Gender differences in substrate utilization during submaximal exercise in endurance-trained subjects

Carsten Roepstorff1, Charlotte H. Steffensen1, Marianne Madsen1, Bente Stallknecht2, Inge-Lis Kanstrup3, Erik A. Richter1, and Bente Kiens1

Departments of 1 Human Physiology and 2 Medical Physiology, Copenhagen Muscle Research Centre, University of Copenhagen; and 3 Department of Clinical Physiology and Nuclear Medicine, Herlev Hospital, DK-2100 Copenhagen, Denmark


    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Substrate utilization across the leg during 90 min of bicycle exercise at 58% of peak oxygen uptake (VO2 peak) was studied in seven endurance-trained males and seven endurance-trained, eumenorrheic females by applying arteriovenous catheterization, stable isotopes, and muscle biopsies. The female and male groups were matched according to VO2 peak per kilogram of lean body mass, physical activity level, and training history of the subjects. All subjects consumed the same diet, well controlled in terms of nutrient composition as well as energy content, for 8 days preceding the experiment, and all females were tested in the midfollicular phase of the menstrual cycle. During exercise, respiratory exchange ratio (RER) and leg respiratory quotient (RQ) were similar in females and males. Myocellular triacylglycerol (TG) degradation was negligible in males but amounted to 12.4 ± 3.2 mmol/kg dry wt in females and corresponded to 25.0 ± 6.0 and 5.0 ± 7.3% of total oxygen uptake in females and males, respectively (P < 0.05). Utilization of plasma fatty acids (12.0 ± 2.5 and 9.6 ± 1.5%), blood glucose (13.6 ± 1.5 and 14.3 ± 1.5%), and glycogen (48.5 ± 4.9 and 42.8 ± 2.1%) were similar in females and males. Thus, in females, measured substrate oxidation accounted for 99% of the leg oxygen uptake, whereas in males 28% of leg oxygen uptake was unaccounted for in terms of measured oxidized lipid substrates. These findings may indicate that males utilized additional lipid sources, presumably very low density lipoprotein-TG or TG located between muscle fibers. On the basis of RER and leg RQ, it is concluded that no gender difference existed in the relative contribution from carbohydrate and lipids to the oxidative metabolism across the leg during submaximal exercise at the same relative workload. However, an effect of gender appears to occur in the utilization of the different lipid sources.

[13C]palmitate; plasma fatty acids; myocellular triacylglycerol; glucose; glycogen


    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

RECENTLY, IT HAS BEEN INVESTIGATED in several studies whether a gender difference exists in the relative utilization of carbohydrates and lipids as fuel sources during submaximal exercise. Some studies have shown that females derive a relatively larger contribution from lipids to oxidative metabolism during exercise than males (6, 11, 19, 36). However, others have observed a similar relative utilization of carbohydrates and lipids in females and males exercising at the same relative workload (3, 17, 26).

The relative contribution from carbohydrates and lipids as fuel during submaximal exercise is a result of the sum of utilization of the different carbohydrates (blood glucose and muscle glycogen) and lipids [albumin-bound long-chain fatty acids (FA) from the blood plasma, FA from circulating very low density lipoprotein-triacylglycerols (VLDL-TG), and FA from myocellular triacylglycerols (MCTG)]. It has previously been observed in a few studies that females and males have a similar systemic turnover of plasma FA during exercise expressed relative to body mass (BM) (3, 7) or lean body mass (LBM) (26). Furthermore, Friedlander et al. (7) found that systemic plasma FA oxidation during exercise did not differ between untrained females and males. It has also previously been observed that systemic turnover of glucose was similar in females and males during submaximal exercise at the same relative workload (6, 17, 26).

The study of substrate utilization locally in the active muscles provides a much more detailed picture than whole body measurements, which do not reflect metabolism only in skeletal muscle. Recently, Burguera et al. (3) observed that plasma FA total uptake and release across the leg were similar in untrained females and males during bicycle exercise at 45% of peak oxygen uptake (VO2 peak). However, whether this gender similarity exists at a higher relative workload and/or in trained individuals is not known. Furthermore, the oxidation of plasma FA in the exercising leg has not yet been compared in females and males.

So far, the three methods most often applied to quantify the respective utilization of blood glucose, glycogen, plasma FA, VLDL-TG, and MCTG during exercise are the muscle biopsy technique, the stable isotope tracer technique, and net balances across the active muscle tissue bed, respectively. However, up to now, the relative utilization of these energy sources during exercise has not been determined by applying the three mentioned methods simultaneously in a single gender comparative study. Particularly, gender comparisons of net balances across the active muscles are lacking. Such studies would be expected to yield valuable information on possible gender differences in substrate utilization during exercise.

Therefore, the purpose of the present study was specifically to determine the utilization of blood glucose, glycogen, plasma FA, and MCTG, when applying simultaneously the muscle biopsy technique, the stable isotope tracer technique, and net balances across the active muscles.


    MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

From screening of 48 young endurance-trained females and males, seven females and seven males were recruited to participate in the study (Table 1) on the basis of the training and oxidative capacity criteria given in Prescreening that all females were eumenorrheic with a cycle length between 28 and 35 days and that none of them were taking oral contraceptives. Preliminary tests and the main exercise experiment in females were carried out in the midfollicular phase of their menstrual cycle [determined as days 7-11 from onset of menstruation, mean day 9 ± 1 (mean ± SE) for the exercise experiment].

                              
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Table 1.   Subject characteristics

All subjects were fully informed of the risks associated with the study, and all of them gave written, informed consent. The study was approved by the Copenhagen Ethics Committee and was carried out in accordance with the Declaration of Helsinki II.

Experimental Design

Prescreening. VO2 peak was initially determined in an incremental bicycle exercise test, where respiratory measurements were carried out with the Douglas bag technique. Training history and present weekly training were determined from self-reports (questionnaire and activity record). Furthermore, body composition was calculated from body density (31) determined by hydrostatic weighing with a correction for residual lung volume measured by the oxygen dilution method (16). Single-leg composition was determined by means of dual-energy X-ray absorptiometry (Lunar, Madison DPX-IQ version 4.6.6) from a whole body scan by a pelvis cut angled through the femoral necks according to the manufacturer's directions (Table 1).

Only subjects engaged in endurance-type physical training for a minimum of 5-7 h/wk for >= 2 yr were enrolled in the study. Furthermore, a VO2 peak >55 ml · kg BM-1 · min-1 and >60 ml · kg BM-1 · min-1 was required for females and males, respectively. The male group was matched to the female group according to their VO2 peak/LBM and training history (Table 1).

Dietary control. When enrolled in the study, all subjects recorded their food intake by weighing on 5 nonconsecutive days (consisting of 1 day without training, 1 day with heavy training, 1 weekend day, and 2 weekdays with normal training) to determine the amount of energy and the nutrient composition of their habitual diet. Food records were analyzed using a computer program (Dankost 2000, Danish Catering Center, Copenhagen, Denmark). On the basis of these individual food records, subjects consumed a controlled, isocaloric diet during the 8 days preceding the exercise experiment. The diet consisted of ~15 energy percent (E%) protein, ~20 E% fat, and ~65 E% carbohydrate. This nutrient composition was similar to the habitual diet of the subjects. Food items with a high ratio of 13C to 12C were avoided in the controlled diet to keep the background enrichment of 13CO2 in breath and blood as low as possible during the exercise experiment. During the 8 days, all food intake was strictly controlled, and all food was weighed to an accuracy of 1 g and registered in a dietary record. Throughout the 8 days, adherence to the diet was evidenced by the close resemblence between the prescribed dietary content and the actual intake.

Exercise experimental protocol. The exercise test consisted of bicycling on a Krogh bicycle ergometer for 90 min at 58% VO2 peak.

On the morning of the exercise experiment, subjects arrived at the laboratory at 8:00 AM by either bus, train, or car after an overnight fast from 11:30 PM the night before. Furthermore, the subjects had abstained from exercise training during the 2 days preceding the exercise experiment. After 30 min of rest in the supine position, Teflon catheters were inserted under local anesthesia into the femoral artery and the contralateral femoral vein by use of aseptic techniques. The tips of the catheters were advanced proximally to ~2 cm above and below the inguinal ligament, respectively. A thermistor probe (Edslab T.D. Probe 94-030-2.5F, Baxter Healthcare, Deerfield, IL), for measurement of venous blood temperature, was inserted through the femoral venous catheter and advanced 8 cm proximal to the catheter tip. A venous catheter was inserted into an antecubital vein in each arm for infusion of [6,6-2H2]glucose and [U-13C]palmitate.

