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.     

Relationship between cyclic AMP production and lipolysis induced by forskolin in rat fat cells.

Forskolin (7 beta-acetoxy-8, 13-epoxy-1 alpha,6 beta,9 alpha-trihydroxy-labd-14-ene-11-one) induced both cyclic AMP production and lipolysis in intact fat cells, but stimulated lipolysis without increasing cyclic AMP at a concentration of 10(-5) M. Homogenization of fat cells elicited lipolysis without elevation of cyclic AMP. Forskolin did not stimulate lipolysis in the homogenate. Forskolin stimulated both cyclic AMP production and lipolysis in a cell-free system consisting of endogenous lipid droplets and a lipoprotein lipase-free lipase fraction prepared from fat cells. However, at a concentration of 10(-6) M, it induced lipolysis without increase in the cyclic AMP content in this cell-free system. In the cell-free system, homogenization of the lipid droplets resulted in marked increase in lipolysis to almost the same level as that with 10(-4) M forskolin without concomitant increase in cyclic AMP. Addition of forskolin to a cell-free system consisting of homogenized lipid droplets and lipase did not stimulate lipolysis further. Phosphodiesterase activities were found to be almost the same both in the presence and absence of forskolin in these reaction mixtures. Although 10(-3) M forskolin produced maximal concentrations of cyclic AMP: 6.7 x 10(-7) M in fat cells and 2.7 x 10(-7) M in the cell-free system, 10(-4) M cyclic AMP did not stimulate lipolysis in the cell-free system. In a cell-free system consisting of lipid droplets and the lipase, pyrophosphate inhibited forskolin-induced cyclic AMP production, but decreased forskolin-mediated lipolysis only slightly. Based on these results, mechanism of lipolytic action of forskolin was discussed.     

Mechanism of the stimulatory action of okadaic acid on lipolysis in rat fat cells

Okadaic acid was found to induce concentration- and time-dependent lipolysis in rat fat cells in the absence of lipolytic hormones, but it did not significantly increase the total hormone-sensitive lipase (HSL) activity in these fat cells, the activity of HSL extracted from fat layer and that of HSL in the supernatant of homogenized fat cells. Western blotting of fat cell homogenate fractions with an antiserum raised against synthetic peptide derived from rat HSL showed that HSL protein shifted from the supernatant to the fat layer in response to okadaic acid, which increased the HSL protein content on the fat layer and concomitantly reduced that of the supernatant, concentration- and time-dependently. Sonication of the fat cells abolished their responsiveness to okadaic acid. The lipolytic action of okadaic acid was examined and its site was identified using a cell-free system comprising lipid droplets isolated from rat fat cells and HSL. Okadaic acid induced lipolysis in this cell-free system and sonication of the lipid droplets caused disappearance of lipolytic action of okadaic acid. Okadaic acid failed to stimulate lipolysis in a cell-free system comprising HSL and artificial lipid droplets (trioleoylglycerol emulsified with gum arabic) instead of lipid droplets isolated from rat fat cells. These results suggest that okadaic acid does not increase the catalytic activity of HSL but induces translocation of HSL to the lipid droplets isolated from rat fat cells. The site of the lipolytic action of okadaic acid in relation to the interaction between HSL and lipid droplet is discussed.     

Role of phospholipid in adrenaline-induced lipolysis and cyclic AMP production.

Lipid micelles consisting of a glyceride mixture (triolein, diolein, and monoolein) and lecithin bound adrenaline-14C more strongly than did micelles consisting of the glyceride mixture only. Lipid micelles consisting of the glyceride mixture and phosphatidic acid also bound adrenaline-14C effectivily, whereas lipid micelles consisting of the glyceride mixture and diglyceride, obtained from lecithin, did not bind the hormone strongly. Both phenoxybenzamine (an alpha- blocker) and propranolol (a beta-blocker) strongly inhibited the association between adrenaline-14C and lipid micelles consisting of the glyceride mixture and lecithin. Propranolol, inhibited adrenaline-induced lipolysis in both fat cells and fat globules, whereas, phenoxybenzamine, did not affect adrenaline-induced lipolysis. Both agents reduced adrenaline-induced adenyl-cyclase activation in fat cell ghosts. Phospholipid was also found to be related with adrenaline-mediated adenylcyclase activation.     

