Subcellular distribution of "peripheral type" binding sites for [3H]Ro5-4864 in guinea pig lung. Localization to the mitochondrial inner membrane

Binding of [3H]Ro5-4864, a specific ligand for "peripheral type" benzodiazepine receptors, was determined in subcellular fractions of guinea pig lung. Even though the level of binding was predominant in the mitochondrial fraction, nuclear and cytosolic fractions also contained significantly measurable amounts of binding sites. The presence of binding sites in the microsomal fraction and in a fraction intermediate in density between the mitochondria and microsomes depended on which buffer was used to homogenize the tissue. If calcium-containing mannitol buffer was used, binding was negligible in the postmitochondrial organelles. However, in the case of sucrose buffer which did not contain any calcium, the postmitochondrial organelle fractions contained measurable amounts of binding sites. Most probably, these binding sites were of mitochondrial and nuclear origin. Furthermore, binding sites in the mitochondria were associated with the succinic dehydrogenase-enriched mitochondrial inner membrane, but not with the monoamine oxidase- and cholinephosphotransferase-enriched outer mitochondrial membrane. Furthermore, several proteolytic enzymes caused a decrease in binding of the ligand to the mitochondrial membrane only under hypotonic conditions and not under isotonic conditions, suggesting that the location of the receptors is inside the mitochondria.     

Two subcellular locations for peripheral-type benzodiazepine acceptors in rat liver

Subcellular fractionation of rat liver by differential centrifugation showed the mitochondrial fractions to have the greatest enrichment of 'peripheral-type' benzodiazepine acceptor. Two peaks of acceptor sites were found on isopycnic density-gradient centrifugation, one peak (rho = 1.19 g/ml) corresponding to the peak of mitochondria as judged by marker enzyme distribution and by transmission electron microscopy, and the other peak (rho = 1.17 g/ml) which is not mitochondrial as judged by the lack of mitochondrial enzyme markers. Whereas the density of the mitochondrial acceptor was sensitive to sonication and was shown to have an outer-membrane location, the density of the non-mitochondrial acceptor was insensitive to sonication. The non-mitochondrial acceptor was shown not to be associated with Golgi, lysosomes, rough endoplasmic reticular microsomes, peroxisomes, or some types of plasma membranes, as judged by differences in the distribution of marker activities. No enrichment of benzodiazepine acceptor was found in the purified nuclear fraction. Both acceptors were shown to be peripheral-type high-affinity acceptors as judged by ligand specificities and by photoaffinity labelling.     

The heterogeneity of rat brain mitochondria isolated on continuous sucrose gradients

Abstract— The distribution of a series of enzymes in the post-nuclear supernatant of rat brain homogenates was investigated following continuous density-gradient centrifugation. The enzymes studied were acetyl coenzyme A synthetase, glutamic dehydrogenase, glutamine synthetase, glutaminase I, succinic dehydrogenase and monoamine oxidase. Each of these enzymes with the exception of glutamine synthetase appears predominantly in the mitochondrial region of the gradient. Although about 20 per cent of this enzyme is present in the crude mitochondrial pellet, on density gradient centrifugation no special association of glutamine synthetase with any of the mitochondrial fractions was observed. Each of the other enzymes studied was found to have a characteristic distribution in the gradient; this suggests that brain mitochondria may be heterogeneous both in buoyant density and in their enzyme content. Three principal fractions are described: (i) dense particles containing high concentrations of acetyl coenzyme A synthetase and glutamic dehydrogenase; (ii) a fraction comprising the bulk of the mitochondria with high levels of monoamine oxidase, succinic dehydrogenase and glutaminase I; and (iii) particles in the synaptic ending region of the gradient characterized by relatively high levels of monoamine oxidase and succinic dehydrogenase and containing only small amounts of the other enzymes studied. If the mitochondrial heterogeneity that is observed on centrifugation reflects the existence within brain cells of mitochondria with specialized function, a partial explanation may be available for multiple pools of tricarboxylic acid cycle intermediates which have been postulated from isotopie labelling experiments.     