Thereafter, the subjects rested for ~60 min in the supine position. Then, arterial and venous resting blood samples were obtained simultaneously for determination of background enrichments of the isotopes. Expired air was collected in Douglas bags. Then, a muscle biopsy was obtained from vastus lateralis muscle under local anesthesia with the needle introduced in a distal angle.

With the subjects still in the supine position, infusion of stable isotopes was initiated and continued during the following 90 min at rest. After a primer infusion of [6,6-2H2]glucose (3.203 mg/kg BM) and NaH[13C]O3 (0.085 mg/kg BM) into the antecubital vein of one arm, within 1 min, constant infusions of [U-13C]palmitate (0.011 µmol · kg BM-1 · min-1) and [6,6-2H2]glucose (0.055 mg · kg BM-1 · min-1) into the antecubital veins of contralateral arms were initiated using calibrated syringe pumps (Harvard Apparatus, Plymouth Meeting, PA, and VIAL Médical SE 200 B, St. Etienne, France). [6,6-2H2]glucose and NaH[13C]O3 infusates were passed through a 0.22-µm sterile filter (Millex-Or, Millipore, Molsheim, France) before infusion, whereas [U-13C]palmitate was not, because of the preparation described below.

During the last 10 min of the infusion period at rest, femoral venous blood flow was measured by the thermodilution method with bolus injections of 5 ml of ice-cold sterile saline (1). Furthermore, expired air was collected in Douglas bags, and blood samples were obtained twice at 5-min intervals for determination of basal isotope enrichment in blood and expiratory air as well as for determination of basal resting blood concentrations. To avoid dehydration during the rather long preexercise resting and exercising periods, a slow intravenous saline drip was started at the same time that the infusion of stable isotopes was initiated. During the experiment, a total of ~800 ml of isotonic saline was administered.

The subjects commenced a 90-min bicycle exercise test on a Krogh bicycle ergometer at a workload corresponding to 58% VO2 peak. Males and females exercised at the same relative workload. Infusion of stable isotopes was continued during the exercise period, with the infusion rate of [6,6-2H2] glucose doubled, whereas the infusion rate of [U-13C] palmitate remained unchanged compared with that at rest. Blood was sampled simultaneously from the femoral artery and vein at 15, 30, 60, 75, and 90 min of exercise. Femoral venous blood flow was determined immediately before each blood sampling by means of a constant infusion of ice-cold saline in accordance with the thermodilution method (1, 12). Expiratory air was collected in Douglas bags before each measurement of femoral venous blood flow. Heart rate was monitored and registered continuously with a Polar Vantage XL heart rate monitor (Polar Electro KY, Kempele, Finland). Blood pressure was measured through the femoral arterial catheter connected to a pressure transducer (Statham P23XL, Spectramed, Oxnard, CA). During exercise, water was offered ad libitum.

At termination of exercise, another muscle biopsy was obtained from the vastus lateralis through the same incision as the first biopsy but with the needle directed in a proximal angle.

Methods

Breath samples. Expired volumes of air from the Douglas bags were measured with a chain-suspended Collins spirometer, and a small sample of mixed expiratory air was analyzed for O2 (Servomex S-3A) and CO2 (Beckman LB2). Furthermore, samples of mixed expiratory air from the Douglas bags were collected into 10-ml evacuated glass tubes (Vacutainer, Becton-Dickinson, Meylan, France) for subsequent determination of the enrichment of 13CO2 in the expiratory air.

Muscle biopsies. The biopsy was freed from all visible blood and fat, rapidly frozen in liquid nitrogen, and stored at -80°C for subsequent biochemical analysis. Before analysis, the muscle tissue was freeze-dried and dissected free of all visible adipose tissue, connective tissue, and blood under a microscope. The dissected muscle fibers were pooled and then divided into subpools for determination of MCTG and glycogen concentrations. The glycogen concentration was determined by a fluorometric method (15), and the concentration of MCTG was determined according to Kiens and Richter (13).

Blood samples. Blood hemoglobin, O2 saturation, PO2, PCO2, and pH were determined by means of a blood gas analyzer (ABL510, Radiometer Medical, Copenhagen, Denmark). From these values, the hematocrit (Hct) and the blood O2 and CO2 concentrations were calculated according to equations provided by Siggaard-Andersen et al. (30). Blood glucose and lactate concentrations were measured on a glucose analyzer (YSI model 2300 Stat Plus, Yellow Springs Instrument, Yellow Springs, OH). Plasma FA concentration was measured by a colorimetric commercial assay kit (Wako Chemicals, Neuss, Germany) which was performed by a COBAS FARA autoanalyzer (COBAS FARA 2, Roche Diagnostic, Basel, Switzerland). Concentrations of insulin (Pharmacia Insulin Radioimmunoassay 100, Pharmacia & Upjohn Diagnostics, Uppsala, Sweden) as well as epinephrine and norepinephrine (KatCombi Radioimmunoassay, Immuno-Biological Laboratories, Hamburg, Germany) in plasma were determined by radioimmunoassay.

Isotope analyses. [U-13C]palmitate (98% enriched), NaH[13C]O3 (99% enriched), and [6,6-2H2]D-glucose (99% enriched) were purchased from Cambridge Isotope Laboratories, Andover, MA. On the day of the exercise experiment, the palmitate tracer in solution was added to methanolic potassium hydroxide to form the potassium salt, dried under nitrogen, redissolved in sterile water at 60°C, passed through a 0.22-µm sterile filter (Millex-Or), and added, and thereby complexed, to sterile 20% (wt/vol) human albumin (State Serum Institute, Copenhagen, Denmark).

Enrichments of 13CO2 in expiratory air samples and blood samples were determined by gas chromatography-isotope ratio mass spectrometry (GC-IRMS; Deltaplus, Finnigan MAT, Bremen, Germany). Before injection into the GC, samples were brought to pressure with pure helium, and phosphoric acid was added to the blood samples to release CO2 in gaseous form. Each injection introduced 20 µl of samples into the column in split mode (split ratio 1:2 for breath and 1:5 for blood samples). A fused silica 25 m × 0.32 mm CP-Poraplot Q column (Chrompack, VARIAN, Analytical Instruments, Værløse, Denmark) was used for chromatography. A deactivated, fused silica 5 m × 0.32 mm column coated with cyanophenylmethyl (Chrompack, VARIAN) was used as a postcolumn. Helium was the carrier gas at 1.8 ml/min. Injector and oven temperatures were set at 35 and 30°C, respectively.

Derivatization of palmitate to its methyl ester was modified from the method described by Patterson et al. (21). Briefly, heptadecanoic acid was added to plasma samples or blanks and mixed for 10 min. Precipitation of proteins was carried out by adding ice-cold acetone, mixing for 1 min, placing at -20°C for 15 min, and centrifuging. After centrifugation, the supernatant was transferred to a new tube. After H2O and hexane were added, mixed for 15 min, and centrifuged, the supernatant was transferred to a new tube, and samples were evaporated under nitrogen. To form FA methyl esters, buffer and iodomethane were added, samples were mixed for 10 min, hexane was added, and samples were mixed for 15 min and centrifuged. The supernatant was transferred to a new tube and evaporated under nitrogen. To separate FA methyl esters by solid phase extraction (SPE) chromatography, hexane was added to the dried samples, mixed for 2 min, and transferred to SPE tubes (Supelclean LC/SI, 3-ml tubes, Supelco, Bellefonte, PA) previously washed twice with hexane. SPE tubes were rinsed with hexane, and FA methyl esters were eluted with two rinses of 3% ethyl acetate in hexane and collected into a new tube. Finally, samples were evaporated under nitrogen, and hexane was added before transfer to GC vials.

