Changes in the activities of the enzymes of hepatic fatty acid oxidation during development of the rat

Dipeptidyl peptidase 9 enzymatic activity influences the expression of neonatal metabolic genes

The success of dipeptidyl peptidase 4 (DPP4) inhibition as a type 2 diabetes therapy has encouraged deeper examination of the post-proline DPP enzymes. DPP9 has been implicated in immunoregulation, disease pathogenesis and metabolism. The DPP9 enzyme-inactive (Dpp9 gene knock-in; Dpp9 gki) mouse displays neonatal lethality, suggesting that DPP9 enzyme activity is essential in neonatal development. Here we present gene expression patterns in these Dpp9 gki neonatal mice. Taqman PCR arrays and sequential qPCR assays on neonatal liver and gut revealed differential expression of genes involved in cell growth, innate immunity and metabolic pathways including long-chain-fatty-acid uptake and esterification, long-chain fatty acyl-CoA binding, trafficking and transport into mitochondria, lipoprotein metabolism, adipokine transport and gluconeogenesis in the Dpp9 gki mice compared to wild type. In a liver cell line, Dpp9 knockdown increased AMP-activated protein kinase phosphorylation, which suggests a potential mechanism. DPP9 protein levels in liver cells were altered by treatment with EGF, HGF, insulin or palmitate, suggesting potential natural DPP9 regulators. These gene expression analyses of a mouse strain deficient in DPP9 enzyme activity show, for the first time, that DPP9 enzyme activity regulates metabolic pathways in neonatal liver and gut.

Developmental Changes in Carnitine Octanoyltransferase Gene Expression in Intestine and Liver of Suckling Rats

Carnitine octanoyltransferase (COT), which facilitates the transport of shortened fatty acyl-CoAs from peroxisomes to mitochondria, is expressed in the intestinal mucosa of suckling rats; its mRNA levels increase rapidly after birth, remain steady until day 15, and decrease until weaning, when basal, adult values are established, which remain unchanged thereafter. The process seems to be controlled at the transcriptional level since the developmental pattern of mRNA coincides with that of pre-mRNA values. Dam's milk may influence the intestinal expression of COT, since mRNA levels at birth are low and increase after the first lactation. Moreover, mRNA levels decrease in rats weaned on day 18 or 21. COT is also expressed in the liver of suckling rats. Hepatic COT mRNA is maximal at day 3, remains constant until day 9, and decreases thereafter; this pattern is also similar to that of pre-mRNA values. The profile of expression of COT in intestine and liver strongly resembles that of mitochondrial 3-hydroxy 3-methylglutaryl-coenzyme A synthase and carnitine palmitoyltransferase I, suggesting that analogous transcription factors modulate ketogenesis and mitochondrial and peroxisomal fatty acid oxidation.

The effect of dexamethasone treatment on the expression of the regulatory genes of ketogenesis in intestine and liver of suckling rats

The influence of the injection of dexamethasone on ketogenesis in 12 day old suckling rats was studied in intestine and liver by determining mRNA levels and enzyme activity of the two genes responsible for regulation of ketogenesis: carnitine palmitoyl transferase I (CPT I) and mitochondrial HMG-CoA synthase. Dexamethasone produced a 2 fold increase in mRNA and activity of CPT I in intestine, but led to a decrease in mit. HMG-CoA synthase. In liver the mRNA levels and activity of both CPT I and mit. HMG-CoA synthase decreased. Comparison of these values with the ketogenic rate of both tissues following dexamethasone treatment suggests that mit. HMG-CoA synthase could be the main gene responsible for the regulation of ketogenesis in suckling rats. The changes produced in serum ketone bodies by dexamethasone, with a profile that is more similar to the ketogenic rate in the liver than that in the intestine, indicate that liver contributes more to ketone body synthesis in suckling rats. Two day treatment with dexamethasone produced no change in mRNA or activity levels for CPT I in liver or intestine. While mRNA levels for mit. HMG-CoA synthase changed little, the enzyme activity is decreased in both tissues.

