Calcitonin increases fatty acid synthetase activity dependently of calcium-calmodulin in the hepatic cytosol of fed rats

The effect of calcitonin (CT) on fatty acid synthetase activity in the hepatic cytosol was investigated after a single subcutaneous administration of the hormone to fed rats. Administration of CT (synthetic [Asu1,7] eel CT; 80 MRC mU/100 g body weight) produced significant increases in fatty acid synthetase activity and calcium concentration in the hepatic cytosol of intact and thyroparathyroidectomized rats. The hormonal effect on the enzyme activity was not observed in rats fasted for 24 h. The increase in fatty acid synthetase activity by CT administration was completely inhibited by treatment with 10 microM EGTA. This enzyme activity was restored by addition of calcium ion (2.5-10 microM). The increased enzyme activity of CT-treated rats was markedly reduced by addition of W-7 (15 microM), a calmodulin inhibitor, in the enzyme assay system. Moreover, the cytosolic enzyme activity of normal rat liver was markedly raised by in vitro addition of both calcium ion (5 microM) and calmodulin (2.5 micrograms). These results suggest that CT increases fatty acid synthetase activity in the hepatic cytosol of fed rats, and that this hormonal regulation may depend on calmodulin, and be mediated through raised calcium in the cytosol.     

Hormonal regulation of fatty acid synthetase, acetyl-CoA carboxylase and fatty acid synthesis in mammalian adipose tissue and liver.

The major objectives of this study were to define the roles of adrenal glucocorticoids and glucagon in the long-term regulation of fatty acid synthetase and acetyl-CoA carboxylase of mammalian adipose tissue and liver. Particular emphasis was given to elucidation of the mechanisms whereby these hormones produce their regulatory effects on enzymatic activity. To dissociate mental manipulation, nutritional conditions were ridgidly controlled in the experiments described. Administration of glucocorticoids to adult rats led to a marked reductionin activities of fatty acid synthetase and carboxylase in adipose in adipose tissue but no change occurred in liver. Adrenalectomy produced an increase in activities of these lipogenic enzymes in adipose tissure, but, again, no change was noted in liver. The decrease in enzymatic activities in adipose tissue with glucocorticoid administration correlated well with a decrease in fatty acid synthesis, determined in vivo by the 3-H2O method. The mechanisms whereby glucocorticoids led to a decrease in fatty acid synthetase activity were elucidated by the use of immunochemical techniques. Thus, the decrease in fatty acid synthetase activity observed in adipose tissue was shown to reflect a decrease in content of enzyme, and not a change in catalytic efficiency. The mechanism underlying the decrease in enzyme content is a decrease in synthesis of the enzyme. The relation of the effects of glucocorticoids to the effects of certain other hormones involved in regulation of lipogenesis was investigated in hypophysectomized and in diabetic animals. Thus, the observation that the glucocorticoid effect on synthetase and carboxylase occurred in adipose tissue of hypophysectomized rats indicated that alterations in levels of other pituitary-regulated hormones were not necessary for the effect. That glucocorticoids play some role in regulation of synthetase and carboxylase in liver, at lease in the diabetic state, was shown by the observation that the low activities of these enzymes in diabetic animals could be restored to normal by adrenalectomy. An even more pronounced restorative effect was apparent in adipose tissue of adrenalectomized, diabetic animals. Administration of glucagon during the refeeding of starved rats resulted in a marked reduction in the induction of fatty acid synthetase, acetyl-CoA carboxylase and in the rate of incorporation of 3-H from 3-H2O into fatty acids in liver, but no change in these parameters occurred in adipose tissue. Administration of theophylline resulted in intermediate reduction in liver. The mechanisms whereby glucagon led tto a decrease in fatty acid synthetase activity were elucidated by the use of immunochemical techniques. Thus, the changes in fatty acid synthetase activity were shown to reflect reductions in content of enzyme. The mechanism underlying these reductions in content is reduced synthesis of enzyme.     