COMPARATIVE STUDIES ON MITOCHONDRIA ISOLATED FROM NEURON-ENRICHED AND GLIA-ENRICHED FRACTIONS OF RABBIT AND BEEF BRAIN

Fractions enriched in neuronal and glial cells were obtained from dispersions of whole beef brain and rabbit cerebral cortex by large-scale density gradient centrifugation procedures. The fractions were characterized by appropriate microscopic observation. Mitochondria were then isolated from these fractions by differential centrifugation of their homogenates. The two different types of mitochondria were characterized with respect to certain enzyme activities, respiratory rate, rate of protein synthesis, and their buoyant density in sucrose gradients. The mitochondria from the neuron-enriched fraction were distinguished by a higher rate of incorporation of amino acids into protein, higher cytochrome oxidase activity, and a higher buoyant density in sucrose density gradients. Mitochondria from the glia-enriched fraction showed relatively high monoamine oxidase and Na⁺- and K⁺-stimulated ATPase activities. The rates of oxidation of various substrates and the acceptor control ratios did not differ appreciably between the two types of mitochondria. The difference in the buoyant density of mitochondria isolated from the neuron-enriched and glia-enriched cell fractions was utilized in attempts to separate neuronal and glial mitochondria from the mixed mitochondria obtained from whole brain homogenates in shallow sucrose gradients. The appearance of two peaks of cytochrome oxidase, monoamine oxidase, and protein concentration in such gradients shows the potential feasibility of such an approach.     

Purification and characterization of two plasma membrane domains from ejaculated bull spermatozoa

Plasma membranes were detached from ejaculated bull spermatozoa by a brief sonication in a moderately hypotonic medium, and the released plasma membranes were partially purified by differential centrifugation. The resulting fraction was enriched 8- and 15-fold in alkaline phosphatase and 5' nucleotidase activities, respectively, compared with the starting sonicated spermatozoa. This total plasma membrane fraction was separated into two distinct fractions by equilibrium density centrifugation on a continuous linear sucrose gradient. Two peaks of light scattering material were formed at densities of 1.117 and 1.148 g/ml. The denser peak contained most of the protein of the plasma membrane fraction, whereas nearly all the concanavalin A binding activity was found in the lighter peak. The two bands had distinctly different polypeptide compositions when analyzed by SDS PAGE. Polyclonal antibodies were raised in rabbits against a major integral membrane glycoprotein of each fraction (Mr of 92,000 in the light peak and 98,000 in the dense peak). The two antigens were detected on the surface of intact spermatozoa by indirect immunofluorescence microscopy. The 92-kD protein (present in the lighter band) was detected only on the plasma membrane of the acrosomal and anterior postacrosomal regions of the head. The 98-kD antigen, present in the heavier band, was localized to the surface of the postacrosomal region of the head, to the principal piece of the tail, and to the connecting piece between the head and tail. The exclusive localization of the 92-kD polypeptide to the surface of the anterior portion of the head was confirmed by immunoelectron microscopy. These data show that the two fractions isolated on the sucrose gradient originate from different regions of the sperm cell plasma membrane.     

Characterization of rat liver endosomal fractions. In vivo activation of insulin-stimulable receptor kinase in these structures

A protocol employing discontinuous sucrose gradient centrifugation was developed to prepare light mitochondrial (L) and Golgi fraction endosomes from simultaneously prepared parent L and microsomal fractions. As judged by the concentration of labeled hormone postinjection, L intermediate and heavy endosome subfractions were 40- to 175-fold purified and Golgi intermediate and heavy endosome subfractions were 30- to 45-fold purified. On electron microscopy, L endosomal fractions contained a predominance of lipoprotein-filled vesicles and were less heterogeneous than corresponding Golgi endosomal fractions. All endosomal fractions were enriched in receptors for insulin and prolactin but binding sites for the former were more broadly distributed in other subfractions than those for the latter. On Percoll gradient centrifugation, L endosomal fractions yielded one peak (rho 1.057) corresponding to the heavier of two peaks seen in Golgi endosomal fractions. The protein composition of high density L and Golgi endosomes, as assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, was similar. The bulk of marker enzymes assayed did not migrate with the endosomal components. Combined acid phosphatase cytochemistry and electron microscope radioautography established that about 80% of the L endosomes contained no acid phosphatase. By affinity labeling and immunological titration with insulin receptor antibody, insulin receptors were identical in L and Golgi endosomes. Insulin-stimulable receptor kinase was demonstrable in both L and Golgi endosome fractions. Following in vivo insulin administration, the insulin receptor kinase in both L and Golgi endosomes was significantly activated. This activated state was not inhibited by a large excess of antiserum to insulin and thus not due to insulin contaminating the partially purified receptor preparation. These observations are compatible with the maintenance and/or initiation of hormone-dependent phosphorylations intracellularly.     

