Immunoblot analysis of glutaminase peptides in intact and solubilized mitochondria isolated from various rat tissues.

Antibodies were prepared against isolated rat renal glutaminase and affinity-purified against the 65 kDa peptide contained in the purified rat brain glutaminase. The affinity-purified IgGs were then used to compare the glutaminase immunoreactive peptides contained in samples that had been subjected to SDS/polyacrylamide-gel electrophoresis and transferred to nitrocellulose. The purified brain glutaminase and isolated brain mitochondria contain 68 and 65 kDa peptides that exhibit nearly equivalent immunostaining. Partial proteolysis of the isolated 68 and 65 kDa peptides with Staphylococcus aureus V8 proteinase produced an identical pattern of immunoreactive proteolytic fragments. However, digestion of the two peptides with chymotrypsin resulted in similar, but slightly different, patterns. The pattern of immunostaining was unaltered even when the brain mitochondria were solubilized with Triton X-100 and stored for 2 days at 4 degrees C. A very similar pattern was observed when intact renal mitochondria were subjected to immunoblot analysis. However, when renal mitochondria were solubilized, the 68 kDa peptide was rapidly degraded to the 65 kDa form. At 4 degrees C this reaction occurs with apparent first-order kinetics and a t1/2 of 35 min. Degradation of the 65 kDa form of the renal glutaminase occurs with much slower kinetics, but is nearly complete after 24 h. Solubilization of mitochondria isolated from various zones of the kidney indicated that the responsible endogenous proteinase was localized primarily in the cortex. Mitochondria isolated from intestinal or renal papillary tissue contain four glutaminase immunoreactive peptides (Mr 68,000, 65,000, 61,000 and 58,000). The smallest of these peptides is identical in size with the single immunoreactive peptide observed in liver tissue.     

Ca(2+)-sensitive reduction of 5,5'-dithiobis-(2-nitrobenzoic acid) by rat liver mitochondria.

Energized rat liver mitochondria in the presence of EGTA reduced linearly 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) at the rate of 7 nmol SH/min per mg protein within more than 1 hour at 20 degrees C. The Km for DTNB, 1.4 mM, was decreased by Mg2+ and spermine to 0.5 and 0.7 mM, respectively. The reaction was suppressed under conditions of decreasing mitochondrial content of NADPH, was blocked by 1,3-bis-(2-chloroethyl)-1-nitrosourea, the inhibitor of disulfide reductases, and was sensitive to external free Ca2+ in the micromolar range. After lysis of mitochondria the reduction of DTNB required the addition of NADPH and EGTA and was inhibited by 1 mM sodium arsenite. These observations suggest that the reduction of DTNB by mitochondria is catalyzed by Ca(2+)-sensitive thioredoxin reductase (EC 1.6.4.5).     

Activity of branched-chain 2-oxo acid dehydrogenase complex in rat liver mitochondria and in rat liver.

Four mitochondrial marker enzymes were used to show that: (1) high-protein (24%) diet increased the rat liver concentration and content of total branched-chain 2-oxo acid dehydrogenase complex (BCDC) by 31% by increasing mitochondrial specific activity of BCDC; (2) starvation increased the liver concentration of BCDC by 25% by decreasing liver weight; the liver content of mitochondria and the mitochondrial specific activity of BCDC were unchanged; (3) protein-free diet decreased rat liver BCDC concentration and content by 20%, by decreasing the liver concentration and content of mitochondria. Protein-free diet increased liver mitochondrial specific activities of L-glutamate, 2-oxoglutarate and NAD-isocitrate dehydrogenases. The validity of a mitochondrial method for the determination of the liver concentration of BCDC and the percentage in the active form in vivo is confirmed, and improvements are described. The experimental basis of criticisms of its use in this regard by Zhang, Paxton, Goodwin, Shimomura & Harris [(1987) Biochem. J. 246, 625-631] was not confirmed. The finding by Harris, Powell, Paxton, Gillim & Nagae [(1985) Arch. Biochem. Biophys. 243, 542-555], that starvation has no effect on the percentage of BCDC in the active form in rat liver, is confirmed.     

Influence of phospholipids on the activity of phosphate-dependent glutaminase in extracts of rat liver mitochondria.

Liver glutaminase can be solubilized from frozen-and-thawed mitochondria by treatment with phospholipase A2. Solubilization by this technique markedly changes the kinetic properties of the enzyme. The properties of the membrane-bound form of the enzyme are partially restored by adding phosphatidylcholine or phosphatidylethanolamine to the phospholipase extract. It is concluded that the kinetic properties of liver glutaminase are a function of the interaction of this enzyme with membrane phospholipids.     

A rapid method for the isolation of intact mitochondria from isolated rat liver cells.

