CO2 metabolism in the liver

Effect of liver disease and transplantation on urea synthesis in humans: relationship to acid-base status

It has been suggested that hepatic urea synthesis, which consumes HCO-3, plays an important role in acid-base homeostasis. This study measured urea synthesis rate (Ra urea) directly to assess its role in determining the acid-base status in patients with end-stage cirrhosis and after orthotopic liver transplantation (OLT). Cirrhotic patients were studied before surgery (n = 7) and on the second postoperative day (n = 11), using a 5-h primed-constant infusion of [15N2]urea. Six healthy volunteers served as controls. Ra urea was 5.05 +/- 0.40 (SE) and 3.11 +/- 0.51 micromol. kg-1. min-1, respectively, in controls and patients with cirrhosis (P < 0. 05). Arterial base excess was 0.6 +/- 0.3 meq/l in controls and -1.1 +/- 1.3 meq/l in cirrhotic patients (not different). After OLT, Ra urea was 15.05 +/- 1.73 micromol. kg-1. min-1, which accompanied an arterial base excess of 7.0 +/- 0.3 meq/l (P < 0.001). We conclude that impaired Ra urea in cirrhotic patients does not produce metabolic alkalosis. Concurrent postoperative metabolic alkalosis and increased Ra urea indicate that the alkalosis is not caused by impaired Ra urea. It is consistent with, but does not prove, the concept that the graft liver responds to metabolic alkalosis by augmenting Ra urea, thus increasing HCO-3 consumption and moderating the severity of metabolic alkalosis produced elsewhere.

Mitochondrial carbonic anhydrase (isozyme V) in mouse and rat: cDNA cloning, expression, subcellular localization, processing, and tissue distribution

When the human cDNA, isolated on the basis of homology to the murine carbonic anhydrase (CA) "Y" was expressed in COS cells, the human CA was targeted to and processed in mitochondria, as expected for CA-V. However, tissue distribution reported for the corresponding mouse CA Y mRNA was much more limited than that reported for the distribution of CA-V immunostaining in rat tissues. To determine whether the murine cDNA actually encodes a mitochondrial CA activity and to compare the tissue distribution of the homologous murine and rat gene products, we used reverse transcription-PCR to reisolate the murine CA-V candidate cDNA and used the murine cDNA probe to isolate the homologous rat cDNA. We compared the two cDNA sequences, the activities they expressed after transfection of COS cells, and the sites of N-terminal processing of expressed products. In addition, we used antibodies to the C-terminal peptides predicted from each cDNA to compare distribution of CA-V in mouse and rat tissues and to identify CA-Vs in mitochondria isolated from mouse and rat liver. From these studies, we conclude that both mouse and rat CA-V candidate cDNAs encode active CAs that are targeted to and processed in mitochondria and that there are real differences in tissue distribution of CA-V between mouse and rat. However, the findings that are M(r) of CA-V in rat tissues is smaller than that previously reported and that the tissue distribution also differs lead us to conclude that the antibody used in prior reports most likely misidentified another antigen in rat tissues as CA-V.

Control of lactate utilization by extracellular pH in isolated rat liver cells

This study reports the influence of external pH on lactate balance in hepatocytes isolated from fed and 24-hour-starved rats. The effects of changes in extracellular pH on the utilization of lactate by liver cells has been studied in conditions simulating metabolic acidosis (pH 7.15, 10 mmol/L bicarbonate). The addition of lactate to a suspension of liver cells from fed rats shifted the lactate balance from net release to net utilization; the threshold of this shift was about 3 mmol/L in the presence of 10 mmol/L glucose. In these cells, acidic external pH (7.15) played a crucial role in stimulating the lactate utilization as shown by (1) a diminished release of lactate in the absence of lactate addition (-60%); (2) a marked decrease of the threshold of lactate utilization down to 1.2 mmol/L; and (3) a net stimulation of the lactate utilization for concentrations in the physiologic range (2 to 3 mmol/L). The effect of acidosis was mediated by an inhibition of glycolysis (-40%). Besides that, at pH 7.45, the addition of 100 mumol/L AICA-riboside 5-amino-4-imidazolecarboxamide riboside, (an inhibitor of hepatic glycolysis) mimicked the effect of acidosis. Moreover, differences in lactate fluxes between the two pH conditions were decreased in the absence of glucose. In liver cells from starved rats, regardless of the concentration of added lactate, the lactate balance was always directed toward net utilization. Accordingly, a change in external pH from 7.45 to 7.15 had a lesser effect on lactate metabolism than in liver cells from fed rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Human mitochondrial carbonic anhydrase: cDNA cloning, expression, subcellular localization, and mapping to chromosome 16

