Norepinephrine-induced Lipolysis Research Articles

Transcriptome analysis of norepinephrine-induced lipolysis in differentiated adipocytes of Bama pig

Sympathetic innervation of white adipose tissue (WAT) plays a key role in the regulation of lipid metabolism. Sympathetic activation promotes release of norepinephrine (NE), which binds to adrenergic receptors on adipocytes, promoting adipocyte lipolysis and enhanced oxidative metabolism. However, the mechanism by which sympathetic nerves regulate lipid metabolism in pig adipose tissue remains unclear. We used NE to simulate the process of sympathetic driving in pig adipocytes. RNA sequencing (RNA-seq) was used to determine the gene expression profile of pig adipocytes responding to NE stimulation. Our data suggests that the lipolytic signaling pathway is activated in pig adipocytes upon acute stimulation of NE, resulting in enhanced lipid metabolism and lipolysis, consistent with the phenomena found in humans and mice. Specifically, differentially expressed protein coding genes (PCGs) (SIRT4, SLC27A1) are mainly associated with functions that inhibit fatty acid oxidation and promote lipid synthesis. Similarly, we investigated the changes in regulatory transcripts such as long non-coding RNAs (lncRNAs) and transcripts of uncertain coding potential (TUCP) in response to NE and found that differentially expressed lncRNAs (lncG47338, lncG30660, lncG29516, lncG3790) and TUCP (TUCP_G38001) were co-expressed with target genes related to the promotion of fatty acid β-oxidation, lipolysis and oxidative metabolism, thus acting as regulators. These results indicate a broad suite of gene expression alterations in response to NE stimulation and promote the understanding of the molecular mechanisms by which NE regulates lipid metabolism in pigs.

1647-P: Novel Functions of CXCL12 as a Brown Adipocyte–Derived Secreted Factor

The capacity of brown adipose tissue (BAT) to regulate metabolism through cold-induced thermogenesis and secretion of molecules appeals as a potential therapeutic against metabolic disease. BAT secreted factors have gained interest as they may coordinate the adaptive response to cold and tissue remodeling. Yet, BAT secretory functions need deeper investigation before identifying druggable candidates. Thus, our group aimed to study secreted factors from active brown adipocytes that may sway adipocyte function and/or may orchestrate inter-cellular communications. For this, mRNA levels in mature adipocytes of brown, beige and white adipose depots from mice exposed to 21 days of cold were evaluated using RNA sequencing, and bioinformatic analysis was used to filter for potentially secreted factors. Cxcl12 was found to be the most cold-induced chemokine specifically in BAT. mRNA expression analysis of Cxcl12 by qPCR and fluorescence in-situ hybridization revealed its enrichment in brown adipocytes upon cold. Cold also increased CXCL12 levels in BAT media but not plasma, indicating a potential local action. Cxcl12 knockdown in active brown adipocytes impaired thermogenesis, estimated by Ucp1 gene expression, norepinephrine-induced lipolysis and mitochondrial respiration, despite intact β-adrenergic signaling, as estimated by immunoblotting of phosphorylated proteins. Together, these data suggest that Cxcl12 regulates adipocyte function independently from the β-adrenergic pathway. Additionally, CXCL12 exerted inter-cellular crosstalks by promoting macrophage chemotaxis and neurite outgrowth in vitro. Here we present CXCL12 as a novel brown adipocyte, cold-induced secreted factor involved in adipocyte function and inter-cellular crosstalk within BAT. Further characterization of the role of CXCL12 and other secreted factors in BAT will provide valuable knowledge on the adaptive mechanisms of BAT to cold and may open new avenues to leverage BAT functions for the treatment of metabolic disease. Disclosure M.Agueda oyarzabal: None. M.Tozzi: None. T.W.Schwartz: None. C.C.Schéele: Research Support; Novo Nordisk A/S. B.Emanuelli: None. K.Plucinska: None. M.Isidor: None. L.R.Ingerslev: None. P.Petersen: None. O.Dmytriyeva: None. J.Henningsen: None. E.Brown: None. K.Rupar: None. Funding Novo Nordisk Foundation (18CC0034900, 19SA0035436); Copenhagen Bioscience PhD Program

