Prostaglandin inhibition of cyclic-AMP accumulation and rate of lipolysis in fat cells

A direct relationship between the rate of cyclic AMP accumulation for 2 minutes and the rate of free fatty acid mobilization for 20 minutes was found in rat isolated fat cells stimulated with norepinephrine or theophylline. The concentration-dependent inhibition of cAMP accumulation by prostaglandin E₂ was reflected in proportional inhibition of lipolysis. These data suggest that the anti-lipolytic mechanism of action of prostaglandin E₂ is mediated by inhibition of the early rate of cAMP accumulation rather than the total production of cAMP.     

Bimodal effect of insulin on hormone-stimulated lipolysis: relation to intracellular 3',5'-cyclic adenylic acid and free fatty acid levels

The present study was undertaken to determine the relationship between the antilipolytic and lipolytic effects of insulin on hormone-stimulated lipolysis and the mechanisms of these reactions. The dose-response curve of norepinephrine-stimulated lipolysis in rat adipocytes was not sigmoidal but biphasic in nature. Intracellular free fatty acid levels were linearly related to lipolytic rate and also described a biphasic profile in response to increments in norepinephrine concentration. Intracellular 3',5'-cyclic AMP levels measured 10 min after addition of increasing concentrations of norepinephrine showed a rise and a plateau followed by a secondary rise. Insulin was antilipolytic at low concentrations of norepinephrine and distinctly lipolytic at high concentrations. The combined antilipolytic and lipolytic effect of insulin is termed the "bimodal" effect of insulin on hormone-stimulated lipolysis. The bimodal effect of insulin correlated positively with changes in peak intracellular 3',5'-cyclic AMP levels. In the presence of glucose, insulin invariably enhanced lipolysis. It is suggested that the antilipolytic effect of insulin is achieved by both inhibition of adenyl cyclase activity and activation of low-K(m) 3',5'-cyclic AMP phosphodiesterase, the net effect being a low accumulation of 3',5'-cyclic AMP. On the other hand, the lipolytic effect of insulin probably reflects enhancement of adenyl cyclase activity to an extent that overrides any activation of low-K(m) 3',5'-cyclic AMP phosphodiesterase activity, resulting in an increase in peak adipocyte 3',5'-cyclic AMP levels.     

Lipid peroxidation inhibits norepinephrine-stimulated lipolysis in rat adipocytes. Reduction of beta-adreno-ceptor number

The effect of lipid peroxidation on lipolysis depends on the intactness of the adipocyte plasma membrane. In the intact cells, the norepinephrine-stimulated lipolysis was inhibited, while the basal one was elevated. In the lysed cells, lipid peroxidation had no effect upon hormone-stimulated lipolysis, but the basal one was strongly inhibited. The effects of free radical damage (iron plus ascorbate ions) were compared to those of malondialdehyde, a non-radical product of lipid peroxidation. Although qualitatively similar, deterioration of plasma membrane induced by malondialdehyde was much lower than by free radicals. The changes in lipolytic response to norepinephrine were accompanied by a drastic reduction in the number of beta-adrenergic receptors.     

Characterization of lipolytic responses of isolated white adipocytes from hamsters.

1. Lipolysis by isolated white adipocytes from hamsters, as measured by glycerol production, was stimulated by corticotropin, isopropylnorepinephrine (INE), norepinephrine, or epinephrine (EPI), in a dose-dependent fashion. 2. Lipolysis was stimulated by five inhibitors of cyclic 3',5'-adenosine monophosphate phosphodiesterase: caffeine, theophylline, 1-methyl-3-isobutyl xanthine, 1-ethyl-4-(isopropylidenehydrazine)-1H-pyrazolo-(3,4,-b)-pyridine-5-carboxylic acid ethyl ester (SQ 20009), and 4-(3,4-dimethoxybenzyl)-2-imidazolidinone (Ro 7-2956). Caffeine-stimulated lipolysis consistently attained higher rates than did hormone-stimulated lipolysis. However, when cells were stimulated by both caffeine and a hormone, lipolytic rates were consistently lower than those attained under the influence of caffeine alone. 3. Isolated white adipocytes from hamsters were sensitive to both alpha- and beta-adrenergic antagonists. The beta-adrenergic antagonist propranolol could completely inhibit norepinephrine-stimulated glycerol production. The alpha-adrenergic antagonist phentolamine, on the other hand, had a biphasic effect on the cells. At 5-10(-7) M or 5-10(-6) M, phentolamine enhanced norepinephrine-stimulated lipolysis, while concentrations higher than 5-10(-5) M caused inhibition. 4. The effects of two different concentrations of six antilipolytic agents, prostaglandin E1, nicotinic acid, phenylisopropyladenosine, 5-methylpyrazole-3-carboxylic acid, adenosine and insulin, were measured. With the exception of insulin, all of these agents showed much more potent inhibition of caffeine-stimulated lipolysis than of hormone-stimulated lipolysis. Insulin, in contrast, showed only modest inhibition of hormone-stimulated lipolysis and virtually no inhibition of caffeine-stimulated lipolysis.     

