A Single Bout of One-Legged Exercise to Local Exhaustion Decreases Insulin Action in Nonexercised Muscle Leading to Decreased Whole-Body Insulin Action

Ethical Approval

The study was approved by the Regional Ethics Committee for Copenhagen (H-6–2014–038; Copenhagen, Denmark) and complied with the guidelines of the 2013 Declaration of Helsinki. Written informed consent was obtained from all participants prior to entering the study.

Experimental Protocol

Eight young (26 ± 1 years), lean (BMI 23.5 ± 0.4 kg/m²), moderately trained (48.5 ± 2.4 mL · min⁻¹ · kg⁻¹), and healthy men were included in the study and underwent a euglycemic-hyperinsulinemic clamp (EHC) on 2 separate days: one day with prior one-legged exercise to local exhaustion (exercise day) and another day without prior exercise (rest day). The 2 experimental days were performed in randomized order and separated by at least 11 days (Fig. 1).

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Figure 1

Experimental study design. Subjects underwent an EHC on 2 separate days in a randomized order: one day with prior one-legged knee-extensor exercise to local exhaustion (exercise day) and on another day without prior exercise (rest day). Insulin-stimulated glucose uptake was measured in both legs on both days. Biopsies were obtained in both legs immediately before and after EHC on both days.

A minimum of 1 week prior to the first experimental day, VO_2peak was determined by an incremental cycle test to exhaustion (Monark cycle ergometer, Ergomedic 839E) using breath-by-breath measurements of VO₂ (MasterScreen CPX; Intramedic A/S, Gentofte, Denmark). Body composition was measured by DXA (DPX-IQ Lunar; Lunar Corporation, Madison, WI). After familiarization to the one-legged knee-extensor ergometer (18), peak workload (PWL) of the knee extensors was determined in both legs by an incremental test. Prior to the first experimental day, subjects recorded food intake for 3 days, which they repeated prior to the second experimental day. Subjects abstained from alcohol, caffeine, and strenuous physical activity for 48 h prior to both experimental days.

On the morning of the experimental days, subjects arrived at the laboratory 1 h after having ingested a small breakfast (oatmeal, skimmed milk, and sugar; 5% of daily energy intake) (19). Upon arrival, they either rested for 2.5 h or performed one-legged exercise until local exhaustion with a randomized leg. The exercise protocol consisted of one-legged knee-extensor exercise for 1 h at 80% PWL with 5-min intervals at 90% PWL every 10 min. This was followed by 4-min intervals until exhaustion with 1 min at 50% PWL between intervals. The intensity for the 4-min intervals started at 100% PWL. When subjects were unable to maintain a kicking frequency of 60 rpm, intensity was lowered by 10 percentage points until subjects were unable to finish 4 min at 60% PWL. The average duration of the one-legged exercise was 2 h and 21 ± 6 min.

Subjects then rested in the supine position, and catheters (Pediatric Jugular Catheterization set; Teleflex Inc., Wayne, PA) were inserted into the femoral vein of both legs and a dorsal hand vein (Venflon Pro Safety; Mediq Danmark A/S, Brøndbyvester, Denmark) for sampling of arterialized venous blood (heated hand vein). In seven of the eight subjects, a primed (priming dose 2.6 mg · kg⁻¹), constant [6,6-²H₂]-glucose tracer infusion (0.044 mg · kg⁻¹ · min⁻¹) was initiated after 2 h of rest. Four hours after the exercise bout, the EHC was initiated with a bolus of insulin (9 mU · kg⁻¹) (Actrapid; Novo Nordisk, Bagsværd, Denmark) followed by 120 min of constant insulin infusion (1.42 mU · min⁻¹ · kg⁻¹). Glucose was infused during the EHC from a 20% glucose solution enriched with 1.9% [6,6-²H₂]-glucose and adjusted throughout the clamp to maintain euglycemia. Blood samples were drawn from all three catheters before (−60, −30, and 0 min) and during (15, 30, 45, 60, 80, 100, and 120 min) the EHC. Prior to blood sampling, femoral arterial blood flow was measured using the ultrasound Doppler technique (Philips iU22; ViCare Medical A/S, Birkerød, Denmark). Blood samples for the measurement of plasma enrichment of the glucose isotope were drawn from the heated hand vein prior to (−30, −15, and 0 min), in the beginning (25, 30, and 35 min) and in the end of the EHC (100, 110, and 120 min). Muscle biopsies of m. vastus lateralis were obtained in both legs immediately before and after the clamp under local anesthesia (∼3 mL Xylocaine 2%; AstraZeneca, Copenhagen, Denmark) using the Bergström needle technique with suction (20). We were unable to obtain a full set of biopsies from one subject, and thus, analyses performed on the muscle biopsies are n = 7.