Studies on the mechanism of the effects of experimental inflammation on adaptive synthesis of rat liver fatty acid synthetase

The mechanism of suppression, by experimental inflammation of the usual increase in hepatic fatty acid synthetase activity resulting from fat-free feeding following starvation (adaptive synthesis), was investigated immunochemically. That suppression results from changes in amount of hepatic fatty acid synthetase was shown by the observation that fatty acid synthetase preparations from inflamed and uninflamed animals, exhibiting a wide variety of specific enzyme activities, had identical immunochemical equivalence points. In confirmation of this, the amounts of fatty acid synthetase, determined by radial immunodiffusion in gels containing anti-fatty acid synthetase serum, varied concomitantly with changes in enzyme activity regardless of the relative times of inflammation and onset of adaptive synthesis. Serum insulin levels were not dramatically elevated during the first 48 h of fat-free feeding, but rose markedly thereafter. Inflammation, either alone or combined with fat-free feeding, resulted in increased serum glucose levels, followed by a similar pattern of increased serum insulin levels some 12 h later. Fat-free feeding did not affect serum cortisol levels, but depressed liver cyclic AMP. Inflammation invariably resulted in a marked increase in serum cortisol within 12 h and a concomitant elevation of hepatic cyclic AMP, indicating possible roles for cortisol and cyclic AMP in suppression of hepatic fatty acid synthetase synthesis.     

Hypothyroidism down-regulates mitochondrial citrate carrier activity and expression in rat liver

The effect of hypothyroidism on citrate carrier (CiC) activity has been investigated in rat-liver mitochondria. The rate of citrate transport was reduced by approximately 50% in mitochondria from hypothyroid as compared with euthyroid rats. In parallel, a decrease in the rate of de novo fatty acid synthesis was observed in the cytosol of the former animals. Kinetic analysis of citrate transport revealed that only the Vmax was reduced by hypothyroidism, while Km was almost unaffected. Hypothyroidism increased the mitochondrial percentage of phosphatidylcholine while decreased that of phosphatidylethanolamine; an altered fatty acid pattern but no significant difference in the sum of saturated and unsaturated fatty acids as well as in the unsaturation index was observed. The CiC Arrhenius plot did not show appreciable difference between the two groups of rats. However, Western blot analysis associated with mRNA quantitation indicated that both protein level and mRNA accumulation of hepatic CiC were noticeably decreased in hypothyroid state. Therefore, a reduced content of the carrier protein can represent a plausible mechanism to explain the decline in the CiC activity observed in rat liver mitochondria of hypothyroid rats.     

Mechanisms by which tumor necrosis factor stimulates hepatic fatty acid synthesis in vivo

We have previously shown that bolus intravenous administration of tumor necrosis factor (TNF) to normal rats results in a rapid (within 90 min) stimulation of hepatic fatty acid synthesis, which is sustained for 17 hr. We now demonstrate that TNF stimulates fatty acid synthesis by several mechanisms. Fatty acid synthetase and acetyl-CoA carboxylase (measured after maximal stimulation by citrate) were not higher in livers from animals that had been treated with TNF 90 min before study compared to controls. In contrast, 16 hr after treatment with TNF, fatty acid synthetase was slightly elevated (35%) while acetyl-CoA carboxylase was increased by 58%. To explain the early rise in the hepatic synthesis of fatty acids, we examined the regulation of acetyl-CoA carboxylase. The acute increase in fatty acid synthesis was not due to activation of acetyl-CoA carboxylase by change in its phosphorylation state (as calculated by the ratio of activity in the absence and presence of 2 mM citrate). However, hepatic levels of citrate, an allosteric activator of acetyl-CoA carboxylase, were significantly elevated (51%) within 90 min of TNF treatment. TNF also induces an acute increase (within 90 min) in the plasma levels of free fatty acids. However, hepatic levels of fatty acyl-CoA, which can inhibit acetyl-CoA carboxylase, did not rise 90 min following TNF treatment and were 35% lower than in control livers by 16 hr after TNF. These data suggest that TNF acutely regulates hepatic fatty acid synthesis in vivo by raising hepatic levels of citrate.(ABSTRACT TRUNCATED AT 250 WORDS)     

DIFFERENCES IN THE REGULATION OF TYROSINE AMINOTRANSFERASE IN BRAIN AND LIVER

Abstract— l -Tyrosine:2-oxoglutarate aminotransferase (EC 2.6.1.5) activity in rat brain is not regulated in the same way as in rat liver. No diurnal rhythm in the activity of the cerebral enzyme was found in rats fed ad lib. although there was a marked diurnal variation in the activity of the hepatic enzyme. In adrenalectomized rats, hydrocortisone and glucagon induced the enzyme in liver but had no effect on the enzyme in brain. In normal rats, treatment with reserpine or exposure to cold elevated the activity of the hepatic enzyme without affecting the enzyme in brain. Thus, the tyrosine aminotransferase of brain differed from the enzyme in liver since it did not exhibit diurnal variations of activity and was not affected by hormones, drugs, or stress.     

