Urea synthesis in the liver and kidney of developing sheep

In order to establish if the urea found in foetal fluids in sheep could be of foetal origin and whether there are changes in the ability of ovine liver to synthesise urea during foetal and postnatal development, the rates of urea production from ammonium and bicarbonate ions have been measured in liver and kidney slices from animals aged from 50 days conceptual age to 16 weeks after birth, and in pregnant and non-pregnant ewes. The activities of five enzymes directly involved in the biosynthesis of urea have also been determined.Urea was found to be synthesised by foetal liver from at least 50 days conceptual age at rates similar to those observed in adult ewes. Highest rates of urea synthesis per unit weight of liver were found immediately after birth. In the liver there were significant positive correlations between the rates of urea synthesis by slices and the activities of carbomoyl phosphate synthase (ammonia) (EC 2.7.2.5), argininosuccinate synthetase (EC 6.3.4.5) and argininosuccinate lyase EC 4.3.2.1). Ornithine carbomoyl transferase (EC 2.1.3.3) activity was highest in the livers of ruminating animals. Hepatic arginase activity (EC 3.5.3.1) was highest during the late foetal life and in the mature foetuses the activity was ten-fold greated than that in maternal liver.Urea was not synthesised from ammonia and bicarbonate in kidney slices and neither ornithine carbomoyl transferase activity nor argininosuccinate synthetase activity could be detected. The activity of renal arginase was at least 70 times less than that found in the liver and the highest activity was found in ruminating lambs.The changes observed in the activities of the urea cycle enzymes during development have been contrasted with those reported to occur in other species. It is concluded that there is no single factor regulating the activities of the five enzymes directly concerned with urea synthesis during development. The results support the hypothesis that in mammals the ability of the liver to synthesise urea in foetal life is related to renal development.     

Effect of alkalinity (pH 10) on ureogenesis in the air-breathing walking catfish,Clarias batrachus

Exposure of fish to alkaline conditions inhibits the rate of ammonia excretion, leading to ammonia accumulation and toxicity. The purpose of this study was to determine the role of ureogenesis via the urea cycle, to avoid the accumulation of ammonia to a toxic level during chronic exposure to alkaline conditions, for the air-breathing walking catfish, Clarias batrachus, where a full complement of urea cycle enzyme activity has been documented. The walking catfish can survive in water with a pH up to 10. At a pH of 10 the ammonia excretion rate by the walking catfish decreased by approximately 75% within 6 h. Although there was a gradual improvement of ammonia excretion rate by the alkaline-exposed fish, the rate remained 50% lower, even after 7 days. This decrease of ammonia excretion was accompanied by a significant accumulation of ammonia in plasma and body tissues (except in the brain). Urea-N excretion for alkaline-exposed fish increased 2.5-fold within the first day, which was maintained until day 3 and was then followed by a slight decrease to maintain a 2-fold increase in the urea-N excretion rate, even after 7 days. There was also a higher accumulation of urea in plasma and other body tissues (liver, kidney, muscle and brain). The activity of glutamine synthetase and three enzymes operating in the urea cycle (carbamyl phosphate synthetase, argininosuccinate synthetase, argininosuccinate lyase) increased significantly in hepatic and extra-hepatic tissue, such as the kidney and muscle in C. batrachus, during exposure to alkaline water. A significant increase in plasma lactate concentration noticed during alkaline exposure possibly helped in the maintenance of the acid-base balance. It is apparent that the stimulation of ureogenesis via the induced urea cycle is one of the major physiological strategies adopted by the walking catfish (C. batrachus) during chronic exposure to alkaline water, to avoid the in vivo accumulation of ammonia to a toxic level in body tissues and for the maintenance of pH homeostasis.     

Excretion of nitrogen compounds in sweat during a sauna]

The aim of the study was to determine a loss of nitrogen compounds with sweat in sauna and to estimate their plasma concentration. Sweat was collided during 30 min stay in sauna. Blood was taken before and immediately after the sauna. Concentrations of ammonia, urea, creatinine and uric acid were determined in the both fluids. It has been found, that the concentration of ammonia in sweat exceeds, that in plasma by 77 times. Ammonia plasma concentration following sauna increased by about 60%. Sweat urea concentration exceeded that in plasma by 3.5 times. Plasma urea concentration was significantly reduced after sauna. Sweat creatinine concentration was about two times higher than that in plasma. No uric acid was detected in sweat. Sweating did not affect plasma creatinine and uric acid concentrations. Results indicate that considerable amount of nitrogen is lost with sweat during sauna.     