The enrichment of [U-13C]palmitate was measured by gas chromatography-combustion-isotope ratio mass spectrometry (GC-C-IRMS; Hewlett-Packard 5890, Palo Alto, CA, and GC Combustion III/Deltaplus, Finnigan MAT) on the methyl ester derivatives. A 30 m × 0.32 mm ID column coated with 0.2 µm of 10% cyanopropylyl-90% biscyanopropylyl polysiloxane (Rtx 2330, Restek, Bellefonte, PA) was used for chromatography. A deactivated fused silica 5 m × 0.32 mm column coated with cyanophenylmethyl (Chrompack, VARIAN) was used as a precolumn. Injection of samples (2 µl) into the column occurred by large-volume injection (programmed temperature vaporization). Helium was the carrier gas at 1.8 ml/min. Temperatures were set at the following: injector, initially 50°C, stayed for 1 min, increased to 285°C at 20°C/min, and stayed for 5 min; oven, initially 50°C, stayed for 4 min, increased to 150°C at 10°C/min, increased to 160°C at 2°C/min, increased to 250°C at 20°C/min, and stayed for 10 min; oxidation reactor, 960°C; reduction reactor, 650°C.

For determination of 13CO2 enrichment, a CO2 gas with known 13CO2 enrichment was used as a reference gas. Based on this reference gas, the enrichment of 13CO2 was obtained as a delta -value with reference to the enrichment of 13CO2 in Pee Dee Belemnite limestone. From the delta -value, the ratio between 13CO2 and 12CO2 was calculated for every sample.

Plasma palmitate concentrations were determined by GC (AutoSystem XL, Perkin-Elmer, Wellesley, MA) on the methyl ester derivatives by using heptadecanoic acid as an internal standard. Each injection introduced 2 µl of samples into the column in split mode (split ratio 1:5). A 30 m × 0.32 mm ID column coated with 0.2 µm 10% cyanopropylyl-90% biscyanopropylyl polysiloxane (Rtx 2330) was used for chromatography. A fused silica 5 m × 0.32 mm column coated with deactivated cyanophenylmethyl (Chrompack, VARIAN) was used as a precolumn. Helium was the carrier gas at 1.8 ml/min. Temperatures were set at the following: injector, 300°C; oven, initially 50°C, stayed for 4 min, increased to 130°C at 10°C/min, increased to 160°C at 4°C/min, and then increased to 250°C at 20°C and stayed for 10 min.

Derivatization of glucose to its butylboronic acid acetate derivative was modified from Pickert et al. (24). Briefly, precipitation of proteins was carried out by adding a methanol-chloroform solution (2.3:1 vol/vol) to the plasma samples, centrifuging, and transferring the supernatant to a new tube. Lipids were then removed by adding chloroform and H2O at pH 2.0, centrifuging, and transferring the supernatant to a new tube. After being frozen at -70°C in liquid nitrogen and vacuum centrifuged in a SpeedVac centrifugal concentrator (MAXI dry lyo F.D. 1.0, Heto-Holten, Allerød, Denmark), the extracted glucose was derivatized by adding butylboronic acid in pyridine and nitrogen gas, heating, and finally adding acetic anhydride and nitrogen gas. After 90 min of reaction at 25°C, the liquid was transferred to a new tube, evaporated to dryness with nitrogen, redissolved in ethyl acetate, and transferred to a GC vial.

The enrichment of [6,6-2H2]glucose was determined by GC-MS (Finnigan Trace GC 2000 - Automass III) on the butylboronic acid acetate derivative. A fused silica 30 m × 0.25 mm ID CP-Sil 8 CB low bleed/MS column (Chrompack, VARIAN) was used for chromatography. A deactivated fused silica 5 m × 0.32 mm column coated with cyanophenylmethyl (Chrompack, VARIAN) was used as a precolumn. Injection of samples (2 µl) into the column occurred by large volume injection (programmed temperature vaporization). Helium was the carrier gas at 1.8 ml/min. Temperatures were set at the following: injector, initially 60°C, stayed for 1 min, increased to 285°C at 60°C/min, and stayed; oven, initially 105°C, stayed for 6.5 min, increased to 206°C at 25°C/min, increased to 207°C at 0.2°C/min, increased to 300°C at 25°C/min, and stayed for 5 min. Ions of mass-to-charge ratio (m/z) 296-304 were monitored on the mass spectrometer in profile mode.

Before the analyses of palmitate concentration and [6,6-2H2]glucose enrichment were carried out, systems were calibrated with a series of standards containing known amounts of palmitate or known enrichments of [6,6-2H2]glucose. Regression analysis was performed on the observed concentrations and enrichments vs. the actual concentrations and enrichments of the standards. The slope was used to correct the raw concentration and enrichment data of plasma samples.

Calculations

Plasma FA and glucose kinetics. Enrichments are reported in units of tracer-to-tracee ratio (TTR), which is defined as TTR = ratiosa - ratiobk, where sa is sample and bk is background sample. At rest, systemic rates of appearance (Ra) and disappearance (Rd) were calculated using steady-state equations (39). Non-steady-state equations modified for use with stable isotopes were applied during exercise (25). The effective volume of distribution was assumed to be 40 ml/kg BM for palmitate and 165 ml/kg BM for glucose (25). For glucose, however, it did not affect the results whether a distribution volume of 40, 100, or 165 ml/kg BM was applied. Across the exercising leg, palmitate uptake and release were calculated using the following equations provided by Wolfe (39)
leg palmitate uptake<IT>=</IT><FR><NU>E<SUB>A</SUB>[A]<IT>−</IT>E<SUB>V</SUB>[V]</NU><DE>E<SUB>A</SUB>[A]</DE></FR> [A]<IT>·</IT>PF

leg palmitate release<IT>=</IT>leg palmitate uptake

<IT>−</IT>([A]<IT>−</IT>[V])<IT>·</IT>PF
where EA and EV are the enrichments of [U-13C]palmitate in the plasma of the femoral artery and vein, respectively, [A] and [V] are the plasma concentrations of palmitate in the femoral artery and vein, respectively, and PF is femoral venous plasma flow. Systemic and leg palmitate oxidation during exercise were calculated using the following equations provided by Wolfe (39)
systemic palmitate oxidation<IT>=</IT><FR><NU>E<SUB>CO<SUB>2</SUB></SUB><IT>·</IT><A><AC>V</AC><AC>˙</AC></A><SUB>CO<SUB>2</SUB></SUB></NU><DE>E<SUB>V</SUB><IT>·</IT>c<IT>·</IT>16</DE></FR>

leg palmitate oxidation<IT>=</IT><FR><NU>[<SUP>13</SUP>CO<SUB>2</SUB>]<SUB>V</SUB><IT>−</IT>[<SUP>13</SUP>CO<SUB>2</SUB>]<SUB>A</SUB></NU><DE>E<SUB>V</SUB><IT>·</IT>c<IT>·</IT>16</DE></FR><IT>·</IT>BF
where ECO2 is the enrichment of 13CO2 in the expiratory air and VCO2 is the excretion of CO2 in breath. EV is the enrichment of [U-13C]palmitate in the plasma of the femoral vein, and the factor 16 accounts for the fact that oxidation of 1 mol of palmitate results in 16 mol of CO2. [13CO2]A and [13CO2]V are the blood concentrations of 13CO2 in the femoral artery and vein, calculated as the enrichment of 13CO2 times the blood concentration of CO2, BF is femoral venous blood flow, and c is the acetate correction factor. FA kinetics were calculated as the palmitate kinetics divided by the ratio between the plasma palmitate concentration and the plasma FA concentration.

Background correction. Enrichments of 13CO2 in breath and blood during exercise were corrected for the increase in background enrichment after initiation of exercise observed during background experiments in three subjects. No increase in background enrichment at initiation of exercise was observed for [U-13C]palmitate and [6,6-2H2]glucose.

