The intracellular location of pyruvate carboxylase, citrate synthase and 3-hydroxyacyl-CoA dehydrogenase in lactating rat mammary gland.

The intracellular location of pyruvate carboxylase (EC 6.4.1.1), citrate synthase (EC 4.1.3.7) and 3-hydroxyacyl-CoA dehydrogenase (EC 1.1.1.35) in rat mammary gland was investigated by using a fractional-extraction technique. The results indicate a mitochondrial location for all three enzymes.     

Phosphoenolpyruvate carboxykinase and pyruvate carboxylase in developing rat liver

1. Phosphoenolpyruvate carboxykinase and pyruvate carboxylase were measured in foetal, newborn and adult rat liver extracts by a radiochemical assay involving the fixation of [¹⁴C]bicarbonate. 2. Pyruvate-carboxylase activity in both foetal and adult liver occurs mainly in mitochondrial and nuclear fractions, with about 10% of the activity in the cytoplasm. 3. Similar studies of the intracellular distribution of phosphoenolpyruvate carboxykinase show that more than 90% of the activity is in the cytoplasm. However, in the 17-day foetal liver about 90% of the activity is in mitochondria and nuclei. 4. Pyruvate-carboxylase activity in both particulate and soluble fractions is very low in the 17-day foetal liver and increases to near adult levels before birth. 5. Phosphoenolpyruvate-carboxykinase activity in the soluble cell fraction increases 25-fold in the first 2 days after birth. This same enzyme in the mitochondria has considerable activity in the foetal and adult liver and is lower in the newborn. 6. Kinetic and other studies on the properties of phosphoenolpyruvate carboxykinase have shown no differences between the soluble and mitochondrial enzymes. 7. It is suggested that the appearance of the soluble phosphoenolpyruvate carboxykinase at birth initiates the rapid increase in overall gluconeogenesis at this stage.     

Mitochondrial location of pyruvate carboxylase in Aspergillus niger

Pyruvate carboxylase has been found in the mitochondrial fraction of two strains of Aspergillus niger along with the marker enzymes of citrate synthase and cytochrome c oxidase. The location of pyruvate carboxylase in A. nidulans was, however, confirmed to be in the cytosolic fraction. The enzyme from the former sources was dependent upon the presence of acetyl-CoA for full activity; the enzyme from A. nidulans was unaffected by the presence or absence of acetyl-CoA.     

Some aspects of the kinetics of rat liver pyruvate carboxylase

1. The kinetics of rat liver pyruvate carboxylase were examined and the effect of various agents as activators or inhibitors determined. 2. Essentially similar results were obtained in comparisons of kinetics determined by a radioactivity method involving extracts of acetone-dried powders from whole livers and with a spectrophotometric assay using partially purified enzyme from the mitochondrial fraction. Activity per g of liver from fed or starved rats assayed under optimum substrate and activator conditions was 3 or 6 mumol of oxaloacetate formed/min at 30 degrees C, respectively. 3. The enzyme exhibited cold-lability and lost activity on standing, even in 1.5m-sucrose. 4. The K(m) towards pyruvate was about 0.33mm and towards bicarbonate 4.2mm. K(m) towards MgATP(2-) was 0.14mm. Mg(2+) ions activated the enzyme, in addition to their role in MgATP(2-) formation. From calculations of likely concentrations of free Mg(2+) in the assay medium a K(a) towards Mg(2+) of about 0.25mm was deduced. Mn(2+) also activated the enzyme as well as Mg(2+), but at much lower concentrations. It appeared to be inhibitory when concentrations of free Mn(2+) as low as 0.1mm were present. 5. Excess of ATP is inhibitory, and this appears at least in part independent of the trapping of Mg(2+). 6. Both Co(2+) and Zn(2+) were inhibitory; 2mol of the latter appeared to be bound even in the presence of excess of Mg(2+) and the inhibition was time-dependent. 7. Ca(2+) inhibited by competition with Mg(2+) (K(i) about 0.38mm). The inhibition due to Ca(2+) was less pronounced when activation was with Mn(2+). Inhibition by Ca(2+) and ATP appeared to be additive. 8. Hill plots suggested that no interactions occurred between ATP-binding sites. Although similar plots for total Mg(2+) gave n=3.6, no conclusions could be drawn due to the chelation of the cation with other components of the assay. Similar difficulties arose in assessing the values for Ca(2+). 9. The enzyme was inactive in the absence of acetyl-CoA and showed a sigmoidal response in its presence. K(a) was about 0.1mm with possibly up to four binding sites. Malonyl-CoA was a competitive inhibitor, with K(i) 0.01mm. 10. There was no apparent inhibition by glucose, glucose 6-phosphate, fructose 6-phosphate, fructose 1,6-diphosphate, acetoacetate, beta-hydroxybutyrate, malate, aspartate, pyruvate, palmitoylcarnitine, octanoate, glutathione, butacaine, triethyltin or potassium chloride under the conditions used. Inhibition was found with citrate (possibly by chelation) and adenosine, and also by phosphoenolpyruvate, AMP, ADP and cyclic AMP, K(i) towards the last four being 0.55, 0.76, 0.25 and 1.4mm respectively.     