In vivo nitric oxide suppression of lipolysis in subcutaneous abdominal adipose tissue is greater in obese than lean women

Mounting evidence suggests there is a reduced mobilization of stored fat in obese compared to lean women. It has been suggested that this decreased lipid mobilization may lead to, or perpetuate, the obese state; however, there may be a beneficial effect of reduced lipolysis, either by allowing for a sink of excess fatty acids, or by limiting a potentially harmful rise in interstitial and circulating fatty acid concentration. Nitric oxide (NO) may be responsible for a portion of the reduced in vivo rates of lipolysis in obese women because NO reduces adipose tissue lipolysis and adipose tissue nitric oxide synthase (NOS) mRNA is higher in obese than lean individuals. The purpose of this study was to determine if the inhibition of NOS by L-N(g)-monomethyl-L-arginine (L-NMMA) in the absence and presence of lipolytic stimulation would result in a larger increase in lipolytic rate in obese (OB) than lean (LN) women. Microdialysis probes were inserted into the subcutaneous abdominal adipose tissue of seven obese and six lean women to monitor lipolysis. Dialysate glycerol concentration increased in response to L-NMMA in OB (basal 125 ± 26 μmol/l; L-NMMA 225 ± 35 μmol/l) to a greater extent than in LN (basal 70 ± 18 μmol/l; L-NMMA 84 ± 20 μmol/l) women (P < 0.05). Dialysate glycerol increased to a similar extent in OB and LN in response to adrenergic stimulation by isoprenaline or norepinephrine in the presence of L-NMMA. The differential glycerol responses to L-NMMA between obese and lean could not be explained by differential blood flow responses. It can be concluded that NO suppresses basal lipolysis in obese women to a greater extent than in lean women.     

Multiple effects of guanine nucleotides on human platelet adenylate cyclase

We report that the adenylate cyclase system in human platelets is subject to multiple regulation by guanine nucleotides. Previously it has been reported that GTP is either required for or has little effect on the response of the enzyme to prostaglandin E₁. We have found that when platelet lysates were prepared in the presence of 5 mM EDTA, GTP lowered the basal and prostaglandin E₁-stimulated adenylate cyclase activity when the enzyme was assayed in the presence of Mg²⁺. The basal and prostaglandin E₁-stimulated adenylate cyclase activities were also increased by washing, which presumably removes endogenous GTP. The analog, guanyl-5′-yl-imidodiphosphate mimics the inhibitory effect of GTP on prostaglandin E₁-stimulated adenylate cyclase activity but it stimulates basal enzyme activity. The onset of the inhibitory effect of GTP on the adenylate cyclase system is rapid (1 min) and is maintained at a constant rate during incubation for 10 min. GTP and guanyl-5′-yl-imidodiphosphate were noncompetitive inhibitors of prostaglandin E₁. An increase in the concentration of Mg²⁺ gradually reduces the effect of GTP while having little influence on the effect of guanyl-5′-yl-imidodiphosphate. Neither the substrate concentration nor the pH (7.2–8.5) is related to the inhibitory effect of guanine nucleotides. The inhibition by nucleotides was found to show a specificity for purine nucleotides with the order of potency being guanyl-5′-yl-imidodiphosphate > dGTP > GTP > ITP > XTP > CTP > TTP. The inhibitory effect of GTP is reversible while the effect of guanyl-5′-yl-imidodiphosphate is irreversible. The GTP inhibitory effect was abolished by preparing the lysates in the presence of Ca²⁺. However, the inhibitory effect of guanyl-5′-yl-imidodiphosphate persisted. Substitution of Mn²⁺ for Mg²⁺ in the assay medium resulted in a diminution of the inhibitory effect of GTP on basal activity and converted the inhibitory effect of GTP on prostaglandin E₁-stimulated activity to a stimulatory effect. At a lower concentration of Mn²⁺ (less than 2 mM) guanyl-5′-yl-imidodiphosphate inhibited prostaglandin E₁-stimulated adenylate cyclase activity, but at a higher concentration of Mn²⁺, it caused an increase in enzyme activity exceeding that occuring in the presence of prostaglandin E₁. In the presence of Mn²⁺, dGTP mimics the effect of GTP and is 50% as effective as GTP. Our data suggest that the inhibitory effect of GTP on prostaglandin E₁-stimulated adenylate cyclase is mainly due to its direct effect on the enzyme itself, whereas the stimulatory effect of GTP on prostaglandin E₁-stimulated adenylate cyclase is due to enhancement of the coupling between the prostaglandin E₁ receptor and adenylate cyclase. These studies also indicate that the method of preparation of platelet lysates can profoundly alter the nature of guanine nucleotide regulation of adenylate cyclase.     

