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.     

Hyperpolarization of the liver cell membrane by palmitate as affected by glucose and lactate: implications for control of feeding

Since the membrane potential of liver cells being in contact with vagal afferents has been proposed to represent a major signal in metabolic control of food intake, we investigated the effect of palmitate, glucose and lactate on the membrane potential of hepatocytes with microelectrodes using superfused mouse liver slices. The mice used for the experiments were fed a fat-enriched diet (18% fat). Palmitate (0.5 mM) hyperpolarized the membrane of hepatocytes by 3-4 mV, and this hyperpolarization was not affected by 5-10 mM glucose and 0.5-1 mM lactate. Glucose alone did not influence the potential, even when mice fed a high carbohydrate diet were employed. At lactate concentrations > or = 2 mM the palmitate induced hyperpolarization was eliminated and 5 mM lactate or pyruvate alone hyperpolarized the liver cell membrane. Similar to the palmitate induced hyperpolarization, the lactate induced hyperpolarization was prevented by the K-channel blocker TEA, suggesting that activation of K channels is involved in the hyperpolarization. The results show that physiological concentrations of glucose and lactate do not affect the hyperpolarization of the liver cell membrane due to fatty acid oxidation. The implications of these findings with regard to control of food intake by fatty acid oxidation and lactate metabolism are discussed. The observations are consistent with a signal function of the hepatic membrane potential in physiological control of food intake by fatty acid oxidation. Hepatic lactate metabolism at supraphysiological lactate concentrations may also produce a satiety signal coded by the hepatic membrane potential.     

Mice lacking serum paraoxonase are susceptible to organophosphate toxicity and atherosclerosis

Serum paraoxonase (PON1) is an esterase that is associated with high-density lipoproteins (HDLs) in the plasma; it is involved in the detoxification of organophosphate insecticides such as parathion and chlorpyrifos. PON1 may also confer protection against coronary artery disease by destroying pro-inflammatory oxidized lipids present in oxidized low-density lipoproteins (LDLs). To study the role of PON1 in vivo, we created PON1-knockout mice by gene targeting. Compared with their wild-type littermates, PON1-deficient mice were extremely sensitive to the toxic effects of chlorpyrifos oxon, the activated form of chlorpyrifos, and were more sensitive to chlorpyrifos itself. HDLs isolated from PON1-deficient mice were unable to prevent LDL oxidation in a co-cultured cell model of the artery wall, and both HDLs and LDLs isolated from PON1-knockout mice were more susceptible to oxidation by co-cultured cells than the lipoproteins from wild-type littermates. When fed on a high-fat, high-cholesterol diet, PON1-null mice were more susceptible to atherosclerosis than their wild-type littermates.     

Dietary lipid and postnatal development. I. A model for neonatal studies requiring high and low fat diets from birth

As a prerequisite to a biochemical investigation into the role of dietary lipids in regulating perinatal fatty acid metabolism, we developed and evaluated a model in which the amount of lipid in the diet can be easily controlled from birth to at least 10 days of age. Neonatal rabbits were fed purified equicaloric diets in which lipid supplied either 14.2% or 77.6% of the total calories. Mortality due to all causes was about 40% in both groups. Some differences in physical development between the two groups were noted. Animals receiving the smaller amount of lipid (LF group) gained weight to 150% birth weight day 10, whereas the group receiving the larger amoung of lipid (HF group) did not gain. In addition, the HF group had lower body temperatures, smaller liver and kidney weights, and greater brain weights relative to body weight. These differences are discussed in relation to the composition of the HF and LF diets. The model promises to provide a direct approach to a more precise evaluation of varied dietary regimens in the neonatal period. In particular, the model lends itself to studies relating diet to developing biochemical functions. In an accompanying paper, we report the results of an investigation comparing fatty acid oxidation in heart and liver of neonates fed the HF and LF diets described here.     