Substrate-dependent lipolysis induced by isoproterenol

The relationship between isoproterenol-induced lipolysis and the phosphorylation of perilipin and hormone-sensitive lipase (HSL) was examined using cell-free systems consisting of lipid droplets isolated from rat fat cells and HSL, and/or trioleoylglycerol emulsified with gum arabic and HSL. Isoproterenol was found to stimulate lipolysis in the cell-free system with the lipid droplets without an increase in the phosphorylation of either perilipin or HSL. On the other hand, no stimulation of lipolysis was found in the cell-free system containing lipid droplets despite increases in the phosphorylation of perilipin and HSL. In the cell-free system consisting of trioleoylglycerol emulsified with gum arabic and HSL, neither isoproterenol nor increases in the phosphorylation of perilipin and HSL accelerated lipolysis. These results suggest that isoproterenol-induced lipolysis may not be mediated through the phosphorylation of perilipin and HSL, and may rather be dependent on the substrate of HSL.     

Dissociation of the effect of adrenalin on glucose uptake from that on adenosine cyclic 3′,5′-monophosphate levels and on lipolysis in rat-isolated fat cells

The effects of the adrenergic blocking agents phenoxybenzamine, phentolamine, indoramin and propranol on adrenalin-stimulated glucose uptake, lipolysis and cyclic AMP formation have been studied in rat-isolated fat cells. The β-adrenergic blocking agent propranolol was found to inhibit adrenaline-stimulated lipolysis and cyclic AMP formation at concentrations which did not inhibit adrenalin-stimulated glucose uptake. Conversely, the α-adrenergic blocking agent phenoxybenzamine inhibited adrenalin-stimulated glucose uptake at concentrations which did not inhibit lipolysis and cyclic AMP formation. The α-adrenergic blocking agents phentolamine and indoramin did not show differential effects on adrenalin-stimulated lipolysis and glucose uptake. Phenoxybenzamine had no effect on glucose uptake stimulated by insulin, adrenocorticotropic hormone and dibutyryl cyclic AMP. It is suggested that a substantial proportion of adrenalin-stimulated glucose uptake in rat-isolated fat cells is mediated by a mechanism not involving cyclic AMP. The adrenalin receptor was apparently α in type although the lack of effects of phentolamine and indoramin were not typical of those described on other α-systems.     

Hormone action at the membrane level. IV. Epinephrine binding to rat liver plasma membranes and rat epididymal fat cells.

[3-H]Epinephrine binding to isolated purified rat liver plasma membranes is a reversible process. An initial peak in binding occurs at about 15 min and a plateau occurs by 50 min. Optimal binding occurred at a membrane protein concentration of 125mug. Rat liver plasma membranes stored at-70 degrees C up to 4 weeks showed no difference in epinephrine binding capacity as compared to control fresh membranes. Epinephrine binding to liver plasma membranes was decreased by 79% by phospholipase A2 (phosphatide acylhydrolase EC 3.1.1.4), 81% by phospholipase C (phosphatidylcholine choline phosphohydrolase EC 3.1.4.3) and 59% by phospholipase D (phosphatidylcholine phosphatidohydrolase EC 3.1.4.4). Trypsin and pronase digestion of the membrane decreased epinephrine binding by 97 and 47% respectively. In the presence of 10-3M Mg-2+ ions, increasing concentrations of QTP decreased epinephrine binding to liver plasma membranes. A maximal effect was demonstrated with 10-5M GTP, representing an inhibition of 52% of the control. In a Mg-2+ -free system, epinephrine binding was unaffected by GTP. However, in a Mg-2+ -free system, increasing concentrations of ATP cause increasing inhibition of hormone binding. ATP at 10-3 M reduced epinephrine binding to 28% of the control. GRP (10-5 M) was shown to inhibit epinephrine uptake rather than epinephrine release from the membrane. [3-H]Epinephrine binding to isolated rat epididymal fat cells shows an initial peak within 5 min followed by a gradual rise which plateaus after 60 min. Epinephrine binding increased nearly linearly with increasing fat cell protein concentration (40-200 mug protein). GTP (10-5 M) and ATP (10-4 M) decreased epinephrine binding to rat epididymal fat cells by 41%. Nearly complete inhibition of binding was demonstrated with 10-2-10-3M ATP. Epinephrine analogs that contain two hydroxyl groups in the 3 and 4 position on the benzene ring act as inhibitors of [3-H]epinephrine binding to rat adipocytes. Alteration of the epinephrine side chain has relatively little influence on binding. Analogs in which one of the ring hydroxyl groups is missing or methylated are poor inhibitors of [3-H]epinephrine binding. Alpha-(phentolamine and phenoxybenzamine) and beta-(propranolol and dichorisoproterenol) adrenergic blocking agents were tested with respect to their ability to influence [3-H]epinephrine binding and their influence on epinephrine-stimulated lipolysis. Only dichloroisoproterenol significantly inhibited epinephrine binding (by 25%). The two beta-adrenergic blocking agents caused an inhibition of epinephrine-stimulated glycerol release, with propranolol being most effective. Phentolamine and phenoxybenzamine had no significant effect on the epinephrine stimulation of glycerol release by fat cells.     