Metabolism and excretion of nitrogen during metamorphosis and egg production in the sawfly, Neodiprion sertifer

Measurements of whole-body dry matter, total nitrogen, water-soluble protein, amino acids, and uric acid were determined at successive stages during metamorphosis in Neodiprion sertifer. The major change was in the uric acid fraction: in females, it increased up to the non-pharate pupa and then decreased during the subsequent stages of adult development and egg production; in males, it continued to increase during adult development. The decline of uric acid could not be explained by the accumulation of allantoin, allantoic acid, urea, or uric acid riboside. Examination of amino acid levels in the gut revealed an accumulation in the pupa followed by a depletion at the onset of adult development. This was followed by an excretory phase marked by the progressive accumulation of large quantities of uric acid and small quantities of urea, ammonia, and amino acids during the formation of the meconium. Amino acid analysis of the meconium revealed the presence of large proportions of proline, hydroxyproline, and histidine in comparison with the other amino acids.     

Bovine amniotic and allantoic fluids for the culture of murine embryos

This study evaluated bovine amniotic and allantoic fluids as culture media for two-cell murine embryos to the hatched blastocyst stage. Amniotic and allantoic fluids were collected from four 70-d periods of pregnancy and pooled from at least five different animals. In Experiment 1 (n = 470) the fluids were frozen twice. Treatments consisted of twice frozen amniotic or allantoic fluid from each pregnancy period, Whitten's medium and fetal calf serum. The later two media were controls. Twice-frozen amniotic fluid <70 d pregnancy period, fetal calf serum and Whitten's medium supported the development of embryos to the hatched blastocyst stage. Whitten's medium was superior to twice-frozen amniotic fluid <70 d pregnancy period or fetal calf serum (P<0.01). Biochemical analysis showed lower glucose in amniotic and allantoic fluids than in Whitten's medium. Experiment 2 (n = 425) was performed to evaluate the effect of glucose supplementation to amniotic fluid. No benefit of glucose supplementation of the amniotic fluid was observed. In Experiment 3 (n = 432), the fluids were transported nonfrozen on ice. Treatments consisted of nonfrozen amniotic fluid <70 d pregnancy period; nonfrozen amniotic fluid <70 d pregnancy period + glucose), nonfrozen allantoic fluid <70 d pregnancy period; and Whitten's medium. The percentages of embryos developing to hatched blastocyst stage were 66.6, 56.5, 57.4 and 63.9% respectively, for each of the four treatments. No differences were found between any two treatments (P<0.05). In Experiment 4 (n = 231) the fluids were stored at -20 degrees C for 15 d. Whitten's medium was superior to amniotic or allantoic fluid <70 d pregnancy period in sustaining embryo development (P<0.05). In conclusion, these data indicate that nonfrozen bovine amniotic or allantoic fluid <70 d pregnancy period can support the development of murine embryos to the hatched blastocyst stage comparable to culture in Whitten's medium. Glucose supplementation of the amniotic fluid offered no advantage, and freezing of fluids had an adverse effect on in vitro embryo development.     

Subcellular location of glutamine synthetase and urea cycle enzymes in liver of spiny dogfish (Squalus acanthias)

Glutamine synthetase and glutamine- and acetylglutamate-dependent carbamoyl-phosphate synthetase, both of which are present in high concentrations in liver of urea-retaining elasmobranchs, have been found to be located exclusively in the mitochondria in liver from the representative elasmobranch Squalus acanthias. This observation is consistent with the view that the function of this unique carbamoyl-phosphate synthetase is related to urea synthesis, and that the initial nitrogen-donating substrate for urea synthesis in these species is glutamine rather than ammonia. The urea cycle enzymes, ornithine carbamoyltransferase and arginase, are also located in the mitochondria, whereas argininosuccinate synthetase and argininosuccinate lyase are located in the cytosol. Glutamine synthetase and arginase are mitochondrial enzymes in uricotelic species, but are normally found in the cytoplasm in ureotelic species. the properties of the elasmobranch arginase, however, are characteristic of arginases from ureotelic species (e.g. the Km for arginine is 1.2 mM, and the enzyme has an Mr congruent to 100,000).     

