Changes in lipid synthesis in rat liver during development

Development of fatty acid-synthetic capacity in interscapular brown adipose tissue during suckling in genetically obese Zucker rats

The development of the lipogenic capacity in brown adipose tissue was studied in suckling lean (Fa/fa) and obese (fa/fa) Zucker pups aged from 7 to 22 days. In both lean and obese pups, activities of the two key lipogenic enzymes, fatty acid synthetase and acetyl-CoA carboxylase, and of citrate cleavage enzyme rose from the early to the late suckling period. Compared with lean pups, 7-day-old fa/fa pups showed a 35% increase in fat accumulation in interscapular brown adipose tissue and a 25% increase in fatty acid synthetase activity. By 10 days of age, fat deposition, lipogenesis in vivo (assessed by the incorporation of 3H from 3H2O into fatty acids) and fatty acid synthetase activity were 1.5-2-fold higher in pre-obese than in lean pups. Compared with lean pups, the increased lipogenesis in vivo observed in brown adipose tissue of 10-day-old pre-obese pups could not entirely account for the difference in fat deposition observed in this tissue, suggesting that additional mechanisms are at play to explain the increased fat content of this tissue.

Biochemistry of liver development in the perinatal period

Just before birth, changes occur in the metabolic capacities of rat liver so that the animal can adapt to changes in the substrate supply. In utero, glucose is the main energy-generating fuel and the liver metabolism is directed towards glucose degradation. The activities of the rate-limiting enzymes of glycolysis, hexokinase and phosphofructokinase, are high. In preparation for post-natal life, when the continuous glucose supply from the mother is interrupted, very large amounts of glycogen are stored in the late fetal liver. With the intake of the fat-rich and carbohydrate-poor milk diet, the animal develops the ability to synthesize glucose de novo from non-carbohydrate precursors. During suckling, metabolic energy is derived mainly from the beta-oxidation of fatty acids, which in turn is an essential prerequisite for the high rate of gluconeogenesis, by yielding acetyl-CoA for the activation of pyruvate carboxylase and by generating a high NADH/NAD ratio for the shift of the glyceraldehyde 3-phosphate dehydrogenase reaction in the direction of glucose formation.--The developmental adaptation of metabolism and the process of enzymatic differentiation are closely connected with the maturation of the endocrine system and the changes in the concentration of circulating hormones. The neonatal regulation of phosphoenolpyruvate carboxykinase and of tyrosine aminotransferase by variations in the hormonal milieu around birth, and also the interaction of hormonal and nutritional factors in the induction of serine dehydratase and glucokinase at the end of the suckling period, will be discussed in detail.

Effect of increased substrate availability on fatty acid synthesis in the growth retarded fetus

The purpose of this study was to test the hypothesis that increased substrate (glucose) availability will enhance fatty acid synthesis in the growth retarded rat fetus. At 17 days of gestation, 19 time-dated pregnant rats had one uterine artery ligated, leading to growth retardation (IUGR) in the fetuses located on the uterine horn supplied by the ligated artery. The uterine artery of the opposite uterine horn was left untouched, resulting in appropriately grown fetuses, which served as controls. At 21 days of gestation the animals were infused with either 20% dextrose or 0.9% saline via a maternal jugular vein catheter for 4 hr. Fetal organ fatty acid synthesis was measured by maternal 3H2O injection. In the growth retarded saline infused fetus, specific activity for 3H (representing rate of fatty acid synthesis) was significantly lower in fetal liver, lung and carcass. Dextrose infusion resulted in increased fatty acid synthesis in both control and IUGR fetuses in all tissues cited above. The specific activity in glucose infused IUGR fetal organs equalled that of saline infused control fetuses. The data indicate that maternal glucose infusion resulted in an increased rate of fatty acid synthesis, in IUGR fetuses; consequently, the deficit in fatty acid synthesis in the IUGR fetus (compared to appropriately grown control fetuses) was abolished.

Lipogenesis at the suckling-weaning transition in liver and brown adipose tissue of the rat

The responses of rat hepatic and brown adipose tissue in vivo lipogenesis to premature (15 days) and normal (21 days) weaning have been correlated to changes in the activities of acetyl-CoA carboxylase and two NADPH-producing enzymes, malic enzyme and glucose-6-phosphate dehydrogenase. Both tissues show an induction of lipogenesis in response to weaning. In the liver, lipogenic flux is closely linked to the activity of acetyl-CoA carboxylase, but not necessarily that of malic enzyme or glucose-6-phosphate dehydrogenase, whereas no such dissociation between enzyme activity and flux rate occurs in brown adipose tissue. Thyroid hormones, implicated in many physiological changes around weaning, do not seem to play a primary role in the adaptation of lipogenesis to the dietary change at this time, although a permissive role in both tissues is possible.