Subcellular localization of glyoxylate cycle enzymes in Ascaris suum larvae

Evidence is presented on the particulate nature of glyoxylate cycle enzymes in metazoa with the use of 15-day old larvae of the nematode Ascaris suum. Homogenization procedures were developed to disrupt the resistant nematode cuticle. Malate synthase and isocitrate lyase, key enzymes of the glyoxylate cycle, consistently sedimented with mitochondrial enzymes in differential pellets while catalase, a major peroxisomal enzyme, was always soluble. Isopycnic sucrose gradient centrifugation of the differential pellet yielded two protein peaks: one at 1.18 g/cm3 (characteristic for mitochondria), and another at 1.23 g/cm3 (common for glyoxysomes and peroxisomes). Electron microscopy of these fractions revealed that the lighter peak consisted primarily of mitochondria, while the heavier band contained proteinaceous bodies termed "dense granules" morphologically resembling microbodies. SIgnificantly, both malate synthase and isocitrate lyase cosedimented with the mitochondrial marker enzymes in the lighter peak (1.18 g/cm3) and not with the dense granules. Further purification of mitochondria, accomplished by separating dense granules with a step gradient before isopycnic centrifugation, substantiated the evidence that microbodies (glyoxysomes) do not occur in these nematode larvae. Rough-surfaced membranes were alternatively considered as the subcellular site, but the evidence tends to favor localization of the glyoxylate bypass enzymes in the mitochondria.     

Preparation of noradrenaline-storing organelles from bovine sympathetic ganglia: Biochemical and morphological evaluation of partly purified large dense cored vesicles

Large dense cored vesicles from bovine sympathetic ganglia were isolated and partly purified. Biochemical and morphological evaluation of the present vesicle-preparation revealed that it represents a convenient fraction for the characterization of perikaryal noradrenergic vesicles.

Homogenates of bovine stellate ganglia were subjected to differential centrifugation and D₂O-sucrose density gradient centrifugation. Biochemical evaluation of gradient fractions was performed by measuring marker enzyme activities reflecting subcellular contamination, while morphological evaluation was performed by electron microscopic analysis of the isolated fractions. Both techniques revealed that the vesicle-preparation was, at first, still considerably contaminated by mitochondria and lysosomes.

An improved purification could be achieved by subjecting this fraction to an additional centrifugation under iso-osmotic conditions, also applied for the preparation of highly purified splenic nerve vesicles. The resulting vesicle-fraction was almost complete free of contaminating enzyme activities and consisted merely of large dense cored vesicles as revealed by electron microscopic observations (50–70% purity). Neuropeptide Y and chromogranin A were enriched more than 50 times as compared to the total homogenate.

Although the purity of these vesicles was still not satisfactory for direct chemical analysis, this vesicle-preparation seemed very well suited for immunological characterization of perikaryal large dense cored vesicles.     