Taiwanese green propolis ethanol extract promotes adipocyte differentiation and alleviates TNF-α-mediated downregulation of adiponectin expression

Abstract The objective was to examine the effects of Taiwanese green propolis (TGP) ethanol extract on adipocyte differentiation and lipolysis. TGP ethanol extract significantly enhanced the differentiation of murine mesenchymal stem cells into adipocytes, and this was accompanied by an increase in intracellular triglyceride content and adiponectin levels. TGP ethanol extract significantly increased the expression of adipogenic transcription factor-associated genes in murine mesenchymal stem cells after hormonal induction of adipogenesis. TGP ethanol extract was able to alleviate norepinephrine-induced lipolysis in differentiated adipocytes, which was accompanied by a decrease in lipolytic gene expression. Besides, TGP ethanol extract could reduce the tumor necrosis factor-α (TNF-α)-mediated inhibition of adiponectin gene expression and secretion during adipogenic differentiation of mesenchymal stem cells and in differentiated adipocytes. These results demonstrate that TGP ethanol extract enhances adipocyte differentiation and is capable of reversing the inhibitory effects of TNF-α on adipocyte differentiation and adiponectin expression in differentiated adipocytes.

MetAP2 inhibition increases energy expenditure through direct action on brown adipocytes

Inhibitors of methionine aminopeptidase 2 (MetAP2) have been shown to reduce body weight in obese mice and humans. The target tissue and cellular mechanism of MetAP2 inhibitors, however, have not been extensively examined. Using compounds with diverse chemical scaffolds, we showed that MetAP2 inhibition decreases body weight and fat mass and increases lean mass in the obese mice but not in the lean mice. Obesity is associated with catecholamine resistance and blunted β-adrenergic receptor signaling activities, which could dampen lipolysis and energy expenditure resulting in weight gain. In the current study, we examined effect of MetAP2 inhibition on brown adipose tissue and brown adipocytes. Norepinephrine increases energy expenditure in brown adipose tissue by providing fatty acid substrate through lipolysis and by increasing expression of uncoupled protein-1 (UCP1). Metabolomic analysis shows that in response to MetAP2 inhibitor treatment, fatty acid metabolites in brown adipose tissue increase transiently and subsequently decrease to basal or below basal levels, suggesting an effect on fatty acid metabolism in this tissue. Treatment of brown adipocytes with MetAP2 inhibitors enhances norepinephrine-induced lipolysis and energy expenditure, and prolongs the activity of norepinephrine to increase ucp1 gene expression and energy expenditure in norepinephrine-desensitized brown adipocytes. In summary, we showed that the anti-obesity activity of MetAP2 inhibitors can be mediated, at least in part, through direct action on brown adipocytes by enhancing β-adrenergic-signaling-stimulated activities.

Fat expansion through norepinephrine catabolism

Certain macrophage populations limit norepinephrine-induced lipolysis in adipose tissues in response to aging or obesity.

Toward a Neuroimmunoendocrinology of Adipose Tissue.