Lack of feedback regulation of cyclic 3':5'-AMP accumulation by free fatty acids in chicken fat cells.

Fat cells isolated from the mesenteric adipose tissue of chickens (pullets) responded to glucagon with an increase in lipolysis and a sustained rise in cyclic adenosine 3':5'-monophosphate (cyclic AMP) over a 30-min incubation. The prolonged accumulation of cyclic AMP due to glucagon in chicken fat cells was primarily intracellular. In addition, there was little increase in cyclic AMP accumulation due to theophylline alone or potentiation of the increase due to glucagon. These data indicate that chicken fat cells, unlike rat fat cells, are relatively insensitive to theophylline. Neither lipolysis nor cyclic AMP accumulation by chicken fat cells was inhibited by free fatty acid to albumin ratios (3 to 7) which markedly reduced both events in rat fat cells. However, in the absence of albumin from the medium, lipolysis in chicken fat cells was reduced, but not to the same extent as in rat fat cells. Chicken fat cells did accumulate more intracellular free fatty acids in response to lipolytic agents than did rat fat cells. The uptake of oleate by rat and chicken fat cells was identical. Glucagon-induced accumulation of cyclic AMP by chicken fat cell ghosts was unaffected by added oleate. Under identical conditions glucagon-induced adenylate cyclase activity of rat fat cell ghosts was markedly inhibited by added oleate. Triglyceride lipase activity of the pH 5.2 precipitate from a 40,000 x g infranatant of homogenized fat cells from chickens was less sensitive than that from rat fat cells to the ratio of oleate to albumin. These results suggest that the maintenance of cyclic AMP levels in chicken fat cells incubated with lipolytic agents results from the relative insensitivity of chicken fat cells to free fatty acid inhibition of cyclic AMP accumulation.     

Biomodulator-mediated susceptibility of endogenous lipid droplets from rat adipocytes to hormone-sensitive lipase