Expression of adhesion molecules on endothelial cells after contact with knitted Dacron

Glutamine synthetase and carbamoylphosphate synthetase I expression was examined immunohistochemically in livers of spf-ash homozygous and hemizygous mice, in which one of the urea cycle enzymes (ornithine carbamoyltransferase) is deficient and hyperammonemic disorders are obvious. In the mutant adult mouse liver, only hepatocytes lining central veins expressed glutamine synthetase. In contrast, other hepatocytes expressed carbamoylphosphate synthetase I but not glutamine synthetase. This complementary expression pattern is similar to that seen in wild-type mouse liver. In the liver of mutant young mice, which showed severe retarded growth and abnormal hair and skin development, the developmental expression pattern of both enzymes was also similar to that of the corresponding wild-type liver. However, suppression of carbamoylphosphate synthetase I expression in the pericentral hepatocytes occurred later in the mutant than in wild-type liver. These results show that high plasma concentrations of ammonium ions, which are one of the substrates for both the enzymes, do not change their complementary expression. Instead they support the idea that factor(s) associated with central veins rather than humoral factors direct pericentral hepatocytes to express glutamine synthetase and to suppress carbamoylphosphate synthetase I expression.     

In vitro inhibition of carnitine acyltransferase activity in mitochondria from rat and mouse liver by a diethylhexylphthalate metabolite

The effects of mono(2-ethyl-5-oxohexyl)phthalate [ME(O)HP], a di(2-ethylhexyl)phthalate (DEHP) metabolite and a potent peroxisomal inducer, on the mitochondrial beta-oxidation were investigated. In isolated rat hepatocytes, ME(O)HP inhibited long chain fatty acid oxidation and had no effect on the ketogenesis of short chain fatty acids, suggesting that the inhibition occurred at the site of carnitine-dependent transport across the mitochondrial inner membrane. In rat liver mitochondria, ME(O)HP inhibited carnitine acyltransferase I (CAT I; EC 2.3.1.21) competitively with the substrates palmitoyl-CoA and octanoyl-CoA. An analogous treatment of mouse mitochondria produced a similar competitive inhibition of palmitoyl-CoA transport whereas ME(O)HP exposure with guinea pig and human liver mitochondria revealed little or no effect. The addition of clofibric acid, nafenopin or methylclofenopate revealed no direct effects upon CAT I activity. Inhibition of transferase activity by ME(O)HP was reversed in mitochondria which had been solubilized with octyl glucoside to expose the latent form of carnitine acyltransferase (CAT II), suggesting that the inhibition was specific for CAT I. Our results demonstrate that in vitro ME(O)HP inhibits fatty acid oxidation in rat liver at the site of transport across the mitochondrial inner membrane with a marked species difference and support the idea that induction of peroxisome proliferation could be due to an initial biochemical lesion of the fatty acid metabolism.     

The role of malonyl-coa in the coordination of fatty acid synthesis and oxidation in isolated rat hepatocytes

Fatty acid synthesis and fatty acid oxidation were examined in rat hepatocytes under a variety of experimental conditions. In cells from fed animals, glucagon acutely switched the direction of fatty acid metabolism from synthesis to oxidation. Addition of lactate plus pyruvate had the opposite effect. The inhibitory action of glucagon on fatty acid synthesis and its stimulatory effect on fatty acid oxidation were largely, but not completely, offset by the simultaneous addition of lactate plus pyruvate. Changes in cellular citrate and malonyl-CoA levels indicated that glucagon exerted its inhibitory effect on fatty acid synthesis at two levels: (i) blockade of glycolysis; and (ii) partial inhibition of a more distal step, probably acetyl-CoA carboxylase. Under all conditions, fatty acid oxidation was related in a linear and reciprocal fashion to the rate of fatty acid synthesis and the tissue malonyl-CoA content. The latter fluctuated through a range of 1 to 6 nmol per g wet weight of cells. Since malonyl-CoA inhibits carnitine acyltransferase I of liver mitochondria with a Ki in the region of 1 to 2 micron, the present studies support the concept that this compound plays a pivotal role in the coordination of hepatic fatty acid synthesis and oxidation. The ketogenic effect of glucagon on liver appears to be manifested in large part through the ability of the hormone to reduce the tissue malonyl-CoA concentration.     