Our understanding of the interactions between the different cell types populating endocrine organs has reached an unprecedented degree of complexity. This is particularly true of white adipose tissue, which until recently, was viewed as a passive lipid storage depot. The discovery of circulating factors secreted from adipocytes, including leptin (1), however, sparkled interest for adipose tissue as an endocrine organ that can modulate metabolic pathways at the organismal level (2, 3). Immunologists and neuroscientists also became increasingly interested in adipose tissue. In particular, there is a growing area of research concerned with the relations between adipocytes, resident macrophages and the sympathetic nervous system in the control of lipolysis, thermogenesis, insulin resistance, and the switch from white to brown fat (4–9). Moreover, ongoing research is trying to establish the functional relevance of brown adipose tissue in humans in situations of elevated sympathetic outflow (eg, cold) (10). Lastly, adding to the complexity of the aforementioned interactions and blurring the lines between conventional scientificdisciplines, adipocytes andadiposemacrophages have been discovered to release proinflammatory factors and neurotransmitters, respectively (11, 12). Therefore, adipose tissue is progressively being revisited as an important site of convergence for multiple regulatory systems, including, most notably, the nervous and immune systems. In this issue of Endocrinology, Tang et al (13) provided additional evidence of the complex interactions that exist between adipocytes, sympathetic nerves, and macrophages. Briefly, using a combination of in vivo and in vitro experiments, the authors established that norepinephrine derived from the sympathetic nervous system constitutively down-regulated the expression of TNFin mouse white and brown adipose tissues (Figure 1). More interestingly, using pharmacology and several knock-out models, they narrowed down the signaling pathways responsible for the immunosuppressive actions of norepinephrine (13). Specifically, the 2-adrenergic receptor and protein kinase A signaling pathways were shown to be required for the downregulation of TNFin adipose macrophages. In contrast, the 3-adrenergic receptor mediated norepinephrine-induced lipolysis. To the best of my knowledge, relatively few studies have examined the immunomodulatory role of the sympatheticnervoussystemonadipose tissue.However,one previous study (14) demonstrated that the administration of leptin in ob/ob mice was correlated with an adrenergic-dependent accumulation of antiinflammatory markers in adiposemacrophages.Overall, the2aforementionedstudiesare consistent with one another. In my view, the above results are not entirely surprising given the known immunosuppressive effects of the sympathetic nervous system when activated by psychogenic stressors (15). Interestingly, the aforementioned neuroimmune interactions appear to be under the control of the hypothalamic neuropeptide Agouti-related protein (AgRP) (Figure 1). Specifically, the acute intracerebroventricular administration of AgRP induced a 2-fold increase in the levels of TNFmRNA in white adipose tissue, but not in brown adipose tissue (13). Although fasting greatly stimulates the activity of AgRP neurons (16), it is also associated with a complex chain of events in white adipose tissue, including a transient rise in inflammatory markers, lipolysis, and infiltration of immune cells (17–19). In light of the data provided by Tang et al (13), altered sympathetic signaling in macrophages may contribute to the intraadipose adaptations seen in response to fasting. Of

Green tea catechins enhance norepinephrine-induced lipolysis via a protein kinase A-dependent pathway in adipocytes

Green tea catechins have been shown to attenuate obesity in animals and humans. The catechins activate adenosine monophosphate-activated protein kinase (AMPK), and thereby increase fatty acid oxidation in liver and skeletal muscles. Green tea catechins have also been shown to reduce body fat in humans. However, the effect of the catechins on lipolysis in adipose tissue has not been fully understood. The aim of this study was to clarify the effect of green tea catechins on lipolysis in adipocytes and to elucidate the underlying mechanism. Differentiated mouse adipocyte cell line (3T3-L1) was stimulated with green tea catechins in the presence or absence of norepinephrine. Glycerol and free fatty acids in the media were measured. Phosphorylation of hormone-sensitive lipase (HSL) was determined by Western blotting, and the mRNA expression levels of HSL, adipose triglyceride lipase (ATGL), and perilipin were determined by quantitative RT-PCR. The cells were treated with inhibitors of protein kinase A (PKA), protein kinase C (PKC), protein kinase G (PKG), or mitogen-activated protein kinase (MAPK) to determine the responsible pathway. Treatment of 3T3-L1 adipocytes with green tea catechins increased the level of glycerol and free fatty acids released into the media in the presence, but not absence, of norepinephrine, and increased the level of phosphorylated HSL in the cells. The catechins also increased mRNA and protein levels of HSL and ATGL. PKA inhibitor (H89) attenuated the catechin-induced increase in glycerol release and HSL phosphorylation. The results demonstrate that green tea catechins enhance lipolysis in the presence of norepinephrine via a PKA-dependent pathway in 3T3-L1 adipocytes, providing a potential mechanism by which green tea catechins could reduce body fat.

