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.     

Analysis of regulatory factors for urea synthesis by isolated perfused rat liver. I. Urea synthesis with ammonia and glutamine as nitrogen sources.

Urea synthesis was studied using the isolated liver perfusion with ammonium cholride and glutamine as nitrogen sources. The rate of urea formation increases with ammonium cholorde concentration up to 5mM, and the rate remained constant in the range between 5 and 20mM of ammonium chloride as the substrate. The concentration of ammonia in the medium to support the half-maximum velocity of urea formation was 0.7mM. The rate of urea formation was stimulated by the addition of 2.5mM ornithine, and the greater part of the ornithine which was taken up into the liver was accumulated as citrulline in the presence of ammonia. A considerable accelerating effect of N-acetylglutamate on the synthetic rate was observed, but a rather high concentration of N-acetylglutamate was required in order to obtain the maximum effect possibly, because its permeability into liver cells may be limited. A marked additive effect on the rate of urea formation was observed with the combined addition of ornithine and N-acetylglutamate. The metabolic conversion of glutamine nitrogen to urea in the perfused rat liver and the effect of several compounds which stimulated urea synthesis with ammonia were further examined. The process of conversion of glutamine nitrogen to urea might be composed of the following three steps. In the first lag phase, a small amount of glutamine was removed from the medium. In the second stage, the glutamine level decreased rapidly and ammonia was accumulated in the perfusate. The third stage was a period in which glutamine concentration remained at a constant low level, and the accumulated ammonia was rapidly conversed to urea. The rate of urea formation in this third stage was found to be much higher than that with ammonia as the substrate. The maximum rate of glutamine removal was obtained at pH 7.7 of the perfusate and at a concentration of 10mM glutamine. Urea formation with glutamine was also stimulated by the addition of ornithine, malate, or N-acetylglutamate, which had accelerating effects on the urea synthesis with ammonia. This stimulation was due to an effective conversion of ammonia to urea, but no change in the rate of removal glutamine was obtained.     

Role of anion translocation across the mitochondrial membrane in the regulation of urea synthesis from ammonia by isolated rat hepatocytes.

The regulation of urea synthesis from ammonia was investigated using isolated hepatocytes from fasted rats. Addition of ammonia alone produced only a small increase of urea formation, which was stimulated 2-fold by ornithine in conjunction with a fall of ATP levels and an accumulation of citrulline. Further addition of oleate or beta-hydroxybutyrate produced an additional 2-fold stimulation of urea formation to approximately 200 mumol/g dry weight/hour. The presence of oleate also protected against the inhibitory effect of 2,4-dinitrophenol on urea synthesis and the cellular ATP content. The data suggest that both the rate of of energy production and the rate of generation of reducing equivalents from endogensou substrates are insufficient to meet the requirements for optimal rates of urea synthesis. Urea formation from NH3 in the presence of ornithine and oleate, but iin the absence of gluconeogenic precursors, was inhibited by butylmalonate, a known inhibitor of malate-phosphate exchange across the mitochondrial membrane, and stimulated by theaddition of malate and other dicarboxylic acids and amino acids to the cell suspension...     

The urea cycle in the liver of arthritic rats

The urea cycle in the liver of adjuvant-induced arthritic rats was investigated using the isolated perfused liver. Urea production in livers from arthritic rats was decreased during substrate-free perfusion and also in the presence of the following substrates: alanine, alanine + ornithine, ammonia, ammonia + lactate, ammonia + pyruvate and glutamine but increased when arginine and citrulline + aspartate were the substrates. No differences were found with ammonia + aspartate, ammonia + aspartate + glutamate, aspartate, aspartate + glutamate and citrulline. Ammonia consumption was smaller in the arthritic condition when the substance was infused together with lactate or pyruvate but higher when the substance was simultaneously infused with aspartate or aspartate + glutamate. Glucose production tended to correlate with the smaller or higher rates of urea synthesis. Blood urea was higher in arthritic rats (+25.6%), but blood ammonia was lower (–32.2%). Critical for the synthesis of urea from various substrates in arthritic rats seems to be the availability of aspartate, whose production in the liver is probably limited by both the reduced gluconeogenesis and aminotransferase activities. This is indicated by urea synthesis which was never inferior in the arthritic condition when aspartate was exogenously supplied, being even higher when both aspartate and citrulline were simultaneously present. Possibly, the liver of arthritic rats has a different substrate supply of nitrogenous compounds. This could be in the form of different concentrations of aspartate or other aminoacids such as citrulline or arginine (from the kidneys) which allow higher rates of hepatic ureogenesis.     

