Regulation of messenger ribonucleic acid levels for five urea cycle enzymes in cultured rat hepatocytes. Requirements for cyclic adenosine monophosphate, glucocorticoids, and ongoing protein synthesis

In adult rat liver, amounts of the urea cycle enzymes are regulated by diet, glucocorticoids, and cAMP. Rat hepatocytes cultured in chemically defined medium were used to precisely define the roles of glucocorticoids and cAMP in regulation of these enzymes at the pretranslational level. With the exception of ornithine transcarbamylase mRNA, cultured rat hepatocytes retain the capacity to express mRNAs for the urea cycle enzymes at the same level observed for liver of intact rats. In the absence of added hormones, mRNAs for argininosuccinate synthetase and argininosuccinate lyase remained at or above normal in vivo levels, while mRNAs for the other three enzymes declined to very low levels. Messenger RNAs for carbamyl phosphate synthetase I, argininosuccinate synthetase, argininosuccinate lyase, and arginase increased in response to either dexamethasone or 8-(4-chlorophenylthio) cAMP (CPT-cAMP). Half-maximal responses occurred at 2-3 nM dexamethasone and at 2-7 microM CPT-cAMP. Cycloheximide abolished the response to dexamethasone but not to CPT-cAMP, suggesting that dexamethasone induced expression of an intermediate gene product required for induction of these mRNAs. The effects of a combination of both hormones were additive for argininosuccinate lyase mRNA and synergistic for carbamyl phosphate synthetase I, argininosuccinate synthetase, and arginase mRNAs. Messenger RNA for ornithine transcarbamylase showed little or no response to any condition tested. Depending on the particular mRNA and hormonal condition tested, increases in mRNA levels ranged from 1.4- to 70-fold above control values.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nutritional and hormonal regulation of mRNA abundance for arginine biosynthetic enzymes in kidney

Argininosuccinate synthetase and argininosuccinate lyase catalyze the synthesis of arginine from citrulline in kidney and also serve as components of the urea cycle in liver of ureotelic animals. Dietary and hormonal regulation of mRNAs encoding these enzymes have been well studied in liver but not in kidney. Messenger RNAs for these enzymes are localized within the renal cortex. Starvation and extreme variations in dietary protein content (0% vs 60% casein) produced 2.6- to 3.5-fold increases in mRNA abundance for these two enzymes in rat kidney. Argininosuccinate lyase mRNA was not induced by dibutyryl cAMP, dexamethasone, or a combination of the two agents. In contrast, argininosuccinate synthetase mRNA was induced 2-fold by dibutyryl cAMP but was unresponsive to dexamethasone. Thus, diet and hormones regulate levels of these mRNAs in rat kidney, but the responses are both qualitatively and quantitatively distinct from the responses previously reported for rat liver.     

Regulation of genes for inducible nitric oxide synthase and urea cycle enzymes in rat liver in endotoxin shock

Arginine is an intermediate of the urea cycle in the liver. It is synthesized by the first four enzymes of the cycle, carbamylphosphate synthetase I, ornithine transcarbamylase, argininosuccinate synthetase, and argininosuccinate lyase, and is hydrolyzed to urea and ornithine by arginase I, forming the cycle. In endotoxemia shock, inducible nitric oxide (NO) synthase (iNOS) is induced in hepatocytes and arginine is utilized for NO production. Regulation of the genes for iNOS and the urea cycle enzymes was studied using lipopolysaccharide (LPS)-treated rat livers. When rats were injected intraperitoneally with LPS, iNOS mRNA was markedly induced. Cationic amino acid transporter-2 and C/EBPbeta mRNAs were also highly increased. In contrast, mRNAs for all the urea cycle enzymes except ornithine transcarbamylase were gradually decreased and reached 16-28% of controls at 12 h. However, all these enzymes remained unchanged at protein level up to 24 h. In light of these results, we suggest that synthesis of urea cycle enzymes is downregulated and that the protein synthetic capacity is directed to synthesis of proteins required for defense against endotoxemia.     