Effects of Prostaglandin F2αon Adipocyte Biology Relevant to Graves' Orbitopathy

In Graves' orbitopathy (GO), increased proliferation, excess adipogenesis, and hyaluronan overproduction produce GO exophthalmos. Enophthalmos occurs in some glaucoma patients treated with Bimatoprost (prostaglandin F2α, PGF2α) eye drops. We hypothesized that enophthalmos is secondary to reductions in orbital tissue proliferation, adipogenesis, and/or increased lipolysis. We aimed to determine which of these is affected by PGF2α by using the 3T3-L1 murine preadipocyte cell line and primary human orbital fibroblasts (OFs) from GO patients (n=5) and non-GO (n=5). 3T3-L1 cells and orbital OFs were cultured alone or with PGF2α (all experiments used 10(-8) to 10(-6) M) and counted on days 1/2/3 or 5, respectively; cell cycle analysis (flow cytometry) was applied. Adipogenesis (in the presence/absence of PGF2α) was evaluated (day 7 or 15 for 3T3-L1 and primary cells, respectively) morphologically by Oil Red O staining and quantitative polymerase chain reaction measurement of adipogenesis markers (glycerol-3-phosphate dehydrogenase and lipoprotein lipase, respectively). For lipolysis, in vitro-differentiated 3T3-L1 or mature orbital adipocytes were incubated with norepinephrine and PGF2α and free glycerol was assayed. Appropriate statistical tests were applied. The population doubling time of 3T3-L1 was 27.3±1.4 hours-significantly increased by dimethyl sulfoxide 0.02% to 44.6±4.8 hours (p=0.007) and further significantly increased (p=0.049 compared with dimethyl sulfoxide) by 10(-8) M PGF2α to 93.6±19.0 hours, indicating reduced proliferation, which was caused by prolongation of G2/M. GO OFs proliferated significantly more rapidly than non-GO (population doubling time 5.36±0.34 or 6.63±0.35 days, respectively, p=0.035), but the proliferation of both was significantly reduced (dose dependent from 10(-8) M) by PGF2α, again with prolongation of G2/M. Adipogenesis in 3T3-L1 cells was minimally affected by PGF2α when assessed morphologically, but the drug significantly reduced transcripts of the glycerol-3-phosphate dehydrogenase differentiation marker. GO OFs displayed significantly higher adipogenic potential than non-GO, but in both populations, adipogenesis, evaluated by all 3 methods, was significantly reduced (dose dependent from 10(-8) M) by PGF2α. There was no effect of PGF2α on basal or norepinephrine-induced lipolysis, in 3T3-L1 or human OFs, either GO or non-GO. The results demonstrate that PGF2α significantly reduces proliferation and adipogenesis and that human OFs are more sensitive to its effects than 3T3-L1. Consequently, PGF2α could be effective in the treatment of GO.

Effects of Zingerone on Fat Storage in Ovariectomized Rats

We reported that ginger prevented obesity in mice fed a high-fat diet in previous study. In this experiment, we examined the effects of zingerone, the major pungent component of ginger on fat storage in ovariectomized (Ovx) rats. Oral administration of 170 mg/kg zingerone significantly reduced body weight and the final parametrail adipose tissue weight in ovariectomized rats. Blood glucose levels after oral administration of glucose were lower in zingerone-treated Ovx-rats than in the Ovx-rats (control). Basal lipolysis in zingerone-treated Ovx-rats was increased compared with that in the Ovx-rats. Zingerone significantly increased norepinephrine-induced lipolysis associated with the translocation of hormone-sensitive lipase (HSL) from the cytosol to lipid droplets in adipocytes. These results indicate that zingerone may prevent the fat storage through increasing norepinephrine-induced lipolysis in adipocytes.

