Distinct localization of renin and angiotensins in separate subcellular fractions of the rat adrenal cortex.

The subcellular localization of renin and immunoreactive angiotensins I and II was studied in rat adrenal cortical tissues. The identity of the immunoreactive angiotensins was confirmed as angiotensin I and angiotensin II by radioimmunoassay and high-performance liquid chromatography, respectively, with reference to standard compounds. By differential centrifugation of tissue homogenate in 0.25 M sucrose/30 mM Tris-HCl/l mM EDTA, pH 7.4, specific immunoreactive renin was found to be localized principally (60%) in the mitochondrial fraction (P2), whereas about 40% of both angiotensins I and II was contained in the soluble fraction; only 18-20% of both peptides was contained in the P2 fraction. On Percoll density gradient centrifugation of P2, renin was fractionated mostly in a denser band whereas angiotensins I and II were contained in a lighter density area closely corresponding to mitochondrial and lysosomal marker enzymes. These results suggest that renin and angiotensins in the cells of the rat adrenal gland reside in different subcellular compartments and argue against intracellular formation of angiotensins by renin in renin granules.     

Studies on mouse liver urate oxidase

Summary Distribution of urate oxidase in subcellular components such as nuclei, mitochondria, lysosomes, microsomes, and cell sap, was investigated by both enzymatic and immunochemical methods. The subcellular components were prepared from mouse liver homogenate by differential centrifugation and the resulting microbody-rich mitochondrial fraction was fractionated by sucrose density gradient centrifugation. The enzymatically determined urate oxidase was distributed mainly in mitochondrial and lysosome fractions. The immunochemically assayed urate oxidase antigen was localized in mitochondrial, lysosome, and microsome fractions. The antigen to enzyme ratio was 1.0 in the mitochondrial and lysosome fractions, and about 2.0 in the microsome fraction.Sucrose density gradient centrifugation of the mitochondrial fraction indicated that the urate oxidase antigen was distributed around three density bands of 1.07, 1.15, and 1.24. The main band (1.24) was consistent with the microbody fraction. From these results, it was suggested that a precursor protein (proenzyme) might be located in the microsome fraction.This work was supported in part by a grant 777007 from the Ministry of Education, Japan, in 1972.     

Comparative subcellular fractionation of control and cold-adapted rat brown and white adipose tissue with special reference to peroxisomal and mitochondrial distributions

A new technique for single-step subcellular fractionation of adipose tissue homogenates by analytical sucrose density gradient centrifugation in a vertical pocket reorientating rotor is described. The density gradient distributions of mitochondrial and peroxisomal marker enzymes in brown and white adipose tissue of control and cold exposed rats are compared. The equilibrium density of brown fat mitochondria was found to be significantly increased compared with white fat mitochondria. GDP binding activity was localized solely to the mitochondria in both control and cold-adapted brown adipose tissue. Brown and white fat mitochondria fractions were isolated by differential centrifugation and the specific activities of various enzymes in the homogenate and mitochondrial preparations determined. The specific activity of creatine kinase in brown adipose tissue was found to be ten-fold higher than in white fat and subcellular fractionation studies showed the activity to have an exclusively cytosolic distribution in both tissues. GDP binding activity and some of the mitochondrial enzymes showed, in brown adipose, a striking increase in total activity in cold adapted rats compared to control animals. For some enzyme activities there was a small increase when expressed per mg tissue or per mg mitochondrial protein. When expressed per mg DNA i.e. per cell, there was a reduced specific activity of the mitochondrial and peroxisomal enzymes in both brown and white adipose tissue on cold adaptation.     

