Contact sites between mitochondrial envelope membranes. Structure and function in energy- and protein-transfer

The role of endozepine in the regulation of steroid synthesis

Endozepine has recently been isolated from various steroid-forming organs. The following article explores the role of endozepine in the regulation of steroid synthesis. Steroid hormone synthesis from cholesterol begins in the inner mitochondrial membrane, where cytochrome P450 converts cholesterol to pregnenolone. Scientists thought that ACTH would stimulate this conversion, but experiments showed no such stimulation. However, addition of aminoglutethimide to block side-chain cleavage caused the expected reaction of ACTH to take place. Next the role of protein synthesis on the actions of ACTH was explored. Then endozepine was isolated from bovine fasciculata based on stimulation of pregnenolone production by freshly prepared mitochondria. After further experimentation it was concluded that endozepine is a peptide with at least two groups of actions: It binds GABAA receptors in the central nervous system, and it increases the mitochondrial synthesis of pregnenolone.

Metabolism of exogenous cholesterol by rat adrenal mitochondria is stimulated equally by physiological levels of free Ca2+ and by GTP

Adrenal mitochondria metabolize cholesterol at inner membrane (IM) cytochrome P450scc. Exogenous and outer membrane (OM) cholesterol are metabolized more slowly due to a limiting transfer of cholesterol from OM to IM. This process is stimulated by in vivo ACTH treatment and inhibited by cycloheximide (CX)-induced depletion of labile regulatory proteins. In isolated rat adrenal mitochondria, GTP enhances the metabolism of exogenous cholesterol, consistent with enhanced intermembrane cholesterol transfer (Xu et al. (1989) J. Biol Chem. 264, 17674), but metabolism of 20 alpha-hydroxycholesterol, which readily traverses mitochondrial membranes, is not affected. The non-hydrolyzable analog, GTP gamma S, completely inhibits the activation of cholesterol metabolism by GTP, suggesting a requirement for GTP hydrolysis. Low concentrations of Ca2+ (0.4-4 microM) stimulate two independent cholesterol transport processes. For exogenous cholesterol, a Ca(2+)-mediated process can replace GTP since each produces comparable stimulation and the combination produces little additional activity. This Ca2+ stimulation is insensitive to GTP gamma S and also to Ruthenium Red (RR), which prevents Ca2+ entry into the matrix. Ca2+ also enhances availability to P450 scc of endogenous OM cholesterol, which accumulates during in vivo CX-inhibition. This stimulation is, however, distinguished by insensitivity to GTP and complete inhibition by RR. Ca2+, therefore, enhances intermembrane transfer of exogenous cholesterol from OM without entry into the matrix through a process which is independently stimulated by GTP. Ca2+ induces transfer of endogenous OM cholesterol through a completely different mechanism involving RR-inhibited matrix changes.(ABSTRACT TRUNCATED AT 250 WORDS)

The compartmentation of nucleoside diphosphate kinase in mitochondria

The compartmentation of nucleoside diphosphate kinase (NDPK) was studied in mitochondria isolated from heart and liver of rat, rabbit, and pigeon. Compartmentation was assessed by determining latencies of enzyme activities, fractionating mitochondria with digitonin, and treating mitochondria with trypsin in the presence and absence of digitonin. NDPK activity in pigeon liver mitochondria was five- and seven-fold higher than in rat and rabbit liver mitochondria. The ratios of NDPK activities in liver vs. heart mitochondria were about 15 for rat, 2 for rabbit, and more than 40 for pigeon. Nearly all NDPK in pigeon liver mitochondria is in the matrix space, but outside the matrix in rat and rabbit liver mitochondria. Most NDPK in pigeon heart mitochondria was located outside the matrix while a significant fraction may be in the matrix of rat and rabbit heart mitochondria. These results are discussed relative to the assumed role that mitochondrial NDPK transfers the phosphoryl group of GTP produced in the Krebs cycle to the adenine nucleotide pool.