Comparative studies of the role of hormone-sensitive lipase and adipose triglyceride lipase in human fat cell lipolysis

Hormone-sensitive lipase (HSL) and adipose triglyceride lipase (ATGL) regulate adipocyte lipolysis in rodents. The purpose of this study was to compare the roles of these lipases for lipolysis in human adipocytes. Subcutaneous adipose tissue was investigated. HSL and ATGL protein expression were related to lipolysis in isolated mature fat cells. ATGL or HSL were knocked down by RNA interference (RNAi) or selectively inhibited, and effects on lipolysis were studied in differentiated preadipocytes or adipocytes derived from human mesenchymal stem cells (hMSC). Subjects were all women. There were 12 lean controls, 8 lean with polycystic ovary syndrome (PCOS), and 27 otherwise healthy obese subjects. We found that norepinephrine-induced lipolysis was positively correlated with HSL protein levels (P < 0.0001) but not with ATGL protein. Women with PCOS or obesity had significantly decreased norepinephrine-induced lipolysis and HSL protein expression but no change in ATGL protein expression. HSL knock down by RNAi reduced basal and catecholamine-induced lipolysis. Knock down of ATGL decreased basal lipolysis but did not change catecholamine-stimulated lipolysis. Treatment of hMSC with a selective HSL inhibitor during and/or after differentiation in adipocytes reduced basal lipolysis by 50%, but stimulated lipolysis was inhibited completely. In contrast to findings in rodents, ATGL is of less importance than HSL in regulating catecholamine-induced lipolysis and cannot replace HSL when this enzyme is continuously inhibited. However, both lipases regulate basal lipolysis in human adipocytes. ATGL expression, unlike HSL, is not influenced by obesity or PCOS.

UCP1 deficiency increases susceptibility to diet‐induced obesity with age

Loss of nonshivering thermogenesis in mice by inactivation of the mitochondrial uncoupling protein gene (Ucp1-/- mice) causes increased sensitivity to cold and unexpected resistance to diet-induced obesity at a young age. To clarify the role of UCP1 in body weight regulation throughout life and influence of UCP1 deficiency on longevity, we longitudinally analyzed the phenotypes of Ucp1-/- mice maintained in a room at 23 degrees C. There was no difference in body weight and lifespan between genotypes under the standard chow diet condition, whereas the mutant mice developed obesity with age under the high-fat (HF) diet condition. Compared with Ucp1+/+ mice, Ucp1-/- mice showed increased expression of genes related to thermogenesis and fatty acid metabolism, such as beta3-adrenergic receptor, in adipose tissues of the 3-month-old mutants; however, the augmented expression was reduced in Ucp1+/+ mice in 11-month-old Ucp1-/- mice fed the HF diet. Likewise, the increased levels of UCP3 and cAMP-dependent protein kinase in the brown adipose tissue of Ucp1-/- mice given the standard diet were decreased significantly in that of Ucp1-/- mice fed the HF diet, which animals showed impaired norepinephrine-induced lipolysis in their adipose tissues. These results suggest profound attenuation of beta-adrenergic responsiveness and fatty acid utilization in Ucp1-/- mice fed the HF diet, bringing them to late-onset obesity. Our findings provide evidence that UCP1 is neither essential for body weight regulation nor for longevity under conditions of standard diet and normal housing temperature, but deficiency increases susceptibility to obesity with age in combination with HF diet.

