1 Sports Medicine Research Unit and 5 Department of Clinical Physiology, Bispebjerg Hospital, DK-2400 Copenhagen; 2 Copenhagen Muscle Research Center and 3 Department of Growth and Reproduction, Rigshospitalet, DK-2100 Copenhagen; and 4 Clinical Drug Development, Novo Nordisk, DK-2800 Bagsvaerd, Denmark
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ABSTRACT |
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The present study investigated whether recombinant human (rh) growth hormone (GH) combined with endurance training would have a larger effect on oxidative capacity, metabolism, and body fat than endurance training alone. Sixteen healthy, elderly women, aged 75 yr, performed closely monitored endurance training on a cycle ergometer over 12 wk. rhGH was given in a randomized, double-blinded, placebo-controlled design in addition to the training program. GH administration resulted in a doubling of serum insulin-like growth factor I levels. With endurance training, peak oxygen uptake increased by ~18% in both groups, whereas the marked increase in muscle citrate synthase activity was 50% larger in the GH group compared with the placebo group. In addition, only the GH group revealed an increase in muscle L-3-hydroxyacyl-CoA dehydrogenase activity. Body weight remained unchanged in both groups, but the GH group showed significant changes in body composition with a decrease in fat mass and an increase in lean body mass. Twenty-four-hour indirect calorimetry performed in four subjects showed a marked increase in energy expenditure with increased relative and absolute fat combustion in the two subjects receiving rhGH. In conclusion, rhGH adds to the effects of endurance training on muscle oxidative enzymes and causes a reduction in body fat in elderly women.
insulin-like growth factor I; enzymes; exercise; calorimetry; body composition
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INTRODUCTION |
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AGING IS ASSOCIATED WITH A loss in muscle mass and strength and an increase in body fat (9, 21). In addition, oxidative capacity and basal metabolic rate (BMR) are decreased (22). These changes have been attributed both to aging per se and to the development of a sedentary lifestyle (4). However, a causal relation to the age-related decline in growth hormone (GH) secretion has also been proposed (18). Children and young adults with GH deficiency (GHD) mimic the elderly in the sense that they also are characterized by a significant increase in body fat and a decrease in lean body mass (LBM) and BMR compared with controls. In GHD, these abnormalities are corrected by the administration of recombinant human GH (rhGH) in doses that restore serum insulin-like growth factor (IGF) I levels (13). Furthermore, administration of rhGH in supraphysiological doses to both obese women and to healthy elderly men decreases body fat and increases LBM (23, 25). These observations suggest that GH may play a role in determining body composition.
Increased muscle mass may explain the increase in LBM observed with rhGH administration. This is supported by studies showing that rhGH administration increases muscle protein synthesis (5). However, some authors have questioned whether this anabolic effect is of any significance in humans since the increase in LBM and nitrogen retention is only reflected in very small improvements in muscle strength (34). Furthermore, recent studies have not shown any additive effects of rhGH combined with strength training in humans (29, 35, 36).
So far research has focused on potential additive anabolic effects of rhGH combined with strength training. Considering the profound influence of GH on metabolism, it is somewhat surprising that no attention has been given to possible additive effects of rhGH combined with endurance training. On this background, the present study aimed at investigating whether the addition of rhGH enhances endurance training-induced adaptations. We hypothesized that rhGH combined with endurance training would increase oxidative capacity, oxidative metabolism, and fat loss more than endurance training alone.