Die subzelluläre Lokalisation von Enzymen des Phenylpropanoidstoffwechsels im Antherentapetum: Phenylalanin-Ammonium-Lyase,Zimtsäure 4-Hydroxylase,SAM: Kaffeesäure 3-0-Methyltransferase

Summary After separation of the contents of anthers into pollen and tapetum fractions, the subcellular localization of tapetum enzymes involved in phenylpropanoid metabolism have been studied by differential centrifugation and by sucrose density gradient centrifugation.The experiments showed that nearly all the activity of both phenylalanine ammonia-lyase and an O-methyltransferase was in the soluble fraction. In contrast the cinnamic acid 4-hydroxylase activity is associated with the 12,000×g and 100,000×g pellet. After fractionation of the tapetum fraction by sucrose density gradient centrifugation, activity of cinnamic acid 4-hydroxylase was highest in those fractions with maximum NADH-Cytochrome c-reductase activity. Combination of the hydroxylase with ER is suggested.The results are discussed with special regard to the secretory function of the tapetum cells.     

Localization of dolichol in the lysosomal fraction of rat liver

The distribution of dolichol and/or dolichol esters in subcellular fractions prepared from a rat liver homogenate has been investigated. After saponification of the various fractions dolichol was isolated and quantitated by high performance liquid chromatography in three systems. The degree of purity of the subcellular preparations was examined by marker enzymes and by electron microscopy. Using differential centrifugation it was found that the level of dolichol was highest in the mitochondria-lysosome fraction. Upon further resolution of this fraction by sucrose density centrifugation it was found that the majority of the dolichol was associated with the lysosome-rich fraction. In contrast, the mitochondrial fraction had only a low level of dolichol. This novel observation was confirmed by the finding that dolichol was greatly enriched in a highly purified lysosome fraction preparations isolated by Metrizamide density centrifugation. The enrichment of dolichol in this purified preparation paralleled the observed enrichment of the lysosomal enzyme activity in this fraction. All of these data suggest that the majority of cellular dolichol and/or dolichol esters is localized in the lysosome fraction. The significance of this finding in relation to the metabolism of dolichol is discussed.     

Formation of cholic acid from 3 alpha, 7 alpha, 12 alpha-trihydroxy-5 beta-cholestanoic acid in human skin fibroblasts.

Whether 3 alpha, 7 alpha, 12 alpha-trihydroxy-5 beta-cholestanoic acid (THCA) was converted into cholic acid in human skin fibroblasts was examined. THCA was incubated with subcellular fractions of cultured skin fibroblasts in the presence of NAD+, ATP, CoA, and Mg2+. The reaction products were analyzed by thin-layer chromatography and high-performance liquid chromatography after p-bromophenacyl ester derivatization. The highest specific activity was found in the light mitochondrial fraction (2.71 nmol/mg protein/h). The specific activity was about 9-fold higher than that in heavy mitochondrial fraction. The peroxisomal fraction prepared from the light mitochondrial fraction by sucrose gradient centrifugation was also able to catalyze the conversion of THCA into cholic acid. The specific activity in this fraction was a further 2.2-fold higher than that in the light mitochondrial fraction. These results suggest that cultured human skin fibroblasts are able to convert THCA into cholic acid, and that the activity exists in peroxisomes.     

Is there a plasma membrane-located anion-sensitive ATPase? IV. Distribution of the enzyme in rat pancreas.

The intracellular localization of anion-sensitive Mg2+-ATPase in rat pancreas was studied by differential centrifugation, density gradient centrifugation and by the use of inhibitors of mitochondrial Mg2+-ATPase. The anion-sensitive MG2+-ATPase appears to be localized almost exclusively in a mitochondrial (15 min, 15 000 times g) fraction which shows two peaks after density gradient centrifugation. Both peaks coincide with the highest levels of cytochrome c oxidase activity, but not with alkaline phosphatase, (Na+ plus K+)-ATPase and leucine aminopeptidase activities or RNA. They appear to be equal sensitive to inhibition by oligomycin, aurovertin D and the rat liver mitochondrial inhibitor protein, at least when 1 mM EDTA is present in the isolation media. We conclude that no significant plasma membrane-located anion-sensitive Mg2+-ATPase activity is present in rat pancreas.     

