Lactate dehydrogenase associated with the mitochondrial fraction and with a mitochondrial inhibitor--II. Enzyme interaction with a mitochondrial inhibitor

A LDH inhibitor has been isolated from the LDH-free crude mitochondrial fraction of rabbit skeletal muscle. The inhibitor is only released after solubilization of the particle bound enzyme. It only interacts with soluble LDH, since the enzyme bound to the mitochondrial fraction was not inhibited. The inhibitor molecular weight is above 10,000 dalton, it is precipitated by 7.5% trichloroacetic acid or 80% (NH4)2SO4 saturation. It is highly stable to heat and pH variations. The inhibitor only interacts with the enzyme at ionic strengths below 20 mM and at pH 6.0 or less. The kinetic behavior of the inhibited enzyme is non-hyperbolic and is similar to the mitochondrial fraction bound enzyme.     

Lactate dehydrogenase activity in the mitochondrial fraction of chicken liver: enzyme binding and kinetic behavior of soluble and bound enzyme

Chicken liver crude mitochondrial fraction showed lactate dehydrogenase activity (6.5% of cytoplasmic enzyme). Most of the mitochondrial lactate dehydrogenase was solubilized by sonication of the mitochondrial fraction in 0.15 M NaCl, pH 6. Total extracted lactate deshydrogenase activity was 3-fold higher than the initial pellet activity. Different isoenzymatic compositions were observed for cytosoluble and mitochondrial extracted lactate dehydrogenase. The pI, values of the 5 lactate dehydrogenase isoenzymes were found to be independent of their origin. The cytosoluble lactate dehydrogenase and the separated H4,H3M and H2M2 isoenzymes were able to bind to the chicken liver mitochondrial fraction in 5 mM sodium phosphate buffered medium, and could be solubilized afterwards with 0.15 M NaCl, pH 6. The enzyme bound to the mitochondrial fraction was less active than the soluble one. Particle saturation by the bound enzyme occurred with all mitochondrial fractions assayed. According to the Langmuir isotherm, the non-sonicated mitochondrial fractions contain a single type of binding sites for lactate dehydrogenase; in contrast, the sonicated mitochondrial fraction should contain different binding sites. Chicken liver crude or sonicated active mitochondrial fractions showed a hyperbolic behavior with respect to NADH and a non-hyperbolic one with respect to pyruvate. This mechanism is different from the bi-bi compulsory order mechanism of the soluble enzyme. With hydroxypyruvate as the substrate, the active mitochondrial fraction fit a sequential mechanism but lost the rapid-equilibrium characteristics of the soluble enzyme.     

Comparative binding of lactate dehydrogenase to mitochondrial fractions

Beef liver mitochondrial fraction showed LDH activity (1.76 +/- 0.25 U/g pellet). Sixty seven% of the initial mitochondrial pellet LDH activity (almost M4 isoenzyme) was released when suspended in NaCl 0.15 M. When the washed particles were sonicated in a 0.15 M NaCl medium, the solubilized LDH activity (all five isoenzymes as cytosoluble fraction) was 5-fold higher than the initial pellet activity. The different isoenzymatic composition of intramitochondrial and externally bound forms of the enzyme should be taken into account when investigating the physiological role of intramitochondrial LDH. Beef liver cytosoluble LDH (very little content of M4 isoenzyme) showed no affinity for the beef liver mitochondrial fraction but purified M4-LDH isoenzyme was able to bind to the particulate fraction from the same source. This suggests an isoenzyme specificity for the interaction. The maximum amount of cytosoluble LDH bound to the mitochondrial fraction depends on the enzyme and the particulate fraction source. Therefore, binding capacity to the mitochondrial fraction depends not only on the net charge of LDH isoenzymes, which play a predominant role in the binding, but also on individual characteristics of the LDH isoenzymes and mitochondrial fractions from different sources. This suggests that electrostatic forces are not the only ones involved in the binding process.     