A full-length cDNA clone encoding human mitochondrial carbonic anhydrase (CA), CA V, was isolated from a human liver cDNA library. The 1123-bp cDNA includes a 55-bp 5' untranslated region, a 915-bp open reading frame, and a 153-bp 3' untranslated region. Expression of the cDNA in COS cells produced active enzyme. The 34-kDa precursor and 30-kDa mature form of CA V were identified on Western blots of COS-cell homogenates by a CA V-specific antibody raised to a synthetic peptide corresponding to the C-terminal 17 aa of CA V. Both 34-kDa and 30-kDa bands were also present in mitochondria isolated from transfected COS cells, whereas only the 30-kDa band was present in mitochondria isolated from normal human liver. The N-terminal sequence determined directly on the 30-kDa soluble CA purified from transfected COS cells indicated that processing of the precursor to mature human CA V involves removal of a 38-aa mitochondrial leader sequence. The 267-aa sequence deduced for mature human CA V shows 30-49% similarity to amino acid sequences of previously characterized human CAs (CA I-CA VII) and 76% similarity to the corresponding amino acid sequence deduced from the mouse cDNA. PCR analysis of DNAs from human-rodent somatic cell hybrids localized the gene for CA V to human chromosome 16, the same chromosome to which CA VII has previously been mapped.

Metabolic zonation of the liver: regulation and implications for liver function

Liver parenchyma shows a remarkable heterogeneity of the hepatocytes along the porto-central axis with respect to ultrastructure and enzyme activities resulting in different cellular functions within different zones of the liver lobuli. According to the concept of metabolic zonation, the spatial organization of the various metabolic pathways and functions forms the basis for the efficient adaptation of liver metabolism to the different nutritional requirements of the whole organism in different metabolic states. The present review summarizes current knowledge about this heterogeneity, its development and determination, as well as about its significance for the understanding of all aspects of liver function and pathology, especially of intermediary metabolism, biotransformation of drugs and zonal toxicity of hepatotoxins.

The intracellular distribution and activities of phosphoenolpyruvate carboxykinase isozymes in various tissues of several mammals and birds

1. The intracellular distribution and/or activities of phosphoenolpyruvate carboxykinase isozymes were determined in liver, kidney, gastrointestinal mucosa, adipose, skeletal muscle, brain, spleen, lung and heart of fed and fasted rabbits, guinea pigs, rats, chickens and pigeons. 2. Liver and kidney of all species contained the highest enzyme activity/g. 3. Carboxykinase activity/g gastrointestinal mucosa of rabbits was quite high compared to the low activity in guinea pig and rat mucosa and essentially undetectable activity in chicken and pigeon mucosa. 4. Activity/g was high in rat brown adipose. 5. Low carboxykinase activity/g was found in skeletal muscle of all species and in white adipose of guinea pig, rabbit and rat although activity was undetectable in white adipose of chicken and pigeon. 6. Carboxykinase activity was essentially undetectable in brain, spleen, lung and heart of all species.

