The antilipolytic action of insulin on adrenocorticotrophin-stimulated rat adipocytes. The roles of adenosine 3',5'-monophosphate and the protein kinase dependent on adenosine 3',5'-monophosphate

The extent to which a fall in cellular cyclic AMP could account for the antilipolytic action in rat epididymal adipocytes incubated with adrenocorticotrophic hormone was studied. The antilipolytic effect, measured by suppression of glycerol release, was always associated with a decrease in cyclic AMP, but the magnitude of the fall was modified by several factors. For example, it was greater when the cAMP level was high, as when it is at its peak after hormone stimulation, or when cell concentrations are low. Glucose did not modify appreciably the insulin effect on the nucleotide level. The inhibitory effects of insulin on corticotrophin-stimulated lipolysis and cyclic AMP levels were detectable at the concentrations of 1 microU/ml and were biphasic, with maximal effects at 10-100 microU/ml. Protein kinase activity ratio was similarly affected. Activity of cyclic-AMP-dependent protein kinase conformed closely to the level of cyclic AMP. There was no indication that insulin modified the sensitivity of the kinase to cyclic AMP. Insulin did not alter the relationship of cellular cyclic AMP levels to glycerol when adipocytes were incubated with various concentrations of corticotrophin. This was true, irrespective of whether measurements were made when cyclic AMP was on the upward rise after hormone stimulation, or on the decline. The curves obtained with and without insulin were superimposable. It is concluded that the inhibitory action of insulin on lipolysis in fat cells can be fully accounted for by a decrease in cyclic AMP.     

Inhibition of lipolysis in hamster epididymal adipocytes by selective alpha-adrenergic agents. Evidence for cyclic AMP-dependent and independent mechanisms.

In this study the role of cyclic AMP in the antilpolytic effect of the alpha-adrenergic agents methoxamine and phenylephrine in hamster epididymal adipocytes was studied. Both methozamine and phenylephrine lowered the very high levels of cyclic AMP that were produced by high concentrations of isoproterenol (10 muM) or ACTH (100 MU/ml), and partially inhibited lipolysis. When lower concentrations of isoproterenol were used, the antilipolytic effect of phenylephrine and methoxamine was still evident. Under these conditions methoxamine produced a slight suppression of cyclic AMP levels while phenylephrine increased accumulation of cyclic AMP. It follows, therefore, that the inhibition of lipolysis by the alpha agents is most likely unrelated to changes in cyclic AMP levels; in contrast, phenylephrine promoted lipolysis and increased cyclic AMP levels. When the stimulus for lipolysis was provided by methylxanthines a different picture emerged. Methoxamine antagonized lipolysis and lowered cyclic AMP levels. In the presence of propranolol, phenylephrine lowered cyclic AMP levels and suppressed methylxanthine-accelerated lipolysis. It is suggested that when methy xanthines provide the stimulus for lipolysis the antilipolytic effect of methoxamine and phenylephrine (in the presence of propranolol) may be mediated by the suppression in cyclic AMP levels.     

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.     

Control of endogenous triglyceride breakdown in the mouse diaphragm

The control of endogenous triglyceride breakdown was studied in vitro, in the incubated intact mouse diaphragm. Isoproterenol (2 microgram/ml) produced parallel increases in glycerol and free fatty acid release, and in tissue cyclic AMP levels, suggesting that cyclic AMP mediates the action of the catecholamine on triglyceride mobilization. In addition to cyclic AMP, calcium seems to be involved in the action of isoproterenol because preincubation of hemidiaphragms in the presence of the calcium ionophore A23187 decreased the lipolytic effect of the drug. Insulin (12.5 mU/ml) antagonized the action of isoproterenol on triglyceride breakdown (it decreased glycerol and free fatty acid release) without altering its stimulatory effect on cyclic AMP levels. On the other hand, no detectable effect on lipolysis was observed with carbachol in control and denervated hemidiaphragms, although the latter possess acetylcholine receptors over the entire surface area of the muscle. It was concluded that catecholamines control triglyceride breakdown in muscle while the cholinergic system does not seem to be involved. Cyclic AMP, calcium, and insulin all affect lipolysis in muscle and the interrelationships remain to be elucidated.     

Inhibition of adenosine 3':k'-monophosphate accumulation white fat acids, lactate, and beta-hydroxybutyrate.