Steady state kinetics of soluble and membrane-bound mitochondrial ATPase

Steady state kinetic measurements of the rate of hydrolysis of ATP to ADP and inorganic phosphate by beef heart mitochondrial ATPase have been performed with both the solubilized enzyme and with the enzyme attached to a mitochondrial membrane fraction at 25° in 0.1 M NaCl with Mg²⁺ as the metal ion activator. These studies indicate the ATP Michaelis constants are somewhat larger for the soluble enzyme and the turnover numbers are considerably larger. In addition, the steady state parameters are essentially independent of pH over the range 7–9 for the membrane-bound enzyme, while the turnover number for the soluble enzyme varies considerably with pH. The product, ADP, is a competitive inhibitor of ATP and inhibits the soluble enzyme much more strongly than the membrane-bound enzyme. Oligomycin inhibits the membrane-bound enzyme very strongly, but has no effect on the activity of the soluble enzyme. The oligomycin inhibition is noncompetitive in nature.     

Steady state kinetics of soluble and membrane-bound mitochondrial ATPase

Steady state kinetic measurements of the rate of hydrolysis of ATP to ADP and inorganic phosphate by beef heart mitochondrial ATPase have been performed with both the solubilized enzyme and with the enzyme attached to a mitochondrial membrane fraction at 25° in 0.1 M NaCl with Mg²⁺ as the metal ion activator. These studies indicate the ATP Michaelis constants are somewhat larger for the soluble enzyme and the turnover numbers are considerably larger. In addition, the steady state parameters are essentially independent of pH over the range 7–9 for the membrane-bound enzyme, while the turnover number for the soluble enzyme varies considerably with pH. The product, ADP, is a competitive inhibitor of ATP and inhibits the soluble enzyme much more strongly than the membrane-bound enzyme. Oligomycin inhibits the membrane-bound enzyme very strongly, but has no effect on the activity of the soluble enzyme. The oligomycin inhibition is noncompetitive in nature.     

Lactate dehydrogenase binding to the mitochondrial fraction and to a mitochondrial inhibitor as a function of the isoenzymatic composition

Purified rabbit skeletal muscle LDH M4 isoenzyme, but not H4 isoenzyme, was observed to bind to either the crude mitochondrial fraction or a mitochondrial inhibitor. Several sources of LDH isoenzymes in which M-type subunits with an alkaline pI are predominant bind to this crude mitochondrial fraction and are inhibited by the mitochondrial inhibitor. Binding and inhibition have also been observed with H-type isoenzymes with a pI near 7. The binding and the inhibition processes did not occur with H-type isoenzymes with an acid pI or with M-type isoenzymes with pI near 6. The binding capacity of LDH to the mitochondrial fraction and to the mitochondrial inhibitor is very similar and depends on the net protein charge and not on whether the subunits are H- or M-type.     

Effects of SH group reagents on creatine kinase interaction with the mitochondrial membrane

Solubilization of the specific mitochondrial isoenzyme of creatine kinase (CKm) from rabbit heart mitochondria by treatment with SH group reagents has been studied. From the various compounds tested only the negatively charged organomercurials are able to induce an extensive solubilization of the enzyme. This effect is fully reversible since the solubilized enzyme readily reassociates with the membrane when the bound organomercurial is removed by treatment of the homogenate by an excess of dithiothreitol. Solubilization by negatively charged organomercurials can be partly prevented by pretreatment of mitochondria with either disulfide or uncharged organomercurials. No clear-cut relationship has been pointed out when the amount of SH titrated by various reagents has been compared with the extent of CKm solubilization. More detailed studies with para-chloromercuribenzoate (pCMB) show that extensive CKm solubilization (about 75%) occurs for pCMB concentration as low as 25 microM, whereas pronounced inhibition of the enzyme is observed only for concentrations greater than 200 microM. By cross-reassociation of enzyme solubilized either by para-hydroxymercuribenzoate (pHMB) or by 20 mM sodium phosphate (NaPi) with mitochondria depleted of CKm by pHMB or by NaPi treatment, SH groups whose titration impedes CKm reassociation with the mitochondrial membrane have been tentatively located on the enzyme. Thus, negatively charged organomercurials, could induce a reversible conformational modification of the enzyme which is no longer able to bind on the inner mitochondrial membrane. Furthermore, our results show that the binding of an excess of mitochondrial CK, which has been previously reported, could reflect unspecific binding since it occurs only on mitoplasts incubated in very hypotonic medium, but not in isotonic medium.     