Acetate correction factor. The acetate correction factor c was applied when calculating plasma FA oxidation rates systemically as well as across the exercising leg to account for the amount of 13CO2 label from [U-13C]palmitate lost by fixation at any step between the entrance of labeled acetyl-CoA into the tricarboxylic acid cycle and recovery in the breath or venous blood, respectively, despite complete oxidation of [U-13C]palmitate (37). A correction factor of 0.23 at rest and 0.91 during exercise was applied in the calculation of palmitate oxidation rates. The values of this factor were based on studies by Schrauwen and colleagues (27, 28) and a study by Van Loon et al. (38), where the acetate correction factor was determined in endurance-trained males bicycling at the same relative and absolute workload as the males in the present study. In one of the studies by Schrauwen et al. (28), it was shown that 13CO2 label recovery was practically similar in females and males at rest, whereas males had a slightly higher recovery of 13CO2 label than females during bicycle exercise at 40-50% VO2 peak. However, this gender difference disappeared when correction was made for oxygen uptake/LBM and respiratory exchange ratio (RER) (28). In the present study, oxygen uptake/LBM and RER were similar in females and males during exercise, indicating that, presumably, no gender difference existed in 13CO2 label recovery during exercise. Therefore, we applied identical acetate correction factors in females and males.

Indirect calorimetry. The relative contributions from fat and carbohydrate to the systemic oxidative metabolism (in percentages of total oxygen uptake) were estimated from the RER, on the assumption that RER reflected the systemic nonprotein respiratory quotient (RQ). The following equations were used, modified from Ref. 6
RER<IT>=</IT><FR><NU><A><AC>V</AC><AC>˙</AC></A><SC>co</SC><SUB>2</SUB></NU><DE><A><AC>V</AC><AC>˙</AC></A><SC>o</SC><SUB>2</SUB></DE></FR>

% carbohydrate in <A><AC>V</AC><AC>˙</AC></A><SC>o</SC><SUB>2</SUB><IT>=</IT><FR><NU>RER<IT>−</IT>0.70</NU><DE>0.30</DE></FR><IT>·</IT>100<IT>%</IT>

% lipid in <A><AC>V</AC><AC>˙</AC></A><SC>o</SC><SUB>2</SUB><IT>=</IT>100<IT>−% </IT>carbohydrate in <A><AC>V</AC><AC>˙</AC></A><SC>o</SC><SUB>2</SUB>
An estimation of the contribution from the main energy sources (glucose, glycogen, plasma FA, and MCTG) to the oxidative metabolism across the exercising leg was made according to the method previously described by Kiens et al. (12). In this calculation, the aforementioned equations were used to estimate the relative contributions from carbohydrates and lipids to the oxidative metabolism across the leg with RER substituted by leg RQ, where leg RQ was calculated as
leg RQ<IT>=</IT><FR><NU>[CO<SUB>2</SUB>]<SUB>Venousblood</SUB><IT>−</IT>[CO<SUB>2</SUB>]<SUB>Arterialblood</SUB></NU><DE>[O<SUB>2</SUB>]<SUB>Arterialblood</SUB><IT>−</IT>[O<SUB>2</SUB>]<SUB>Venousblood</SUB></DE></FR>
where [CO2] and [O2] are the concentrations of CO2 and O2, respectively.

Statistics

Data are presented as means ± SE unless otherwise stated. For variables independent of time, an unpaired t-test was performed to test for differences between genders. In a few cases, data suitable for an unpaired t-test were not distributed normally, and a Mann-Whitney rank-sum test was run instead. For variables measured before and after exercise as well as variables measured before and during exercise, a two-way analysis of variance (ANOVA), with repeated measures for the time factor, was performed to test for differences between genders or changes due to time. When a significant main effect of time was found, significant pairwise differences were performed using Tukey's post hoc test. In all cases, a probability of 0.05 was used as the level of significance.


    RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Workload

Females as well as males completed the 90-min bicycle exercise test at a workload averaging 58 ± 1% VO2 peak. The workload expressed relative to LBM averaged 41.5 ± 1.5 and 41.7 ± 0.8 ml O2 · kg LBM-1 · min-1 in females and males, respectively [not significant (NS)]. The average absolute workload was 170 ± 6 W in females and 196 ± 6 W in males (P < 0.01).

Respiratory and Cardiovascular Parameters

Resting femoral venous blood flow was 0.22 ± 0.02 and 0.32 ± 0.05 l/min in females and males, respectively (NS). During exercise, a constant blood flow was observed in the female subjects (averaging 5.6 ± 0.2 l/min). On the other hand, in the male subjects, femoral venous blood flow increased (P < 0.01) continuously from 15 min (5.9 ± 0.2 l/min) to 60 min (6.5 ± 0.3), after which it leveled off (averaging 6.3 ± 0.3 l/min during the last 30 min of exercise). During exercise, a main effect of gender was observed (P < 0.05).

No measurable differences in the Hct of femoral arterial and venous blood were observed at rest or during exercise (P > 0.05). At rest, the Hct was 39 ± 1 and 43 ± 1% in females and males, respectively. After 15 min of exercise, an increase (P < 0.001) in Hct was observed to 42 ± 1% in females and 47 ± 1% in males, whereafter Hct decreased slightly but significantly (P < 0.001) to 40 ± 1 and 44 ± 1% at 90 min of exercise in females and males, respectively. A main effect of gender was observed in Hct (P < 0.05).

Resting oxygen uptake across the leg was 13 ± 2 and 20 ± 4 ml/min in females and males, respectively (NS). During exercise, leg oxygen uptake was constant in both groups, averaging 838 ± 48 ml/min and 999 ± 39 ml/min in females and males, respectively (P < 0.05).

Leg RQ increased at initiation of exercise from 0.79 ± 0.01 and 0.80 ± 0.01 at rest to 0.91 ± 0.02 and 0.89 ± 0.02 at 15 min of exercise in females and males, respectively. During the 1st h of exercise, leg RQ was constant, averaging 0.90 ± 0.02 and 0.88 ± 0.02 in females and males, respectively, but then decreased (P < 0.01) to 0.87 ± 0.02 and 0.82 ± 0.01 at 90 min in females and males, respectively. No gender differences were observed in leg RQ (NS).

At rest, RER was similar in females (0.79 ± 0.02) and males (0.79 ± 0.02) (NS) (Fig. 1). At initiation of exercise, RER increased (P < 0.001) in females as well as in males and did not change during the 1st h of exercise (averaging 0.89 ± 0.02 and 0.91 ± 0.01 in females and males, respectively). However, from 60 to 90 min, RER decreased significantly to 0.87 ± 0.02 in females and 0.88 ± 0.01 in males. No gender difference was observed in RER during exercise at any time point (NS).


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Fig. 1.   Respiratory exchange ratio (RER). §Different from exercise, P < 0.001; dagger different from 15, 30, and 60 min, P < 0.05.

Metabolite Concentrations

The arterial concentrations of blood glucose, plasma FA, and glycerol are shown in Fig. 2. After an increase (P < 0.001) in arterial blood glucose concentration (Fig. 2A) at initiation of exercise, it did not change significantly from 15 to 30 min. During the next 30 min, arterial glucose concentration decreased (P < 0.05) to a lower level, which was maintained throughout exercise.


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Fig. 2.   Arterial concentrations (conc.) of glucose, plasma fatty acid (FA), and glycerol. A: arterial blood glucose concentration. Different from 15 min, dagger dagger P < 0.01; dagger dagger dagger P < 0.001; different from 30 min, Dagger P < 0.05; Dagger Dagger P < 0.01; Dagger Dagger Dagger P < 0.001. B: arterial plasma FA concentration. §Different in males from 15 (P < 0.05) and 90 min (P < 0.01); different in males from 15 min, dagger P < 0.05; dagger dagger P < 0.01; Dagger different in males from 15, 30, and 60 min, P < 0.001. C: arterial plasma glycerol concentration. Different from previous time point, dagger P < 0.05; dagger dagger P < 0.01; dagger dagger dagger P < 0.001; Dagger different from 30 min, P < 0.001.

During the first 15 min of exercise, arterial plasma FA concentration decreased in males (P < 0.05) but not in females (NS) (Fig. 2B). Then, it increased (P < 0.01) continuously until the end of exercise in males, whereas a borderline significant increase (P = 0.06) was observed in females.

At initiation of exercise, an increase (P < 0.001) was observed in arterial plasma glycerol concentration (Fig. 2C), followed by a further significant increase throughout exercise.