The large increase in cyclic AMP accumulation by rat white fat cells seen in the presence of lipolytic agents plus methylxanthines and adenosine deaminase was markedly inhibited by lactate. However, lipolysis was unaffected by lactate. Octanoate, hexanoate, heptanoate, and beta-hydroxybutyrate inhibited both cyclic AMP accumulation and lipolysis by rat fat cells. The mechanism by which these acids inhibit lipolysis differs from that for long chain fatty acids such as oleate. Oleate directly inhibited triglyceride lipase activity of homogenized rat adipose tissue. In contrast, octanoate, beta-hydroxybutyrate, and lacatate had no effect on triglyceride lipase activity. Hormone-stimulated adenylate cyclase activity of rat fat cell ghosts was inhibited by oleate and 4mM octanoate but not by 1.6 mM octanoate, heptanoate, hexanoate, beta-hydroxybutyrate or lactate. None of the acids affected the soluble protein kinase activity of rat adipose tissue. There was no stimulation by lactate, butyrate, beta-hydroxybutyrate, or octanoate of the soluble or particulate cyclic AMP antilipolytic action of a short chain acid such as octanoate or hexanoate was not accompanied by any drop in total fat cell ATP. The mechanism by which lactate lowers cyclic AMP but not lipolysis remains to be established.     

Cyclic AMP metabolism and lipolysis in cultured human adipocyte precursors

Triacylglycerol breakdown (lipolysis) results from a series of reactions culminated by activation of "hormone-stimulated" triacylglycerol lipase, an enzyme unique to adipose tissue. We have studied various components of the lipolytic process in human omental adipocyte precursors differentiating in culture. The levels of cyclic AMP, the "second messenger" of lipolytic hormones, were about sixfold higher in fat cell precursors than those in abdominal skin fibroblasts. L-Isoproterenol resulted in significant elevation of cyclic AMP levels in both cell types. Preincubation of intact adipocyte precursors with insulin resulted in significant enhancement of "low Km" cyclic AMP phosphodiesterase activity; in contrast, this hormone had no effect on fibroblast phosphodiesterase activity, a distinctive biochemical difference despite the morphological similarities between the two cell types during the early stages of adipocyte precursor maturation. Incubation of adipocyte precursors with isoproterenol resulted in the release of fatty acids into the medium, findings indicative of "hormone-stimulated" lipase activity and, hence, the operation of the entire "lipolytic cascade"; isoproterenol-stimulated lipolysis was inhibited by insulin. Release of fatty acids from fibroblasts was not observed. Thus, "hormone-stimulated" lipolysis and insulin stimulation of cyclic AMP phosphodiesterase activity are expressed during early stages of human adipocyte precursor differentiation.     

Berberine attenuates cAMP-induced lipolysis via reducing the inhibition of phosphodiesterase in 3T3-L1 adipocytes

Berberine, a hypoglycemic agent, has been shown to decrease plasma free fatty acids (FFAs) level in insulin-resistant rats. In the present study, we explored the mechanism responsible for the antilipolytic effect of berberine in 3T3-L1 adipocytes. It was shown that berberine attenuated lipolysis induced by catecholamines, cAMP-raising agents, and a hydrolyzable cAMP analog, but not by tumor necrosis factor α and a nonhydrolyzable cAMP analog. Unlike insulin, the inhibitory effect of berberine on lipolysis in response to isoproterenol was not abrogated by wortmannin, an inhibitor of phosphatidylinositol 3-kinase, but additive to that of PD98059, an extracellular signal-regulated kinase kinase inhibitor. Prior exposure of adipocytes to berberine decreased the intracellular cAMP production induced by isoproterenol, forskolin, and 3-isobutyl-1-methylxanthine (IBMX), along with hormone-sensitive lipase (HSL) Ser-563 and Ser-660 dephosphorylation, but had no effect on perilipin phosphorylation. Berberine stimulated HSL Ser-565 as well as adenosine monophosphate-activated protein kinase (AMPK) phosphorylation. However, compound C, an AMPK inhibitor, did not reverse the regulatory effect of berberine on HSL Ser-563, Ser-660, and Ser-565 phosphorylation, nor the antilipolytic effect of berberine. Knockdown of AMPK using RNA interference also failed to restore berberine-suppressed lipolysis. cAMP-raising agents increased AMPK activity, which was not additive to that of berberine. Stimulation of adipocytes with berberine increased phosphodiesterase (PDE) 3B and PDE4 activity measured by hydrolysis of ³[H]cAMP. These results suggest that berberine exerts an antilipolytic effect mainly by reducing the inhibition of PDE, leading to a decrease in cAMP and HSL phosphorylation independent of AMPK pathway.     