Inhibition of lipolysis in hamster adipocytes with selective alpha-adrenergic stimuli. Functional characterization of the alpha-receptor

This communication shows the relative potencies of the alpha-agonists clonidine, methoxamine, methyl norepinephrine and phenylephrine in producing inhibition of lipolysis. At cell densities greater than 15 mg cell/ml lipolysis activated by either 1-methyl-3-isobutyl xanthine or adenosine deaminase was inhibited by alpha-adrenergic stimuli with a rank order of potency of clonidine greater than methoxamine greater than methyl norepinephrine; phenylephrine produced a further stimulation of lipolysis. At the same cell density isoproterenol-accelerated lipolysis was inhibited by alpha-adrenergic stimuli with a rank order of potency of phenylephrine greater than methoxamine greater than clonidine greater than methyl norepinephrine. When the density of fat cells was reduced to less than 5 mg/ml, clonidine was a more effective inhibitor of isoproterenol-activated lipolysis thatn phenylephrine. Lipolysis that was activated by dibutyryl cyclic AMP, ACTH or cholera enterotoxin was not reduced by any alpha-adrenergic agent. Under conditions when clonidine failed to inhibit catecholamine-activated lipolysis (i.e., at cell densities greater than 15 mg/ml), it failed to antagonize the antilipolytic activity of phenylephrine. The antilipolytic activities of clonidine and phenylephrine were most effectively antagonized by the blocking drugs phentolamine and yohimbine; in contrast, phenoxybenzamine and prazosin were less effective blockers. These data indicate that the alpha-adrenergic receptor on hamster fat cells is similar to presynaptic alpha-adrenergic receptors. The data further suggest the possibility that phenylephrine may exert its action through a separate alpha-adrenergic receptor mechanism.     

Roles of alpha and beta adrenergic receptors in control of glucose oxidation in hamster epididymal adipocytes

Oxidation of [¹⁴C]glucose in isolated epididymal adipocytes from Golden hamsters was stimulated by isoproterenol and norepinephrine, which all interact with β-adrenergic receptors and by adrenorticotrophic hormone. In contrast α-receptor agonists, such as phenylephrine, methoxamine or clonidine did not increase basal glucose oxidation. The β-adrenergic blocking drug propranolol inhibited both lipolysis and glucose oxidation when these had been stimulated by isoproterenol, ephinephrine and phenoxybenzamine did not the α-adrenergic blocking drugs phentolamine and phenoxybenzamine did not influence lipolysis or glucose oxidation when isoproterenol provided the stimulus and increased both liposlysis and glucose metabolism in the presence of either epinephrine or norepinephrine. All α-adrenergic agonists tested (phenylephrine, methoxamine and clonidine) lowered liposlysis and glucose oxidation in isolated adipocytes exposed to isoproterenol. However, when adrenorcortropin provided the stimulus for glucose oxidation and lipolysis, only clonidine produced a significant reduction in lipolysis and glucose oxidation. None of the α-agonists influenced glucose metabolism which had been increased by insulin. These data confirm the presence of both α and β adrenergic receptors on hamster epididymal adipocytes and suggests that they exert antagonistic influences on lipolysis and glucose oxidation. These data are also consistent with the view that adrenergic stimulation of glucose oxidation and lipolysis in adipocytes are both mediated through β receptors.     