The effect of protein content of the diet on the rate of urea formation in sheep liver

1. In the livers of six sheep given a high-protein diet, the concentrations of certain urea-cycle enzymes [ornithine transcarbamoylase, arginine synthetase (combined activity of argininosuccinate synthetase and argininosuccinase) and arginase] were significantly greater than when the sheep were given a low-protein diet. Alkaline phosphatase activity/mg. of liver protein was not significantly affected by diet. 2. Three sheep previously given the high-protein diet showed no significant rise in the concentration of ammonia in the blood after the administration of urea (0·5g./kg. body wt.). The concentration of ammonia in the blood of the three sheep given the low-protein diet rose exponentially with time after dosing with urea and all sheep died. 3. It is suggested that tolerance to ammonia toxicity in the sheep is at least partly a function of the activity of the urea-cycle enzymes in the liver.     

An Aspect of Urea Cycle Enzymes in Goat

A large amount of ammonia is produced in the rumen and some portion of the ammonia are absorbed into the portal blood through the rumen mucosa. Accordingly, it seems that ammonia detoxication is more necessary for the ruminant than for the non-ruminant. Activities of the urea cycle enzymes as principal instrument for ammonia detoxication in goat were investigated in this experiment.

The activities of the urea cycle enzymes of goat were found to be very similar to those of rat reported by other authors. The activities of the urea cycle enzymes were affected by the protein level of diet. Administration of magnesium aspartate increased the activities of argininosuccinate synthetase and arginase, and had some effect on the concentrations of citrulline, aspartic acid, and urea in the liver.     

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.     

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.     

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.     

Induction of ureogenesis in perfused liver of a freshwater teleost, Heteropneustes fossilis, infused with different concentrations of ammonium chloride

The induction pattern of urea cycle enzymes and the rate of urea-N excretion were studied with relation to ammonia load in the perfused liver of a freshwater ammoniotelic teleost, Heteropneustes fossilis, when infused with different concentrations of ammonium chloride for 60 min. Both urea-N excretion and uptake of ammonia by the perfused liver were found to be a saturable process. The V_max of urea-N excretion (0.45 μmol/g liver/min) was obtained at ammonium chloride addition of 1.18 μmol/g liver/min. The maximum induction of carbamyl phosphate synthetase (ammonia dependent), 200%, and of ornithine transcarbamylase, 120%, was seen by the addition of 0.58 μmol/g liver/min, and for argininosuccinate synthetase and argininosuccinate lyase of 150% and 115%, respectively, by the addition of 2.8 μmol/g liver/min of ammonium chloride. However, arginase activity did not alter in any of the concentrations of ammonium chloride added. An increase of ammonia load of 3–5 μmol/g wet wt from the physiological level in the perfused liver was sufficient to initiate and to cause maximum induction of most of the urea cycle enzymes activitty. These results further confirm the capacity of transition from ammoniotelism to ureotelism in this unique freshwater air-breathing teleost to tolerate a very high ambient ammonia.     

Metabolic adaptations to nitrogen excess in late gestation in rat.

Pregnant rats of 19th and 21st days were given an acute nitrogen overload produced by an infusion of either 0.2 M ammonium acetate or 0.2 M glutamine. Metabolic adaptations to nitrogen excess were studied measuring--in fetomaternal unit--non-protein nitrogen content and the activities of enzymes related with ammonia metabolism. Maternal and fetal plasma urea levels were increased by ammonium acetate treatment. Glutamine overload increased more the amino acid content in the mothers than in conceptus. As response to ammonium acetate treatment, glutamate dehydrogenase activity in liver was more sensitive in pregnant than in nonpregnant rats, suggesting more nitrogen incorporation into amino acids in pregnancy. Regarding glutamine synthetase activity, both treatments had an opposite effect except in kidney. The adenylate deaminase activity of pregnant rats was inhibited similarly to nonpregnant rats by nitrogen overloads, but stronger after glutamine infusion. Placenta and fetal metabolism were adjusted, as the dams, to lack of ammonia production by nitrogen overloads and to glutamine synthesis by ammonium acetate infusion.     