The arterial blood lactate concentration averaged 0.5 ± 0.1 mM at rest in both groups. During exercise, small increases to a maximum value of 1.1 ± 0.2 mM after 15 min were observed in both groups.

There were no significant gender differences in arterial glucose, plasma FA, glycerol, or lactate concentrations during exercise.

Glucose Kinetics

The enrichment of [6,6-2H2]glucose in arterial plasma is shown in Fig. 3A. The [6,6-2H2]glucose enrichment did not change significantly during the first 75 min of exercise, whereafter it decreased from 75 to 90 min (P < 0.01). Furthermore, a main effect of gender was observed (P < 0.05).


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Fig. 3.   Enrichments of [6,6-2H2]glucose, [U-13C]palmitate, and 13CO2. TTR, tracer-to-tracee ratio. A: arterial enrichment of [6,6-2H2]glucose. *Main effect of gender, P < 0.05; dagger different from 15 min (P < 0.05), 30 min (P < 0.001), and 60 and 75 min (P < 0.01). B: arterial enrichment of [U-13C]palmitate. §Different from exercise, P < 0.001; Dagger different from 15 min, P < 0.01. C: femoral venous enrichment of [U-13C]palmitate. Different from rest and 15 min, dagger dagger P < 0.01; dagger dagger dagger P < 0.001; Dagger different from 30 min (P < 0.001) and 60 min (P < 0.05). D: enrichment of 13CO2 in the expiratory air. Different from previous time point, dagger P < 0.05; dagger dagger P < 0.01; different from 30 min, Dagger Dagger P < 0.01; Dagger Dagger Dagger P < 0.001. E: arterial enrichment of 13CO2. Different from rest and 15 min, dagger dagger P < 0.01; dagger dagger dagger P < 0.001; Dagger different from 30 min, P < 0.05. F: femoral venous enrichment of 13CO2. Different from rest and 15 min, dagger P < 0.05; dagger dagger P < 0.01; dagger dagger dagger P < 0.001.

The systemic glucose Ra and Rd are provided in Table 2 and were similar in females and males at rest (NS), but lower in females than in males during exercise (P < 0.05).

                              
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Table 2.   Systemic blood glucose and plasma FA kinetics at rest and during exercise

At initiation of exercise, the glucose net uptake across the leg (Fig. 4A) increased (P < 0.001). However, throughout exercise, it did not change significantly, averaging 114 ± 24 and 110 ± 21 µmol · kg lean leg mass (LLM)-1 · min-1 during the last hour of exercise in females and males, respectively. No significant gender differences were observed at rest or during exercise.


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Fig. 4.   Glucose and plasma FA net uptake across the leg. LLM, lean leg mass. A: glucose net uptake across the leg. §Different from exercise, P < 0.001. B: plasma FA net uptake across the leg. §Different from exercise, P < 0.001.

Plasma FA Kinetics

The enrichments of [U-13C]palmitate in plasma and 13CO2 in the expiratory air and blood at rest and during exercise are shown in Fig. 3. The only significant changes in the enrichments during the last 60 min of the exercise period occurred in the femoral venous enrichment of [U-13C]palmitate, which decreased slightly from 30 min (P < 0.001) and 60 min (P < 0.05) to 90 min; the enrichment of 13CO2 in the expiratory air, which increased slightly from 30 to 60 min (P < 0.01), 75 min (P < 0.01), and 90 min (P < 0.001); and the femoral arterial enrichment of 13CO2, which increased slightly from 30 to 90 min (P < 0.05). No significant gender differences were observed in the enrichments of [U-13C]palmitate and 13CO2.

The contribution of palmitate to the total plasma FA concentration was similar in arterial and femoral venous blood, averaging 27.8 ± 2.6% in females and 34.5 ± 5.2% in males. The gender difference was not statistically significant.

The systemic plasma FA turnover and oxidation at rest and during the last hour of exercise are shown in Table 2. These kinetic parameters were not significantly different between females and males.

Across the leg, a net release of FA to plasma was observed at rest in females as well as in males (Fig. 4B). From the initiation of exercise, a net uptake of plasma FA was observed across the leg, which did not change significantly throughout exercise, averaging 79 ± 19 µmol/min in females and 158 ± 40 µmol/min in males during the last hour of exercise (P < 0.05). However, when expressed relative to LLM, no significant gender difference was observed in leg plasma FA net uptake (averaging 9.1 ± 2.6 and 14.2 ± 3.8 µmol · kg LLM-1 · min-1 during the last hour of exercise in females and males, respectively, Fig. 4B).

The plasma FA total uptake and oxidation across the active muscles were similar in females and males (NS), whereas females had a higher release of FA to plasma (P < 0.01) (Table 3).

                              
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Table 3.   Plasma FA kinetics across the leg during exercise

Muscle Samples

Muscle tissue samples were obtained from only six of the female subjects. Glycogen concentrations in vastus lateralis muscle before exercise were not significantly different between females and males (Fig. 5A). At termination of exercise, a significant decrease (P < 0.001) in glycogen concentration was observed in both groups. No significant gender difference was observed after exercise, and the glycogen utilization was similar in the two groups (NS).


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Fig. 5.   Glycogen and myocellular triacylglycerol (MCTG) concentrations in vastus lateralis muscle. A: glycogen concentration. dagger Different from before exercise, P < 0.001. B: MCTG concentration. *Gender difference, P < 0.05; dagger different from before exercise, P < 0.01; §gender difference in change from before to after exercise, P < 0.05.

Concentrations of MCTG in vastus lateralis before exercise were higher in females than in males (P < 0.05) (Fig. 5B). At termination of exercise, a decrease (P < 0.01) in MCTG concentration was observed in females; however, no significant change occurred in the males. Thus the change in MCTG concentration during exercise was significantly different between females and males.

Substrate Utilization Across the Leg

On the basis of the substrate utilizations across the leg provided above, relative contributions to the oxidative metabolism across the leg during 90 min of exercise derived from blood glucose, plasma FA, muscle glycogen, and MCTG were estimated (Fig. 6).


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Fig. 6.   Estimated relative contributions to the oxidative metabolism across the leg during 90 min of exercise derived from blood glucose, muscle glycogen, plasma FA, and MCTG. Different from females, *P < 0.05; **P < 0.01.

The active muscle mass in one of the exercising legs was estimated from the decrease in glycogen concentration in vastus lateralis during exercise and the glycogen oxidation during exercise. The glycogen oxidation was calculated as total leg carbohydrate oxidation estimated from indirect calorimetry minus glucose uptake across the leg. The active muscle mass per leg was 3.3 ± 0.3 and 4.3 ± 0.2 kg in females and males, respectively (P < 0.05).

Total oxygen uptake across the leg during exercise was 72.3 ± 4.5 and 87.9 ± 2.9 l O2 in females and males, respectively (P < 0.01). The relative contribution from blood-borne glucose and muscle glycogen, respectively, averaged 13.6 ± 1.5 and 48.5 ± 4.9% in females and 14.3 ± 1.5 and 42.8 ± 2.1% in males. Thus, in females, carbohydrates accounted for 62.1 ± 4.7% of the oxidative metabolism, whereas in males carbohydrates accounted for 57.1 ± 3.3%. Plasma FA (isotopically determined oxidation) and MCTG, respectively, contributed 12.0 ± 2.5 and 25.0 ± 6.0% to the oxidative metabolism in females and 9.6 ± 1.5 and 5.0 ± 7.3% in males. Thus measurable lipid utilization contributed 37.0 ± 6.4 and 14.6 ± 6.7% to the oxidative metabolism in females and males, respectively. The relative contribution from MCTG to the oxidative metabolism as well as the total measurable lipid utilization differed between females and males (P < 0.05 for both). None of the other energy sources differed significantly between females and males in their relative contribution to the oxidative metabolism during the bicycle exercise test.

In females, 0.9 ± 6.1% of the total oxygen consumption across the leg could not be accounted for as measurable substrate utilization. In males, the amount of oxygen that could not be accounted for amounted to 28.3 ± 6.5% of the total oxygen consumption across the leg. Thus the amount of oxygen not accountable for differed between females and males (P < 0.01).