Mitochondrial carbonic anhydrase is involved in rat renal glucose synthesis

At 37 degrees C, pH 7.4, carbonic anhydrase activity (kenz) of disrupted rat renal proximal tubules and cortical mitochondria was 2.5 +/- 0.8 (n = 3) and 0.15 +/- 0.40 (n = 3) ml.mg-1.s-1, respectively. Turnover number for renal mitochondrial carbonic anhydrase (CA V) was 24,000 s-1. CA V activity of intact mitochondria was completely inhibited by 0.15 microM ethoxzolamide (EZ). Intact proximal tubules, prepared from 48-h starved male rats, were incubated at 37 degrees C in 10 mM pyruvate in Krebs-Henseleit bicarbonate saline buffer, 5% CO2-95% O2. The rate of glucose synthesis over 60 min was reduced 50% by including 0.6 microM EZ in the incubation solution. The concentration of NaHCO3 was doubled to 50 mM (with a corresponding decrease in NaCl) and the solution gassed with 10% CO2-90% O2; 2.4 microM EZ no longer decreased glucose synthesis. It was concluded that inhibition of glucose synthesis by EZ was directly a result of inhibiting the carbonic anhydrases. The rate of glucose production was subsequently determined with tubules incubating in a HCO3(-)-free N-2-hydroxyethylpiperazine-N'-2-ethane-sulfonic acid (HEPES) buffer; this rate was decreased 50% by 0.6 microM EZ. These data support the hypotheses that CA V provides HCO3- for pyruvate carboxylase and that CO2 can be provided by tubular metabolism. Intact tubules were incubated in from 5 to 20 mM pyruvate in either 25 or 50 mM HCO3-; in either buffer, the rate of glucose synthesis was similar, increasing with increasing pyruvate concentration. At no pyruvate concentration was there a change in the rate of glucose production when tubules were incubated in 50 mM HCO3- buffer with 1.6 microM EZ. These data also support the hypothesis that CA V provides the HCO3- substrate for pyruvate carboxylation when there is a high rate of intracellular CO2 production and external CO2 is low. It is further concluded that the cytosolic carbonic anhydrase (CA II) and the membrane-bound carbonic anhydrase (CA IV) are not involved in glucose synthesis from pyruvate.

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.

A nondestructive method for the measurement of radioactive 14CO2 in blood

A method for estimation of 14CO2 present in blood and tissular samples is described. It is basically based on the introduction of large amounts of a gas mixture (95% O2, 5% CO2) in the samples which serves to remove the CO2 label by gas dilution. The gas phase is later captured in scintillation vials containing an organic-soluble base that retains the carbon label. The results obtained by means of this methodology show much better recoveries for blood samples than those obtained when the classic acid-diffusion method is used. In addition, it is a very fast procedure which does not alter the pH or protein integrity of the biological sample.

Synthesis of malate from phosphoenolpyruvate by rabbit liver mitochondria: implications for lipogenesis

(1) Rabbit liver mitochondria can convert exogenous phosphoenolpyruvate to malate. (2) Malate production is dependent on phosphoenolpyruvate and HCO3- and is stimulated by CN- or malonate alone and especially in combination. (3) Malate production is inhibited 70% by 3-mercaptopicolinate, a specific inhibitor of phosphoenolpyruvate carboxykinase, and 50-60% by 1,2,3-benzenetricarboxylate, an inhibitor of the tricarboxylate transporter. (4) Rat liver mitochondria incubated with phosphoenolpyruvate under identical conditions do not produce malate. (5) Malate production from phosphoenolpyruvate is stimulated by exogenous GDP or IDP but not by ADP. (6) Data support the conclusion that malate is being produced from oxalacetate generated by reversal of mitochondrial phosphoenolpyruvate carboxykinase. A possible role for this enzyme in hepatic lipogenesis is suggested.

Rat kidney mitochondrial carbonic anhydrase

Mitochondrial carbonic anhydrase has previously been quantitated in liver mitochondria; it was not detected in guinea pig kidney cortical mitochondria. Evidence of this enzyme in rat kidney cortical mitochondria is reported. Electron microscopy showed that intact mitochondria were free of other intracellular organelles. When intact kidney mitochondria were added to isotonic 3'-(N'-morpholino) propanesulfonic acid buffer with 25 mM KHCO3 (1% labeled with 18O) the rate of disappearance of C18O16O was biphasic; this indicates that there is carbonic anhydrase within the inner mitochondrial membrane. Intact rat kidney mitochondria were assayed for carbonic anhydrase activity at 4 degrees C by the changing pH technique. The rate of CO2 hydration in the presence and absence of intact mitochondria was identical; this rate increased when Triton X-100 was added which indicates that all carbonic anhydrase is inside the inner mitochondrial membrane. Carbonic anhydrase activity was quantitated as kenz (units, ml.s-1 mg-1 mitochondrial protein) at 37 degrees C, pH 7.4, in 25 mM NaHCO3 (1% labeled with 18O) by following the rate of disappearance of C18O16O from solutions before and after addition of disrupted mitochondria. Values of Kenz for liver and kidney mitochondria from rats given free access to normal rat chow and water at neutral pH were 0.06 and 0.08 (respectively). Values of kenz for liver and kidney mitochondria from rats fed as above and with free access to water adjusted to pH 2.5 with HCl were 0.04 and 0.16, respectively. Values of kenz for rats starved for 48 h were 0.06 and 0.12 (respectively). The values of kenz remained 0.11-0.14 in liver mitochondria from guinea pigs fed normally, given dilute acid, or starved and the value was always at zero in guinea pig kidney mitochondria. Values of Kenz were measured with disrupted mitochondria by the 18O technique as a function of pH at 25 degrees C, 25 to 75 mM NaHCO3, ionic strength 0.3. From pH 7.0 to 8.0 kenz increased threefold for mitochondria from rat liver, fed rat kidney, and acid rat kidney, and increased eightfold for mitochondria from guinea pig liver. kenz was decreased similarly by increasing HCO3- in mitochondria from rat liver, fed kidney, and acid kidney; it is concluded that carbonic anhydrase in rat liver mitochondria is probably the same isozyme as in rat kidney mitochondria. The published observation that rat kidney cortices are up to 10 times as gluconeogenic from pyruvate as guinea pig kidney cortices can be explained by the presence of mitochondrial carbonic anhydrase in rat but not guinea pig mitochondria.