The amount of fatty acid release by a fat cell homogenate without pretreatment with epinephrine was found to be slightly more than that released from fat cells by epinephrine, suggesting that fat cells contain high lipolytic activity even in the absence of lipolytic agents. Fat cells contain high hormone-sensitive lipase activity (1383 mumole free fatty acids/g/hr) in the absence of epinephrine, and addition of epinephrine to the cells did not increase the activity, significantly. Like epinephrine, DBcAMP and/or theophylline also elicited marked release of glycerol from fat cells without activating the hormone-sensitive lipase activity. However, although fat cells contain a large amount of hormone-sensitive lipase, lipolysis was negligible in the absence of these lipolytic agents. These results suggest that lipolytic agents such as epinephrine, DBcAMP, and theophylline induce lipolysis in fat cells through some mechanism other than activation of hormone-sensitive lipase and that in the absence of lipolytic agents, some system in fat cells inhibits lipolysis of endogenous lipid droplets by hormone-sensitive lipase. The lipid droplets in fat cells consist mainly of triglyceride with phospholipids, cholesterol, carbohydrate, and protein as minor constituents. The phospholipid fraction was found to consist of 75% phosphatidylcholine and 25% phosphatidylethanolamine. Of the minor constituents of endogenous lipid droplets, only phosphatidylcholine strongly inhibited hormone-sensitive lipase activity in a [3H]triolein emulsion. These results suggest that phosphatidylcholine in endogenous lipid droplets may be responsible for inhibition of hormone-sensitive lipase. Then, a cell-free system was established in which epinephrine, DBcAMP, and theophylline stimulated lipolysis of endogenous lipid droplets from fat cells by lipase solution. In this system, these lipolytic agents did not induce lipolysis in the absence of added lipase. Lipolysis in the mixture of the endogenous lipid droplets and lipase solution was accelerated by phospholipase C with concomitant loss of epinephrine-induced lipolysis. After pretreatment of the endogenous lipid droplets with phospholipase C, these lipolytic agents no longer induced lipolysis. Pretreatment of the endogenous lipid droplets with phospholipase C reduced their phospholipid content with the formation of phosphorylcholine, but did not affect their triglyceride and cholesterol contents. Treatment of the endogenous lipid droplets with phospholipase D did not affect lipolysis in the cell-free system. These results suggest that phosphatidylcholine in the endogenous lipid droplets may inhibit their lipolysis by hormone-sensitive lipase in fat cells and also be involved in the mechanisms of the stimulatory effects of epinephrine, DBcAMP, and theophylline on lipolysis.     

Roles of cAMP and free fatty acids on the activity of the hexose monophosphate shunt

Summary Basal glucose utilization by isolated rat adipocytes have been found to be increased ten times in the presence of certain preparations of albumin. In these conditions the effects of several adrenergic agonists and related compounds on glucose oxidation, lipolysis and triacylglycerol synthesis in isolated fat cells have been studied. Oxidation of D(1-¹⁴C) glucose in rat adipocytes was almost completely inhibited by norepinephrine and isoproterenol when added to incubated fat cells. Agents able to modify intracellular AMP cyclic levels by different mechanisms display a similar ability to imitate the effect of lipolytic agents. The inhibition of glucose oxidation due to norepinephrine and isoproterenol is partially reverted by propanolol. Under the same conditions in which norepinephrine and isoproterenol markedly reduced glucose conversion to ¹⁴CO₂, they stimulated lipolysis and triacylglycerol synthesis and in this case propanolol also reverted those actions. However, in these experimental conditions, norepinephrine and isoproterenol did not raise CAMP levels 10 min after hormone addition.It is concluded from these data that glucose oxidation through hexose monophosphate shunt, activation of lipolysis and triacylglycerol synthesis in isolated rat fat cells by lipolytic agents occurs by a mechanism(s) that depend(s) on intracellular free fatty acids levels.     

Regulation of triglyceride metabolism in the isotopically prelabeled perfused heart.

Utilization of 14C-prelabeled endogenous triglycerides was studied in isolated perfused working rat hearts. Lipolysis was estimated by the disappearance of 14C-labeled and total triglycerides. Metabolic 14CO2 production was continuously monitored to evaluate triglyceride fatty acid oxidation. Triglyceride utilization was enhanced by an increase in ventricular pressure development as evidenced by a faster rate of triglyceride mobilization and oxidation. Added catecholamines stimulated lipolysis in hearts perfused with glucose-containing buffer but were without effect in the presence of exogenous fatty acids; the latter were shown to be potent and, possibly, direct inhibitors of myocardial lipolysis. Mediation of catecholamine-induced lipolysis by cyclic AMP has not been settled. Dibutyryl cyclic AMP produced only a slight lipolytic effect, although theophylline, a known phosphodiesterase inhibitor, was a potent lipolytic agent. Theophylline may have exerted its lipolytic effect through an alternative mechanism. Hypoxia per se was a strong inhibitor of heart triglyceride utilization. Furthermore, added epinephrine was without effect on triglyceride lipolysis in hypoxic hearts. Thus, cardiac muscle triglyceride utilization is influenced by such factors as mechanical function, exogenous substrates, hormones, and oxygen availability. The mechanisms involved in these areas of regulation need to be resolved.     