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METHODS |
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Subjects
Seventeen healthy women, age 75 ± 1 yr (mean ± SE), height 160 ± 1 cm, body weight 66.2 ± 2.5 kg, and body mass index 25.8 ± 1.0 kg/m2, participated in the study. Informed consent was obtained according to the declaration of Helsinki 2, and the study protocol was approved by the Ethics Committee for Medical Research in Copenhagen (KF 02-130/97) and by the Danish Drug Agency. Before entering the study, subjects underwent a thorough medical history and physical examination, including blood tests and an exercise electrocardiogram (ECG). Exclusion criteria were metabolic and cardiac disease, anemia, previous or present cancer, and medication known to interfere with skeletal muscle and/or fat metabolism. Estrogen replacement therapy was not allowed.Experimental Protocol
After inclusion, subjects were randomized in blocks of four to receive either placebo or GH, and the subjects then underwent a 12-wk closely supervised endurance-training program on cycle ergometers. Measurements were performed at baseline and after 12 wk.Administration of GH
GH (Norditropin; Novo Nordisk) was administered subcutaneously in the thigh one time daily in a randomized, double-blinded, placebo-controlled design. After thorough instruction, subjects were able to perform the injections themselves at home in the evening before bedtime. Checking the syringes and reviewing the injection technique several times during the study ensured compliance. To avoid side effects, the dose was increased over 3 wk. During the first week the dose was 0.5 IU/m2, during the second week 1.0 IU/m2, and for the remainder of the study period 1.5 IU/m2 (12 µg · kgDetermination of Peak Oxygen Uptake
Peak oxygen uptake (Training Program
The subjects trained on a cycle ergometer (model 818 E; Monark, Varberg, Sweden) three times per week for 12 wk. Each subject followed an interval program of 60 min on each training session. An interval program was chosen for psychological reasons to obtain a high degree of compliance. The subjects were equipped with a wireless heart rate monitor (HRM; Polar Vantage NV; Polar Electro, Kempele, Finland) that enabled them to monitor HR and exercise duration continuously. After a 10-min warm-up period, the subjects performed seven intervals of 2-, 4-, 6-, 8-, 6-, 4-, and 2-min length, respectively, each interval being separated by 2 min from the previous interval. During the intervals, the subjects had to adjust the load so that HR, within 5 beats/min, was kept at a level corresponding to 75% ofDetermination of 24-h Energy Expenditure
In four subjects, 24-h energy expenditure (EE) was assessed by indirect calorimetry on the basis of measurements ofThe gas exchange of the subjects was calculated from the measurements
of oxygen and carbon dioxide concentrations (Ureas 3 G; Hartman and
Braun analyzers, Frankfurt, Germany) at the outlet of the chamber and
from measured airflow through the chamber. The room temperature was
maintained constant at 24°C during the daytime and at 18°C during
the night. EE was calculated using the following equation with the
assumption that the contribution of methane production to EE is
negligible
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Dual-Energy X-Ray Absorptiometry
The dual-energy X-ray absorptiometry (DEXA) scan was performed using a Lunar DPX-IQ scanner (software version 4.6 C; Lunar, Madison, WI) before and after the 12-wk training period. Subjects were scanned in the morning after an overnight fast, just after having emptied the urine bladder, and while wearing only a standard hospital gown. Either a fast (12-min)- or a medium (25-min)-mode scanning procedure was used, depending on the distance between the beam collector and the skin of the abdomen. The same two trained persons performed all scans. One person analyzed all scans using the extended research analysis software provided by Lunar. In the analysis, total body scans were divided into the following three regions: arms, legs, and trunk. Total and regional scans were further divided into the following three compartments: LBM, fat mass (FM), and bone mineral content (BMC).Muscle Biopsies
Muscle biopsies were taken from the right musculus vastus lateralis at the midthigh level at baseline and after 5 and 12 wk of training. Sampling at 5 and 12 wk was performed 1 cm distal and 1 cm proximal to baseline sampling, respectively. The overlying skin was anesthetized with 1% lidocaine, and sampling was done through an incision using a 5-mm Bergström needle (2). A suction device in conjunction with the biopsy needle was used to create a negative pressure while sampling, which allowed for a larger sample specimen. Samples were immediately frozen in liquid N2, transferred to a vial, and stored atBlood Sampling
Blood for determination of GH, insulin-like growth factor (IGF)-I, IGF-II, IGF-binding protein 3 (IGFBP-3), and acid-labile subunit (ALS) was sampled from a radial artery in the morning after an overnight fast. Samples were allowed to clot for 10 min at room temperature and were centrifuged at 4°C for 15 min to obtain serum. Serum was stored atAnalytical Methods
Serum. GH. GH was determined by time-resolved immunofluoresence assay (Delfia; Wallac, Turku, Finland). The detection limit was 0.03 ± 0.02 mU/l. Inter- and intra-assay coefficients of variation were 5.9% (at 16.54 mU/l) and 2.2% (at 14.1 mU/l), respectively.