Lipogenic enzymes in rat maternal adipose tissue in the perinatal period.

1. The specific activities of fatty acid synthetase, acetyl-CoA carboxylase and pyruvate dehydrogenase were measured in rat adipose-tissue extracts in pregnancy and lactation. Fatty acid synthetase specific activity correlates very closely with the rate of fatty acid synthesis, the enzyme specific activity decreasing after mid-pregnancy in a manner very similar to the rate of fatty acid synthesis. Acetyl-CoA carboxylase specific activity also decreases dramatically after mid-pregnancy. Initial pyruvate dehydrogenase specific activity shows a decrease between 2 days pre partum and 2 days post partum, but total enzyme activity shows no significant change in the same period. 2. Immunotitrations of fatty acid synthetase and pyruvate dehydrogenase activities were carried out; the titrations showed that the change in the fatty acid synthetase activity is due to a change in the enzyme amount; the amount of pyruvate dyhydrogenase does not change. Therefore the decrease in fatty acid biosynthesis in subcutaneous and parametrial adipose tissue in late pregnancy and early lactation is associated with a decrease in the amount of at least one of the enzymes involved in fatty acid biosynthesis. The correlation of these events with known hormonal changes is discussed.     

Mechanism of fatty acid synthesis

Significant advances have been made in the past few years in our understanding of the mechanism of synthesis of fatty acids, the structural organization of fatty acid synthetase complexes and the mechanism of regulation of activity of these enzyme systems. Numerous fatty acid synthetase complexes have been purified to homogeneity and the mechanism of synthesis of fatty acids by these enzyme systems has been ascertained from tracer, and recently, kinetic studies. The results obtained by these methods are in complete agreement. Furthermore, the kinetic results have indicated that fatty acid synthesis proceeds by a seven-site ping-pong mechanism. Several of the fatty acid synthetases have been dissociated completely to nonidentical half-molecular weight subunit species and these have been separated by affinity chromatography. From one of these subunits acyl carrier protein has been obtained. Whether the nonidentical subunits can be dissociated into individual proteins or whether these subunits are each comprised of one peptide is still a matter of controversy. However, it appears to us that each of the half-molecular weight subunits is indeed comprised of individual proteins. Studies on the regulation of activity of fatty acid synthetase complexes of avian and mammalian liver have resulted in the separation by affinity chromatography of three species (apo, holo-$\text{a}$ and holo-$\text{b}$) of fatty acid synthetase. Since these species have radically different enzyme activities they may provide a mechanism of short-term regulation of fatty acid synthetase activity. Other studies have shown that the quantity of avian and mammalian liver fatty acid synthetases is controlled by a change in the rate of synthesis of this enzyme complex. This change in the rate of synthesis of enzyme complex is under the control of insulin and glucagon. The former hormone increases the rate of enzyme synthesis, whereas the latter decreases it. Further studies on fatty acid synthetase complexes will undoubtedly concentrate upon more refined aspects of the structural organization of these enzyme systems, including the sequencing of acyl carrier proteins, the effects of protein-protein interaction on the kinetics of the partial reactions of fatty acid synthesis catalyzed by separated enzymes of the complex, the mechanism of hormonal regulation of fatty acid synthetase activity and x-ray diffraction analysis of subunits and complex.     