Hormones

At initiation of exercise, the arterial insulin concentration did not change significantly, but it decreased (P < 0.001) continuously from 30 to 90 min of exercise in females as well as in males (Fig. 7A). The arterial epinephrine concentration did not change significantly from rest to exercise, but it increased (P < 0.01) continuously from 30 to 90 min of exercise in both females and males (Fig. 7B). The norepinephrine concentration increased (P < 0.001) from rest to exercise and did not change significantly during the exercise period (Fig. 7C). No gender differences were observed at any of the time points in plasma concentrations of insulin, epinephrine, and norepinephrine (NS).


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Fig. 7.   Arterial plasma concentrations of insulin, epinephrine, and norepinephrine. A: arterial insulin concentration. Different from rest and 30 min, dagger P < 0.05; dagger dagger dagger P < 0.001. B: arterial epinephrine concentration. Different from rest, dagger dagger P < 0.01; dagger dagger dagger P < 0.001; Dagger different from 30 min, P < 0.01. C: arterial norepinephrine concentration. dagger Different from rest, P < 0.001.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present study revealed an equal relative contribution from carbohydrates and lipids as fuel across the leg (as estimated from leg RQ) during submaximal prolonged bicycle exercise at the same relative workload in endurance-trained females and males. However, a marked gender difference in the utilization of the different lipid sources was observed. Thus females degraded MCTG during exercise, whereas males did not. Furthermore, in females, the oxygen uptake across the leg for lipid oxidation was accounted for solely by MCTG and plasma FA oxidation. On the other hand, in males, MCTG and plasma FA oxidation did not cover the total amount of oxygen uptake for lipid oxidation, indicating that males oxidized additional lipid sources. Finally, we observed that females released a significantly higher amount of FA to plasma across the leg during exercise than did the male subjects.

The finding that RER was also similar in females and males is in line with some previous studies (3, 17, 26) but in contrast to others (7, 11, 19, 34, 36), where females utilized more lipids than males during exercise. In the present study, females were all tested in the midfollicular phase of their menstrual cycle, and all subjects ingested a well controlled experimental diet for 8 days before the main exercise experiment. Besides the menstrual status of the females and the dietary status of the subjects, a possible gender difference in the relative oxidation of carbohydrates and lipids might be influenced by the type and intensity of exercise, which differ markedly among some of the previous studies (3, 7, 17, 36).

It might be argued that the lack of a gender difference in the relative contribution from carbohydrates and lipids to the oxidative metabolism in the present study might be ascribed to the relatively small number of subjects. However, we have recently found similar RER during exercise in a larger number of females (n = 20) and males (n = 21), including both trained and untrained subjects (33). Moreover, we have also recently observed that breakdown of MCTG in females is independent of training status (33). Thus the conclusions reached in the present study are not to any major extent dependent on the training status of the subjects.

Lipid Sources Utilized

In the present study, males had a significantly higher net uptake of plasma FA across the leg during exercise than females despite an equal arterial concentration and delivery of plasma FA in females and males. However, when expressed relative to LLM, no gender difference was observed in net plasma FA uptake, indicating that the amount of muscle mass involved during exercise is responsible for plasma FA net uptake. Moreover, we observed that the systemic turnover of plasma FA, determined by tracer technique, was similar in females and males when expressed relative to LBM. The arterial glycerol and FA concentrations, where no gender difference was observed, are also in line with the finding of similar systemic plasma FA turnover in females and males. Expressing systemic plasma FA turnover relative to BM in the present study (data not shown) did not result in a gender difference either, supporting previous studies (3, 7). However, it is probably more correct to express plasma FA turnover relative to LBM to correct for the possible influence of the apparent gender difference in body composition on the turnover of plasma FA. Across the exercising leg, the total uptake and oxidation of plasma FA were similar in females and males, whereas the release of FA to plasma was higher in females than in males. The observation of a partial gender difference in plasma FA kinetics across the exercising leg is in immediate contrast to findings in a recent study by Burguera et al. (3), where the plasma FA total uptake and release across the leg were similar in females and males during exercise. However, there might be no contradiction between the two findings, because in the study by Burguera et al., subjects were untrained and bicycle exercise was performed at 45% VO2 peak, indicating that training status of the subjects and relative workload may influence plasma FA kinetics.

Even though the amount of plasma FA taken up systemically as well as across the leg was in the same range as in previous studies (3, 26), only 32-34% of the systemic plasma FA total uptake occurred across the two legs. This is in accord with previous observations in our laboratory, where 40-50% of the systemic plasma FA total uptake occurred across the legs during the last 30 min of 1-h bicycle exercise at 70% VO2 peak in moderately trained males (10). That such a relatively small fraction of the systemic plasma FA total uptake occurs in the active muscles implies that more than one-half of the systemic plasma FA total uptake would presumably occur in adipose tissue, liver, heart, and accessory as well as in inactive muscles during exercise, which may seem unlikely. At present, we are not able to explain these observations. A possibility to consider is contamination of the sampled femoral venous blood with blood draining tissues other than skeletal muscle, e.g., subcutaneous adipose tissue, which would have a high concentration of FA. Therefore, even if the contamination in terms of blood volume were small compared with the large flow perfusing the active muscles, the femoral venous concentration of FA might be artificially increased. Still, blood from adipose tissue would be expected to have a rather low level of enrichment with [13C]palmitate, since the FA would be derived from intracellular, mainly unlabeled triacylglycerols. Thus the arteriovenous difference of [13C]palmitate would be only slightly underestimated if contamination with blood draining adipose tissue was significant. The effect of such possible contamination on the calculation of plasma FA total uptake is therefore expected to be minor. Furthermore, even if contamination were an issue, it would not to any major extent influence the calculation of leg plasma FA oxidation and consequently the estimation of relative utilization of the different energy sources, because plasma FA oxidation rates across the leg depend primarily on femoral arterial and venous 13CO2 concentrations. The femoral venous 13CO2 concentration would not be expected to be changed much by contamination of small volumes of blood from adipose tissue.

At rest only ~40% of systemic plasma FA total uptake was oxidized in the present study irrespective of gender. This supports previous studies in resting isolated rat muscle that used the pulse-chase technique, where a significant incorporation of exogenous palmitate into MCTG occurred (4, 22). During exercise, however, 86-96% of systemic plasma FA total uptake was oxidized in both females and males according to plasma FA total uptake and oxidation calculated from the tracer technique. This was slightly higher than in previous studies calculating this percentage in moderately trained females (5) and males (18). Across the leg in the present study, 100 and 84% of the plasma FA total uptake was oxidized in females and males, respectively. In the study by Guo et al. (8), the pulse-chase technique was applied to evaluate the kinetics of plasma palmitate after its entrance into the muscle cell. The authors showed that a significant incorporation of plasma palmitate into MCTG in vastus lateralis muscle occurred during exercise at 45% VO2 peak in untrained females and males. The finding of a 100 and 84% oxidation of plasma FA total uptake in the present study, in contrast to the study by Guo et al., might, however, be expected, due to the higher workload in the present study. Furthermore, the higher training level and, consequently, the higher skeletal muscle oxidative capacity of the subjects in the present study compared with that in the study by Guo et al., presumably increase their ability to oxidize a large fraction of the plasma FA taken up into skeletal muscle rather than incorporate plasma FA into MCTG. Therefore, it is not at all unexpected that, during exercise at 58% VO2 peak, a very high fraction of the plasma FA taken up across the leg was oxidized irrespective of gender. Finally, during submaximal exercise, parts of the motor neurons in the leg are inactive; therefore, part of the incorporation of plasma FA into MCTG may occur in nonactive muscle fibers. Obviously, the lower the relative exercise intensity, the higher the proportion of inactive fibers.