Hormonal control of lipolysis from the white adipose tissue of hibernating jerboa (Jaculus orientalis)

1. Plasma glucose, glycerol, free fatty acids and total lipid content of the white adipose tissue were measured in euthermic and hibernating jerboa. 2. During hibernation, plasma glucose and glycerol were low compared to the euthermic animals, whereas there was no obvious difference in plasma free fatty acids. The white adipose tissue lipid content was strongly reduced in the hibernating state. 3. The effect of lipolytic hormones (norepinephrine and glucagon) and antilipolytic hormone (insulin) on in vitro glycerol release by adipose tissue isolated from hibernating or euthermic jerboa has been studied. 4. The white adipose tissue from hibernating jerboa presented a higher sensitivity to norepinephrine and glucagon than that of euthermic jerboa; insulin did not modify either basal glycerol release or lipolysis induced by the two lipolytic hormones at low temperatures (7 degrees C) and during the rewarming (from 7 degrees C to 37 degrees C) of the tissue slices. 5. These results suggested that white adipose tissue constitutes an important source of substrates derived from lipolysis during hibernation.     

Beta-adrenergic stimulation of fatty acid release from brown fat cells differentiated in monolayer culture

The ability of brown adipocytes differentiated in monolayer culture to respond to norepinephrine was investigated. It was found that fatty acid release in confluent brown adipocytes in monolayer culture was induced by norepinephrine, thus these cells were hormone-sensitive. After confluence, the rate of fatty acid release successively declined. The norepinephrine-stimulated fatty acid release was inhibited by propranolol, but not by phentolamine, indicating a mediation via beta-adrenergic receptors. It was concluded that there exist in the brown adipose tissue of nonfetal rats preadipocytes which possess the ability to express in culture a fully developed beta-adrenergic lipolytic response.     

Prostaglandin production and lipolysis in isolated rat adipocytes as affected by dietary fat

The influence of dietary fat on prostaglandin production and lipolysis was tested in basal and norepinephrine stimulated adipocytes isolated from the epididymal fat pads of fasted rats. Seven diets varying in fat calories and polyunsaturation were utilized. No basal differences were noted for prostaglandin E₂ production or lipolysis. Norepinephrine stimulated prostaglandin E₂ and F_2α production was significantly (P < 0.01) increased with greater polyunsaturation of fat, but not by increased fat calories. Norepinephrine stimulated lipolysis was depressed by an increase in fat calories but was unaffected by the degree of polyunsaturation of fat. This is in vitro evidence against the concept that prostaglandins play a feedback regulator role in fat cell lipolysis since no correlation could be made between the two parameters.     

Insulin as an activator of cyclic AMP accumulation in rat fat cells.

In rat fat cells incubated with lipolytic agents and insulin for 30 or 60 minutes the increase in cyclic AMP accumulation due to norepinephrine and theophylline or adenosine deaminase added during the last 2-5 minutes of the incubation period was much greater as compared to cells incubated in the absence of insulin. Protaglandin E1 or nicotinic acid were just as anti-lipolytic as insulin but prior incubation with these agents markedly decreased the subsequent rise in cyclic AMP accumulation due to late catecholamine addition. The ability of insulin to increase cyclic AMP accumulation appeared to be secondary to inhibition of lipolysis. These results indicate that prostaglandin E1 and nicotinic acid are inhibitors of cyclic AMP accumulation while insulin acts by another mechanism to reduce lipolysis.     

Effect of guanyl nucleotides on the stimulation of adenyl cyclase activity in human thyroid plasma membranes by thyroid-stimulating hormone and prostaglandin E2

Thyroid homogenates and thyroid plasma membranes were prepared from human thyroid and the effects of thyroid-stimulating hormone (thyrotropin), NaF, and prostaglandins E₁ and E₂ on adenyl cyclase activity in these preparations were studied. The basal level of adenyl cyclase activity in plasma membranes was 5–8 times greater than that of the original homogenates. Adenyl cyclase activity in plasma membranes was stimulated 4.7-fold by 100 munits/ml of thyrotropin and 5-fold by 10 mM of NaF, but the activity in the homogenates was only stimulated 2-fold by either thyrotropin or NaF. Prostaglandin E₁ (10^?6?10^?3 M) and prostaglandin E₂ (10^?7?10^?4 M) failed to stimulate adenyl cyclase activity in plasma membranes, but they did stimulate adenyl cyclase activity in the homogenates. A marked stimulatory effect of prostaglandin E₂ (10^?5 M) on adenyl cyclase activity in plasma membranes resumed in the presence of GTP (10^?7?10^?4 M), although GTP itself only slightly stimulated enzyme activity. GDP and GMP were also effective in this respect, although their potencies varied from compound to compound. GTP potentiated slightly the action of thyrotropin on adenyl cyclase in plasma membranes, but it significantly depressed an increase of enzyme activity produced by NaF. Since GTP did not affect the ATP-regenerating system, it seems that GTP, GDP or GMP was required for the manifestation of prostaglandin E₂ action on adenyl cyclases of human thyroid plasma membranes.     