A method is described for the preparation of intact mitochondria from isolated hepatocytesby sonication. Sonication of a suspension of rat liver cells for 10–30 s yields a homogenate from which tightly coupled mitochondria can be isolated. These mitochondria exhibit high respiratory control ratios and normal ADP:O ratios using glutamate plus malate, β-hydroxybutyrate, succinate, or ascorbate plus N,N,N′,N′-tetramethyl-p-phenylendiamine as substrates. The yield of mitochondrial protein is approximately 100–120 mg starting from 5 g of liver tissue. The mitochondrial fraction is essentially free of contaminating plasma membrane and microsomes and contains only small amounts of peroxisomes and lysosomes.     

Mono(ADP-ribosylation) in rat liver mitochondria

This paper investigates protein mono(ADP-ribosylation) in rat liver mitochondria. In isolated inner mitochondrial membranes, in the presence of both ADP-ribose and NAD+, a protein is mono-(ADP-ribosylated) with high specificity. The reaction apparently consists of enzymatic NAD+ glycohydrolysis and subsequent binding of free ADP-ribose to the acceptor protein. In terms of chemical stability, the resulting bond is unique among the ADP-ribose linkages thus far characterized. Formation of a Schiff base adduct between free ADP-ribose and the acceptor protein is excluded. In intact mitochondria at least three classes of proteins are ADP-ribosylated in vivo. One ADP-ribose-protein linkage is of the carboxylate ester type as indicated by its lability in neutral buffer. Another class of ADP-ribosylated proteins requires hydroxylamine for release of ADP-ribose. The third class is stable in hydroxylamine but labile to alkali, similar to the ADP-ribose-cysteine linkage in transducin formed by pertussis toxin.     

Localization and some properties of phosphate-dependent glutaminase in disrupted liver mitochondria.

1. Glutaminase activity in frozen and thawed liver mitochondria was activated by NH4+, phosphate and HCO3-ions and also by ATP . 2. NH4+ and HCO3-ions decreased the requirement of the enzyme for phosphate. The activation by ATP was observed only in the presence of NH4+ or HCO3-ions. 3. In frozen-and-thawed mitochondria, the enzyme was loosely bound to the inner membrane, the Arrhenius plot showing a break at 23 degrees C. On sonication, glutaminase was detached from the membrane and the Arrhenius plot became linear. 4. The apparent Km for glutamine of the membrane-bound form was 6 mM, and that of the soluble form was 21 mM. 5. It is likely that the properties of glutaminase in the intact cell are dependent on the association of this enzyme with the mitochondrial membrane.     

Primer directed poly(A) synthesis in rat liver mitochondria

Rat liver mitochondria contain an endogenous factor highly specific in stimulating the homologous poly(A) polymerase. By using an $\text{in vivo}$ labelling with [³²P] orthophosphate it is possible to prepare a labelled factor and to demonstrate that it is stably incorporated in an acid insoluble molecule. This suggests that the factor probably acts as a primer in the polymerization of ATP molecules, being involved in the recognition between the mitochondrial poly(A) polymerase and the homologous RNA molecules which have to be polyadenylated.     

Isolation of intact mitochondria from the rat liver using vibration

A method for isolating mitochondria from the rat liver is described. In this method the homogenization step is replaced by vibration with the frequency of 50 Hz realized by a simple device. Mitochondria isolated by vibration demonstrate higher indices of the oxidative phosphorylation with succinate and glutamate + malate used as substrates than those isolated by homogenization do. The method described permits decreasing considerably the isolation medium expenditure remaining the mitochondria yield per gram of the liver unchanged.     

Contemporaneous isolation of deoxyribonucleic acid-dependent ribonucleic acid polymerase and poly(A) polymerase from rat liver mitochondria.

A plasma-membrane fraction was isolated from the alga Hydrodictyon africanum by micro-dissection and its phospholipid components were analysed. Phosphatidylcholine was the major phospholipid of the preparation. Both phosphatidylserine and diphosphatidylglycerol were enriched in the fraction compared with the whole cell, but the relative amount of phosphatidylglycerol present was less than that in the whole cell. Phosphatidylinositol was absent from the plasma-membrane preparation.     

Ca2+ ions, an allosteric activator of calcium uptake in rat liver mitochondria

In a previous investigation, I have shown that the kinetics of the Ca uniporter change fundamentally when mitochondria have transitorily lost their membrane potential. The sigmoidal kinetics, usually observed in liver mitochondria, became almost hyperbolic. This means an increase in the affinity for calcium, and hence a considerable acceleration of Ca uptake in the range of low, e.g., physiological calcium concentration. In this investigation I show that extramitochondrial calcium released from the deenergized mitochondria causes the allosteric activation of the Ca uniporter. The dependence of the allosterical activation on the extramitochondrial Ca2+ concentration and on time is described. It is also reported that it is possible to activate allosterically the Ca uniporter of energized mitochondria by a short-term elevation of the extramitochondrial Ca2+ concentration. The process of activation is reversible. It is quickly reversed by the addition of chelators for Ca2+, and it is slowly reversed when the activating Ca2+ has to be removed by the mitochondrial Ca uniporter, though the bulk of extramitochondrial calcium is taken up by it very quickly. Several kinetics of the Ca uniporter are described. The implications of continually changing kinetics of the Ca uniporter are considered for carbon tetrachloride intoxication and the action of alpha 1-adrenergic agonists in liver cells.     