Role of ureogenesis in tackling problems of ammonia toxicity during exposure to higher ambient ammonia in the air-breathing walking catfish<Emphasis Type="Italic">clarias batrachus</Emphasis>

In the present study, the possible role of ureogenesis to avoid the accumulation of toxic ammonia to a lethal level under hyper-ammonia stress was tested in the air-breathing walking catfishClarias batrachus by exposing the fish at 25 mM NH₄Cl for 7 days. Excretion of ammonia by the NH₄Cl-exposed fish was totally suppressed, which was accompanied by significant accumulation of ammonia in different body tissues. The walking catfish, which is otherwise predominantly ammoniotelic, turned totally towards ureotelism from ammoniotelism with a 5-to 6-fold increase of urea-N excretion during exposure to higher ambient ammonia. Stimulation of ureogenesis was accompanied with significant increase of some of the key urea cycle enzymes such as carbamyl phosphate synthetase (urea cycle-related), argininosuccinate synthetase and argininosuccinate lyase both in hepatic and non-hepatic tissues. Due to this unique physiological strategy of turning towards ureotelism from ammoniotelism via the induced urea cycle, this air-breathing catfish is able to survive in very high ambient ammonia, which they face in certain seasons of the year in the natural habitat.     

A 15N-n.m.r. study of cerebral, hepatic and renal nitrogen metabolism in hyperammonaemic rats.

1. Rats were infused with 15NH4+ or L-[15N]alanine to induce hyperammonaemia, a potential cause of hepatic encephalopathy. HClO4 extracts of freeze-clamped brain, liver and kidney were analysed by 15N-n.m.r. spectroscopy in combination with biochemical assays to investigate the effects of hyperammonaemia on tissue concentrations of ammonia, glutamine, glutamate and urea. 2. 15NH4+ infusion resulted in a 36-fold increase in the concentration of blood ammonia. Cerebral glutamine concentration increased, with 15NH4+ incorporated predominantly into the gamma-nitrogen atom of glutamine. Incorporation into glutamate was very low. Cerebral ammonia concentration increased 5-10-fold. The results suggest that the capacity of glutamine synthetase for ammonia detoxification was saturated. 3. Pretreatment with the glutamine synthetase inhibitor L-methionine DL-sulphoximine resulted in 84% inhibition of [gamma-15N]glutamine synthesis, but incorporation of 15N into other metabolites was not observed. The result suggests that no major alternative pathway for ammonia detoxification, other than glutamine synthetase, exists in rat brain. 4. In the liver 15NH4+ was incorporated into urea, glutamine, glutamate and alanine. The specific activity of 15N was higher in the gamma-nitrogen atom of glutamine than in urea. A similar pattern was observed when [15N]alanine was infused. The results are discussed in terms of the near-equilibrium states of the reactions involved in glutamate and alanine formation, heterogeneous distribution in the liver lobules of the enzymes involved in ammonia removal and their different affinities for ammonia. 5. Synthesis of glutamine, glutamate and hippurate de novo was observed in kidney. Hippurate, as well as 15NH4+, was contributed by co-extracted urine. 6. The potential utility and limitations of 15N n.m.r. for studies of mammalian metabolism in vivo are discussed.     

Fatty acid synthesis in chick embryonic heart and liver during development.

Fatty acid synthesis by subcellular fractions of heart and liver of chick embryos at varying stages of development has been studied. Fatty acid synthetase activity is associated with the embryonic heart at early stages of development, as suggested by substrate requirement, Schmidt decarboxylation of synthesized fatty acids and gas liquid chromatographic identification of the products as palmitic and stearic acids. The fatty acid synthetase activity decreases in heart cytosol with age of the embryo and is absent in the newly hatched chick and in older chicken. The acetyl CoA carboxylase activity is negligible in embryonic and adult chicken heart. The fatty acid synthetase activity in liver is low, but measurable during the entire embryonic development. The activity increases by about three-fold on hatching and thereafter in fed, newly hatched chicks by about 35-fold, over the basal embryonic activity. The acetyl and malonyl transacylase activities in the heart and liver cytosols during development followed closely the fatty acid synthetase activities in heart and liver, respectively. A non-coordinate induction of fatty acid synthetase and acetyl CoA carboxylase activities in liver was observed during development. The microsomal chain elongation in liver and heart followed the pattern of fatty acid synthetase activity in liver and heart, respectively. The mitochondrial chain elongation in embryonic heart is initially low and increases with age; while this activity in liver is higher in early stages of embryonic development than in the older embryos and the chicks. Measurement of lipogenesis from acetate-1-¹⁴C by liver and heart slices from chick embryos and newly hatched chicks support the conclusions reached in the studies with the subcellular fractions. The results obtained indicate that the major system of fatty acid synthesis in embryonic and adult heart is the mitochondrial chain elongation. In embryonic liver, fatty acid synthesis proceeds by chain elongation, while the de novo system is the major contributor to the lipogenic capacity of the liver after hatching.     

