Subcellular fractionation by differential and zonal centrifugation of aerobically grown glucose-de-repressed Saccharomyces carlsbergensis

1. Homogenates were prepared from sphaeroplasts of aerobically grown glucose-de-repressed Saccharomyces carlsbergensis and the distributions of marker enzymes were investigated after differential centrifugation. Cytochrome c oxidase and cytochrome c were sedimented almost completely at 10(5)g-min, and this fraction also contained 37% of the catalase, 27% of the acid p-nitrophenyl phosphatase, 53 and 54% respectively of the NADH- and NADPH-cytochrome c oxidoreductases. 2. Zonal centrifugation indicated complex density distributions of the sedimentable portions of these enzymes and of adenosine triphosphatases and suggested the presence of two mitochondrial populations, as well as a bimodal distribution of peroxisomes and heterogeneity of the acid p-nitrophenyl phosphatase-containing particles. 3. Several different adenosine triphosphatases were distinguished in a post-mitochondrial supernatant that contained no mitochondrial fragments; these enzymes varied in their sensitivities to oligomycin and ouabain and their distributions were different from those of pyrophosphatase, adenosine phosphatase and adenosine pyrophosphatase. 4. The distribution of NADPH-cytochrome c oxidoreductase demonstrated that it cannot be used in S. carlsbergensis as a specific marker enzyme for the microsomal fraction. Glucose 6-phosphatase, inosine pyrophosphatase, cytochrome P-450 and five other enzymes frequently assigned to microsomal fractions of mammalian origin were not detected in yeast under these growth conditions.     

Changes in enzyme activities and distributions during glucose de-repression and respiratory adaptation of anaerobically grown Saccharomyces carlsbergensis

1. During anaerobic glucose de-repression the respiration rate of whole cells of Saccharomyces carlsbergensis remained constant and was insensitive to antimycin A but was inhibited by 30% by KCN. Aeration of cells for 1 h led to increased respiration rate which was inhibited by 80% by antimycin A or KCN. 2. Homogenates were prepared from sphaeroplasts of anaerobically grown, glucose de-repressed cells and the distribution of marker enzymes was investigated after zonal centrifugation on sucrose gradients containing MgCl(2). These homogenates contained no detectable cytochrome c oxidase or catalase activity. The complex density distributions of NADH- and NADPH-cytochrome c oxidoreductases and adenosine triphosphatase(s) [ATPase(s)] were very different from those of anaerobically grown, glucose-repressed cells. 3. The specific activity of total ATPase was lowered and sensitivity to oligomycin decreased from 58 to 7% during de-repression. 4. Cytochrome c oxidase and catalase activities were detectable in homogenates of cells after 10min aeration. Zonal centrifugation indicated complex, broad sedimentable distributions of all enzyme activities assayed; the peaks of activity were at 1.27g/ml. 5. Centrifugation of homogenates of cells adapted for 30min and 3 h indicated a shift of density of the major sedimentable peak from 1.25g/ml (30min) to 1.235g/ml (3 h). After 30min adaptation a minor zone of oligomycin-sensitive ATPase and 15% of the total cytochrome c oxidase activities were detected at rho=1.12g/l; these particles together with those of higher density containing cytochrome c oxidase, ATPase and NADH-cytochrome c oxidoreductase activities were all sedimented at 10(5)g-min. 6. Electron microscopy indicated that the mitochondria-like structures of anaerobically grown, glucose-de-repressed cells were similar to those of repressed cells. After 10min of respiratory adaptation highly organized mitochondria were evident which resembled the condensed forms of mitochondria of aerobically grown, glucose-de-repressed cells. High-density zonal fractions of homogenates of cells after adaptation also contained numerous electron-dense vesicles 0.05-0.2mum in diameter. 7. The possibility that the ;promitochondria' of anaerobically grown cells may not be the direct structural precursors of fully functional mitochondria is discussed.     

