Differences in the half-lives of some mitochondrial rat liver enzymes may derive partially from hepatocyte heterogeneity

The different turnover rates of rat liver mitochondrial enzymes make autophagy unlikely to be the main mechanism for degradation of mitochondria. Although alternatives have been presented, hepatocyte heterogeneity has not been considered. Lighter hepatocytes isolated in a discontinuous Percoll gradient contain more glutamate dehydrogenase (GDH) (half-life 1 day) and a more active autophagic system than heavier hepatocytes. The latter contain more carbamoyl phosphate synthase (CPS) and ornithine carbamoyl transferase (OTC) (half-lives 8 days) but less lysosomal activity. As expected, isolated autophagic vacuoles contain, relative to the mitochondrial content, 3-times less OTC and CPS than GDH, probably reflecting a faster lysosomal engulfment of mitochondria in the light hepatocytes (which contain more GDH). These data may explain some of the half-life differences of the enzymes studied.     

Monoclonal antibodies used in immunocytochemical localization by electron microscopy of carbamoyl phosphate synthetase I in liver from rats fed high-protein diets

Carbamoyl phosphate synthetase I (CPS-I) is the most abundant protein of rat liver mitochondria. Biochemical measurements in liver homogenates have shown that the liver from rats fed a high-protein diet contains more CPS-I per gram tissue protein than controls. However, there is no information on changes in the intact tissue at the cellular and mitochondrial level. Therefore, monoclonal antibodies to beef liver CPS-I were produced by the hybridoma technique. Four clones, C-241/1A, B, C, and D secreted immunogammaglobulin (IgG) IgG1. Using C-241/C, we measured by electron microscopy immunogold procedures the labeling of CPS-I in mitochondria from liver of rats fed high protein (casein, 50 and 80% of total food intake) diets. CPS-I (expressed as gold particles/micron2 of mitochondrial cross-sectional area) was greater than in mitochondria from control rats (20% casein diet), whether the rats were fed for 1, 6, or 14 months on the high-protein diets. The immunocytochemical measurements shown here demonstrate that the increase in the level of CPS-I in high-protein diets is a reflection of both the larger number of CPS-I molecules per mitochondrial area and the larger proportion of the total hepatocyte volume occupied by mitochondria. Similar measurements were carried out with glutamate dehydrogenase (GDH) using previously characterized monoclonal antibodies. No differences in GDH labeling were found with high-protein diets. Interestingly, when mitochondria from hepatocytes of rats fed a high-protein diet were divided into two subpopulations on the basis of mitochondrial cross-sectional size (i.e., greater or less than 0.7 micron2), the large mitochondria had 1.2 times more CPS-I and 0.8 times less GDH than the small mitochondria nearby.     

Control of the NADPH supply and GSH recycling for oxidative stress management in hepatoma and liver mitochondria

To unveil what controls mitochondrial ROS detoxification, the NADPH supply and GSH/GSSG recycling for oxidative stress management were analyzed in cancer and non-cancer mitochondria. Therefore, proteomic and kinetomic analyses were carried out of the mitochondrial (i) NADPH producing and (ii) GSH/GSSG recycling enzymes associated to oxidative stress management. The protein contents of the eight enzymes analyzed were similar or even higher in AS-30D rat hepatoma mitochondria (HepM) than in rat liver (RLM) and rat heart (RHM) mitochondria, suggesting that the NADPH/GSH/ROS pathway was fully functional in cancer mitochondria.The Vmax values of IDH-2 were much greater than those of GDH, TH and ME, suggesting that IDH-2 is the predominant NADPH producer in the three mitochondrial types; in fact, the GDH reverse reaction was favored. The Vmax values of GR and GPx were lower in HepM than in RLM, suggesting that the oxidative stress management is compromised in cancer mitochondria. The Km values of IDH-2, GR and GPx were all similar among the different mitochondrial types.Kinetic modeling revealed that the oxidative stress management was mainly controlled by GR, GPx and IDH. Modeling and experimentation also revealed that, due to their higher IDH-2 activity and lower GPx activity presumably by acetylation, HepM (i) showed higher steady-state NADPH levels; (ii) required greater peroxide concentrations to achieve reliable steady-state fluxes and metabolite concentration; and (iii) endured higher peroxide concentrations without collapsing their GSH/GSSG ratios. Then, to specifically prompt lower GSH/GSSG ratios under oxidative stress thus compromising cancer mitochondria functioning, GPx should be re-activated.     