Inorganic carbon transport in biological systems

1. The flux of inorganic carbon (Ci) is an important biological process. 2. CO2 crosses membranes through passive diffusion and, perhaps active transport while HCO3- crosses membranes via facilitated diffusion and active transport mechanisms. 3. Carbonic anhydrase is ubiquitous and enhances the flux of Ci. 4. Generally, Ci crosses membranes through passive and facilitated diffusion when the flux of Ci, per se, is important and crosses membranes via active transport when cells are regulating their intracellular pH and/or ion levels.

Inhibition of CA V decreases glucose synthesis from pyruvate

The carbonic anhydrase inhibitor acetazolamide reduces citrulline synthesis by intact guinea pig liver mitochondria and also inhibits mitochondrial carbonic anhydrase (CA V) and the more lipophilic carbonic anhydrase inhibitor ethoxzolamide reduces urea synthesis by intact guinea pig hepatocytes in parallel with its inhibition of total hepatocytic carbonic anhydrase activity. Intact hepatocytes from 48-h starved male guinea pig livers were incubated at 37 degrees C in Krebs-Henseleit with 95% O2/5% CO2 at pH 7.1 with 5 mM pyruvate, 5 mM lactate, 3 mM ornithine, 10 mM NH4Cl, 1 mM oleate; with these inclusions both urea and glucose synthesis start with HCO3- -requiring enzymes, carbamyl phosphate synthetase I and pyruvate carboxylase, respectively. Urea and glucose synthesis were inhibited in parallel by increasing concentrations of ethoxzolamide, estimated Ki for each approximately 0.1 mM. In other experiments hepatocytes were incubated at 37 degrees C in Krebs-Henseleit with 95% O2/5% CO2 at pH 7.1 with 10 mM glutamine, 1 mM oleate; with these inclusions glucose synthesis no longer starts with a HCO3- -requiring enzyme. Urea synthesis was inhibited by ethoxzolamide with an estimated Ki of 0.1 mM, but glucose synthesis was unaffected. Intact mitochondria were prepared from 48-h starved male guinea pig livers. Pyruvate carboxylase activity of intact mitochondria was determined in isotonic KCl-Hepes buffer, pH 7.4, 25 degrees C, with 7.5 mM pyruvate, 3 mM ATP, and 10 mM NaHCO3. Inclusion of ethoxzolamide resulted in reduction in the rate of pyruvate carboxylation in intact mitochondria, but not in disrupted mitochondria. It is concluded that carbonic anhydrase is functionally important for gluconeogenesis in the male guinea pig liver when there is a requirement for bicarbonate as substrate.