The effects of carbon tetrachloride on rat liver microsomes during the first hour of poisoning in vivo, and the modifying actions of promethazine

The effects of an oral administration of carbon tetrachloride on various liver microsomal and supernatant components were studied 1hr. and 2hr. after dosing. The modifications of such early changes resulting from a concomitant administration of promethazine together with the carbon tetrachloride were also investigated. The microsomal components studied were: cytochromes P-450 and b(5); inorganic pyrophosphatase; NADH- and NADPH-cytochrome c reductases; NADH- and NADPH-neotetrazolium reductases; a lipid-peroxidation system associated with the oxidation of NADPH and stimulated by ADP and Fe(2+). NAD- and NADP- DT-diaphorases were measured in the supernatant solution remaining after isolation of liver microsomes, and the distribution of RNA phosphorus between the microsomes and supernatant solution was also determined. Carbon tetrachloride produced a rapid fall in inorganic pyrophosphatase activity, a rather slower decrease in cytochrome P-450 content of the microsomes and small increases in the activities of NADH-cytochrome c reductase and neotetrazolium reductases. The activities of NADPH-cytochrome c reductase, the NADPH-ADP/Fe(2+)-linked lipid-peroxidation system, DT-diaphorases and the content of cytochrome b(5) in the microsomes were unchanged. There was also a loss of RNA phosphorus from the microsomes into the supernatant solution. The RNA phosphorus redistribution, the decrease in inorganic pyrophosphatase and the increases in neotetrazolium reductase activities were at least partially prevented by a concomitant dosing with promethazine. However, the decrease in cytochrome P-450 was not affected by promethazine treatment. These early changes are discussed in terms of the liver necrosis produced by carbon tetrachloride and which is greatly retarded in its onset by the administration of promethazine.     

Distribution of membranes, especially of plasma-membrane fragments, during zonal centrifugations of homogenates from glucose-repressed Saccharomyces Cerevisiae.

1. The distributions of several enzymes and other marker components were examined after zonal centrifugations of whole homogenates from glucose-repressed Saccharomyces cerevisiae on sucrose and iso-osmotic Ficoll, and the composition and morphology of the fractions were investigated. 2. After high-speed zonal centrifugation most of the protein, acid and alkaline phosphatases, alkaline pyrophosphatase, adenosine monophosphatase, beta-fructofuranosidase, alpha-mannosidase, NADPH-cytochrome c oxidoreductase and an appreciable amount of phospholipid and sterol were non-sedimentable, i.e. were at densities below 1.09 (g/cm3). Most of the RNA was at p=1.06-1.08 in Ficoll and at p=1.09-1.11 in sucrose. 3. The bulk of the Mg2+-dependent adenosine triphosphatase (Mg-ATPase) was coincident with the main peak of phospholipid and sterol, at median density 1.10, which was also rich in smooth-membrane vesicles. In Ficoll, a minor peak of phospholipid and sterol at p-1.12-1.15 contained a smaller part of the oligomycin-insensitive Mg-ATPase and heavy membrane fragments. In sucrose, several minor peaks of Mg-ATPase were in the mitochondrial density range, and a peak of oligomycin-insensitive Mg-ATPase coincident with a minor peak of phospholipid and sterol at around p-1.25 contained heavy membrane fragments of high carbohydrate content, especially mannose. 4. Further purification of the oligomycin-insensitive Mg-ATPase containing membrane preparations was performed on Urografin gradients. 5. It is argued that the oligomycin-insensitive Mg-ATPase containing membranes are fragments of the plasma membrane, but have different densities because they contain different amounts of glycoprotein particles.     

Relative Activities and Characteristics of Some Oxidative Respiratory Enzymes from Conidia of Verticillium albo-atrum

Conidia of Verticillium albo-atrum Reinke and Berthold, collected from shake cultures grown in Czapek broth, were sonified for 4 or 8 minutes or ground frozen in a mortar to obtain cell-free homogenates. These were assayed for certain enzymes associated with respiratory pathways. Malic dehydrogenase was the most active, glucose-6-P and NADH dehydrogenase were less active, NADH-cytochrome c reductase, NADPH dehydrogenase, and cytochrome oxidase were low in activity, and succinic dehydrogenase and succinic cytochrome c reductase were very low to negligible in activity. No NADH oxidase activity was detected.