Effect of streptozotocin-diabetes on rat liver mitochondrial adenosine triphosphatase turnover.

The apparent turnover rates of some mitochondrial enzymes can be modified in diabetes. We studied the effect of streptozotocin-diabetes on the half-life of a protein tightly bound to the inner membrane, ATPase. The half-life (t 1/2), measured by the double-isotope technique, decreased by approx. 20% in diabetes (from approximately equal to 2.56 days in controls to approximately equal to 2.06 days in diabetic rats). These results suggest that diabetes produces an increase in degradation of ATPase by a mechanism which is not yet clear, possibly influenced by alterations induced by diabetes in hepatic lysosomes that are associated with hepatic autophagy.     

The subcellular localization of glutamate dehydrogenase (GDH): is GDH a marker for mitochondria in brain?

Glutamate dehydrogenase (GDH, EC 1.4.1.2) has long been used as a marker for mitochondria in brain and other tissues, despite reports indicating that GDH is also present in nuclei of liver and dorsal root ganglia. To examine whether GDH can be used as a marker to differentiate between mitochondria and nuclei in the brain, we have measured GDH by enzymatic activity and on immunoblots in rat brain mitochondria and nuclei which were highly enriched by density-gradient centrifugation methods. The activity of GDH was enriched in the nuclear fraction as well as in the mitochondrial faction, while the activities of other mitochondrial enzymes (fumarase, NAD-isocitrate dehydrogenase and pyruvate dehydrogenase complex) were enriched only in the mitochondrial fraction. Immunoblots using polyclonal antibodies against bovine liver GDH confirmed the presence of GDH in the rat brain nuclear and mitochondrial fractions. The GDH in these two subcellular fractions had a very similar molecular weight of 56,000 daltons. The mitochondrial and nuclear GDH differed, however, in their susceptibility to solubilization by detergents and salts. The mitochondrial GDH could be solubilized by extraction with low concentrations of detergents (0.1% Triton X-100 and 0.1% Lubrol PX), while the nuclear GDH could be solubizeded only by elevated concentrations of detergents (0.3% each) plus KCl (>150mM). Our results indicate that GDH is present in both nuclei and mitochondria in rat brain. The notion that GDH may serve as a marker for mitochondria needs to be re-evaluated.     

Degradation of transplanted rat liver mitochondrial-outer-membrane proteins in hepatoma cells.

Reductively [3H]methylated 3H mitochondrial-outer-membrane vesicles from rat liver and vesicles where monoamine oxidase has been derivatized irreversibly by [3H]-pargyline have been deliberately miscompartmentalized by heterologous transplantation into hepatoma (HTC) cells by poly(ethylene glycol)-mediated vesicle-cell fusion. Fluorescein-conjugated mitochondrial-outer-membrane vesicles have also been used to show that transplanted material is patched, capped and internalized. Reductively methylated outer-membrane proteins and monoamine oxidase are destroyed at the same rate (t1/2 24 h). Mitochondrial-outer-membrane proteins are not degraded at the same rate as HTC plasma-membrane proteins, endogenous cell protein, or endocytosed protein. Transplanted radiolabelled mitochondrial-outer-membrane proteins accumulate intracellularly in structures that are distinct from plasma membrane and lysosomes. However, when mitochondrial-outer-membrane vesicles derivatized with [14C]sucrose are transplanted, the acid-soluble degradation products accumulate in the lysosomal fraction. [14C]Sucrose-conjugated HTC cell plasma membrane accumulates in intracellular structures that are again distinct from plasma membrane and lysosomes. In contrast with the above observations, homologously transplanted mitochondrial-outer-membrane proteins from rat liver are destroyed in hepatocytes at rates that are remarkably similar (t1/2 60-70 h) to the rates in rat liver in vivo [Evans & Mayer (1982) Biochem. Biophys. Res. Commun. 107, 51-58].     