Effect of prolonged ethanol ingestion on hepatic lipogenesis and related enzyme activities

1. Hepatic lipogenesis in vivo and the activities of enzymes associated with fatty acid synthesis in the liver were studied in rats fed for 21 days on liquid diets containing ethanol. 2. The ethanol-fed rats developed a moderate hepatic triacylglycerol accumulation during this period. When carbohydrate was replaced by ethanol in the diet, the rate of fatty acid synthesis was slower in the ethanol-fed rats on low-, medium- and high-fat diets than in the appropriate controls. However, when the fat/carbohydrate ratio was kept the same in the ethanol-fed and control rats, ethanol had no influence on the rate of fatty acid synthesis. 3. Glucose 6-phosphate dehydrogenase activity was lower in the ethanol-fed group. ;Malic' enzyme activity did not change during the ethanol treatment when the fat/carbohydrate ratio was kept unchanged. 4. The ATP citrate lyase activity was lower in the ethanol-fed rats on all diets, whereas acetyl-CoA synthetase activity was independent of the composition of the control diet, but was lower in the ethanol-fed rats, in which the concentration of the active form of pyruvate dehydrogenase was also lower. 5. It is concluded that hepatic fatty acid synthesis does not play any major role in ethanol-induced triacylglycerol accumulation. Careful design of the diets is necessary to reveal the specific effects of ethanol on the enzymes associated with lipogenesis.     

Influence of thyroid hormone deficiency on the citrate synthase activity in rat brain regions during early postnatal development

The developmental pattern of citrate synthase activity has been studied in the liver and several brain areas of hypothyroid rats during the 4 first weeks of life. While citrate synthase activity in the liver showed a rise during the 2 first weeks of life, different patterns of enzyme activity were found in the brain regions of euthyroid animals. Citrate synthase activity increased in the cerebellum, decreased in the cerebral cortex and did not change significantly in the brain stem during the period studied. In the liver and brain areas, too, a decrease in citrate synthase activity was observed during hypothyroidism. From the 2nd week of birth, the citrate synthase activity in the brain but not in the liver was found to have recovered. The newly elevated citrate synthase activity coincided with a slight increase in thyroid hormone serum levels.     

Mercury inhibition of avian fatty acid synthetase complex.

(1) Subcutaneous or intra-abdominal injections of 8 mg of HgCl2/100 g body weight markedly depressed hepatic fatty acid synthetase activity of chicks at 1 h post-injection. The depression occurred despite the fact that the chicks continued to eat up until the time they were killed. Under these same conditions, the hepatic activity of acetyl-CoA carboxylase (EC 6.4.1.2) was not affected by HgCl2, while the activity of the mitochondrial system of fatty acid elongation was stimulated. (2) When 2-mercaptoethanol was included in the incubation medium for a highly purified preparation of fatty acid synthetase, 500 muM HgCl2 was required to show definite inhibition of the enzyme. When 2-mercaptoethanol was omitted, 50 muM HgCl2 was inhibitory and 100 muM HgCl2 abolished enzyme activity. (3) 2 mM dithiothreitol completely protected the purified fatty acid synthetase preparation from inhibition by 100 muM HgCl2. When dithiothreitol was added after the addition of enzyme to the mercury-containing medium, protection of the enzyme was not complete. (4) Dialysis of cytosol fractions from chicks injected with HgCl2 against 500 vol. of 0.2 M potassium phosphate buffer (pH 7.0) containing 1 mM EDTA and 10 mM dithiothreitol for 4 h at 4 degrees stimulated the fatty acid synthetase activity of the fractions. Dialysis of cytosol fractions from noninjected chicks under the same conditions was without effect on fatty acid synthetase activity. (5) These data support the hypothesis that the inhibitory effect of HgCl2 administered in vivo on hepatic fatty acid synthetase activity in chicks is mediated through the interaction of mercury with the sulfhydryl groups of the enzyme.     

Coordinate control of rat liver lipogenic enzymes by insulin

Recent evidence has established that insulin is required for the dietary induction of rat liver fatty acid synthetase [Proc. Nat. Acad. Sci. USA69, 3516 (1972)]. Since other hepatic lipogenic enzymes as well as fatty acid synthetase exhibit coordinate adaptation to nutritional changes [Advan. Enzyme Regul.10, 187(1972)], the role of insulin in the dietary induction of these enzymes has been investigated. When a high-carbohydrate, fat-free diet was fed to diabetic rats previously fasted for 48 hr, insulin was shown to be required for the dietary induction of acetyl-CoA carboxylase, citrate cleavage enzyme, malic enzyme, glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, fatty acid synthetase, and glucokinase. Activity of serine dehydrase, selected as a model gluconeogenic enzyme, was increased in diabetic rats, whereas insulin treatment reduced the activity of this enzyme during the course of refeeding. The behavior of serine dehydrase was consistent with its gluconeogenic role. The activity of the cytosol isocitrate dehydrogenase did not change during refeeding in the diabetic or insulin-treated diabetic rat. Glucagon, the physiological antagonist of insulin, inhibited the increase in activity of each of the lipogenic enzymes requiring insulin for induction. Our results indicate that insulin is required for the coordinate regulation of the lipogenic enzymes of mammalian liver.     

