Hormonal regulation of fatty acid synthetase in chick embryo liver.

Fatty acid synthetase activity in chick embryonic liver is negligible compared to that in newly hatched, fed chicks. The enzyme activity is prematurely induced 5–50-fold in 20-day-old embryos and in newly hatched chicks by the administration of insulin, hydrocortisone, growth hormone, glucagon or dibutyryl cyclic AMP. The induction of the enzyme activity is blocked by the administration of cycloheximide, indicating that new protein synthesis is required. Immunochemical titrations of different enzyme preparations from 5-day-old chicks, adult chicken and various inducer-treated embryos gave an identical equivalence point, indicating that the changes in synthetase activity after hormonal induction in embryos are related entirely to changes in content of enzyme. The increase in liver synthetase content after administration of insulin, glucagon or dibutyryl cyclic AMP is directly related to an increase in the rate of synthetase synthesis. The induction of the synthetase activity by suboptimal doses of glucagon or cyclic AMP is potentiated by the phosphodiesterase inhibitory theophylline. There is a very rapid decay of synthetase activity, with a half-life of about 4 h after elevation to higher levels following administration of insulin, glucagon or dibutyryl cyclic AMP. Glucagon and dibutyryl cyclic AMP induction of the synthetase activity is observed early in the embryonic development, whereas insulin induction is noted 2 days before hatching. Insulin, glucagon and cyclic AMP are potentially capable of altering the levels of glycolytic intermediates which may be involved in the induction of synthetase.     

Cellular energy metabolism during fetal development. IV. Fatty acid activation, acyl transfer and fatty acid oxidation during development of the chick and rat

We have investigated developmental profiles of ATP-dependent palmityl-CoA synthetase, acetyl-CoA synthetase, palmitylcarnitine transferase, and fatty acid oxidation in heart and liver of developing chicks and rats. Palmityl-CoA synthetase activity of rat liver and heart homogenates increased 6- to 10-fold during the first postnatal week. Chick embryo heart activity peaked between 13 and 16 days of development. The activity of embryonic chick livers was bimodal with highest activity seen at 7 and 16 days of development. Posthatching values were approximately 50–75% of the peak embryonic levels. Acetyl-CoA synthetase activity of rat liver and heart homogenates was low but also showed developmental increases following birth. Acetyl-CoA synthetase activity of chick embryonic hearts was greatest at 16 days of development. Palmitylcarnitine transferase activity of rat liver and heart homogenates showed a striking increase during the first week of life. Chick heart activity was similar to that observed for palmityl-CoA synthetase with a peak between 13 and 16 days of embryonic development. Coincident with the postnatal rise in fatty acid activation and palmitylcarnitine transferase activity in developing rats, the oxidation of palmityl-CoA plus carnitine and of palmitylcarnitine increased from barely measurable levels at birth to adult levels by 30 days of age. The increases that we observe probably relate to changes in the specific activity of the enzymes as well as to an increase in the absolute number of mitochondria during development.     

Tissue-Specific antioxidant profiles and susceptibility to lipid peroxidation of the newly hatched chick

The hatching process is characterized by a range of adaptive changes, and a newly hatched chick is considered as an intermediate stage between prenatal and postnatal development. The aim of the present study was to evaluate the characteristic relationships between tissue-specific fatty acid composition and antioxidant protection in newly hatched chicks. Liver, yolk sac membrane, heart, kidney, lung, and four brain regions (cerebrum, cerebellum, stem, and optic lobes) were collected. Fatty acid composition of total lipids and phosphoglycerides, α-tocopherol, lutein, ascorbic acid, reduced glutathione, and the activities of Mn-and Cu,Zn-superoxide dismutase (SOD) and Se-dependent and non-Se-glutathione peroxidase (GSH-Px), and catalase (CAT) were determined. The levels of Fe, Cu, Zn, and Mn as well as tissue susceptibility to lipid peroxidation were also studied. The tissues of the newly hatched chick showed distinctive features in fatty acid profiles, antioxidant accumulation, and susceptibility to lipid peroxidation. The brain clearly displayed the greatest susceptibility to spontaneous and Fe-stimulated lipid peroxidation, was highly unsaturated and contained very low levels of vitamin E, no detectable carotenoids, low GSH-Px, and low CAT activity. At the same time, the brain was characterized by high ascorbic acid concentration and comparatively high SOD activity. It was suggested that in postnatal development, antioxidant enzymes presumably play the major role in antioxidant protection of the chick tissues.     

