Human beta-2 adrenoceptor gene polymorphisms are highly frequent in obesity and associate with altered adipocyte beta-2 adrenoceptor function.

Catecholamines play a central role in the regulation of energy expenditure, in part by stimulating lipid mobilization through lipolysis in fat cells. The beta-2 adrenoceptor (BAR-2) is a major lipolytic receptor in human fat cells. To determine whether known polymorphisms in codons 16, 27, and 164 of this receptor play a role in obesity and subcutaneous adipocyte BAR-2 lipolytic function, we investigated a group of 140 women with a large variation in body fat mass. Only the polymorphisms in codons 16 and 27 were common in the study population. The Gln27Glu polymorphism was markedly associated with obesity with a relative risk for obesity of approximately 7 and an odds ratio of approximately 10. Homozygotes for Glu27 had an average fat mass excess of 20 kg and approximately 50% larger fat cells than controls. However, no significant association with changes in BAR-2 function was observed. The Arg16Gly polymorphism was associated with altered BAR-2 function with Gly16 carriers showing a fivefold increased agonist sensitivity and without any change in BAR-2 expression. However, it was not significantly linked with obesity. These findings suggest that genetic variability in the human BAR-2 gene could be of major importance for obesity, energy expenditure, and lipolytic BAR-2 function in adipose tissue, at least in women.

Modifications of citric acid cycle activity and gluconeogenesis in streptozotocin-induced diabetes and effects of metformin.

To better define the modifications of liver gluconeogenesis and citric acid cycle, or Krebs' cycle, activity induced by insulin deficiency and the effects of metformin on these abnormalities, we infused livers isolated from postabsorptive or starved normal and streptozotocin-induced diabetic rats with pyruvate and lactate (labeled with [3-13C]lactate) with or without the simultaneous infusion of metformin. Lactate and pyruvate uptake and glucose production were calculated. The 13C-labeling pattern of liver glutamate was used to calculate, according to Magnusson's model, the relative fluxes through Krebs' cycle and gluconeogenesis. These relative fluxes were converted into absolute values using substrate balances. In normal rats, starvation increased gluconeogenesis, the flux through pyruvate carboxylase-phosphoenolpyruvate carboxykinase (PC-PEPCK), and the ratio of PC to pyruvate dehydrogenase (PDH) flux (P < 0.05); metformin induced only a moderate decrease in the PC:PDH ratio. Livers from postabsorptive diabetic rats had increased lactate and pyruvate uptakes (P < 0.05); their metabolic fluxes resembled those of starved control livers, with increased gluconeogenesis and flux through PC-PEPCK. Starvation induced no further modifications in the diabetic group. Metformin decreased glucose output from the liver of starved diabetic rats (P < 0.05). The flux through PC-PEPCK and also pyruvate kinase were decreased (P < 0.05) by metformin in both groups of diabetic rats. In conclusion, insulin deficiency increased in this model of diabetes gluconeogenesis through enhanced uptake of substrate and increased flux through PC-PEPCK; metformin decreased glucose production by reducing the flux through PC-PEPCK.

Reduced hormone-sensitive lipase activity is not a major metabolic defect in Finnish FCHL families.

The pathogenetic mechanisms behind familial combined hyperlipidemia (FCHL) are unknown. However, exaggerated postprandial lipemia and excessive serum free fatty acid (FFA) concentrations have drawn attention to altered lipid storage and lipolysis in peripheral adipose tissue. Hormone-sensitive lipase (HSL) is the enzyme responsible for intracellular lipolysis in adipocytes and a decrease of adipocyte HSL activity has been demonstrated in Swedish FCHL subjects. The aim of the study was to investigate if adipose tissue HSL activity had any effect on lipid phenotype and if low HSL activity and FCHL were linked in Finnish FCHL families. A total of 48 family members from 13 well-characterized Finnish FCHL families and 12 unrelated spouses participated in the study. FCHL patients with different lipid phenotypes (IIA, IIB, IV) did not differ in adipose tissue HSL activity from each other or from the 12 normolipidemic spouses (P = 0.752). In parametric linkage analysis using an affecteds-only strategy the low adipose tissue HSL activity was not significantly linked with FCHL phenotype. However, we found a significant sibling-sibling correlation for the HSL trait (0.51, P < 0.01). Thus, a modifying or interacting role of HSL in the pathogenesis of FCHL could not be excluded.