Anti-obese action of raspberry ketone

Raspberry ketone (4-(4-hydroxyphenyl) butan-2-one; RK) is a major aromatic compound of red raspberry (Rubus idaeus). The structure of RK is similar to the structures of capsaicin and synephrine, compounds known to exert anti-obese actions and alter the lipid metabolism. The present study was performed to clarify whether RK helps prevent obesity and activate lipid metabolism in rodents. To test the effect on obesity, our group designed the following in vivo experiments: 1) mice were fed a high-fat diet including 0.5, 1, or 2% of RK for 10 weeks; 2) mice were given a high-fat diet for 6 weeks and subsequently fed the same high-fat diet containing1% RK for the next 5 weeks. RK prevented the high-fat-diet-induced elevations in body weight and the weights of the liver and visceral adipose tissues (epididymal, retroperitoneal, and mesenteric). RK also decreased these weights and hepatic triacylglycerol content after they had been increased by a high-fat diet. RK significantly increased norepinephrine-induced lipolysis associated with the translocation of hormone-sensitive lipase from the cytosol to lipid droplets in rat epididymal fat cells. In conclusion, RK prevents and improves obesity and fatty liver. These effects appear to stem from the action of RK in altering the lipid metabolism, or more specifically, in increasing norepinephrine-induced lipolysis in white adipocytes.

Inhibitory effects of halothane on the thermogenic pathway in brown adipocytes: localization to adenylyl cyclase and mitochondrial fatty acid oxidation

Volatile anesthetics such as halothane efficiently inhibit nonshivering thermogenesis as well as the cellular manifestation of that phenomenon: norepinephrine-induced respiration in brown adipocytes. To identify the molecular site(s) of action of such anesthetics, we have examined the effect of halothane on the sequential intracellular steps from the interaction of norepinephrine with isolated brown adipocytes to the stimulation of mitochondrial respiration (=thermogenesis). We did not identify an inhibition at the level of the adrenergic receptors, but a first site of inhibition was identified as the generation of cAMP by adenylyl cyclase; this led to inhibition of norepinephrine-induced expression of the uncoupling protein-1 (UCP1) gene and reduced norepinephrine-induced lipolysis as secondary effects. Although an inhibition of lipolysis in itself would inhibit thermogenesis, circumvention of this inhibition revealed that a second, postlipolytic, site of inhibition existed: halothane also inhibited the stimulatory effect of exogenous fatty acids on cellular respiration. This inhibition was independent of the presence of UCP1 in the mitochondria of the cells and was thus not directly on the thermogenic uncoupling mechanism. Since not only fatty acid oxidation but also pyruvate oxidation were inhibited by halothane in isolated mitochondria, whereas glycerol-3-phosphate oxidation was not, the second site of action of halothane, evident when cyclase/lipolytic inhibition was circumvented, was located to the respiratory chain, complex I. The results thus explain the inhibition of nonshivering thermogenesis by identifying two sites of action of halothane in brown adipocytes. In addition, the results may open for new formulations of the molecular background to anesthesia.

Anti-obesity action of Salix matsudana leaves (Part 2). Isolation of anti-obesity effectors from polyphenol fractions of Salix matsudana.

Previously, it was reported that polyphenol fractions prepared from the leaves of Salix matsudana reduced the elevation of the rat plasma triacylglycerol level at 3 and 4 h after oral administration of a lipid emulsion containing corn oil, at a dose of 570 mg/kg. Moreover, body weights at 2-9 weeks and the fi nal parametrial adipose tissue weights were significantly lower in mice fed the high-fat diet with 5% polyphenol fractions of S. matsudana leaves than in those fed the high-fat diet alone. The polyphenol fractions of S. matsudana leaves also significantly reduced the hepatic total cholesterol content, which was elevated in mice fed the high-fat diet alone. In addition, the polyphenol fractions of S. matsudana leaves inhibited palmitic acid uptake into brush border membrane vesicles prepared from rat jejunum and alpha-amylase activity, and their fractions enhanced norepinephrine-induced lipolysis in fat cells. To clarify the active substances inhibiting the palmitic acid uptake into small intestinal brush border membrane, the alpha-amylase activity or enhancing the norepinephrine-induced lipolyis in fat cells, the isolation of the active substances from polyphenol fraction was attempted using the above three assay systems. Compounds 1, 2 and 3 were isolated from the polyphenol fractions and identified as apigenin-7-O-d-glucoside, luteolin-7-O-d-glucoside and chrysoeriol-7-O-d-glucoside, respectively. Among three flavonoids, apigenin-7-O-d-glucoside inhibited alpha-amylase activity, and luteolin-7-O-d-glucoside and chrysoeriol-7-O-d-glucoside inhibited palmitic acid uptake into small intestinal brush border membrane. Furthermore, three flavonoid glucosides enhanced norepinephrine-induced lipolysis in fat cells.