Human renin activation by protease from the renin granule fraction of the dog kidney cortex

To clarify the possible conversion of prorenin in renin granules where conversion reportedly occurred, we investigated whether the renin granule fraction of the kidney could activate prorenin to the active form. Renin granules were isolated from the dog kidney cortex by discontinuous sucrose density gradient centrifugation. Human active renin was quantified by immunoradiometric assay which could detect only the human active renin but not the inactive human renin or dog renin. Inactive renin from human amniotic fluid was incubated with the subcellular fraction of the dog kidney cortex. The renin granule fraction that showed the highest renin activity stimulated the inactive renin to become the active form. The membrane preparation obtained from the renin granule fraction by freezing and thawing the fraction in low osmolarity retained the activity of renin activation. Other subcellular fractions showed less renin activation. The optimal pH for renin activation by the membrane was pH 5.0 to 6.0. The activation depended on the time of incubation and concentration. The activation was inhibited by N-ethylmaleimide but not by EDTA or serine protease inhibitors. These results suggest that renin is processed by a membrane bound protease in renin granules.     

Release of the phosphodiesterase activator by cyclic AMP-dependent ATP:protein phosphotransferase from subcellular fractions of rat brain.

The subcellular distribution of the endogenous phosphodiesterase activator and its release from membranes by a cyclic AMP-dependent ATP:protein phosphotransferase was studied in fractions and subfractions of rat brain homogenate. These fractions were obtained by differential centrifugation and sucrose density gradient; their identity was ascertained by electron microscopy and specific enzyme markers. In the subcellular particulate fractions, the concentration of activator is highest in the microsomal fraction, followed by the mitochondrial and nuclear fractions. Gradient centrifugation of the main mitochondrial subfraction revealed that activator was concentrated in those fractions containing mainly synaptic membranes. Activator was releasted from membranes by a cyclic AMP-dependent phosphorylation of membrane protein. The release of activator occurred mainly from the mitochondrial subfractions containing synaptic membranes and synaptic vesicles. The data support the view that a release of activator from membranes may be important in normalizing the elevated concentration of cyclic AMP following persistent transsynaptic activation of adenylate cyclase.     

Enhancement of long-chain acyl-CoA hydrolase activity in peroxisomes and mitochondria of rat liver by peroxisomal proliferators

The present study has confirmed previous findings of long-chain acyl-CoA hydrolase activities in the mitochondrial and microsomal fractions of the normal rat liver. In addition, experimental evidence is presented in support of a peroxisomal localization of long-chain acyl-CoA hydrolase activity. (a) Analytical differential centrifugation of homogenates from normal rat liver revealed that this activity (using palmitoyl-CoA as the substrate) was also present in a population of particles with an average sedimentation coefficient of 6740 S, characteristic of peroxisomal marker enzymes. (b) The subcellular distribution of the hydrolase activity was greatly affected by administration of the peroxisomal proliferators clofibrate and tiadenol. The specific activity was enhanced in the mitochondrial fraction and in a population of particles with an average sedimentation coefficient of 4400 S, characteristic of peroxisomal marker enzymes. Three populations of particles containing lysosomal marker enzymes were found by analytical differential centrifugation, both in normal and clofibrate-treated rats. Our data do not support the proposal that palmitoyl-CoA hydrolase and acid phosphatase belong to the same subcellular particles. In livers from rats treated with peroxisomal proliferators, the specific activity of palmitoyl-CoA hydrolase was also enhanced in the particle-free supernatant. Evidence is presented that this activity at least in part, is related to the peroxisomal proliferation.     

Hydroxymethylglutaryl coenzyme A reductase activity in hamster adrenal mitochondria purified on a sucrose gradient.

Hamster adrenal homogenates were fractionated by differential centrifugation to obtain crude mitochondrial and microsomal pellets. The mitochondria were further purified on a linear sucrose density gradient. The crude mitochondrial fraction was separated into three bands on the gradient. One of the bands (band 3, D₂₀²⁰ = 1.165) contained all the measurable cytochrome C oxidase activity. Band 3 also contained the highest specific activity of HMG-CoA reductase corresponding to a 1.9 fold enrichment compared to the crude mitochondrial pellet. The evidence presented supports the possibility that a part of the HMG-CoA reductase activity in hamster adrenals is associated with mitochondria.     