Hormone action at the membrane level. IV. Epinephrine binding to rat liver plasma membranes and rat epididymal fat cells

[³H]Epinephrine binding to isolated purified rat liver plasma membrane is a reversible process. An initial peak in binding occurs at about 15 min and a plateau occurs by 50 min. Optimal binding occurred at a membrane protein concentration of 125μg. Rat liver plasma membranes stored at ?70 °C up to 4 weeks showed no difference in epinephrine binding capacity as compared to control fresh membranes.Epinephrine binding to liver plasma membranes was decreased by 79% by phospholipase A₂ (phosphatide acylhydrolase EC 3. 1. 1. 4), 81% by phospholipase C (phosphatidylcholine choline phosphohydrolase EC 3.1.4.3) and 59% by phopholipase D (phosphatidylcholine phosphatidohydrolase EC 3.1.4.4). Trypsin and pronase digestion of the membrane decreased epinephrine binding by 97 and 47% respectively.In the presence of 10^?3M Mg²⁺ ions, increasing concentrations of GTP decreased epinephrine binding to liver plasma membranes. A maximal effect was demonstrated with 10^?5M GTP, representing an inhibition of 52% of the control. In a Mg²⁺-free system, epinephrine binding was unaffected by GTP. However, in a Mg²⁺-free system, increasing concentrations of ATP cause increasing inhibition of hormone binding. ATP at 10^-3 M reduced epinephrine binding to 28% of the control. GTP (10^?5M) was shown to inhibit epinephrine uptake rather than epinephrine release from the membrane.[³H]Epinephrine binding to isolated rat epididymal fat cells shows an initial peak within 5 min followed by a gradual rise which plateaus after 60 min. Epinephrine binding increased nearly linearly with increasing fat cell protein concentration (40–200 μg protein).GTP (10^?5M) and ATP (10^?4M) decreased epinephrine binding to rat epididymal fat cells by 41%. Nearly complete inhibition of binding was demonstrated with 10^?2?10^?3M ATP. Epinephrine analogs that contain two hydroxyl groups in the 3 and 4 position on the benzene ring act as inhibitors of [³H]epinephrine binding to rat adipocytes. Alteration of the epinephrine side chain has relatively little influence on binding. Analogs in which one of the ring hydroxyl groups is missing or methylated are poor inhibitors of [³H]epinephrine binding.Alpha-(phentolamine and phenoxybenzamine) and beta-(propranolol and dichorisoproterenol) adrenergic blocking agents were tested with respect to their ability to influence [³H]epinephrine binding and their influence on epinephrine-stimulated lipolysis. Only dichloroisoproterenol significantly inhibited epinephrine binding (by 25%). The two beta-adrenergic blocking agents caused an inhibition of epinephrine-stimulated glycerol release, with propranolol being most effective. Phentolamine and phenoxybenzamine had no significant effect on the epinephrine stimulation of glycerol release by fat cells.     

Effects of adrenergic blocking agents on lipolysis and adenyl cyclase activity induced by vasoactive intestinal polypeptide (VIP).

VIP stimulates lipolysis and adenyl cyclase activity in the rat adipose tissue. VIP-induced lipolysis and adenyl cyclase activity are not affected by phenoxybenzamine. VIP-induced lipolysis is inhibited by propranolol but VIP-induced adenyl cyclase activity is not.     