The liver in transforming growth factor-Beta-1 (TGF-beta 1) null mutant mice

Transforming growth factor-beta-1 (TGF-beta 1) null mutant mice have no gross developmental abnormalities at birth but succumb to multifocal inflammatory lesions that lead to organ failure and death about 20 days after birth. Treatment with anti-inflammatory and immune suppressive agents, such as rapamycin, reduces the severity and extent of inflammatory infiltrates in the liver and can prolong the life of knockout (KO) mice compared to untreated null mice. To determine whether there is an associated hepatic phenotype, livers of "young" (< 3 weeks), "old" (> 3 weeks), and age-matched wild-type (WT) mice were studied using light and electronmicroscopy. On light microscopy, old KO mice had foci of mononuclear cells in liver parenchyma in addition to scattered foci of megalocytosis. Intracytoplasmic vacuoles, some of which were juxtanuclear in location, were also seen but these were most prominent in the oldest (10 weeks) rapamycin-treated mouse. In the untreated young KO mice, there were only foci of mononuclear cells in the liver parenchyma and portal tracts and variable numbers of binucleated hepatocytes. Ultrastructurally, there was a significant increase in the number of mitochondria in livers of the old KO mice, when compared either to the age-matched wild-type or to the young KO mice (p > .001). Hepatocytes from all KO mice showed increased numbers of hypertrophied or enlarged Golgi complexes compared to age-matched wild-type mice. Intracytoplasmic canaliculi lined with microvilli were seen in livers of old KO mice, but were absent in the young KO and wild-type mice. Primary cultures of hepatocytes, derived from livers of both young and old KO mice, showed similar changes on phase contrast and electronmicroscopy. These included juxtanuclear vacuoles, intracytoplasmic canaliculi, enlarged Golgi vesicles, and increased numbers of autolysosomes. Phenotypic abnormalities of mitochondria were either minimal or absent in cultured KO hepatocytes. The findings demonstrate, for the first time, that targeted disruption of the TGF-beta 1 gene in mice results in an altered ultrastructural phenotype of hepatocytes. The data suggest that TGF-beta 1 may be required for normal development and regulation of subcellular organelles in hepatocytes and may be essential for physiological functions involving mitochondria and Golgi complex.     

Suppression of glycolysis is associated with an increase in glucose cycling in hepatocytes from diabetic rats

Rates of cycling between glucose and glucose 6-phosphate and between glucose and pyruvate, and the effects of these cycles on glucose metabolism, were compared in hepatocytes isolated from fasted normal or streptozotocin-induced diabetic rats. In diabetic hepatocytes the rate of glucose phosphorylation was 30% lower than that in normal hepatocytes, and there was a doubling of the rate of glucose/glucose 6-phosphate cycling. In addition, the rate of glycolysis was 60% lower in diabetic hepatocytes. This inhibition of glycolysis and stimulation of glucose/glucose 6-phosphate cycling appeared to be a consequence of the elevated rates of endogenous fatty acid oxidation observed in diabetic hepatocytes. The proportion of glycolytically derived pyruvate that was recycled to glucose was more than doubled in hepatocytes from diabetic rats compared with normal animals. This increase also appeared to be linked to the high rates of endogenous fatty acid oxidation in diabetic cells. As a consequence of the increased rates of both these cycles, 85% of all glucose molecules taken up by diabetic hepatocytes were recycled to glucose, compared with only 50% in normal hepatocytes. Glucose cycling is therefore likely to make a substantial contribution to the hyperglycemia of diabetes.     

