Fusion of liposomes with mitochondrial inner membranes

A procedure is outlined for the fusion of mixed phospholipid liposomes (small unilamellar vesicles) with the mitochondrial inner membrane, which enriches the membrane lipid bilayer 30-700% in a controlled fashion. Fusion was initiated by manipulation of the pH of a mixture of freshly sonicated liposomes and the functional inner membrane/matrix fraction of rat liver mitochondria. During the pH fusion procedure, liposomes became closely apposed with and sequestered by the inner membranes as revealed by freeze-fracture electron microscopy. After the pH fusion procedure, a number of ultrastructural, compositional, and functional characteristics were found to be proportionally related: the membrane surface area increased; the lateral density distribution of intramembrane particles (integral proteins) in the plane of the membrane decreased whereas the particles remained random; the membrane became more buoyant; the ratio of membrane lipid phosphorus to total membrane protein increased; the ratio of membrane lipid phosphorus to heme a of cytochrome c oxidase increased; and the rate of electron transfer between some interacting membrane oxidoreduction proteins decreased. These data reveal that liposomal phospholipid was incorporated into the membrane bilayer (not simply adsorbed to the membrane surface) and that integral membrane proteins diffused freely into the laterally expanding bilayer. Furthermore, the data suggest that the rate of electron transfer may be limited by the rate of lateral diffusion of oxidoreduction components in the bilayer of the mitochondrial inner membrane.     

Lateral translational diffusion of cytochrome c oxidase in the mitochondrial energy-transducing membrane

The degree of freedom for lateral translational diffusion by cytochrome c oxidase and other integral proteins in the energy-transducing membrane of the mitochondrion was determined by combining the use of an immunoglobulin probe monospecific for the oxidase with thermotropic lipid phase transitions. Lateral mobility of the oxidase was monitored by observing the distribution of the immunoglobulin probe on the membrane surface by deep-etch electron microscopy and by observing the distribution of intramembrane particles (integral proteins) in the hydrophobic interior of the membrane by freeze-fracture electron microscopy. Incubation of the membrane with the immunoglobulin resulted in a time-dependent clustering of predominantly large intramembrane particles. Low temperature-induced lipid phase transitions resulted in the close packing of all intramembrane particles and cytochrome c oxidase by lateral exclusion from domains of gel-state bilayer lipid and was completely reversible. However, when cytochrome c oxidase was crosslinked through an immunoglobulin lattice prior to returning the membrane to above the lipid phase transition temperature, small intramembrane particles rerandomized while the large oxidase-related particles remained clustered. These observations reveal that cytochrome c oxidase can diffuse laterally in the energy-transducing membrane, either independently of all other integral proteins or in physical union with one or more other integral proteins. In addition, many other as yet unidentified smaller integral proteins can diffuse independently of the oxidase.     

Fluidity in mitochondrial membranes: thermotropic lateral translational motion of intramembrane particles.

The fracture faces of frozen rat liver mitochondria reveal that intramembrane particles can be induced to under go long-range lateral translational motion and aggregation, which parallel the appearance of large, particle-free smooth patches in the hydrophobic interior of the two mitochondrial membranes. These lateral separations were observed under conditions that induce thermotropic lipid-lipid phase separations. Low temperature-induced lateral separation occurred between the intramembrane particles (integral proteins) and smooth patches (bilayer lipid) at temperatures between about 10 and -12 degrees in the outer membrane and between about -4 and -12 degrees in the inner, energy transducing membrane.     

Reconstitution of intramembrane particles in recombinants of erythrocyte protein band 3 and lipid: effects of spectrin-actin association.

The integral membrane protein Band 3 of the human erythrocyte, either purified or in a crude Triton X-100 extract of ghosts, was combined with egg lecithin in a cholate solution. During dialysis to remove cholate, lipid bilayer vesicles formed in which Band 3 existed as a dimer and in which intramembrane particles indistinguishable from those in the native membrane were exposed by freeze-fracturing. The recombinant vesicles were stable in both high and low salt concentrations, sedimented at a density that increased in prportion to their protein content, and bound spectrin-actin extracted from erythrocyte ghosts. When spectrin-actin was associated with the vesicles, the behavior of the recombinant intramembrane particles simulated that of the erythrocyte ghost intramembrane particles: they were dispersed at pH 7.6 and aggregrated at pH 5-5.5. Thus, some of the characteristics of the native membrane have been reconstituted in the recombinant.     

Reconstitution of a functional synaptosomal membrane possessing the protein constituents involved in acetylcholine translocation.