Metabolism of cholesterol in the tissues and blood of the chick embryo

Three artificially inseminated laying White Leghorn hens were given 35-50 micro c of cholesterol-4-(14)C intravenously. Their subsequently produced eggs contained cholesterol-(14)C-labeled yolks. Some of the fertilized eggs were analyzed for cholesterol content and radioactivity. Other eggs were incubated until hatching. The specific activity of the cholesterol contained in the serum and tissues of newly hatched chicks was determined and compared with that of yolk sac, which was taken as representative of egg yolk cholesterol before its metabolic transfer into the chick embryo. The specific activities of cholesterol in intestine, liver, serum, heart, and skeletal muscle and the whole chick were 95-98% of that in yolk sac, but that of brain cholesterol was only 11% of this value. These results indicate that whereas most of the cholesterol in the chick originated from the egg yolk, cholesterol biosynthesis was active in the brain and provided about 90% of its cholestero content. Newly hatched chicks were found to be hyperlipemic compared with older chicks and had fatty livers with a high cholesterol content. Desmosterol was found in 9- and 15-day old chick embryos but not in the newly hatched chicks, in which the only sterol was cholesterol.     

The coenzyme A requirement of mammalian fatty acid synthetase: evidence for involvement in the elongation of acyl-enzyme thioesters

We have confirmed that coenzyme A is required for rat fatty acid synthetase activity (T. C. Linn, M. J. Stark, and P. A. Srere, 1980, J. Biol. Chem.255, 1388–1392). When rat liver or mammary gland fatty acid synthetase was assayed in the presence of a CoA-scavenging system such as ATP citrate lyase, almost complete inhibition of fatty acid synthesis was observed. The inhibition was reversed by addition of CoA or pantetheine, but not by addition of N-acetylcysteamine or other thiols. In the absence of CoA, the rate of elongation of acyl moieties on both native fatty acid synthetase and fatty acid synthetase lacking the chain-terminating thioesterase I component (trypsinized fatty acid synthetase) was reduced 100-fold. All of the palmitate synthesized slowly by the CoA-depleted native multienzyme was released, by the thioesterase I component, as the free fatty acid; only shorter-chainlength acyl moieties remained bound to the enzyme. The acyl-S-multienzyme thioesters formed by the trypsinized fatty acid synthetase in the absence of CoA contained saturated moieties of chain length C₆-C₁₆; addition of CoA promoted elongation of the acyl-S-multienzyme thioesters without release from the enzyme. The transfer of acetyl and malonyl moieties from CoA to the multienzyme, the reduction of S-acetoacetyl-N-acetylcysteamine and S-crotonyl-N-acetylcysteamine, and the dehydration of S-β-hydroxybutyryl-N-acetylcysteamine, reactions catalyzed by the fatty acid synthetase, were not dependent on the presence of CoA. The hydrolysis of acyl-S-multienzyme catalyzed by thioesterase I, the resident chain-terminating component of the fatty acid synthetase, and thioesterase II, a monofunctional mammary gland chain-terminating enzyme, was also independent of CoA availability as was hydrolysis of an acyl-S-pantetheine pentapeptide isolated from the multienzyme. On the basis of these observations we conclude that CoA is required for the elongation of acyl moieties on the fatty acid synthetase but not for their release from the multienzyme.     

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.     

Induction of microsomal stearyl coenzyme A desaturase in the newly hatched chicks.

The development of the stearyl-CoA desaturase system was studied in newly hatched chicks. The desaturation activity was very low in hepatic microsomes from chick embryos, less than 0.05 nmol of oleate formed min^?1 (mg of protein)^?1. After hatching and feeding, the desaturation activity gradually increased to 4–5 nmol of oleate formed min^?1 (mg of protein)^?1 in 6-day-old chicks. This increase could be prevented by administration of cycloheximide or actinomycin D. Measurement of the microsomal electron transfer components throughout the induction period showed no significant changes in the NADH- or NADPH-specific reductases or in the concentrations of cytochromes b₅ and P-450. However, the activity of the terminal component of the desaturase system (the desaturase enzyme) increased in parallel with the desaturation activity. Supplementing the liver microsomes from chick embryos with isolated desaturase enzyme resulted in the formation of an active desaturation system. It is proposed that the induction of the stearyl-CoA desaturase system during development of newly hatched chicks is dependent on the synthesis of the terminal desaturase enzyme.     