Alignment of sarcoplasmic reticulum-mitochondrial junctions with mitochondrial contact points

Propagation of ryanodine receptor (RyR2)-derived Ca(2+) signals to the mitochondrial matrix supports oxidative ATP production or facilitates mitochondrial apoptosis in cardiac muscle. Ca(2+) transfer likely occurs locally at focal associations of the sarcoplasmic reticulum (SR) and mitochondria, which are secured by tethers. The outer mitochondrial membrane and inner mitochondrial membrane (OMM and IMM, respectively) also form tight focal contacts (contact points) that are enriched in voltage-dependent anion channels, the gates of OMM for Ca(2+). Contact points could offer the shortest Ca(2+) transfer route to the matrix; however, their alignment with the SR-OMM associations remains unclear. Here, in rat heart we have studied the distribution of mitochondria-associated SR in submitochondrial membrane fractions and evaluated the colocalization of SR-OMM associations with contact points using transmission electron microscopy. In a sucrose gradient designed for OMM purification, biochemical assays revealed lighter fractions enriched in OMM only and heavier fractions containing OMM, IMM, and SR markers. Pure OMM fractions were enriched in mitofusin 2, an ~80 kDa mitochondrial fusion protein and SR-mitochondrial tether candidate, whereas in fractions of OMM + IMM + SR, a lighter (~50 kDa) band detected by antibodies raised against the NH(2) terminus of mitofusin 2 was dominating. Transmission electron microscopy revealed mandatory presence of contact points at the junctional SR-mitochondrial interface versus a random presence along matching SR-free OMM segments. For each SR-mitochondrial junction at least one tether was attached to contact points. These data establish the contact points as anchorage sites for the SR-mitochondrial physical coupling. Close coupling of the SR, OMM, and IMM is likely to provide a favorable spatial arrangement for local ryanodine receptor-mitochondrial Ca(2+) signaling.     

Intracellular distribution of hexokinase in rabbit brain

Hexokinase in mammalian brain is particulate and usually considered to be bound to the outer mitochondrial membrane. Investigation of rabbit brain mitochondria prepared either by differential centrifugation and discontinuous density gradient centrifugation has provided evidence that this particulate fraction also contains endoplasmic vesicles and synaptosomes. Solubilization of the bound hexokinase by different combinations of detergents and metabolites has proved the existence of different hexokinase binding sites. Electron microscopic examination of hexokinase location by immuno-gold labelling techniques confirmed, that hexokinase is indeed predominantly bound to mitochondria but that a significant proportion is also bound to non-mitochondrial membranes. Attempts to quantify this distribution were unsuccessful since different figures were obtained using anti-hexokinase IgG affinity purified on immobilized native or denatured hexokinase. Binding studies of the purified rabbit brain mitochondrial hexokinase to rabbit liver mitochondria and microsomes confirmed that in addition to a binding site on mitochondria there is another binding site on microsomes. The N-terminal sequence of hexokinase has been shown to be important for mitochondria binding and also for microsome binding. These results suggest that the intracellular localization of hexokinase in rabbit brain is not exclusively mitochondrial and that the metabolic role of this enzyme should be reconsidered by including a binding site on the endoplasmic reticulum.     

Presence of Kynurenine Hydroxylase in Developing Rat Brain

Abstract: Kynurenine-3-hydroxylase, an enzyme that is part of the degradative pathway for tryptophan, was present in the cerebral cortex of neonatal rats and exhibited a K_m , for L-kynurenine close to that of the liver enzyme. This enzyme was enriched in mitochondrial fractions isolated from cerebral cortices of neonatal rats by Ficoll-sucrose gradient centrifugation, with some activity also present in synaptosomal fractions probably due to the mitochondrial content of synaptosomes since cytochrome c oxidase, another mitochondrial enzyme, had a similar distribution in the gradient. Kynurenine hydroxylase as well as monoamine oxidase, another mitochondrial enzyme, had increased specific activities in synaptosomal fractions isolated from 14-day-old rats compared to fractions from 8-day-old rats. Hypothyroidism, induced on the day of birth, resulted in increased activities of kynurenine hydroxylase and monoamine oxidase in synaptosomal fractions isolated from 14-day-old rats.     