Subcellular distribution of GTP-binding proteins, Go and Gi2, in rat cerebral cortex

The localization of GTP-binding protein (G-protein) subunits, Go alpha, Gi2 alpha and beta, in subcellular fractions of rat cerebral cortex was determined by means of immunoassays specific for the respective subunits. High concentrations of all three subunits were observed in both crude mitochondrial and microsomal fractions. Muscarinic cholinergic receptors were also densely localized in these fractions. Then the crude mitochondrial and microsomal fractions were subfractionated by sucrose density gradient centrifugation. Each fraction obtained was evaluated morphologically by electron microscopy and biochemically by determination of membrane markers. The crude mitochondrial fraction was subfractionated into myelin, synaptic plasma membrane, and mitochondrial fractions. All the G-protein subunits examined and muscarinic receptors were exclusively localized in the synaptic plasma membrane fraction. Among the submicrosomal fractions, the heavy smooth-surfaced microsomal fraction showed the highest concentrations of all G-protein subunits and receptors, while the rough-surfaced microsomal fraction contained low amounts of them. The heavy smooth-surfaced microsomal fraction also contained high specific activity of (Na(+)-K+)-ATPase, a marker of the plasma membrane. These results indicated that the Go alpha, Gi2 alpha and beta subunits are mainly localized in the plasma membrane in the brain.     

Release of the phophodiesterase activator by cyclic AMP-dependent ATP:protein phosphotransferase from subcellular fractions of rat brain

The subcellular distribution of the endogenous phosphodiesterase activator and its release from membranes by a cyclic AMP-dependent ATP:protein phosphotransferase was studied in fractions and subfractions of rat brain homogenate. These fractions were obtained by differential centrifugation and sucrose density gradient; their identity was ascertained by electron microscopy and specific enzyme markers.In the subcellular particulate fractions, the concentration of activator is highest in the microsomal fraction, followed by the mictochondrial and nuclear fractions. Gradient centrifugation of the main mitochondrial subfraction revealed that activator was concentrated in those fractions containing mainly synaptic membranes.Activator was released from membranes by a cyclic AMP-dependent phosphorylation of membrane protein. The release of activator occurred mainly from the mitochondrial subfractions containing synaptic membranes and synaptic vesicles.The data support the view that a release of activator from membranes may be important in normalizing the elevated concentration of cyclic AMP following persistent transsynaptic activation of adenylate cyclase.     

Intracellular localization of aldehyde dehydrogenase in rat liver

1. Distribution of aldehyde dehydrogenase activity in rat liver was studied by measuring the rate of disappearance of acetaldehyde in the presence of each of the subcellular fractions. These were obtained by rough separation of particulate fractions from the soluble portion of the cell, by differential centrifugation, and by isopycnic gradient centrifugation. 2. The maximal rate of acetaldehyde oxidation was 3.7 mumol/min per g, with an apparent K(m) value below 10(-5)m. The highest rate of activity was observed in phosphate buffers of high P(i) concentration (above 60mm). 3. The activity measured was completely dependent on NAD(+). 4. The microsomal fraction and the nuclei were inactive in the assay. Of the total activity 80% was found in the mitochondrial fraction and the remaining 20% in the cytoplasm. 5. The distribution pattern is important from the point of view of acetaldehyde oxidation during ethanol metabolism. The apparent discrepancy of the results obtained by different workers and the localization of acetaldehyde oxidation in vivo is discussed.     