13N as a tracer for studying glutamate metabolism

This mini-review summarizes studies my associates and I carried out that are relevant to the topic of the present volume [i.e. glutamate dehydrogenase (GDH)] using radioactive ¹³N (t_1/2 9.96 min) as a biological tracer. These studies revealed the previously unrecognized rapidity with which nitrogen is exchanged among certain metabolites in vivo. For example, our work demonstrated that (a) the t_1/2 for conversion of portal vein ammonia to urea in the rat liver is ∼10-11 s, despite the need for five enzyme-catalyzed steps and two mitochondrial transport steps, (b) the residence time for ammonia in the blood of anesthetized rats is ≤7-8 s, (c) the t_1/2 for incorporation of blood-borne ammonia into glutamine in the normal rat brain is <3 s, and (d) equilibration between glutamate and aspartate nitrogen in rat liver is extremely rapid (seconds), a reflection of the fact that the components of the hepatic aspartate aminotransferase reaction are in thermodynamic equilibrium. Our work emphasizes the importance of the GDH reaction in rat liver as a conduit for dissimilating or assimilating ammonia as needed. In contrast, our work shows that the GDH reaction in rat brain appears to operate mostly in the direction of ammonia production (dissimilation). The importance of the GDH reaction as an endogenous source of ammonia in the brain and the relation of GDH to the brain glutamine cycle is discussed. Finally, our work integrates with the increasing use of positron emission tomography (PET) and nuclear magnetic resonance (NMR) to study brain ammonia uptake and brain glutamine, respectively, in normal individuals and in patients with liver disease or other diseases associated with hyperammonemia.     

Trans10, cis12-conjugated linoleic acid induces mitochondria-related apoptosis and lysosomal destabilization in rat hepatoma cells

Conjugated linoleic acid (CLA) is a powerful anti-carcinogenic fatty acid. Previously, we showed that 10trans 12cis (10t, 12c) CLA induced apoptotic cell death in rat hepatoma. Here, we demonstrated significant cytotoxic effects of 1 muM 10t, 12c-CLA, but not 9c, 11t-CLA, on dRLh-84 rat hepatoma cells. 9t, 11t and 9c, 11c-CLA also showed low levels of cytotoxic activity. 10t, 12c-CLA activated caspase-3, 9 followed by cytochrome c release from mitochondria into the cytosol. Inhibitors of caspase-3, 9 blocked the cytotoxicity of 10t, 12c-CLA. 10t, 12c-CLA also induced translocation of Bax protein into the mitochondrial membrane and cleavage of Bid protein. Lysosomal destabilization induced by 10t, 12c-CLA was observed by monitoring the re-localization of Acridine Orange and the leakage of beta-hexosaminidase from lysosomes. 10t, 12c-CLA directly degraded the isolated lysosomes from the rat liver. Our observations indicate that 10t, 12c-CLA induces mitochondria-related apoptosis accompanied by lysosomal destabilization in rat hepatoma cells.     

Degradation of epidermal growth factor receptor in rat liver. Membrane topology through the lysosomal pathway.