Regulation of hepatic fatty acid synthetase in the obese-hyperglycemic mutant mouse.

Regulation of fatty acid synthetase has been studied in the obese-hyperglycemic mouse and compared with regulation in non obese, littermate control animals. The mechanisms underlying the regulatory changes were defined by immunochemical techniques. Several major conclusions are justified from the data obtained: (1) Although the hepatic specific activity of fatty acid synthetase is higher in obese than in non obese animals pair-fed chow, no difference in hepatic activities is apparent in animals pair-fed the fat-free diet; (2) The higher enzymatic activity in obese animals fed chow is related to a higher content of enzyme, and this higher content is associated with a higher rate of enzyme synthesis; (3) The decrease in hepatic synthetase activity with starvation is distinctly more striking in non obese than in obese animals, and the changes in activity reflect changes in content of enzyme; (4) With starvation there is a decrease in synthesis of enzyme in obese and non obese animals, but only in non obese animals is there also a marked increase in the rate of synthetase degradation (t1/2 = 24 h during starvation, t1/2 = 76 h during normalfeeding); (5) Refeeding starved mice a fat-free diet results in a more striking increase in hepatic synthetase activity in non obese than in obese animals; (6) Administration of triiodothyronine causes a more marked increase in hepatic synthetase activity in non obese than in obese animals. The data thus define a variety of differences in regulation of hepatic fatty acid synthetase in mutant and normal animals. The roles of enzyme synthesis and degradation in the etiology of these differences are defined, and possible mechanisms underlying regulation of synthetase synthesis and degradation in normal mammalian liver are suggested by the observations.     

Effects of gamma-linolenic acid supplementation on lipogenesis regulation in pregnant zinc-deficient rat and fetus

In the liver of zinc-deficient pregnant rats fatty acid synthetase and delta 9-desaturase activities decreased and diet supplementation with gamma-linolenic acid potentiated this effect. However, in liver microsomes from the foetuses of zinc-deficient mothers, HMG CoA reductase and delta 9-desaturase activities declined but fatty acid activity rose. The same applied to foetuses from mothers whose diet was supplemented with gamma-linolenic acid and here again, the effect of zinc deficiency was potentiated. The fact that delta 9 activity dropped whereas fatty acid synthetase activity rose implied a defect in the mechanism regulating the functioning of these enzymes. In the non zinc-deficient group of pregnant females, gamma-linolenic acid supplementation had no effect on fatty acid synthetase and delta 9-desaturase activities but significantly increased HMG CoA reductase activity. In foetuses from the same group, the activities of MHG CoA reductase, delta 9-desaturase and fatty acid synthetase all increased.     

Avian fatty acid synthetase: Evidence for short-term regulation of activity

Liver biopsies were performed on starved chicks at 0 and 4 h after refeeding a fat-free diet. Fatty acid synthetase activity increased after refeeding, and administration of cycloheximide did not prevent the rise of enzyme activity. Incorporation of [carboxyl-¹⁴C]leucine into fatty acid synthetase was measured in enzyme purified from the livers of starved chicks, starved-refed (4 h) chicks, and starved-refed chicks injected with cycloheximide. The data suggest that the synthesis of enzyme protein was inhibited in starved and cycloheximide-treated refed chicks in comparison with refed chicks. Liver cytosol from fed or starved chicks was filtered through centrifuge ultrafiltration membranes and the residues were suspended in the same or opposite filtrates. Fatty acid synthetase activity in residues from starved chicks was stimulated when suspended in filtrates from fed chicks. The evidence is consistent with the hypothesis that a portion of the fatty acid synthetase in the liver of starved chicks is present as an inactive form which can be activated upon refeeding.     

