Muscle stimulation and sampling for PDH activity.

The average body weight of all treatment groups was 240±9 g. Animals were fasted 12 h overnight before isoflurane anesthesia induction at 5% for 3 min. Anesthesia was maintained at 1.5–2.5% during the surgical procedure, and body temperature was monitored via rectal thermocouple (Omega HH11) and maintained at 36.5–37.5°C. For control resting (n = 5) and DCA (n = 4) treatment groups no stimulation was performed. The control gastrocnemius-plantaris muscle group was excised immediately after anesthesia induction, whereas DCA-treated muscles were excised 1 h after tail vein injection of DCA (150 mg/kg at 220 mg/ml) dissolved in isotonic saline. Muscles were immediately freeze-clamped after excision in liquid N₂-precooled Wollenberger tongs and stored at −80°C for analysis. For 0.5 Hz (n = 4) and 1.0 Hz (n = 4) stimulation groups the sciatic nerve of one hindlimb was exposed as described previously (33). In brief, a 1.5-cm-wide incision was made on the lateral aspect of the hip, and blunt dissection was performed through the gluteus adjacent to the sciatic nerve. The nerve was then insulated from surrounding tissues with a small strip of Parafilm, and a bipolar platinum electrode was placed around the nerve and the wound closed with cyanoacrylate glue. A length of suture (20-lb test braided nylon) was fixed to the patellar tendon, which was fixed in place on a custom Perspex animal holder. The lower limb was dissected free of overlying skin, and a length of suture was secured to the Achilles tendon. The calcaneus was cut to remove anterior muscles from interfering with the force recording from the gastrocnemius-plantaris-soleus muscles. The animal was positioned prone in the Perspex animal holder with the knee fixed in place and the Achilles tendon attached to a strain gauge (Grass FT03C). Maximum force output was then achieved by determining the supramaximal stimulation voltage and the optimal resting length with the length-tension relation. After initial maximal tension was measured, muscles were stimulated at either 0.5 Hz or 1.0 Hz for 5 min. Immediately after this period, the gastrocnemius-plantaris muscle group was freeze-clamped in liquid N₂-precooled Wollenberger tongs while the muscles were still contracting to maintain the phosphorylation status of PDH. Samples were then stored at −80°C for later biochemical analyses.

[2-¹⁴C]pyruvate tracer solution for PDH activity assay.

A standard solution of 35 mM pyruvate was made in water and its concentration verified. Briefly, 1 µl of 35 mM pyruvate was added to 0.99 ml of 303 mM triethanolamine (TEA)-3.03 mM EDTA and 10 µl of 25 mM NADH, pH 7.5 at room temperature (RT). Pyruvate concentration was assayed in triplicate with a spectrophotometric lactate dehydrogenase (LDH) assay after consumption of NADH at 340 nm at 25°C. Baseline absorbance was measured, and excess LDH (5–10 units) was added and incubated for 5 min or until no absorbance change was present. The pyruvate concentration was then calculated from the change in absorbance from baseline with the extinction coefficient of NADH (ε₃₄₀=6,220 M⁻¹·cm⁻¹) assuming that the reaction of NADH is 1:1 with pyruvate. Five milliliters of standardized 35 mM pyruvate solution were then added to 250 µCi of [2-¹⁴C]pyruvate sodium salt (specific activity 7.3 mCi/mmol; Perkin Elmer no. NEC256), and the final concentration was verified by spectrophotometric LDH assay as described above. Specific activity of the [2-¹⁴C]pyruvate tracer solution was then determined via reaction with glutamate with glutamate pyruvate transaminase to form [2-¹⁴C]alanine. This step was performed to determine the fraction of the ¹⁴C label that is specific to pyruvate in the tracer solution. In brief, 1 µl of [2-¹⁴C]pyruvate tracer solution was added to 500 µl of 50 mM TEA, 0.5 mM EDTA, and 250 mM glutamate, pH 7.5 at RT. Assays were carried out in duplicate with two negative controls. Glutamate pyruvate transaminase (~2 units) was then added to initiate the reaction but omitted from negative controls. Reactions were carried out at RT, and after 1 h 400 µl aliquots were removed and loaded into gravity flow columns containing a 1-ml settled volume of anion exchange resin (Bio-Rad AG1x8 resin, 200–400 mesh, acetate form) contained in a 3-ml syringe with a Luer lock stopcock. This resin traps the negatively charged [2-¹⁴C]pyruvate while the positively charged [2-¹⁴C]alanine passes through. Resin was then washed three times with 500 µl of water, and column eluate was collected into 25 ml glass scintillation vials containing 20 ml of Safety-Solve scintillant and counted with a Packard Tri-Carb liquid scintillation analyzer. Background counts from negative controls were subtracted from sample values to obtain the specific activity (cpm/µmol) of the [2-¹⁴C]pyruvate tracer solution. Aliquots (100 µl) of the [2-¹⁴C]pyruvate tracer solution were stored at −80°C until needed.