Identification of Synapse Specific Components: Synaptic Glycoproteins, Proteins, and Transmitter Binding Sites

Synaptic junctions (SJ) were prepared from synaptic plasma membranes (SPM) by extraction with Triton X-100 and density gradient centrifugation. These SJs were enriched in certain Concanavalin A (Con A) binding glycoproteins, the 52,000 Mr postsynaptic density (PSD) protein, and receptor sites for L-glutamate, L-aspartate, kainic acid (KA) but not quinuclidinyl benzilate (QNB). Various other membrane fractions were extracted by means of the same procedure. Those fractions prepared from light SPMs and crude myelin contained identifiable synaptic junctions and were also highly enriched in the synaptic components. The SJ-like fraction from mitochondria did not contain any of the characteristic synaptic macromolecules. However, this fraction from microsomes contained levels of the 52,000 Mr PSD protein and binding sites for L-glutamate (L-Glu) and L-aspartate (L-Asp) similar to true synaptic junctions, although the Con A binding glycoproteins and KA binding sites were nearly absent. On the basis of electron microscopy, the SJ-like fraction from microsomes did not contain structures recognizable as SJs. Thus, the Con A binding glycoproteins and KA binding sites appear to be excellent markers for the SJ.     

Subcellular localization of prostaglandin E2 binding sites in bovine adrenal medulla

Prostaglandins E₁ and E₂ are specifically bound by particulate fractions from bovine adrenal medulla. The subcellular localization of these binding sites has been investigated by comparing their distribution in subcellular fractions obtained by differential and gradient centrifugation to those of marker enzymes for various organelles. Prostaglandin E₂ binding sites were purified about 16-fold with respect to the homogenate in a fraction which was highly enriched in plasma membranes on the basis of the activities of the marker enzymes acetylcholinesterase and calcium-dependent ATPase, which were both purified by about 12-fold in this fraction. The plasma membrane fraction contained relatively low activities of marker enzymes for mitochondria (monoamine oxidase), lysosomes (acid phosphatase), endoplasmic reticulum (glucose-6-phosphatase), Golgi (galactosyl transferase) and chromaffin granule membranes (dopamine β-hydroxylase). The only other fractions enriched in prostaglandin E₂ binding sites were those for the endoplasmic reticulum and the Golgi, in which the binding sites were purified about 4-fold and 7-fold, respectively. This is probably due mainly to contamination with plasma membranes, since calcium-dependent ATPase and acetylcholinesterase were each purified to a similar extent in these two fractions. These data suggest that the high-affinity prostaglandin E₂ binding sites of the adrenal medulla are localized primarily on the plasma membranes of the medullary cells.     

Protein import into mitochondria: ATP-dependent protein translocation activity in a submitochondrial fraction enriched in membrane contact sites and specific proteins

To identify the membrane regions through which yeast mitochondria import proteins from the cytoplasm, we have tagged these regions with two different partly translocated precursor proteins. One of these was bound to the mitochondrial surface of ATP-depleted mitochondria and could subsequently be chased into mitochondria upon addition of ATP. The other intermediate was irreversibly stuck across both mitochondrial membranes at protein import sites. Upon subfraction of the mitochondria, both intermediates cofractionated with membrane vesicles whose buoyant density was between that of inner and outer membranes. When these vesicles were prepared from mitochondria containing the chaseable intermediate, they internalized it upon addition of ATP. A non-hydrolyzable ATP analogue was inactive. This vesicle fraction contained closed, right-side-out inner membrane vesicles attached to leaky outer membrane vesicles. The vesicles contained the mitochondrial binding sites for cytoplasmic ribosomes and contained several mitochondrial proteins that were enriched relative to markers of inner or outer membranes. By immunoelectron microscopy, two of these proteins were concentrated at sites where mitochondrial inner and outer membranes are closely apposed. We conclude that these vesicles contain contact sites between the two mitochondrial membranes, that these sites are the entry point for proteins into mitochondria, and that the isolated vesicles are still translocation competent.     