We have generated and characterized three rabbit polyclonal antibodies that recognize different regions of the epidermal growth factor receptor (EGF-R) and used them to study the degradation of the receptor in the isolated perfused rat liver. Quantitative immunoblot analyses of rat liver homogenates prepared from tissue biopsies collected at various times after epidermal growth factor (EGF) addition showed that both the ectoplasmic and cytoplasmic domains of rat liver EGF-Rs were degraded with similar kinetics (t1/2 = 3.5-3.8 h at 25 degrees C with cycloheximide). No immunoreactive intermediate breakdown products were detected. EGF-stimulated degradation of both receptor domains was inhibited by the thiol protease inhibitor leupeptin, suggesting lysosome involvement in the hydrolysis of the whole molecule. To study this further, protease protection experiments were performed on endosome- and lysosome-enriched fractions isolated from leupeptin-treated livers. We found that the cytoplasmic domains of greater than 90% of the EGF-Rs in endosomal fractions were accessible to digestion when proteinase K was added to the intact vesicle populations, while the ectoplasmic domain was unaltered. In contrast, both the ectoplasmic and cytoplasmic domains of approximately 55% of the EGF-Rs present in lysosome-enriched fractions were inaccessible to proteinase K digestion in the absence of detergent. These findings suggest that movement of EGF-Rs from the limiting membrane of endosomes to the lumen of lysosomes permits the degradation of the entire EGF-R molecule within lysosomes.     

The role of aspartic and cysteine proteinases in albumin degradation by rat kidney cortical lysosomes

We have investigated the degradation of 125I-labeled bovine serum albumin by lysates of rat kidney cortical lysosomes. Maximal degradation of albumin occurred at pH 3.5-4.2, with approximately 70% of the maximal rate occurring at pH 5.0. Degradation was proportional to lysosomal protein concentration (range 100-600 micrograms) and time of incubation (1-5 h). Dithioerythritol (2 mM) stimulated albumin degradation 5- to 10-fold. Albumin degradation was not inhibited by phenylmethanesulfonyl fluoride (1 mM) or EDTA (5 mM), indicating that neither serine nor metalloproteinases are involved to a significant extent. Pepstatin (5 micrograms/ml), an inhibitor of aspartic proteinases, inhibited albumin degradation by approximately 50%. Leupeptin (10 microM) and N-ethylmaleimide (10 mM), inhibitors of cysteine proteinases, decreased albumin degradation by 34 and 65%, respectively. Combinations of aspartic and cysteine proteinase inhibitors produced nearly complete inhibition of albumin degradation. Taken together, these data indicate that aspartic and cysteine proteinases are primarily responsible for albumin degradation by renal cortical lysosomes under these conditions. In keeping with the above data, we have measured high activities of the cysteine proteinases, cathepsins B, H, and L, in cortical tubules, the major site of renal protein degradation. Using the peptidyl 7-amino-4-methylcoumarin (NHMec) substrates (Z-Arg-Arg-NHMec, for cathepsin B; Arg-NHMec for cathepsin H; and Z-Phe-Phe-CHN2-inhibitable hydrolysis of Z-Phe-Arg-NHMec corrected for inhibition of cathepsin B activity for cathepsin L) values obtained were (means +/- SE, mU/mg protein, 1 mU = production of 1 nM product/min, n = 6): cathepsin B, 2.1 +/- 0.34; cathepsin H, 1.35 +/- 0.19; cathepsin L, 14.49 +/- 1.26. In comparison, the activities of cathepsins B, H, and L in liver were: 0.56 +/- 0.03, 0.28 +/- 0.04, and 1.27 +/- 0.16, respectively.     

Induction of glutamate dehydrogenase in the ovine fetal liver by dexamethasone infusion during late gestation

Glucocorticoids near term are known to upregulate many important enzyme systems prior to birth. Glutamate dehydrogenase (GDH) is a mitochondrial enzyme that catalyzes both the reversible conversion of ammonium nitrogen into organic nitrogen (glutamate production) and the oxidative deamination of glutamate resulting in 2-oxoglutarate. The activity of this enzyme is considered to be of major importance in the development of catabolic conditions leading to gluconeogenesis prior to birth. Ovine hepatic GDH mRNA expression and activity were determined in near-term (130 days of gestation, term 147 +/- 4 days) control and acutely dexamethasone-treated (0.07 mg(-1) hr(-1) for 26 hr) fetuses. Dexamethasone infusion had no effect on placental or fetal liver weights. Dexamethasone infusion for 26 hr significantly increased hepatic GDH mRNA expression. This increased GDH mRNA expression was accompanied by an increase in hepatic mitochondrial GDH activity, from 30.0 +/- 7.4 to 58.2 +/- 8.1 U GDH/U CS (citrate synthase), and there was a significant correlation between GDH mRNA expression and GDH activity. The generated ovine GDH sequence displayed significant similarity with published human, rat, and murine GDH sequence. These data are consistent with the in vivo studies that have shown a redirection of glutamine carbon away from net hepatic glutamate release and into the citric acid cycle through the forward reaction catalyzed by GDH, i.e., glutamate to oxoglutarate.     

