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Adipose Tissue Lipolysis and Hormone-Sensitive Lipase Expression during Very-Low-Calorie Diet in Obese Female Identical Twins¹

Obesity Unit, Fourth Department of Medicine (V.S., M.K., V.H.), Charles University, Prague 2, Czech Republic; Laboratoire des Adaptations de l’Organisme à l’Exercice Musculaire, Service d’Exploration de la Fonction Respiratoire et de Médecine du Sport, Hôpital Purpan, and INSERM Unité 317, Institut Louis Bugnard, Hôpital Rangueil, Faculté de Médecine (I.H., I.G., F.C., M.B., M.D., D.R., M.G., M.L., D.L.), Université Paul Sabatier, 31403 Toulouse Cédex 4, France; and Department of Cell and Molecular Biology (C.H.), Lund University, 22100 Lund, Sweden

Address all correspondence and requests for reprints to: Dr. Dominique Langin, Institut National de la Santé et de la Recherche Médicale U317, Institut Louis Bugnard, Centre Hospitalier Universitaire Rangueil, F-31403 Toulouse Cédex 4, France. E-mail: langin{at}rangueil.inserm.fr

	Abstract

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Eight pairs of obese female monozygotic twins were subjected to a 4-week, very-low-calorie diet (VLCD) that induced a decrease in mean body mass index from 32.9 ± 1.1 to 29.7 ± 1.1 kg/m². Infusion of the ß-adrenergic agonist, isoproterenol, induced an increase in plasma levels of nonesterified fatty acids and glycerol that was more pronounced during than before VLCD. sc fat biopsies were obtained before and during VLCD to study adipocyte lipolysis. ß-adrenergic sensitivity was moderately improved during VLCD. Basal and stimulated lipolyses, and hormone-sensitive lipase activity and protein levels were increased during VLCD. Before VLCD, intrapair resemblance was found for basal and stimulated lipolysis rates. In response to the treatment, intrapair resemblance was observed for basal lipolysis and for lipolysis stimulated with agents acting on plasma membrane receptors. These results suggest that the increase of basal lipolysis during VLCD is caused by an increase of hormone-sensitive lipase expression. They support the notion that the genotype may play a role in regulating the changes of adipose tissue lipolysis rates observed during VLCD.

	Introduction

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OBESITY, an excessive accumulation of adipose tissue, is a frequent disorder in Western countries (1). Dietary calorie restriction is a basic treatment of the obese patient used to induce weight loss. Because of the risks and poor results associated with starvation, very-low-calorie diets (VLCD) are preferred (2). The aim of these diets is to diminish body weight through a decrease in fat mass while preserving lean body mass. The depletion of fat depots is caused by the hydrolysis of triglycerides stored in adipose tissue (3, 4). The mechanisms underlying the enhanced rate of lipolysis during VLCD and the possible counterregulatory mechanisms limiting the decrease of the fat mass are not well understood. The in vitro basal rate of lipolysis, i.e. the rate of spontaneous lipolysis in the absence of hormonal stimulation, was reported to be enhanced during VLCD, but the molecular basis of this increase is not known (5, 6, 7, 8).

Obesity is a heterogeneous phenotype with the involvement of multiple genes and their interactions with nongenetic factors. Studies of monozygotic twins who have been reared apart revealed that the genetic contribution to the body-mass index (weight in kilograms divided by the square of the height in meters) was as high as 70% (9). Other genetic epidemiology approaches have shown that body fat mass and body mass index are characterized by a genetic contribution of 25–40% (10). Moreover, individuals, i.e. genotypes, respond differently to changes in environmental and lifestyle conditions. For example, genetic factors are likely to be involved in the tendency to gain weight during overfeeding periods (11). Similarly, an interaction between genotype and calorie restriction is possible.

The aim of the present study was to measure the variations in adipose tissue lipolysis during VLCD and to evaluate the genetic contribution to these changes. For that purpose, pairs of female obese identical twins were studied. The in vivo metabolic response to a ß-adrenergic stimulation was assessed by infusing isoproterenol. The lipolytic effect of catecholamines on isolated fat cells was studied with agents acting on adrenoceptors and at the postreceptor level. The level of hormone-sensitive lipase expression also was determined.