In the present study, females had a significantly higher resting concentration of MCTG in vastus lateralis muscle than males, and females utilized significant amounts of MCTG during exercise, whereas males did not. This observation has recently been shown in our laboratory on a larger number of females and males, including both trained and untrained subjects (33). Other studies where the muscle biopsy technique was applied have also shown that males do not utilize MCTG during prolonged submaximal exercise (2, 14, 32). Furthermore, Guo et al. (8) observed no change in MCTG palmitate concentration in vastus lateralis during 90-min bicycle exercise at 45% VO2 peak in untrained females and males. A gender comparison was not made in their study. On the other hand, in a recent study by Romijn et al. (26), the difference between systemic lipid oxidation (determined by indirect calorimetry) and systemic plasma FA total uptake (determined by tracer technique) was similar in females and males during exercise, leading the authors in that study to conclude that, during exercise, no gender difference in whole body MCTG oxidation exists. However, in the present study, the difference between systemic lipid oxidation (averaging 28.7 ± 4.8 and 23.8 ± 2.5 µmol FA equivalents · kg LBM-1 · min-1 during exercise in females and males, respectively) and systemic plasma FA oxidation (averaging 15.1 ± 1.8 and 12.4 ± 3.0 µmol FA equivalents · kg LBM-1 · min-1 during exercise in females and males, respectively) was also similar in females and males [i.e., a difference of 13.6 ± 4.2 µmol FA equivalents · kg LBM-1 · min-1 in females and 11.4 ± 4.7 µmol FA equivalents · kg LBM-1 · min-1 in males (NS)], despite the obvious gender difference in MCTG utilization in vastus lateralis muscle. Therefore, a methodological problem must exist when indirectly estimating whole body MCTG oxidation as the difference between systemic lipid oxidation and systemic plasma FA total uptake or oxidation. As mentioned before, the fact that only one-third of the systemic plasma FA uptake occurred in the legs during exercise further indicates that systemic plasma FA uptake is a poor measure of leg plasma FA metabolism during exercise. Therefore, subtraction of systemic plasma FA turnover from total lipid oxidation cannot be expected to produce a reasonable estimate of MCTG breakdown, in accord with our findings that whole body nonplasma FA oxidation is not equivalent to MCTG utilization. This point of view has been voiced before (2, 10). Thus increasing evidence suggests that the indirect estimation of MCTG utilization by subtraction of systemic plasma FA turnover from total lipid oxidation is not valid.

Carbohydrate Sources

In contrast to previous studies (17, 26), we observed a higher systemic glucose turnover during exercise in endurance-trained males than in endurance-trained females. Furthermore, we observed a generally higher systemic glucose turnover than Romijn et al. (26), despite comparable workloads and training status of the subjects. These discrepancies are difficult to explain. However, from the data presented it is possible to calculate that 93 and 75% of the systemic glucose total uptake occurred across the two legs during exercise in females and males, respectively, indicating that our determination of systemic glucose turnover was not too high compared with the glucose uptake across the legs. Despite the observed gender difference in systemic glucose turnover expressed relative to LBM, we found a similar glucose net uptake across the leg in females and males expressed in absolute terms (data not shown) as well as relative to LLM. This suggests that males might have a higher total uptake of glucose in adipose tissue, liver, heart, brain, or inactive muscles during exercise compared with females.

In the present study, the content of glycogen in vastus lateralis was similar in females and males before exercise. During exercise, the utilization of glycogen in vastus lateralis was also similar in females and males. This is in contrast to the study by Tarnopolsky et al. (36), where the utilization of muscle glycogen in vastus lateralis was higher in males than in females. It should, however, be noted that the study by Tarnopolsky et al., where subjects completed 95 min of treadmill running at 63% VO2 peak, revealed a significantly higher systemic oxidation of total carbohydrate in males than in females, thus differing from the conditions in the present study.

Substrate Utilization Across the Leg

The estimated active muscle mass plays an important role when the total utilization of muscle glycogen and MCTG is calculated. The estimation of active muscle mass is based on the assumptions that the difference in glycogen concentration between the two muscle tissue samples obtained before and after exercise, respectively, is representative of all active leg muscle tissue and that all of the glucose taken up across the leg during exercise is oxidized (12). Therefore, the estimation of active muscle mass is subject to potentially large variation, which might influence the variability especially of the total MCTG utilization and therefore also the amount of oxygen not accountable for as utilized substrate. For instance, an active muscle mass 0.5 kg (12%) higher than originally estimated in the male subjects would change the contributions from blood glucose, glycogen, plasma FA, and MCTG to the oxidative metabolism across the leg to 14, 53, 10, and 6%, respectively, decreasing the percentage of oxygen uptake across the leg not accountable for as substrate utilized from 28 to 17%. Despite these considerations, the MCTG utilization (25.0 ± 6.0 and 5.0 ± 7.3% of total oxygen uptake in females and males, respectively) and the sum of plasma FA and MCTG utilization (37.0 ± 6.4 and 14.6 ± 6.7%) differed significantly between females and males. On the other hand, the utilization of blood glucose (13.6 ± 1.5 and 14.3 ± 1.5%) and glycogen (48.5 ± 4.9 and 42.8 ± 2.1%) was similar in females and males. Finally, a significant gender difference was also observed in the percentage of oxygen uptake across the leg not accountable for as substrate utilized (0.9 ± 6.1 and 28.3 ± 6.5%). It might be speculated that the unaccountable oxygen consumption in males originated from oxidation of VLDL-TG or TG located between the muscle fibers, as has been suggested earlier (9, 12). Furthermore, a contribution from protein to the oxidative metabolism during exercise should not be disregarded (12) and seems to be larger in males than in females (23).

In conclusion, in the present study, the oxidative metabolism during prolonged submaximal exercise was evaluated in endurance-trained males compared with endurance-trained females in their midfollicular phase of the menstrual cycle. Despite similar relative contributions from carbohydrates and lipids to the oxidative metabolism during exercise at the same relative workload in endurance-trained females and males, we observed a gender difference in the relative utilization of the different lipid sources. Thus, although the plasma FA oxidation across the exercising leg was similar in females and males, MCTG was significantly degraded in females but not in males. In females, measured substrate oxidation accounted for 99% of the leg oxygen uptake, whereas in males, 28% of leg oxygen uptake was unaccounted for in terms of measured oxidized lipid substrates. These findings thus may indicate that males utilized a third lipid source, presumably VLDL-TG or TG located between muscle fibers.


    ACKNOWLEDGEMENTS

We are thankful to Gerrit van Hall for support and advice on analysis and calculation of stable isotope tracer data. Furthermore, we acknowledge the skilled technical assistance of Irene Bech Nielsen, Nina Pluszek, Betina Bolmgren, and Winnie Taagerup.


    FOOTNOTES

This study was supported by the Danish National Research Foundation, Grant 504-12, and by the Danish Sports Research Council.

Address for reprint requests and other correspondence: Carsten Roepstorff, Copenhagen Muscle Research Centre, Dept. of Human Physiology, Universitetsparken 13, DK-2100 Copenhagen Ø, Denmark (E-mail: croepstorff{at}ifi.ku.dk).

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.

10.1152/ajpendo.00266.2001

Received 20 June 2001; accepted in final form 5 October 2001.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

1.   Andersen, P, and Saltin B. Maximal perfusion of skeletal muscle in man. J Physiol (Lond) 366: 233-249, 1985[Abstract].

2.   Bergman, BC, Butterfield GE, Wolfel EE, Casazza GA, Lopaschuk GD, and Brooks GA. Evaluation of exercise and training on muscle lipid metabolism. Am J Physiol Endocrinol Metab 276: E106-E117, 1999[Abstract/Free Full Text].

3.   Burguera, B, Proctor D, Dietz N, Guo Z, Joyner M, and Jensen MD. Leg free fatty acid kinetics during exercise in men and women. Am J Physiol Endocrinol Metab 278: E113-E117, 2000[Abstract/Free Full Text].

4.   Dyck, DJ, Peters SJ, Glatz J, Gorski J, Keizer H, Kiens B, Liu S, Richter EA, Spriet LL, van der Vusse GJ, and Bonen A. Functional differences in lipid metabolism in resting skeletal muscle of various fiber types. Am J Physiol Endocrinol Metab 272: E340-E351, 1997[Abstract/Free Full Text].

5.   Friedlander, AL, Casazza GA, Horning MA, Buddinger TF, and Brooks GA. Effects of exercise intensity and training on lipid metabolism in young women. Am J Physiol Endocrinol Metab 275: E853-E863, 1998[Abstract/Free Full Text].

6.   Friedlander, AL, Casazza GA, Horning MA, Huie MJ, Piacentini MF, Trimmer JK, and Brooks GA. Training-induced alterations of carbohydrate metabolism in women: women respond differently from men. J Appl Physiol 85: 1175-1186, 1998[Abstract/Free Full Text].