Abundance of mRNAs encoding urea cycle enzymes in fetal and neonatal mouse liver

The relative abundances of mRNAs encoding the five urea cycle enzymes during development of mouse liver have been determined and compared with those of mRNAs encoding four other liver-specific proteins (phosphoenolpyruvate carboxykinase, tyrosine aminotransferase, alpha-fetoprotein, and albumin). Urea cycle enzyme mRNAs in fetal liver are expressed at 2-14% of the abundance in adult liver as early as 6 days before birth. Expression of the urea cycle enzyme mRNAs is not coordinate during the fetal and neonatal period. However, profiles of three urea cycle enzyme mRNAs are quite similar to that of alpha-fetoprotein mRNA, suggesting the possibility of a common response to regulatory signals during fetal development. With the exception of ornithine transcarbamylase mRNA, the urea cycle enzyme mRNAs have been shown previously to be inducible by cAMP and glucocorticoids. However, only argininosuccinate lyase mRNA exhibits any significant change in abundance at birth, resembling postnatal expression of tyrosine aminotransferase mRNA. The results indicate that the urea cycle enzyme mRNAs are potentially useful markers for elucidating various features of hepatocyte differentiation in mammals.     

Expression of arginase II and related enzymes in the rat small intestine and kidney

Arginase, which catalyzes the conversion of arginine to urea and ornithine, and consists of a liver-type (arginase I) and a non-hepatic type (arginase II). Arginine is also used for the synthesis of nitric oxide and creatine phosphate, while ornithine is used for the synthesis of polyamines and proline, and thus collagen. Arginase II mRNA and protein are abundant in the intestine (most abundant in the jejunum and less abundant in the ileum, duodenum, and colon) and kidney of the rat. In the kidney, the levels of arginase II mRNA do not change appreciably from 0 to 8 weeks of age. In contrast, arginase II mRNA and protein in the small intestine are not detectable at birth, appear at 3 weeks of age, the weaning period, and their levels increase up to 8 weeks. On the other hand, mRNAs for ornithine aminotransferase (OAT), ornithine decarboxylase, and ornithine carbamoyltransferase (OCT) are present at birth and their levels do not change much during development. Arginase II is elevated in response to a combination of bacterial lipopolysaccharide, dibutyryl cAMP, and dexamethasone in the kidney, but is not affected by these treatments in the small intestine. Immunohistochemical analysis of arginase II, OAT, and OCT in the jejunum revealed their co-localization in absorptive epithelial cells. These results show that the arginase II gene is regulated differentially in the small intestine and kidney, and suggest different roles of the enzyme in these two tissues. The co-localization of arginase II and the three ornithine-utilizing enzymes in the small intestine suggests that the enzyme is involved in the synthesis of proline, polyamines, and/or citrulline in this tissue.     

Effect of streptozotocin diabetes on some urea cycle enzymes

Streptozotocin induced diabetes in rats increased the activities of the three mitochondrial enzymes, carbamylphosphate synthetase, ornithine transcarbamylase and N-acetylglutamate synthetase, but not of the cytosolic N-acetylglutamate deacylase. Levels of both N-acetylglutamate and arginine, which are activators of carbamylphosphate synthetase and N-acetylglutamate synthetase respectively, increased in diabetes. These results serve to explain the increase both of mitochondrial citrulline and urea formation in hepatocytes and the increased urea excretion in diabetes.     

The effect of glucagon on ureagenesis from ammonia by isolated rat hepatocytes

Glucagon, at a maximally effective concentration of 1 μM, stimulated by 35% the rate at which rat hepatocytes synthesized urea from 10 mM NH₄Cl in the presence of 10 mM ornithine. The rate at which citrulline accumulated in the incubations was relatively unchanged by the presence of glucagon.Mitochondria isolated from glucagon treated hepatocytes were observed to synthesize citrulline from 10 mM NH₄Cl and 10 mM ornithine more rapidly than did mitochondria isolated from untreated hepatocytes.The role of the intracellular malate concentration in the regulation of the rate of urea synthesis, and the changes observed in the cellular content of malate in response to glucagon are discussed.     