Mitochondrial biogenesis in the liver during development and oncogenesis

The analysis of the expression of oxidative phosphorylation genes in the liver during development reveals the existence of two biological programs involved in the biogenesis of mitochondria. Differentiation is a short-term program of biogenesis that is controlled at post-transcriptional levels of gene expression and is responsible for the rapid changes in the bioenergetic phenotype of mitochondria. In contrast, proliferation is a long-term program controlled both at the transcriptional and post-transcriptional levels of gene expression and is responsible for the increase in mitochondrial mass in the hepatocyte. Recently, a specific subcellular structure involved in the localization and control of the translation of the mRNA encoding the beta-catalytic subunit of the H(+)-ATP synthase (beta-mRNA) has been identified. It is suggested that this structure plays a prominent role in the control of mitochondrial biogenesis at post-transcriptional levels. The fetal liver has many phenotypic manifestations in common with highly glycolytic tumor cells. In addition, both have a low mitochondrial content despite a paradoxical increase in the cellular representation of oxidative phosphorylation transcripts. Based on the paradigm provided by the fetal liver we hypothesize that the aberrant mitochondrial phenotype of fast-growing hepatomas represents a reversion to a fetal program of expression of oxidative phosphorylation genes by the activation, or increased expression, of an inhibitor of beta-mRNA translation.

Gene expression of mitochondrial 3-hydroxy-3-methylglutaryl-CoA synthase in a poorly ketogenic mammal: effect of starvation during the neonatal period of the piglet

The low ketogenic capacity of pigs correlates with a low activity of mitochondrial 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA) synthase. To identify the molecular mechanism controlling such activity, we isolated the pig cDNA encoding this enzyme and analysed changes in mRNA levels and mitochondrial specific activity induced during development and starvation. Pig mitochondrial synthase showed a tissue-specific expression pattern. As with rat and human, the gene is expressed in liver and large intestine; however, the pig differs in that mRNA was not detected in testis, kidney or small intestine. During development, pig mitochondrial HMG-CoA synthase gene expression showed interesting differences from that in the rat: (1) there was a 2-3 week lag in the postnatal induction; (2) the mRNA levels remained relatively abundant through the suckling-weaning transition and at maturity, in contrast with the fall observed in rats at similar stages of development; and (3) the gene expression was highly induced by fasting during the suckling, whereas no such change in mitochondrial HMG-CoA synthase mRNA levels has been observed in rat. The enzyme activity of mitochondrial HMG-CoA synthase increased 27-fold during starvation in piglets, but remained one order of magnitude lower than rats. These results indicate that post-transcriptional mechanism(s) and/or intrinsic differences in the encoded enzyme are responsible for the low activity of pig HMG-CoA synthase observed throughout development or after fasting.

The effect of fasting/refeeding and insulin treatment on the expression of the regulatory genes of ketogenesis in intestine and liver of suckling rats