Immunohistochemical Localization of Arginase II and Other Enzymes of Arginine Metabolism in Rat Kidney and Liver

Arginine is a precursor for the synthesis of urea, polyamines, creatine phosphate, nitric oxide and proteins. It is synthesized from ornithine by argininosuccinate synthetase and argininosuccinate lyase and is degraded by arginase, which consists of a liver-type (arginase I) and a non-hepatic type (arginase II). Recently, cDNAs for human and rat arginase II have been isolated. In this study, immunocytochemical analysis showed that human arginase II expressed in COS-7 cells was localized in the mitochondria. Arginase II mRNA was abundant in the rat small intestine and kidney. In the kidney, argininosuccinate synthetase and lyase were immunostained in the cortex, intensely in proximal tubules and much less intensely in distal tubules. In contrast, arginase II was stained intensely in the outer stripes of the outer medulla, presumably in the proximal straight tubules, and in a subpopulation of the proximal tubules in the cortex. Immunostaining of serial sections of the kidney showed that argininosuccinate synthetase and arginase II were collocalized in a subpopulation of proximal tubules in the cortex, whereas only the synthetase, but not arginase II, was present in another subpopulation of proximal tubules. In the liver, all the enzymes of the urea cycle, i.e. carbamylphosphate synthetase I, ornithine transcarbamylase, argininosuccinate synthetase and lyase and arginase I, showed similar zonation patterns with staining more intense in periportal hepatocytes than in pericentral hepatocytes, although zonation of ornithine transcarbamylase was much less prominent. The implications of these results are discussed.     

Nitrogen excretion during embryonic development of the green iguana, Iguana iguana (Reptilia; Squamata)

Development within the cleidoic egg of birds and reptiles presents the embryo with the problem of accumulation of wastes from nitrogen metabolism. Ammonia derived from protein catabolism is converted into the less toxic product urea or relatively insoluble uric acid. The pattern of nitrogen excretion of the green iguana, Iguana iguana, was determined during embryonic development using samples from allantoic fluid and from the whole homogenized egg, and in hatchlings and adults using samples of blood plasma. Urea was the major excretory product over the course of embryonic development. It was found in higher concentrations in the allantoic sac, suggesting that there is a mechanism present on the allantoic membrane enabling the concentration of urea. The newly hatched iguana still produced urea while adults produced uric acid. The time course of this shift in the type of nitrogen waste was not determined but the change is likely to be related to the water relations associated with the terrestrial habit of the adult. The green iguana produces parchment-shelled eggs that double in mass during incubation due to water absorption; the eggs also accumulate 0.02 mM of urea, representing 82% of the total measured nitrogenous residues that accumulate inside the allantois. The increase in egg mass and urea concentration became significant after 55 days of incubation then were unchanged until hatching.     

Ureide biogenesis and the enzymes of ammonia assimilation and ureide biosynthesis in nitrogen fixing pigeonpea (Cajanus cajan) nodules

Allantoic acid production from IMP, XMP, inosine, xanthosine, hypoxanthine, xanthine, uric acid and allantoin was investigated by incubating each of these substrates withCajanus cajan cytosol and bacteroid fractions separately in the presence and absence of NAD+ and allopurinol. Allantoic acid synthesis by bacteroid fraction could only be observed with uric acid and allantoin as substrates. Addition of NAD⁺ or allopurinol to the reaction mixtures had no effect. However, with cytosol fraction, allantoic acid was produced by each of these substrates, with maximum rate with allantoin. With NAD⁺ or with allopurinol, allantoic acid was produced only with uric acid and allantoin as substrates. NADH production with cytosol fraction could again be observed with all the substrates. Except with uric acid and allantoin, allopurinol completely inhibited NADH formation. Regardless of the presence or absence of allopurinol, none of the substrates exhibited significant activity with bacteroid fraction. Based on the activities of glutamine synthetase, glutamate synthase, glutamate dehydrogenase, aspartate aminotransferase, asparagine synthetase, nucleotidase, nucleosidase, xanthine de-hydrogenase, uricase and allantoinase and their intracellular localisation in various nodule fractions, a probable pathway for the biogenesis of ureides in pigeonpea nodules has been proposed