Intracellular localization of pyruvate carboxylase in mammalian liver

We propose that an adequate amount of extramitochondrial (soluble) pyruvate carboxylase exists in mammalian liver. It has been previously accepted that pyruvate carboxylase is localized in the mitochondria-containing glutamate dehydrogenase. The overall activity and distribution of pyruvate carboxylase and of phosphoenol-pyruvate carboxykinase in mammalian liver has been studied using an improved technique for the fractional extraction of isolated mitochondria. We found about 40% of the total pyruvate carboxylase and about 60 % of the total PEP-carboxykinase in the soluble fraction. Glutamate dehydrogenase was considered to be the ‘marker enzyme’ for mitochondria. Our results strongly support the view that in murine, porcine, bovine and chicken liver, the pyruvate involved in gluconeogenesis is not required to enter the mitochondria prior to its carboxylation to oxalacetate, because extramitochondrial carboxylation of pyruvate through the ‘soluble pyruvate carboxylase’ is possible.     

Effect of thyroid hormone on the turnover of rat liver pyruvate carboxylase and pyruvate dehydrogenase.

Immunochemical techniques have been utilized to study the effect of thyroid status on the content and rates of synthesis and degradation of pyruvate carboxylase and pyruvate dehydrogenase in rat liver. Liver from hyperthyroid rats had twice the pyruvate carboxylase activity of normal rats while thyroidectomized rats had about two-thirds of normal activity. Pyruvate dehydrogenase complex activity was unchanged in the hyperthyroid state but was significantly reduced (by a third) in hypothyroid rats. Changes in catalytic activity during altered thyroid status were by immunochemical means to be closely related to the amount of the hepatic enzymes present. Isotopic studies showed that the changes in the content of pyruvate carboxylase and pyruvate dehydrogenase reflected alterations in the rate of the synthesis of the enzymes with the degradation rates little affected by thyroid status. The half-life for pyruvate carboxylase was 4.6 days, and that for pyruvate dehydrogenase, 8.1 days. In both cases, the turnover time was slower than that of the average mitochondrial protein (t1/2 = 3.8 days) for the control animals.     

Pig liver pyruvate carboxylase. The reaction pathway for the carboxylation of pyruvate

1. The reaction pathway for the carboxylation of pyruvate, catalysed by pig liver pyruvate carboxylase, was studied in the presence of saturating concentrations of K(+) and acetyl-CoA. 2. Free Mg(2+) binds to the enzyme in an equilibrium fashion and remains bound during all further catalytic cycles. MgATP(2-) binds next, followed by HCO(3) (-) and then pyruvate. Oxaloacetate is released before the random release, at equilibrium, of P(i) and MgADP(-). 3. This reaction pathway is compared with the double displacement (Ping Pong) mechanisms that have previously been described for pyruvate carboxylases from other sources. The reaction pathway proposed for the pig liver enzyme is superior in that it shows no kinetic inconsistencies and satisfactorily explains the low rate of the ATP[unk][(32)P]P(i) equilibrium exchange reaction. 4. Values are presented for the stability constants of the magnesium complexes of ATP, ADP, acetyl-CoA, P(i), pyruvate and oxaloacetate.     

Regulation of pyruvate metabolism via pyruvate carboxylase in rat brain mitochondria

1. The fixation of CO(2) by pyruvate carboxylase in isolated rat brain mitochondria was investigated. 2. In the presence of pyruvate, ATP, inorganic phosphate and magnesium, rat brain mitochondria fixed H(14)CO(3) (-) into tricarboxylic acid-cycle intermediates at a rate of about 250nmol/30min per mg of protein. 3. Citrate and malate were the main radioactive products with citrate containing most of the radioactivity fixed. The observed rates of H(14)CO(3) (-) fixation and citrate formation correlated with the measured activities of pyruvate carboxylase and citrate synthase in the mitochondria. 4. The carboxylation of pyruvate by the mitochondria had an apparent K(m) for pyruvate of about 0.5mm. 5. Pyruvate carboxylation was inhibited by ADP and dinitrophenol. 6. Malate, succinate, fumarate and oxaloacetate inhibited the carboxylation of pyruvate whereas glutamate stimulated it. 7. The results suggest that the metabolism of pyruvate via pyruvate carboxylase in brain mitochondria is regulated, in part, by the intramitochondrial concentrations of pyruvate, oxaloacetate and the ATP:ADP ratio.     

Effect of streptozotocin-induced diabetes mellitus on the turnover of rat liver pyruvate carboxylase and pyruvate dehydrogenase.