Sexuality of mitochondria: fusion, recombination, and plasmids

Mitochondrial fusion, recombination, and mobile genetic elements, which are essential for mitochondrial sexuality, are well established in various organisms. The recombination of mitochondrial DNA (mtDNA) depends upon fusion between parental mitochondria, and between their mtDNA-containing areas (mt-nuclei), to allow pairing between the parental mtDNAs. Such mitochondrial fusion followed by recombination may be called "mitochondrial sex." We have identified a novel mitochondrial plasmid named mF. This plasmid is apparently responsible for promoting mitochondrial fusion and crosses over with mtDNA in successive sexual crosses with mF- strains. Only in mF+ strains carrying the mF plasmid did small spherical mitochondria fuse which subsequently underwent fusion between the mt-nuclei that contained the mtDNA derived from individual mitochondria. Several successive mitochondrial divisions followed, accompanied by mt-nuclear divisions. The resulting mitochondria contained recombinant mtDNA with the mF plasmid. Such features remind us also of the bacterial conjugative plasmids such as F plasmid. Therefore, in the final part of this chapter, we discuss the origin of sex and its relationship to the sexuality of mitochondria.

The effect of calcium on mitochondrial contact sites: a study on isolated rat hearts

Mitochondrial contact sites are dynamic structures created by fusion of the inner and outer mitochondrial membranes. Stimulation of the metabolism results in an increase of the number of contact sites. Functionally, it is shown that mitochondrial creatine kinase (Mi-CK) is active in contact sites and therefore, Mi-CK cytochemistry was performed (using a tetrazolium salt) to improve the visibility of the contact sites. As calcium is involved as an intracellular messenger of hormonal stimulation, the effect of increasing extracellular calcium concentrations on the number of contact sites was investigated. Therefore, isolated rat hearts were perfused with Krebs-Henseleit buffers differing in their calcium content. During the perfusions the heart function was evaluated and at the end of each experiment, the hearts were processed for Mi CK cytochemistry and the number of contact sites was expressed as the ratio of surface densities contact sites to mitochondrial membranes (Ss). At 2.2 mM calcium perfusion, the physiological parameters and the Ss reached a maximum. This was in contrast to the 0.6 and the 3.6 mM of calcium perfusions whereby both the physiological values and the Ss were decreased. Treatment with noradrenaline in vivo, as was done in previous studies or perfusion with 2.2 mM of calcium ends up with similar values for Ss. From these results, it could be suggested that there might be a link between calcium, heart function and the formation of Mi CK active contact sites.

Electrophysiology of the inner mitochondrial membrane

The application of electrophysiological techniques to mitochondrial membranes has allowed the observation and partial characterization of several ion channels, including an ATP-sensitive K(+)-selective one, a high-conductance "megachannel", a 107 pS anionic channel and three others studied at alkaline pH's. A reliable correlation with the results of non-electrophysiological studies has been obtained so far only for the first two cases. Activities presumed to be associated with the Ca2+ uniporter and with the adenine nucleotide translocator, as well as the presence of various other conductances have also been reported. The review summarizes the main properties of these pores and their possible relationship to permeation pathways identified in biochemical studies.

Mitochondrial creatine kinase: a major constituent of pathological inclusions seen in mitochondrial myopathies

Overaccumulation of abnormally organized mitochondria in so-called "ragged-red" skeletal muscle fibers is a morphological hallmark of mitochondrial myopathies, in particular of mitochondrial encephalomyopathies. Characteristic for the abnormal mitochondria is the occurrence of highly ordered crystalline inclusions. Immuno-electron microscopy revealed that these inclusions react heavily with specific antibodies against mitochondrial creatine kinase (Mi-CK). Image processing of selected crystalline inclusions, sectioned along the crystallographic b, c planes, resulted in an averaged picture displaying an arrangement of regular, square-shaped particles with a central cavity. The overall appearance, dimensions, and symmetry of these building blocks are very reminiscent of single isolated Mi-CK octamers. Taking these findings together, it is concluded that Mi-CK octamers indeed represent the major, if not the only, component of these mitochondrial inclusions.

Distribution of phospholipid hydroperoxide glutathione peroxidase (PHGPx) in rat testis mitochondria

The distribution of phospholipid hydroperoxide glutathione peroxidase (PHGPx) in isolated rat testis mitochondria was investigated, using a reverse sucrose density gradient centrifugation procedure for the separation of the inner and outer membranes and the contact sites between the two membranes. The results indicate that PHGPx is largely localized in the contact sites fraction. This finding might therefore suggest that the enzyme has more than just an antioxidant function.