Isolation of L-dynurenine 3-hydroxylase from the mitochondrial outer membrane of rat liver.

Outer membrane preparations of rat liver mitochondria were isolated, after the mitochondria had been prepared by mild digitonin treatment under isotonic conditions. L-Kynurenine 3-hydroxylase [EC 1.14.13.9] was solubilized on a large scale from outer membrane by mixing with 1% digitonin or 1% Triton X-100, followed by fractionation into a minor fraction I and a major fraction II by DEAE-cellulose column chromatography. The distribution of total L-Dynurenine 3-hydroxylase was roughly 20 and 80% in fraction I and II, respectively. Fraction I consisted of crude enzyme loosely bound to anion exchanger. In the present investigation, fraction I was not used because of its low activity and rapid inactivation. In contrast, fraction II consisted of crude enzyme with high activity, excluded from DEAE-cellulose column chromatography in the presence of 1 M KC1. In addition, fraction II was purified by Sephadex G-200 gel filtration and DEAE-Sephadex A-50 column chromatography with linear gradient elution, adding 1 M KC1 and 1% Triton X-100 to 0.05 M Tris-acetate buffer, pH 8.1. After isoelectric focusing, the purified enzyme preparation was proved to be homogeneous, since the L-kynurenine 3-hydroxylase fraction gave a single band on disc gel electrophoresis. The molecular weight of this enzyme was estimated to be approximately 200,000 or more by SDS-polyacrylamide gel electrophoresis and from the elution pattern on Sephadex G-200 gel filtration. A 16-Fold increase of the enzyme activity was obtained compared with that of the mitochondrial outer membrane. The isoelectric point of the enzyme was determined to be pH 5.4 by Ampholine isoelectric focusing.     

Presence in Dry Pea Cotyledons of Soluble Succinate Dehydrogenase That Is Assembled into the Mitochondrial Inner Membrane during Seed Imbibition

SUCCINATE DEHYDROGENASE (SUCCINATE: phenazine methosulfate oxidoreductase, EC 1.3.99.1) activity in crude mitochondrial fraction from pea (var. Alaska) cotyledons increased during seed imbibition to reach a maximum after about 12 hours. The increase was not inhibited by either cycloheximide or d(-)threo-chloramphenicol. The postmicrosomal fraction from dry cotyledons, but not that from fully imbibed ones, contained a soluble form of succinate dehydrogenase. The soluble enzyme was partially purified by ammonium sulfate fractionation and diethylaminoethyl-cellulose and Sepharose 6B column chromatography. The enzyme showed no succinate-coenzyme Q oxidoreductase activity and had a molecular mass of about 100,000 daltons. The soluble enzyme seemed to differ only slightly from succinate dehydrogenase solubilized from the mitochondrial inner membrane from fully imbibed cotyledons by a detergent. It is proposed that the soluble succinate dehydrogenase is associated with an inert mitochondrial inner membrane in dry cotyledons to form an active one during seed imbibition.     

Hepatic nuclease. 2. Association of polyadenylase, alkaline ribonuclease and deoxyribonuclease with rat-liver mitochondria.

Six types of nuclease activities were found to be concentrated in the large granule fraction isolated from rat liver homogenastes by differential centrifugation. Analysis by density equilibration shows that three nucleases are associated with mitochondria: an alkaline ribonulcease (pH optimum 8.8), an alkaline deoxyribonuclease (pH optimum 7.6) and an enzyme acting on polyriboadenylate (pH optimum 7.5). When the outer mitochondrial membrane is ruptured in hypotonic medium, the three mitochondrial nucleases are partially solubilized. Solubilization is however obtained by addition of KCL to the suspension medium. It is concluded that mitochondrial nucleases are localized in the intermembrane space but that an adsorption to the outer face of the inner mitochondrial membrane occurs in sucrose 0.25 M. The mitochondrial localization of alkaline ribonuclease, alkaline deoxyribonuclease and polyadenylate accounts for at least 80% of the activity of liver homogenate; nevertheless, an excess of these enzymes is present in the microsomal fraction. Although no definite conculusion can be reached for the significance of this observation, it is shown by density equilibration analysis that these nuclease are not associated either with ribosomes or with the membranes which are the major component of the microsomal fraction.     