7.   Friedlander, AL, Casazza GA, Horning MA, Usaj A, and Brooks GA. Endurance training increases fatty acid turnover, but not fat oxidation, in young men. J Appl Physiol 86: 2097-2105, 1999[Abstract/Free Full Text].

8.   Guo, Z, Burguera B, and Jensen MD. Kinetics of intramuscular triglyceride fatty acids in exercising humans. J Appl Physiol 89: 2057-2064, 2000[Abstract/Free Full Text].

9.   Havel, RJ, Pernow B, and Jones NL. Uptake and release of free fatty acids and other metabolites in the legs of exercising men. J Appl Physiol 23: 90-99, 1967[Free Full Text].

10.  Helge JW, Watt PW, Richter EA, Rennie MJ, and Kiens B. Fat utilization during exercise; adaptation to fat-rich diet increases utilization of plasma FA and VLDL-TG in humans. J Physiol (Lond). In press.

11.   Horton, TJ, Pagliassotti MJ, Hobbs K, and Hill JO. Fuel metabolism in men and women during and after long-duration exercise. J Appl Physiol 85: 1823-1832, 1998[Abstract/Free Full Text].

12.   Kiens, B, Essen-Gustavsson B, Christensen NJ, and Saltin B. Skeletal muscle substrate utilization during submaximal exercise in man: effect of endurance training. J Physiol (Lond) 469: 459-478, 1993[Abstract].

13.   Kiens, B, and Richter EA. Types of carbohydrate in an ordinary diet affect insulin action and muscle substrates in humans. Am J Clin Nutr 63: 47-53, 1996[Abstract].

14.   Kiens, B, and Richter EA. Utilization of skeletal muscle triacylglycerol during postexercise recovery in humans. Am J Physiol Endocrinol Metab 275: E332-E337, 1998[Abstract].

15.   Lowry, OH, and Passonneau JV. A Flexible System of Enzymatic Analysis. New York: Academic, 1972.

16.   Lundsgaard, C, and van Slyke DD. Studies of lung volume. I. Relation between thorax size and lung volume in normal adults. J Exp Med 27: 65-85, 1917.

17.   Marliss, EB, Kreisman SH, Manzon A, Halter JB, Vranic M, and Nessim SJ. Gender differences in glucoregulatory responses to intense exercise. J Appl Physiol 88: 457-466, 2000[Abstract/Free Full Text].

18.   Martin, WH, III, Dalsky GP, Hurley BF, Matthews DE, Bier DM, Hagberg JM, Rogers MA, King DS, and Holloszy JO. Effect of endurance training on plasma free fatty acid turnover and oxidation during exercise. Am J Physiol Endocrinol Metab 265: E708-E714, 1993[Abstract/Free Full Text].

19.   McKenzie, S, Phillips SM, Carter SL, Lowther S, Gibala MJ, and Tarnopolsky MA. Endurance exercise training attenuates leucine oxidation and BCOAD activation during exercise in humans. Am J Physiol Endocrinol Metab 278: E580-E587, 2000[Abstract/Free Full Text].

20.   Mittendorfer, B, Sidossis LS, Walser E, Chinkes DL, and Wolfe RR. Regional acetate kinetics and oxidation in human volunteers. Am J Physiol Endocrinol Metab 274: E978-E983, 1998[Abstract/Free Full Text].

21.   Patterson, BW, Zhao G, Elias N, Hachey DL, and Klein S. Validation of a new procedure to determine plasma fatty acid concentration and isotopic enrichment. J Lipid Res 40: 2118-2124, 1999[Abstract/Free Full Text].

22.   Peters, SJ, Dyck DJ, Bonen A, and Spriet LL. Effects of epinephrine on lipid metabolism in resting skeletal muscle. Am J Physiol Endocrinol Metab 275: E300-E309, 1998[Abstract].

23.   Phillips, SM, Atkinson SA, Tarnopolsky MA, and MacDougall JD. Gender differences in leucine kinetics and nitrogen balance in endurance athletes. J Appl Physiol 75: 2134-2141, 1993[Abstract].

24.   Pickert, A, Overkamp D, Renn W, Liebich H, and Eggstein M. Selected ion monitoring gas chromatography/mass spectrometry using uniformly labelled [13C]glucose for determination of glucose turnover in man. Biol Mass Spectrom 20: 203-209, 1991[ISI][Medline].

25.   Romijn, JA, Coyle EF, Sidossis LS, Gastaldelli A, Horowitz JF, Endert E, and Wolfe RR. Regulation of endogenous fat and carbohydrate metabolism in relation to exercise intensity and duration. Am J Physiol Endocrinol Metab 265: E380-E391, 1993[Abstract/Free Full Text].

26.   Romijn, JA, Coyle EF, Sidossis LS, Rosenblatt J, and Wolfe RR. Substrate metabolism during different exercise intensities in endurance-trained women. J Appl Physiol 88: 1707-1714, 2000[Abstract/Free Full Text].

27.   Schrauwen, P, Aggel-Leijssen DP, Marken Lichtenbelt WD, van Baak MA, Gijsen AP, and Wagenmakers AJ. Validation of the [1,2-13C]acetate recovery factor for correction of [U-13C]palmitate oxidation rates in humans. J Physiol (Lond) 513: 215-223, 1998[Abstract/Free Full Text].

28.   Schrauwen, P, Blaak E, Aggel-Leijssen DP, Borghouts LB, and Wagenmakers AJ. Determinants of the acetate recovery factor: implications for estimation of [13C]substrate oxidation. Clin Sci (Colch) 98: 587-592, 2000[ISI][Medline].

29.   Sidossis, LS, Coggan AR, Gastaldelli A, and Wolfe RR. A new correction factor for use in tracer estimations of plasma fatty acid oxidation. Am J Physiol Endocrinol Metab 269: E649-E656, 1995[Abstract/Free Full Text].

30.   Siggaard-Andersen, O, Wimberley PD, Fogh-Andersen N, and Gøthgen IH. Measured and derived quantities with modern pH and blood gas equipment: calculation algorithms with 54 equations. Scand J Clin Lab Invest 48: 7-15, 1988[Medline].

31.   Siri, WE. The gross composition of the body. Adv Biol Med Phys 4: 239-279, 1956.

32.   Starling, RD, Trappe TA, Parcell AC, Kerr CG, Fink WJ, and Costill DL. Effects of diet on muscle triglyceride and endurance performance. J Appl Physiol 82: 1185-1189, 1997[Abstract/Free Full Text].

33.  Steffensen CH, Roepstorff C, Madsen M, and Kiens B. Myocellular triacylglycerol breakdown in females but not in males during exercise. Am J Physiol. In press.

34.   Tarnopolsky, MA, Atkinson SA, Phillips SM, and MacDougall JD. Carbohydrate loading and metabolism during exercise in men and women. J Appl Physiol 78: 1360-1368, 1995[Abstract/Free Full Text].

35.   Tarnopolsky, MA, Bosman M, Macdonald JR, Vandeputte D, Martin J, and Roy BD. Postexercise protein-carbohydrate and carbohydrate supplements increase muscle glycogen in men and women. J Appl Physiol 83: 1877-1883, 1997[Abstract/Free Full Text].

36.   Tarnopolsky, LJ, MacDougall JD, Atkinson SA, Tarnopolsky MA, and Sutton JR. Gender differences in substrate for endurance exercise. J Appl Physiol 68: 302-308, 1990[Abstract/Free Full Text].

37.   Van Hall, G. Correction factors for 13C-labelled substrate oxidation at whole-body and muscle level. Proc Nutr Soc 58: 979-986, 1999[ISI][Medline].

38.   Van Loon, LJC, Schrauwen P, and Wagenmakers AJM The effect of exercise intensity on breath 13CO2 recovery during [1,2-13C]acetate infusion. Proc Nutr Soc 58: 166A, 1999[ISI].

39.   Wolfe, RR. Radioactive and Stable Isotope Tracers in Biomedicine: Principles and Practice of Kinetic Analysis. New York: Wiley-Liss, 1992.


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