With the exception of NADH-cytochrome c reductase and possibly succinic dehydrogenase and cytochrome c reductase, there was no evident increase in specific activity of the enzymes during germination. Some NADH-cytochrome c reductase and a small amount of succinic-dehydrogenase and cytochrome c reductase were associated with the particulate fraction from 105,000 × g centrifugation. The other enzymes, including cytochrome oxidase, almost completely remained in the supernatant fraction.

Menadione and vitamin K-S(II) markedly stimulated NADH-cytochrome c reductase activity in the supernatant fraction but had much less effect on NADPH-cytochrome c reductase in this fraction or on either of these enzyme systems in the particulate fraction. Electron transport inhibitors affected particulate NADH- and NADPH-cytochrome c reductase activity but had no effect on these in the supernatant fraction.

     

Fractionation by differential and zonal centrifugation of spheroplasts prepared from a glucose-repressed fission yeast Schizosaccharomyces pombe 972h-.

A method is described for the preparation of spheroplasts in high yield from Schizosaccharomyces pombe, by treating cells grown in the presence of glucose and deoxyglucose with snail digestive enzymes. Gentle disruption of such spheroplasts yielded homogenates, from which marker enzymes for nuclei (NAD pyrophosphorylase) and mitochondria (cytochrome c oxidase activity and spectroscopically-detectable cytochromes a + a3) could be quantitatively sedimented by low-speed centrifugation. In contrast to previous findings with Saccharomyces carlsbergensis, cytochrome c oxidase and another mitochondrial enzyme, succinate dehydrogenase, were completely sedimentable by zonal centrifugation in sucrose gradients in the presence of either 2 mM-MgCl2 or 0-4 mM-EDTA. Mitochondria were apparently smaller and of lower buoyant density in gradients containing EDTA. The bulk of the total units of malate dehydrogenase and NADH; cytochrome c oxidoreductase sedimented with mitochondria, whereas NADPH: cytochrome c oxidoreductase was located in fractions containing no mitochondria. The distributions of mitochondrial enzymes were heterogeneous in populations of mitochondria separated on the basis of size or density. The possible origins of mitochondrial heterogeneity in extracts of S. pombe are discussed with special reference to changes in the enzyme activities of cells during the cell cycle.     

Subcellular Distribution of Enzymes in Ochromonas malhamensis*

SYNOPSIS. The activity and distribution of 7 enzymes in Ochromonas malhamensis were studied. Subcellular organelles were separated by centrifugation at 648,000 g min to precipitate the larger particles; the resulting supernatant was centrifuged at 5,560,000 g min to separate the microsomal fraction from the supernatant. Sixty-four percent of the cytochrome oxidase (1.9.3.1 ferrocytochrome c:oxygen oxidoreductase, 81% of the catalase (1.11.1.6 hydrogen-peroxide: hydrogen-peroxide oxidoreductase) and 70% of the urate oxidase (1.7.3.3 urate:oxygen oxidoreductase) activity was associated with the larger particles, altho only 20% of the total protein was found in this fraction. Three acid hydrolases, cathepsin (3.4.4.9 cathepsin C, acid phosphatase (3.1.3.2 orthophosphoric monoesterphosphohydrolase) and acid ribonuclease (2.7.7.17 ribonucleate nucleotido-2′-transferase) were found mostly in the supernate (50-60%, yet their latency and their similar subcellular distribution indicated the presence of lysosomes. After 2.5 hr centrifugation in a sucrose density gradient (ρ= 1.08–1.25, the acid hydrolases showed a broad distribution which differed greatly from cytochrome oxidase associated with mitochondria. Catalase, which could not be separated from cytochrome oxidase by centrifuging on this gradient, had a different distribution after centrifugation on a kinetic gradient. Urate oxidase had a similar distribution to catalase and both these enzymes were latent, indicating the presence of peroxisomes.     

