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.     

The development of mitochondrial oxidative enzymes in rat heart muscle.

Three different developmental patterns have been found in the heart muscle mitochondria: (a) Activity of inner membrane enzymes, succinate-cytochrome c reductase and rotenone-sensitive NADH-cytochrome c reductase, was found to increase rapidly after birth till the 25th day; no further increase was found till the 60th day. Both brances of the respiratory chain, i.e. NADH-dependent and flavoprotein-linked were found to develop in parallel. (b) Activity of retoenone insensitive-NADH cytochrome c reductase, an outer membrane enzyme, did not show any change during developement. (c) Activity of monoamine oxidase, another outer membrane enzyme, was found to increase after the 10th day of postnatal life and the increase in activity continued till the 60th day.     

The development of oxidative enzymes in rat liver mitochondria.

During early postnatal development there was an increase in the specific activity of a number of oxidative enzymes localized on the outer and inner mitochondrial membrane. The succinic oxidase complex of the inner mitochondrial membrane, whose activity in 1-day-old rats was 50% of the value in adult animals, attained the maximum on about the 10th day after birth. Activity of the choline and the proline oxidase complex, both of which are also localized in the inner mitochondrial membrane, was minimal in 1-day-old rats and went on rising after the 10th day. Rotenone-insensitive NADH-cytochrome c reductase activity, which is localized on the outer mitochondrial membrane, remained stable up to the 10th day, and rose between the 10th and the 90th day. Developmental changes in monoaminooxidase activity, which is likewise localized on the outer mitochondrial membrane, followed a similar course to the choline and proline oxidase complexes. The amount of cytochromes a+alpha3 and cytochrome b in isolated mitochondria did not alter during development. The protein spectrum of the mitochondrial particles, determined by polyacrylamide gel electrophoresis in sodium dodecyl sulphate, likewise displayed no marked changes during postnatal development. The above findings show that the metabolic functions of the mitochondria mature during development and that changes in the different enzymes have their own characteristic time course.     

ENZYMATIC PROPERTIES OF THE INNER AND OUTER MEMBRANES OF RAT LIVER MITOCHONDRIA

Treatment of rat liver mitochondria with digitonin followed by differential centrifugation was used to resolve the intramitochondrial localization of both soluble and particulate enzymes. Rat liver mitochondria were separated into three fractions: inner membrane plus matrix, outer membrane, and a soluble fraction containing enzymes localized between the membranes plus some solublized outer membrane. Monoamine oxidase, kynurenine hydroxylase, and rotenone-insensitive NADH-cytochrome c reductase were found primarily in the outer membrane fraction. Succinate-cytochrome c reductase, succinate dehydrogenase, cytochrome oxidase, β-hydroxybutyrate dehydrogenase, α-ketoglutarate dehydrogenase, lipoamide dehydrogenase, NAD- and NADH-isocitrate dehydrogenase, glutamate dehydrogenase, aspartate aminotransferase, and ornithine transcarbamoylase were found in the inner membrane-matrix fraction. Nucleoside diphosphokinase was found in both the outer membrane and soluble fractions; this suggests a dual localization. Adenylate kinase was found entirely in the soluble fraction and was released at a lower digitonin concentration than was the outer membrane; this suggests that this enzyme is localized between the two membranes. The inner membrane-matrix fraction was separated into inner membrane and matrix by treatment with the nonionic detergent Lubrol, and this separation was used as a basis for calculating the relative protein content of the mitochondrial components. The inner membrane-matrix fraction retained a high degree of morphological and biochemical integrity and exhibited a high respiratory rate and respiratory control when assayed in a sucrose-mannitol medium containing EDTA.     

Participation of a cytochrome b5-like hemoprotein of outer mitochondrial membrane (OM cytochrome b) in NADH-semidehydroascorbic acid reductase activity of rat liver

The participation of a cytochrome b₅-like hemoprotein of outer mitochondrial membrane (OM cytochrome b) in the NADH-semidehydroascorbate (SDA) reductase activity of rat liver was studied. NADH-SDA reductase activity was strongly inhibited by antibodies against OM cytochrome b and NADH-cytochrome b₅ reductase, whereas no inhibition was caused by anti-cytochrome b₅ antibody. NADH-SDA reductase exhibited the same distribution pattern as OM cytochrome b-mediated rotenone-insensitive NADH-cytochrome c reductase activity among various subcellular fractions and submitochondrial fractions. Both activities were localized in outer mitochondrial membrane. These observations suggest that OM cytochrome b-mediated rotenone-insensitive NADH-cytochrome c reductase system participates in the NADH-SDA reductase activity of rat liver.     

