, Chung Y, Molé P, Kuno S, and Jue T. Comparative analysis of NMR and NIRS measurements of intracellular PO2 in human skeletal muscle. Am J Physiol Regul Integr Comp Physiol 276: R1682R1690, 1999.
51. Tschakovsky ME and Hughson RL. Interaction of factors determining oxygen uptake at the onset of exercise. J Appl Physiol 86: 11011113, 1999.
52. Vandenborne K, McCully K, Kakihira H, Prammer M, Bolinger L, Detre JA, De Meirlier K, Walter G, Chance B, and Leigh JS. Metabolic heterogeneity in human calf muscle during maximal exercise. Proc Natl Acad Sci USA 88: 57145718, 1991.
53. Wharton DC and Gibson QH. Cytochrome oxidase from Pseudomonas aeruginosa: IV. reaction with oxygen and carbon monoxide. Biochim Biophys Acta 430: 445453, 1976.[ISI][Medline]
54. Whipp BJ, Rossiter HB, Ward SA, Avery D, Doyle VL, Howe FA, and Griffiths JR. Simultaneous determination of muscle 31P and O2 uptake kinetics during whole body NMR spectroscopy. J Appl Physiol 86: 742747, 1999.
55. Wittenberg BA and Wittenberg JB. Transport of oxygen in muscle. Annu Rev Physiol 51: 857878, 1989.[CrossRef][ISI][Medline]
56. Zhang J, Murakami Y, Zhang Y, Cho YK, Ye Y, Gong G, Bache RJ, Uurbil K, and From AHL. Oxygen delivery does not limit cardiac performance during high work states. Am J Physiol Heart Circ Physiol 277: H50H57, 1999.