Biochemical studies on rat liver Golgi apparatus. II. Further characterization of isolated Golgi fraction.

Although the preparation of rat liver Golgi apparatus isolated by our method contains appreciable activities of NADH- and NADPH-cytochrome c reductases and glucose-6-phosphatase, these enzymes as well as thiamine pyrophosphatase of the extensively fragmented Golgi fraction are partitioned in aqueous polymer two-phase systems quite differently from those associated with microsomes. Similarly, the partition patterns of acid phosphatase and 5'-nucleotidase of the Golgi fragments differ from those of homogenized lysosomes and plasma membrane, respectively. It is concluded that most, if not all, of these marker enzymes in the Golgi fraction cannot be ascribed to contamination by the non-Golgi organelles. In sucrose density gradient centrifugation the NADH- and NADPH-cytochrome c reductase activities of the Golgi fraction behave identically with galactosyltransferase but differently from the reductase activities of microsomes, again indicating that the reductases are inherently associated with the Golgi apparatus. NADPH-cytochrome c reductase of the Golgi preparation is immunologically identical with that of microsomes. The marker enzymes mentioned above and galactosyltransferase behave differently from one another when the Golgi fragments are subjected to partitioning in aqueous polymer two-phase systems, suggesting that these enzymes are not uniformly distributed in the Golgi apparatus structure.     

Oscillations of enzyme activities during the cell-cycle of a glucose-repressed fission-yeast Schizosaccharomyces pombe 972h

1. Increased specific activities of cytochrome c oxidase, catalase, succinate dehydrogenase, succinate-cytochrome c oxidoreductase, NADH-cytochrome c oxidoreductase and malate dehydrogenase were observed during glucose de-repression of Schizosaccharomyces pombe. 2. The cell-cycle of this organism was analysed by three different methods: (a) harvesting of cells at intervals from a synchronous culture, (b) separation of cells by rate-zonal centrifugation into different size classes and (c) separation of cells by isopycnic-zonal centrifugation into different density classes. 3. Measurement of enzyme activities during the cell-cycle showed that all the enzymes assayed [cytochrome c oxidase, catalase, acid p-nitrophenylphosphatase, NADH-dehydrogenase, NADH-cytochrome c oxidoreductase, NADPH-cytochrome c oxidoreductase, succinate dehydrogenase, malate dehydrogenase, isocitrate dehydrogenase (NADP) and fumarate hydratase] show periodic expression as ;peaks'. 4. Cytochrome c oxidase shows a single maximum at 0.67 of a cycle, whereas succinate dehydrogenase exhibits two maxima separated by 0.5 of a cell-cycle. 5. All other enzymes assayed showed two distinct maxima per cell-cycle; for catalase, malate dehydrogenase and NADPH-cytochrome c oxidoreductase there is the possibility of multiple fluctuations. 6. The single maximum of cytochrome c oxidase appears at a similar time in the cycle to one maximum of each of the other enzymes studied, except for NADH dehydrogenase. 7. These results are discussed with reference to previous observations on the expression of enzyme activities during the cell-cycle of yeasts.     