Measuring glycerol turnover, gluconeogenesis from glycerol, and total gluconeogenesis with [2-13C] glycerol: role of the infusion-sampling mode.

Mass isotopomer distribution analysis (MIDA) of glucose during infusion of [2-13C]glycerol is a new method for measuring total gluconeogenesis (GNG). Since this method relies on calculation of the isotopic enrichment (IE) of hepatic triose phosphates (TP), the results should be independent of the sites of tracer infusion and blood sampling. Postabsorptive and starved rats were infused with [2-13C]glycerol and sampled either in the arterial-venous (A-V) or venous-arterial (V-A) modes. Blood was also sampled from the portal vein. In both postabsorptive and starved rats, glycerol turnover rate (Rt) and the percent contribution of glycerol to total glucose production were higher in the A-V mode than in the V-A mode (P < .05). Glycerol IE in portal venous blood was intermediate between IE values observed in peripheral arterial and venous blood. Its use for calculating the contribution of glycerol to glucose production reconciled the results obtained with the two infusion-sampling modes in both postabsorptive and starved rats; this contribution was increased by starvation (P < .01). In postabsorptive rats, total GNG calculated from MIDA of glucose accounted for approximately 50% of glucose production whatever the infusion-sampling mode (A-V, 48.8% +/- 4.7%; V-A, 52.2% +/- 3.9%). This contribution increased to 90% in starved rats, again, with no difference between A-V (95.2% +/- 1.8%) and V-A (89.2% +/- 1.3%) modes. In conclusion, during infusion of [2-13C]glycerol, total GNG measured from MIDA of glucose is independent of the infusion-sampling mode, contrary to calculations of Rt and GNG from glycerol. Measurement of glycerol IE in portal venous blood reconciles the results obtained with the two modes with respect to the contribution of glycerol to GNG.

Glucose production and gluconeogenesis in postabsorptive and starved normal and streptozotocin-diabetic rats.

Using a 3-hour primed-continuous infusion of [3-3H]glucose and [2-13C]glycerol, we measured glucose production, gluconeogenesis from glycerol, and total gluconeogenesis (using mass isotopomer distribution analysis [MIDA] of glucose) in postabsorptive and starved normal and streptozotocin-diabetic rats. In normal rats, 48 hours of starvation increased (P < .01) the percent contribution of both gluconeogenesis from glycerol (from 14.4% +/- 1.8% to 25.5% +/- 4.0%) and total gluconeogenesis (from 52.2% +/- 3.9% to 89.8% +/- 1.3%) to glucose production, but the absolute gluconeogenic fluxes were not modified, since glucose production decreased. Diabetic rats showed increased glucose production in the postabsorptive state; this decreased with starvation and was comparable to the of controls after 48 hours of starvation. Gluconeogenesis was increased in postabsorptive diabetic rats (69.0% +/- 1.3%, P < .05 v controls). Surprisingly, this contribution of gluconeogenesis to glucose production was not found to be increased in 24-hour starved diabetic rats (64.4% +/- 2.4%). These rats had significant liver glycogen stores, but gluconeogenesis was also low (42.8% +/- 2.1%) in 48-hour starved diabetic rats deprived of glycogen stores. Moreover, in 24-hour starved diabetic rats infused with [3-13C]lactate, gluconeogenesis was 100% when determined by comparing circulating glucose and liver pyruvate enrichment, but only 47% +/- 3% when calculated from the MIDA of glucose. Therefore, MIDA is not a valid method to measure gluconeogenesis in starved diabetic rats. This was not explained by differences in the labeling of liver and kidney triose phosphates: functional nephrectomy of starved diabetic rats decreased glucose production, but gluconeogenesis calculated by the MIDA method was only 48% +/- 3.3%. We conclude that (1) diabetic rats have increased glucose production and gluconeogenesis in the postabsorptive state; (2) starvation decreases glucose production and increases the contribution of gluconeogenesis, but MIDA is not an appropriate method in this situation; and (3) the kidneys contribute to glucose production in starved diabetic rats.

Regulation of lipolysis in humans. Pathophysiological modulation in obesity, diabetes, and hyperlipidaemia.