Channeling of urea cycle intermediates in situ in permeabilized hepatocytes

Preferential use of endogenously generated intermediates by the enzymes of the urea cycle was observed using isolated rat hepatocytes made permeable to low molecular weight compounds with alpha-toxin. The permeabilized cells synthesized [14C]urea from added NH4Cl, [14C]HCO3-, ornithine, and aspartate, using succinate as a respiratory substrate; with all substrates saturating, about 4 nmol of urea were formed per min/mg dry weight of cells. Urea usually accounted for about 40-50% of the total (NH3 + ornithine)-dependent counts, arginine for less than 10%, and citrulline for about 30%. Very tight channeling of arginine between argininosuccinate lyase and arginase was shown by the fact that the addition of a 200-fold excess of unlabeled arginine to the incubations did not decrease the percentage of counts found in urea or increase that found in arginine, even though a substantial amount of the added arginine was hydrolyzed inside the cells. The channeling of argininosuccinate between its synthetase and lyase was demonstrated by similar observations; unlabeled argininosuccinate added in 200-fold excess decreased the percentage of counts in urea by only 25%. Channeling of citrulline from its site of synthesis by ornithine transcarbamylase in the mitochondrial matrix to argininosuccinate synthetase in the cytoplasmic space was also shown. These results strongly suggest that the three "soluble" cytoplasmic enzymes of the urea cycle are grouped around the mitochondria and are spatially organized within the cell in such a way that intermediates can be efficiently transferred between them.     

Effect of ornithine and lactate on urea synthesis in isolated hepatocytes.

1. In hepatocytes isolated from 24 h-starved rats, urea production from ammonia was stimulated by addition of lactate, in both the presence and the absence of ornithine. The relationship of lactate concentration to the rate of urea synthesis was hyperbolic. 2. Other glucose precursors also stimulated urea production to varying degrees, but none more than lactate. Added oleate and butyrate did not stimulate urea synthesis. 3. Citrulline accumulation was largely dependent on ornithine concentration. As ornithine was increased from 0 to 40 mM, the rate of citrulline accumulation increased hyperbolically, and was half-maximal when ornithine was 8-12 mM. 4. The rate of citrulline accumulation was independent of the presence of lactate, but with pyruvate the rate increased. 5. The rate of urea production continued to increase as ornithine was varied from 0 to 40 mM. 6. It was concluded that intermediates provided by both ornithine and lactate are limiting for urea production from ammonia in isolated liver cells. It was suggested that the stimulatory effect of lactate lies in increased availability of cytosolic aspartate for condensation with citrulline.     

A possible rate limiting factor in urea synthesis by isolated hepatocytes: the transport of ornithine into hepatocytes and mitochondria

The uptake of ornithine by isolated hepatocytes and by the particulate fraction of these cells was measured under various conditions of urea synthesis. Under conditions of maximum urea synthesis, i.e. in the presence of glucose, ornithine, ammonium chloride and oleate, the cytosolic concentration and the mitochondrial concentration of ornithine was extremely low, while citrulline accumulated in the cytosol. The data indicate that the rate of citrulline synthesis is limited by the availability of mitochondrial ornithine.     

Evidence for urea cycle activity in Sporosarcina ureae

Sporosarcina ureae BS 860, a motile, sporeforming coccus, possesses the enzymes required for a functioning urea (ornithine) cycle. This is only the second known example of urea cycle activity in a prokaryote. Specific activities are reported for ornithine carbamoyltransferase, argininosuccinase, arginase, and urease. Although argininosuccinate synthetase activity could not be detected directly in crude cell extracts, indirect evidence from radiocarbon tracing data for arginine synthesis from the substrate, l-[1-¹⁴C]-ornithine, strongly suggest the presence of this or other similar enzyme activity. Furthermore, good growth in defined media containing either 1.0% glutamine, ornithine, or citrulline as sole carbon sources suggests argininosuccinate synthetase activity is necessary for arginine synthesis. The effect of varying pH on arginase and urease activities indicate that these two enzymes may function within the context of the urea cycle to generate ammonia for amino acid synthesis, as well as for raising the pH of the growth micro-environment.     