Transport of phosphatidic acid within the mitochondrion

Transfer of phosphatidic acid from the outer to the inner membrane within intact rat liver mitochondria was assessed by measuring the ratio of lipid 32P to the marker enzyme of the outer membrane, rotenone-insensitive NADH-cytochrome c reductase, in the outer and inner membrane fractions obtained after incubation of mitochondria under conditions for net synthesis of [32P]phosphatidic acid. This transfer was found to proceed with time, to occur only under high ionic strength of the external medium and to be insensitive to N-ethylmaleimide and factors reducing the number of contact sites between the two mitochondrial membranes. These results are interpreted as supporting the idea that phosphatidic acid transport within the mitochondrion occurs as free diffusion through the aqueous phase and not being mediated by phospholipid transfer protein(s).     

THE SURFACE CHARGE OF RAT LIVER MITOCHONDRIA AND THEIR MEMBRANES : Clarification of Some Controversies Concerning Mitochondrial Structure

The surface charge of intact mitochondria and submitochondrial particles was examined by the technique of preparative free flow electrophoresis. When submitochondrial preparations obtained by a swelling-contraction procedure were examined with this technique, two fractions were observed. One of these fractions exhibited the same electrophoretic properties as intact mitochondria, which indicated that it was derived from the outer limiting membrane of the mitochondrion. This fraction was found to contain the enzymes monoamine oxidase and rotenone-insensitive NADH-cytochrome c reductase which have been reported to be localized in the outer mitochondrial membrane. The other fraction exhibited an electrophoretic mobility which was different from that of intact mitochondria, and this fraction contained enzymes characteristic of the inner membrane-matrix fraction such as soluble and particulate enzymes of the Krebs cycle. Microsomes exhibited an electrophoretic mobility which was almost identical with that of the outer mitochondrial membrane. In addition to resolving the localization of enzymes in mitochondrial membranes, these data indicate that the outer limiting membrane of the mitochondrion is the sole determinant of the surface charge of mitochondria.     

Inner- and outer-membrane enzymes of mitochondria during liver regeneration

1. Marker enzymes for the mitochondrial matrix, inner membrane, inter-membrane space and outer membrane were measured in mitochondria isolated from control and regenerating rat liver. The specific activity of these enzymes was then followed for up to 30 days after operation. 2. The specific activity of marker enzymes for the matrix, inner membrane and inter-membrane space remained constant during liver regeneration. 3. However, the specific activities of monoamine oxidase and kynurenine hydroxylase, both outer-membrane markers, fell by 67% and 49% respectively from their control values at 4 days after operation, and returned to normal by about 3 weeks. 4. The repression of kynurenine hydroxylase activity was shown to be unrelated to any independent variation in tryptophan catabolism, based on tryptophan pyrrolase assays. 5. These results are considered to indicate that enzymes of the inner and outer mitochondrial membranes are synthesized asynchronously during morphogenesis. 6. The enzyme complement of purified outer membrane at 4 days after operation was about 50% of that of the appropriate control. Thus the composition of the outer membrane itself may vary dramatically, and supports the concept that constitutive enzymes may turn over independently of a membrane's existence. 7. The behaviour of the rotenone-insensitive, NADH cytochrome c reductase did not parallel the other outer-membrane enzymes for intact mitochondria, but did so when assayed in highly purified fractions of outer membrane. This suggests a labile binding to the outer membrane during the early stages of morphogenesis. 8. Electrophoresis of inner- and outer-membrane proteins revealed little difference between control and experimental mitochondria at 4 days, except for an increase in several, high-molecular-weight components of the outer membrane. These bands closely correspond to similar bands derived from smooth endoplasmic reticulum. 9. The results are discussed in relation to the biogenesis and turnover of mitochondria, and are considered to provide evidence for turnover as a unit, at least for the matrix, inner membrane, inter-membrane space and possibly some form of primary outer membrane.     