Homogenization and assay buffers for PDH activity assay.

Homogenization buffer A, for measurement of PDH active fraction (PDH_a), contained (in M) 0.05 Tris·HCl, 0.005 EGTA, 0.005 MgCl₂·6H₂O, 0.05 KCl, 0.05 NaF, 0.005 DCA, and 0.001 DTT, with 0.1% Triton X-100, pH 7.8 on ice. Homogenization buffer B, for measurement of total PDH activity (PDH_t), contained (in M) 0.05 Tris·HCl, 0.024 CaCl₂·2H₂O, 0.005 MgCl₂·6H₂O, 0.05 KCl, and 0.005 DCA, with 0.1% Triton X-100 and with 0.01 M glucose, 0.001 M DTT, and 5 U/ml hexokinase added fresh before use, pH 7.8 on ice. Assay buffer contained 0.12 M Tris·HCl, 0.577 mM Na₂EDTA, 0.001 M MgCl₂·6H₂O, and 0.001 M DCA, with 3.86 mM NAD⁺, 5.77 mM CoA, 0.001 M thiamine pyrophosphate, 0.012 M l-carnitine-HCl, and 0.8 U/ml CAT added fresh before use, pH 7.8 at 37°C. For assay of PDH_t, 2.88 mM NaF was also added to assay buffer.

PDH activity assay.

PDH activity was determined by a method developed previously by Sterk et al. (2003) with modifications outlined below (55). In brief, PDH activity in muscle homogenates was determined by a coupled enzyme assay after the conversion of the radiolabeled substrate ([2-¹⁴C]pyruvate) to radiolabeled product ([1-¹⁴C]acetylcarnitine):