Relationships between lipolysis induced by various lipolytic agents and hormone-sensitive lipase in rat fat cells

Norepinephrine induced lipolysis in rat fat cells, in vitro, in a time- and concentration-dependent manner, without concomitantly increasing hormone-sensitive lipase (HSL) activity. It also induced, time and concentration dependently, HSL translocation from the cytosol to the lipid droplets in fat cells. Isoproterenol, forskolin, dibutyryl cyclic AMP, and theophylline also induced lipolysis in fat cells, but did not stimulate HSL activity. These agents also induced HSL translocation from the cytosol to the lipid droplets in fat cells: about 80% to 90% of all HSL was located in lipid droplets after incubation for 1 h.These results suggest that the critical event in lipolytic activation of fat cells induced by lipolytic agents is not an increase in the catalytic activity of HSL but translocation of HSL to its substrate on the surfaces of lipid droplets in fat cells.-Morimoto, C., K. Kameda, T. Tsujita, and H. Okuda. Relationships between lipolysis induced by various lipolytic agents and hormone-sensitive lipase in rat fat cells. J. Lipid Res. 2001. 42: 120;-127.     

A phospholipase D-dependent process forms lipid droplets containing caveolin,adipocyte differentiation-related protein,and vimentin in a cell-free system

We developed a microsome-based, cell-free system that assembles newly formed triglyceride (TG) into spherical lipid droplets. These droplets were recovered in the d 相似文献   

Roles of alpha and beta adrenergic receptors in control of glucose oxidation in hamster epididymal adipocytes.

Oxidation of [14C] glucose in isolated epididymal adipocytes from Golden hamsters was stimulated by isoproterenol, epinephrine and norepinephrine, which all interact with beta-adrenergic receptors and by adrenocorticotrophic hormone. In contrast alpha-receptor agonists, such as phenylephrine, methoxamine or clonidine did not increase basal glucose oxidation. The beta-adrenergic blocking drug propranolol inhibited both lipolysis and glucose oxidation when these had been stimulated by isoproterenol, epinephrine or norepinephrine. Conversely, the alpha-adrenergic blocking drugs phentolamine and phenoxybenzamine did not influence lipolysis or glucose oxidation when isoproterenol provided the stimulus and increased both lipolysis and glucose metabolism in the present of either epinephrine or norepinephrine. All alpha-adrenergic agonists tested (phenylephrine, methoxamine and clonidine) lowered lipolysis and glucose oxidation isolated adipocytes exposed to isoproterenol. However, when adrenocorticotropin provided the stimulus for glucose oxidation and lipolysis, only clonidine produced a significant reduction in lipolysis and glucose oxidation. None of the alpha-agonists influenced glucose metabolism which had been increased by insulin. These data confirm the presence of both alpha and beta adrenergic receptors on hamster epididymal adipocytes and suggest that they exert antagonistic influences on lipolysis and glucose oxidation. These data are also consistent with the view that adrenergic stimulation of glucose oxidation and lipolysis in adipocytes are both mediated through beta receptors.     

Effects of epinephrine, corticotropin, and thyrotropin on lipolysis and glucose oxidation in rat adipose tissue

(Log dose)-response curves have been determined for lipolysis and for the conversion of glucose-(14)C to (14)CO(2) by adipose tissue from rats in the presence of epinephrine, corticotropin, and thyrotropin. The stimulatory effect of epinephrine on lipolysis was greater than that of corticotropin or thyrotropin. Lipolysis induced by epinephrine was inhibited by propranolol but only slightly by phenoxybenzamine, whereas lipolysis induced by corticotropin was inhibited by phenoxybenzamine to a much greater extent than by propranolol. Neither blocking drug had a pronounced effect on the response to thyrotropin. Epinephrine stimulated the oxidation of glucose-(14)C to CO(2) more than did either thyrotropin or corticotropin. Moreover, epinephrine stimulated the conversion of glucose-(14)C to CO(2) and fatty acids even when lipolysis was not increased. These studies indicate that epinephrine can affect glucose utilization independently of its effect on lipolysis.     