Electron microscopic localization of glutamate dehydrogenase in rat liver mitochondria by an immunogold procedure and monoclonal and polyclonal antibodies

Glutamate dehydrogenase (GDH) was localized in rat liver by indirect electron microscopic immunogold, using different sizes of gold particles and monoclonal and polyclonal antibodies. Using the protein A-gold technique in double immunocytochemical experiments, both antibodies, at their optimal dilutions, gave similar results. A novel assessment of the distribution of GDH was made by measurements of the number of gold particles per square micrometer of cross-sectional images of individual mitochondria. The data indicate intracellular homogeneity among mitochondria in individual parenchymal cells. The enzyme is almost absent in non-parenchymal cells. Finally, GDH was found mainly in association with the mitochondrial inner membrane.     

Evidence for degradation of intracellular protein in liver lysosomes of fasted rats

Evidence that intracellular protein degradation occurs in lysosomes has been indirect and derived from liver perfusion (1) or the inhibitor studies (2,3). We report here that liver lysosomes of greater purity are obtained from fed rats than from fasted rats. Lysosomes of less purity may contain an enlarged pool of partially degraded intracellular protein; on the other hand, less purity could be due to less marker enzyme, NAβGase. Measurements of NAβGase activity and lysosomal protein of rat livers showed that both NAβGase and lysosomal protein increased upon fasting but protein more so (3.5 and 6.5x, in 2 days). The increase in lysosomal protein is direct evidence that liver lysosomes are involved in intracellular protein degradation during fasting of rats.     

Cooperation of lysosomes and inner mitochondrial membrane in the degradation of carbamoyl phosphate synthetase and other proteins

Carbamoyl phosphate synthetase (CPS) from rat liver is proteolitically inactivated at acid pH by broken lysosomes. Inactivation increases when lysosomes are previously incubated with inner mitochondrial membrane, although this mitochondrial fraction does not inactivate CPS 'per se'. The increased degradation is due to membrane factor(s), most probably mitochondrial proteinase(s), solubilized by lysosomal matrix proteinases, after incubation of the inner mitochondrial membrane fraction with broken lysosomes. This (these ) factor(s) degrade(s) CPS and other proteins in the absence of lysosomal proteinases or when these are inhibited by leupeptin, chymostatin and pepstatin. We have also tested the possible regulation of this degradation and found that ATP and, particularly, acetyl glutamate accelerate the degradation of CPS by the factor(s) liberated from the inner mitochondrial membrane.     

Isopycnic density values for lysosomes and mitochondria in rat adrenal cortex

Adrenocortical tissues of male adult Wistar rats were fractionated by isopycnic density gradient centrifugation. Fractions were analyzed for density, protein and marker enzymes for lysosomes and mitochondria with rat liver being used as a reference tissue for subcellular enzyme distribution. Both lysosomes and mitochondria of adrenal cortex showed unimodal distribution profiles of marker enzymes with their modal isopycnic density values at 1.165. This value was significantly lower than the corresponding ones for lysosomes and mitochondria in rat liver but was very close to those in porcine adrenal cortex. Modal isopycnic density as well as distribution profiles of marker enzymes for lysosomes and mitochondria remained unchanged 24 hr after 0.1 or 10 units of ACTH (Cortrosyn Z) administration. As in porcine adrenal cortex, lysosomes in rat adrenal cortex were characterized by a higher content of cathepsin D than those in rat liver.     