Regional and subcellular distribution of choline acetyltransferase in the brain of rats

—Homogenates of corpus striatum, cerebral cortex and hypothalamus excised from rat brain were fractionated on discontinuous Ficoll and sucrose density gradients, and the distribution of choline acetyltransferase (ChAc) in the mitochondrial and synaptosomal fractions was determined. In the hypothalamic and cortical regions the fractions enriched in synaptosomes showed much higher activity of ChAc than those containing mainly mitochondria. On the other hand, the corpus striatum showed an equal distribution of ChAc activity in those two fractions. The localization of ChAc was also studied in the postnuclear supernatants obtained from three brain regions, using continuous sucrose density gradients. The distribution of ChAc was compared to that of monoamine oxidase (MAO), potassium and protein. When the pellets obtained from the fractions collected from the gradient were suspended in sucrose, the peak of ChAc activity was close to that of MAO in all three brain regions. When 0.1 mm EDTA +1% butanol was used in order to liberate the occluded form of ChAc, the maximum liberation occurred in lighter fractions, resulting in a shift of the activity peak toward the top of the gradient. This was found with fractions from hypothalamic and cortical regions. In the striatum, the liberated ChAc remained in the same fractions as the occluded enzyme. The results indicate that ChAc is liberated only in those fractions where it is present in synaptosomes. In agreement with the results on the discontinuous gradients this occurs in particles of lower density than mitochondria in cortex and hypo-thalamus, but in particles of similar density to mitochondria in the corpus striatum, indicating regional differences in the distribution of ChAc in the brain. K+ containing particles centrifuged in less dense fractions than those containing ChAc, indicating that synaptosomes are heterogeneous with respect to these two marker substances.     

Preparation and properties of thyroid cell membranes

Summary Calf and human thyroids have been disrupted by nitrogen microcavitation, and the thyroid membranes prepared by repeated centrifugation in low ionic strength buffers. Two classes of membranes were prepared by centrifugation on a discontinuous gradient of ficoll. A lighter fraction was comprised of somewhat larger vesicles; they were higher in Na⁺–K⁺-activated ATPase, phosphodiesterase, and 5-nucleotidase than was the heavier fraction. The heavier fraction had a higher nicotinamide adenine nucleotide dehydrogenase-diaphorase activity. Thus the lighter fraction appears to have been enriched in fragments derived from the plasma membrane.     

Binding of alpha- and beta gamma-subunits of Go to beta 1-adrenoceptor in sealed unilamellar lipid vesicles.

First, we describe a preparation of sealed unilamellar lipid vesicles. When this preparation was subjected to sucrose density gradient centrifugation, two rather uniform fractions emerged, one consisting of lighter lipid-rich vesicles with average diameters ranging over 150-200 nm (fraction I), the other consisting of heavier vesicles with average diameters ranging over 30-70 nm (fraction II). When the lipid mixture containing dimyristoylglycerophosphocholine, cholesterol, dipalmitoylglycerophosphoserine and dipalmitoylglycerophosphoethanolamine at molar ratios of 54:35:10:1 was reconstituted with alpha- and beta gamma-subunits of Go-proteins purified to homogeneity from bovine brain, the lipid-rich lighter vesicle fraction I took up these subunits nearly exclusively. Whereas, when a beta 1-adrenoceptor preparation purified from turkey erythrocyte membranes was reconstituted, it was found nearly completely in the smaller heavier vesicle fraction II where it was incorporated inside-out. On co-reconstitution of either alpha o or beta gamma alone with beta 1-adrenoceptors, some of these subunits appear together with beta 1-adrenoceptors in the small vesicle fraction II, but much more alpha o was bound to the receptor in the presence of beta gamma-subunits. The observations reported are novel and surprising in several respects: firstly, they suggest that beta gamma-subunits can bind to the non-activated beta 1-receptor where they may serve as an anchor for alpha-subunits. Secondly, the binding of alpha o- and beta gamma-subunits to the beta 1-adrenoceptors enhances the basal GTPase activity of alpha o. Thirdly, since the binding domains of the beta 1-adrenoceptor for G-proteins were facing outwards in our sealed vesicle preparations, it follows that interactions of G-proteins with the beta-receptor can occur at the aqueous membrane interface as was postulated originally by M. Chabre [Trends Biochem. Sci. 12, 213-215 (1987)] for the transducin-rhodopsin interactions. Finally, the binding of Go-subunits from bovine brain to a beta 1-adrenoceptor from turkey erythrocytes was not expected, since these polypeptides are not likely to be physiological partners.     