The influence of fasting/refeeding and insulin treatment on ketogenesis in 12-day-old suckling rats was studied in intestine and liver by determining mRNA levels and enzyme activity of the two genes responsible for regulation of ketogenesis: carnitine palmitoyl transferase I (CPT I) and mitochondrial HMG-CoA synthase. Fasting produced hardly any change in mRNA or activity of CPT 1 in intestine, but led to a decrease in mitochondrial (mit.) HMG-CoA synthase. In liver, while mRNA levels and activity for CPT I increased, neither parameter was changed in HMG-CoA synthase. The comparison of these values with the ketogenic rate of both tissues under the fasting/refeeding treatment shows that HMG-CoA synthase could be the main gene responsible for regulation of ketogenesis in suckling rats. The small changes produced in serum ketone bodies in fasting/refeeding, with a profile similar to the ketogenic rate of the liver, indicate that liver contributes most to ketone body synthesis in suckling rats under these experimental conditions. Short-term insulin treatment produced increases in mRNA levels and activity in CPT I in intestine, but it also decreased both parameters in mit. HMG-CoA synthase. In liver, graphs of mRNA and activity were nearly identical in both genes. There was a marked decrease in mRNA levels and activity, resembling those values observed in adult rats. As in fasting/refeeding, the ketogenic rate correlated better to mit. HMG-CoA synthase than CPT I, and liver was the main organ regulating ketogenesis after insulin treatment. Serum ketone body concentrations were decreased by insulin but recovered after the second hour. Long-term insulin treatment had little effect on the mRNA levels for CPT I or mit. HMG-CoA synthase, but both the expressed and total activities of mit. HMG-CoA synthase were reduced by half in both intestine and liver. The ketogenic rate of both organs was decreased to 40% by long-term insulin treatment. The different effects of refeeding and insulin treatment on the expression of both genes, on the ketogenic rate, and on ketone body concentrations are discussed.

Developmental changes in carnitine palmitoyltransferases I and II gene expression in intestine and liver of suckling rats

Carnitine palmitoyltransferase (CPT) I is expressed in the intestine of suckling rats; its mRNA increases very rapidly after birth, remains on a plateau until day 18 and decreases until weaning, when basal (adult) values are reached, which remain unchanged thereafter. CPT II mRNA values do not show any appreciable change in this period. CPT I and CPT II are expressed mainly in mucosa and, to a lesser extent, in the muscular part of the intestine. Intestinal expression of CPT I is maximal in duodenum and jejunum, whereas CPT II is expressed in a similar pattern throughout the whole intestine. Dam's milk may influence the intestinal expression of CPT I, since mRNA levels at birth are low but increase after the first lactation. Moreover, rats weaned at either day 18 or 21 decrease their mRNA levels. Apparently, CPT II gene expression is not influenced by the mother's milk. CPT I and CPT II are also expressed in the liver of suckling rats. Hepatic CPT I is maximal at day 3, and levels of CPT II mRNA do not change, in a similar fashion to that in intestine. The profile of expression of CPT I in liver and intestine strongly resembles that previously reported for mitochondrial 3-hydroxy-3-methyl-glutaryl-CoA synthase.

Diacylglycerol metabolism in neonatal rat liver: characterization of cytosolic diacylglycerol lipase activity and its activation by monoalkylglycerols

Diacylglycerol lipase (glycerol ester hydrolase, EC 3.1.1.3) activities were investigated in subcellular fractions from neonatal and adult rat liver in order to determine whether one or more different lipases might provide the substrate for the developmentally expressed, activity monoacylglycerol acyltransferase. The assay for diacylglycerol lipase examined the hydrolysis of sn-1-stearoyl,2- [14C]oleoylglycerol to labeled monoacylglycerol and fatty acid. Highest specific activities were found in lysosomes (pH 4.8) and cytosol and microsomes (pH 8). The specific activity from plasma membrane from adult liver was 5.8-fold higher than the corresponding activity in the neonate. In other fractions, however, no developmental differences were observed in activity or distribution. In both lysosomes and cytosol, 75 to 90% of the labeled product was monoacylglycerol, suggesting that these fractions contained relatively little monoacylglycerol lipase activity. In contrast, 80% of the labeled product from microsomes was fatty acid, suggesting the presence of monoacylglycerol lipase in this fraction. Analysis of the reaction products strongly suggested that the lysosomal and cytosolic diacylglycerol lipase activities hydrolyzed the acyl-group at the sn-1 position. The effects of serum and NaCl on diacylglycerol lipase from each of the subcellular fractions differed from those effects routinely observed on lipoprotein lipase and hepatic lipase, suggesting that the hepatic diacylglycerol lipase activities were not second functions of these triacylglycerol lipases. Cytosolic diacylglycerol lipase activity from neonatal liver and adult liver was characterized. The apparent Km for 1-stearoyl,2-oleoylglycerol was 115 microM. There was no preference for a diacylglycerol with arachidonate in the sn-2 position. Bovine serum albumin stimulated the activity, whereas dithiothreitol, N-ethylmaleimide, and ATP inhibited the activity. Both sn-1(3)- and 2-monooleylglycerol ethers stimulated cytosolic diacylglycerol lipase activity 2-3-fold. The corresponding amide analogs stimulated 28 to 85%, monooleoylglycerol itself had little effect, and 1-alkyl- or 1-acyl-lysophosphatidylcholine inhibited the activity. These data provide the first characterization of hepatic subcellular lipase activities from neonatal and adult rat liver and suggest that independent diacylglycerol and monoacylglycerol lipase activities are present in microsomal membranes and that the microsomal and cytosolic diacylglycerol lipase activities may describe an ambipathic enzyme. The data also suggest possible cellular regulation by monoalkylglycerols.