Regulation of hepatic carnitine palmitoyltransferase activity during the foetal-neonatal transition

Overt carnitine palmitoyl transferase (CPT1) activity was measured in liver mitochondria from foetal rats (21 days gestation) and from neonatal rats (1 day post-partum). Birth was accompanied by a 6-fold increase in CPT1 activity, a 14-fold decrease in sensitivity to inhibition by malonyl CoA and an increase in the nH and the S0.5 for palmitoyl CoA. The activity of latent enzyme (CPT2) was unaffected at birth.

Effect of age and cholestyramine feeding on rat liver 3-hydroxy-3-methyl glutaryl CoA reductase, sterol carrier protein 1 and sterol carrier protein 2 activities

The rate of formation of sterol from squalene in livers from suckling rats was less than one-third that of adults. This difference was due to a lesser activity of microsomal enzymes in the suckling rat livers, and not to any difference in cytosolic sterol carrier protein 1. The microsomal enzymes and sterol carrier protein 2 of the cytosol required for the conversion 7-dehydrocholesterol to cholesterol were both lower in suckling rats compared to adults. Both those activities paralleled the differences in HMG-CoA reductase activities between suckling and adult rats. Feeding of cholestryamine to adult rats increased the activities of the microsomal enzymes, sterol carrier protein 1 and sterol carrier protein 2 involved in the conversion of squalene to cholesterol.

De novo fatty acid synthesis in developing rat lung

The rate of de novo fatty acid synthesis in developing rat lung was measured by the rate of incorporation of 3H from 3H2O into fatty acids in lung slices and by the activity of acetyl-CoA carboxylase in fetal, neonatal and adult lung. Both tritium incorporation and acetyl-CoA carboxylase activity increased sharply during late gestation, peaked on the last fetal day, and declined by 50% 1 day after birth. In the adult, values were only one-half the peak fetal rates. In vitro regulation of acetyl-CoA carboxylase activity in fetal lung was similar to that described in adult non-pulmonary tissues: activation by citrate and inhibition by palmitoyl-CoA. Similarly, incubation conditions that favored enzyme phosphorylation inhibited acetyl-CoA carboxylase activity in lung while dephosphorylating conditions stimulated activity. Incorporation of [U-14 C]glucose into lung lipids during development was influenced heavily by incorporation into fatty acids, which generally paralleled the rate of tritium incorporation into fatty acids. The relative utilization of acetyl units from exogenous glucose for overall fatty acid synthesis was greater in adult lung than in fetal or neonatal lung, suggesting that other substrates may be important for fatty acid synthesis in developing lung. In fetal lung explants, de novo fatty acid synthesis was inhibited by exogenous palmitate. Taken together, these data suggest that de novo synthesis may be an important source of saturated fatty acids in fetal lung but of lesser importance in the neonatal period. Furthermore, the regulation of acetyl-CoA carboxylase activity and fatty acid synthesis in lung may be similar to non-pulmonary tissues.

Fatty acid synthesis in rat fetuses with intrauterine growth retardation

The effect of uterine artery ligation at 17 days of gestation to induce intrauterine growth retardation (IUGR) on fetal fatty acid synthesis was studied in pregnant rats. Significant impairment in fatty acid synthesis was observed in fetal liver and lung tissues. The specific activity of fatty acids at 19 days of gestation in the liver was lower in the IUGR rats, as compared to controls, 44.6 +/- 13 versus 87.9 +/- 10 cpm/mumol fatty acids (p less than .05). At 21 days of gestation, the specific activity of fatty acids was 40.6 +/- 7.8 as compared to 75.8 +/- 9.8 cpm/mumole in the IUGR and control fetuses, respectively (p less than .05). In lung, the specific activity of fatty acids was 25.7 +/- 5.4 cmp/mumole in IUGR fetuses as compared to 46.6 +/- 9 cpm/mumole in control littermates at 19 days (p less than .05). This difference persisted at 21 days since the specific activity was 32.2 +/- 2.4 in experimental fetuses as compared to 42.6 +/- 3.0 cpm/mumole in controls (p less than .05). Brain and placental tissues demonstrated no statistically significant differences in specific activity at either time in gestation. The total fatty acid content per organ for both liver and lung was also reduced in the IUGR group. Decreased substrate transfer from mother to fetus during placental insufficiency may account for decreased lipogenesis in the IUGR fetus. Brain and placental tissues are spread despite significant compromises in liver and lung capabilities for fatty acid synthesis.