The structure of mitochondrial creatine kinase and its membrane binding properties

The biochemical and biophysical characterization of the mitochondrial creatine kinase (Mi-CK) from chicken cardiac muscle is reviewed with emphasis on the structure of the octameric oligomer by electron microscopy and on its membrane binding properties. Information about shape, molecular symmetry and dimensions of the Mi-CK octamer, as obtained by different sample preparation techniques in combination with image processing methods, are compared. The organization of the four dimeric subunits into the Mi-CK complex as apparent as apparent in the end-on projections is discussed and the consistently observed high binding affinity of the four-fold symmetric end-on faces towards many support films and towards each other is outlined. A study on the oligomeric state of the enzyme in solution and in intact mitochondria, using chemical crosslinking reagents, is presented together with the results of a search for a possible linkage of Mi-CK with the adenine nucleotide translocator (ANT). The nature of Mi-CK binding to model membranes, demonstrating that rather the octameric than the dimeric subspecies is involved in lipid interaction and membrane contact formation, is resumed and put into relation to our structural observations. The findings are discussed in light of a possible in vivo function of the Mi-CK octamer bridging the gap between outer and inner mitochondrial membranes at the contact sites.

The influence of the cytosolic oncotic pressure on the permeability of the mitochondrial outer membrane for ADP: implications for the kinetic properties of mitochondrial creatine kinase and for ADP channelling into the intermembrane space

Cytosolic proteins as components of the physiological mitochondrial environment were substituted by dextrans added to media normally used for incubation of isolated mitochondria. Under these conditions the volume of the intermembrane space decreases and the contact sites between the both mitochondrial membranes increase drastically. These morphological changes are accompanied by a reduced permeability of the mitochondrial outer compartment for adenine nucleotides as it was shown by extensive kinetic studies of mitochondrial enzymes (oxidative phosphorylation, mi-creatine kinase, mi-adenylate kinase). The decreased permeability of the mitochondrial outer membrane causes increased rate dependent concentration gradients in the micromolar range for adenine nucleotides between the intermembrane space and the extramitochondrial space. Although all metabolites crossing the outer membrane exhibit the same concentration gradients, considerable compartmentations are detectable for ADP only due to its low extramitochondrial concentration. The consequences of ADP-compartmentation in the mitochondrial intermembrane space for ADP-channelling into the mitochondria are discussed.

The importance of the outer mitochondrial compartment in regulation of energy metabolism

Substitution of physiologically present macromolecules during isolation of mitochondria and investigation of their functions led to a significant change in regulation of oxidative phosphorylation. The differences compared to conventionally isolated mitochondria were that stimulation of oxidative phosphorylation appeared to rather depend on the activity of peripheral kinases than on the addition of free ADP. The localisation of peripheral kinases such as hexokinase and mitochondrial creatine kinase are described as well as the effects of macromolecules on the regulation of bound hexokinase and of oxidative phosphorylation via this enzyme.

Creatine metabolism and the consequences of creatine depletion in muscle

Currently, considerable research activities are focussing on biochemical, physiological and pathological aspects of the creatine kinase (CK)-phosphorylcreatine (PCr)-creatine (Cr) system (for reviews see [1,2]), but only little effort is directed towards a thorough investigation of Cr metabolism as a whole. However, a detailed knowledge of Cr metabolism is essential for a deeper understanding of bioenergetics in general and, for example, of the effects of muscular dystrophies, atrophies, CK deficiencies (e.g. in transgenic animals) or Cr analogues on the energy metabolism of the tissues involved. Therefore, the present article provides a short overview on the reactions and enzymes involved in Cr biosynthesis and degradation, on the organization and regulation of Cr metabolism within the body, as well as on the metabolic consequences of 3-guanidinopropionate (GPA) feeding which is known to induce a Cr deficiency in muscle. In addition, the phenotype of muscles depleted of Cr and PCr by GPA feeding is put into context with recent investigations on the muscle phenotype of 'gene knockout' mice deficient in the cytosolic muscle-type M-CK.