Mammalian fatty acid synthetase. II. Modification of purified human liver complex activity.

Highly purified human-liver fatty acid synthetase complex was used to study the effect of several potential modifiers. Adenosine 3',5'-phosphate did not alter the activity of either purified synthetase or of multienzyme present in 700 times g supernates. Its dibutyryl derivative was also ineffective when incubated with liver slices. Fructose 1,6-diphosphate, fructose 6-phosphate, and glucose 6-phosphate stimulated significantly the activity of the purified enzyme. Fructose 1,6-diphosphate, which was most effective, decreased the Km of the synthetase for NADPH. Phosphoenolpyruvate, rac-glycero-3-phosphate and potassium phosphate were ineffective; All longg-chain fatty acyl-CoA thioesters tested were inhibitory, but this effect was not observed until the regions of their critical micellar concentrations were reached. Free myristate, palmitate, and stearate did not inhibit synthetase activity up to the highest concentration tested (1 mM)qn enzyme preparation derived from livers of fasted rats inactivated purified rat-liver 4'-phospho[14-C]pantetheine-fatty acid synthetase by releasing its prosthetic group. It also decreased the activity of the purified human-liver complex.     

Lipogenesis in the liver and adipose tissue of the cardiomyopathic hamster.

The activities of fatty acid synthetase, citrate cleavage enzyme, glucose-6-phosphate dehydrogenase and malic enzyme were measured in the liver and adipose tissue of cardiomyopathic and normal hamsters at age 33, 68 and 108 days. There was no difference in the activity of hepatic fatty acid synthetase between the diseased animals and the controls at any stage in their development. The activity of glucose-6-phosphate dehydrogenase was not different until age 108 days where it was significantly elevated in the BIO 82.62 strain. Citrate cleavage enzyme in the liver was depressed at all stages in the diseased animals as was malic enzyme. In adipose tissue, all enzyme activities were significantly depressed in the cardiomyopathic animals at the three stages. These data suggest that lipogenesis was depressed in the cardiomyopathic hamster.     

Control of fatty acid synthetase mRNA levels in rat liver by insulin, glucagon, and dibutyl cyclic AMP

The quantity of translatable fatty acid synthetase mRNA in liver of rats subjected to different hormonal states was determined with a rabbit reticulocyte lysate cell-free translation system. Both membrane-free polysomal and total cellular poly (A)-containing RNA were translated. The level of translatable fatty acid synthetase mRNA was 11-fold or more lower in livers of diabetic rats than in similar animals treated with insulin. In contrast, both glucagon and dibutyl cyclic AMP caused a 3-fold reduction over controls in the amount of translatable fatty acid synthetase mRNA in livers of animals refed a fat-free diet for 12 hr. These changes are consistent with the previously reported alterations in the relative rates of fatty acid synthetase synthesis measured in vivo. This suggests that the changes in the amount of fatty acid synthetase that occur in liver in response to the above hormonal changes are primarily due to changes in the amount of mRNA coding for this enzyme.     

Diurnal variations of lipogenic enzymes, their substrate and effector levels, and lipogenesis from tritiated water in rat liver

The activities of glucose-6-phosphate dehydrogenase, malic enzyme, fatty acid synthetase and acetyl-CoA carboxylase (extracted with or without phosphatase inhibitor) in rat liver did not vary significantly during 24 h. The hepatic levels of glucose 6-phosphate and malate increased coordinately 3-6 h after the beginning (1900 h) of food intake and were high until morning, whereas the levels of acetyl-CoA and citrate peaked at 1900 h and then decreased. However, it is remarkable that the in vivo incorporation of 3H from tritiated water into fatty acids in liver increased with the level of malonyl-CoA after food intake. Comparing the substrate and effector levels with the Km and Ka values for the enzymes, the levels of acetyl-CoA, malonyl-CoA and citrate appear to limit the enzyme activities. It is suggested that, after food intake, the physiological activity of acetyl-CoA carboxylase was increased with the substrate increase and/or with the catalytic activation with citrate, and consequently, the fatty acid synthetase activity was also increased, whereas the enzyme activities measured under optimum conditions were not.