Control of hepatic mitochondrial 3-hydroxy-3-methylglutaryl-CoA synthase during the foetal/neonatal transition, suckling and weaning in the rat

(1) We assayed active and total (i.e. active plus succinylated) 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA) synthase in mitochondria isolated from foetal, neonatal, suckling or weaned rats. (2) HMG-CoA synthase was substantially succinylated and inactivated in mitochondria isolated from term-foetal, (1-h-old, 6-h-old, 1-day-old) neonatal, suckling and high carbohydrate/low-fat (hc)-weaned rats. Succinylation of HMG-CoA synthase was very low in mitochondria isolated from the livers of foetal, 30-min-old neonatal and high-fat/carbohydrate-free (hf)-weaned rats. (3) There was a negative correlation between active HMG-CoA synthase and succinyl-CoA content in mitochondria isolated from term-foetal, suckling and hc-weaned rats. (4) Differences in active enzyme could not be entirely accounted for by differences in succinylation and inactivation of the synthase. Immunoassay confirmed that the absolute amounts of mitochondrial HMG-CoA synthase increased during the foetal/neonatal transition and decreased with hc weaning. The levels remained elevated with hf weaning. (5) From these data we propose that mitochondrial HMG-CoA synthase is controlled by two different mechanisms in young rats. Regulation by succinylation provides a mechanism for rapid modification of existing enzyme in response to changing metabolic states. Changes in the absolute amounts of HMG-CoA synthase provide a more long-term control in response to nutritional changes.

Intramitochondrial factors controlling hepatic fatty acid oxidation at weaning in the rat

Fatty acid oxidation was studied in isolated liver mitochondria of rats during the suckling-weaning transition. The oxidation rate of oleyl-CoA and palmitoylcarnitine was reduced 2.5-fold in rats weaned on a high-carbohydrate diet compared to suckling rats, when acetyl-CoA produced by beta-oxidation was directed towards ketone-body synthesis. Weaning on a high-fat diet minimized this change. Channeling of acetyl-CoA towards citrate synthesis doubled the oxidation rate of both substrates in HC-weaned rats. Thus, in addition to changes in carnitine palmitoyltransferase I activity, the beta-hydroxymethylglutaryl-CoA synthase pathway is also involved in the decreased fatty acid oxidation at weaning. This was confirmed by measurement of beta-hydroxymethylglutaryl-CoA synthase pathway activity.

Carnitine palmitoyltransferase in liver and five extrahepatic tissues in the rat. Inhibition by DL-2-bromopalmitoyl-CoA and effect of hypothyroidism