Creatine kinase in non-muscle tissues and cells

Over the past years, a concept for creatine kinase function, the 'PCr-circuit' model, has evolved. Based on this concept, multiple functions for the CK/PCr-system have been proposed, such as an energy buffering function, regulatory functions, as well as an energy transport function, mostly based on studies with muscle. While the temporal energy buffering and metabolic regulatory roles of CK are widely accepted, the spatial buffering or energy transport function, that is, the shuttling of PCr and Cr between sites of energy utilization and energy demand, is still being debated. There is, however, much circumstantial evidence, that supports the latter role of CK including the distinct, isoenzyme-specific subcellular localization of CK isoenzymes, the isolation and characterization of functionally coupled in vitro microcompartments of CK with a variety of cellular ATPases, and the observed functional coupling of mitochondrial oxidative phosphorylation with mitochondrial CK. New insight concerning the functions of the CK/PCr-system has been gained from recent M-CK null-mutant transgenic mice and by the investigation of CK localization and function in certain highly specialized non-muscle tissues and cells, such as electrocytes, retina photoreceptor cells, brain cells, kidney, salt glands, myometrium, placenta, pancreas, thymus, thyroid, intestinal brush-border epithelial cells, endothelial cells, cartilage and bone cells, macrophages, blood platelets, tumor and cancer cells. Studies with electric organ, including in vivo 31P-NMR, clearly reveal the buffer function of the CK/PCr-system in electrocytes and additionally corroborate a direct functional coupling of membrane-bound CK to the Na+/K(+)-ATPase. On the other hand, experiments with live sperm and recent in vivo 31P-NMR measurements on brain provide convincing evidence for the transport function of the CK/PCr-system. We report on new findings concerning the isoenzyme-specific cellular localization and subcellular compartmentation of CK isoenzymes in photoreceptor cells, in glial and neuronal cells of the cerebellum and in spermatozoa. Finally, the regulation of CK expression by hormones is discussed, and new developments concerning a connection of CK with malignancy and cancer are illuminated. Most interesting in this respect is the observed upregulation of CK expression by adenoviral oncogenes.

Mitochondrial biogenesis in striated muscle

Mitochondrial biogenesis (synthesis) has been observed to occur in skeletal muscle in response to chronic use. It also occurs in cardiac muscle during growth and hypertrophy, and it may be impaired during the aging process. This review summarizes the literature on the processes of mitochondrial biogenesis at the biochemical and molecular levels, with particular reference to striated muscles. Mitochondrial biogenesis involves the expression of nuclear and mitochondrial genes and the coordination of these two genomes, the synthesis of proteins and phospholipids and their import into the organelle, and the incorporation of these lipids and proteins into their appropriate locations within the matrix, inner or outer membranes. The emphasis is on the regulation of these events, with information derived in part from other cellular systems. Although descriptions of mitochondrial content changes in heart and skeletal muscle during altered physiological states are plentiful, much work is needed at the molecular level to investigate the regulatory processes involved. A knowledge of biochemical and molecular biology techniques is essential for continued progress in the field. This is a promising area, and potential new avenues for future research are suggested.

Mitochondrial matrix granules: their behavior during changing metabolic situations and their relationship to contact sites between inner and outer mitochondrial membranes

Since their discovery in the early fifties mitochondrial granules have been the subject of many researches. Some twenty years ago two hypotheses on their function were introduced. Peachey thought that the granules were a sink of cations and that they would eventually regulate the concentrations of these ions. Alternatively, Barnard thought that the granules were precursors of the mitochondrial inner membrane. There are only a few data on organic constituents of the granules. Phospholipids (e.g., cardiolipin) glycoprotein or lipids, calcium precipitable lipoprotein, cytochrome c oxidase seem to be present in the granules. There has been much debate on whether calcium is present or not. Reports are mostly based on X-ray microanalysis, the result of which depends on preparation techniques. In heart muscle in stimulating situations the NMG (native matrix granules) move towards the inner membrane and are incorporated in it. They appear to create contact sites between inner and outer mitochondrial membranes in which enzymes can function efficiently. It is hypothetized that the system, NMG-contact sites, forms the structural basis of a regulatory mechanism, by which cells can cope with a high and sudden energy demand.