Isolation and characterization of subcellular membranes from canine stomach smooth muscle

Subcellular membrane fractions were isolated from the circular muscle of the corpus of canine stomach by differential and isopycnic sucrose density gradient centrifugation. Differential centrifugation gave a mitochondrial fraction enriched (fourfold) in cytochrome c oxidase and a microsomal fraction enriched (fourfold) in 5'-nucleotidase and NADPH-cytochrome c reductase over postnuclear supernatant. On the basis of a study using continuous gradient, a discontinuous sucrose density gradient was prepared to yield F1 to F5 fractions. The F3 fraction at the interface of 18-32% (w/w) sucrose was maximally enriched (13-fold) in 5'-nucleotidase. The fraction contained very low levels of cytochrome c oxidase but did contain NADPH-cytochrome c reductase (eightfold enrichment). The F4 fraction, at the interface of 32-40% (w/w) sucrose, was maximally enriched in NADPH-cytochrome c reductase (12-fold) and cytochrome c oxidase (6-fold). The distribution of the azide-insensitive. ATP-dependent Ca2+ uptake correlated very well with that of 5'-nucleotidase but less well with NADPH-cytochrome c reductase and not at all with cytochrome c oxidase. Sodium azide and ruthenium red inhibited the ATP-dependent Ca2+ uptake by the mitochondrial fraction and postnuclear supernatant, but not by the F3 fraction. ATP-dependent Ca2+ uptake by the F3 fraction was inhibited by calcium ionophores A23187 and ionomycin, but not by the sodium ionophore, monensin. These results are consistent with the hypothesis that the plasma membrane plays a major role ih regulating intracellular Ca2+ concentration in canine corpus circular muscle.     

NADPH-cytochrome P-450 oxidoreductase. The role of cysteine 566 in catalysis and cofactor binding

Site-directed mutagenesis was employed to investigate the role of Cys566 in the catalytic mechanism of rat liver NADPH-cytochrome P-450 oxidoreductase. Rat NADPH-cytochrome P-450 oxidoreductase and mutants containing either alanine or serine at position 566 were expressed in Escherichia coli and purified to homogeneity. Substitution of alanine at position 566 had no effect on enzymatic activity with the acceptors cytochrome c and ferricyanide but did increase trans-hydrogenase activity with 3-acetylpyridine adenine dinucleotide phosphate by 79%. The Km for NADPH was increased 2.5-fold, and the NADP+ KI was increased 4.8-fold compared with that found for the wild-type enzyme. The conservative substitution, Ser566, produced a 50% decrease in cytochrome c reductase activity whereas activity with ferricyanide was decreased 57%, and 3-acetylpyridine adenine dinucleotide phosphate activity was unaffected. The NADPH Km was increased 4.6-fold, and the NADP+ KI increased 7.6-fold. The dependence of cytochrome c reductase activity on the KCl concentration was markedly altered by the Cys566 substitutions. Maximum activity for the wild-type enzyme was observed at approximately 0.18 M KCl whereas maximum activity for the mutant enzymes was observed between 0.04 and 0.09 M KCl. The pH dependence of cytochrome c reductase activity, cytochrome c Km, and flavin content were unaffected by these substitutions. These results demonstrate that Cys566 is not essential for activity of rat liver NADPH-cytochrome P-450 oxidoreductase although the cysteine side chain does affect the interaction of NADPH with the enzyme.     

The markers of pig heart mitochondrial sub-fractions : I. - The dual location of NADPH-cytochrome c reductase in outer membrane and microsomes.

Evidence is presented about the dual location of NADPH-cytochrome c reductase in mitochondrial outer membranes as well as in microsomes, from pig heart. A high specific activity, was found in both fractions, even after their purification by washing, digitonin treatments, or passages on sucrose gradients. A large fraction of the total activity was associated with both mitochondria and microsomes. Mitochondrial outer membrane differs from microsomes by a low choline phosphotransferase activity and the absence of cytochrome P-450. The properties of mitochondrial and microsomal rotenone-insensitive NADH- and NADPH-cytochrome c reductases were studied. In microsomes, both activities have the same optimum pH (8.5) ; in contrast, in mitochondria they have a different one. The Km-NADPH were always much higher than those for NADH. In mitochondria the Km for NAD(P)H were dependent on cytochrome c concentration. The results show that the rotenone-insensitive NADH- and NADPH-cytochrome c reductases of mitochondria and microsomes have quite different behavior and do not appear to be supported by the same enzyme.     