Analysis of Plasma Samples

Plasma glucose concentration was measured by a blood-gas analyzer (ABL800 FLEX; Radiometer Danmark, Brønshøj, Denmark). Plasma insulin concentration was measured using an Insulin ELISA kit (ALPCO). Plasma fatty acids (FAs) (NEFA C kit; Wako Chemicals Europe GmbH, Neuss, Germany) were measured using an enzymatic colorimetric method (Hitachi 912 automatic analyzer). Plasma enrichment of the labeled glucose isotope was measured using liquid chromatography mass spectrometry as previously described (21).

Muscle Homogenate and Lysate Preparation

Muscle biopsies were freeze-dried for 48 h and dissected free of visible blood, fat, and connective tissue. Muscle biopsies were homogenized as previously described (22), and lysates were recovered by centrifuging the homogenates (20 min, 18,320g, at 4°C). Homogenate and lysate protein content were determined by the bicinchoninic acid method (Pierce Biotechnology Inc., Waltham, MA).

SDS-PAGE and Western Blotting

To measure protein expression and phosphorylation, samples were separated on self-cast gels using SDS-PAGE followed by semidry transfer of proteins on polyvinylidene difluoride membranes. Membranes were blocked for 5 min in 2% skimmed milk in TBS containing 0.05% Tween-20 followed by overnight incubation at 4°C in primary antibodies: anti–phospho-AktSer473 (Research Resource Identifier: AB_329825), anti–phospho-Akt^Thr308 (AB_329828), anti-Akt2 (AB_2225186), anti–phospho-TBC1D4^Thr642 (AB_2651042), anti–phospho-TBC1D4^Ser588 (AB_10860251), anti–phospho-TBC1D1^Thr596 (AB_10828720), and anti–phospho-GSK3α^Ser21/GSKβ^Ser9 (AB_329830) (Cell Signaling Technology, Danvers, MA); anti-GLUT4 (AB_2191454) (Thermo Fisher Scientific, Waltham, MA); anti–phospho-TBC1D4^Ser704 (custom made; Capra Science Antibodies AB, Ängelholm, Sweden); anti-TBC1D4 (AB_2818964) and anti-TBC1D1 (AB_2814949) (Abcam, Cambridge, U.K.); anti-GSK3β (AB_397601) (BD Transduction Laboratories, San Diego, CA); anti–glycogen synthase (GS) (custom made; Oluf Pedersen, University of Copenhagen); and anti–phospho-TBC1D4^Ser341, anti–pyruvate dehydrogenase (PDH), anti–phospho-PDH^site1, anti–phospho-PDH^site2, anti–phospho-GS^Ser7+10 (GS^2+2a), and anti–phospho-GS^Ser640+644 (GS^3a+3b) (custom made; Dr. David Grahame Hardie, University of Dundee, Dundee, U.K.). Membranes were incubated with horseradish peroxidase–conjugated secondary antibodies (Jackson ImmunoResearch Europe Ltd, Ely, U.K.) for 45 min at room temperature before visualizing protein bands with chemiluminescence (Millipore, Burlington, MA) and a ChemiDoc MP imaging system (Bio-Rad Laboratories, Hercules, CA). Some membranes were stripped and reprobed with a new primary antibody against another phosphorylation site or corresponding total protein after removal of the first antibody by incubation in stripping buffer (62.3 mmol/L Tris-HCl, 69.4 mmol/L SDS, double-distilled H₂O, and 0.08% β-mercaptoethanol, pH 6.7). The membranes were checked for successful removal of the initial primary antibody before reprobing.

Muscle Metabolites

Muscle glycogen was measured in homogenates (150 µg protein) as glycosyl units after acid hydrolysis determined by a fluorometric method (23). Muscle glucose, glucose-6-phosphate (G6P), and lactate were extracted with perchloric acid and measured fluorometrically (23).

GS Activity

GS activity was measured in homogenates in the presence of 0.02, 0.17, and 8 mmol/L G6P as previously described (24).