Perinatal lipogenesis in the liver and brown adipose tissue of the rat

1. Hepatic lipogenesis falls during late foetal life, reaching low levels soon after birth. 2. Of the lipogenic enzymes studied only changes in foetal liver acetyl-CoA carboxylase activities correlate well with the changes in lipogenic flux. 3. In contrast to liver, brown adipose tissue lipogenesis increases during late foetal life. 4. A similar developmental pattern in foetal brown adipose tissue was observed for the activities of a number of enzymes normally associated with lipogenesis. 5. The studies suggest the existence of different controls over the development of lipogenesis in the two tissues investigated during the perinatal period.

Age-related quantitative changes in enzyme activities of rat brain

The patterns of brain enzymes linked to energy metabolism have been determined in rats aged between 3 and 21 months and compared to those of the developing brain as an estimate of the senescent energy capacity of this organ. During aging, pyruvate kinase increases, pointing towards an enhancement of the glucose-dependence of this organ. However, NAD-isocitrate dehydrogenase declines, suggesting a reduction of Krebs cycle activity in the aged rat brain. An increase in cytoplasmic NAD-malate dehydrogenase found during aging could provide an alternative mechanism of NAD recovery.

Metabolic changes in rats subjected to space flight for 18.5 days in the biosatellite Cosmos 936

From an investigation of the activity of six glucocorticoid dependent liver enzymes, the existence of chronic, transient, stress-induced hypercorticosteronaemia during flight is probable. This hypercorticosteronaemia arises from weightlessness and induces gluconeogenesis. Weightlessness also caused substantial increases in liver glycogen level. The increased lipolytic activity and that of lipoprotein lipase in several groups of animals could be interpreted as enhancement of fat mobilization and utilization under the influence of stress. As this latter enhancement was also found in ground-based controls, it may have been due to the stress of handling rather than to space flight per se.

Synthesis of fatty acids and cholesterol by liver, adipose tissue and intestinal mucosa from obese and control patients

Biopsies of adipose tissue, liver and small bowel mucosa obtained from grossly obese and control subjects were used to study absolute rates of fatty acid, cholesterol, and other nonsaponifiable lipid synthesis using glucose as substrate and 3H2O as the isotopic marker. Fatty acid synthesis in subcutaneous adipose tissue expressed on a cell basis was greater in obese than control subjects and was stimulated by a high concentration of insulin (1000 micro U/ml), but not by a lower amount (100 micro U/ml). Fatty acid synthesis in omental adipose tissue exceeded by 3-fold that of subcutaneous fat. Fatty acid synthesis in obese liver was twice that of control liver and 20 times greater than obese adipose tissue. In terms of total organ activity fatty acid synthesis in fat tissue equalled or exceeded that of liver in both obese and control subjects. The cholesterol content of obese adipose tissue 1.86 +/- 0.11 mg/g exceeded that of controls 1.47 +/- 0.07 mg/g. All tissues examined synthesized cholesterol and nonsaponifiable lipids, liver greater than adipose tissue greater than small bowel mucosa. Nonsaponifiable lipid synthesis per gram of adipose tissue or liver was similar in obese and control tissue. The synthesis of total nonsaponifiable lipids including sterols, hydrocarbons and squalene was appreciable in adipose tissue and was approximately 15% of that of liver. However, cholesterol synthesis in the liver exporessed in terms of total organ activity was 50 times that in adipose tissue. The study demonstrates by direct comparison that liver is the dominant cholesterogenic organ in man and also shows that adipose tissue is a significant site of formation of fatty acids and nonsaponifiable lipids.