Adipose tissue is considered as the body's largest storage organ for energy in the form of triglycerides, which are mobilised through the lipolysis process to provide fuel to other organs and to deliver substrates to liver for gluconeogenesis (glycerol) and lipoprotein synthesis (free fatty acids). The release of glycerol and free fatty acids is intensively regulated by hormones and agents. In man, the major hormones are insulin (inhibition of lipolysis) and catecholamines (stimulation of lipolysis). Physiological factors such as dieting, physical exercise and ageing also regulate lipolysis. The lipolytic process is modified in pathological conditions, e.g. obesity (both upper and lower obesity), diabetes (non- and insulin-dependent diabetes mellitus), and dyslipidaemia (in particular, familial combined hyperlipidaemia). The regulation of lipolysis is complex because of the heterogeneity of fat depots (visceral versus subcutaneous), which may contribute to the well-known gender differences in accumulation of fat. Since visceral fat depot is directly drained into the liver and has a high turnover of visceral triglycerides, "portal" free fatty acids seem to be an important pathophysiological factor in common complications of obesity (in particular, metabolic syndrome). New advances in genetic studies indicate that polymorphisms in several genes encoding for proteins that regulate the lipolysis process are important for the development of obesity and its complications.

In vivo studies of intrahepatic metabolic pathways.

In vivo studies of liver metabolism have long been limited to measurement by the balance technique or isotope dilution method of the amounts of substrates taken up or produced by the liver. New methods, based mainly on the use of stable isotopes, now allow important data to be obtained on intrahepatic metabolic pathways. Nuclear magnetic resonance and chemical biopsy of glucuronic acid by acetaminophen facilitate the study of glycogen metabolism. Chemical biopsies of liver glutamine by phenylacetate and of cytosolic acetylCoA by sulfamethoxazole provide important data respectively on Krebs cycle activity and gluconeogenesis and on lipogenesis and cholesterol synthesis. Mass isotopomer distribution analysis of molecules synthesised during infusion of 13C-labelled precursors allows an estimation of in vivo gluconeogenesis as well as cholesterol synthesis and lipogenesis. Finally, these metabolic pathways can be studied through the incorporation of deuterium from deuterated water in glucose, fatty acids and cholesterol. All these non-invasive techniques allow investigations to be undertaken in human beings to study the nutritional and hormonal regulation of liver metabolism in normal subjects and in pathological situations.

Metabolism of lipids in human white adipocyte.

Adipose tissue is considered as the body's largest storage organ for energy in the form of triacylglycerols, which are mobilized through lipolysis process, to provide fuel to other organs and to deliver substrates to liver for gluconeogenesis (glycerol) and lipoprotein synthesis (free fatty acids). The release of glycerol and free fatty acids from human adipose tissue is mainly dependent on hormone-sensitive lipase which is intensively regulated by hormones and agents, such as insulin (inhibition of lipolysis) and catecholamines (stimulation of lipolysis). A special attention is paid to the recently discovered perilipins which could regulate the activity of the lipase hormono-sensible. Most of the plasma triacylglycerols are provided by dietary lipids, secreted from the intestine in the form of chylomicron or from the liver in the form of VLDL. Released into circulation as non-esterified fatty acids by lipoprotein lipase, those are taken up by adipose tissue via specific plasma fatty acid transporters (CD36, FATP, FABPpm) and used for triacylglycerol synthesis. A small part of triacylglycerols is synthesized into adipocytes from carbohydrates (lipogenesis) but its regulation is still debated in human. Physiological factors such as dieting/fasting regulate all these metabolic pathways, which are also modified in pathological conditions e.g. obesity.

Measuring gluconeogenesis with [2-13C]glycerol and mass isotopomer distribution analysis of glucose.

We tested the validity of the use of [2-13C]glycerol and of the mass isotopomer distribution analysis of glucose for measuring gluconeogenesis in vitro and in vivo. When isolated rat livers (starved for 48 h) were infused with labeled glycerol without or with lactate+pyruvate, gluconeogenesis accounted for > 90% of glucose production. When glucose was added to the infusate so that glucose produced by the liver represented only 80 or 45% of total glucose output, this dilution could be calculated from the mass isotopomer distribution of glucose. When postabsorptive and starved rats were infused with [2-13C]glycerol, gluconeogenesis accounted for 54 +/- 2 and 89 +/- 1%, respectively, of glucose production. However, accurate measures could be obtained, particularly in postabsorptive rats, only with high tracer infusion rates (representing > or = 50% of endogenous glycerol production rate). In both groups of rats, these infusion rates resulted in an increase in total glycerol turnover rate and gluconeogenesis from glycerol. In addition, hepatic concentration of glycerol 3-phosphate was increased. In conclusion, [2-13C]glycerol infusion and mass isotopomer distribution analysis of glucose appear to be useful methods for studies of gluconeogenesis in vitro and in vivo; however, accurate measurements in vivo can be obtained only at the expense of some perturbation of the metabolic pathway studied.