A new approach of the estimation of Km of carbamyl phosphate synthetase for ammonia in isolated rat hepatocytes

1. The Km for ammonia of carbamyl phosphate synthetase was determined by preincubating isolated liver cells for 30 min in the absence of ammonia and bicarbonate and in the presence of ornithine, chloroquine, which blocks lysosomal proteolysis, and aminoxy acetic acid, which inhibits transaminases. 2. The reaction was started with the addition of varying concentrations of ammonia and 10 mM bicarbonate. 3. The rate of citrulline formation was measured as related to ammonia concentration. 4. The pre-incubation with ornithine permits an accumulation of intracellular and mitochondrial ornithine concentrations which in turn allow rapid citrulline formation in the carbamyl phosphate form. 5. This prevents any feedback inhibition on a carbamyl phosphate synthetase or decreases in activity due to accumulation of carbamyl phosphate and/or absence of ornithine. 6. Using these methods in combination with [14C]bicarbonate permitted an estimation of exogenous ammonia for carbamyl phosphate synthesis. 7. The Km for ammonia was 1.5 mM, using a pK of 8.88 the Km for free NH3 was 48 microM.     

Mitochondrial citrulline synthesis from ammonia and glutamine in the liver of ureogenic air-breathing catfish, Clarias batrachus (Linnaeus)

The possible synthesis of citrulline, a rate limiting step for urea synthesis via the ornithine-urea cycle (OUC) in teleosts was tested both in the presence of ammonia and glutamine as nitrogen-donating substrates by the isolated liver mitochondria of ureogenic air-breathing walking catfish, C. batrachus. Both ammonia and glutamine could be used as nitrogen-donating substrates for the synthesis of citrulline by the isolated liver mitochondria, since the rate of citrulline synthesis was almost equal in presence of both the substrates. The citrulline synthesis by the isolated liver mitochondria requires succinate at a concentration of 0.1 mM as an energy source, and also requires the involvement of intramitochondrial carbonic anhydrase activity for supplying HCO3 as another substrate for citrulline synthesis. The rate of citrulline synthesis was further stimulated significantly by the isolated liver mitochondria of the fish after pre-exposure to 25 mM NH4Cl for 7 days. Due to possessing this biochemical adaptational strategy leading to the amelioration of ammonia toxicity mainly by channeling ammonia directly and/or via the formation of glutamine to the OUC, this air-breathing catfish could succeed in surviving in high external ammonia, which it faces in its natural habitat in certain seasons of the year.     

Inhibition of arginine synthesis by urea: A mechanism for arginine deficiency in renal failure which leads to increased hydroxyl radical generation