Hepatic 3-hydroxy-3-methylglutaryl coenzyme A reductase activity and cholesterol 7 alpha-hydroxylase activity in neonatal guinea pig

Optimal assay conditions for hepatic HMG-CoA reducatase activity and cholesterol 7 alpha-hydroxylase activity in the guinea pig were determined. These two enzyme activities were studied in the liver of newborn guinea pigs during the first three postnatal weeks. Hepatic HMG-CoA reductase activity of neonatal guinea pigs was similar to that of adult animals. However, cholesterol 7 alpha-hydroxylase activity of newborns was about one-third of that in adult guinea pigs. This finding suggests that the system for bile acid synthesis in the neonatal guinea pigs is underdeveloped.

Lipogenetic and glycolytic enzyme activities in carcinoma and nonmalignant diseases of the human breast

Activities of some enzymes associated with carbohydrate and lipid metabolism were determined in 48 human breast carcinomas and compared with those found in 35 nonmalignant breast tumours and also in 13 normal breast tissues. In fibrocystic disease only the activity of citrate lyase was markedly higher (14-fold) than in normal tissue. The activities of the remaining enzymes did not differ significantly from those in normal tissue. Enzyme activities in breast carcinoma were 4--160 x those determined in normal tissue according to the following sequence : phosphofructokinase less than malate NADP dehydrogenase less than hexokinase less than lactate dehydrogenase less than isocitrate NADP dehydrogenase less than ATP citrate lyase. Activity of citrate lyase, very low in normal breast (0.0017 mumol/min/g of tissue) rose gradually to 0.039, 0.072 and 0.258 mumol/min/g of tissue in localized fibrocystic disease, fibroadenomas and carcinomas respectively. These data support the idea that citrate lyase may play an important role in lipogenesis in hyperplastic human breast tissues.

Sterol and bile acid metabolism during development. 3. Occurrence of neonatal hypercholesterolemia in guinea pig and its possible relation to bile acid pool

The relationship of the changes in plasma cholesterol to bile acid pool was studied in the newborn guinea pig. Plasma cholesterol reached the maximum on the fifth day and gradually declined to adult levels. The cholesterol concentration in the high density lipoproteins (HDL) was higher in the newborn guinea pig than in the adult. Plasma triglycerides peaked on the third day and decreased markedly. The bile acid pool increased progressively after birth with a 13-fold increase at 5 days of age. While the hepatic triglycerides decreased sharply in the newborn guinea pig, hepatic cholesterol increased in the first 5 days and then decreased to adult levels. This study has described the occurrence of "neonatal hypercholesterolemia" in the guinea pig and its possible relationship to the low level of bile acid synthesis.

The development of ketogenesis at birth in the rat

In the suckling newborn rat, blood ketone bodies begin to increase slowly 4h after birth and then rise sharply between 12 and 16h, whereas the major increase in plasma non-esterified fatty acids and liver carnitine occurs during the first 2h of life, parallel with the onset of suckling. In the starved newborn rat, which shows no increase in liver carnitine unless it is fed with a carnitine solution, the developmental pattern of the ketogenic capacity (tested by feeding a triacylglycerol emulsion, which increases plasma non-esterified fatty acids by 3-fold) is the same as in the suckling animal. This suggests that the increases in plasma non-esterified fatty acids and liver carnitine seen 2h after birth in the suckling animal are not the predominant factors inducing the switch-on of ketogenesis. Injection of butyrate to starved newborn pups resulted in a pattern of blood ketone bodies which was similar to that found after administration of triacylglycerols, but, at all time points studied, the hyperketonaemia was more pronounced with butyrate. It is suggested that, even if the entry of long-chain fatty acids into the mitochondria is a rate-limiting step, it is not the only factor controlling ketogenesis after birth in the rat. As in the adult rat, there is a reciprocal correlation between the liver glycogen content and the concentration of ketone bodies in the blood.

Activity and androgenic control of enzymes associated with the tricarboxylic acid cycle, lipid oxidation and mitochondrial shuttles in the epididymis and epididymal spermatozoa of the rat