Fate of egg white trypsin inhibitor and start of proteolysis in developing chick embryo and newly hatched chick

Trypsin inhibitor and proteolytic activities were studied in incubated eggs, embryos, and newly hatched chicks. After rupture of the secondary seroamniotic suture at 11 days, the trypsin inhibitor content of the albumen gradually passes into the amniotic cavity; from there it is taken up orally by the chick embryo. It is supposed that between 11 and 18 days of embryonic development the trypsin inhibitor passes from the gut to the yolk sac through the vitellointestinal duct. The thin yolk contained only traces of trypsin inhibitor, and the allantoic fluid was entirely free from it. The amylase activity demonstrable in the liquid intestinal contents of the chick embryo indicates the presence of pancreatic secretion. The trypsin inhibitor probably suppresses the proteases not only directly, but also through prevention of the activation of zymogens. Enterocytes of chick embryos showed no morphological indication of the absorption of undigested proteins on histological examination. The cloacal membrane of the newly hatched chick ruptures shortly after the bird has dried up, and the trypsin inhibitor is subsequently eliminated along with the intestinal contents. The intestinal proteolytic enzymes appear immediately afterward. The proteolytic activity appeared regardless of whether the birds were or were not fed. Maximum proteolytic activity was measured in the small intestine of chicks that were fasted for 2 days after hatching. The pattern of proteolytic enzymes as well as their sensitivity to protease inhibitors did not notably differ from that of mammals.     

New experiments of biotin enzymes.

The objects of structural studies on biotin-enzymes were acetyl CoA-carboxylase and pyruvate carboxylase of Saccharomyces cerevisiae and beta-methylcrotonyl CoA-carboxylase and acetyl CoA-carboxylase of Achromobacter IV S. It was found that these enzymes can be arranged in three groups. In the first group, as represented by acetyl CoA-carboxylase of Achromobacter, the active enzyme could be resolved in three types of functional components: (1) the biotin-carboxyl carrier protein, (2) the biotin carboxylase, and (3) the carboxyl transferase. In the second group, as represented by beta-methylcrotonyl CoA-carboxylase from Achromobacter only two types of polypeptides are present. The one carries the biotin carboxylase activity together with the biotin-carboxyl-carrier protein, the other one carries the carboxyl transferase activity. In this third group, as represented by the two enzymes of yeast, all three catalytic functions are incorporated in one multifunctional polypeptide chain. The evolution of the different enzymes is discussed. The animal tissues acetyl CoA-carboxylase is under metabolic control, as known from previous studies. It thus has to be expected that the levels of malonyl CoA in livers of rats in all states of depressed fatty acid synthesis are much lower than under normal conditions because the carboxylation of acetyl CoA is strongly reduced and cannot keep pace with the consumption of malonyl CoA by fatty acid synthetase. A new highly sensitive assay method for malonyl CoA was developed which uses tritiated NADPH and measures the incorporation of radioactivity into the fatty acids formed from malonyl CoA in the presence of purified fatty acid synthetase. The application of this method to liver extracts showed that the level of malonyl CoA which amounts to about 7 nmoles per gram of wet liver drops to less than 10% within a starvation period of 24 hr and even further if the starvation period is extended to 48 hr. A low malonyl CoA concentration is also found in the alloxan diabetic animals and in animals being fed a fatty diet after starvation. On the other hand, feeding a carbohydrate rich diet leads to malonyl CoA levels surpassing the levels found after feeding a balanced diet. These observations reconfirm the concept that fatty acid synthesis is principally regulated by the carboxylation of acetyl CoA.     

Development of hepatic acetyl coenzyme A carboxylase in hormone-treated chicks.