We have reported that (1) the synthesis of GSA, a uremic toxin, increases depending on the urea concentration and (2) GSA is formed from argininosuccinic acid (ASA) and the hydroxyl radical or SIN-1 which generates superoxide and NO simultaneously. However, an excess of NO, which also serves as a scavenger of the hydroxyl radical, inhibited GSA synthesis. We also reported that arginine, citrulline or ammonia plus ornithine, all of which increase arginine, inhibit GSA synthesis even in the presence of urea. To elucidate the mechanism for increased GSA synthesis by urea, we investigated the effect of urea on ASA and arginine, the immediate precursor of NO.Isolated rat hepatocytes were incubated in 6 ml of Krebs-Henseleit bicarbonate buffer containing 3% bovine serum albumin, 10 mM sodium lactate, 10 mM ammonium chloride and with or without 36 mM of urea and 0.5 or 5 mM ornithine at 37°C for 20 min. In vivo experiments, 4 ml/100 g body weight of 1.7 M urea or 1.7 M NaCl were injected intra-peritoneally into 5 male Wistar rats. Two hours after the intra-peritoneal injection of urea or 1.7 M NaCl, blood, liver and kidney were obtained by the freeze cramp method and amino acids were determined by an amino acid analyzer (JEOL:JCL-300).ASA in isolated hepatocytes was not detected with or without 36 mM (200 mgN/dl) urea, but the arginine level decreased from 36 to 33 nmol/g wet cells with urea. Ornithine which inhibits GSA synthesis, increased ASA markedly in a dose dependent manner and increased arginine. At 2 h after the urea injection the rat serum arginine level decreased by 42% (n = 5), and ornithine and citrulline levels increased significantly. Urea injection increased the ASA level in liver from 36–51 nmol/g liver but this was not statistically significant.We propose that urea inhibits arginine synthesis in hepatocytes, where the arginine level is extremely low to begin with, which decreases NO production which, in turn, increases hydroxyl radical generation from superoxide and NO. This may, also, be an explanation for the reported increase in oxygen stress in renal failure.     

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.     

Control of ureogenesis

Control of urea synthesis was studied in rat hepatocytes incubated with physiological mixtures of amino acids in which arginine was replaced by equimolar amounts of ornithine. The following observations were made. Intramitochondrial carbamoyl phosphate was always below 0.1 mM. Only when ornithine was absent and when, in addition, the concentration of amino acids was higher than four times their plasma concentration, intramitochondrial carbamoyl phosphate rose up to about 3 mM; under these conditions ammonia accumulated in the medium. The relationship between ornithine-cycle flux and the concentration of the cycle intermediates at varying amino acid concentration indicated that under near-physiological conditions the ornithine-cycle enzymes are far from being saturated with their subsidiaries. Moderate concentrations of norvaline had no effect on the rate of urea synthesis unless the cells were severely depleted of ornithine. Activation of carbamoyl-phosphate synthetase (ammonia) by addition of N-carbamoylglutamate only slightly stimulated urea production at all amino acid concentrations. However, in the presence of the activator the curve relating ornithine-cycle flux to the steady-state ammonia concentration was shifted to lower concentrations of ammonia. The intramitochondrial concentration of carbamoyl phosphate in rat liver in vivo was below 0.1 mM. This value is far below the concentration required for substantial inhibition of carbamoyl-phosphate synthetase. It is concluded that in vivo the function of activity changes in carbamoyl-phosphate synthetase, via the well-documented alterations in the intramitochondrial concentration of N-acetylglutamate, is to buffer the intrahepatic ammonia concentration rather than to affect urea production per se. At constant concentration of ammonia the rate of urea production is entirely controlled by the activity of carbamoyl-phosphate synthetase.     

The urea cycle and related pathways in the liver of Walker-256 tumor-bearing rats

The urea cycle was evaluated in perfused livers isolated from cachectic tumor-bearing rats (Walker-256 tumor). Urea production in livers of tumor-bearing rats was decreased in the presence of the following substrates: alanine, alanine + ornithine, alanine + aspartate, ammonia, ammonia + lactate, ammonia + pyruvate and glutamine. Urea production from arginine was higher in livers of tumor-bearing rats. No difference was found with aspartate, aspartate + ammonia, citrulline, citrulline + aspartate and glutamine + aspartate. Ammonia consumption was smaller in livers from cachectic rats when the substance was infused together with lactate and pyruvate. Glucose production was smaller in the cachectic condition only when alanine was the gluconeogenic substrate. Blood urea was higher in tumor-bearing rats, suggesting higher rates of urea production. The availability of aspartate seems to be critical for urea synthesis in the liver of tumor-bearing rats, which is possibly unable to produce this amino acid in sufficient amounts from endogenous sources. The liver of tumor-bearing rats may have a different exogenous substrate supply of nitrogenous compounds. Arginine could be one of these compounds in addition to aspartate which seems to be essential for an efficient ureogenesis in tumor-bearing rats.     