Lactate and pyruvate isotopic enrichments in plasma and tissues of postabsorptive and starved rats.

It has been proposed that plasma pyruvate isotopic enrichment (IE) during infusion of labeled lactate could be used to estimate the intracellular IE of lactate and pyruvate and thus to calculate their turnover rate. We determined the relations of plasma and tissue IE of lactate and pyruvate in anesthetized rats infused with [3-13C]lactate in an artery and sampled from a vein (A-V mode) or infused in a vein and sampled from an artery (V-A mode). In both groups of rats, the ratio of tissue to plasma lactate IE was < 1 with large differences between tissues: the highest ratio was observed in heart and the lowest in soleus. With the exception of liver, this ratio was higher in the A-V than in the V-A mode. Pyruvate IE was lower than lactate IE in tissues, with a few exceptions, and in plasma. This ratio of pyruvate to lactate IE was approximately 0.70 in plasma in A-V and V-A modes. Moreover pyruvate IE was also always higher in plasma than in tissues. This seemingly surprising result could be explained by the production of labeled pyruvate from labeled lactate inside the circulation by erythrocytes, because we observed a rapid isotopic equilibrium between lactate and pyruvate in blood "in vitro." Apparent lactate turnover was higher in the A-V than in the V-A mode when it was calculated using lactate as well as pyruvate IE. Therefore plasma pyruvate IE cannot be used in rats to estimate tissue IE and did not reconcile turnover rates measured using the A-V or V-A mode.(ABSTRACT TRUNCATED AT 250 WORDS)

New methods for in vivo studies of hepatic metabolism.

In vivo studies of liver metabolism have been limited for a long time to measurements, by the balance technique or the isotope dilution method, of the amounts of substrates taken up or produced by liver. New methods have been developed that now permit us to obtain important information on intrahepatic metabolic pathways. Nuclear magnetic resonance permits noninvasive studies of liver glycogen synthesis and breakdown. Chemical biopsy of glucuronic acid by acetaminophen also permits the study of glycogen synthesis whereas chemical biopsies of liver glutamine by phenylacetate and of cytosolic acetyl-CoA by sulfamethoxazole give important information concerning, respectively, Krebs cycle activity and glconeogenesis and on lipogenesis and cholesterol synthesis. Mass isotopomer distribution analysis of molecules synthesized during the infusion of a deuterium of 13C-labeled precursor permits the estimation of in vivo gluconeogenesis as well as cholesterol synthesis and lipogenesis. Finally, these metabolic pathways can be studied through the incorporation of deuterium from deuterated water in glucose, fatty acids and cholesterol. All these noninvasive techniques will allow investigations to be undertaken in humans, addressing the nutritional and hormonal regulation of liver metabolism in normal subjects and in pathological situations.

Non-invasive tracing of liver intermediary metabolism in normal subjects and in moderately hyperglycaemic NIDDM subjects. Evidence against increased gluconeogenesis and hepatic fatty acid oxidation in NIDDM.