It has been suggested that the carbohydrate-rich diet of chicks after hatching is responsible for the emergence of hepatic enzymes involved in lipogenesis; the injection of glucose to newly hatched chicks gives rise to an appreciable elvation on the activities of acetyl coenzyme A carboxylase and fatty acid synthetase. The present study shows that during the first hours after hatching, there is a natural elevation of glycemia which parallels the increase in acetyl coenzyme A carboxylase activity. However, the administration of hormones which alter the blood glucose levels considerably (insulin, tolbutamide, glucagon and hydrocortisone) did not influence the enzyme activity. The administration of thyroxine, estradiol and cyclic AMP, was also without effect. These results do not support the theory that the increased amount of blood glucose is the natural effector of the induction acetyl coenzyme A carboxylase. They also show that different lipogenic enzymes are not regulated via the same 'operon' since thyroxine or glucagon which alter the level of some enzymes on this pathway did not modify that of the acetyl coenzyme A carboxylase.     

Purification and characterization of fatty acid synthetase from Cryptococcus neoformans

Fatty acid synthetase has been purified from Cryptococcus neoformans 450 fold to a specific activity of 3.6 units per mg protein with an overall yield of 23%. The purified enzyme contained two non-identical subunits, Mr approximately 2.1×10⁵ and 1.8×10⁵. Under optimum conditions, 100 mM KCl and pH 7.5, apparent Km values for the substrates were: Acetyl CoA, 19 M; Malonyl CoA, 5 M; and NADPH, 6 M. Product inhibition patterns were determined to be: CoA, competitive versus acetyl CoA and malonyl CoA, uncompetitive versus NADPH; NADP, competitive versus NADPH, uncompetitive versus acetyl CoA and malonyl CoA; Palmitoyl CoA, competitive versus malonyl CoA, noncompetitive versus acetyl CoA and NADPH; Bicarbonate, uncompetitive versus malonyl CoA. These product inhibition patterns are consistent with the multisite ping-pong mechanism previously proposed for the avian fatty acid synthetase complex. The cryptococcal fatty acid synthetase was inhibited by the polyanionic polymers, heparin and dextran sulfate, an effect never before demonstrated for a fatty acid synthetase. This inhibition exhibited a marked dependence on the length of the polymer chain, with dextran sulfate fractions with Mr of 6×10⁵ and above having K _i values below 100 nanomolar. A model is presented that involves initial binding of the anionic polymer to the enzyme complex at a region of high positive charge density, followed by interaction of the end of the tethered polymer with the catalytic site. This study represents the first purification of fatty acid synthetase from a basidiomycete.     

Effect of acetaldehyde on fatty acid oxidation and ketogenesis by hepatic mitochondria.

Acetaldehyde inhibited the oxidation of fatty acids by rat liver mitochondria as assayed by oxygen consumption and CO₂ production. ADP-stimulated oxygen uptake was more sensitive to inhibition by acetaldehyde than was uncoupler-stimulated oxygen uptake, suggesting an effect of acetaldehyde on the electron transport-phosphorylation system. This conclusion is supported by the decrease in the respiratory control ratio, associated with fatty acid oxidation. Acetaldehyde depressed ketone body production as well as the content of acetyl CoA during palmitoyl-1-carnitine oxidation. Acetaldehyde was considerably more inhibitory toward fatty acid oxidation than was acetate. Therefore, the inhibition by acetaldehyde is not mediated by acetate, the direct product of acetaldehyde oxidation by the mitochondria. Oxygen uptake was depressed by acetaldehyde to a slightly, but consistently, greater extent in the absence of fluorocitrate, than in its presence. This suggests inhibition of oxygen consumption from β-oxidation to acetyl CoA and that which arises from citric acid cycle activity. The inhibition of fatty acid oxidation is not due to any effect on the activation or translocation of fatty acids into the mitochondria.The depression of the end products of fatty acid oxidation (CO₂, ketones, acetyl CoA) as well as the greater sensitivity of palmitate oxidation compared to acetate oxidation, suggests inhibition by acetaldehyde of β-oxidation, citric acid cycle activity, and the respiratory-phosphorylation chain. Neither the activities of palmitoyl CoA synthetase nor carnitine palmitoyltransferase appear to be rate limiting for fatty acid oxidation.     