Immunochemical techniques were used to study the effect of streptozotocin-induced diabetes on the amounts of pyruvate carboxylase and pyruvate dehydrogenase and on their rates of synthesis and degradation. Livers from diabetic rats had twice the pyruvate carboxylase activity of livers from normal rats when expressed in terms of DNA or body weight. The changes in catalytic activity closely paralleled changes in immunoprecipitable enzyme protein. Relative rates of synthesis determined by pulse-labelling studies showed that the ratio of synthesis of pyruvate carboxylase to that of average mitochondrial protein was increased 2.0-2.5 times in diabetic animals over that of control animals. Other radioisotopic studies indicated that the rate of degradation of this enzyme was not altered significantly in diabetic rats, suggesting that the increase in this enzyme was due to an increased rate of synthesis. Similar experiments with pyruvate dehydrogenase, the first component of the pyruvate dehydrogenase complex, showed that livers from diabetic rats had approximately the same amount of immunoprecipitable enzyme protein as the control animals, but a larger proportion of the enzyme was in its inactive state. The rates of synthesis and degradation of pyruvate dehydrogenase were not affected significantly by diabetes.     

Control of pyruvate carboxylase activity by the pyridine-nucleotide redox state in mitochondria from rat liver

Pyruvate carboxylation by isolated mitochondria from rat liver is inhibited by t-butylhydroperoxide in a fully reversible manner. The rate of malate formation at 10 mM pyruvate was decreased by some 80% by 30 microM t-butylhydroperoxide. The effective peroxide concentration was dependent on the mitochondrial hydrogen supply, being increased to about 120 microM in the presence of 50 microM palmitoylcarnitine. Regarding the mechanism(s) of the t-butylhydroperoxide action, pyruvate transport and intramitochondrial energy or activator supply are unlikely involved, because the effect also took place with alanine as the substrate and was not accompanied by a change in the intramitochondrial levels of adenine nucleotides and acetyl-CoA respectively. However, t-butylhydroperoxide caused a rapid fall in the 3-hydroxybutyrate/acetoacetate ratio and a marked increase in the oxidized glutathione content. Therefore, experiments were designed to disclose the participation of the respective redox couples in the expression of pyruvate carboxylase activity. From measurements of NADPH, NADH, oxidized and reduced glutathione contents of mitochondria incubated under a variety of conditions, evidence has been obtained indicating that the mitochondrial NADH supply represents an important factor in the regulation of pyruvate carboxylase activity. The results presented seemingly provide a new basis for the understanding of the functional relationship between beta-oxidation and pyruvate carboxylation.     

Evolution of pyruvate carboxylase and other biotin containing enzymes in developing rat liver and kidney

During contractions, when the rate of ATP hydrolysis exceeds that of ADP phosphorylation, inosine 5'-monophosphate (IMP) accumulates in skeletal muscle. If the cellular energy balance is not promptly restored, subsequent purine degradation to inosine via 5'-nucleotidase can occur, a process that is most robust in the slow-twitch red, as compared to fast-twitch, skeletal muscle. We measured the distribution of 5'-nucleotidase activity among membrane-bound and soluble fractions of fiber specific skeletal muscle sections and found most (80-90%) of the total 5'-nucleotidase activity to be membrane-bound. The 5' IMP nucleotidase activity present in the soluble fraction of muscle extracts differs among fiber types with slow-twitch red > fast-twitch red > mixed fibered > fast-twitch white. Experiments testing the substrate dependence of IMP and AMP dephosphorylation by the soluble fraction of muscle extracts revealed a lower Km toward IMP (approximately 0.7-1.5 mM) than AMP (1.9-2.8 mM). Among skeletal muscle fiber sections, the soluble 5'-nucleotidase activity present in slow-twitch red muscle extracts had the highest substrate affinity, the highest activity with IMP as substrate, and an estimated catalytic efficiency (Vmax/Km) that was > 3-fold higher than calculated for fast-twitch muscle extracts. This is likely due to the Mg2+ dependent cytosolic 5' IMP nucleotidase isoform, since immunoprecipitation experiments revealed 3-4 times more activity in slow-twitch red than in fast-twitch red or fast-twitch white fibers, respectively. These finding are consistent with the previously recognized in vivo pattern of nucleoside formation by muscle where the soleus demonstrated extensive inosine formation at a much lower IMP content than fast-twitch red or fast-twitch white muscle fiber sections.     

Electron microscopic localization of pyruvate carboxylase in rat liver and Saccharomyces cerevisiae by immunogold procedures

The intracellular location of pyruvate carboxylase (EC 6.4.1.1) in rat liver and Saccharomyces cerevisiae was investigated using the antibody-gold and protein A-gold techniques carried out as a postembedding immunoelectron microscopic procedure. The vast majority of gold particles (greater than 98%), indicative of the presence of antigenic sites of pyruvate carboxylase, were found in the mitochondria of rat liver. No other cellular compartment was labeled except the cytosol which did not account for more than 2% of the total labeling of a rat hepatocyte. Furthermore, 60% of labeled pyruvate carboxylase molecules within a mitochondrion were found adjacent to the matrix side of the inner mitochondrial membrane. In contrast, in S. cerevisiae, pyruvate carboxylase was found exclusively in the cytosol.