Kinin-forming activity in rat brain

The present study shows that rat brain contains a kinin-forming activity which is distinguishable from plasma kallikrein. Kinin-forming activity was found in an acetone powder of frozen brain tissue (between 27 and 175.5 ng generated bradykinin/g fresh brain tissue/h). Analysis by high pressure liquid chromatography (HPLC) indicated that the kinin formed chromatographed like true bradykinin (BK). After subcellular fractionation using differential centrifugation of homogenized fresh brain tissue the kinin-forming activity was found mainly in a microsomal (P-3) fraction after preincubation with 2 μM melittin. Further fractionation of P-3 fraction using discontinuous sucrose gradient centrifugation identified activity in both the 1 M sucrose layer (5.8 ± 3.1 ng kinin/mg protein/h) and at the interface between the 0.8 and 0.3 sucrose layers (9.4 ± 4 ng kinin/mg protein/h). Melittin pretreatment did not change these values. The distribution pattern of the kallikrein-like activity was different from that of cathepsin d-like acid protease. The two kinin-forming activities were equally sensitive to treatment with various trypsin inhibitors but were clearly distinguishable from plasma kallikrein: brain activity was inhibited completely by Trasylol but not by soybean trypsin inhibitor (SBTI) or ovomucoid while plasma kallikrein was completely inhibited by SBTI and partially by ovomucoid and Trasilol. Our results clearly distinguish between plasma kallikrein, brain cathepsin d-like acid protease activity and an apparent brain kinin-forming activity, but do not by themselves establish a central biosynthetic pathway for kinin generation.     

Presynaptic localization of histamine H3-receptors in rat brain.

The localization of histamine H3-receptors in subcellular fractions from the rat brain was examined in a [3H] (R) alpha-methylhistamine binding assay and compared with those of histamine H1- and adrenaline alpha 1- and alpha 2-receptors. Major [3H](R) alpha-methylhistamine binding sites with increased specific activities ([3H]ligand binding vs. protein amount) were recovered from the P2 fraction by differential centrifugation. Minor [3H](R)alpha-methylhistamine binding sites with increased specific activities were also detected in the P3 fraction. Further subfractionation of the P2 fraction by discontinuous sucrose density gradient centrifugation showed major recoveries of [3H](R)alpha-methylhistamine binding in myelin (MYE) and synaptic plasma membrane (SPM) fractions. A further increase in specific activity was observed in the MYE fraction, but the SPM fraction showed no significant increase in specific activity. Adrenaline alpha 2-receptors, the pre-synaptic autoreceptors, in a [3H] yohimbine binding assay showed distribution patterns similar to histamine H3-receptors. On the other hand, post-synaptic histamine H1- and adrenaline alpha 1-receptors were closely localized and distributed mainly in the SPM fraction with increased specific activity. Only a negligible amount was recovered in the MYE fraction, unlike the histamine H3- and adrenaline alpha 2-receptors.     

Cestode lysosomes

By differential centrifugation method a lysosomal fraction was obtained from five species of cestodes, which possesses the highest specific activity of acidic phosphatases as compared to other subcellular fractions. By isopyknic centrifugation in the density gradient of saccharose the lysosomal fraction is divided into primary and secondary lysosomes. Lysosomes of cestodes are similar to those of vertebrate animals in the character of fractional distribution of acidic phosphatase, sedimentation abilities and sensitivity of membranes to triton X-100.     

A Ca2+, Calmodulin-dependent NAD kinase from corn is located in the outer mitochondrial membrane

NAD kinase activity from dark grown corn coleoptiles is shown to be almost totally dependent on Ca2+ and calmodulin. Nearly all of the enzyme activity is found in a particulate fraction. Upon differential and density gradient centrifugation the NAD kinase activity co-migrates with the mitochondrial cytochrome c oxidase whereas marker activities for nuclei, etioplasts, endoplasmic reticulum, and microbodies could well be separated, indicating that the NAD kinase is associated with mitochondria. This NAD kinase, associated with intact mitochondria, can be activated by exogenously added Ca2+ and calmodulin. In order to investigate the submitochondrial localization of the NAD kinase, the organelles were ruptured by osmotic treatment and sonication and the submitochondrial fractions were separated by density gradient centrifugation. The NAD kinase activity exhibits the same density pattern as the antimycin A-insensitive NADH-dependent cytochrome c reductase, a marker enzyme of the outer mitochondrial membrane. Marker enzymes for the mitochondrial matrix and the inner mitochondrial membrane reveal different density profiles. These results indicate that the Ca2+, calmodulin-dependent NAD kinase from coleoptiles of dark grown corn seedlings is located at the outer mitochondrial membrane. The physiological relevance of the location and the Ca2+, calmodulin-dependence of the NAD kinase will be discussed.     