Urea synthesis and CO2/HCO3- compartmentation in isolated perfused rat liver

With physiological portal HCO3- and CO2 concentrations of 25mM and 1.2mM in the perfusate, respectively, acetazolamide inhibited urea synthesis from NH4Cl in isolated perfused rat liver by 50-60%, whereas urea synthesis from glutamine was inhibited by only 10-15%. A decreased sensitivity of urea synthesis from glutamine to acetazolamide inhibition was also observed when the extracellular HCO3- and CO2 concentrations were varied from 0-50mM and 0-2.4mM, respectively. Stimulation of intramitochondrial CO2 formation at pyruvate dehydrogenase with high pyruvate concentrations (7mM) was without effect on the acetazolamide sensitivity of urea synthesis from NH4Cl. Urea synthesis was studied under conditions of a limiting HCO3- supply for carbamoyl-phosphate synthesis. In the absence of externally added HCO3- or CO2, when 14CO2 was provided intracellularly by [U-14C]glutamine or [1-14C]-glutamine oxidation, acetazolamide had almost no effect on label incorporation into urea, whereas label incorporation from an added tracer H14CO3- dose was inhibited by about 70%. 14CO2 production from [U-14C]glutamine was about twice as high as from [1-14C]glutamine, indicating that about 50% of the CO2 produced from glutamine is formed at 2-oxoglutarate dehydrogenase. The fractional incorporation of 14CO2 into urea was about 13% with [1-14C]-as well as with [U-14C]glutamine. Addition of small concentrations of HCO3- (1.2mM) to the perfusate increased urea synthesis from glutamine by about 70%. This stimulation of urea synthesis was fully abolished by acetazolamide. The carbonate-dehydratase inhibitor prevented the incorporation of added HCO3- into urea, whereas incorporation of CO2 derived from glutamine degradation was unaffected. Without HCO3- and CO2 in the perfusion medium, when 14CO2 was provided by [1-14C]-pyruvate oxidation, acetazolamide inhibited urea synthesis from NH4Cl as well as 14C incorporation into urea by about 50%. Therefore carbonate-dehydratase activity is required for the utilization of extracellular CO2 or pyruvate-dehydrogenase-derived CO2 for urea synthesis, but not for CO2 derived from glutamine oxidation. This is further evidence for a special role of glutamine as substrate for urea synthesis.

Hepatic urea synthesis and pH regulation. Role of CO2, HCO3-, pH and the activity of carbonic anhydrase

In isolated perfused rat liver, urea synthesis from ammonium ions was dependent on extracellular HCO3- and CO2 concentrations when the HCO3-/CO2 ratio in the influent perfusate was constant (pH 7.4). Urea synthesis was half-maximal at HCO3- = 4 mM, CO2 = 0.19 mM and was maximal at HCO3- and CO2 concentrations above 20 mM and 0.96 mM, respectively. At physiological HCO3- (25 mM) and CO2 (1.2 mM) concentrations in the influent perfusate, acetazolamide, the inhibitor of carbonic anhydrase, inhibited urea synthesis from ammonium ions (1 mM) by 50-60% and led to a 70% decrease in citrulline tissue levels. Acetazolamide concentrations required for maximal inhibition of urea synthesis were 0.01-0.1 mM. At subphysiological HCO3- and CO2 concentrations, inhibition of urea synthesis by acetazolamide was increased up to 90%. Inhibition of urea synthesis by acetazolamide was fully overcome in the presence of unphysiologically high HCO3- and CO2 concentrations, indicating that the inhibitory effect of acetazolamide is due to an inhibition of carbonic-anhydrase-catalyzed HCO3- supply for carbamoyl-phosphate synthetase, which can be bypassed when the uncatalyzed intramitochondrial HCO3- formation from portal CO2 is stimulated in the presence of high portal CO2 concentrations. With respect to HCO3- supply of mitochondrial carbamoyl-phosphate synthetase, urea synthesis can be separated into a carbonic-anhydrase-dependent (sensitive to acetazolamide at 0.5 mM) and a carbonic-anhydrase-independent (insensitive to acetazolamide) portion. Carbonic-anhydrase-independent urea synthesis linearly increased with the portal 'total CO2 addition' (which was experimentally determined to be CO2 addition plus 0.036 HCO3- addition) and was independent of the perfusate pH. At a constant 'total CO2 addition', carbonic-anhydrase-dependent urea synthesis was strongly affected by perfusate pH and increased about threefold when the perfusate pH was raised from 6.9 to 7.8. It is concluded that the pH dependent regulation of urea synthesis is predominantly due to mitochondrial carbonic anhydrase-catalyzed HCO3- supply for carbamoyl phosphate synthesis, whereas there is no control of urea synthesis by pH at the level of the five enzymes of the urea cycle. Because HCO3- provision for carbamoyl phosphate synthetase increases with increasing portal CO2 concentrations even in the absence of carbonic anhydrase activity, susceptibility of ureogenesis to pH decreases with increasing portal CO2 concentrations. This may explain the different response of urea synthesis to chronic metabolic and chronic respiratory acidosis in vivo.