Effect of propionate on the utilization of nitrogen from 15NH4Cl for urea synthesis in hepatocytes isolated from sheep liver

1. The effect of ornithine (2.0 mM) and propionate (5.0 mM) on the utilization of N from 15NH4Cl (5.0 mM) for urea synthesis in hepatocytes isolated from sheep liver was investigated. 2. The capacity of sheep hepatocytes to utilize [15N]ammonia in the absence of the other exogenous substrates was very low and amounted 132 +/- 37.3 mumol/hr per 1 g dry wt. 3. Ornithine failed to affect the total [15N]ammonia uptake and total urea synthesis, but at the same time it markedly increased the utilization of [15N]ammonia for ureagenesis and diminished the rate of urea synthesis from endogenous sources. 4. Propionate markedly increased total [15N]ammonia utilization and total urea formation; this increase resulted from the rise of ammonia utilization for urea synthesis and it was similar in the presence or absence of ornithine. 5. The capacity of sheep liver cells to utilize ammonia in the presence of propionate (in the presence or absence of ornithine) amounted to 256 mumol/hr per 1 g dry wt, thus being similar to the values in vivo. 6. It is concluded that in sheep hepatocytes both ornithine and propionate stimulate the utilization of ammonia for urea synthesis and these effects take place independently and occur by different mechanisms.     

Effect of arginine,ornithine and citrulline supplementation upon performance and metabolism of trained rats

During intense exercise there is an augmented production of ammonia and IMP in the exercised muscle that could be related to the establishment of peripheral fatigue. In order to prevent this accumulation, the urea cycle in the liver eliminates ammonia in the form of urea and the skeletal muscle buffers the increase of ammonia via transamination reactions. In the present study we evaluated the effect of arginine, citrulline and ornithine supplementation, intermediates of the urea cycle, on the performance of sedentary and swimming-trained rats submitted to a single bout of exhaustive exercise. We also measured the glycogen content of the soleus and gastrocnemius muscles and of the liver, as well as the plasma concentrations of ammonia, urea, glutamine, glucose and lactate. The results indicate that arginine, citrulline and ornithine supplementation increased the flux of substrate through the reaction catalysed by glutamine synthetase, leading to increased glutamine production after an exhaustive bout of exercise, and of the mechanism involved in ammonia buffering.     

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.     

Ornithine uptake by isolated hepatocytes and distribution within the cell

Uptake of ornithine by isolated hepatocytes and its distribution within the cell was investigated. Ornithine uptake was energy independent and exhibited a saturable and a nonsaturable component. The Km value of the saturable component was 1.3 mM. At an external ornithine concentration of 0.5 mM the rate of ornithine uptake was 127 +/- 19 nmol/g. Lysine inhibited ornithine uptake, indicating the existence of an ornithine transport system. It was concluded that ornithine transport can limit urea synthesis in the state of transition from a low ammonia to a high ammonia supply.     

Channeling of extramitochondrial ornithine to matrix ornithine transcarbamylase

In the presence of citrulline synthesis, we made the following observations. External ornithine is channeled between its transporter and ornithine transcarbamylase; mitochondria preloaded with cold ornithine, then incubated with [3H]ornithine, produced citrulline of the same specific radioactivity as that of external ornithine, while matrix ornithine remained essentially unlabeled. The channeling of ornithine suggests that some soluble enzymes are organized within the mitochondrial matrix. The rate of ornithine transport can be greater than 80 nmol/min/mg. At rates of carbamyl phosphate synthesis of 10-50 nmol/min/mg, the rate of citrulline synthesis is controlled by external ornithine in the range 0.03-0.2 mM; at greater than or equal to 0.2 mM ornithine, transport is not limiting for citrulline synthesis. At external ornithine concentrations less than or equal to 1 mM, i.e. within the physiological range, this amino acid is undetectable in the matrix. Given the rates of citrulline and urea synthesis which occur in vivo and the concentrations of ornithine present in the liver, our findings indicate that ornithine may contribute to the physiological regulation of urea synthesis. Preliminary reports of parts of this work have been published (Raijman, L., Cheung, C-W., and Cohen, N. S. (1984) Fed. Proc. 43, 1831; Cohen, N. S., Cheung, C-W., and Raijman, L. (1986) Fed. Proc. 45, 2677).     