Mitochondria were isolated from rat adult liver, foetal liver, kidney cortex, heart, skeletal muscle and interscapular brown adipose tissue. DL-2-Bromopalmitoyl-CoA inhibited the overt form of carnitine palmitoyltransferase (CPT1) in heart, skeletal muscle and brown adipose tissue, with an IC50 value (concentration giving 50% inhibition) of 1.3-1.6 microM. By contrast, the IC50 value for inhibition of the kidney or adult liver enzyme was 0.08-0.1 microM. CPT1 in near-term foetal liver differed from that in adult liver in that the IC50 for inhibition by 2-bromopalmitoyl-CoA was 0.57 microM. It is suggested that there may be tissue-specific forms of the catalytic entity of CPT1 and that foetal liver may contain a mixture of adult liver- and muscle-type enzymes. In rats made hypothyroid by administration of propylthiouracil and an iodine-deficient diet, hepatic CPT1 activity was decreased by 83%. However, CPT1 activity in extrahepatic tissues showed no adaptive decrease in hypothyroidism.

Evidence that the development of hepatic fatty acid oxidation at birth in the rat is concomitant with an increased intramitochondrial CoA concentration

The development of hepatic fatty acid oxidation during the perinatal period in the rat was studied using isolated mitochondria. Ketone body synthesis from substrates entering at different levels of beta-oxidation was 2-3 times lower in mitochondria isolated from term-fetal liver than in 16-h-old newborn or adult liver mitochondria. The low rate of palmitoyl-L-carnitine oxidation in term-fetal mitochondria was linked neither to the low capacity of the respiratory chain nor to the removal of acetyl-CoA in the hydroxymethylglutaryl-CoA synthase pathway. The 2.5-times lower concentration of CoA found in term-fetal liver mitochondria when compared to 16-h-old or adult liver mitochondria might be the factor responsible for the low rate of fatty acid oxidation in term-fetal liver mitochondria.

Peroxisomal fatty acid oxidation in rat and human tissues. Effect of nutritional state, clofibrate treatment and postnatal development in the rat

Oxidation of palmitate 14C-labeled in different positions was assayed in the absence and presence of antimycin and rotenone in homogenates of various rat and human tissues to determine total and peroxisomal oxidation and acetyl group production. Total and antimycin-insensitive palmitate oxidation rates were higher in rat heart, liver and quadriceps muscle than in the corresponding human tissues. The proportion of antimycin-insensitive oxidation of [1-14C]palmitate was 17-35% in tissues of starved rats and in human muscles and fibroblasts, but peroxisomal production of acetyl groups amounted only to 5-11% of that by mitochondria. The mean number of peroxisomal beta-oxidation cycles was 1.5-2.5 per palmitate molecule. The nutritional state markedly influenced the total oxidation rate and the antimycin-insensitive proportion in rat liver. Clofibrate feeding increased total and antimycin-insensitive oxidation rates in liver, heart and kidney, but not in quadriceps muscle. Total oxidation capacity was maximal in rat liver at weaning, and in rat heart at an age of 70 days. Antimycin-insensitive oxidation rates increased in rat liver and heart at postnatal development up to weaning. A marked proportion of lignocerate oxidation was antimycin-sensitive in rat tissues.

Activities of enzymes of acetoacetate metabolism in rat brown adipose tissue during development

The activities of two mitochondrial enzymes concerned in the utilization of acetoacetate, namely 3-oxoacid CoA-transferase and acetoacetyl-CoA thiolase, were high throughout the suckling and weanling period in brown adipose tissue of the rat. In contrast, 3-hydroxybutyrate dehydrogenase activity was comparatively low during this period. The activity of cytosolic acetoacetyl-CoA synthetase (involved in lipogenesis) declined after birth and remained low until the pups were weaned. Experiments with brown-adipose-tissue slices from weanling rats indicated that 70% of the [3-14C]acetoacetate utilized was oxidized to 14CO2, and this value was not altered appreciably by the addition of glucose and insulin.

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.