The markers of pig heart mitochondrial sub-fractions: II. — On the association of malate dehydrogenase with inner membrane

Evidence is presented about the dual location of NADPH-cytochrome c reductase in mitochondrial outer membranes as well as in microsomes, from pig heart.A high specific activity, was found in both fractions, even after their purification by washing, digitonin treatments, or passages on sucrose gradients. A large fraction of the total activity was associated with both mitochondria and microsomes.Mitochondrial outer membrane differs from microsomes by a low choline phosphotransferase activity and the absence of cytochrome P-450.The properties of mitochondrial and microsomal rotenone-insensitive NADH- and NADPH-cytochrome c reductases were studied. In microsomes, both activities have the same optimum pH (8.5) ; in contrast, in mitochondria they have a different one. The K_m-NADPH were always much higher than those for NADH. In mitochondria the K_m for NAD(P)H were dependent on cytochrome c concentration.The results show that the rotenone-insensitive NADH- and NADPH-cytochrome c reductases of mitochondria and microsomes have quite different behavior and do not appear to be supported by the same enzyme.     

Biochemical studies on rat liver Golgi apparatus. III. Subfractionation of fragmented Golgi apparatus by counter-current distribution.

Vesicular fragments of Golgi apparatus, smooth- and rough-surfaced microsomes from rat liver are differently partitioned in aqueous polymer two-phase systems consisting of dextran, polyethylene glycol, and sodium phosphate buffer. At a given polymer concentration, the amount of material partitioned in the top phase increases in the following order: rough microsomes less than smooth microsomes less than Golgi fragments. Counter-current distribution of Golgi fragments in the system consisting of 6.8% (w/w) dextran T500 and 6.8% polyethylene glycol 4,000 results in the separation of the fragments into three fractions; i.e. Fractions I, II, and III. NADH- and NADPH-cytochrome c reductase activities are detected almost exclusively in Fraction I, whereas the activities of galactosyltransferase, acid phosphatase, 5'-nucleotidase, and thiamine pyrophosphatase are maximal in Fraction III and minimal in Fraction I. The distribution of these enzymes suggests that Fraction I is similar to, though not identical with, microsomes, Fraction III resembles plasma membrane and lysosomes, and Fraction II is between the two. It is concluded that NADH- and NADPH-cytochrome c reductases are localized in a restricted region of the Golgi structure and that intra-Golgi differentiation seems to proceed in a discontinuous manner.     

NADH-Ubiquinone oxidoreductase: substrate-dependent oxygen turnover to superoxide anion as a function of flavin mononucleotide

Bovine heart mitochondrial NADH-ubiquinone oxidoreductase (complex I) catalyzed NADH- and ubiquinone-1-dependent oxygen (O2) turnover to hydrogen peroxide that was stimulated by piericidin A and superoxide dismutase (SOD), but was insensitive to antimycin A, myxothiazol, and potassium cyanide. The extent of O2 consumption as a function of ubiquinone-1 did not correlate with piericidin A-sensitive rates of ubiquinone reduction. Decylubiquinone did not stimulate O2 consumption, but did initiate an SOD-sensitive cytochrome c reduction when complex I was isolated away from ubiquinol-cytochrome c oxidoreductase. Rates and extent of O2 turnover (ROS production) and ubiquinone reduction were higher than previously reported for submitochondrial particles (SMP) and isolated complex I. This ROS production was shown to co-isolate with complex I flavin.     

Tissue-culture cell fractionation. Fractionation of cellular membranes from 125I/lactoperoxidase-labelled Lettrée cells homogenized by bicarbonate-induced lysis: resolution of membranes by zonal centrifugation and in sucrose and metrizamide gradients.