Heart 6-phosphofructo-1-kinase. Subcellular distribution and binding to myofibrils

6-Phosphofructo-1-kinase (phosphofructokinase) (ATP:D-fructose-6-P 1-phosphotransferase, EC 2.7.1.11) can be identified in sheep heart homogenates in two forms, a soluble form and a form bound to the particulate fraction. Homogenates from immediately-dissected hearts have the enzyme in the soluble form, while those collected after a delay have the enzyme bound to the particulate fraction. Aldolase appears to show the same change in its location. Homogenization in a solution with concentrated macromolecular species (20% albumin) results in a greater association of phosphofructokinase and of aldolase to the particulate fraction in homogenates from immediately dissected hearts. Phosphofructokinase activity can be solubilized by two specific means: by high ionic strength, which is dependent upon specific salts; or by low ionic strength, which is dependent upon the presence of phosphofructokinase substrates or modifier ligands. These two means of solubilization are affected differently upon decreasing the pH below 6.9: the solubilization at low ionic strength is prevented, whereas phosphofructokinase is still solubilized by high ionic strength. Under the latter condition, the enzyme is in the inactive dimeric state, which can be activated at an alkaline pH. Myofibrils present in the particulate fraction can account for the binding of phosphofructokinase in heart homogenates. Purified myofibrils, when added to heart supernatant fluids, can bind phosphofructokinase at a slightly acidic pH. Conditions for phosphofructokinase binding to myofibrils, as well as its dissociation, follow what was observed with the binding of phosphofructokinase to the particulate fraction. At an acidic pH, and in the presence of a high concentration of ATP, phosphofructokinase exhibits low activity. However, if phosphofructokinase is assayed under these conditions while bound to myofibrils, the enzyme is activated.     

Interaction of malonyl-CoA and 2-tetradecylglycidyl-CoA with mitochondrial carnitine palmitoyltransferase I

Malonyl-CoA and 2-tetradecylglycidyl-CoA (TG-CoA) are potent inhibitors of mitochondrial carnitine palmitoyltransferase I (EC 2.3.1.21). To gain insight into their mode of action, the effects of both agents on mitochondria from rat liver and skeletal muscle were examined before and after membrane disruption with octylglucoside or digitonin. Pretreatment of intact mitochondria with TG-CoA caused almost total suppression of carnitine palmitoyltransferase I, with concomitant loss in malonyl-CoA binding capacity. However, subsequent membrane solubilization with octylglucoside resulted in high and equal carnitine palmitoyltransferase activity from control and TG-CoA pretreated mitochondria; neither solubilized preparation showed sensitivity to malonyl-CoA or TG-CoA. Upon removal of the detergent by dialysis the bulk of carnitine palmitoyltransferase was reincorporated into membrane vesicles, but the reinserted enzyme remained insensitive to both inhibitors. Carnitine palmitoyltransferase containing vesicles failed to bind malonyl-CoA. With increasing concentrations of digitonin, release of carnitine palmitoyltransferase paralleled disruption of the inner mitochondrial membrane, as reflected by the appearance of matrix enzymes in the soluble fraction. The profile of enzyme release was identical in control and TG-CoA pretreated mitochondria even though carnitine palmitoyltransferase I had been initially suppressed in the latter. Similar results were obtained when animals were treated with 2-tetradecylglycidate prior to the preparation of liver mitochondria. We conclude that malonyl-CoA and TG-CoA interact reversibly and irreversibly, respectively, with a common site on the mitochondrial (inner) membrane and that occupancy of this site causes inhibition of carnitine palmitoyltransferase I, but not of carnitine palmitoyltransferase II. Assuming that octylglucoside and digitonin do not selectively inactivate carnitine palmitoyltransferase I, the data suggest that both malonyl-CoA and TG-CoA interact with a regulatory locus that is closely juxtaposed to but distinct from the active site of the membrane-bound enzyme.     