Reaction time points were collected and then passaged through gravity flow columns containing anion exchange resin allowing for the separation of ¹⁴C-labeled compounds by trapping the unreacted negatively charged substrate, [2-¹⁴C]pyruvate, while allowing the passage of the positively charged product, [1-¹⁴C]acetylcarnitine, to quantify the reaction rate. Overall reaction rate was limited by the amount of PDH activity, as CAT and substrates of the reaction were added in excess. Thus the rate of [1-¹⁴C]acetylcarnitine production was assumed to be 1:1 with [1-¹⁴C]A-CoA production and used to quantify PDH activity in muscle samples. Reactions were carried out in homogenates produced from freeze-clamped muscle samples of the gastrocnemius-plantaris group. Samples were first powdered under liquid nitrogen by mortar and pestle, followed by two separate assays for determination of PDH_a and PDH_t. Approximately 30–50 mg of muscle powder was added to 250 µl of ice-cold homogenization buffer A (PDH_a) and immediately mixed with vigorous shaking. Buffer volume was then adjusted by adding buffer to a final 10% homogenate concentration. Homogenates were then sonicated on ice with a Branson sonicator at 20 kc three times for 15 s with 15-s breaks in between. Each homogenate was then immediately assayed by adding 15 µl of homogenate to 85 µl of assay buffer prewarmed to 37°C and vortexed to mix. Reactions were carried out in triplicate at time points of 30 s, 1 min, and 1.5 min and initiated by the addition of [2-¹⁴C]pyruvate tracer solution to a final concentration of 1 mM. [2-¹⁴C]pyruvate tracer was added as a drop on the side of the reaction Eppendorf tube, and time points were started by vortexing, mixing the [2-¹⁴C]pyruvate tracer into the assay solution and initiating the reaction. Reaction temperature was maintained at 37°C for the entire duration by means of a heated water bath. Reactions were then quenched at appropriate time points via the addition of 500 µl of ice-cold methanol followed by vortexing. Each time point was run separately, and quenched samples were stored on ice until the reaction series of that sample was complete. Once the reaction series was completed for PDH_a, the entire process was repeated by producing another muscle homogenate with homogenization buffer B for determination of PDH_t activity. Quenched reaction time points were then loaded into gravity flow columns containing a 1-ml settled volume of anion exchange resin (Bio-Rad AG1x8 resin, 200–400 mesh, acetate form) contained in a 3 ml syringe with a Luer lock stopcock. Columns were then washed three times with 500 µl of water, with column eluate collected into 25-ml glass scintillation vials containing 20 ml of Safety-Solve liquid scintillation cocktail. The radioactivity in each vial was then counted with a Packard Tri-Carb liquid scintillation analyzer, and, using the specific activity of the tracer solution, the reaction rate was determined for quantification of PDH activity.

Assay for muscle ATP content.

Muscle samples were assayed for ATP content by the method of Lowry et al. (1972) (38). In brief, the superficial gastrocnemius was sampled under isoflurane anesthesia and immediately freeze-clamped. Muscles were powdered under liquid nitrogen and stored at −80°C until analysis. Metabolites were extracted from powdered muscle samples by adding ice-cold perchloric acid solution (2 N HClO₄, 5 mM EDTA) at a final dilution of 1:10 as previously described (61). Extracts were mixed at 4°C for 20 min and subsequently centrifuged at 20,000 g for 20 min. The supernatant was neutralized by the addition of an equivalent volume of potassium hydroxide buffer (2 N KOH, 150 mM TES, 300 mM KCl), and a second centrifugation (3,000 g, 10 min) step removed precipitated perchlorate salts. Neutralized extracts were assayed for ATP content at RT with a coupled spectrophotometric enzyme assay (38).

NMR spectroscopy during stimulation.

In vivo rat muscle preparations were prepared as previously described for benchtop experiments, but for these experiments the skin and calcaneus process were left intact. An intraperitoneal (IP) catheter (PE 20) was inserted for DCA administration and sealed in place with cyanoacrylate glue. The animal was secured in a custom 74-mm-diameter phosphorus nuclear magnetic resonance (³¹P NMR) probe with the knee secured via a tungsten pin fixed through the femur and attached to brass supports. The Achilles tendon was tied to a custom-built isometric force transducer at the top of the probe. This arrangement positioned the center of the superficial gastrocnemius muscle directly over a 1.7-cm-diameter circular surface coil. Isoflurane anesthesia was maintained at 1.5–2.5% for the duration of the experiment through a nose cone built into the body of the NMR probe, and temperature was monitored via rectal thermistor (YSI model 73A) and maintained at 36.5–37.5°C with thermostated air. In each experiment the muscle length and supramaximal stimulation voltage (5–15 V) were adjusted to yield peak isometric tension development, and the probe was inserted into a Bruker AM400 spectrometer (9.4 T, 7.4-cm vertical bore magnet). Magnetic field homogeneity was optimized by shimming on the available proton signal. ³¹P NMR spectra were acquired at 161.8 MHz (4096 complex points, 8,012-Hz sweep width). The summed free induction decays (FIDs) were apodized with a 30-Hz exponential filter before the Fourier transform. The pulse width (15 µs) was chosen to yield maximum signal-to-noise ratio at a repetition time (TR) of 3.0 s. The NMR signal was corrected for partial saturation by acquiring 128 FIDs under the experimental conditions and a second at 5*T1 for PCr at 9.4 T (TR=15 s). For each stimulation series, spectra (TR=3 s, 8 scans) were acquired at rest (6 spectra), during stimulation (12 spectra), and during recovery after stimulation cessation (16 spectra). Muscles were stimulated at twitch contractile intensities of 0.35, 0.5, 0.75, 1.0, and 2.0 Hz, but no more than four stimulations were used in any experiment and frequencies were randomized. There was no effect of stimulation order on the resulting PCr transients. After the first series of stimulations, DCA was administered IP (150 mg/kg at 220 mg/ml in isotonic saline), followed by a 1 h incubation before an identical stimulation series was performed in the exact order. The triceps surae muscle group was then excised and weighed for normalization of force recordings.