To test whether gluconeogenesis is increased in non-insulin-dependent diabetic (NIDDM) patients we infused (post-absorptive state) healthy subjects and NIDDM patients with [6,6-2H2]glucose (150 min) and [3-13C]lactate (6 h). Liver glutamine was sampled with phenylacetate and its labelling pattern determined (mass spectrometry) after purification of the glutamine moiety of urinary phenylacetylglutamine. After correction for 13CO2 re-incorporation (control test with NaH13CO3 infusion) this pattern was used to calculate the dilution factor (F) in the hepatic oxaloacetate pool and fluxes through liver Krebs cycle. NIDDM patients had increased lactate turnover rates (16.18+/-0.92 vs 12.14+/-0.60 micromol x kg(-1) x min(-1), p < 0.01) and a moderate rise in glucose production (EGP) (15.39+/-0.87 vs 12.52+/-0.28 micromol x kg(-1) x min(-1) , p = 0.047). Uncorrected contributions of gluconeogenesis to EGP were 31+/-3 % (control subjects) and 17+/-2 % (NIDDM patients). F was comparable (1.34+/-0.02 and 1.39 0.09, respectively) and the corrected percent and absolute contributions of gluconeogenesis were not increased in NIDDM (25+/-3 % and 3.8+/-O.5 micromol x kg(1) x min[-1]) compared to control subjects (41+/-3 % and 5.1+/-0.4 micromol x kg(-1) x min(-1]). The calculated pyruvate carboxylase over pyruvate dehydrogenase activity ratio was comparable (12.1+/-2.6 vs 11.2+/-1.4). Lastly hepatic fatty oxidation, as estimated by the model, was not increased in NIDDM (1.8+/-0.4 vs 1.6+/-0.1 micromol x kg(-1) x min[-1]). In conclusion, in the patients studied we found no evidence of increased hepatic fatty oxidation, or, despite the increased lactate turnover rate, an increased gluconeogenesis.

Use of labeling pattern of liver glutamate to calculate rates of citric acid cycle and gluconeogenesis.

The use of the labeling pattern of hepatic glutamate during infusion of L-[3-13C]- or [3-14C]lactate to calculate rates of citric acid cycle activity and gluconeogenesis has been proposed. We tested the validity of this approach by perfusing isolated rat livers (48 h starved) with pyruvate and lactate (10% enriched with [3-13C]lactate) without (control) or with infusion of glucagon (to inhibit pyruvate kinase), mercaptopicolinate (to inhibit phosphoenolpyruvate carboxykinase), or dichloroacetate (to stimulate pyruvate dehydrogenase). Compared with control experiments, glucagon increased glucose output (P < 0.05) and decreased the calculated flux through pyruvate kinase (P < 0.05). Mercaptopicolinate almost totally suppressed glucose production and dramatically reduced the calculated gluconeogenic rate and flux through phosphoenolpyruvate carboxykinase (P < 0.001). Dichloroacetate moderately increased the calculated flux through pyruvate dehydrogenase (P < 0.05). In experiments with perfused livers from fed rats, the calculated gluconeogenic rate and flux through phosphoenolpyruvate carboxykinase were very low compared with control experiments (P < 0.001), whereas the pyruvate dehydrogenase flux was increased (P < 0.05). Therefore, the expected modifications of the citric acid cycle activity and gluconeogenic rate were clearly detected using the labeling pattern of glutamate to calculate these metabolic rates. Except for the perfusions with mercaptopicolinate, the dilution by isotopic exchange in the oxaloacetate pool calculated from the model agreed with the actual dilution of enrichment between liver pyruvate and phosphoenolpyruvate. The present results support the validity of this approach to trace liver metabolism.

Sex differences in visceral fat lipolysis and metabolic complications of obesity.

Cardiovascular complications of obesity are more common in men than women. Sex differences in visceral fat lipolysis may be of importance in this respect, since increased release of free fatty acids (FFAs) from visceral fat to the liver by the portal venous system has been thought to cause several metabolic complications due to obesity, such as hypertension, hyperlipidemia, and glucose intolerance. The aim of this study was to investigate sex differences in clinical characteristics and visceral fat mobilization in obesity. Obese subjects (22 male and 23 female) undergoing elective surgery were matched for body mass index and age. The males had both higher waist-to-hip ratio (WHR), sagittal diameter, blood pressure, fat-cell volume, plasma insulin, glucose, and triglyceride and lower HDL cholesterol levels than the females. The rate of norepinephrine-induced FFA and glycerol release was twofold higher in men (P = .02). No significant reutilization of FFA was observed. The difference in maximum norepinephrine-induced rate of lipolysis between men and women was independent of both WHR and sagittal diameter and was an independent regressor for levels of plasma glucose and plasma HDL cholesterol. Fat-cell volume was an independent regressor for plasma triglycerides and blood pressure. No sex differences in the lipolytic sensitivity to beta 1- or beta 2-adrenoceptor-specific agonists or in the antilipolytic effect of insulin were observed. However, the lipolytic beta 3-adrenoceptor sensitivity was 12 times higher (P = .004) and the antilipolytic alpha 2-adrenoceptor sensitivity 17 times lower (P = .003) in men. Furthermore, lipolysis induced by agents acting at the adenylate cyclase and protein kinase A levels were almost twofold enhanced in men. However, no sex difference in maximum hormone-sensitive lipase activity was observed. In conclusion, in obesity, catecholamine-induced rate of FFA mobilization from visceral fat to the portal venous system is higher in men than women. This phenomenon is partly due to a larger fat-cell volume but also to a decrease in the function of alpha 2-adrenoceptors, an increase in the function of beta 3-adrenoceptors, and an increased ability of cyclic AMP to activate hormone-sensitive lipase. These factors may contribute to gender-specific differences in metabolic and cardiovascular disturbances accompanied by obesity.