Insulin-mediated antilipolysis in permeabilized rat adipocytes

Elucidating the mechanism by which insulin inhibits lipolysis has been hampered by the unavailability of a broken cell preparation in which the intact cell responses to the hormone could be duplicated. Here we report, using digitonin-permeabilized rat adipocytes, that physiological concentrations of insulin inhibit cyclic AMP-activated lipolysis despite the absence of cytosolic and plasma membrane integrity. Cyclic AMP (1.0 mM) maximally activates lipolysis in permeabilized adipocytes greater than 10-fold. Insulin inhibits this activation in a biphasic manner with maximum inhibition of 59 +/- 8% (N = 7) at 10(-9) M. At the submaximal concentrations of cyclic AMP (1.0 to 10 microM), insulin (10(-9) M) inhibits lipolysis 80 to 90%. Additionally, the antilipolytic effect of insulin is rapid (3 min) and it is specific, with the relatively inactive desoctapeptide analogue of insulin being three orders of magnitude less inhibitory than native insulin. In contrast to permeabilized cells, intact cells demonstrate only a small lipolytic response to cyclic AMP which is insensitive to insulin. These findings suggest the following about insulin's antilipolytic effects: 1) an intact cell is not required; 2) the intracellular mechanism of action does not require physiological concentrations of the freely diffusible cytosolic components; and 3) a site of insulin action independent of adenylate cyclase may play a major role.     

Inhibition of rat and human adipocyte adenylate cyclase in the antilipolytic action of insulin, clofibrate, and nicotinic acid.

Clofibrate (Atromid-S), nicotinic acid, and insulin are known to be potent hypolipidemic and antilipolytic agents. The present study was undertaken to define the mechanism of action of this latter effect on isolated rat and human fat cells. Sodium clofibrate (0.42 mM), nicotinic acid (0.42 mM), and insulin (100 microU/mL) were shown to inhibit norepinephrine-stimulated lipolysis in rat and human adipose cells and this inhibition was associated with a reduction in intracellular 3',5'-cyclic AMP levels. A similar cyclic AMP lowering effect was demonstrated with insulin in the presence of procaine-HCL, which uncouples the adenylate cyclase system from lipolysis. This insulin effect was attributed to inhibition of adenylate cyclase. A direct and significant inhibition of adenylate cyclase in membrane fractions obtained from isolated human adipocytes was demonstrated for all three antilipolytic agents. The common membrane site of action of these agents whereby adenylate cyclase activity is depressed, thus decreasing cyclic AMP production and free fatty acid (FFA) mobilization from adipose stores, implies a central role for the adenylate cyclase system. These findings are consistent with the view that the hypotriglyceridemic effects of clofibrate, nicotinic acid, and insulin may be partly explained by deprivation of FFA substrate for hepatic very low density lipoprotein synthesis.     

Site-directed fluorogenic modification of bacteriorhodopsin by 7-chloro-4-nitrobenz-2-oxa-1,3-diazole

Use of a digitonin-permeabilized rat adipocyte preparation overcomes inherent problems which occur when currently used broken cell systems are utilized for studying the regulation of hormone-sensitive lipase. The effect of digitonin on plasma membrane permeability was concentration-dependent being nearly maximum at 20 micrograms/ml as assessed by (a) leakage of 85% cellular lactate dehydrogenase after 30 min, (b) the efflux of 72% preloaded cellular (86Rb) rubidium within 10 min and (c) immediate inhibition of glucose oxidation. Hormone-modulated rates of lipolysis were preserved in this preparation. Following maximal activation of lipolysis in adipocytes with catecholamines, the rate of lipolysis in intact cells and digitonin-treated cells was elevated 26-fold and 20-fold respectively, while the rate in homogenates from these cells was elevated only 2.8-fold. Insulin suppressed catecholamine-dependent activation of lipolysis by at least 90% when subsequently measured in intact cells and digitonin-treated cells. Insulin suppression was only 56% when measured in homogenates. The hormone-sensitive lipase in permeabilized cells, as opposed to intact cells and homogenates, was activated by cyclic AMP to a degree that approached activation by catecholamines. In homogenates, cyclic AMP (1.0 mM) plus ATP (0.25 mM) activated the lipase only 36%, while neither alone had any effect. In digitonin-permeabilized cells, however, exogenous cyclic AMP alone activated lipolysis in a concentration-dependent manner with 1 microM, 30 microM and 1.0 mM cyclic AMP activating lipolysis by 41%, 250% and 1300% respectively. In contrast, lipolysis in intact cells was activated by 0%, 25% and 250% by 1 microM, 30 microM and 1.0 mM cyclic AMP. Also in digitonin-treated preparations, ATP alone activated lipolysis 40%, but ATP plus cyclic AMP activated lipolysis to only 74% of the level due to cyclic AMP alone. These studies indicate that the permeabilized adipocyte preparation is an excellent system for investigating the mechanism of regulation of the hormone-sensitive lipase by permitting manipulation of the intracellular environment while preserving the physiological response of the lipase.     