The Peripheral-Type Benzodiazepine Receptor Is Present in Astrocytes but Is Not a Primary Site of Action for Convulsants/Anticonvulsants

Abstract: High-affinity binding sites for [³H]PK 11195 and [³H]Ro 5-4864 with the properties of the peripheral-type benzodiazepine receptor were detected in primary cultures of both mouse neocortical and cerebellar astrocytes. The binding sites were enriched in mitochondrial fractions on differential centrifugation. An 18-kDa polypeptide was specifically photolabelled in cerebellar astrocytes by [³H]-PK 14105, a photolabel for the peripheral-type benzodiazepine receptor. However, this polypeptide did not show any reactivity with an antiserum previously raised against the corresponding polypeptide from rat adrenal gland. Various anticonvulsant and convulsant agents were tested for their ability and potency at inhibiting [³H]Ro 5-4864 binding to neocortical astrocytes. Many of these compounds, previously reported to be inhibitors of diazepam binding to neocortical astrocytes, proved ineffective in this study. No correlation was observed between convulsant/anticonvulsant potency and ability to inhibit [³H]Ro 5-4864 binding to the peripheral-type benzodiazepine receptor in these cells. Thus, whereas some convulsants and anticonvulsants might interact with this astrocytic receptor, such a system has no validity as a general screening method for these agents.     

Mitochondrial boundary membrane contact sites in brain: points of hexokinase and creatine kinase location, and control of Ca2+ transport

The location of hexokinase at the surface of brain mitochondria was investigated by electron microscopy using immuno-gold labelling techniques. The enzyme was located where the two mitochondrial limiting membranes were opposed and contact sites were possible. Disruption of the outer membrane by digitonin did not remove bound hexokinase and creatine kinase from brain mitochondria, although the activity of outer membrane markers and adenylate kinase decreased, suggesting a preferential location of both enzymes in the contact sites. In agreement with that, a membrane fraction was isolated from osmotically lysed rat brain mitochondria in which hexokinase and creatine kinase were concentrated. The density of this kinase-rich fraction was specifically increased by immuno-gold labelling of hexokinase, allowing a further purification by density gradient centrifugation. The fraction was composed of inner and outer limiting membrane components as shown by the specific marker enzymes, succinate dehydrogenase and NADH-cytochrome-c-oxidase (rotenone insensitive). As reported earlier for the enriched contact site fraction of liver mitochondria the fraction from brain mitochondria contained a high activity of glutathione transferase and a low cholesterol concentration. Moreover, the contacts showed a higher Ca2+ binding capacity in comparison to outer and inner membrane fractions. This finding may have regulatory implications because glucose phosphorylation via hexokinase activated the active Ca2+ uptake system and inhibited the passive efflux, resulting in an increase of intramitochondrial Ca2+.     

Studies on isolated subcellular components of cat pancreas. I. Isolation and enzymatic characterization.

Pancreas of the cat was fractionated into its subcellular components by centrifugation through an exponential ficoll-sucrose density gradient in a zonal rotor. This enables a preparation of four fractions enriched in plasma membranes, endoplasmic reticulum, mitochondria and zymogen granules, respectively. The first fraction, enriched by 9- to 15-fold in the plasma membrane marker enzymes, hormone-stimulated adenylate cyclase, (Na+K+)-ATPase, and 5'-nucleotidase, is contaminated by membranes derived from endoplasmic reticulum but is virtually free from mitochondrial and zymogen-granule contamination. The second fraction from the zonal gradient shows only moderate enrichment of the above marker enzymes but contains a considerable quantity of plasma membrane marker enzymes and represents mostly rough endoplasmic reticulum. The third fraction contains the bulk of mitochondria and the fourth mainly zymogen granules as assessed by electron microscopy and marker enzymes for both mitochondria and zymogen granules, namely succinic dehydrogenase, trypsin and amylase. Further purification of the plasma membrane fractions by differential and sucrose step-gradient centrifugation yields plasma membranes enriched 40-fold in basal and hormone-stimulated adenylate cyclase and (Na+K+)-ATPase.