Dolichol-mediated enhanced protein N-glycosylation in experimental diabetes--a possible additional deleterious effect of hyperglycemia

The role of estrogen and the estrogen receptor (ER) in the induction and promotion of tumors was investigated by using transgenic MT-mER mice, which overexpress the ER. It was hypothesized that because of this abnormal expression of the ER, the reproductive-tract tissues of the MT-mER mice may be more susceptible to tumors after neonatal exposure to the potent synthetic estrogen diethylstilbestrol (DES). Normally non-estrogen responsive tissues that may have expressed ER as a result of the transgene were also studied for DES-induced tumors. Wild-type and MT-mER littermates were treated with 2 micrograms/pup/d DES 1-5 d after birth and then killed at 4, 8, 12, and 18 mo of age. The DES-treated MT-mER mice demonstrated a significantly higher incidence of uterine adenocarcinoma at 8 mo (73%) than the DES-treated wild-type mice (46%). The tumors of the MT-mER mice were often more aggressive than those in the wild-type animals. These tumors were also preceeded at 4 mo by a significantly higher incidence of the preneoplastic lesion atypical hyperplasia in the MT-mER mice (26% compared with 0% in the wild-type mice). Other DES-induced abnormalities were observed at equal rates in the wild-type and MT-mER mice. Although no tumors were observed in untreated wild-type females, a single untreated MT-mER female had uterine adenocarcinoma at 18 mo. These data indicate that the level of ER present in a tissue may also be a determining factor in development of estrogen-responsive tumors.     

Uncoupling of obesity from insulin resistance through a targeted mutation in aP2, the adipocyte fatty acid binding protein

Fatty acid binding proteins (FABPs) are small cytoplasmic proteins that are expressed in a highly tissue-specific manner and bind to fatty acids such as oleic and retinoic acid. Mice with a null mutation in aP2, the gene encoding the adipocyte FABP, were developmentally and metabolically normal. The aP2-deficient mice developed dietary obesity but, unlike control mice, they did not develop insulin resistance or diabetes. Also unlike their obese wild-type counterparts, obese aP2-/- animals failed to express in adipose tissue tumor necrosis factor-alpha (TNF-alpha), a molecule implicated in obesity-related insulin resistance. These results indicate that aP2 is central to the pathway that links obesity to insulin resistance, possibly by linking fatty acid metabolism to expression of TNF-alpha.     

Altered differentiation of hepatocytes in a transgenic mouse model of hepatocarcinogenesis

Transgenic mice carrying the SV40 T antigen (TAg) gene, which develop hepatocellular and biliary cell tumors by 4 mo of age, show ductular structures in the neonatal liver. Coexpression of c-myc with TAg increases the extent and persistence of ductular lesions and also accelerates tumor development. To analyze possible links between altered gene expression and cell differentiation and to determine the relationship between the ductular structures and tumor development in these mice, ductular cells in single (TAg) and bitransgenic (TAg x c-myc) mice were characterized for biliary and hepatocellular differentiation, transgene expression, and proliferation activity. The results show that the ductular cells in these transgenic mice have characteristics of biliary cells, including basement membrane formation, positive laminin staining, and bile duct-specific lectin (Dolichos biflorus agglutinin and peanut agglutinin) binding, and characteristics of hepatocytes, including albumin expression and ultrastructural features such as round nuclei with 1 or 2 nucleoli and well-developed cytoplasmic organelles. However, differences in transgene expression and cell proliferation between the ductular cells and nonductular hepatocytes were not apparent. Thus, the ductular cells could not be defined as tumor progenitor cells in these mouse livers. However, this model suggests that manipulation of gene expression can alter differentiation of hepatic parenchymal cells.     