1. Lettrée cells were grown intraperitoneally in MF-1 mice and labelled extrinsically by the 125I/lactoperoxidase technique. 2. The cells were swollen in 1 mM-NaHCO3 and disrupted in a Dounce homogenizer. 3. Crude fractions of endoplasmic reticulum, plasma membrane and mitochondria were separated from a post-nuclear supernatant by sedimentation-rate gradient centrifugation in a BXIV zonal rotor. 4. Further resolution of these membranes was carried out in isopycnic sucrose gradients. 5. Bands of material from the latter were subfractionated in gradients of metrizamide. Some very pure subfractions of plasma membrane and endoplasmic reticulum were obtained. In addition, one subfraction containing 125I and NADPH-cytochrome c reductase but no Na++K+-stimulated adenosine triphosphatase and another containing these two enzymes but no 125I were resolved.     

Functional expression of mammalian NADPH-cytochrome P450 oxidoreductase on the cell surface of Escherichia coli

To develop a whole-cell oxidoreductase system without the practical limitation of substrate/product transport, easy preparation, stability of enzymes, and low expression levels, we here report the development of a whole cell biocatalyst displaying rat NADPH-cytochrome P450 oxidoreductase (CPR, 77-kDa) on the surface of Escherichia coli by using ice-nucleation protein from Pseudomonas syringae. Surface localization and functionality of the CPR were verified by flow cytometry, electron microscopy, and measurements of enzyme activities. The results of this study comprise the first report of microbial cell-surface display of diflavin-containing mammalian enzymes. This system will allow us to select and develop oxidoreductases, containing bulky and complex prosthetic groups of FAD and FMN, into practically useful whole-cell biocatalysts for broad biological and biotechnological applications including the selective synthesis of new chemicals and pharmaceuticals, bioconversion, bioremediation, and bio-chip development.     

Separation of the primary dehydrogenase from the cytochromes of the nicotinamide adenine dinucleotide (reduced form) oxidase of Bacillus megaterium

A selective extraction procedure was developed for sequentially extracting a fraction containing the primary dehydrogenase and a fraction containing the cytochromes of the nicotinamide adenine dinucleotide (reduced form) (NADH) oxidase of Bacillus megaterium KM membranes. The primary dehydrogenase (NADH-2,6-dichlorophenolindophenol oxidoreductase) activity was extracted from sonically treated membranes with 0.4% sodium deoxycholate for 30 min at 4 C. The insoluble residue was extracted with 0.4% sodium deoxycholate in 1 m KCl for 30 min at 25 C. A combination of the two extracts and dilution in Mg(2+) gave good recovery of the original membrane NADH oxidase activity. The primary dehydrogenase fraction contained 41% of the membrane protein, no cytochromes, flavine adenine dinucleotide as the sole acid-extractable flavine, and most of the membrane ribonucleic acid (RNA). The cytochrome-containing fraction had 16% of the membrane protein, 61% of the membrane cytochrome with the same relative amounts of cytochromes a and b as the original membrane, no acid-extractable flavine, little RNA, and no oxidoreductase activity. The oxidoreductase fraction remained soluble after removal of deoxycholate whereas the cytochrome fraction became insoluble after removal of deoxycholate-KCl, but the precipitated fraction could be redissolved in 0.4% sodium deoxycholate. Treatment of both fractions with ribonuclease to destroy all of the RNA present did not affect the ability of the fractions to recombine into a functional oxidase unit. Treatment of either fraction with phospholipase A prevented restoration of a functional oxidase when the oxidoreductase and cytochrome fractions were treated in solution, but no affect on restoration of oxidase was observed when the phospholipase A treatment was carried out with the soluble oxidoreductase fraction and the insoluble cytochrome fraction.     