Adenosine 3',5'cyclic monophosphate in adipose tissue of diabetic rats.

Normal male rats were made chronically diabetic by injection of alloxan or acutely diabetic by injection of anti-insulin serum. The concentration of cyclic AMP in epididymal adipose tissue was increased approximately 2 1/2-fold 24 h after alloxan administration and up to 7-fold 72 h post-alloxan. Treatment of alloxan-diabetic rats with insulin for 4 h completely suppressed lipolysis but only partially suppressed cyclic AMP levels; 6 h following insulin treatment cyclic AMP levels were normal. When segments of the epididymal fat bodies were incubated in vitro the high cyclic AMP levels were not maintained but instead decreased spontaneously. Addition of insulin to the incubation media decreased lipolysis in tissues of diabetic rats to levels measured in tissues of normal rats and accelerated the decline in cyclic AMP levels but did not return cyclic AMP levels to normal. Rats rendered acutely insulin deficient by injection of anti-insulin serum showed increased plasma glucose and free fatty acid levels and increased adipose tissue free fatty acid, and cyclic AMP levels 30 min following injection of the antiserum. Plasma glucagon levels increased but not until 2 h following anti-insulin serum, thereby excluding the possibility that an increment in plasma glucagon is the primary stimulus for the acceleration of lipolysis in diabetes. These data are consistent with the view that control of adipose tissue cyclic AMP levels in situ is an important physiologic action of insulin.     

Adenosine 3′,5′cyclic monophosphate in adipose tissue of diabetic rats

Normal male rats were made chronically diabetic by injection of alloxan or acutely diabetic by injection of anti-insulin serum. The concentration of cyclic AMP in epididymal adipose tissue was increased approximately 24 h after alloxan administration and up to 7-fold 72 h post-alloxan. Treatment of alloxan-diabetic rats with insulin for 4 h completely suppressed lipolysis but only partially suppressed cyclic AMP levels; 6 h following insulin treatment cyclic AMP levels were normal. When segments of the epididymal fat bodies were incubated in vitro the high cyclic AMP levels were not maintained but instead decreased spontaneously. Addition of insulin to the incubation media decreased lipolysis in tissues of diabetic rats to levels measured in tissues of normal rats and accelerated the decline in cyclic AMP levels but did not return cyclic AMP levels to normal. Rats rendered acutely insulin deficient by injection of anti-insulin serum showed increased plasma glucose and free fatty acid levels and increased adipose tissue free fatty acid, and cyclic AMP levels 30 min following injection of the antiserum. Plasma glucagon levels increased but not until 2 h following anti-insulin serum, thereby excluding the possibility that an increment in plasma glucagon is the primary stimulus for the acceleration of lipolysis in diabetes. These data are consistent with the view that control of adipose tissue cyclic AMP levels in situ is an important physiologic action of insulin.     

Effects of pertussis toxin treatment on the metabolism of rat adipocytes

The protein toxin present in Bordetella pertussis vaccine blocks the inhibition of adenylate cyclase by prostaglandins and adenosine which may be secondary to ADP-ribosylation of an inhibitory guanine nucleotide-binding protein. The stimulatory effects of alpha 1-catecholamine agonists on 32P uptake into phosphatidic acid and phosphatidylinositol in isolated rat adipocytes were virtually abolished by pertussis toxin treatment. In contrast, the stimulatory effects of insulin were increased in adipocytes after pertussis toxin treatment. Pertussis toxin treatment did not alter insulin stimulation of glucose oxidation and actually increased glucose conversion to lipid. Basal lipolysis was elevated in adipocytes by pertussis toxin treatment but not basal cyclic AMP. However, the increases in cyclic AMP and lipolysis due to low concentrations of catecholamines and forskolin were markedly potentiated by pertussis toxin treatment. The inhibitory effects of adenosine on cyclic AMP stimulation due to catecholamines were abolished by pertussis toxin. These data indicate that pertussis toxin selectively interferes with inhibition of cyclic AMP accumulation in rat adipocytes by adenosine, potentiates the increases in cyclic AMP due to catecholamines, increases the stimulatory effects of insulin on adipocyte metabolism, and interferes with alpha 1-catecholamine stimulation of phosphatidylinositol turnover.     