High-resolution NMR spectroscopy for resting metabolites.

To obtain quantitative metabolite values in resting muscle, animals were mounted in the NMR probe and a series of spectra (20) were acquired (2,400 FIDs, 4,096 complex points, 8,012-Hz sweep, 3-s recycle delay, 30-Hz exponential filter) under the control conditions. A second series was acquired 1 h after IP administration of DCA (150 mg/kg at 220 mg/ml in isotonic saline) with the same acquisition settings.

Spectral analysis.

The FIDs of the stimulation series were analyzed with jMRUI software (version 3.0), and relative peak areas were integrated with AMARES (54). Areas of P_i, PCr, γ-ATP, α-ATP, and β-ATP peaks were normalized to the total phosphorus integral of each individual spectrum. PCr and P_i were quantified from their ratio to γ-ATP and adjusted to absolute chemical content using the enzymatically determined ATP content of the rat superficial gastrocnemius muscle determined from perchloric acid extracts described previously (34). Creatine content was estimated assuming that PCr content is 82% of total creatine (34). Intracellular pH (pH_i) was estimated from the chemical shift of P_i relative to PCr (42):

The PCr content during steady-state contractions was calculated as a percentage of the initial value by using the summed data from the six resting spectra and the final six spectra during the contractile phase. The dynamics of PCr changes were fit to a monoexponential function by an iterative least squares algorithm to obtain the time constants of both PCr hydrolysis and resynthesis. Glycolytic ATP synthesis rate (J_GLY) was estimated as follows:

where 1.5 is the stoichiometric coefficient for ATP/H⁺, β is the buffering capacity (1), and d(pH_i)/dt is the rate of acidification during contraction (29). Cytosolic ATPase rate (J_ATPase) was calculated from the initial rate of PCr hydrolysis at the start of stimulation plus the basal ATPase rate of 0.012 mM/s (21, 29). Mitochondrial ATP synthesis rate (J_MITO) was calculated by subtracting J_GLY from J_ATPase, assuming that the steady-state phosphate potential is maintained via the matching of cytosolic ATPase activity (J_ATPase) to J_MITO after J_GLY is accounted for (29). ΔG_ATP was estimated from P_i, PCr, and Cr with the creatine kinase equilibrium equation:

and substituting for [ATP]/[ADP] with K_eqCK=1.66 × 10⁹ M⁻¹ (36):

Analysis of high-resolution, nonstimulation spectra was done with NUTS analysis software version 6.1 and manual Lorentzian line fitting. Individual peaks were normalized to the total phosphorus integral and quantified as described previously.

ATP free energy in resting muscle.