Expression of putative fatty acid transporter genes are regulated by peroxisome proliferator-activated receptor alpha and gamma activators in a tissue- and inducer-specific manner

Regulation of gene expression of three putative long-chain fatty acid transport proteins, fatty acid translocase (FAT), mitochondrial aspartate aminotransferase (mAspAT), and fatty acid transport protein (FATP), by drugs that activate peroxisome proliferator-activated receptor (PPAR) alpha and gamma were studied using normal and obese mice and rat hepatoma cells. FAT mRNA was induced in liver and intestine of normal mice and in hepatoma cells to various extents only by PPARalpha-activating drugs. FATP mRNA was similarly induced in liver, but to a lesser extent in intestine. The induction time course in the liver was slower for FAT and FATP mRNA than that of an mRNA encoding a peroxisomal enzyme. An obligatory role of PPARalpha in hepatic FAT and FATP induction was demonstrated, since an increase in these mRNAs was not observed in PPARalpha-null mice. Levels of mAspAT mRNA were higher in liver and intestine of mice treated with peroxisome proliferators, while levels in hepatoma cells were similar regardless of treatment. In white adipose tissue of KKAy obese mice, thiazolidinedione PPARgamma activators (pioglitazone and troglitazone) induced FAT and FATP more efficiently than the PPARalpha activator, clofibrate. This effect was absent in brown adipose tissue. Under the same conditions, levels of mAspAT mRNA did not change significantly in these tissues. In conclusion, tissue-specific expression of FAT and FATP genes involves both PPARalpha and -gamma. Our data suggest that among the three putative long-chain fatty acid transporters, FAT and FATP appear to have physiological roles. Thus, peroxisome proliferators not only influence the metabolism of intracellular fatty acids but also cellular uptake, which is likely to be an important regulatory step in lipid homeostasis.     

Early modulation of genes encoding peroxisomal and mitochondrial beta-oxidation enzymes by 3-thia fatty acids

The aim of the present study was to elucidate the effects of a single dose of 3-thia fatty acids (tetradecylthioacetic acid and 3-thiadicarboxylic acid) over a 24-hr study period on the expression of genes related to peroxisomal and mitochondrial beta-oxidation in liver of rats. The plasma triglyceride level decreased at 2-4 hr, 4-8 hr, and 8-24 hr, respectively, after a single dose of 150, 300, or 500 mg of 3-thia fatty acids/kg body weight. Four to eight hours after administration of 3-thia fatty acids, a several-fold-induced gene expression of peroxisomal multifunctional protein, fatty acyl-CoA oxidase (EC 1.3.3.6), fatty acid binding protein, and 2,4-dienoyl-CoA reductase (EC 1.3.1.43) resulted, concomitant with increased activity of 2,4-dienoyl-CoA reductase and fatty acyl-CoA oxidase. The expression of carnitine palmitoyltransferase-I and carnitine palmitoyltransferase-II increased at 2 and 4 hr, respectively, although at a smaller scale. In cultured hepatocytes, 3-thia fatty acids stimulated fatty acid oxidation after 4 hr, and this was both L-carnitine- and L-aminocarnitine-sensitive. The hepatic content of eicosapentaenoic acid and docosahexaenoic acid decreased throughout the study period. In contrast, the hepatic content of oleic acid tended to increase after 24 hr and was significantly increased after repeated administration of 3-thia fatty acids. Similarly, the expression of delta9-desaturase was unchanged during the 24-hr study, but increased after feeding for 5 days. To conclude, carnitine palmitoyltransferase-I expression seemed to be induced earlier than 2,4-dienoyl-CoA reductase and fatty acid binding protein, and not later than the peroxisomal fatty acyl-CoA oxidase. The expression of delta9-desaturase showed a more delayed response.     

Perinatal expression and inducibility of human CYP3A7 in C57BL/6N transgenic mice

The expression and inducibility of CYP3A7 transgene in the fetus and suckling neonates from one of the transgenic lines (M10) were investigated by Northern and Western blot analyses. The mRNA expression could be detected as early as the 15th embryonic day and increased gradually with advancing gestation but then remarkably so after birth. The protein expression was also detectable postnatally and increased. Inducibility was achieved in neonatal mice via maternal exposure to zinc sulfate. Midazolam hydroxylase activities could be detected in liver microsomes prepared from 14-day-old neonates. These activities were significantly higher in transgenic than nontransgenic lines of mice (p < 0.001).