Pertussis toxin reversal of the antilipolytic action of insulin in rat adipocytes in the presence of forskolin does not involve cyclic AMP

Insulin inhibition of lipolysis in the presence of forskolin was reversed by a four hour exposure of adipocytes to pertussis toxin. In contrast, the antilipolytic action of insulin against lipolysis due to theophylline was unaffected by pertussis toxin as was the ability of insulin to lower cyclic AMP in the presence of either forskolin or theophylline. The stimulation of adenylate cyclase by norepinephrine in crude plasma membranes obtained from rat adipocytes was inhibited by N6-(Phenylisopropyl)adenosine (PIA) and abolished by pretreating rat adipocytes with pertussis toxin. The stimulation of glucose metabolism by insulin was not altered by pertussis toxin pretreatment of rat adipocytes. These findings suggest that pertussis toxin selectively abolishes the antilipolytic effect of insulin in the presence of forskolin through a cyclic AMP independent mechanism.     

Characterization of antilipolytic action of polyamines in isolated rat adipocytes.

The interactions of polyamines with the lipolytic system were studied in isolated rat adipocytes. Spermine, spermidine and putrescine significantly inhibited adenosine deaminase-stimulated lipolysis. An antilipolytic effect of spermine was detectable at a concentration of 0.25 mM (P less than 0.05). At a concentration of 10 mM all three polyamines inhibited the stimulated lipolysis by 50-60% (P less than 0.001). In addition, spermine enhanced the antilipolytic sensitivity of insulin. Spermine (1 mM) decreased the half-maximal inhibitory concentration of insulin from 320 +/- 70 pM to 56 +/- 20 pM (P less than 0.01). The antilipolytic effects and the cyclic-AMP-lowering effects of the polyamines were almost completely prevented in the presence of different phosphodiesterase (PDE) inhibitors (3-isobutyl-1-methylxanthine and RO 20-1724) and, in addition, polyamines had no effect on lipolysis stimulated by dibutyryl cyclic AMP, indicating that polyamines may inhibit lipolysis by activating the PDE enzyme. This latter suggestion was confirmed by demonstrating that spermine (5 mM) significantly enhanced the low-Km PDE enzyme activity (P less than 0.01). Finally, the amounts of polyamines present in isolated adipocytes were measured, and the estimated cytoplasmic concentrations were 0.02 mM (putrescine), 0.86 mM (spermidine), and 1.0 mM (spermine). It is concluded that polyamines may possibly be involved in the physiological regulation of triacylglycerol mobilization in adipocytes.     

Insulin-like effects of fluoroacetate on lipolysis and lipogenesis in adipose tissue.

Hormone-stimulated lipolysis in adipose tissue was inhibited by fluoroacetate and there was a concomitant decrease in both the basal and hormone-stimulated cyclic AMP levels. Adenylate cyclase (EC 4.6.1.1) activity in membrane preparations was inhibited by fluoroacetate. There was no influence of fluoroacetate on the low Km cyclic AMP phosphodiesterase (EC 3.1.4.17) activity. The rate of glucose conversion to fatty acids was increased when adipose tissue was incubated in the presence of fluoroacetate. The outputs of pyruvate and lactate into the incubation medium were decreased at this time, suggesting decreased tissue pyruvate levels and a site of activation of lipogenesis distal to pyruvate formation. Pyruvate dehydrogenase (EC 1.2.4.1) activity was increased twofold in adipose tissue incubated in the presence of fluoroacetate. This was attributed to a fluoroacetate-induced inhibition of pyruvate dehydrogenase kinase, the enzyme responsible for inactivating the pyruvate dehydrogenase complex. Glucose transport was increased to a small but significant degree by fluoroacetate. In addition, both the tissue content of citrate and its release into the incubation medium were increased, suggesting that fluoroacetate resulted in an inhibition of aconitase (EC 4.2.1.3). The tissue ATP content was unchanged. Because the antilipolytic and lipogenic effects of fluoroacetate parallel those of insulin, they may share a common mechanism.     