In vivo metabolite levels measured by ³¹P NMR spectroscopy in control and DCA treated superficial gastrocnemius muscles are presented in Fig. 2. Activation of PDH with DCA resulted in a 17% decrease in resting P_i compared with control values (P < 0.05) within the same animal (Table 1). However, this was not met with a measurable stoichiometric increase in PCr or any alteration in pH_i. This decrease in intracellular P_i concentration through PDH activation with DCA treatment resulted in a measurable increase in the magnitude of ΔG_ATP from −65.7±0.22 to −66.4±0.30 kJ/mol (P < 0.05) in control and DCA-treated animals, respectively. (Table 1).

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Fig. 2.

Representative high-resolution ³¹P nuclear magnetic resonance spectrum of control (A) and dichloroacetate (DCA)-treated (B) resting rat gastrocnemius muscle within the same animal. Acquisition parameters: 2,400 free induction decays, 4,096 complex points, 8,012-Hz sweep, 3-s repetition time, and 30 Hz exponential filter. EC, extracellular; IC, intracellular; PCr, phosphocreatine; P_i, inorganic phosphate; PME, phosphomonoester.

Effect of PDH activation on PCr dynamics during contractile activity.

Dynamic changes in PCr and reciprocal stoichiometric changes in P_i occur at the onset and cessation of contractile activity and deviate further from their resting levels as contraction intensity increases. Figure 3 shows a representative stack plot of individual ³¹P NMR spectra serially acquired over the time course of one such experiment in control and DCA-treated conditions. Resting ³¹P NMR spectra were acquired for the first 2 min 24 s (spectra 1–6), during the next 4 min 48 s of 0.5-Hz stimulation (spectra 7–18), and during the subsequent 7 min 12 s of recovery (spectra 19–36) to quantify the steady-state and kinetic response of PCr hydrolysis and resynthesis in control and DCA-treated animals (Fig. 3). Force recordings from the triceps surae group were measured concurrently, and muscle force generation was quantified as the total tension time integral (TTI) for each muscle twitch and averaged between groups. No difference in force production between control and DCA treatment conditions was found at 0.35 Hz (67.1±8.1 vs. 58.2±5.9 g·s, n = 6), 0.5 Hz (62.4±13.0 vs. 59.3±13.1 g·s, n = 7), 1.0 Hz (45.5±3.0 vs. 39.2±1.9 g·s, n = 7), and 2.0 Hz (47.0±4.7 vs. 43.6±5.1 g·s, n = 6), with the exception of 0.75 Hz (58.0±10.9 vs. 49.4±10.5 g·s, n = 6, P < 0.05).

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Fig. 3.

Sample ³¹P nuclear magnetic resonance spectra acquired in the rat gastrocnemius muscle before (Rest), during (Stim), and after (Recovery) 0.5-Hz stimulation within 1 animal in control and dichloroacetate (DCA) treatment conditions. Acquisition parameters: total of 36 spectra composed of 8 free induction decays, 4,096 complex points, 8,012-Hz sweep, 3-s repetition time, and 30-Hz exponential filter.

Representative PCr transients during stimulation and recovery before and after DCA treatment are depicted in Fig. 4, A and B, respectively. During PCr consumption at the onset of stimulation, ATP hydrolysis rates (J_ATPase) are derived from linear fitting to the initial rate of PCr hydrolysis (29). PCr transients quantified from both control and DCA-treated rats showed that there was no difference in ATP use irrespective of treatment and that a linear relation exists between increases in ATP use and increased stimulation frequency (see Table 3). In addition, PDH activation with DCA treatment did not alter the time constant for PCr resynthesis depicted as the rising monoexponential functions in Fig. 4, A and B and further quantified in Table 2, indicating that ATP production is also unaffected by DCA treatment (Table 2). During steady-state contractions, pH_i values decreased with increasing stimulation frequency as previously shown in other studies (41). DCA treatment did not result in significant deviation in pH_i from control conditions, with the exception of 0.35-Hz stimulation intensity (Table 2). A representative summed spectrum from one animal during steady-state contraction at 0.5-Hz intensity (spectra 13–18) is shown in Fig. 4, C and D, for control and DCA conditions, respectively. Figure 4E depicts a difference spectrum computed by subtracting the control spectrum (Fig. 4C) from that of the DCA treated condition (Fig. 4D), showing the differences in phosphorus metabolite peak areas. This resulted in residual areas for PCr and P_i indicating elevated PCr and reduced P_i with DCA compared with control stimulation within the same animal at the same intensity.