The lipolytic stimulation of 3T3-L1 adipocytes promotes the translocation of hormone-sensitive lipase to the surfaces of lipid storage droplets

Hormone-sensitive lipase catalyzes the rate-limiting step in the release of fatty acids from triacylglycerol-rich lipid storage droplets of adipocytes, which contain the body's major energy reserves. Hormonal stimulation of cAMP formation and the activation of cAMP-dependent protein kinase leads to the phosphorylation of hormone-sensitive lipase and a large increase in lipolysis in adipocytes. By contrast, phosphorylation of hormone-sensitive lipase by the kinase in vitro results in a comparatively minor increase in catalytic activity. In this study, we investigate the basis for this discrepancy by using immunofluorescence microscopy to locate hormone-sensitive lipase in lipolytically stimulated and unstimulated 3T3-L1 adipocytes. In unstimulated cells, hormone-sensitive lipase is diffusely distributed throughout the cytosol. Upon stimulation of cells with the beta-adrenergic receptor agonist, isoproterenol, hormone-sensitive lipase translocates from the cytosol to the surfaces of intracellular lipid droplets concomitant with the onset of lipolysis, as measured by the release of glycerol to the culture medium. Both hormone-sensitive lipase translocation and lipolysis are reversed by the incubation of cells with the beta-adrenergic receptor antagonist, propranolol. The treatment of cells with cycloheximide fails to inhibit lipase translocation or lipolysis, indicating that the synthesis of nascent proteins is not required. Cytochalasin D and nocodazole used singly and in combination also failed to have a major effect, thus suggesting that the polymerization of microfilaments and microtubules and the formation of intermediate filament networks is unnecessary. Hormone-sensitive lipase translocation and lipolysis were inhibited by N-ethylmaleimide and a combination of deoxyglucose and sodium azide. We propose that the major consequence of the phosphorylation of hormone-sensitive lipase following the lipolytic stimulation of adipocytes is the translocation of the lipase from the cytosol to the surfaces of lipid storage droplets.     

Adipokinetic hormone-induced mobilization of fat body triglyceride stores in Manduca sexta: role of TG-lipase and lipid droplets

Triglycerides (TG) stores build up in the insect fat body as lipid droplets at times of excess of food. The mobilization of fat body triglyceride (TG) is stimulated by adipokinetic hormones (AKH). The action of AKH involves a rapid activation of cAMP-dependent protein kinase (PKA). Recent in vitro studies have shown that PKA phosphorylates and activates the TG-lipase substrate, the lipid droplets. Conversely, purified TG-lipase from Manduca sexta fat body is phosphorylated by PKA in vitro but is not activated. This study was directed to learn whether or not AKH promotes a change in the state of phosphorylation of the lipase in vivo, and what are the relative contributions of cytosol and lipid droplets to the overall increase of lipolysis triggered by AKH. TG-lipase activity of fat body cytosols isolated from control and AKH-treated insects was determined against the native substrate, in vivo [3H]-TG radiolabeled lipid droplets, obtained from control and AKH-treated insects. The lipase activity of the system composed of AKH-cytosol and AKH-lipid droplets (11.1 +/- 2.1 nmol TG/min-mg) was 3.1-fold higher than that determined with control cytosol and lipid droplets (3.6 +/- 0.5 nmol TG/min-mg). Evaluation of the role of AKH-induced changes in the lipid droplets on lipolysis showed that changes in the lipid droplets are responsible for 70% of the lipolytic response to AKH. The remaining 30% appears to be due to AKH-dependent changes in the cytosol. However, the phosphorylation level of the TG-lipase was unchanged by AKH, indicating that phosphorylation of the TG-lipase plays no role in the activation of lipolysis induced by AKH.     

Dynamics of lipid droplet-associated proteins during hormonally stimulated lipolysis in engineered adipocytes: stabilization and lipid droplet binding of adipocyte differentiation-related protein/adipophilin