Intracellular localization of enzymes in spleen. I. Reduced diphosphopyridine nucleotide cytochrome c reductase,cytochrome c oxidase,and succinic dehydrogenase in the rat and guinea pig

1. The intracellular distribution of nitrogen, DPNH cytochrome c reductase, succinic dehydrogenase, and cytochrome c oxidase has been studied in fractions derived by differential centrifugation from rat and guinea pig spleen homogenates. 2. In the spleens of each species, the nuclear fraction accounted for 40 to 50 per cent of the total nitrogen content of the homogenate, and the mitochondrial, microsome, and supernatant fractions contained about 8, 12, and 30 per cent of the total nitrogen, respectively. 3. Per mg. of nitrogen, DPNH cytochrome c reductase was concentrated in the mitochondria and microsomes of both rat and guinea pig spleens. Seventy per cent of the total DPNH cytochrome c reductase activity was recovered in these two fractions. The reductase activity associated with the nuclear fraction was lowered markedly by isolating nuclei from rat spleens with the sucrose-CaCl(2) layering technique. The lowered activity was accompanied by the recovery of about 90 per cent of the homogenate DNA in the isolated nuclei, indicating that little, if any, of the reductase is present in spleen cell nuclei. 4. Per mg. of nitrogen, succinic dehydrogenase was concentrated about 10-fold in the mitochondria of rat spleen, and 65 per cent of the total activity was recovered in this fraction. 5. Cytochrome c oxidase was concentrated, per mg. of nitrogen, in the mitochondria of both rat and guinea pig spleens. The activity associated with the nuclear fraction was greatly diminished when this fraction was isolated from rat spleens by the sucrose-CaCl(2) layering technique. Only 50 to 70 per cent of the total cytochrome c oxidase activity of the original homogenates was recovered among the four fractions from both rat and guinea pig spleens, while the specific activities of reconstructed homogenates were only 55 to 75 per cent of those of the original whole homogenates. This was in contrast to the results with DPNH cytochrome c reductase and succinic dehydrogenase where the recovery of total enzyme activity approached 100 per cent, and the specific activities of reconstructed homogenates equalled those of the original homogenates. The recovery of cytochrome c oxidase was greatly improved when only the nuclei were separated from rat spleen homogenates. 6. Data were presented comparing the concentrations (ratio of activity per mg. of nitrogen of the fraction to activity per mg. of nitrogen of the homogenate) of DPNH cytochrome c reductase in mitochondria and microsomes derived from different organs of different animals. 7. Data were presented comparing the activities per mg. of nitrogen of DPNH cytochrome c reductase in homogenates from several organs of various animals.     

Subcellular localization of retinoids, retinoid-binding proteins, and acyl-CoA:retinol acyltransferase in rat liver

Studies were conducted to define the subcellular localization of endogenous retinoids (vitamin A), retinoid-binding proteins, and acyl-CoA:retinol acyltransferase (ARAT) in liver and to determine whether their distributions were affected by hepatic vitamin A content. Quantitative subcellular fractionation techniques were used. Rats were fed purified diets either containing or lacking vitamin A to obtain animals with total retinoid stores ranging from 0.5 to 172 micrograms of retinol equivalent per gram of liver. Liver homogenates were fractionated by differential centrifugation to yield nuclear (N), mitochondrial-lysosomal (ML), microsomal (P), and high-speed supernatant (S) fractions. N, ML, and P were washed two more times by resuspension and centrifugation to remove constituents bound nonspecifically. S was further resolved into "floating lipid" and underlying "cytosol" by prolonged ultracentrifugation. The distributions of marker constituents were not affected by vitamin A status. Most of the retinyl ester in the liver was recovered in the S fraction where it was entirely (greater than 95%) associated with floating lipid. About half of the total free retinol was also recovered in the S fraction, but it was mostly (2/3) associated with cytosol per se. A substantial portion (30%) of the free retinol was recovered in the 3 X -washed microsomal (P) fraction. Sufficient binding capacity for retinol was present in both P (as retinol-binding protein) and S (as cellular retinol-binding protein) to quantitatively account for the amounts of free retinol present in the two fractions. ARAT activity in the liver was distributed among the subcellular fractions in a manner identical with an endoplasmic reticulum marker enzyme (NADPH-cytochrome C reductase).(ABSTRACT TRUNCATED AT 250 WORDS)