Anti-obesity action of Salix matsudana leaves (Part 1). Anti-obesity action by polyphenols of Salix matsudana in high fat-diet treated rodent animals.

In preliminary experiments, polyphenol fractions prepared from the leaves of Salix matsudana reduced the elevation of the rat plasma triacylglycerol level at 3 and 4 h after oral administration of a lipid emulsion containing corn oil, at a dose of 570 mg/kg. The present study examined the anti-obesity action of polyphenol fractions of S. matsudana leaves by testing whether the polyphenol fractions prevented the obesity induced by feeding a high-fat diet to female mice for 9 weeks. Body weights at 2-9 weeks and the fi nal parametrial adipose tissue weights were significantly lower in mice fed the high-fat diet with 5% polyphenols of S. matsudana leaves than in those fed the high-fat diet alone. The polyphenols of S. matsudana leaves also significantly reduced the hepatic total cholesterol content, which was elevated in mice fed the high-fat diet alone. In addition, the polyphenol fractions of S. matsudana leaves inhibited palmitic acid uptake into brush border membrane vesicles prepared from rat jejunum and alpha-amylase activity, and their fractions enhanced norepinephrine-induced lipolysis in fat cells. In conclusion, it is suggested that the inhibitory effects of the flavonoid glycoside fraction of S. matsudana leaves on high-fat diet-induced obesity might be due to the inhibition of carbohydrate and lipid absorption from small intestine through the inhibition of alpha-amylase and palmitic acid uptake into small intestinal brush border membrane or by accelerating fat mobilization through enhancing norepinephrine-induced lipolysis in fat cells.

A Thyroid Hormone Receptor α Gene Mutation (P398H) Is Associated with Visceral Adiposity and Impaired Catecholamine-stimulated Lipolysis in Mice

Thyroid hormone has profound effects on metabolic homeostasis, regulating both lipogenesis and lipolysis, primarily by modulating adrenergic activity. We generated mice with a point mutation in the thyroid hormone receptor alpha (TRalpha) gene producing a dominant-negative TRalpha mutant receptor with a proline to histidine substitution (P398H). The heterozygous P398H mutant mice had a 3.4-fold (p < 0.02) increase in serum thyrotropin (TSH) levels. Serum triiodothyronine (T3) and thyroxine (T4) concentrations were slightly elevated compared with wild-type mice. The P398H mice had a 4.4-fold increase in body fat (as a fraction of total body weight) (p < 0.001) and a 5-fold increase in serum leptin levels (p < 0.005) compared with wild-type mice. A 3-fold increase in serum fasting insulin levels (p < 0.002) and a 55% increase in fasting glucose levels (p < 0.01) were observed in P398H compared with wild-type mice. There was a marked reduction in norepinephrine-induced lipolysis, as reflected in reduced glycerol release from white adipose tissue isolated from P398H mice. Heart rate and cold-induced adaptive thermogenesis, mediated by thyroid hormone-catecholamine interaction, were also reduced in P398H mice. In conclusion, the TRalpha P398H mutation is associated with visceral adiposity and insulin resistance primarily due to a marked reduction in catecholamine-stimulated lipolysis. The observed phenotype in the TRalpha P398H mouse is likely due to interference with TRalpha action as well as influence on other metabolic signaling pathways. The physiologic significance of these findings will ultimately depend on understanding the full range of actions of this mutation.

Norepinephrine-augmenting lipolytic effectors from Astilbe thunbergii rhizomes.