Reconstitution of a functional presynaptic membrane possessing calcium-dependent acetylcholine release properties has been achieved. The proteoliposomal membrane obtained gains its acetylcholine-releasing capabilities from presynaptic membrane proteins. At the peak of acetylcholine release, intramembrane particles became more numerous in one of the proteoliposomal membrane faces. This phenomenon resembles the intramembrane particle rearrangements found in stimulated synaptosomes. No visible structures capable of releasing acetylcholine as a result of the calcium influx were found inside the proteoliposomes. This supports the view that the release of free cytosolic acetylcholine from stimulated nerve terminals can be directly attributed to presynaptic membrane proteins. These proteins were extracted in a functional form from the synaptosomal membrane.     

Numerical densities of intramembrane particles in the cardiac sarcolemma of normal and myopathic Syrian hamsters

The purpose of this study was to examine the density of intramembrane particles in the cardiac sarcolemma of normal and myopathic Syrian hamsters in a search for a morphological marker of a putative membrane defect. Hereditary cardiomyopathy in hamsters is manifested by progressive multifocal skeletal and cardiac muscle necrosis. Although pharmacological and biochemical data suggest a molecular defect in the cardiac sarcolemma, there has been no morphological observation that would substantiate this suggestion. We quantified numerical densities of intramembrane particles in freeze-fractured sarcolemmal membrane protoplasmic and extracellular faces from the left and right ventricular myocardium of female 25-day-old hamsters of the U.M.-X 7.1 cardiomyopathic line compared with sex- and age-matched randomly bred Syrian hamsters. Intramembrane particle numerical densities significantly increased above control values in cardiomyopathic hamsters for protoplasmic face (from 2188 +/- 61 to 2454 +/- 89 microns-2 in left ventricle (P less than 0.025) and from 2255 +/- 83 to 2574 +/- 56 microns-2 in right ventricle (P less than 0.001]. There was no significant difference between intramembrane particle densities of normal and cardiomyopathic hamsters for extracellular face (707 +/- 45 and 687 +/- 49 microns-2 in the left ventricle and 742 +/- 41 and 746 +/- 28 microns-2 in the right ventricle). These results implicate an increase of protoplasmic face-associated integral proteins in the sarcolemmal membrane of cardiomyopathic hamster. The significance of this finding is not known. It may represent an adaptive change related to a molecular defect in the sarcolemmal membrane of cardiomyopathic hamster.     

Substrate specificity of the TIM22 mitochondrial import pathway revealed with small molecule inhibitor of protein translocation

The TIM22 protein import pathway mediates the import of membrane proteins into the mitochondrial inner membrane and consists of two intermembrane space chaperone complexes, the Tim9-Tim10 and Tim8-Tim13 complexes. To facilitate mechanistic studies, we developed a chemical-genetic approach to identify small molecule agonists that caused lethality to a tim10-1 yeast mutant at the permissive temperature. One molecule, MitoBloCK-1, attenuated the import of the carrier proteins including the ADP/ATP and phosphate carriers, but not proteins that used the TIM23 or the Mia40/Erv1 translocation pathways. MitoBloCK-1 impeded binding of the Tim9-Tim10 complex to the substrate during an early stage of translocation, when the substrate was crossing the outer membrane. As a probe to determine the substrate specificity of the small Tim proteins, MitoBloCK-1 impaired the import of Tim22 and Tafazzin, but not Tim23, indicating that the Tim9-Tim10 complex mediates the import of a subset of inner membrane proteins. MitoBloCK-1 also inhibited growth of mammalian cells and import of the ADP/ATP carrier, but not TIM23 substrates, confirming that MitoBloCK-1 can be used to understand mammalian mitochondrial import and dysfunction linked to inherited human disease. Our approach of screening chemical libraries for compounds causing synthetic genetic lethality to identify inhibitors of mitochondrial protein translocation in yeast validates the generation of new probes to facilitate mechanistic studies in yeast and mammalian mitochondria.     