Hepatic mitochondrial fatty acid oxidation during the perinatal period in the rat

1. The activity of hepatic mitochondrial carnitine acyltransferase I increases rapidly after birth, is high during the suckling period and falls after weaning. In contrast, carnitine acyltransferase II and acyl-CpA dehydrogenase exhibit few developmental changes. 2. These and previous studies indicate that outer mitochondrial membrane acyl-CoA synthetase and inner membrane carnitine acyltransferase I increase in activity after birth much more rapidly than to any other enzymes of fatty acid oxidation. 3. Studies of the 18 hr after caesarian delivery indicate that whereas the major increase in the activity of acyl-CoA synthetase occurs within 3 hr of birth the change in carnitine acyltransferase I activity is less rapid. 4. Prolonged pregnancy, starvation of the mother or feeding the mother a high polyunsaturated fat content diet resulted in increased activities of acyl-CoA synthetase and carnitine acyltransferase I in the fetal liver.

Development of fatty acid oxidation in neonatal guinea-pig liver

The capacity of foetal and neonatal liver to oxidize short-, medium- and long-chain fatty acids was studied in the guinea pig. Liver mitochondria from foetal and newborn animals were unable to synthesize ketone bodies from octanoate, but octanoylcarnitine and palmitoylcarnitine were readily ketogenic. The ketogenic capacity at 24 h after birth was as high as in adult animals. Hepatocytes isolated from term animals were unable to oxidize fatty acids, but at 6 h after birth production of 14CO2, acid-soluble products and acetoacetate from 1-14C-labelled fatty acids was 40-50% of the rates at 24 h. At 12 h of age these rates had already reached the 24 h values and did not change during suckling in the first week of life. The activities of hepatic fatty acyl-CoA synthetases, which were minimal in the foetus or at term, increased to maximal values in 12-24 h. The data show that the capacity for beta-oxidation and ketogenesis develops maximally in this species during the first 6-12 h after birth, and appears to be partly dependent on the development of fatty acid-activating enzyme.

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.

Postnatal development of palmitate oxidation and mitochondrial enzyme activities in rat cardiac and skeletal muscle

1. The palmitate oxidation rate was measured in intact diaphragm and m. flexor digitorum brevis and in whole homogenates of heart, diaphragm and m. quadriceps of developing rats between late foetal life and maturity. Activities of the mitochondrial enzymes cytochrome c oxidase and citrate synthase were also determined. 2. Immediately after birth the palmitate oxidation rate increases markedly in both intact diaphragm and m. flexor digitorum brevis and falls gradually after day 1 to adult values which are about 35% of those at birth. 3. The oxidation capacities of diaphragm and m. quadriceps, but especially of heart, increase steadily during development, starting before birth and reaching adult values at 15-20 days postnatally. The activities of the mitochondrial enzymes show a similar developmental pattern. 4. In heart the increase of oxidative capacity is the result of an increase of both mitochondrial content and mitochondrial activity. The mitochondrial contents of diaphragm and m. quadriceps, on the other hand, decrease with age and the increase of their oxidative capacities is due to a large rise of the mitochondrial activity.

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.

Postnatal development of some membrane-bound enzymes of rat liver and kidney

1. The development of rat liver acyl-CoA:sn-glycerol-3-phosphate-O-acyl-transferase (EC 2.3.1.15) is characterized by an increase and decrease in activity during the neonatal period, followed by a second increase and decrease during the late weaning period. Kidney acyltransferase exhibits a similar peak in activity during the neonatal period before increasing to adult levels of activity during the late weaning period. 2. Nucleosidediphosphatase activity increases rapidly during the neonatal period and thereafter gradually rises to adult levels in both liver and kidney. The latency of the enzyme increases rapidly after birth and thereafter shows little change with age. The enzyme appears to be more latent in the liver than in the kidney at all ages studied. 3. NADPH-cytochrome c reductase of liver has a single steep maximum and minimum in activity during the neonatal period, before increasing again to adult levels during the late weaning period. The enzyme in kidney shows a similar developmental pattern but at much lower levels of specific activity. 4. sn-Glycerol-3-phosphate acyltransferase activity was significantly higher in rough than in smooth membranes throughout the neonatal period of rapid smooth membrane proliferation. This distribution of enzyme activity is unlike that reported by others in phenobarbital-induced smooth membrane proliferation and suggests a major role for rough membranes in phospholipid synthesis during the neonatal period. 5. The qualitative similarity in development in rough and smooth microsomal subfractions for each of these enzymes is in distinct contrast with results previously reported for glucose-6-phosphatase.