The uptake of silicic acid by rat liver mitochondria.

1. To gain insight into a putative role for mitochondria in silicon metabolism, mitochondrial uptake (by which it is meant the removal from the medium) of silicic acid [Si(OH)4] was studied under conditions minimizing SI(OH)4 polymerization. 2. Measurements of mitochondrial respiration and swelling indicated indirectly a significant uptake of Si(OH)4 as a weak acid, but this was not confirmed when 31Si(OH)4 was used as a tracer. 31Si(OH)4 occupied a mitochondrial volume similar to that of 3H2O and was relatively unaffected by mitochondrial energy status and by the pH gradient across the mitochondrial inner membrane. 3. Uptake was directly proportional to Si(OH)4 concentration in the range 0-3 mM. 4. The uptake consisted of two components: under all conditions examined, the greater quantity, amounting to 1-2nmol of Si(OH)4/mg of mitochondrial protein, was bound, a major portion of it external to the inner membrane, with the lesser quantity free within the matrix space. 5. Equilibration of 31Si(OH)4 between medium and matrix was a slow process, having a half-time of approx. 10 min at 22 degrees C. 6. Mersalyl and N-ethylmaleimide inhibited the uptake by preferentially lowering the amount of Si(OH)4 bound. Their action was somewhat variable, depending on the precise nature of the suspending medium, and suggesting that the bound material may represent polymerized forms of Si(OH)4. 7. It is concluded that Si(OH)4 may penetrate the mitochondrial inner membrane by a simple diffusion mechanism.     

Amino acid production in isolated rat liver mitochondria

Amino acid analyses of mitochondrial membranes are compared with the amino acid composition of whole mitochondria (Alberti, 1964) and found to be very similar except in the cystine content. The composition of the endogenous amino acids found in freshly prepared mitochondria has been established and shown to differ considerably from the amino acid composition of membranes or whole mitochondria. The amino acids produced during anaerobic incubation of mitochondria at pH7.4, on the other hand, resemble the membrane in composition, supporting the view that neutral proteinase activity is responsible for their appearance. Aerobic incubation produces a similar pattern of amino acids except that amino acids such as proline, serine, asparagine, glutamic acid and glutamine, which can be metabolically utilized under aerobic conditions, are present to a smaller extent. The presence of large relative concentrations of endogenous taurine, cysteic acid and oxidized glutathione and the accumulation of taurine during incubation is found. The selective retention of taurine and cysteic acid within the mitochondria is established. It is proposed that the first step in the degeneration of isolated mitochondria results from lipid hydroperoxide accumulation caused by the lack of glutathione reductase in isolated mitochondria.     

Oxidation of reduced nicotinamide hypoxanthine dinucleotide by intact rat liver mitochondria

1. The rate of NADH oxidation catalyzed by intact rat liver mitochondria is greatly stimulated in the presence of oxidized nicotinamide hypoxanthine dinucleotide (NHD⁺).2. Mitochondrial oxidation of external NHDH is from 20- to 40-fold more rapid than that of NADH, although these coenzymes are oxidized at similar rates by sonicated mitochondria.3. NADH and NADPH inhibit, while NADP⁺ stimulates NHDH oxidation.4. NHDH oxidation is inhibited by rotenone and CN^?.5. NHDH oxidation is coupled to the phosphorylation of ADP to ATP, yielding P:2e^? ratios approaching 3.6. These studies indicate that external NHDH is oxidized by the intramito-chondrial respiratory chain NADH dehydrogenase and that the inner mitochondrial membrane is significantly more permeable to NHDH than to NADH. Mammalian liver mitochondria have been reported to catalyze the enzymatic deamination of NAD(H) to NHD(H) [Buniatian, H. C. (1970) in Handbook of Neurochemistry (Lajtha, A., ed.), Vol. 3, pp. 399–411, Plenum Press, London and New York; Movcessian, S. G. and Manassian, R. F. (1967) in Problems of Brain Biochemistry, Vol. 3, pp. 53–66, Academic Press, Yerevan], suggesting a metabolic function for the deaminated analogue. It is concluded that this deamination reaction may be operative in a mechanism for the oxidation of cytoplasmic NADH by the respiratory chain.