Structural features of the rat small intestinal microvillus membrane in acute experimental diabetes

Experimentally induced diabetes enhances the specific activity of several microvillus membrane proteins in the rat small intestine. The increase in the specific activity of sucrase-isomaltase has been shown by others to be due to an increase in enzyme protein, raising the possibility that diabetes induces a generalized increase in microvillus membrane proteins. Since intramembrane particles (IMPs) seen on freeze-fracture replicas of microvillus membranes are thought to represent integral membrane proteins, we compared microvillus IMP densities in diabetic rats with those in control rats. In addition, mucosal sucrase, maltase, and alkaline phosphatase specific activities were measured in all animals. Diabetic rats had significantly increased sucrase and maltase but not alkaline phosphatase specific activities compared with control rats. The density of microvillus IMPs on both the protoplasmic and extracellular fracture faces of undifferentiated crypt cells and villus absorptive cells was not increased in experimental diabetes. These data indicate that diabetes does not result in a generalized increase in microvillus membrane proteins. Thus the enhanced activity of microvillus membrane proteins in diabetes appears to be highly selective.Supported by National Institutes of Health research grants AM 27972 and AM 17537. Drs. Madara and Wolf were supported in part by NRSITP AM 07121.     

Reactivities and clinical relevance of antimitochondrial antibodies to four mitochondrial inner membrane proteins in sera of patients with primary biliary cirrhosis

Antimitochondrial antibodies are characteristically detected in sera of patients with primary biliary cirrhosis. The antigens to which the antimitochondrial antibodies in primary biliary cirrhosis sera react have been located in the mitochondrial inner membrane. We have reported on four mitochondrial inner membrane proteins, extracted from beef heart, which reacted with antimitochondrial antibodies of primary biliary cirrhosis. These four proteins had molecular weights of 70, 54, 51 and 45 kd. Forty-six of the 50 PBC sera tested were positive with rat kidney and stomach specimens by the indirect immunofluorescent method. All sera of 50 primary biliary cirrhosis patients were positive with at least one and as many as four of the mitochondrial proteins extracted from beef heart using immunoblotting. Forty-seven primary biliary cirrhosis sera (94%) had IgG antibodies (antimitochondrial antibodies) to the antigen proteins, 43 patients (86%) IgM antimitochondrial antibodies and 38 patients (76%) IgA antimitochondrial antibodies. Seventy per cent of patients had antimitochondrial antibodies in all three immunoglobulin classes. In a few primary biliary cirrhosis sera, antimitochondrial antibodies were represented by only one class of immunoglobulin. The major antigenic proteins of mitochondrial inner membrane to which the antimitochondrial antibodies react were the 70 and 51 kd proteins. All primary biliary cirrhosis sera containing antibodies to the 54 and/or 45 kd proteins reacted with 70 kd as well. Patients with an elevation of serum bilirubin over 2 mg per dl were often found to produce antimitochondrial antibodies reactive with the 54 kd in addition to the 70 kd protein. No significant association was found between histological classifications and reactive patterns of antimitochondrial antibodies.     

Cytochalasins and colchicine increase the lateral mobility of human chorionic gonadotropin-occupied luteinizing hormone receptors on ovine luteal cells

To determine whether cytoskeletal proteins restrict the mobility of LH-receptor complexes occupied by hCG, we measured the rate of lateral diffusion and the fraction of mobile receptor-hormone complexes by fluorescence photobleaching recovery on luteal cells treated with microtubule and microfilament disruptors and on portions of the plasma membrane separated from the underlying cytoskeleton (blebs). Enzymatically dispersed ovine luteal cells obtained on day 11 from superovulated ewes were pretreated for 1 h at 37 C with cytochalasin B (20 micrograms/ml), cytochalasin D (20 micrograms/ml), or colchicine (40 micrograms/ml). These drugs had no effect on the lateral diffusion of cell membrane glycoproteins labeled with tetramethylrhodamine isothiocyanate-derivatized succinyl Concanavalin-A. However, drug treatment caused a significant increase in the diffusion coefficient and mobile fraction of hCG-occupied LH receptors compared to values obtained on untreated cells. hCG-occupied LH receptors on untreated cells exhibited a mobile fraction of 10.3%, and these mobile complexes had a diffusion coefficient of 3.3 X 10(-11) cm2 sec-1.hCG-occupied LH receptors on cytochalasin B-treated cells had a diffusion coefficient of 9.0 X 10(-11) cm2 sec-1, with 26% fluorescence recovery. Cytochalasin D and colchicine caused significantly greater increases in hCG mobility to 22.0 and 22.5 X 10(-11) cm2 sec-1, respectively, although the mobile fraction remained at about 25-30%. That binding of hCG to the LH receptor restricts lateral mobility through interactions of the hormone-occupied receptor complex with the cytoskeleton is further indicated by results obtained on membrane blebs. The fraction of mobile hCG-occupied LH receptors on blebs was 52.3%, and complexes had a diffusion coefficient of 1.7 X 10(-10) cm2 sec-1. The hormone-induced restriction of LH receptor lateral diffusion had no effect on the lateral mobility of tetramethylrhodamine isothiocyanate-epidermal growth factor-labeled receptors.     