A morphological view on mitochondrial protein targeting

Mitochondrial protein targeting includes both intramitochondrial sorting of proteins encoded by the organellar genome and import and subsequent sorting of nuclear encoded precursor proteins. Only a few proteins are encoded by the mitochondrial genome and synthesized in the organellar matrix. These include predominantly inner membrane proteins that are perhaps co-translationally inserted into this membrane. Biochemical data suggest that insertion into the inner membrane may be confined to the inner boundary membrane. Ultrastructurally, however, a preferential association of ribosomes with either inner boundary or cristae membranes has not been established. The majority of the mitochondrial proteins are nuclear encoded and synthesized as precursors in the cytosol. Electron microscopic studies revealed that import of precursor proteins is generally confined to sites where both mitochondrial envelope membranes are closely apposed. In line with these observations, biochemical studies indicated that precursor proteins destined for the inner membrane or matrix have to interact with the energized inner membrane to allow complete passage of the precursor through the outer membrane. As a consequence, the mitochondrial envelope membranes have to be in close proximity at protein import sites. In isolated mitochondria distinct sites (designated as contact sites) exist where both envelope membranes are closely apposed and presumably stably associated. In situ, however, mitochondrial boundary membranes are in close proximity over large areas that cover almost the entire mitochondrial periphery. Consequently, the relative area of the mitochondrial surface, where both boundary membranes are in sufficient proximity for allowing protein translocation, is generally larger in situ compared to that in isolated organelles. Immunocytochemical localization studies showed a rather random distribution of components of the mitochondrial protein translocation machinery over the entire mitochondrial surface and not confined to contact sites. Based on these ultrastructural data and recent biochemical findings we propose that mitochondrial protein import sites are dynamic in nature and include relatively labile regions of close association of the boundary membranes. In vitro, however, mitochondrial protein import may preferentially take place at or near the presumably stable contact sites.

Dynamics of mitochondria in living cells: shape changes, dislocations, fusion, and fission of mitochondria

Mitochondria are semi-autonomous organelles which are endowed with the ability to change their shape (e.g., by elongation, shortening, branching, buckling, swelling) and their location inside a living cell. In addition they may fuse or divide. These dynamics are discussed. Dislocation of mitochondria may result from their interaction with elements of the cytoskeleton, with microtubules in particular, and from processes intrinsic to the mitochondria themselves. Morphological criteria and differences in the fate of some mitochondria argue for the presence of more than one mitochondrial population in some animal cells. Whether these reflect genetic differences remains obscure. Emphasis is laid on the methods for visualizing mitochondria in cells and following their behaviour. Fluorescence methods provide unique possibilities because of their high resolving power and because some of the mitochondria-specific fluorochromes can be used to reveal the membrane potential. Fusion and fission often occur in short time intervals within the same group of mitochondria. At sites of fusion of two mitochondria material of the inner membrane, the matrix compartment seems to accumulate. The original arrangement of the fusion partners is maintained for some minutes. Fission is a dynamic event which, like fusion, in most cases observed in vertebrate cell cultures is not a straight forward process but rather requires several "trials" until the division finally occurs. Regarding fusion and fission hitherto unpublished phase contrast micrographs, and electron micrographs have been included.

Interactions between brain mitochondria and cytoskeleton: evidence for specialized outer membrane domains involved in the association of cytoskeleton-associated proteins to mitochondria in situ and in vitro

The surface distribution of several proteins (porin, hexokinase, and two proteins associated with microtubules or actin filaments) on the outer membrane of brain mitochondria was analyzed by immunogold labelling of purified mitochondria in vitro. The results suggest the existence of specialized domains for the distribution of porin in the outer mitochondrial membrane. Similarities between the distribution of porin and the distribution of microtubule-associated proteins bound in vitro to mitochondria suggested that mitochondria and microtubules interact by binding microtubule-associated proteins to porin-containing domains of the outer membrane. This hypothesis was supported by biochemical studies on outer mitochondrial proteins involved in in vitro binding of cytoskeleton elements. In vitro interactions between mitochondria and microtubules or neurofilaments were analyzed by electron microscopy. These studies revealed cross-bridging between the outer membrane of mitochondria and the two cytoskeleton elements. Cross-bridging was influenced by ATP hydrolysis and by several proteins associated with the surface of mitochondria or with microtubules. In addition, unidentified proteins which were recognized by antibodies to all intermediate filaments subunits were associated either with the mitochondrial surface or with microtubules. This data suggest the participation of additional cytoplasmic proteins in the interactions between cytoskeleton elements and mitochondria.

Bioenergetics. Dissecting the role of creatine kinase

The phenotype of "gene knockout" mice deficient in a creatine kinase isoform sheds new light on the physiological function of the "phosphocreatine circuit."