The apparent Km of ammonia for carbamoyl phosphate synthetase (ammonia) in situ

Experiments with carbamoyl phosphate synthetase (ammonia) in solution and in isolated mitochondria are reported which show the following. NH3 rather than NH4+ is the substrate of the enzyme. The apparent Km of NH3 for the purified enzyme is about 38 microM. The apparent Km for NH3 measured in intact isolated mitochondria is about 13 microM. This value was obtained for both coupled and uncoupled mitochondria and was unchanged when the rate of carbamoyl phosphate synthesis was increased 2-fold by incubating uncoupled mitochondria in the presence of 5 mM-N-acetylglutamate. According to the literature, the concentration of NH3 in liver is well below the measured apparent Km. On the basis of this and previous work we conclude that, quantitatively, changes in liver [NH3] and [ornithine] are likely to be the most important factors in the fast regulation of synthesis of carbamoyl phosphate and urea. This conclusion is consistent with all available evidence obtained with isolated mitochondria, isolated hepatocytes, perfused liver and whole animals.

Influence of ammonium ions on hepatic de novo pyrimidine biosynthesis

Carbamyl phosphate (CP) is synthesized in the liver by two separate enzymes, CPS I and CPS II. CPS I, an intramitochondrial enzyme involved in ureogenesis, has a relative activity of 500- to 1000-fold greater than CPS II, a cytoplasmic enzyme which initiates the sequence of reactions for pyrimidine biosynthesis. The contributions of NH4Cl (substrate for CPS I) ang glutamine (substrate for CPS II) as precursors for pyrimidine biosynthesis in isolated hepatocytes were compared by measuring their effect on uracil nucleotide pool size, the incorporation of NaH14CO3 into these pools, and the accumulation of orotic acid. Physiological concentrations of NH4Cl caused a marked stimulation of incorporation of radioactivity into uracil nucleotides (6-fold increase at 0.5 mM NH4Cl), and radioactive orotate appeared in both the cells and the medium. In contrast, glutamine (at concentrations up to 10 mM) had no effect on the incorporation of radioactivity into uracil nucleotides, and no orotic acid was detected. Uracil nucleotide pools were expanded up to 50% by low levels of NH4Cl, but there was no expansion of this pool in the presence of added glutamine. NH4Cl-driven pyrimidine de novo biosynthesis was insensitive to feedback inhibition by an expanded uracil nucleotide pool, to galactosamine treatment, and to acivicin treatment, indicating that NH+4 stimulated pyrimidine biosynthesis as a result of CP synthesis by mitochondrial CPS I. The consequence of intramitochondrially produced CP being available for pyrimidine biosynthesis is that the controlling step of this pathway (CPS II) is bypassed. The appearance of orotic acid following NH4Cl stimulation indicated that the rate-controlling step of hepatic de novo pyrimidine synthesis under these conditions was orotate phosphoribosyl transferase. These data indicate that, at physiological concentrations of NH+4, the majority of uracil nucleotides synthesized in isolated rat hepatocytes was derived from intramitochondrially generated CP. The effect of NH4Cl on the output of uridine by the isolated perfused rat liver was examined. In the presence of a single addition of 20 mM NH4Cl, the excretion of uridine was increased from 100-200 to 375 nmol h-1 g-1 liver and orotic acid was released into the circulating perfusate reaching a maximum of 2 microM (in 220 ml of perfusate) after 2 h. With 40 mM NH4Cl, uridine export was increased to 450 nmol h-1 g-1 and a maximum of 5 microM orotic acid was released into the perfusate after 2 h.(ABSTRACT TRUNCATED AT 400 WORDS)

Mitochondrial compartmentation of metabolic CO2 resulting from its site of origin in relation to urea synthesis

In isolated hepatocytes the entry into urea of metabolic 14CO2 derived from [14C] formate is modified by the addition of dichloroacetate and hydroxypyruvate. An explanation is that this results from changes in the cytoplasmic/mitochondrial pH gradient. 14CO2 derived from [1-14C] alanine enters into urea more readily than 14CO2 arising from [1-14C]glutamate. It is proposed that the difference, which is more than 4-fold, is indicative of a preferred pathway for metabolic CO2 in liver mitochondria from pyruvate dehydrogenase to carbamoylphosphate synthetase than form oxoglutarate dehydrogenase. Acetazolamide inhibition of carbonic anhydrase is without effect on this observed incorporation into urea.