Phosphoinositide 3-Kinase Activity

Insulin receptor substrate 1 (IRS1)–associated phosphoinositide 3-kinase (PI3K) activity was measured on immunoprecipitates of 200 μg of lysate protein using Protein G agarose and an IRS1 C-terminal antibody (Dr. K. Siddle, Cambridge University, Cambridge, U.K.) as previously described (2). Briefly, the PI3K activity reaction ran for 15 min at 30°C with L-α-phosphatidylinositol (PtdIns) as substrate (Merck, Branchburg, NJ) and ³³P γ-labeled ATP (Hartmann Analytic, Braunschweig, Germany). The reaction was stopped by addition of 5 N HCl, and PtdIns was extracted with chloroform:methanol (1:1) and spotted on a thin-layer chromatography silica gel plate (Merck). After thin-layer chromatography migration, the amount of PtdIns-incorporated ³³P was analyzed with exposure to phosphor imager screens followed by scanning in a Typhoon FLA 7000 IP+ (GE Healthcare, Brøndbyvester, Denmark).

Calculations

Hepatic glucose production was calculated using Steele’s steady-state equations (25). Rates of glucose oxidation were calculated using the stoichiometric equations of Frayn (26). Nonoxidative R_d (NOGD) was calculated by subtracting the glucose oxidation rate from R_d. Exchange of substrates (glucose and lactate) was calculated by multiplying arteriovenous (A-V) differences with femoral arterial blood flow expressed per kilogram of lean leg mass (LLM). During one-legged knee-extensor exercise, only the quadriceps muscle is active (18). Assuming that the prior exercised quadriceps muscle caused the difference in insulin-stimulated glucose uptake between the two legs on the exercise day, we calculated an estimate for the insulin-stimulated glucose uptake exclusively for the quadriceps muscle:(1)

where LGU is leg glucose uptake.

Based on the link between body compartments for a reference man (27), we calculated total leg muscle mass, which on average constituted ∼83% of the LLM measured by DXA. Thus, we calculated the muscle mass for the active quadriceps muscle based on the following assumptions: 1) 83% of lean thigh mass measured by DXA is muscle mass; and 2) quadriceps constitutes 40% of all thigh muscles (28). For the rested muscle, muscle mass was calculated as 83% of LLM with the assumption that all muscles in the rested leg behaved similarly.

To evaluate whether the reduced insulin action in nonexercised muscle was responsible for the reduced whole-body insulin action, we calculated an estimate of the “expected” difference in whole-body glucose disposal between the 2 days based on differences in glucose uptake of the muscles. For the simplicity of the calculation, we assumed that all nonexercised muscles had the same reduction in insulin-stimulated glucose uptake as the nonexercised leg (calculated as the difference between the nonexercised and rested leg), although indications of differential insulin-stimulated glucose uptake between arm and leg muscles exist (29). The reduction in insulin-stimulated glucose uptake of the nonexercised leg was multiplied by the estimated total inactive muscle mass. Total muscle mass was estimated based on assumptions that skeletal muscle constitutes ∼43% of total body weight (30). The amount of inactive muscle mass was calculated as total muscle mass minus the active muscle mass, which was estimated as described above. The total reduction of insulin-stimulated glucose uptake in nonexercised muscle minus the increased uptake in the exercised muscle will be termed the “expected” difference of whole-body glucose disposal:(2)

where AUC is the area under the leg glucose uptake curve for the entire 120-min clamp, TI is total inactive, and m.m. is muscle mass.

This estimate was compared with the actual difference in whole-body glucose disposal between the 2 days (AUC for glucose infusion rate plus hepatic glucose production for the entire 120-min clamp).

Statistics

Data are presented as means ± SEM. Glucose infusion rate was evaluated by paired t test. Insulin-stimulated glucose uptake, glucose A-V difference, and femoral arterial blood flow were evaluated by one-way repeated-measures ANOVA. Insulin-stimulated glucose uptake in the exercised muscle versus rested muscle was evaluated by paired t test. Two-way repeated-measures ANOVA was used to evaluate hepatic glucose production, whole-body R_d, arterial plasma glucose, insulin, FAs, respiratory exchange ratio, lactate release, PI3K, glycogen content, G6P, glucose, GS activity, and all data obtained by Western blotting. Significant main effects and interactions were evaluated by Tukey post hoc test. Differences were considered significant when P < 0.05. All statistical analyses were performed using Sigma Plot (version 13; Systat Software); N = 8, unless otherwise stated. Because there were no significant differences between the two rested legs on the rest day on all parameters, we have chosen to present these data as mean of the two legs on the rest day as “rest leg.”

Data and Resource Availability

The data generated and analyzed during the current study are available from the corresponding author upon reasonable request.