1. Enzyme activities (units/g wet wt.) were determined in the caput and cauda epididymidis and in epididymal spermatozoa of the rat. 2. The activity of most enzymes in the cauda was between 50 and 100% of that in the caput, except that ATP citrate lyase was barely detectable in the cauda. 3. Spermatozoa, unlike epididymal tissue, contained sorbitol dehydrogenase but lacked ATP citrate lyase. NADP+-malate dehydrogenase, mitochondrial glycerol 3-phosphate dehydrogenase, succinate dehydrogenase, carnitine acetyltransferase and citrate synthase were 5 to 400 times as active in spermatozoa as in epididymal tissue. 4. 2-Oxoglutarate dehydrogenase was the least active member of the tricarboxylic acid cycle in all tissues and most closely matched the measured flux through the cycle. 5. The concentrations of hydroxyacyl-CoA dehydrogenase and carnitine palmitoyltransferase were equivalent to the more active enzymes of the tricarboxylic acid cycle, indicating the capacity for extensive lipid oxidation, and the presence of 3-hydroxybutyrate dehydrogenase suggests that these tissues can also oxidize ketone bodies. 6. Transfer of reducing equivalents from cytoplasm to mitochondrion is unlikely to occur by means of the glycerol phosphate cycle because mitochondrial glycerol 3-phosphate dehydrogenase is relatively inactive in epididymal tissue, whereas the cytoplasmic enzyme has little activity in spermatozoa, but transfer may be accomplished by the malate-aspartate shuttle. 7. Transfer of acetyl units from mitochondrion to cytoplasm could be effected by the pyruvate-malate cycle in the caput of androgen-maintained rats, but not in the other tissues because of the low activity of ATP citrate lyase. Acetyl unit transfer could take place via acetylcarnitine, mediated by carnitine acetyltransferase. 8. Castration resulted in a decrease in the concentration of nearly all enzymes, although subsequent administration of testosterone restored concentrations to values similar to those in animals maintained by endogenous androgen. The extent to which enzyme concentration was changed by an alteration in androgen status was highly variable, but was most marked in the case of pyruvate carboxylase.

A comparison of lipid metabolism in hepatocytes isolated from fed and starved neonatal and adult rats

1. The utilization of [1-14C]palmitate by hepatocytes prepared from fed and starved neonatal and adult rats has been examined by measuring isotopic incorporation into various products. 2. In cells from fed adult rats the principal products were esters (triglycerides and phospholipids) but ketone bodies were the main metabolic end products in cells from starved adult and fed and starved neonatal rats. Production of triglycerides exceeded that of phospholipids in fed adult cells whereas phospholipid formation always predominated in neonatal cells. 3. The high rate of fatty acid oxidation and hence NADH formation by neonatal cells is reflected by a lower acetoacetate--3-hydroxybutyrate ratio at the earlier stages of incubation of neonatal cells. 4. The addition of glycerol modified quantitatively the products of palmitate metabolism by adult hepatocytes but no such effects were observed with neonatal cells. 5. Compared with adult cells, neonatal hepatocytes showed very low rates of lipogenesis that were only enhanced a little by addition of lactate/pyruvate and did not show any effects of glucose concentration upon incorporation of tritium from 3H2O into lipids.

Fetal utilization of maternally derived ketone bodies for lipogenesis in the rat

When D-beta-[3-14C]hydroxybutyrate was injected via the femoral vein into pregnant Sprague-Dawley rats at 21 days of gestation, D-beta-[3-14C]hydroxybutyrate was enzymatically detected in fetal plasma within 5 min. The time course of the incorporation of DL-beta-[3-14C]hydroxybutyrate into fetal lipids was studied. Lipid extracts of brown adipose tissue exhibited the greatest relative incorporation followed by pancreas, liver and lung. Less radioactivity was incorporated into brain and placenta. The incorporation into fetal lipids was several-fold greater than into maternal lipids. The labelling of the individual phospholipids was similar in the different tissues with phosphatidylcholine accounting for more than 50%. 75% of the radioactivity in brown adipose tissue was in the triacylglycerol fraction. In brain, liver and placenta, approximately half of the neutral lipid radioactivity was in cholesterol. Experiments in which D-beta-[3-14C]hydroxybutyrate was directly injected into fetuses in utero confirmed that this substrate was directly used by the fetuses without maternal intervention. These studies demonstrate that the rat placenta is permeable to beta-hydroxybutyrate and suggest that this ketone body is rapidly used by the fetus for the synthesis of fatty acids and cholesterol.

