Role of dexamethasone and insulin on the development of the five urea-cycle enzymes in cultured rat foetal hepatocytes

Urea

Urea is generated by the urea cycle enzymes, which are mainly in the liver but are also ubiquitously expressed at low levels in other tissues. The metabolic process is altered in several conditions such as by diets, hormones, and diseases. Urea is then eliminated through fluids, especially urine. Blood urea nitrogen (BUN) has been utilized to evaluate renal function for decades. New roles for urea in the urinary system, circulation system, respiratory system, digestive system, nervous system, etc., were reported lately, which suggests clinical significance of urea.

Argininosuccinate synthetase from the urea cycle to the citrulline-NO cycle

Argininosuccinate synthetase (ASS, EC 6.3.4.5) catalyses the condensation of citrulline and aspartate to form argininosuccinate, the immediate precursor of arginine. First identified in the liver as the limiting enzyme of the urea cycle, ASS is now recognized as a ubiquitous enzyme in mammalian tissues. Indeed, discovery of the citrulline-NO cycle has increased interest in this enzyme that was found to represent a potential limiting step in NO synthesis. Depending on arginine utilization, location and regulation of ASS are quite different. In the liver, where arginine is hydrolyzed to form urea and ornithine, the ASS gene is highly expressed, and hormones and nutrients constitute the major regulating factors: (a) glucocorticoids, glucagon and insulin, particularly, control the expression of this gene both during development and adult life; (b) dietary protein intake stimulates ASS gene expression, with a particular efficiency of specific amino acids like glutamine. In contrast, in NO-producing cells, where arginine is the direct substrate in the NO synthesis, ASS gene is expressed at a low level and in this way, proinflammatory signals constitute the main factors of regulation of the gene expression. In most cases, regulation of ASS gene expression is exerted at a transcriptional level, but molecular mechanisms are still poorly understood.

Regulation of argininosuccinate synthetase mRNA level in rat foetal hepatocytes

Expression of the hepatic gene for argininosuccinate synthase (ASS), one of the key enzymes of the urea cycle, was analysed during the perinatal period in the rat. To this end, the amount of specific mRNA was measured in the liver at various stages of development and in cultured foetal hepatocytes maintained in different hormonal conditions. The ASS mRNA was first detected in 15.5-day foetuses and its level increased concomitantly with a rise in the enzyme activity, suggesting that the appearance of the ASS activity reflects the turning on of specific gene transcription. This was demonstrated by run-on assay which showed an enhanced rate of transcription of the ASS gene during the perinatal period. When foetal hepatocytes were cultured with dexamethasone, a dose-dependent increase in ASS mRNA was measured, which was completely abolished by actinomycin D addition. The transcription rate of the gene was increased about twofold in the presence of the steroid, as measured by nuclear run-on assay. This transcriptional action could additionally require a protein factor since it could be inhibited by the simultaneous addition of puromycin. Insulin or glucagon respectively repressed or enhanced the dexamethasone-induced accumulation of ASS mRNA when added simultaneously with the steroid for 24 h. This developmental regulation of the ASS mRNA by glucocorticoids, insulin and glucagon could account for the modulation of the enzyme activity previously observed in vivo and in vitro in the foetal liver.

Regulation of argininosuccinate synthetase level by corticosteroid and pancreatic hormones during perinatal period

The urea cycle takes place in the hepatocyte of ureothelic animals. The conversion of ammonia into urea involves five reactions. The first 2 take place in the matrix of the mitochondria, the last 2 occur in the cytosol. Argininosuccinate synthetase (AS) is the third reaction of the urea cycle. It catalyses the condensation of citrulline and aspartate into argininosuccinate. We have previously reported that rat AS activity was present in the cytosol and the outer membrane of the mitochondria. We have shown that, at the activity level, the colocation of AS was changing during fetal and neonatal development and was under the control of corticosteroid and pancreatic hormones. However, an unresolved issue was whether both AS had the same specific activity and that their location was changing during ontogenesis or that the specific activities of mitochondrial and cytosolic enzymes were different and/or modified during this period. In the present report, we compared the compartmentalization of AS activity and protein level in the fetus, the new-born and the adult rat and the role of corticosteroid and pancreatic hormones. Specific activities of both AS remained unchanged during ontogenesis. Glucocorticoids induced an increase in mitochondrial AS while glucagon appeared to induce a concomitant decrease in the level of mitochondrial AS and an increase in cytosolic AS.