Studies on norepinephrine-induced efflux of free fatty acid from hamster brown-adipose-tissue cells.

Cells were isolated from brown adipose tissue of warm-adapted hamsters and the fate of free fatty acids released during norepinephrine-induced lipolysis was investigated. The isolated resting cells contain between 100-400 nmoles cell-associated free fatty acids per 10(6) cells; most preparations contained about 200 nmoles/10(6) cells. During norepinephrine-stimulated lipolysis, the level of cell-associated free fatty acids remains constant or decreases gradually, but does not increase, while the concentration of extracellular fatty acids increases linearly. The rate of norepinephrine-stimulated efflux of free fatty acids was 40 +/- 20 nmol X min-1 X 10(6) cells-1 (n = 11) at 37 degrees C. The data strongly indicate that brown adipose tissue can supply free fatty acids to the circulatory system in hamster.     

Comparison of the Lipolytic Effects of Norepinephrine and BRL 37344 in Rat Brown and White Adipocytes

The lipolytic effects of norepinephrine (a non-selective β-agonist) and BRL 37344 (a selective β₃-agonist) were compared in isolated rat brown and white adipocytes. Norepinephrine and BRL 37344 maximally stimulated lipolysis in brown and white adipocytes, approximately 10 times above basal values. However, adipocyte sensitivity for BRL 37344 was greater than that for norepinephrine, particularly in brown adipocytes [the EC₅₀ values (nM) for BRL 37344 and norepinephrine were 5 ± 1 and 103 ± 31 in brown adipocytes (P <0.01) versus 56 ± 9 and 124 ± 17 in white adipocytes (P <0.05), respectively]. On the other hand, the lipolytic effects of norepinephrine were totally blocked by 20–40 times superior concentrations of propranolol or bupranolol in brown as well as in white adipocytes. In contrast, the lipolytic effects of BRL 37344 were fully inhibited by concentrations of propranolol or bupranolol that were 200–1000 superior to the β₃ agonist concentration. The results demonstrate that: (1) the (β₃-agonist BRL 37344 is as effective as norepinephrine for maximally stimulating lipolysis in rat brown and white adipocytes, (2) both adipocyte types are more sensitive to the lipolytic effects of BRL 37344 than to those of norepinephrine, (3) although bupranolol is a better antagonist than propranolol on BRL 37344-stimulated lipolysis, it cannot be considered as a specific β₃-antagonist, (4) brown adipocytes are 10 times more sensitive than white adipocytes to the lipolytic effects of BRL 37344, suggesting an important role of β₃-receptors in brown adipose tissue.     

Maturation dependent decline of adenylate cyclase in rabbit red blood cell membranes

Adenylate cyclase (EC 4.6.1.1) was studied in membrane preparations of reticulocyte-rich blood obtained from phenylhydrazine-treated rabbits and compared to that of untreated animals.Basal and fluoride-stimulated activities were decreased 2- and 4-fold, respectively, during the process of maturation.Catalytic parameters such as time course, protein, ATP, Mg²⁺ concentration curves and K_m have been determined and were found to be similar in the reticulocyte and the erythrocyte.Adenylate cyclase was sensitive to GTP, 5′-guanylyl imidodiphosphate, prostaglandin E₁ and prostaglandin E₂. Activation by prostaglandin E₁ was higher than that produced by prostaglandin E₂. Only additive effect was found when 5′-guanylyl imidodiphosphate or GTP was added to hormone-stimulated activity. The sensitivity of the enzyme to these effectors was decreased over the transition reticulocyte-erythrocyte.In either cell the enzyme was not activated by catecholamines (epinephrine, norepinephrine, isoproterenol).