The development of enzymes of energy metabolism in the brain of a precocial (guinea pig) and non-precocial (rat) species

Key enzymes of ketone body metabolism (3-hydroxybutyrate dehydrogenase, 3-oxo-acid:CoA transferase, acetoacetyl-CoA thiolase) and glucose metabolism (hexokinase, lactate dehydrogenase, pyruvate dehydrogenase, citrate synthase) have been measured in the brains of foetal, neonatal, and adult guinea pigs and compared to those in the brains of neonatal and adult rats. The activities of the guinea pig brain ketone-body-metabolising enzymes remain relatively low in activity throughout the foetal and neonatal periods, with only slight increases occurring at birth. This contrasts with the rat brain, where three- to fourfold increases in activity occur during the suckling period (0-21 days post partum), followed by a corresponding decrease in the adult. The activities of the hexokinase (mitochondrial and cytosolic), pyruvate dehydrogenase, lactate dehydrogenase, and citrate synthase of guinea pig brain show marked increases in the last 10-15 days before birth, so that at birth the guinea pig possesses activities of these enzymes similar to the adult state. This contrasts with the rat brain where these enzymes develop during the late suckling period (10-15 days after birth). The development of the enzymes of aerobic glycolytic metabolism correlate with the onset of neurological competence in the two species, the guinea pig being a "precocial" species born neurologically competent and the rat being a "non-precocial" species born neurologically immature. The results are discussed with respect to the enzymatic activities required for the energy metabolism of a fully developed, neurologically competent mammalian brain and its relative sensitivity to hypoxia.

Regulation of ketogenesis during the suckling-weanling transition in the rat. Studies with isolated hepatocytes

The rates of ketogenesis from endogenous substrates, butyrate or oleate, have been measured in isolated hepatocytes from suckling and weanling rats. Ketogenesis from endogenous substrate and from oleate decreased on weaning, whereas the rate from butyrate remained unchanged. It is concluded that the major site of regulation of ketogenesis during this period of development involves the disposal of long-chain fatty acyl-CoA between the esterification and beta-oxidation pathways. Modulators of lipogenesis [dihydroxyacetone and 5-(tetradecyloxy)-2-furoic acid] did not alter the rate of ketogenesis in hepatocytes from suckling rats, and it is suggested that this is due to the low rate of lipogenesis in these cells. Hepatocytes from fed weanling rats have a high rate of lipogenesis and evidence is presented for a reciprocal relationship between ketogenesis and lipogenesis, and ketogenesis, and esterification in these cells. Dibutyryl cyclic AMP stimulated ketogenesis from oleate in hepatocytes from fed weanling rats, even in the presence of an inhibitor of lipogenesis [5-(tetradecyloxy)-2-furoic acid], but not in cells from suckling rats. It is suggested that cyclic AMP may act via inhibition of esterification and that in hepatocytes from suckling rats ketogenesis is already maximally stimulated by the high basal concentrations of cyclic AMP [Beaudry, Chiasson & Exton (1977) Am. J. Physiol. 233, E175--E180].

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.

Long and medium chain triglycerides increase plasma concentrations of ketone bodies in suckling rats

The potential of medium chain triglyceride (MCT) and long chain triglyceride (LCT) as sources of plasma ketones was investigated in suckling rats. Initially high concentrations of plasma ketones in 6-, 10, and 17-day-old rats increased 2- to 3-fold after acute feeding of MCT. This feeding had the same effect in fed or fasted adult rats. Corn oil (as a source of LCT) induced a large increase in the plasma ketone concentration of suckling rats and a relatively small but significant increase in fasted adult rats. The LCT treatment did not affect plasma ketone levels in fed adult rats. The results show clearly that feeding either LCT or MCT will enhance hyperketonemia in suckling rats. In the livers of all animals, regardless of age, the capacity for incorporation of [1(-14C)]octanoate into CO2 and acetoacetate far exceeded that for [1(-14C)]palmitate. The hyperketonemic action of LCT in suckling rats was accompanied by an increased activity of carnitine palmityltransferase and increased level of carnitine.