Lipid metabolism and mobilization in the guinea pig during pregnancy

The liver of the foetal guinea pig accumulates a large quantity of triacyglycerol late in gestation at the same time that adipose-tissue mass grows at its maximum rate and foetal adipose-tissue lipoprotein lipase activity and sensitivity to lipolytic hormones has substantially declined. The fatty acid for triacyglycerol synthesis is not synthesized in the foetal liver and it is unlikely that it originates from any of the foetal tissues. Before the accumulation of hepatic triacyglycerol the concentration of free fatty acids increases in both the umbilical vein and the maternal inferior vena cava. This occurs at a time when the triacyglycerol lipase activity in maternal adipose tissue is elevated and the rate of lipolysis, but not of fatty acid esterification, is higher than earlier in gestation or than in the non-pregnant state. It is proposed that the increase in lipolysis in maternal adipose tissue, brought about by an increase in circulating lipolytic hormones, mobilizes fatty acid, which passes to the foetus and is partly stored as hepatic triacylglycerol. The foetal liver effectively removes both long-and short-chain fatty acids from umbilical-vein blood. The rate of placental fatty acid transfer is more than adequate to account for the triacylglycerol accumulation.

Effect of maternal diet on fetal hepatic lipogenesis

The effects of: a, maternal diet; b, cyclic-3',5'-adenosinemonophosphate (cyclic AMP) and c, clofibrate on hepatic lipogenesis in fetal rats were studied. The experimental diets contained 22% protein, 40--50% carbohydrate, adequate vitamins, and minerals. In addition, the fat-containing diets were supplemented with either 15% corn oil, 25% corn oil, or 5% cholesterol + 10% oleic acid. In the clofibrate feeding studies, 0.3% (w/v) of the ethyl ester was added to a stock ration or to fat-free diet. Lipogenesis was measured in liver slices incubated with [2-14C]pyruvate, [1-14C]acetate, or 3H2O. In addition, activities of lipogenic enzymes were measured in cytosol fractions from liver homogenates. The effec-s of the experimental diets on liver composition were also examined. Lipogenic activity was higher in fetal than in maternal liver. When 15% corn oil was added to the maternal diet, fatty acid synthesis in fetal liver did not decrease as it did in maternal liver. Maternal fasting decreased fetal fatty acid synthesys by 50% when measured with 14C and less than 10% when measured with 3H2O. Although the addition of cholesterol to the maternal diet decreased cholesterol synthesis in maternal liver, no such decrease was observed in fetal liver. Changes in enzyme activities paralleled alterations in lipogenesis in maternal but not in fetal liver. Corn oil feeding or fasting increased the rate of transfer of linoleate from the dam to the fetus. However, accumulation of linoleate in fetal liver did not correlate with a decreased rate of fatty acid synthesis as it did in maternal liver. Maternal hepatic glycogen stores were depleted by fasting, but glycogen levels in fetal liver remained high under these conditions.

Lipid biosynthesis in liver slices of the foetal guinea pig

Lipid synthesis as measured by the incorporation of acetate or 3H2O into slices of foetal liver, is much higher than in slices of adult liver and shows a peak at about two-thirds of gestation. At this time the synthesis from glucose was low and reached a peak 10 days later. The changes in the activity of ATP citrate lyase, which mirrored acetate incorporation, and the effect of glucose and pyruvate on acetate corporation into lipid suggests that some of the lipid synthesis occurs via intramitochondrial acetyl-CoA production from acetate. Despite this, lipid synthesis was not inhibited by (-)-hydroxycitrate. The low rate of synthesis from glucose at two-thirds of gestation is ascribed to the low activity of pyruvate carboxylase at this time and a role for a phosphoenolpyruvate carboxykinase in providing oxaloacetate for lipogenesis is proposed. The activity of fatty acid synthetase broadly agreed with the changes in lipid synthesis, whereas the activity of acetyl-CoA carboxylase was barely sufficient to account for the rates of lipid synthesis in vivo. Acetate and short-chain fatty acids are likely to be the major precursors for lipid synthesis in vivo.

Cholesterol and fatty acid synthesis in swine

In incubation studies with swine tissue slices, acetate-1-14C or glucose-U-14C as substrates were incorporated more readily into fatty acids and cholesterol in adipose tissue than other tissues tested. Cholesterol and fatty acid synthesizing acitivity was substantial in the small intestine. When acetate was available, liver, small intestine, and adipose tissue were important sites for cholesterol synthesis. Heart and aortic tissue had marginal levels of cholesterol synthesizing ability. Lipogenesis in adult swine liver, heart, and aortic tissue was extremely low. As in tissue slices, incorporation of acetyl-1-14C CoA into fatty acids by adipose homogenates indicated high lipogenic activity. Subcellular fractionations of heart and aortic tissue indicated that the heart microsomal fraction had the highest lipogenic activity as measured by the incroporation of acetyl-4-14C CoA into fatty acids. In adult swine adipose tissue, the incorporation of glucose-U-14C into fatty acid was higher than its incorporation into glyceride-glycerol. The synthesis of glyceride-glycerol from glucose-U-14C or acetate-1-14C in liver was higher than for fatty acid synthesis. The acitivity of acetyl CoA carboxylase, fatty acid synthetase, citrate cleavage enzyme, nicotinamide adenine dinucleotide phosphat-malate dehydrogenase, glucose-6-phosphate dehydrogenase, and 6-phosphogluconate dehydrogenase was considerably higher in adipose tissue than in other tissues tested, paralleling its high lipogenic capacity.