Developmental increase in the inotropic and cyclic AMP response to isoproterenol in embryonic and newly hatched chicks

The cyclic adenosine 3',5'-monophosphate (cyclic AMP) levels of ventricles isolated from 15- to 20-day-old chick embryos and 0- to 3-day-old hatched chicks were compared to clarify the mechanism underlying the change in sensitivity to isoproterenol during perinatal developmental stages when the functional sympathetic innervation has been completely achieved. Isoproterenol produced a positive inotropic effect on ventricles isolated from both embryonic and hatched chicks, but the ventricles from the hatched chicks were more sensitive. At both developmental stages sotalol was an equipotent antagonist of isoproterenol. 3-Isobutyl-1-methylxanthine (IBMX) produced an increment in the contractile force of the ventricles at both stages, but the ventricles from the hatched chicks responded to lower doses of IBMX. The reactivity to isoproterenol in increasing cyclic AMP level was significantly higher in the hatched ventricles than in the embryonic ventricles. The results suggest that the different sensitivities to isoproterenol between embryonic and newly hatched chick ventricles may be due to some changes in the process for cyclic AMP production.     

Acid soluble, short chain esterified and free carnitine in the liver, heart, muscle and brain of pre and post hatched chicks

1. The behaviour of total acid soluble, short chain esterified and free carnitine in the liver, heart, muscle and brain of chick embryos between 11th and 21st day of development and of 8 and 180-day-old chicks is described. 2. Total acid soluble carnitine fluctuates around the same levels in the brain, liver and muscle until 18th day of development, whereas it attains a peak on that day in the heart. At hatching compared to 18th day, it suddenly increases three times in the muscle, drops not significantly in the heart and brain, but sharply in the liver (-40%). However the levels are always higher than those of the grown chick in the brain but lower in the other tissues. 3. Free carnitine levels are almost constant in all tissues during the embryonic life; if compared to adult ones, they are very much lower in the liver, heart and muscle, but higher in the brain, even in 8 day-old chick. 4. Short chain esterified, carnitine reaches a maximum on 18th day of egg incubation in the liver, brain and heart; in the muscle it stays on constant levels until this day and then rapidly increases so that at hatching it doubles the values. 5. The short chain esterified to free carnitine percentage ratio peaks in all tissues on 18th day of development, attaining figures which are well above those determined in the grown chick.     

Rapid modulation of the n-3 docosahexaenoic acid levels in the brain and retina of the newly hatched chick

The newly hatched chick obtains its fatty acids almost completely from the lipids of the egg yolk as these are transferred to the developing embryo during its 21-day period of incubation. Since the diet of the laying hen greatly influences the fatty acid composition of the egg lipids, and presumably also the fatty acid composition of the resulting chick, we tested how quickly and to what extent varying the amount of n-3 fatty acids in the diet of the hen would modulate the level of n-3 fatty acids in the brain and retina of the newly hatched chick. White Leghorn hens were fed commercial or semi-purified diets supplemented with 10% fish oil, linseed oil, soy oil, or safflower oil. Eggs, together with the brain, retina, and serum of newly hatched chicks, were then analyzed for fatty acid composition. The fatty acids of egg yolk responded quickly to the hen's diet with most of the change occurring by 4 weeks. There was a linear relationship between the linolenic acid content of the diets and levels of this fatty acid in egg yolk and chick serum. In chicks from hens fed the fish oil diet, the total n-3 fatty acids, including 22:6(n-3), were elevated twofold in the brain and retina and sevenfold in serum relative to commercial diet controls. The safflower oil diet led to a very low n-3 fatty acid content in egg yolks and only 25% of the control n-3 fatty acid content in the brain and retina of chicks.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of starvation and starvation followed by feeding on enzyme activity and the metabolism of [U-14C]glucose in liver from growing chicks