TOTAL IGF-I. Total IGF-I was determined by RIA as described previously (14). Briefly, serum was extracted by acid-ethanol and was cryoprecipitated before analysis to remove interfering IGFBP. Inter- and intra-assay coefficients of variation were <9 and 6%, respectively. IGF-II. IGF-II was determined by an immunoradiometric assay (Diagnostic Systems Laboratories, Webster, TX). Briefly, this assay is a noncompetitive assay in which the analyte is sandwiched between two antibodies. Samples were pretreated (1:1,000) with acid-ethanol extraction to separate IGF-II from its binding proteins before measurement. Inter- and intra-assay coefficients of variation were 6.3-10.4% and 4.2-7.2%, respectively (37). IGFBP-3. IGFBP-3 was determined by RIA as described previously (3). Reagents for the assay were obtained from Mediagnost (Tübingen, Germany). Sensitivity was 0.29 µg/l (defined as 3 SD from the mean of the zero standard). Inter- and intra-assay coefficients of variation were 10.7 and 2.4% (at bound-to-free ratios of 0.4-0.5), respectively. ALS. ALS was determined by a newly developed commercially available enzyme-linked immunosorbent assay (Diagnostic Systems Laboratories). Standards ranged from 1.09 to 70 mg/l. In our hands, interassay coefficients of variation (n = 22) were 20.4 (at 2.8 mg/ml) and 12.1% (at 17.6 mg/l). Intra-assay coefficients of variation (n = 20) were 8.6% (at 30.1 mg/l) and 7.4% (at 8.4 mg/ml; see Ref. 15).Muscle biopsies.
Approximately 10 mg of each muscle sample were used for the preparation
of muscle homogenate. Briefly, the samples were freeze-dried for
48 h at 40°C and were dissected free of blood, fat, and
connective tissue at
20°C and 30% relative humidity using a
stereomicroscope. Samples were then transferred to homogenization tubes
containing phosphate buffer with BSA and were placed on ice [400 µl
buffer/mg muscle; preparation of buffer: 20 ml 0.3 M phosphate buffer
(pH = 7.7) + 100 µl BSA]. After homogenization, the
homogenate was spun for 2 min at 11,000 rpm, and the supernatant was
transferred to an Eppendorf vial and stored at
80°C until further
analysis. The maximal enzymatic activities (expressed as µmol
metabolized substrate · g muscle
mass
1 · min
1 at 25°C) of citrate
synthase (CS), L-3-hydroxyacyl-CoA dehydrogenase (HAD),
phosphofructokinase (PFK), and lactate dehydrogenase (LDH) were
determined on a Cobas analyzer (Cobas Fara II; F. Hoffmann-La Roche,
Diagnostics Division) using NAD+-NADH enzymatic
fluorometric assays.
Statistics
All data are presented as means ± SE. A nonparametric ranking sum test was used to detect significant differences between unpaired (Mann-Whitney) and paired (Wilcoxon) data before and after the training period. P < 0.05 (2-tailed testing) was considered significant. ![]() |
RESULTS |
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Subjects
Sixteen out of seventeen recruited subjects completed the study. One subject left the study after 3 wk because she felt the training program was too demanding. Demographic data for the sixteen remaining subjects, divided into a placebo group (n = 8) and a GH group (n = 8), are presented in Table 1. Body weight was significantly greater in the GH group compared with the placebo group (P < 0.05). The groups were similar with respect to all other subject characteristics.