Labeling of complex III, with [35S]diazobenzenesulfonate: orientation of this electron transfer segment in the mitochondrial inner membrane.

[34S]Diazobenzenesulfonate has been used to tag the surface-exposed polypeptides of isolated complex III. All nine different component polypeptides were labeled, indicating that each is at least partially exposed on the surface of the isolated, detergent-dispersed complex. Labeling studies were also conducted on the membrane-bound complex. Preparations of intact mitochondria and submitochondrial particles were separately labeled with [35S]diazobenzenesulfonate in order to determine the distribution of the polypeptides of complex III between the outer (cytoplasmic) and inner (matrix) surfaces of the mitochondrial inner membrane, respectively. Polypeptides II and III were the only components labeled in a significant amount in submitochondrial particles (i.e., from the matrix side). Polypeptides III, IV, and VI were heavily labeled in mitochondria (i.e., from the cytoplasmic side). Polypeptides I,II, V, and VII were also labeled in mitochondria but to a much lesser extent. Polypeptides VIII and IX were not significantly labeled from either side of the membrane. The labeling data and information obtained from previous crosslinking studies [Smith, R.J. & Capaldi, R.A. (1977) Biochemistry 16, 2629-2633] are used to derive a picture of the arrangement of complex III in the mitochondrial inner membrane.     

Dynamic interaction between Isp45 and mitochondrial hsp70 in the protein import system of the yeast mitochondrial inner membrane.

The protein import system of the yeast mitochondrial inner membrane includes at least three membrane proteins that presumably form a transmembrane channel as well as several chaperone proteins that mediate the import and refolding of precursor proteins. We show that one of the membrane proteins, Isp45, spans the mitochondrial inner membrane yet is extracted from this membrane at high pH. Solubilization of mitochondria with a nonionic detergent releases Isp45 as a complex with the chaperones mitochondrial hsp70 (mhsp70) and GrpEp. Both chaperones reversibly dissociate from Isp45 upon addition of ATP or adenosine 5'-[gamma-thio]triphosphate, suggesting that dissociation requires the binding of ATP. Control experiments indicate that the interaction between mhsp70 and Isp45 occurs in the intact mitochondria. We propose that Isp45 lines the inside of a proteinaceous channel across the inner membrane and that it is the membrane anchor for an ATP-driven "import motor" composed of mhsp70 and GrpEp. This arrangement is reminiscent of the protein transport systems of the yeast endoplasmic reticulum and the bacterial plasma membrane.     

Brief occurrence of a population of presynaptic intramembrane particles coincides with transmission of a nerve impulse.

Small pieces of Torpedo electric organ were cryofixed at 1-ms time intervals in a liquid medium at -190 degrees C before, during, and after the passage of a single nerve impulse. In contrast to studies using this or other preparations, these experiments were done without 4-aminopyridine or other drugs that potentiate transmitter release. Freeze-fracture replicas were made from the most superficial layers of the tissue, where the rate of cooling was rapid enough to retain ultrastructure in the absence of chemical fixation. We found that the transmission of an impulse was accompanied by the momentary appearance of a population of large intramembrane particles in both the protoplasmic (P) and the external (E) leaflets of the presynaptic plasma membrane. The change was very brief, appearing soon after the stimulus artifact. It lasted for 2-3 ms. Large pits denoting vesicle openings at the presynaptic membrane were found in a small proportion of nerve terminals; their number did not increase during transmission of the nerve impulse. Reducing the temperature from 16 to 5 degrees C slowed the time course of both the electrophysiological response and the change in intramembrane particles. The number of large particles did not increase when stimulation was applied in a low-Ca medium, a condition where the nerve terminals were still depolarized by the action potential but did not release the neurotransmitter. From these and other observations, we conclude that this transient change of intramembrane particles is closely linked to the mechanism of acetylcholine release at the nerve-electroplaque junction.     

Direct visualization of the interrelationship between intramembrane and extracellular structures.

The apical surface of the toad urinary bladder is covered by an interconnected mesh of glycocalyx, which appears to attach to the plasma membrane bilayer. To evaluate the interrelationship between these extracellular elements and intramembrane structures, a strategy was devised to produce composite replicas that allow the simultaneous visualization of intramembrane particles by freeze-fracture while the glycocalyx mesh is replicated by rotary shadowing of the extracellular surface after freeze-drying. Evaluation of these composite replicas by electron microscopy reveals that contacts occur between extracellular filamentous elements and intramembrane particles. This structural organization may be important for stabilizing intramembrane components and for anchoring extracellular elements to the membrane.     