Determination of (13C) urea enrichment by gas chromatography/mass spectrometry and gas chromatography/isotope ratio mass spectrometry.

We present gas chromatographic/mass spectrometric and gas chromatographic/isotope ratio mass spectrometric assays of the 13C enrichment of plasma urea converted to its dimethylaminomethylene derivative. The limits of sensitivity of the two techniques are 0.2% and 0.02%, respectively. The techniques were tested in rats and humans infused with (13C)urea or (3-13C)lactate. (13C)Urea enrichment during the infusion of (3-13 C)lactate in humans was not detectable by gas chromatography/mass spectrometry but was easily measured by gas chromatography/isotope ratio mass spectrometry. These assays should be useful for clinical investigations, in which the incorporation of a (13C)gluconeogenic substrate into glucose must be corrected for the incorporation of 13CO2 derived from the oxidation of the substrate. This correction involves measuring the low-level 13C enrichment of urea.

Noninvasive tracing of human liver metabolism: comparison of phenylacetate and apoB-100 to sample glutamine.

The labeling pattern of hepatic glutamine during infusion of [3-13C]lactate provides information on liver intermediary metabolism and allows us to correct apparent gluconeogenic rates for isotopic dilution in the oxaloacetate (OAA) pool. Liver glutamine can be sampled by its conjugation with phenylacetate to form phenylacetylglutamine (PAGN) but also by purifying the glutamine of the apolipoproteinB-100 of very low-density lipoprotein (apoB-100-VLDL). We compared these methods in normal and non-insulin dependent diabetes subjects. We tested also whether apoB-100-VLDL alanine enrichment could solve the problem of dilution of gluconeogenic precursor enrichments between peripheral blood and liver (prehepatic dilution). In both normal and diabetic subjects, the labeling patterns of glutamine obtained from PAGN or apoB-100-VLDL were comparable. Therefore, metabolic fluxes and correction factors for dilution in the OAA pool were also comparable. With both methods, gluconeogenic rates were not increased in diabetic patients. Use of the enrichment of apoB-100-VLDL alanine to correct for prehepatic dilution led to high estimates of gluconeogenesis; it remains uncertain whether this enrichment provides a correct estimate of liver pyruvate enrichment.

Various phosphodiesterase subtypes mediate the in vivo antilipolytic effect of insulin on adipose tissue and skeletal muscle in man.

The antilipolytic effect of insulin on human abdominal subcutaneous adipose tissue and skeletal muscle during local inhibition of cAMP-phosphodiesterases (PDEs) was investigated in vivo, by combining microdialysis with a euglycaemic, hyperinsulinaemic clamp. During hyperinsulinaemia, the glycerol concentration decreased by 40% in fat and by 33% in muscle. Addition of the selective PDE3-inhibitor amrinone abolished the insulin-induced decrease in adipose glycerol concentration, but did not influence the glycerol concentration in skeletal muscle. Nor did the PDE4-selective inhibitor rolipram or the PDE5-selective inhibitor dipyridamole influence the insulin-induced decrease in muscle tissue glycerol. However, the non-selective PDE-inhibitor theophylline counteracted the antilipolytic action of insulin at both sites. The specific activity of PDEs was also determined in both tissues. PDE3-activity was 36.8+/-6.4 pmol x min(-1) x mg(-1) in adipose tissue and 3.9+/-0.5 pmol x min(-1) x mg(-1) in muscle. PDE4-activity in skeletal muscle was high, i.e., 60.7+/-10.2 pmol x min(-1) x mg(-1) but 8.5 pmol x min(-1) x mg(-1) or less in adipose tissue. In conclusion, insulin inhibits lipolysis in adipose tissue and skeletal muscle by activation of different PDEs, suggesting a unique metabolic role of muscle lipolysis.