A calmodulin endoproteinase from mitochondrial membranes

A proteinase specific for calmodulin has been identified in a crude rat kidney Triton-extracted or sonicated mitochondrial fraction and solubilized by EGTA extraction of these membranes. Mitochondrial fractions from other tissues had less activity, with relative activities: kidney = spleen greater than testes greater than liver, and no detectable activity in either brain or skeletal muscle. This enzyme is active in the presence of EGTA, but not in the presence of calcium, and cleaves calmodulin into three major peptide fragments with Mr 6000, 9000 and 10,000. N-methylated and non-methylated calmodulins were both cleaved by calmodulin proteinase and while troponin was a poor substrate, it was cleaved in the presence of either calcium or EGTA. No other EF hand calcium-binding proteins or other major mitochondrial proteins were cleaved by this enzyme. The peptides resulting from calmodulin proteinase action were isolated by reverse-phase high performance liquid chromatography (HPLC) and sequenced. Sequence analysis indicated that calmodulin proteinase cleaves calmodulin at Lys-75. The effects of proteinase inhibitors indicate that calmodulin proteinase is a trypsin-like enzyme belonging to the serine endopeptidase family of enzymes.     

Some properties of mitochondrial and cell sap alanine aminotransferase of the rat heart.

Alanine aminotransferase activity is present in mitochondria and the cell sap fraction of the rat myocardium. As distinct from the cell sap form, mitochondrial alanine aminotransferase was significantly inhibited by chloride ions, maleate and incubation medium temperatures of over 40 degrees C. Activity of the cell sap enzyme was inhibited by phosphate and stimulated by temperatures of over 40 degrees C. The pH optimum for cell sap alanine aminotransferase was in the region of 8, while for the mitochondrial enzyme it had a wider range (pH 7.3-8.2). D,L-penicillamine, and antagonist of vitamin B6, inhibited alanine aminotransferase activity equally in intact and tritonized mitochondria and in the cell sap fraction. The activity of mitochondrial and cell sap alanine aminotransferease rose in correlation to the stage of ontogenesis, the maximum increase being observed in the cell sap fraction 14-20 days after birth. The addition of coenzyme to the incubation medium did not affect the activity of either mitochondrial or cell sap alanine aminotransferase. The results indicate that there are two different alanine aminotransferase enzymes in the rat heart, with different intracellular localizations and probably with different regulative functions.     

Kinetic behaviour of soluble and mitochondrial bound lactate dehydrogenase

Rabbit liver mitochondrial fraction shows lactate dehydrogenase activity. The kinetic behaviour of mitochondrial bound enzyme fits a bibi sequential type mechanism as well as the cytosolic rabbit liver lactate dehydrogenase. The bound enzyme has greater values of Km(NADH) and Km(pyruvate) than the soluble one, suggesting that binding induces a decrease in the affinity of both substrates. The behaviour of the free and the mitochondrial-bound enzyme is of the Michaelis-Menten type, but the kinetics of a mixture of rabbit liver cytosolic and mitochondrial-bound lactate dehydrogenase is sigmoidal, suggesting that a cooperative phenomenon takes place.     

Solubilization and reconstruction of microsomal AMP-deaminase from skeletal muscles]

Microsomal AMP-deaminase was solubilized by 0.5 M KCl after treatment of microsomal membranes with 0.12 M KCl. Using disc-electrophoresis in polyacrylamide gel in the presence of sodium dodecyl sulfate one major protein component (mol. weight about 90 000) and three minor ones with molecular weights of 110 000, 80 000, and 60 000 were found in the soluble fraction. In addition to proteins, the fraction was found in the soluble fraction. In addition to proteins, the fraction was found to contain a small amount of phospholipids. The deaminase found in the solution may be reconstructed into the membranes at a decrease in KCl concentration, part of enzyme being bound in the inactive form under excess of the soluble fraction. Deaminase binding to the membranes is unaffected by the changes within the pH range of 6.2--7.8 and temperature range of 4--10 degrees C. It is assumed that AMP-deaminase is bound to other membrane components by electrostatic bonds.     