Subcellular distribution of OM cytochrome b-mediated NADH-semidehydroascorbate reductase activity in rat liver

Tissue, cellular, and subcellular distributions of OM cytochrome b-mediated NADH-semidehydroascorbate (SDA) reductase activity were investigated in rat. NADH-SDA reductase activity was found in the post-nuclear particulate fractions of liver, kidney, adrenal gland, heart, brain, lung, and spleen of rat. Liver, kidney, and adrenal gland had higher NADH-SDA reductase activity than other tissues, and OM cytochrome b-dependent activity was 60-70% of the total activity. On the other hand, almost all of the reductase activity of heart and brain cells was mediated by OM cytochrome b. The ratio of the OM cytochrome b-mediated activities of NADH-SDA reductase to rotenone-insensitive NADH-cytochrome c reductase varied among these tissues. OM cytochrome b-mediated NADH-SDA reductase and rotenone-insensitive NADH-cytochrome c reductase activities were mainly present in the parenchymal cells of rat liver. The localization of the cytochrome-mediated reductase activities in the outer mitochondrial membrane was confirmed by subfractionation of liver mitochondria. Among the submicrosomal fractions, OM cytochrome b-mediated NADH-SDA reductase activity was highest in the cis-Golgi membrane fraction, in which monoamine oxidase activity was also highest. On the other hand, OM cytochrome b-mediated rotenone-insensitive NADH-cytochrome c reductase activity showed a slightly different distribution pattern from the NADH-SDA reductase activity. Thenoyltrifluoroacetone (TTFA), a metal chelator, effectively inhibited the NADH-SDA reductase activity, though other metal chelators did not affect the activity. TTFA failed to inhibit rotenone-insensitive NADH-cytochrome c reductase activity at the concentration which gave complete inhibition of NADH-SDA reductase activity.     

The role of lipid-protein interactions in NADH-cytochrome c reductase (rotenone-insensitive) of rat liver mitochondria

The phospholipid depletion of rat liver mitochondria, induced by acetone-extraction or by digestion with phospholipase A₂ or phospholipase C, greatly inhibited the activity of NADH-cytochrome c reductase (rotenone-insensitive). A great decrease of the reductase activity also occurred in isolated outer mitochondrial membranes after incubation with phospholipase A₂. The enzyme activity was almost completely restored by the addition of a mixture of mitochondrial phospholipids to either lipid-deficient mitochondria, or lipid-deficient outer membranes. The individual phospholipids present in the outer mitochondrial membrane induced little or no stimulation of the reductase activity. Egg phosphatidylcholine was the most active phospholipid, but dipalmitoyl phosphatidylcholine was almost ineffective. The lipid depletion of mitochondria resulted in the disappearance of the non-linear Arrhenius plot which characterized the native reductase activity. A non-linear plot almost identical to that of the native enzyme was shown by the enzyme reconstituted with mitochondrial phospholipids. Triton X-100, Tween 80 or sodium deoxycholate induced only a small activation of NADH-cytochrome c reductase (rotenone-insensitive) in lipiddeficient mitochondria. The addition of cholesterol to extracted mitochondrial phospholipids at a 1 : 1 molar ratio inhibited the reactivation of NADH-cytochrome c reductase (rotenone-insensitive) but not the binding of phospholipids to lipid-deficient mitochondria or lipid-deficient outer membranes.These results show that NADH-cytochrome c reductase (rotenone-insensitive) of the outer mitochondrial membrane requires phospholipids for its activity. A mixture of phospholipids accomplishes this requirement better than individual phospholipids or detergents. It also seems that the membrane fluidity may influence the reductase activity.     

Activity of the inner and outer membrane oxidative enzymes in brown adipose tissue mitochondria.

1. The specific activity of cytochrome-oxidase, succinate-cytochrome c reductase and su-cinate-oxidase of brown adipose tissue mitochondria of 17-day-old rats was found to be twice as high in brwon adipose tissue mitochondria as in the liver. The specific activity of rotenone-sensitive NADH-cytochrome c reductase and NADH-oxidase was found to be six times higher in brown adipose tissue mitochondria than in the liver. 2. Brown adipose tissue mitochondria have extremely low activity of outer membrane enzymes. When compared with liver the specific activity of rotenone-insensitive NADH-cytochrome c reductase was found to be seven times lower, the specific activity of monoamineoxidase up to 30 times lower according to the substrate used. 3. The optimum conditions for the determination of both NADH-cytochrome c reductases in brown adipose tissue mitochondria were more specified on the base of the following findings: (a) the outer membrane rotenone-insensitive NADH-cytochrome c reductase is strongly inactivated by freezing-thawing, (b) freezing-thawing, alone is insufficient to release completely maximal activity of rotenone-sensitive NADH-cytochrone c reductase, freezing-thawing activite can be further potentiated by e.g. trypsin treatment. 4. The activities of the outer membranes of brown-adipose tissue mitochondria are discussed with regards to the structural integrity of the outer membrane, the activities of the inner membrane enzymes are discussed with regards to the functional specifity of the tissue.     