Origin of the ammonia used for mitochondrial citrulline synthesis as revealed by 13C-15N spin coupling patterns observed by 13C NMR.

The sources of ammonia used by isolated, intact rat liver mitochondria in the production of citrulline have been investigated in situ using a novel methodology based on the analysis of 13C-15N heteronuclear couplings observed by 13C NMR. Isolated mitochondria from rat liver were incubated with ornithine, 13CO3H- and 15NH4Cl, using unlabeled glutamate or glutamine as alternative, intramitochondrial nitrogen donors. The production of (7-13C, 8-15N) or (7-13C, 8-14N) citrulline was determined in situ by 13C NMR and the relative proportions of 15N- and 14N-citrullines confirmed by high resolution 13C NMR analysis of the C-7 citrulline resonance observed in perchloric acid extracts prepared at the end of the incubations. The 15N fractional enrichment of the intramitochondrial NH3 pool was manipulated either by modifying the 15N enrichment of added 15NH4Cl, or by altering the concentration of the unlabeled nitrogen donors in the incubation medium. Fractional 15N enrichments measured in the N-8 nitrogen of the resulting (7-13C) citrulline closely paralleled those of the external 15NH4Cl with minor dilutions derived from the unlabeled nitrogen contribution from the alternative substrates. In the presence of 10 mM 15NH4Cl, 10 mM glutamate contributed 4% of the citrulline N-8 nitrogen. Under similar conditions, the contribution of nitrogen from 10 mM glutamine to N-8 citrulline was 6%. These results indicate that the primary source of ammonia used for citrulline synthesis by isolated, intact rat liver mitochondria is extramitochondrial, providing also an illustration of the use of 13C-15N spin coupling patterns observed by 13C NMR, as a new tool in the study of ammonia metabolism.     

Interrelations between ureogenesis and gluconeogenesis in isolated hepatocytes. The role of antion transport and the competition for energy.

1. Glucose synthesis from lactate plus pyruvate and from lactate plus alanine was measured in the presence or absence of 1mM-oleate or 2mM-octanoate at low (2mM) or high (8mM) concentrations of NH4Cl. 2. Both fatty acids alone or with 2mM-NH4Cl doubled glucose production from lactate plus pyruvate. Glucose synthesis from lactate plus alanine, in the presence of oleate, was decreased 16% by 2mM-NH4Cl. 3. In the presence of fatty acids, 8mM-NH4Cl decreased gluconeogenesis by 60-65% from both lactate plus pyruvate and lactate plus alanine. This inhibition was correlated with a high accumulation of aspartate and a drastic decrease in 2-oxoglutarate and malate in the cells. 4. In the presence of 2mM- or 8 mM-NH4Cl, oleate and glucogenic precursors, the addition of 2.5mM-ornithine stimulated urea synthesis. 5. This was paralleled by a decrease of 16% in glucose synthesis from lactate plus pyruvate in the presence of 2mM-NH4Cl and had no effect at 8mM-NH4Cl. In the system producing glucose from lactate plus alanine, ornithine completely reversed the inhibition caused by 2mM-NH4Cl and only partly that by 8mM-NH4Cl. 6. Gluconeogenesis from pyruvate was also inhibited by 2mM-NH4Cl in the presence of oleate or ethanol. This way due to the decrease of malate, which is the C4 precursor of glucose in this system. 7. The limitation of gluconeogenesis by 2-oxoglutarate and malate concentrations in the liver cell and the competition for energy between glucose and urea synthesis is discussed.     