An EtOAc-soluble fraction from a 80% Me2CO extract of the rhizomes of Astilbe thunbergii enhanced norepinephrine-induced lipolysis in rat fat cells, while an EtOAc-insoluble fraction had no effect. The active substances isolated from the EtOAc-soluble fraction of the rhizomes were identified as eucryphin (1), bergenin (2), and astilbin (3), which enhanced norepinephrine-induced lipolysis at concentrations of 10-1000 microgram/mL, while they themselves did not cause lipolysis. Furthermore, these compounds slightly stimulated adrenocorticotrophic hormone-induced lipolysis and inhibited insulin-induced lipogenesis from glucose.

Analysis of the cellular mechanism for halothane inhibition of brown adipose tissue thermogenesis.

In the present studies, halothane is demonstrated to have a general inhibitory effect on norepinephrine-induced cAMP accumulation, lipolysis and rate of oxygen consumption, but no obvious effect on the respiratory capacity of isolated mitochondria. Further studies are necessary to elucidate these effects of halothane on brown adipose tissue nonshivering thermogenesis. Such studies may contribute to the understanding of the molecular effects of volatile anesthetics.

Norepinephrine-induced lipolysis in rat fat cells from visceral and subcutaneous sites: role of hormone-sensitive lipase and lipid droplets.

Norepinephrine-induced lipolysis was examined in visceral (epididymal and omental) and subcutaneous (abdominal and femoral) fat cells in rats. Hormone-induced lipolysis was considerably higher in the visceral fat cells than in the subcutaneous cells. A higher hormone-sensitive lipase (HSL) activity was present in the visceral than in the subcutaneous fat cells. Endogenous lipid droplets were prepared from rat visceral (epididymal and omental) and subcutaneous (abdominal and femoral) fat cells and norepinephrine-induced lipolysis was examined in a cell-free system consisting of the lipid droplets prepared from fat cells from each site and a fixed amount of HSL from rat epididymal adipose tissue. In this cell-free system, norepinephrine induced a higher rate of lipolysis with lipid droplets from the visceral than from the subcutaneous fat cells. These findings suggest that the difference in norepinephrine-induced lipolysis between visceral and subcutaneous fat cells may be due to the differences in HSL activity and lipid droplet character at each site.

Catecholamine-induced adipocyte lipolysis in human hyperthyroidism.

Increased lipid mobilization in thyrotoxicosis is attributed to amplification of catecholamine action in fat cells by thyroid hormones. We investigated the adrenergic regulation of lipolysis in isolated sc abdominal fat cells obtained from 14 patients with thyrotoxicosis and 18 control subjects. Ten of the hyperthyroid subjects were also reinvestigated after antithyroid treatment. The thyrotoxic state was associated with a 3-fold increase in maximum norepinephrine-induced lipolysis (P < 0.005), unaltered sensitivity to dobutamine (selective beta 1-adrenoceptor agonist) and clonidine (selective alpha 2-adrenoceptor agonist), but 15 times enhanced sensitivity to terbutaline (selective beta 2-adrenoceptor agonist; P < 0.01). Moreover, thyrotoxicosis was accompanied by a 3-fold increase in beta 2-adrenoceptor number (P < 0.005), but unchanged beta 1-adrenoceptor levels. Further, the lipolytic effects of dibutyryl cAMP (activating protein kinase A and thereby hormone-sensitive lipase) and forskolin (activating adenylate cyclase) were about 60% enhanced (P < 0.005). No change in the maximum activity of the hormone-sensitive lipase could be demonstrated in the hyperthyroid state compared to that in the euthyroid state. The observed abnormalities in lipolysis and beta 2-adrenoceptor number were normalized after antithyroid treatment. It is concluded that in human hyperthyroidism, the interactions between thyroid hormone and catecholamines in adipocytes involve abnormalities at both receptor and postreceptor levels. The former mechanism seems to be a selective increase in the expression of the beta 2-adrenoceptors. The latter mechanism involves increased ability of cAMP to activate hormone-sensitive lipase, but not a change in maximum enzyme capacity.