Kinetics of assembly and dissociation of the mitochondrial creatine kinase octamer. A fluorescence study

The dissociation of octameric mitochondrial creatine kinase (Mi-CK) into dimers induced by the transition-state analogue complex (TSAC) mixture (creatine+Mg(2+)+ADP+NO3-) is accompanied by a large (25.2%) decrease in Trp fluorescence. This effect is caused by a Trp residue situated at the dimer-dimer interface within the octamer, which becomes susceptible to solvent quenching upon octamer dissociation. Octamer formation, induced by adding excess EDTA to TSAC-dissociated Mi-CK, involves a transient tetrameric species, whereas the dissociation reaction proceeds in a one-step, all-or-none fashion. From fluorescence spectroscopic investigations of the octamer formation and dissociation reactions, a first-order dissociation rate constant of 0.19 min-1 and a bimolecular association rate constant of 318 M-1 s-1 at 30 degrees C were obtained. The octamers formed after EDTA addition can be dissociated again by lowering the temperature to 4 degrees C, indicating a substantial hydrophobic contribution to the interactions stabilizing the octamer.

The mitochondrial permeability transition pore may comprise VDAC molecules. I. Binary structure and voltage dependence of the pore

Electrophysiological records suggest that the pore responsible for the mitochondrial Ca(2+)-dependent permeability transition (PTP), identified as the mitochondrial megachannel (MMC) observed in patch-clamp experiments, may comprise two cooperating porin (VDAC) molecules. We have re-investigated the voltage dependence of the megachannel, which favors the closed state(s) at negative (physiological) transmembrane potentials. This behavior confirms that MMC corresponds to the permeabilization pore. As detailed in the accompanying paper [(1993) FEBS Lett. 330, 206-210] this voltage dependence resembles that of VDAC. Alpidem, a ligand of the mitochondrial benzodiazepine receptor, which reportedly comprises VDAC, the adenine nucleotide carrier and a third component, elicited currents from silent mitoplast patches, suggesting that the benzodiazepine receptor may be identical to the PTP/MMC.

The mitochondrial permeability transition pore may comprise VDAC molecules. II. The electrophysiological properties of VDAC are compatible with those of the mitochondrial megachannel

The electrophysiological properties of isolated mitochondrial porin (VDAC), reconstituted in planar bilayers or proteoliposomes, resemble those of the mitochondrial megachannel believed to be the permeability transition pore. In particular, a correspondence was found with regard to the voltage dependence: VDAC was driven to closed states by potentials of either sign, but the effect was not symmetrical; voltages negative in the compartment to which VDAC was added were more effective. The results are consistent with the hypothesis that the PTP may consist of two cooperating VDAC channels, plus presumably an adenine nucleotide carrier dimer and a third component known to be part of the mitochondrial benzodiazepine receptor.

One of the chloroplast envelope ion channels is probably related to the mitochondrial VDAC

The voltage dependence of large conductance channels in the intact chloroplast envelope of Nitellopsis obtusa was examined using the patch-clamp technique. The channel switched to the lower conducting substates with amplitudes of around 45 and 20% of that in the open state when potentials larger than 30 mV were applied. The steepness of the voltage dependence approximately corresponds to 4 elementary charges being transferred across the entire voltage drop to close the channel both at positive and negative potentials. The transition to the closed substates could also be induced by König's polyanion, a well known modulator of the mitochondrial outer membrane channel.

Effect of macromolecules on the structure of the mitochondrial inter-membrane space and the regulation of hexokinase

Macromolecules as components of the physiological mitochondrial environment were substituted by addition of 10% dextran 70. This led to a significant reduction of the space between the two envelope and the crista membranes and to an increase of contact sites as observed by freeze-fracture analysis. The preferential binding of hexokinase in these sites was employed to further analyze the dextran effect: (i) desorption of the enzyme by digitonin treatment was found to be significantly reduced in the presence of dextran although liberation of adenylate kinase and monoamine oxidase were not affected, (ii) the affinity of isolated hexokinase isozyme I to liver mitochondria was increased by dextran. Generally the binding of hexokinase to intact mitochondria (also control mitochondria) followed a co-operative mechanism and led to an activation. Cooperativity and activation were not observed when the contact formation was suppressed by dinitrophenol or glycerol. The binding of hexokinase to the isolated outer membrane resembled that of mitochondria in the absence of contacts (i.e., no cooperativity and activation). Conversely to the observation in intact mitochondria, dextran rather reduced the affinity of hexokinase to the isolated outer membrane. Kinetic analyses of the dextran effect served to explain the function of contact site specific hexokinase binding. We observed that dextran improved the hexokinase dependent stimulation of the oxidative phosphorylation (state 3 respiration), while the activity of the enzyme with internal or external ATP remained unaffected. The results suggest three things: (i) that contact sites are probably more frequent in the intact cell than in vitro in the absence of macromolecules, (ii) that the contact preference of hexokinase serves rather the ADP supply of the translocator than the ATP transfer to the enzyme and (iii) that the total cellular hexokinase activity may be regulated by specific binding of the enzyme to the contact sites, either because of a different pore structure or because of additional components exclusively exposed in these sites.