Control by pH of urea synthesis in isolated rat hepatocytes

Control by pH of urea synthesis has been studied in isolated rat hepatocytes incubated with a physiological mixture of amino acids. Inhibition of urea synthesis by decreasing the pH of the medium was caused by diminished production of ammonia and not, as suggested in the literature, by inhibition of entry of ammonia into the ornithine cycle. The decrease by low pH of the rate of degradation of the added amino acids, that of alanine being quantitatively the most important, was accompanied by a decrease in their intracellular concentration. It is concluded that inhibited transport of amino acids across the plasma membrane of the hepatocyte is responsible, at least in part, for the fall in urea synthesis with decreasing pH. It is proposed that inhibition by low pH of other steps in the ureogenic pathway, distal to the production of ammonia, does not affect flux through the ornithine cycle per se, but rather contributes to the buffering of the intrahepatic concentration of ammonia.     

Functional inhibition of cytosolic and mitochondrial aspartate aminotransferase by l-2-amino-4-methoxy-trans-3-butenoic acid in isolated rat hepatocytes and mitochondria

The transaminase inhibitor l-2-amino-4-methoxy-trans-3-butenoic acid (AMB) decreased aspartate aminotransferase activity by approximately two-thirds in isolated rat liver mitohondria incubated with succinate, ammonia, and ornithine. Aspartate production by the mitochondria was unaffected over the 30-min incubation period, indicating that mitochondrial aspartate aminotransferase activity is normally far in excess of that required for maximal rates of aspartate production. In rat hepatocytes incubated with lactate, ammonia, and ornithine the inhibition of both the cytosolic and mitochondrial isozymes of aspartate aminotransferase by AMB was partially blocked by the presence of ammonia and ornithine. When pyruvate was substituted for lactate as a carbon source with isolated hepatocytes, the presence of ammonia and ornithine blocked the inhibition by AMB of the mitochondrial but not the cytosolic isozyme of aspartate aminotransferase. Urea formation by cells incubated with lactate, ammonia, and ornithine was unaffected by AMB unless the cells were preincubated with the inhibitor prior to the addition of substrates. However, urea formation by cells incubated in the presence of pyruvate, ammonia, and ornithine was inhibited strongly by AMB even without preincubation. The results suggest that the stimulation of ureogenesis from ammonia and ornithine by pyruvate involves the cytosolic isozyme of aspartate aminotransferase. In contrast, the stimulation of ureogenesis elicited by lactate primarily involved mitochondrial aspartate aminotransferase.     

Differential effects of N-acetylglutamate on citrulline synthesis by coupled and uncoupled mitochondria

When rats were placed on a low-protein (5%) diet for 24 h or less, liver mitochondrial acetylglutamate decreased rapidly, carbamyl phosphate synthetase (ammonia) and ornithine transcarbamylase decreased little, and carbamyl phosphate synthesis (measured as citrulline) by isolated mitochondria occurred at very low rates. The matrix acetylglutamate content of these mitochondria, whether coupled or uncoupled, was increased similarly by preincubating them with added acetylglutamate, but citrulline synthesis increased from less than 1 to 2.3 nmol min-1 mg-1 in the coupled state, and from less than 1 to 35 nmol min-1 mg-1 in the uncoupled state. However, when coupled mitochondria were incubated with the substrates required for the synthesis of acetylglutamate in the matrix, citrulline synthesis increased to 48 nmol min-1 mg-1; this rate was similar to that of mitochondria from control rats (fed a normal diet). When mitochondria from controls were incubated with up to 5mM acetylglutamate, citrulline synthesis by coupled mitochondria was increased by 10 to 40%, while synthesis by uncoupled mitochondria was 1.5 to 4 times higher than that observed with the coupled mitochondria; matrix acetylglutamate in both conditions rose to levels similar to those in the medium. The reason for the different behavior of carbamyl phosphate synthetase (ammonia) in coupled and uncoupled mitochondria was not apparent; neither oxidative phosphorylation nor ornithine transport were limiting in the coupled system. These observations are an example of the restrictions imposed upon enzymatic systems by the conditions existing in the mitochondrial matrix, and of the different behavior of carbamyl phosphate synthetase in situ and in solution. In addition, they show that conclusions about the characteristics of the enzyme in coupled mitochondria based on observations made in uncoupled mitochondria are not necessarily justified.