1. The conversion of [U-(14)C]glucose into carbon dioxide, cholesterol and fatty acids in liver slices and the activities of ;malic' enzyme, citrate-cleavage enzyme, NADP-linked isocitrate dehydrogenase and hexose monophosphate-shunt dehydrogenases in the soluble fraction of homogenates of liver were measured in chicks that were starved or starved then fed. 2. In newly hatched chicks the incorporation of [U-(14)C]glucose and the activity of ;malic' enzyme did not increase unless the birds were fed. The response to feeding of [U-(14)C]glucose incorporation into fatty acids increased as the starved chicks grew older. 3. Citrate-cleavage enzyme activity increased slowly even when the newly hatched chicks were unfed. On feeding, citrate-cleavage enzyme activity increased at a much faster rate. 4. In normally fed 20-day-old chicks starvation decreased the incorporation of [U-(14)C]glucose into all three end products and depressed the activities of ;malic' enzyme and citrate-cleavage enzyme. Re-feeding increased all of these processes to normal or higher-than-normal levels. 5. In both newly hatched and 20-day-old chicks starvation increased the activity of isocitrate dehydrogenase and feeding or re-feeding decreased it. 6. Very little change in hexose monophosphate-shunt dehydrogenase activity was observed during the dietary manipulations. 7. The results indicate that increased substrate delivery to the liver is the principal stimulus to the increased rate of glucose metabolism observed in newly hatched chicks. The results also suggest that changes in the activities of ;malic' enzyme and citrate-cleavage enzyme are secondary to an increased flow of metabolites through the glucose-to-fatty acid pathway and that the dehydrogenases of the hexose monophosphate shunt play a minor role in NADPH production for fatty acid synthesis.     

Rapid Purification of Enzymes of Fatty Acid Biosynthesis from Rat Adipose Tissue

Abstract

Acetyl CoA carboxylase, ATP-citrate lyase and fatty acid synthetase were purified to homogeneity by a simple procedure. The purification method consists of polymerization of acetyl CoA carboxylase with citrate followed by avidin-Sepharose affinity chromatography. ATP-citrate lyase and fatty acid synthetase were isolated as by-products of acetyl CoA carboxylase purification and are separated from each other by chromatography on DE-52. ATP-citrate lyase was further purified by CoA-agarose affinity chromatography and fatty acid synthetase was purified on Bio-Gel A-1.5m. Purified ATP-citrate lyase, acetyl CoA carboxylase and fatty acid synthetase had specific activities of 9.9, 2.8 and 1.8 U/mg respectively with an over all recovery of 30, 25 and 50% respectively. Using these purified enzymes, we found that ATP-citrate lyase and acetyl CoA carboxylase were phosphorylated in vitro by both cAMP-dependent protein kinase and ATP-citrate lyase kinase whereas fatty acid synthetase was not phosphorylated by these protien kinases.     

Inhibitory effect of acetazolamide on the activity of acetyl CoA carboxylase of mouse liver.

The effect of different concentrations of acetazolamide on the activities of acetyl CoA carboxylase and fatty acid synthetase was studied. Acetazolamide inhibits the activity of 100, 00 × g supernatant acetyl CoA carboxylase and that of this purified enzyme even in the presence of high concentrating of bicarbonate. It is without action on fatty acid synthetasse.     

Rapid purification of enzymes of fatty acid biosynthesis from rat adipose tissue

Acetyl CoA carboxylase, ATP-citrate lyase and fatty acid synthetase were purified to homogeneity by a simple procedure. The purification method consists of polymerization of acetyl CoA carboxylase with citrate followed by avidin-Sepharose affinity chromatography. ATP-citrate lyase and fatty acid synthetase were isolated as by-products of acetyl CoA carboxylase purification and are separated from each other by chromatography on DE-52. ATP-citrate lyase was further purified by CoA-agarose affinity chromatography and fatty acid synthetase was purified on Bio-Gel A-1.5m. Purified ATP-citrate lyase, acetyl CoA carboxylase and fatty acid synthetase had specific activities of 9.9, 2.8 and 1.8 U/mg respectively with an over all recovery of 30, 25 and 50% respectively. Using these purified enzymes, we found that ATP-citrate lyase and acetyl CoA carboxylase were phosphorylated in vitro by both cAMP-dependent protein kinase and ATP-citrate lyase kinase whereas fatty acid synthetase was not phosphorylated by these protein kinases.     

Acetate metabolism by tissues of the rabbit

Acetyl CoA synthetase (E.C.6.2.1.1) and acetyl CoA hydrolase (E.C.3.1.2.1) activities were assayed in sub-cellular fractions of rabbit liver, heart and kidney homogenates. The intracellular location of acetyl CoA hydrolase was predominantly mitochondrial in all tissues, whereas that for acetyl CoA synthetase varied between the tissues studied. The relationship between location of enzyme activity and metabolism of acetate in different tissues is discussed.