Identification of a 45-kDa protein at the protein import site of the yeast mitochondrial inner membrane.

Import of proteins into mitochondria involves the cooperation of protein translocation systems in the outer and inner membranes. We have identified a 45-kDa protein at the protein import site of the yeast mitochondrial inner membrane. This 45-kDa protein could be crosslinked to a partly translocated precursor, which cannot be imported across the inner membrane when the matrix is depleted of ATP. In addition, an antibody against this protein strongly inhibited protein import into right-side-out inner-membrane vesicles. The 45-kDa protein accounts for only 0.1% of mitochondrial protein and appears peripherally attached to the outer face of the inner membrane. The properties of this protein suggest that it is a component of the protein import system of the mitochondrial inner membrane.     

Localization to the inner surface of the cytoplasmic membrane by immunoelectron microscopy of enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system of Escherichia coli.

The phosphoenolpyruvate:sugar phosphotransferase system of Escherichia coli constitutes a major pathway for sugar translocation. It is composed of integral membrane proteins (enzyme II components) that recognize specific extracellular sugars as well as phosphocarrier proteins, one of which is called enzyme I. While enzyme I plays a role in energizing the enzyme II for sugar transfer, its precise cellular distribution had not previously been defined. This study was designed to elucidate the cellular location of this protein by immunoelectron microscopy. Enzyme I antibody bound to E. coli cryosections was visualized with protein A-gold. The gold particles in sections of wild-type E. coli were found primarily associated with the surface of the inner membrane. A strain of E. coli harboring a plasmid encoding the gene for enzyme I was also tested for its distribution of enzyme I. Consistent with the biochemically established overproduction of enzyme I, this strain showed an approximately 80-fold higher density of gold particles per unit cell volume than the wild-type cells. The substantial overproduction of immunoreactive enzyme I was associated with a significant (approximately 20-fold) increase in the amount of that protein bound to the inner membrane. In addition, a substantial fraction of the total enzyme I accumulated within a 60-nm-wide zone in the vicinity of the inner membrane. A model to explain the zonal distribution of enzyme I under conditions of overexpression of the protein is presented.     

Lateral mobility of cytochrome c on intact mitochondrial membranes as determined by fluorescence redistribution after photobleaching.

Lateral mobility of an active fluorescent derivative of cytochrome c on the membranes of giant mitochondria was measured by fluorescence redistribution after photobleaching. A diffusion coefficient of 1.6 X 10(-10) cm2/sec was determined for the labeled cytochrome c on inner mitochondrial membranes under conditions where succinate oxidase activity was demonstrated. This relatively low rate of diffusion, together with results of other investigators, is explained in terms of a model involving a dynamic equilibrium between freely diffusing and associated forms of electron-transfer components.     

Capillary electrophoresis reveals changes in individual mitochondrial particles associated with skeletal muscle fiber type and age

Capillary electrophoresis (CE) with postcolumn laser-induced fluorescence detection (LIF) was used to analyze single skeletal muscle fibers from young and old rats. Due to selective labeling of mitochondria with 10-N-nonyl acridine orange, the zeptomole (10(-21) mole) sensitivity, and the high separation power, three properties of individual mitochondrial particles were revealed: the number, the distributions of cardiolipin, and their electrophoretic mobilities. Type I fibers had more mitochondrial particles and cardiolipin per particle than did type IIb fibers from rats of similar age. Individual fibers of the same fiber type from young rats contained more mitochondrial particles and cardiolipin per particle than did fibers from old rats. There were fiber type-specific and age-specific differences in the electrophoretic mobility of individual mitochondrial particles. The CE-LIF results of individual mitochondrial particles are the first of their kind in that they reveal fiber type-specific and age-specific differences that are not obviously noticed in bulk measurements of heterogeneous tissues.     

COMPARISON OF RAT LIVER MITOCHONDRIAL AND MICROSOMAL MEMBRANE PROTEINS

An improved method is described for dissolving membrane proteins and for resolving them by polyacrylamide gel electrophoresis. With this procedure, the inner mitochondrial membrane has been found to contain 23 different protein species and the outer membrane 12. Only one protein species appears to be common to the two membranes. Smooth and rough microsomal membranes contain 15 different proteins. The approximate molecular weight and relative amount of each protein species have been extrapolated from the gel patterns. The outer mitochondrial membrane and the smooth microsomal membrane contain at least three protein species that appear to be identical, suggesting that they possess a common origin.