	Materials and Methods

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Subjects

Eight pairs of female obese monozygotic twins were selected (40.1 ± 7.7 yr old). Zygoty of the subjects was established by history, physical appearance and identity of blood groups, red cell antigens, human leukocyte antigen system of A, B, and C loci, and apolipoprotein-B3 hypervariable region (data not shown). None of the patients was taking drugs before the study and during the diet period. The participants were sedentary. The patients received a 1600 kJ/day (383 kcal/day) liquid formula diet for 28 days (12). The formula included 36 g protein, 50 g carbohydrate, 4 g fat, and the recommended daily allowance of vitamins and minerals (National Research Council, 1989). The subjects stayed at the Obesity unit of Prague University Hospital during 1 week before the beginning of the diet (to perform entry examinations) and throughout the diet period. The examinations mentioned below were carried out during the first week of the hospital stay, i.e. before the diet, and at days 27 and 28 of VLCD. All subjects had given their informed consent before the study, and the investigation protocol was approved by the Ethical Committee of Prague University Hospital.

In vivo experimental protocol

Subjects were examined in the morning after an overnight fast. Height, body weight, and waist-to-hip ratio were measured. Percentage of fat was determined by hydrostatic weighing (13). Subsequent examinations were performed with subjects in a lying position. Heart rate and blood pressure were monitored continuously. Two iv catheters were inserted into antecubital veins, one in each arm. One catheter was used for isoproterenol infusion, the other one for blood sampling. After a 20-min resting period, a first blood sample was drawn for determination of basal values. Thereafter, the infusion of isoproterenol, diluted in saline solution, was started. Protection of the isoproterenol solution from light degradation was ensured by wrapping aluminum foil around the syringe, and the line was connected to the subject. Three sequential doses of isoproterenol were used: 0.02, 0.04, and 0.06 µg/kg lean body mass. Each dose was perfused for 10 min, and blood sampling was performed during the last minute of each 10-min interval. The infusion was interrupted if the subject’s heart rate exceeded 130 beats/min, which happened in two subjects at the highest rate of infusion.

Plasma glucose and free fatty acids were determined with a glucose oxidase technique (Biotrol, Paris, France) and an enzymatic procedure (Unipath, Dardilly, France), respectively. Plasma insulin concentrations were measured using a RIA kit (Pasteur Institute, Paris, France). Glycerol was analyzed using a sensitive radiometric method (14).

Fat cell isolation and measurement of lipolysis

An sc abdominal fat biopsy (300–400 mg) was performed under local anesthesia (10–15 cm from the umbilic), and adipocytes were isolated using collagenase (15). Digestion was performed for 40–50 min at 37 C in a Krebs-Ringer bicarbonate buffer, pH7.4, containing 90 mg glucose/100 mL and 4% BSA with 1 mg/mL collagenase. At the end of digestion, the fat cell suspension was filtered and rinsed three times. Fat cell volume and cell surface area were determined from 200 adipocytes for each subject before and during VLCD (15, 16). The quantity of glycerol released into the medium was measured using an ultrasensitive bioluminescent technique to estimate adipocyte lipolysis (17). All measurements were performed in triplicate. Drug potency was estimated by calculating half-maximum effective concentration and pD2 value [-log(half-maximum effective concentration)].

Determination of hormone-sensitive lipase activity

The assay was performed essentially as previously described (18). Isolated adipocytes were rinsed twice with saline phosphate buffer. Cells were then homogenized at 4 C in 0.25 mol/L sucrose, 1 mmol/L EDTA, 1 mmol/L dithioerythritol, and the protease inhibitors, leupeptin and antipain (both at 20 µg/mL). The samples were centrifuged at 100,000 x g for 45 min at 4 C. The fat-free infranatant was recovered for analysis of enzyme activity using 1(3)-mono[³H]oleoyl-2-oleylglycerol as substrate. All samples were incubated in triplicate on one occasion for 30 min at 37 C. A diacylglycerol analogue was used as substrate for enhancing assay activity, because hormone-sensitive lipase has 10-fold higher activity toward diacylglycerol than triacylglycerol. The diacylglycerol lipase activity is not dependent upon the phosphorylation state of the enzyme. Moreover, because this substrate has only one hydrolyzable ester bond at the 1(3)-position, neither the diacylglycerol analogue nor its hydrolysis products are substrates for monoacylglycerol lipase, which is abundant in adipose tissue. Furthermore, under conditions of the assay, i.e. pH 7.0 and no apoCII present, very low lipoprotein lipase activity was measured (19). One unit of enzyme activity is defined as 1 µmol fatty acid released per min at 37 C. Lipase activity was normalized to the protein concentration of the infranatant, which was measured according to Lowry, using BSA as standard (20).