The relationship between intramitochondrial N-acetylglutamate and activity of carbamoyl-phosphate synthetase (ammonia). The effect of glucagon

1. The relationship between urea synthesis, intracellular N-acetylglutamate and the capacity of rat-liver mitochondria to synthesize citrulline was investigated. 2. Treatment of rats with glucagon prior to killing results not only in an increased intramitochondrial ATP concentration and an increased capacity of the mitochondria to synthesize citrulline, but also in an increased concentration of intramitochondrial N-acetylglutamate. 3. Comparison of the rate of citrulline synthesis in mitochondria from glucagon-treated and from control rats, incubated under different conditions, shows that the increased N-acetylglutamate concentration after glucagon treatment is at least in part responsible for the observed increased capacity of the mitochondria to synthesize citrulline. 4. Ureogenic flux in isolated hepatocytes under different incubation conditions correlated with the intracellular concentration of N-acetylglutamate and with the capacity of the mitochondria to synthesize citrulline. 5. When isolated hepatocytes were incubated with NH3, ornithine, lactate and oleate, intracellular N-acetylglutamate increased about eightfold in the first 10 min; during this period the rate of urea synthesis increased considerably. 6. It is concluded that the concentration of intramitochondrial N-acetylglutamate plays an important role in the short-term control of flux through the urea cycle under different nutritional and hormonal conditions.     

STUDIES ON FUNCTIONAL AND METABOLIC ROLE OF UREA CYCLE INTERMEDIATES IN BRAIN

Abstract— The distribution of argininosuccinate synthetase, argininosuccinase and arginase, and the synthesis of urea in cerebullum. cerebral cortex and brain stem have been studied. Cerebral cortex had high levels of argininosuccinate synthetase and argininosuccinase. and a high ability to synthesize urea from aspartic acid and citrulline. Of the three regions, cerebullum had the highest arginase activity. The activities of the enzymes transamidinase and ornithine aminotransferase in the metabolism of arginine and ornithine in pathways other than urea formation have been studied in the three regions of the rat brain. The activity of creatine phosphokinase in all regions was the same: carbamylphosphatase activity was highest in cerebullum. Cerebral cortex had a high activity of aspartic acid transcarba-mylase. The brain stem, among the three regions, had the lowest activities of glutamine synthetase and glutaminase. The activities of these enzymes in the different regions are discussed in relation to urea production and the utilization of the urea cycle intermediates.
Intraperitoneal injection of high amounts of citrulline brought about a rise in the glutamine synthetase activity of cerebellum and brain stem and a rise in ornithine aminotransferase in cerebral cortex and liver. These results are discussed in relation to the mechanism of action of citrulline in alleviating the toxicity in hyperammonaemic states.     

Urea formation in the green vegetable bug Nezara viridula

Urea comprises 7·7 per cent of the total nitrogen excretion of Nezara viridula. The bug is capable of oxidizing uric acid to allantoin, which is also excreted, but the uricolytic pathway is not active beyond this point. Of the enzymes of the ornithine cycle, arginase and ornithine transcarbamalase are active, but there is no evidence for the arginine synthetase system. Carbamyl phosphate synthetase has a low activity detectable only by the use of radioactive substrates. Confirmation of the operation of only part of the ornithine cycle is seen in the incorporation of bicarbonate carbon into citrulline, but not into arginine or urea, by homogenates of bug tissue. It is concluded that urea in the excreta is derived from excess arginine in the diet by the action of the enzyme arginase. Free arginine is present in the cell sap of the bean pods on which the bugs feed in amounts sufficient to account for the urea excreted.