Binding of cardiolipin/lecithin and monoamine oxidase to lipid-depleted mitochondrial membrane structure.

Lipid-depleted pig liver mitochondrial residues were incubated with different proportions of the acidic phospholipid cardiolipin and the zwitterionic phospholipid lecithin in either separate or mixed liposomes. When cardiolipin and lecithin were present in separate liposomes all of the cardiolipin but no lecithin bound to the residues. When present in the same liposomes, cardiolipin also caused binding of lecithin to the mitochondrial residues. When monoamine oxidase solubilized from pig liver mitochondria by extraction of the phospholipids was included in the incubation, binding of the enzyme to the residues occurred in the presence of cardiolipin. The percentage of enzyme bound followed the same trend as the binding of phospholipids to the mitochondrial residues.     

Opposite changes with age in liver and muscle in the mitochondrial and soluble glucose-1,6-bisphosphate and 6-phosphogluconate dehydrogenase

Glucose-1,6-bisphosphate (Glc-1,6-P2), the powerful regulator of carbohydrate metabolism, was markedly decreased in liver of adult rats (2 months of age) as compared to young rats (1-2 weeks of age). This regulator was found to be present in both the mitochondrial and soluble fractions of liver. Its concentration in both these fractions was decreased with age. Concomitant to the decrease in Glc-1,6-P2, which is a potent inhibitor of 6-phosphogluconate dehydrogenase, the activity of this enzyme was markedly increased with age in both the mitochondrial and soluble fractions. However, the increase in this enzyme's activity was more pronounced in the mitochondrial fraction. The mitochondrial enzyme was more susceptible to inhibition by Glc-1,6-P2 as compared to the soluble enzyme, and this may explain the greater enhancement in its activity with age in this fraction. The tibialis anterior muscle exhibited changes with age opposite to those found in liver; Glc-1,6-P2 concentration, in both the mitochondrial and soluble fractions of muscle increased with age, and this increase was accompanied by a concomitant reduction in the activity of the mitochondrial and soluble 6-phosphogluconate dehydrogenase. Similar to liver, the mitochondrial enzyme was more affected by age, as it also exhibited a greater susceptibility to inhibition by Glc-1,6-P2.     

Invertase activity associated with the walls of Solanum tuberosum tubers

Three fractions with invertase activity (beta-D-fructofuranoside fructohydrolase, EC 3.2.1.26) were isolated from mature Solanum tuberosum tubers: acid soluble invertase, invertase I and invertase II. The first two invertases were purified until electrophoretic homogeneity. They are made by two subunits with an apparent M(r) value of 35,000 and their optimal pH is 4.5. Invertase I was eluted from cell walls with ionic strength while invertase II remained tightly bound to cell walls after this treatment. This invertase was solubilized by enzymatic cell wall degradation (solubilized invertase II). Their K(m)s are 28, 20, 133 and 128 mM for acid soluble invertase, invertase I, invertase II and solubilized invertase II, respectively. Glucose is a non-competitive inhibitor of invertase activities and fructose produces a two site competitive inhibition with interaction between the sites. Bovine serum albumin produces activation of the acid soluble invertase and invertase I while a similar inhibition by lectins and endogenous proteinaceous inhibitor from mature S. tuberosum tubers was found. Invertase II (tightly bound to the cell walls) shows a different inhibition pattern. The test for reassociation of the acid soluble invertase or invertase I on cell wall, free of invertase activity, caused the reappearance of all invertase forms with their respective solubilization characteristics and molecular and kinetic properties. The invertase elution pattern, the recovery of cell wall firmly bound invertase and the coincidence in the immunological recognition, suggest that all three invertases may be originated from the same enzyme. The difference in some properties of invertase II and solubilized invertase II from the other two enzymes would be a consequence of the enzyme microenvironment in the cell wall or the result of its wall binding.