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Fig. 4.

Phosphocreatine (PCr) content expressed as % of initial resting values and steady-state ³¹P nuclear magnetic resonance spectrum during 0.5-Hz stimulation before and after dichloroacetate (DCA) treatment in 1 animal. A: control PCr content during 0.5-Hz stimulation and recovery. B: PCr content during 0.5-Hz stimulation and recovery after DCA administration. Dashed line indicates control steady-state PCr content at the end of the stimulation, taken as the average PCr content in the last 6 spectra during stimulation. Linear regression fits of the initial rate of PCr hydrolysis were used to determine the ATP hydrolysis rate (J_ATPase) during muscle stimulation. Time constant of PCr recovery (τ^PCr) was calculated by fitting normalized PCr spectral area to a monoexponential function by an iterative least squares algorithm. C: summed steady-state ³¹P nuclear magnetic resonance (NMR) spectrum of the last 6 spectra acquired during 0.5-Hz stimulation in the control condition. D: summed steady-state ³¹P NMR spectrum of the last 6 spectra acquired during 0.5-Hz stimulation after DCA treatment. E: difference spectrum: DCA − control spectrum. Intensity adjusted to 4 times that of C and D. P_i, inorganic phosphate.

At intensities below the reported aerobic threshold for rat hindlimb muscles (25) (0.35 Hz, 0.5 Hz, 0.75 Hz) PDH activation with DCA resulted in significantly higher steady-state PCr levels relative to the comparable control condition within the same animal (Fig. 5). This effect was lost with stimulation at intensities of 1.0 Hz and 2.0 Hz, with no discernible differences in the observed steady-state energetics. Increased PCr levels at each stimulation frequency were associated with equivalent decreases in P_i levels as illustrated in Fig. 6A. The plot of P_i against PCr shows a linear relationship with a slope of −1.0 P_i/PCr (R²=0.97), indicating a 1:1 stoichiometric balance between PCr reduction and P_i increase, validating the in vivo quantification of these metabolites. Figure 6, B and C, shows P_i and calculated free ADP levels against J_ATPase showing distinct reductions in P_i and ADP in DCA-treated contraction frequencies compared with controls.

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Fig. 5.

Steady-state phosphocreatine (PCr) expressed as % of initial resting values before and after dichloroacetate (DCA) treatment. PCr peak areas of the last 6 spectra during gastrocnemius muscle stimulation were averaged and normalized to the average PCr peak area of the first 6 spectra acquired in the gastrocnemius muscle at rest. Values are means±SE. *Significantly different from control (P < 0.05) of the same stimulation intensity by 2-tailed paired Student’s t-test.

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Fig. 6.

Steady-state phosphorus metabolites during contraction at 0.35 Hz, 0.5 Hz, 0.75 Hz, and 1.0 Hz before and after dichloroacetate (DCA) treatment. A: reciprocal relationship between steady-state inorganic phosphate (P_i) and phosphocreatine (PCr) during contraction. Linear regression was fit to group data, as there is no significant difference in slope between conditions. B: steady-state P_i content as a function of cytosolic ATP hydrolysis rate (J_ATPase). C: steady-state ADP content calculated from the creatine kinase equilibrium reaction as a function of J_ATPase. Linear regressions fit to initial linear portion of the data that include the first 3 points from 0.35 Hz, 0.5 Hz, and 0.75 Hz data.