Purification and characterization of glutamate dehydrogenase as another isoprotein binding to the membrane of rough endoplasmic reticulum

Glutamate dehydrogenase (GDH) was purified from rough endoplasmic reticulum (RER) in rat liver using anion-exchange and affinity chromatography. As GDH has been known as an enzyme that exists mainly in the matrix of mitochondria, the properties of purified GDH were compared with those of mitochondrial GDH. The GDH activity in 0. 1% Triton X-100-treated RER subcellular fraction was nearly the same as intact RER, whereas that of the mitochondrial fraction increased by 50% after the detergent treatment. In kinetic values, in addition, mitochondrial GDH had a higher K(m) value for NADP(+) than NAD(+), whereas the K(m) value for NAD(+) was higher than that for NADP(+) in the case of GDH of RER, which showed a difference in specificity to cofactors. Moreover, when two GDH isoproteins were incubated at 42 degrees C or treated with trypsin, GDH from RER was more stable against heat inactivation and less susceptible to proteolysis than mitochondrial GDH in both cases. In addition, GDH of RER had at least five amino acids different from mitochondrial GDH when sequences of N-terminal and several internal peptide fragments were analyzed. These results showed that GDH of RER is another isoprotein of GDH, of whose properties are different from those of mitochondrial GDH.     

Distribution of the integral membrane protein NADH-cytochrome b5 reductase in rat liver cells, studied with a quantitative radioimmunoblotting assay.

The intracellular localization of the post-translationally inserted integral membrane protein, NADH-cytochrome b5 reductase, was investigated, using a quantitative radioimmunoblotting method to determine its concentration in rat liver subcellular fractions. Subcellular fractions enriched in rough or smooth microsomes, Golgi, lysosomes, plasma membrane and mitochondrial inner or outer membranes were characterized by marker enzyme analysis and electron microscopy. Reductase levels were determined both with the NADH-cytochrome c reductase activity assay, and by radioimmunoblotting, and the results of the two methods were compared. When measured as antigen, the reductase was relatively less concentrated in microsomal subfractions, and more concentrated in fractions containing outer mitochondrial membranes, lysosomes and plasma membrane than when measured as enzyme activity. Rough and smooth microsomes had 4-5-fold lower concentrations, on a phospholipid basis than did mitochondrial outer membranes. Fractions containing Golgi, lysosomes and plasma membrane had approximately 14-, approximately 16, and approximately 9-fold lower concentrations of antigen than did mitochondrial outer membranes, respectively, and much of the antigen in these fractions could be accounted for by cross-contamination. No enzyme activity or antigen was detected in mitochondrial inner membranes. Our results indicate that the enzyme activity data do not precisely reflect the true enzyme localization, and show an extremely uneven distribution of reductase among different cellular membranes.     

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.     

An improved procedure for the simultaneous purification in high yield of peroxisomes,lysosomes, and mitochondria from rat liver

Summary Peroxisomes, lysosomes, and mitochondria have been purified from rat liver by sucrose density gradient centrifugation without prior treatment of the animals with Triton WR-1339 or other detergents which cause hyperlipidemia. A crude organelle fraction was first prepared by differential centrifugation of a rat liver homogenate, this fraction contained approximately 70% of the mitochondrial, 40% of the peroxisomal, and 30% of the lysosomal marker enzymes measured in the homogenate. The crude organelle fraction was applied to the top of a sucrose density gradient and centrifuged. A clear separation of the organelles was obtained only when dextran was present in the gradients. Success or failure of the method was found to depend on the particular preparation of dextran used in the gradients. A method for subfractionating dextran was developed which yields dextran fractions that make the separations completely reproducible. Starting with a crude organelle fraction derived from 12 g of liver, approximately 85% of the mitochondrial, 70% of the peroxisomal, and 50% of the lysosomal activities were obtained as pure fractions. The organelle separation takes less than five hours to complete, it represents a substantial improvement over previous methods.