Transport properties and inhibitor sensitivity of isolated and reconstituted porin differ from those of intact mitochondria

The pore-forming protein porin has been isolated from rat heart mitochondria and reconstituted in phospholipid vesicles of different composition. Rapid release of anions, cations and non-charged molecules has been demonstrated from the proteoliposomes but not from the protein-free liposomes. In spite of its higher molecular mass and charges, the movement of ATP was almost as fast as that of inorganic phosphate. Polyanion (1:2:3 copolymer of methacrylate/maleate/styrene), a potent inhibitor of porin residing in the mitochondrial contact sites decreased the solute movements but did not completely block any of the investigated transport processes (phosphate, chloride, ATP). Alterations of the lipid environment had significant effect: an increase in the proportion of soybean phospholipids to egg yolk phospholipids resulted in a decrease in the amount of transported substance but did not fully inhibit the ion movements. It is concluded that the transport properties of porin reconstituted in artificial phospholipid membranes are different from the characteristics of porin prevailing in the mitochondrial contact sites and additional regulatory factors are suggested to be effective in the intact mitochondria.

Expression of active octameric chicken cardiac mitochondrial creatine kinase in Escherichia coli

Sarcomeric mitochondrial creatine kinase (Mib-CK) of chicken was expressed in Escherichia coli as a soluble enzyme by using an inducible phage-T7 promoter. Up to one third of the protein in E. coli extracts consisted of soluble recombinant Mib-CK in an enzymically active form. Approx. 20 mg of nearly-homogenous Mib-CK was isolated in a two-step isolation procedure starting with 1 litre of isopropyl beta-D-thiogalactopyranoside-induced E. coli culture, whereas previous attempts to express other CK genes in E. coli have resulted in 20-fold lower yields and inclusion-body formation. Selection of the Mib-CK expression plasmid on media containing kanamycin rather than ampicillin extended the time period of maximal Mib-CK expression. Recombinant Mib-CK displayed an identical N-terminal amino acid sequence, identical Km for phosphocreatine and Vmax. values, the same electrophoretic behaviour and the same immunological cross-reactivity as the native enzyme isolated from chicken heart mitochondria. The recombinant Mib-CK had the same molecular mass as native chicken Mib-CK in m.s. analysis, indicating that post-translational modification of the enzyme in chicken tissue does not occur. As judged by gel-permeation chromatography and electron microscopy, recombinant enzyme formed predominantly octameric oligomers with the same overall structure as the chicken heart enzyme. Furthermore, the enzymes isolated from both sources formed protein crystals of space group P42(1)2, when grown in the absence of ATP, with one Mi-CK octamer per asymmetric unit. The indistinguishable X-ray-diffraction patterns indicate identical structures for the native and recombinant proteins.

Regulation of cholesterol movement to mitochondrial cytochrome P450scc in steroid hormone synthesis