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GH Administration
Of the eight subjects receiving GH, five experienced side effects that necessitated a dose reduction. With no side effects, a typical end dose was 2.5-3.0 IU/day (12 µg · kgO2 peak
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Serum GH, IGF-I , IGF-II, IGFBP-3, and ALS
Markers for the GH-IGF axis are presented in Fig. 1. At baseline, there were no differences in serum GH, IGF-I, IGF-II, IGFBP-3, or ALS between the two groups, whereas all markers, except for IGF-II, were significantly greater in the GH group after 12 wk of training. IGF-II tended to increase from 738 ± 52 to 801 ± 59 (9 ± 4%) in the placebo group (P < 0.08). None of the other markers changed in that group.
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24-h EE
Data obtained from measurements in the respiration chamber are presented in Table 3. In response to the 8-wk training period, 24-h EE (kJ · kg
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DEXA
At baseline, there were no differences in total or regional LBM or in total or regional FM between the two groups. After 12 wk, the GH group displayed greater total LBM (16%, P < 0.02), arm LBM (22%, P < 0.01), and leg LBM (17%, P < 0.02) than the placebo group. There were no changes in body weight or total or regional body composition in the placebo group as a result of training, although leg LBM tended to increase from 59.7 ± 3.1 to 60.8 ± 3.2% (P < 0.09; Fig. 2). In the GH group, there was no change in body weight but a significant decrease in total and regional (arm, trunk, and leg) FM and a significant increase in total and regional (arm, trunk, and leg) LBM (Fig. 2). Fat loss was not related to FM at baseline (Fig. 3). BMC remained unchanged in both groups (data not given).
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Muscle Enzyme Activities
At baseline, there were no differences in muscle CS, HAD, LDH, or PFK activities between groups. After 12 wk, CS activity was increased by 35 ± 12% in the placebo group (P < 0.02) and by 52 ± 7% in the GH group (P < 0.02). The increase in the GH group was significantly larger compared with the placebo group (P < 0.05; Fig. 4). No change in HAD activity was observed in the placebo group, whereas an increase of 24 ± 6% was seen in the GH group (P < 0.02). There were no changes in LDH or PFK activities, although there was a tendency for LDH to increase by 21 ± 10% in the GH group (P < 0.07).
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DISCUSSION |
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A major finding in the present study is the larger increase in muscle oxidative enzyme activity when rhGH administration is combined with physical endurance training compared with the effect of training alone (Fig. 4). From the present study, mechanisms behind this effect of GH can only be hypothesized. In this respect, it is interesting that the myogenic transcription factor myogenin not only has been shown to be involved in muscle differentiation (8, 10, 17) but also may play a role in shifts from glycolytic to typically oxidative metabolism without concomitant changes in myosin heavy chain composition (11). Thus GH, by increasing IGF-I, may enhance transcriptional activity through myogenin, and this may enhance the exercise effect on muscle oxidative enzymes.
The combination of rhGH and physical endurance training or the effect of rhGH per se on muscle oxidative enzyme activity has, to our knowledge, not been studied in humans. Only a few animal studies exist, but they are difficult to compare, and the results are diverging (6, 7, 16, 32). Thus no clear picture emerges from the literature. However, from the present study, it is unclear whether GH per se stimulates oxidative enzyme activity in skeletal muscle. Previous studies in elderly men have not been able to demonstrate any additive effects of GH on strength training in terms of increased strength, hypertrophy, or increased muscle protein synthesis rate (28, 29, 36). Endurance training represents an entirely different stimulus to the muscle than resistance training, and muscle adaptation to endurance training may be regulated differently from strength training.
Both O2 peak and oxidative muscle
enzymes (but not the glycolytic enzymes) increased in response to
endurance training by 19 and 35%, respectively. This is in agreement
with adaptations that potentially can be achieved with training in this
age group (19) and underscores the high compliance among
subjects toward the training program. When rhGH was combined with
endurance training,
O2 peak did not
improve further, whereas oxidative enzyme activity in the contracting
skeletal muscle improved by an additional 17%. This illustrates a
specific peripheral effect on muscle rather than any effect on the
central circulatory system or improved peripheral tissue oxygen extraction.