Lipolysis in human fat cells obtained under local and general anesthesia.

OBJECTIVES: As adipose tissue is usually obtained during local or general anesthesia in clinical studies, these two forms of anesthesia were presently compared as regards lipolysis induced by catecholamines in isolated human fat cells. DESIGN: Fat samples from the abdominal subcutaneous region were obtained first during local anesthesia (lidocaine) given so that the anesthetic agent did not influence lipolysis and second, during gastric banding under general anesthesia (propofol) immediately after skin incision. SUBJECTS: Eleven obese patients, drug free and otherwise healthy. MEASUREMENTS: Isolated fat cells were incubated in the presence or absence of increasing concentrations of different lipolysis agents, acting at adrenoceptor or various post-receptor levels in the lipolytic cascade. Glycerol release to the incubation medium was measured as an index of lipolysis. RESULTS: All agonists caused a concentration dependent increase (terbutaline, dobutamine, CGP 12177, forskolin, dibutyryl cyclic AMP, isoprenaline and noradrenaline) or inhibition (clonidine) of glycerol release. The comparison of data from local and general anesthesia procedures showed no statistical difference in glycerol response for any of the drugs used. CONCLUSIONS: Adrenergic regulation of lipolysis is not influenced by the mode of sampling, at least not in subcutaneous fat cells of obese subjects obtained during local anesthesia with lidocaine as compared to general anesthesia with propofol.

The different effects of a Gln27Glu beta 2-adrenoceptor gene polymorphism on obesity in males and in females.

OBJECTIVES: To investigate the role of a polymorphism in codon 27 (Gln27Glu) of the beta 2-adrenoceptor gene for obesity in males compared to previously investigated females with an association of this polymorphism to obesity. DESIGN: Population-based study. SETTING: Medical department at a University Hospital. SUBJECTS: A total of 138 non-related Swedish males with body mass indexes (BMI) in the range 19.4-53.4 kg m-2 were recruited as: healthy volunteers, healthy obese subjects and subjects undergoing surgery for uncomplicated gallstone or abdominal hernia. In order to investigate the impact of gender, the results were compared with a subset of an earlier investigated female population of 109 Swedish females. Obesity was defined as a BMI > 27 kg m-2. MAIN OUTCOME MEASURES: Genotype examination of beta 2-adrenoceptor polymorphism in codon 27 with polymerase chain reaction and restriction fragment length polymorphism. RESULTS: The allele frequency of Gln27 and Glu27 did not differ between males and females when obese and non-obese subjects were investigated together. However, in obese males, the frequency of the Glu27 allele was significantly decreased (P = 0.034), whereas the frequency of this allele was increased in obese females (P = 0.013). No impact of the female androgen status on the distribution of the Gln27Glu polymorphism could be demonstrated in the obese females. CONCLUSION: A positive association between obesity and the Glu27 genetic variant in the beta 2-adrenoceptor exists in females, whereas in males there is a negative correlation between Glu27 and obesity. The findings suggest that different genetic factors contribute to obesity in males and females.

Decreased expression and function of adipocyte hormone-sensitive lipase in subcutaneous fat cells of obese subjects.

Decreased lipolytic effect of catecholamines in adipose tissue has repeatedly been demonstrated in obesity and may be a cause of excess accumulation of body fat. However, the mechanisms behind this lipolysis defect are unclear. The role of hormone-sensitive lipase was examined using abdominal subcutaneous adipocytes from 34 obese drug-free and otherwise healthy males or females and 14 non-obese control subjects. The enzyme catalyzes the rate-limiting step of the lipolysis pathway. The maximum lipolytic capacity of fat cells was significantly decreased in obesity when measured using either a non-selective beta-adrenergic receptor agonist (isoprenaline) or a phosphodiesterase resistant cyclic AMP analogue (dibutyryl cyclic AMP). Likewise, enzyme activity, protein expression, and mRNA of hormone-sensitive lipase were significantly decreased in adipocytes of obese subjects. The findings were not influenced by age or gender. The data suggest that a decreased expression of hormone-sensitive lipase in subcutaneous fat cells, which in turn causes decreased enzyme function and impaired lipolytic capacity of adipocytes, is present in obesity. Impaired expression of the hormone-sensitive lipase gene might at least in part explain the enzyme defect.