Intestinal arginine metabolism during development. Evidence for de novo synthesis of L-arginine in newborn pig enterocytes

The capacity for L-arginine metabolism was studied in villus enterocytes isolated from pigs at birth, after 2-8 days suckling and after weaning. Immediately after birth, enterocytes were able to convert 1 mM L-citrulline, 2 mM L-glutamine or 1 mM L-ornithine to L-arginine. In 2-8-day-old animals, the net production of L-arginine from L-citrulline (2.00 +/- 0.45 nmol x 10(6) cells-1 x 30 min-1), or from L-ornithine (0.29 +/- 0.06 nmol x 10(6) cells-1 x 30 min-1) was similar to the values obtained at birth. Furthermore, 40% of L-arginine synthetized de novo from L-citrulline were released into the incubation medium. In 2-8-day-old animals, the production of L-arginine from L-glutamine represented only 5% of the production at birth (the latter being 0.73 +/- 0.15 nmol x 10(6) cells-1 x 30 min-1). In enterocytes isolated from post-weaned pigs, no significant production of L-arginine from either L-glutamine or L-ornithine was detected. In contrast, although the L-arginine production from L-citrulline was very low in post-weaned animals, it was significantly enhanced in the presence of L-glutamine, representing 23% of the production measured in suckling animals. The capacity of enterocytes to cleave L-arginine to L-ornithine and urea was very limited at birth, but was increased more than threefold in 2-day-old animals. This was concomitant with a marked increase in arginase activity. In post-weaned animals, the flux through arginase in intact enterocytes, and the arginase activity were both threefold higher than in 2-8-day-old animals. It is concluded that enterocytes isolated from neonatal pigs exhibit the capacity for a net production of L-arginine since the metabolism of this amino acid is oriented to anabolism rather than catabolism. The results are discussed in relation to L-arginine metabolism in the neonatal liver.

Expression of argininosuccinate lyase mRNA in foetal hepatocytes. Regulation by glucocorticoids and insulin

Argininosuccinate lyase (ASL), the fourth enzyme of the urea cycle, belongs to a group of liver enzymes appearing in the late foetal period in the rat. Several hormones, including glucocorticosteroids and insulin have been implicated in the control of the development of this enzyme activity. In this study, the cloned cDNA was used to measure the relative abundance of ASL mRNA in the livers of rats at various stages of perinatal development and in cultured foetal hepatocytes during hormonal manipulations. The ASL mRNA was first detectable on day 15.5 of gestation and increased in amount concomitantly with the rise in the enzyme activity, suggesting that the appearance of enzyme activity reflects the turning on of specific gene transcription. When foetal hepatocytes were exposed to dexamethasone, an increase in ASL mRNA was detected, which was completely abolished by addition of actinomycin D, suggesting a transcriptional effect of the steroid. In contrast, administration of cortisol to foetuses in utero had no effect on the mRNA level, suggesting that the steroid action is inhibited in the intra-uterine environment. Insulin might be the inhibiting factor since it completely repressed the dexamethasone-induced accumulation of ASL mRNA in foetal hepatocytes. These data were confirmed in vivo by experiments using streptozotocin, which produces insulin-depleted foetuses and causes the accumulation of ASL mRNA. This regulation of ASL mRNA by glucocorticoids and insulin could account for the modulation of the enzyme activity observed in vivo and in vitro.