Western blot analysis

Fat-depleted infranatants (50 µg protein) were subjected to SDS-PAGE (8%) and electroblotting to nitrocellulose membranes. Western blot analysis was performed using a chicken antibody directed against recombinant rat hormone-sensitive lipase (HSL) as primary antibody (21), a horseradish peroxidase conjugated antichicken IgG (Sigma-Aldrich, L’isle d’abeau, France) as secondary antibody, and Enhanced Chemiluminescence detection system (Amersham, Little Chalfont, Buckinghamshire, UK).

Statistical analysis

Results are expressed as mean ± SEM. Similarities within pairs of twins in response to VLCD were calculated according to Bouchard and co-workers (22). The effects of treatment (VLCD) and the interactions between genotypes and VLCD were assessed with a two-way ANOVA for repeated measures on one factor (time). Twins were considered nested within the pair, whereas the treatment effect was defined as fixed. The intraclass correlation coefficient for the changes of lipolysis rates in response to VLCD treatment was computed from the between-pairs and within-pairs means of square. This coefficient provides a quantitative estimate of the similarity within pairs in response to VLCD. An intraclass coefficient close to 1 indicates a perfect within-pair resemblance in response to VLCD, whereas a coefficient close to 0 would imply an absence of within-pair resemblance in response to the treatment.

	Results

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Table 1 presents the clinical data of eight pairs of female monozygotic twins before and during VLCD. The mean body mass index was reduced by more than 3 kg/m² in response to VLCD. Decreases of waist-to-hip ratio, fat mass, and fat cell volume also were observed. Systolic and diastolic blood pressures were decreased during VLCD. Regarding metabolic variables, only the level of blood glucose was lower after 4 weeks of VLCD.

View larger version (19K): [in this window] [in a new window]   Figure 1. Within pair resemblance for changes in basal (panel A) and isoproterenol-stimulated (panel B) lipolyses in response to VLCD. Variations in lipolysis rates are expressed in µmol glycerol/106 cells·4 h.

View larger version (14K): [in this window] [in a new window]   Figure 2. Lipolytic effects of adrenergic agonists before () and during () VLCD. A, Lipolysis induced by epinephrine in the presence of 10-5 mol/L 2-adrenergic antagonist, RX821002; B, lipolysis induced by the nonselective ß-adrenergic agonist, isoproterenol. Values in panels A and B are expressed after subtraction of basal lipolysis. C, Antilipolysis induced by epinephrine in the presence of 2 µg/mL adenosine deaminase and 10-5 mol/L ß-adrenergic antagonist, propranolol. Values are expressed as percentage of adenosine deaminase-induced lipolysis after subtraction of basal lipolysis. Values are mean ± SD.

View larger version (13K): [in this window] [in a new window]   Figure 3. Detection of HSL in human adipocytes during (D) and before (B) VLCD. Fat-depleted infranatants (50 µg protein) were subjected to SDS-PAGE (8%) and electroblotting to nitrocellulose membranes. Western blot analysis was performed using an anti-HSL antibody and Enhanced Chemiluminescence detection. The results from four subjects are represented. rHSL, Recombinant rat HSL (84 kDa); hHSL, homogenates from COS cells transfected with an expression vector for human HSL (88 kDa).