In mature adipocytes, triglyceride is stored within lipid droplets, which are coated with the protein perilipin, which functions to regulate lipolysis by controlling lipase access to the droplet in a hormone-regulatable fashion. Adipocyte differentiation-related protein (ADRP) is a widely expressed lipid droplet binding protein that is coexpressed with perilipin in differentiating fat cells but is minimally present in fully differentiated cultured adipocytes. We find that fibroblasts ectopically expressing C/EBPalpha (NIH-C/EBPalpha cells) differentiate into mature adipocytes that simultaneously express perilipin and ADRP. In response to isoproterenol, perilipin is hyperphosphorylated, lipolysis is enhanced, and subsequently, ADRP expression increases coincident with it surrounding intracellular lipid droplets. In the absence of lipolytic stimulation, inhibition of proteasomal activity with MG-132 increased ADRP levels to those of cells treated with 10 mum isoproterenol, but ADRP does not surround the lipid droplet in the absence of lipolytic stimulation. We overexpressed a perilipin A construct in NIH-C/EBPalpha cells where the six serine residues known to be phosphorylated by protein kinase A were changed to alanine (Peri A Delta1-6). These cells show no increase in ADRP expression in response to isoproterenol. We propose that ADRP can replace perilipin on existing lipid droplets or those newly formed as a result of fatty acid reesterification, under dynamic conditions of hormonally stimulated lipolysis, thus preserving lipid droplet morphology/structure.     

Regulation of hormone stimulation of adipose tissue lipolysis by guanosine triphosphate

Guanosine triphosphate (GTP) enhanced the rate of mobilization of free fatty acids from isolated rat epididymal fat cells and potentiated the lipolytic response to norepinephrine, adrenocorticotropic hormone, glucagon, and theophylline. ITP, CTP, UTP, and TTP also increased basal and norepinephrine-stimulated lipolysis but to a lesser extent than GTP. ATP differed from the other nucleotides by inhibiting norepinephrine-stimulated lipolysis. The degree of phosphorylation of the guanine was important for activity since GTP was more active than GDP which, in turn, was more active than GMP in potentiating hormone-sensitized free fatty acid mobilization. Cyclic 3′, 5′-GMP, guanine, and guanosine were inactive in this regard. Activation of lipolysis by GTP occurred immediately upon addition of the nucleotide. The lipolytic response to GTP alone or in combination with norepinephrine or theophylline was exquisitely sensitive to inhibition by prostaglandin E₂. Nicotinic acid also inhibited the GTP response but to a lesser extent than prostaglandin E₂ and the β-blocker, propranolol, had no effect. Lipolytic concentrations of GTP in combination with norepinephrine increased intracellular levels of cAMP. By some as yet unknown mechanism GTP and GDP sensitized the adenylate cyclase of adipocytes to the actions of both agonists and antagonists.     

Activation of the lipid droplet controls the rate of lipolysis of triglycerides in the insect fat body

The hydrolysis of triglyceride (TG) stored in the lipid droplets of the insect fat body is under hormonal regulation by the adipokinetic hormone (AKH), which triggers a rapid activation cAMP-dependent kinase cascade (protein kinase A (PKA)). The role of phosphorylation on two components of the lipolytic process, the TG-lipase and the lipid droplet, was investigated in fat body adipocytes. The activity of purified TG-lipase determined using in vivo TG-radiolabeled lipid droplets was unaffected by the phosphorylation of the lipase. However, the activity of purified lipase was 2.4-fold higher against lipid droplets isolated from hormone-stimulated fat bodies than against lipid droplets isolated from unstimulated tissue. In vivo stimulation of lipolysis promotes a rapid phosphorylation of a lipid droplet protein with an apparent mass of 42-44 kDa. This protein was identified as "Lipid Storage Droplet Protein 1" (Lsdp1). In vivo phosphorylation of this protein reached a peak approximately 10 min after the injection of AKH. Supporting a role of Lsdp1 in lipolysis, maximum TG-lipase activity was also observed with lipid droplets isolated 10 min after hormonal stimulation. The activation of lipolysis was reconstituted in vitro using purified insect PKA and TG-lipase and lipid droplets. In vitro phosphorylation of lipid droplets catalyzed by PKA enhanced the phosphorylation of Lsdp1 and the lipolytic rate of the lipase, demonstrating a prominent role PKA and protein phosphorylation on the activation of the lipid droplets. AKH-induced changes in the properties of the substrate do not promote a tight association of the lipase with the lipid droplets. It is concluded that the lipolysis in fat body adipocytes is controlled by the activation of the lipid droplet. This activation is achieved by PKA-mediated phosphorylation of the lipid droplet. Lsdp1 is the main target of PKA, suggesting that this protein is a major player in the activation of lipolysis in insects.