In this study, rhGH enhanced both the CS and HAD activity in muscle biopsy tissue. This finding is interesting in view of the data obtained from the respiration chamber. Although only four of the subjects were studied this way, the data clearly indicate that rhGH administration causes a substantial increase in 24-h EE and a shift in substrate oxidation. GH administration has been shown previously to increase the BMR in normal (33) and in GH-deficient subjects (12). However, in these studies, the EE was only measured in a short period postprandially. From the present preliminary data, it is not possible to identify by which mechanisms GH increases the EE and changes the oxidative metabolism. However, it can easily be calculated that neither the increase in HR (33) nor the shift in substrate oxidation observed with GH administration is able to account for >5-10% of the increase in EE. It is tempting to speculate that mechanisms stimulating uncoupling proteins (24, 26, 27), and hence futile cycling, quantitatively may contribute to the EE-enhancing effect of GH, but further studies are needed to elucidate this.
Body composition was estimated by the use of DEXA scanning, which evidently limits the amount of detailed information that can be extracted (Fig. 2). However, it can be stated that total FM did only decrease significantly with training if this was accompanied by the administration of GH (Fig. 2). Also, this decrease occurred in all body regions. Our study design does not allow us to determine whether the effects are due to GH per se or the combination of GH and training. The observed increase in LBM with GH administration should be interpreted with some caution. It may represent an increase in muscle mass but is probably almost exclusively explained by the fluid retention induced by GH (20). In support of the latter, recent results from our laboratory have shown that LBM declines within days after stopping GH administration.
In the present study, elderly women received exogenous GH, aiming at a dose of 1.5 IU/m2. However, almost all individuals developed side effects at this dose, resulting in an almost halving of the dose in most individuals for the remainder of the training period. Despite this very moderate dose, all individuals receiving GH more than doubled their IGF-I serum levels (Fig. 1). This increased level is comparable to, and even above, levels seen in young, healthy individuals in their second decade (14). In addition to this, serum GH, IGF-II, IGFBP-3, and ALS were also increased in the GH group. Somewhat surprising, a trend (P < 0.08) toward an increase in serum IGF-II was observed in the placebo group. In animals, it has been shown that GH administration is able to induce skeletal muscle hypertrophy (31). In that study, the increase in skeletal muscle mass was associated with a marked upregulation of both IGF-I and IGF-II mRNA locally in the muscle. The present study suggests that even physical training aiming at increasing endurance and oxidative capacity rather than muscle hypertrophy and strength stimulates the release of IGF-II from human skeletal muscle. The role of IGF-II in the present study is unknown. Possibly IGF-II could play a role, together with IGF-I, in stimulating myogenic factors and thus could account for the larger response in enzyme activity observed in the training group receiving GH.
In conclusion, the present study confirms our hypothesis that, in healthy elderly women, rhGH combined with endurance training increases skeletal muscle oxidative enzyme activity more than endurance training alone. In addition, we suggest that the marked loss of body fat seen with rhGH administration is due to increased 24-h EE with increased relative and absolute fat combustion over a 12-wk period.
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ACKNOWLEDGEMENTS |
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Inge Rasmussen and Annie Høj are thanked for excellent laboratory work. Merete Vannby and Carsten Bo Nielsen are thanked for valuable help in performing muscle enzyme assays. Novo Nordisk is thanked for providing rhGH and for good collaboration.
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FOOTNOTES |
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The study was supported by grants from the Novo Nordisk Foundation, the Danish Medical Research Council (12-1610-1, 9802636), the Danish National Research Foundation (504), the Danish Heart Foundation (97-1-3-48-22465), and the John and Birthe Meyer Foundation.
Address for reprint requests and other correspondence: K. H. W. Lange, Sports Medicine Research Unit, Bldg. 8, Bispebjerg Hospital, Bispebjerg Bakke 23, DK-2400 Copenhagen, Denmark (E-mail: klange{at}dadlnet.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.
Received 13 January 2000; accepted in final form 15 June 2000.
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