Transfer of cholesterol to cytochrome P450scc is generally the rate-limiting step in steroid synthesis. Depending on the steroidogenic cell, cholesterol is supplied from low or high density lipoproteins (LDL or HDL) or de novo synthesis. ACTH and gonadotropins stimulate this cholesterol transfer prior to activation of gene transcription, both through increasing the availability of cytosolic free cholesterol and through enhanced cholesterol transfer between the outer and inner mitochondrial membranes. Cytosolic free cholesterol from LDL or HDL is primarily increased through enhanced cholesterol ester hydrolysis and suppressed esterification, but increased de novo synthesis can be significant. Elements of the cytoskeleton, probably in conjunction with sterol carrier protein(2) (SCP(2)), mediate cholesterol transfer to the mitochondrial outer membranes. Several factors contribute to the transfer of cholesterol between mitochondrial membranes; steroidogenesis activator peptide acts synergistically with GTP and is supplemented by SCP(2). 5-Hydroperoxyeicosatrienoic acid, endozepine (at peripheral benzodiazepine receptors), and rapid changes in outer membrane phospholipid content may also contribute stimulatory effects at this step. It is suggested that hormonal activation, through these factors, alters membrane structure around mitochondrial intermembrane contact sites, which also function to transfer ADP, phospholipids, and proteins to the inner mitochondria. Cholesterol transfer may occur following a labile fusion of inner and outer membranes, stimulated through involvement of cardiolipin and phosphatidylethanolamine in hexagonal phase membrane domains. Ligand binding to benzodiazepine receptors and the mitochondrial uptake of 37 kDa phosphoproteins that uniquely characterize steroidogenic mitochondria could possibly facilitate these changes. ACTH activation of rat adrenals increases the susceptibility of mitochondrial outer membranes to digitonin solubilization, suggesting increased cholesterol availability. Proteins associated with contact sites were not solubilized, indicating that this part of the outer membrane is resistant to this treatment. Two pools of reactive cholesterol within adrenal mitochondria have been distinguished by different isocitrate- and succinate-supported metabolism. These pools appear to be differentially affected in vitro by the above stimulatory factors.

Phospholipid import into mitochondria: possible regulation mediated through lipid polymorphism

We previously demonstrated that the translocation of microsomal phosphatidylserine to the inner mitochondrial membrane occurs via contact sites before decarboxylation. According to the specific lipid composition of contact sites, we investigated lipid polymorphism as a possible regulation mechanism of phospholipid import into mitochondria. Phosphatidylserine import into mitochondria is increased in the presence of calcium, under conditions where non bilayer lipid-structures can be induced in cardiolipin-containing membranes. The results are discussed in terms of structural as well as functional domains heterogeneity within contact sites.

Single channel recording in the chloroplast envelope

The patch-clamp technique was applied to study ion channels in the intact chloroplast envelope. Three channel types were characterized: two cation-selective, with a conductance (in 100 mM KCl) of 517 and 1016 pS, respectively, and one anion-selective with a conductance of 159 pS. All three channels showed voltage-dependent closures at both positive and negative membrane potentials.

Coordinated regulation of cerebral glycolytic and oxidative metabolism, mediated by mitochondrially bound hexokinase dependent on intramitochondrially generated ATP

Hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) of rat brain mitochondria is associated with membrane regions thought to correspond to contact sites (regions of close interaction of the inner and outer mitochondrial membranes). Two intramitochondrial compartments of ATP also appear to be located at contact sites, and are dependent on oxidative phosphorylation for their generation. Neither of these compartments was associated with the intermembranal space containing adenylate kinase, nor was there detectable intramitochondrial compartmentation of ATP generated by the adenylate kinase reaction. Formation of these compartments was not dependent on the presence of bound hexokinase since equivalent amounts of compartmented ATP were found in mitochondria from which a major portion of the hexokinase had been removed by treatment with Glc-6-P. During active oxidative phosphorylation, mitochondrially bound hexokinase is totally dependent upon intramitochondrially compartmented ATP as a substrate. Both the levels of ATP in the intramitochondrial compartments and the rate of glucose phosphorylation by mitochondrially bound hexokinase were shown to be correlated with the rate of oxidative phosphorylation. This dependence of hexokinase on intramitochondrial ATP levels that reflect the status of mitochondrial oxidative metabolism provides a mechanism by which hexokinase can serve as a mediator, coordinating the rate at which glucose is introduced into the glycolytic pathway with terminal oxidative stages of metabolism and avoiding the accumulation of lactate which has been associated with toxic effects on the brain.

The 'ins' and 'outs' of mitochondrial membrane channels

The outer membrane of the mitochondrion contains thousands of copies of a pore-forming protein called VDAC or porin. Considerable progress has been made towards elucidating the molecular structure of this channel. Moreover, mounting evidence that the permeability of VDAC may be regulated is challenging the textbook notion of the outer membrane as a simple sieve. Numerous other channel activities have been detected by electrophysiol approaches in both the outer and inner mitochondrial membranes. The inner-membrane channels do not appear to be open under normal physiological conditions and so should not dissipate energy-transducing ion gradients. The biological functions of the different classes of mitochondrial channels are uncertain, but several possibilities (including protein translocation) are being explored.

Intracellular compartmentation, structure and function of creatine kinase isoenzymes in tissues with high and fluctuating energy demands: the 'phosphocreatine circuit' for cellular energy homeostasis

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