	Discussion

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During calorie deprivation, triglycerides stored in adipose tissue are hydrolyzed into glycerol and free fatty acids, which become, with ketone bodies, the preferred fuels in the body. Under these conditions, an increase of plasma concentrations of glycerol and free fatty acids could be expected. In agreement with previous in vivo studies (24, 25), no change in the plasma levels of the metabolites was observed (Table 1). The increase of glycerol and free fatty acid concentrations induced by isoproterenol (Table 2) was higher during vs. before VLCD. In agreement with these results, acute exercise, a condition known to activate the sympathetic nervous system, has been shown to induce a higher rise of plasma glycerol during vs. before calorie restriction (24). However, the VLCD-induced increase of plasma glycerol and free fatty acid concentrations in response to isoproterenol may reflect more than the changes in in vivo adipose tissue lipolytic rates because the metabolite plasma levels are determined by both lipolysis and utilization rates.

At the cellular level, a moderate increase of ß-adrenergic sensitivity was observed (Fig. 2). The most prominent change was the 2-fold rise in basal lipolysis. During VLCD, an increase of basal lipolysis rate expressed on a per-cell basis has been reported in early studies (5, 6, 8). In some situations, basal and catecholamine-induced lipolyses are positively correlated with fat cell size when lipolysis rates are expressed per cell number (26, 27). To correct for fat cell size variations, results were expressed per cell surface area (Table 3). The VLCD-induced increase of lipolysis was similar using either mode of expression. These data show that the increase of lipolysis was independent of change in fat cell size. In the rat, a fasting-induced increase in basal lipolysis is associated with an increase of hormone-sensitive lipase expression (28). A similar relationship is found in man. Because hormone-sensitive lipase catalyzes the rate-limiting step in adipose tissue lipolysis, the increase in basal lipolysis during VLCD is likely to be caused by the increased hormone-sensitive lipase expression (Fig. 3). We have shown recently that long-term treatment of mouse adipocytes with cAMP produced a decrease of hormone-sensitive lipase activity and mRNA levels (29). Weight loss or energy restriction causes a decrease of basal sympathetic activity, as measured by lower basal norepinephrine level and appearance rate (30, 31). It remains to be seen whether a low sympathetic tone promotes an increase of hormone-sensitive lipase expression.

A major goal of the present study was to evaluate whether variations in the lipolytic response of sc adipocytes of individuals subjected to VLCD were related to the genotype of the subject. Before the treatment, significant intrapair resemblance was seen for basal and stimulated lipolysis rates expressed per cell number and per cell surface (Table 4). A similar observation has been reported by Bouchard and co-workers (22) for basal lipolysis of male monozygotic twins. The extent of the genetic contribution in basal lipolysis before VLCD is difficult to appreciate because similarities within twin pairs may result from shared genes as well as from shared family environment during childhood and youth. In our study, most pairs of twins had been reared together but were living apart at the time of the study. A significant genotype-calorie restriction interaction effect was seen for basal lipolysis and for lipolysis stimulated with agents acting on plasma membrane receptors. No intrapair resemblance was found with dibutyryl cAMP. These data suggest that the genetic factors controlling adipose tissue lipolysis increase during VLCD interact with proximal components of the lipolytic cascade. The precise level of interaction between genetic factors and fat cell lipolysis, however, remains to be determined.

In conclusion, energy restriction in moderately obese females resulted in an increased in vivo effect of the ß-adrenergic agonist isoproterenol on plasma free fatty acid and glycerol levels and a moderately increased in vitro sensitivity of the ß-adrenergic component of adipocyte lipolysis. The basal rates of lipolysis and hormone-sensitive lipase expression were increased during VLCD. The data also suggest that the genotype influences changes in sc adipose tissue lipolysis in response to VLCD.

	Acknowledgments

 
We thank Dr. Michel Meste (Université Paul Sabatier, Toulouse) for help with statistical analyses.

	Footnotes

 
¹ This work was supported in part by the Ministère de l’Enseignement Supérieur et de la Recherche and Groupe Danone. The laboratories involved in this study are members of the European Union BIOMED I Concerted Action on the Impairment of Adipose Tissue Metabolic Regulation as a Generator of Risk Factors for Cardiovascular Disease (EUROLIP).

Received July 31, 1996.

Revised November 6, 1996.

Accepted November 22, 1996.

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This Article Abstract Full Text (PDF) Submit a related Letter to the Editor Purchase Article View Shopping Cart Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Copyright Permission Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Stich, V. Articles by Langin, D. Search for Related Content PubMed PubMed Citation Articles by Stich, V. Articles by Langin, D.