Protein degradation in cultured fetal hepatocytes. Absence of an inhibitory effect of insulin

The role of insulin to regulate protein turnover in fetal liver was investigated using primary cultures of fetal-rat hepatocytes. The basal rate of protein degradation (in the presence of insulin and amino acids) was the same in cultured fetal and adult hepatocytes (2.48 +/- 0.16 versus 2.46 +/- 0.06% of total protein degraded/h respectively). Incubation of cells in an unsupplemented media (without insulin or amino acids) resulted in a deprivation-induced increase in degradation in cells from both groups (P less than 0.05). Rates of proteolysis could be returned to their respective basal values by the addition of amino acids at 5 times their normal plasma concentrations. In adult cells, addition of insulin alone significantly inhibited protein degradation (P less than 0.05), whereas, in contrast, insulin was without effect on protein degradation in fetal hepatocytes. Both fetal and adults cells responded to dibutyryl cyclic AMP with an increase in protein degradation above that seen in the no-additions group. Results of experiments in which the effect of inhibitors of protein degradation (chloroquine, NH4Cl, amino acids and dinitrophenol) were tested suggested that lysosomes were responsible for 20-30% of total protein degradation in fetal hepatocytes. Impaired insulin processing in fetal hepatocytes was examined as a possible cause of the insulin-resistance in these cells. As determined by h.p.l.c. analysis, the same pattern of initial degradation products of insulin was found in fetal hepatocytes as had previously been found in adult hepatocytes. Incubation of cells with various doses of chloroquine resulted in an increase in cell-associated 125I-insulin and a decrease in insulin degradation in both fetal and adult cells. At the highest dose of chloroquine tested (500 microM), a slightly greater increase in insulin binding and a decrease in insulin degradation were observed in fetal cells as compared with adult cells. Rates of insulin internalization were also compared between fetal and adult cells. A 30% slower rate of insulin internalization was observed in fetal cells, as compared with adult cells. It was concluded that the absence of an effect of insulin on protein degradation in fetal hepatocytes is not the result of a major difference in insulin internalization and processing between fetal and adult hepatocytes.

Normalization of enhanced hepatic gluconeogenesis by the antiglucocorticoid RU 38486 in acutely uraemic rats

Hepatic amino acid uptake, urea and glucose production are increased in acute uraemia. It has been shown that this metabolic pattern is mediated by glucocorticoids. Accordingly, the administration of the antiglucocorticoid RU 38486 to acutely uraemic rats resulted in a reduction of serum urea-N and glucose levels. To clarify whether this effect is due to a reduction in hepatic gluconeogenesis we examined the effect of the antiglucocorticoid RU 38486 on urea and glucose formation in isolated hepatocytes from sham-operated (SHAM) and bilaterally nephrectomized (BNX) rats receiving RU 38486 or the vehicle only. Hepatic glucose production in BNX rats was considerably increased from Na-pyruvate (+79%), alanine (+174%), glutamine (+158%), and serine (+87%) compared with SHAM animals. Concomitantly, hepatic urea formation was also enhanced from amino acid substrates in acutely uraemic rats. When uraemic animals were treated with RU 38486, glucose production from amino acids and Na-pyruvate was reduced to the range of SHAM animals or even lower. This effect could not be demonstrated in SHAM-operated controls. A comparable decrement in hepatic urea production was observed in BNX rats treated with the antiglucocorticoid. Thus, glucocorticoids appear to play a key role in the abnormal hepatic urea and glucose production of acutely uraemic rats.

Comparison of biochemical properties of liver arginase from streptozocin-induced diabetic and control mice

Arginase activity is elevated in livers of diabetic animals compared to controls and there is evidence that this is due in part to increased specific activity (activity/mg arginase protein). To investigate the molecular basis of this increased activity, the physicochemical and kinetic properties of hepatic arginase from diabetic and control mice were compared. Two types of arginase subunits with molecular weights of 35,000 and 38,000 were found in both the diabetic and control animals and the subunits in these animals had similar, multiple ionic forms. Kinetic parameters of purified preparations of arginase for arginine (apparent Km and Vmax values) and the thermal stability of these preparations from diabetics and controls were also similar. Furthermore, no difference was found in the distribution of arginase activity among different subcellular liver fractions. Separation of basic and acidic oligomeric forms of arginase by fast-protein liquid chromatography resulted in a slightly different distribution of activity among the forms in the normal and diabetic group. The apparent Km values for Mn2+ of the basic form of the enzyme were 25 and 33 microM for the enzyme from normal and diabetic animals, respectively; for acidic forms, for which two apparent Km values were measured, the values were 8 and 197 microM for arginase from controls and 35 and 537 microM from diabetics. These results indicate that in diabetes, while no marked changes in the physicochemical characteristics of arginase are obvious, some changes are found in the interaction of arginase with its cofactor Mn.