Inhibitory effect and mode of action of somatostatin on lipolysis in chicken adipocytes

The effect of somatostatin on lipolysis was investigated utilizing isolated chicken adipocytes. Somatostatin-14 and -28 inhibited basal lipolysis. This ability to suppress glycerol release (used as an index of lipolysis) was emphasized in presence of stimulated lipolysis. Concentration of 1 ng/ml somatostatin-14 (0.625 nM) and somatostatin-28 (0.312 nM) was found to inhibit completely the glycerol release induced by concentrations of glucagon up to 2 ng/ml (0.58 nM). The percentage of inhibition was dose-dependent. The antilipolytic effect of somatostatin-14 was also observed during ACTH and aminophylline-stimulated lipolysis. Among the mechanisms which could account for the inhibition, a possible competitive effect of somatostatin-14 with 125I-labelled glucagon binding to adipocyte membranes was excluded. The small inhibiting effect of somatostatin-14 on glycerol release prompted by dibutyryl cyclic AMP, together with the significant inhibiting effect on aminophylline-stimulated lipolysis argued for a reduction of cyclic AMP accumulation. The increase of cyclic AMP levels induced by glucagon was substantially reduced in presence of somatostatin-14. It was concluded that in chicken adipocytes somatostatin inhibited the rate of lipolysis and that reduction on cyclic AMP could be responsible, at least in part, for the antilipolytic effect.     

Regulation of cyclic AMP metabolism and lipolysis in isolated rat fat cells by insulin, N6-(phenylisopropyl) adenosine and 2',5'-dideoxyadenosine.

The increases in cyclic AMP accumulation and lipolysis by rat fat cells incubated in the presence of catecholamines were abolished by N6-(phenylisopropyl) adenosine. The same inhibition of cyclic AMP accumulation was seen in the presence of 2',5'-dideoxyadenosine but lipolysis was unaffected. In contrast, insulin inhibited lipolysis without affecting cyclic AMP accumulation by norepinephrine plus adenosine deaminase. These results suggest that there are either multiple pools of cyclic AMP or that ther exists some other mechanism which is involved in the regulation of lipolysis by hormones.     

The effect of manganese on lipogenesis, lipolysis, adenosine 3',5' cyclic monophosphate and cyclic nucleotide phosphodiesterase activity in adipocytes from NZY mice

The insulin-like action of Mn2+ was investigated in adipocytes isolated from male mice of the NZY strain. In agreement with previous reports Mn2+ was found to stimulate both the oxidation of [U-14C]glucose to CO2 and the incorporation of [U-14C]glucose into total lipid and fatty acid, and to inhibit lipolysis stimulated by epinephrine, cyclic AMP or theophylline. The maximum effect of Mn2+ was greater than that of a maximal concentration of insulin and when both agents were present in these concentrations the effect was similar to that observed with Mn2+ alone. Mn2+ lowered the level of cyclic AMP in adipocytes incubated with isoproterenol. The effect was seen as early as 1 minute and it was greater than a maximal concentration of insulin. When Mn2+ was added to suspensions of adipocytes it increased the activity of the membrane-bound low Km cyclic nucleotide phosphodiesterase in subsequently prepared homogenates. The enzyme was stimulated 1.8-fold by Mn2+ compared with a 1.7-fold stimulation by insulin and a 2-fold stimulation in the presence of both Mn2+ and insulin.     

Similar and opposite effects of dibutyryl cyclic AMP and insulin on glucose metabolism in adipose tissue

The effects of N⁶-2′-O-dibutyryl cyclic AMP on glucose metabolism and lipolysis in fragments of rat epididymal adipose tissue were studied. Measurements were made of glucose uptake, conversion of glucose carbon to CO₂ and tissue fatty acids and glyceride-glycerol, lactate production, and glycerol release. Low concentrations of dibutyryl cyclic AMP (0.1–0.5 mM) increased all parameters of glucose metabolism and inhibited glycerol release in tissue from both normally fed and fasted rats. Higher concentrations of dibutyryl cyclic AMP (3–5 mM) diminished glucose utilization and greatly accelerated lipolysis. Insulin, 50 μunits/ml, accelerated glucose metabolism in the presence of either low or high concentrations of dibutyryl cyclic AMP though the effect of insulin was greatly reduced by 3 mM dibutyryl cyclic AMP. Tissue exposed to concentrations of dibutyryl cyclic AMP which inhibited glucose metabolism (5 mM), then rinsed and reincubated without dibutyryl cyclic AMP, displayed increased glucose utilization. The results of these experiments emphasize the need for caution in interpretation of the effects of dibutyryl cyclic AMP on adipose tissue metabolism and the need for further research to elucidate the role of cyclic AMP in the regulation of glucose metabolism.