The effects of choline and inositol on hepatic lipid metabolism and the incidence of the fatty liver and kidney syndrome in broilers

1. Diets high in wheat and low in protein (18%) produced 5 to 6% mortality from fatty liver and kidney syndrome (FLKS) in broiler chicks whereas there were no deaths from FLKS in birds fed on a maize/barley diet containing 20% protein. 2. Supplementation of the wheat-based diets with choline or inositol (2-5 g additive/kg diet) did not affect the incidence of FLKS or liver lipid metabolism. 3. The wheat-based diet did not significantly affect the activities of hepatic lipogenic enzymes suggesting that hepatic lipid biosynthesis is not a cause of the syndrome. 4. The biotin contents of the wheat and maize/barley diets were little different, which may suggest that factors other than this are implicated in FLKS.

Fatty acid synthesis by human adipose tissue

The effect of age and nutritional status on the synthesis of fatty acids from a variety of labeled substrates by human adipose tissue in vitro was investigated. The results of this study clearly demonstrate that, although human adipose tissue is able to oxidize glucose to CO2, its ability to incorporate glucose-carbon into long chain fatty acids is negligible. Although the utilization of acetate for the synthesis of fatty acids by adipose tissue is substantial in the presence of glucose and insulin, its physiologic significance in human under normal dietary conditions is questionable. That the capacity of human adipose tissue is limited is further supported by (1) a negligible incorporation of pyruvate-3-14C (up to 25 mM concentration in the incubation medium) into fatty acids, (2) a lack of stimulation in lipogenesis by human adipose tissue after refeeding a diet high in carbohydrate and very low in fat to a previously starved human, and (3) an extremely low activity of pyruvate carboxylase and ATP-citrate lyase in adipose tissues from humans of varying ages. The activities of other key lipogenic enzymes, glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, and NADP-malate dehydrogenase, are also low. These enzymes can be stimulated in human adipose tissue after a fasting-refeeding regimen. The activity of phosphoenolpyruvate carboxykinase is also very low in human adipose tissue,and it is suggested that a pathway of glyceroneogenesis may not play a significant role in human adipose tissue. In light of our results, together with previous reports, it is possible to conclude that the capacity of human adipose tissue to utilize a dietary carbohydrate for the synthesis of fatty acids is extremely low and that the liver plays a major role in the biosynthesis of endogenous fatty acids from dietary carbohydrate in the human.

Effect of cholesterol feeding on cholesterol biosynthesis in maternal and foetal rat liver

Hepatic cholesterol biosynthesis has been studied in rat foetuses whose mothers had been fed on a cholesterol rich diet during the last week of gestation. Foetal liver was found to be capable of synthesizing cholesterol from acetate in vitro. The rate of incorporation of labelled acetate into digitonin precipitable sterols, fatty acids and CO(2) in foetal liver was much higher than that found in maternal liver. Cholesterol feeding reduced the rate of sterol synthesis in maternal liver but it did not have any appreciable effect on foetal liver. In order to investigate whether this lack of feed-back control in foetal liver could be attributable to an obstacle to the placental transfer of dietary cholesterol. 14-C-cholesterol was administered to the pregnant rats and its distribution in maternal and foetal liver and plasma was studied. Our results indicate that placental transfer of cholesterol from mother to foetus occurs very slowly so that only a small proportion of labelled cholesterol is found in foetal plasma over a 48 hour period following the administration of radioactive cholesterol. Cholesterol transferred from the mother into the foetal plasma is efficiently taken up by the foetal liver. These findings would suggest that the low amount of dietary cholesterol transferred from the mother into the foetal plasma is not sufficient to activate the control mechanism of the cholesterol biosynthetic pathway in the foetal liver.