Glucocorticoid and developmental regulation of amylase mRNAs in mouse liver cells

We characterized alpha-amylase expression in the hepatoma cell line Hepa 1-6 and in normal mouse liver. Both Amy-1 and Amy-2 were expressed in Hepa 1-6 and were regulated by glucocorticoids. Transcription in the hepatoma cells was initiated at the same start sites as in mouse tissues. Glucocorticoid treatment increased the abundance of Amy-1 and Amy-2 transcripts by 10 to 20-fold. This increase was detected within 4 h and was maximal by 24 h. The pattern of amylase expression in this hepatoma cell line accurately reflects amylase expression in the liver in vivo. During liver development, we observed a large increase in the abundance of Amy-1 transcripts just before birth, at a time when circulating glucocorticoids are also elevated. Adult mouse liver expressed Amy-1 and Amy-2 at levels comparable to those of fully induced hepatoma cells. Liver is thus a likely source of both amylase isozymes in mouse serum. These studies demonstrate that Amy-2 expression is not limited to the pancreas but also occurs at a low level in liver cells.

Glucocorticoid and developmental regulation of amylase mRNAs in mouse liver cells

We characterized alpha-amylase expression in the hepatoma cell line Hepa 1-6 and in normal mouse liver. Both Amy-1 and Amy-2 were expressed in Hepa 1-6 and were regulated by glucocorticoids. Transcription in the hepatoma cells was initiated at the same start sites as in mouse tissues. Glucocorticoid treatment increased the abundance of Amy-1 and Amy-2 transcripts by 10 to 20-fold. This increase was detected within 4 h and was maximal by 24 h. The pattern of amylase expression in this hepatoma cell line accurately reflects amylase expression in the liver in vivo. During liver development, we observed a large increase in the abundance of Amy-1 transcripts just before birth, at a time when circulating glucocorticoids are also elevated. Adult mouse liver expressed Amy-1 and Amy-2 at levels comparable to those of fully induced hepatoma cells. Liver is thus a likely source of both amylase isozymes in mouse serum. These studies demonstrate that Amy-2 expression is not limited to the pancreas but also occurs at a low level in liver cells.

Multiple molecular forms of mouse liver arginase

Hepatic arginase (L-arginine amidinohydrolase, EC 3.5.3.1) is an oligomer composed of three or four subunits. The present studies indicate heterogeneity in the size and charge of arginase subunits in mouse liver. Two types of arginase subunits with molecular weights of approximately 35,000 and 38,000 have been found. These two subunits are detected in liver cytosol or in purified preparations of arginase after sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and Western blotting. Two dimensional SDS-PAGE revealed multiple ionic forms of arginase for both the 35,000 and 38,000 subunits; the subunits contain basic proteins (pI range 7.8-9.1) and acidic proteins (pI range 5.8-6.4). Limited proteolysis by trypsin eliminated the molecular weight differences between the subunits without substantially affecting either their isoelectric points or activity. Comparative peptide maps and amino acid analyses of the 35,000- and 38,000-Da subunits showed that they were very similar. The data indicate that a neutral peptide (approx 3000 Da) is responsible for the differences in subunit molecular weight and that the multiple sized and charged forms are variants of the same protein.

Induction of the five urea-cycle enzymes by glucagon in cultured foetal rat hepatocytes