Effects of maternal ethanol consumption on hepatic lipid biosynthesis in foetal and neonatal rats

Effects of prolonged maternal ethanol consumption were studied on hepatic lipid content, on the rates of fatty acid synthesis and on the activities of enzymes involved in fatty acid synthesis in the livers of foetal and suckling neonatal rats. Prolonged maternal ethanol consumption resulted in a significant increase in the contents of hepatic total lipids, triacylglycerols and plasma unesterified fatty acids in foetal and neonatal rats. Studies in vitro with 3H2O showed that maternal ethanol consumption did not result in a significant change in its rate of incorporation into lipid fractions of foetal and neonatal livers. The rates of fatty acid synthesis showed a pronounced decrease immediately after birth, compared with the foetal stage, but increased in the adult animals. On the other hand, the highest rates of lipid oxidation were observed in the neonatal stage. Maternal ethanol consumption resulted in a significant decrease in the rates of [14C]palmitate oxidation to 14CO2 by both the foetal and neonatal livers. Maternal ethanol consumption did not result in an increase in the activities of any of the lipid-synthesizing enzymes tested throughout the period of development. Although increased fatty acid synthesis does not seem to be the mechanism for the accumulation of these lipids, decreased oxidation of the lipids may be partly responsible for the lipid accumulation.

Enhancement of the anti-anabolic response to adenosine 3':5'-cyclic monophosphate during development. The inhibition of hepatic protein synthesis

Cyclic AMP causes an age-dependent inhibition of protein synthesis in rat liver. The onset of inhibition is about 10--12 days after birth. The developmental response to cyclic AMP is associated with a change in the microsomal component of the protein-synthesizing system.

Relative utilization of fatty acids for synthesis of ketone bodies and complex lipids in the liver of developing rats

The regulation of hepatic ketogenesis, as related to the metabolism of fatty acids through oxidative and synthetic pathways, was studied in developing rats. [1-14C] palmitate was used as a substrate to determine the proportions of free fatty acids utilized for the production of ketone bodies, CO2 and complex lipids. Similar developmental patterns of hepatic ketogenesis were obtained by measuring the production of either [14C] acetoacetate from exogenous [1-14C] palmitate or the sum of unlabeled acetoacetate and beta-hydroxybutyrate from endogenous fatty acids. The production of total ketone bodies was low during the late fetal stage and at birth, but increased rapidly to a miximum value within 24 hr after brith. The maximal ketogenic capacity appeared to be maintained for the first 10 days of life. 14CO2 production from [1-14C] palmitate increased by two- to fourfold during the suckling period, from its initial low rate seen at birth. The capacity for synthesis of total complex lipids was low at birth and had increased by day 3 to a maximal value, which was comparable to that of adult fed rats. The high lipogenic capacity lasted throughout the remaining suckling period. When ketogenesis was inhibited by 4-pentenoic acid, the rate of synthesis of complex lipids did not increase despite an increase in unutilized fatty acids. During the mid-suckling period, approximately equal amounts of [1-14C] palmitate were utilized for the synthesis of ketone plus CO2 and for complex lipid synthesis. By contrast, in adult fed rats, the incorporation of fatty acids into complex lipids was four times higher than that of ketone plus CO2. These observations suggest that stimulated hepatic ketogenesis in suckling rats results from the rapid oxidation of fatty acids and consequent increased production of acetyl CoA, but not from impaired capacity for synthesis of complex lipids.