Biochemical studies on sub-fractions of rat liver mitochondria

Highly purified mitochondria from rat liver were separated into six sub-fractions by differential centrifugation. The sub-fractions represent a spectrum from “heavy” to “very light” mitochondria. Enzymes representative of mitochondrial compartments were assayed to see whether functional differences occurred among the various mitochondrial sub-fractions. Respiratory control and NADH oxidase activity, both of which are indicators of mitochondrial structural integrity, were also measured. An enzyme marker for endoplasmic reticulum (glucose-6-phosphatase, G-6-Pase) was also assayed. Specific activities for monoamine oxidase (outer membrane marker), cytochrome oxidase (inner membrane marker) and malate-cytochrome c reductase did not vary within experimental error in all sub-fractions; similarly, for respiratory control and NADH oxidase activity. Malate dehydrogenase, a component of malate-cytochrome c reductase is located within the matrix surrounded by the inner membrane. Specific activity of adenylate kinase (located between the outer and inner membrane) decreased markedly from the “heavy” mitochondria to the “very light” fractions. Specific activity for G-6-Pase, very low in the “heavy” fractions, increased markedly in the “light” to “very light” fractions. Isopycnic density centrifugation on a linear sucrose density gradient of each of the fractions indicated that the correlation coefficient for the sucrose concentrations at which cytochrome oxidase and G-6-Pase activities peaked was 0.995. Thus the “light” to “very light” mitochondria may represent mitochondria whose outer membrane is still contiguous with the endoplasmic reticulum. Microsomes containing the endoplasmic reticulum peaked on the gradient at a significantly lower sucrose concentration than any of the mitochondrial sub-fractions. A buoyant effect of endoplasmic reticulum still attached to any of the mitochondrial sub-fractions would be expected to lower the density of attached mitochondria and thus give rise to “light” and “very light” mitochondria.     

A comparison of microbody membranes with microsomes and mitochondria from plant and animal tissue

Microbodies (peroxisomes and glyoxysomes), mitochondria, and microsomes from rat liver, dog kidney, spinach leaves sunflower cotyledons, and castor bean endosperm were isolated by sucrose density-gradient centrifugation. The microbody-limiting membrane and microsomes each contained NADH-cytochrome c reductase and had a similar phospholipid composition. NADH-cytochrome c reductase from plant and animal microbodies and microsomes was insensitive to antimycin A, which inhibited the activity in the mitochondrial fractions. The pH optima of cytochrome c reductase in plant microbodies and microsomes was 7.5–9.0, which was 2 pH units higher than the optima for the mitochondrial form of the enzyme. The activity in animal organelles exhibited a broad pH optimum between pH 6 and 9. Rat liver peroxisomes retained cytochrome c reductase activity, when diluted with water, KCl, or EDTA solutions and reisolated. Cytochrome c reductase activity of microbodies was lost upon disruption by digitonin or Triton X-100, but other peroxisomal enzymes of the matrix were not destroyed. The microbody fraction from each tissue also contained a small amount of NADH-cytochrome b₅ reductase activity. Peroxisomes from spinach leaves were broken by osmotic shock and particles from rat liver by diluting in alkaline pyrophosphate. Upon recentrifugation liver peroxisomes yielded a core fraction containing urate oxidase at a sucrose gradient density of 1.23 g × cm⁻³, a membrane fraction at 1.17 g × cm⁻³ containing NADH-cytochrome c reductase, and soluble matrix enzymes at the top of the gradient.     

SEPARATION OF MITOCHONDRIAL MEMBRANES OF NEUROSPORA CRASSA : II. Submitochondrial Localization of the Isoleucine-Valine Biosynthetic Pathway

Separation of Neurospora mitochondrial outer membranes from the inner membrane/matrix fraction was effected by digitonin treatment and discontinuous density gradient centrifugation. The solubilization of four isoleucine-valine biosynthetic enzymes was studied as a function of digitonin concentration and time of incubation in the detergent. The kinetics of the appearance of valine biosynthetic function in fractions outside of the inner membrane/matrix fraction, coupled with enzyme solubilization patterns similar to that for the matrix marker, mitochondrial malate dehydrogenase, indicate that the four isoleucine-valine pathway enzymes are localized in the mitochondrial matrix.     