Basal-lateral membranes from rabbit renal cortex prepared on a large scale in a zonal rotor

Basal-lateral membranes from the renal cortex of the rabbit were isolated by sucrose gradient centrifugation in a zonal rotor which allows for a large-scale preparation of these membranes. A heterogeneous population of membranes (P4) which contained 29% of the (Na+ + K+)-ATPase found in the homogenate of renal cortex was prepared by differential centrifugation. When pellet P4 was subjected to centrifugation in a sucrose gradient the activity of (Na+ + K+)-ATPase, a marker for basal-lateral membranes, could be separated from enzymatic markers of other organelles. The specific activity of (Na+ + K+)-ATPase was enriched 12-fold at a density of 1.141 g/cm3. Membranes (P alpha) contained in the (Na+ + K+)-ATPase-rich fractions consisted primarily of closed vesicles which exhibited probenecid inhibitable transport of rho-aminohippurate. These membranes did not exhibit Na+-dependent, phlorizin-inhibitable D-glucose transport. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of proteins from P alpha revealed at least six major protein bands with molecular weights of 91000, 81000, 73000, 65000, 47000 and 38000. A small fraction of total alkaline phosphatase found in the homogenate was found in pellet P4. Membranes containing this alkaline phosphatase activity were distributed widely over the gradient, with peak activity found at a density of 1.141 g/cm3. In contrast, when brush borders were subjected to gradient centrifugation under the same conditions as P4, alkaline phosphatase was found in a narrow distribution, with peak activity at a density of 1.158 g/cm3. The principle subcellular localization of the alkaline phosphatase found in P4 could not be determined unambiguously from the data, but the activity did not seem to be primarily associated with classical brush borders.     

Intraplastidic Localization of the Enzymes That Convert delta-Aminolevulinic Acid to Protoporphyrin IX in Etiolated Cucumber Cotyledons

The intraplastidic localization of the enzymes that catalyze the conversion of δ-aminolevulinic acid (ALA) to protoporphyrin IX (Proto) is a controversial issue. While some researchers assign a stromal location for these enzymes, others favor a membranebound one. Etiochloroplasts were isolated from etiolated cucumber cotyledons (Cucumis sativus, L.) by differential centrifugation and were purified further by Percoll density gradient centrifugation. Purified plastids were highly intact, and contamination by other subcellular organelles was reduced five- to ninefold in comparison to crude plastid preparations. Most of the ALA to Proto conversion activity was found in the plastids. On a unit protein basis, the ALA to Proto conversion activity of isolated mitochondria was about 2% that of the purified plastids, and could be accounted for by contamination of the mitochondrial preparation by plastids. Lysis of the purified plastids by osmotic shock followed by high speed centrifugation, yielded two subplastidic fractions: a soluble clear stromal fraction and a pelleted yellowish one. The stromal fraction contained about 11% of the plastidic ALA to Proto conversion activity while the membrane fraction contained the remaining 89%. The stromal ALA to Proto conversion activity was in the range of stroma contamination by subplastidic membrane material. Complete solubilization of the ALA to Proto activity was achieved by high speed shearing and cavitation, in the absence of detergents. Solubilization of the ALA to Proto conversion activity was accompanied by release of about 30% of the membrane-bound protochlorophyllide. It is proposed that the enzymes that convert ALA to Proto are loosely associated with the plastid membranes and may be solubilized without the use of detergents. It is not clear at this stage whether the enzymes are associated with the outer or inner plastid membranes and whether they form a multienzyme complex or not.