Foetal hepatocytes obtained from rats at different stages were cultured in order to investigate the inducibility of the five urea-cycle enzymes by glucagon and dibutyryl cyclic AMP (Bt2cAMP). When 18.5-day-old hepatocytes were cultured for 3 days with 10(-7) M glucagon, the activities of carbamoyl phosphate synthetase (CPS), argininosuccinase (ASL) and arginase were increased by 1.4-, 1.8- and 1.9-fold, respectively, as compared to controls. These effects were mimicked by 10(-4) M Bt2cAMP, but the activities of ornithine transcarbamylase (OTC) and argininosuccinate synthetase (ASS) were never changed by the addition of these compounds. Hepatocytes cultured at earlier stages were not responsive to glucagon unless dexamethasone was added simultaneously, suggesting that this steroid might induce some steps necessary for glucagon action. Bt2cAMP was effective as early as day 16.5 without requiring the presence of steroids. In addition, the effect of the cyclic nucleotide appeared additive or synergistic with that of dexamethasone. The simultaneous addition of actinomycin D did not affect the glucagon-induced increase in enzyme levels, thus suggesting a post-transcriptional effect of the hormone on the foetal enzyme activities. Insulin itself did not have any effect on the basal level of the enzyme activities and had only a moderate inhibitory effect on glucagon-induced ASL activity. This slight effect of insulin is in contrast with the marked inhibitory effect of dexamethasone on this enzyme activity that we described previously.

Direct analysis of growth factor requirements for isolated human fetal hepatocytes

Hepatocytes were isolated from human fetal liver in order to analyze the direct effects of growth factors and hormones on human hepatocyte proliferation and function. Mechanical fragmentation and then dissociation of fetal liver tissue with a collagenase/dispase mixture resulted in high yield and viability of hepatocytes. Hepatocytes were selected in arginine-free, ornithine-supplemented medium and defined by morphology, albumin production and ornithine uptake into cellular protein. A screen of over twenty growth factors, hormones, mitogenic agents and crude organ and cell extracts for effect on the stimulation of hepatocyte growth revealed that EGF, insulin, dexamethasone, and factors concentrated in bovine neural extract and hepatoma cell-conditioned medium supported attachment, maintenance and growth of hepatocytes on a collagen-coated substratum. The population of cells selected and defined as differentiated hepatocytes had a proliferative potential of about 4 cumulative population doublings. EGF and insulin synergistically stimulated DNA synthesis in the absence of other hormones and growth factors. Although neural extracts enhanced hepatocyte number, no effect on DNA synthesis of neural extracts or purified heparin-binding growth factors from neural extracts could be demonstrated in the absence or presence of defined hormones, hepatoma-conditioned medium or serum. Hepatoma cell-conditioned medium had the largest impact on both hepatocyte cell number and DNA synthesis under all conditions. Dialyzed serum protein (1 mg/ml) at 10 times higher protein concentration had a similar effect to hepatoma cell-conditioned medium (100 micrograms/ml). The results suggest that hepatoma cell conditioned medium may be a concentrated and less complicated source than serum for purification and characterization of additional normal hepatocyte growth factors.

Long-term maintenance of monoxygenase activities in cultured fetal rat hepatocytes

Fetal hepatocytes cultured in the presence of dexamethasone even in low concentration were maintained alive for several weeks. The expression of monoxygenase in these cells is switched from fetal to adult type. Their aldrin epoxidase and ethoxycoumarin-o-de-ethylase activities were maintained at a high level. Cytochrome P-450 concentration remains stable in these cells throughout the culture period. Cell-cell and cell-biomatrix interactions seem to play an important role in the control of growth, maturation and enzymatic activity expression of the cells in culture. This model may constitute an interesting approach for the study of drug metabolism and drug toxicity in vitro.

Some aspects of amino acid metabolism in the rat fetus

1. In spite of an eventual catabolic phase during the last third of pregnancy, nitrogen retention seems to increase in pregnant rats. Furthermore, the high uterine blood flow and the high placental transfer of amino acids maintains an adequate nutrient supply to the fetuses. 2. The terminal rat fetus has a high circulating plasma amino acid level, as well as an increased free amino acid tissue pool when compared to its mother's. 3. In the rat fetus the development of enzymatic capabilities shows a sudden emergence (also denomined clustering) in late fetal life. In a general trend, the activities of enzymes related with amino acid metabolism are not well developed during rat fetal life. 4. The rate of amino nitrogen excretion in rat fetus is low, mainly due to the low development of urea cycle enzyme activities. 5. The rates of protein synthesis in many tissues are high in the rat fetus and they show a progressive decrease until delivery. On the other hand, the rates of protein breakdown are also higher during fetal life than in the adult.