Influence of Ca2+ on the isolation from rat brain mitochondria of a fraction enriched of boundary membrane contact sites

Data have been obtained suggesting that the complex porin-hexokinase of brain mitochondria may be related to the contact sites between the outer and inner membrane. In the attempt to isolate from brain mitochondria the inner and outer membranes and the boundary membrane contacts, a procedure was developed based on swelling and shrinking of the organelles, followed by sonication and reverse discontinuous density gradient centrifugation. Three fractions were obtained by this technique, which were identified by measuring the relative specific activities of marker enzymes, namely succinate-cytochrome c reductase; NADH-cytochrome c reductase (rotenone insensitive); hexokinase and glutathione transferase, for the inner and outer membranes and contact sites, respectively. The fraction which contains the contact sites is characterized by the highest specific activity of hexokinase and glutathione transferase and by the highest calcium binding capacity; physiological concentrations of this cation produces a sharper separation of this fraction. Results indicate that both the porin-hexokinase gating system of the outer membrane and the calcium transporting complex of the inner membrane are present in the fraction which contains the contact sites.     

Immunochemical subfractionation of a microsomal fraction of rat liver with antibody-coated Staphylococcus aureus cells

The procedure for immunochemical adsorption of vesicles with specific antigen on their outer surfaces was improved. When microsomal vesicles were mixed with Staphylococcus aureus cells coated with the antibody against NADPH-cytochrome c reductase, more than 90% of the enzyme activity was adsorbed on the cell, whereas, only about 10% of the activity was adsorbed on cells coated with the same amount of anti-ovalbumin antibody. NADH-cytochrome c reductase and aldehyde dehydrogenase activities were adsorbed on the cell to the same extent as was NADPH-cytochrome c reductase activity. Under this condition, there was no adsorption of the activities of the marker enzymes of lysosomes and Golgi apparatus, whereas large amounts of the activities of the plasma membrane enzymes were adsorbed. The specific activity of NADPH-cytochrome c reductase in the adsorbed vesicles from the microsomal fractions increased considerably. In contrast, marker enzymes of the Golgi or of the plasma membranes could be enriched in unadsorbed vesicles from the Golgi fractions.     

Dextran causes aggregation of mitochondria and influences their oxidoreductase activities and light scattering

It has been reported that dextrans diminish the intermembrane space of mitochondria, increase the number of contact sites between the inner and the outer mitochondrial membranes, decrease the outer membrane permeability to adenosine 5(')-diphosphate, and change the kinetic properties of mitochondrial kinases. In the present work the influence of dextran M40 (5% w/v) on the oxidoreductase activities of the inner and outer membranes of mitochondria, the interaction of cytochrome c with mitochondrial membranes, and the light scattering by rat liver mitochondria were studied. No influence of dextran on the release of cytochrome c from mitochondria or its interaction with mitochondrial membranes was observed. Decreases in the NADH-oxidase (to 80+/-2% of the control), NADH-cytochrome c reductase (to 26+/-2%), succinate-cytochrome c reductase (to 70+/-5%), and NADH-ferricyanide reductase (to 75+/-3%) activities induced by dextran, which may be due to the mitochondrial aggregation, were observed. The formation of aggregates was registered by light scattering, confirmed by light microscopy, and explained within the framework of the Gouy-Chapman theory of the electrical double layer. The observed mitochondrial aggregation seems to be useful also for understanding the mechanisms of mitochondrial condensation and perinuclear clustering during apoptosis.     

Alterations in enzyme and cytochrome profiles of Rana catesbeiana liver organelles during thyroxine-induced metamorphosis. Changes in membrane-localized phosphohydrolases, oxidoreductases, and cytochrome levels in response to in vivo thyroxine administration.

A primary objective of the present study has been to determine the changes which occur in Rana catesbeiana liver organelle membranes during thyroxine-induced metamorphosis. To this end, enzyme and cytochrome profiles were determined for mitochondria, microsomes, and nuclear membrane fractions isolated from livers of R. catesbeiana tadpoles which had been fasted for 6 days at 15 +/- 0.5 degrees and then immersed in thyroxine, 2.6 X 10(-8) M, for periods of up to 12 days at 23.5 +/- 0.4 degrees. The ratio of total succinate-cytochrome c reductase activity in the initial homogenate fraction to the total activity of this mitochondrial "marker" enzyme recovered in the final mitochondrial fraction remained constant, approximately 0.5, throughout the course of thyroxine treatment; however, after a 3- to 4-day latency the mitochondrial protein mass recovered per unit mass of initial homogenate protein was found to increase significantly (approximately 2-fold by Day 10 of thyroxine treatment). A similar increase was also observed in the yield of microsomal, but not nuclear membrane, protein mass as a function of thyroxine treatment. Prolonged thyroxine treatment (12 days) resulted in approximately 50% decreases in tadpole liver homogenate and microsomal NADH-cytochrome c reductase specific activities; in contrast, mitochondrial and nuclear membrane NADH-cytochrome c reductase specific activities were not altered under the same conditions. In addition, homogenate and microsomal NADPH-cytochrome c reductase specific activities were found to have increased significantly after 12 days of thyroxine treatment; however, the specific activity of NADPH-cytochrome c reductase in the mitochondrial fraction was unchanged. It was also observed that thyroxine treatment resulted in increases in homogenate and microsomal glucose-6-phosphatase specific activities, whereas the mitochondrial as well as nuclear membrane glucose-6-phosphatase specific activities remained unchanged. Furthermore, in contrast to homogenate and mitochondrial monoamine oxidase specific activities, which decreased 30 and 40%, respectively, as a consequence of thyroxine treatment (12 days), the succinate-cytochrome c reductase and oligomycin-sensitive Mg2+ ATPase specific activities determined for these fractions increased significantly. In all instances, changes as a result of thyroxine treatment in membrane-localized homogenate or organelle enzyme specific activities were apparent only after a 3- to 4-day initial latent period. The in vitro effects of thyroxine (10(-10) - 10(-5) M) on the membrane-localized enzyme activities examined in this study were either negligible or, as in the case of mitochondrial succinate-cytochrome c reductase and microsomal NADH-cytochrome c reductase, opposite to the changes observed in response to in vivo thyroxine treatment, with the exception of microsomal NADPH-cytochrome c reductase activity which was enhanced approximately 2-fold by 10(-5) M thyroxine...     

The interaction of rat liver carbamoyl phosphate synthetase and ornithine transcarbamoylase with inner mitochondrial membranes

The intramitochondrial localization of the urea cycle enzymes, carbamoyl phosphate synthetase and ornithine transcarbamoylase, has been examined by both in vitro and in situ studies. The following three lines of evidence are presented to establish that significant fractions of the rat liver enzymes are loosely associated with the inner mitochondrial membrane: 1) when the mitochondrion is fractionated, the enzymes partition between the matrix and membrane fractions in the absence of detergent and partition solely to the matrix in the presence of detergent; 2) the purified enzymes associate with purified inner membrane preparations; and, 3) protein A-gold electron microscopic immunocytochemical analysis of rat liver sections reveals a nonrandom arrangement of the enzyme, with the maximal enzyme density adjacent to the inner mitochondrial membrane. These findings serve as the basis for novel potential mechanisms for regulation of the activity of the enzymes and provide additional evidence for the extensive organization of the mitochondrial matrix. The membrane interaction might also serve as the organizing factor for a carbamoyl phosphate synthetase-ornithine transcarbamoylase or other multienzyme complex.     

Enzyme Distribution in Potato Mitochondria

Enzyme distribution in potato mitochondria was investigatedby selectively disrupting the outer and inner membranes withdigitonin. Antimycin-insensitive NADH-cytochrome c reductase,an outer membrane marker, was released at low digitonin concentrations(0.1 mg mg^–1 mitochondrial protein). Soluble matrix enzymes,fumarase and malate dehydrogenase were released at 0.3–0.4mg digitonin mg^–1 protein, as the inner membrane ruptured.Very little (about 10%) cytochrome oxidase activity was released,even at higher digitonin concentrations, in accord with thisenzyme being an integral inner membrane protein. By this criterionadenylate kinase is also firmly bound to the inner membrane.Evidence indicates that it faces the intermembrane space. Malic enzyme activity was released by the same digitonin concentrationthat released fumarase and malate dehydrogenase, indicatingthat malic enzyme is a soluble matrix enzyme. No activity wasreleased at low digitonin concentrations which selectively breakthe outer membrane, showing that malic enzyme is not presentin the intermembrane space. Considerable catalase activity (20—40 µmol O₂ min^–1mg^–1 protein) was associated with washed mitochondrialpreparations, but 95% of this was lost upon purification ofmitochondria. The remaining activity was firmly bound to themitochondrial membranes.