Anion transport and membrane morphology.

Freeze-fracture electronmicroscopy has been used to examine the membrane ultrastructure of human red blood cells in the presence of inhibitors of chloride exchange. The extent of inhibition was correlated with a decrease of intramembrane particle density on the B-fracture face. Dimethylsulfoxide (DMSO) and glycerol, which markedly and reversibly reduced the intramembrane particle density, were shown to drastically and reversibly inhibit chloride self-exchange. DMSO was shown to be a noncompetitive inhibitor of chloride flux.     

Cation transport and membrane morphology

Summary Freeze-fracture electron-microscopy has been used to study membrane ultrastructure in (1) red cells from five species of mammals which have naturally occurring differences in cation transport and (2) red cells which have been treated with various drugs known to affect transport. A reproducible method for estimation of the intramembrane particle density is described. Considerable differences in the densities of intramembrane particles on the A-fracture faces were noted in five species of red cells studied. Such differences were not noted on the B-fracture faces. The differences correlated with species differences in active potassium transport and membrane phospholipid composition. Ouabain and trinitrocresolate-treated red cell membranes were found to have small but reproducible reductions in intra-membrane particle densities on the B-fracture faces, but such differences were not seen in valinomycin and amphotericin B-treated red cells. It was found that dimethylsulfoxide (DMSO) and glycerol drastically reduced intra-membrane particle densities. However, over the range of glycerol and DMSO concentrations in which membrane morphology was altered, no effects on either passive or active potassium transport were observed. It appears that the particles which are altered by DMSO and glycerol are not involved in cation transport.     

Differences in intramembrane particle distribution in young and old human erythrocytes

The distribution of intramembrane particles in human erythrocytes was studied by freeze-fracture on young and old cells and compared to that obtained after ATP depletion or following addition of a clustering agent. It was shown that intramembrane particles became aggregated and the mean particle density increased as the cells aged. Likewise, both particle aggregation and increased density were found in young cells after moderate ATP depletion. In contrast, mean particle density was markedly reduced in both cell types after exhaustive depletion. Paradoxically, Zn treatment led to decreased particle density in young cells, whilst producing the opposite effect in aged cells. The results suggest that their low ATP content may account for the increased particle density of senescent cells.     

Endocochlear potential generation is associated with intercellular communication in the stria vascularis: Structural analysis in the viable dominant spotting mouse mutant

Summary Deafness in the viable dominant spotting mouse mutant is due to a primary defect of the stria vascularis which results in absence of the positive endocochlear potential in scala media. Endocochlear potentials were measured and the structure of stria vascularis of mutants with potentials close to zero was compared with that in normal littermate controls by use of morphometric methods. The stria vascularis was significantly thinner in mutants. Marginal cells were not significantly differnet from controls in terms of volume density or intramembrane particle density but the network density of tight junctions was significantly reduced in the mutants. A virtual absence of gap junctions between basal cells and marginal or intermediate cells was observed, but intramembrane particle density and junctional complexes between adjacent basal cells were not different from controls. The volume density of basal cells was significantly greater in mutants. Intermediate cells accounted for a significantly smaller volume density of the stria vascularis in mutants and had a lower density of intramembrane particles than controls. Melanocytes were not identified in the stria vascularis of mutants. These results suggest that communication between marginal, intermediate and basal cells might be important to the normal function of the stria vascularis.     

Effect of hypnorm, chloralosane and pentobarbital on the ultrastructure of the inner membrane of rat heart mitochondria

Rat heart mitochondria were isolated from four groups of animals treated in a different way. The animals of the first group were killed after decapitation (D-group) without previous anaesthesia. The three other groups of animals were anaesthetised with different anaesthetics. The second group (N-group) was anaesthetised with nembutal (sodium pentobarbital), the third group with chloralosane (C-group) and the fourth group with hypnorm (H-group). From these three anaesthetics only nembutal is known to interact with mitochondria. After retrograde perfusion and excision of the heart, mitochondria were prepared from the ventricles by standard methods. After freeze-fracturing the mitochondrial suspension, the intramembrane particle dimension and density on both fracture faces of the inner mitochondrial membrane were measured. The intramembrane particle diameter on the P-face of the inner membrane of the N-group mitochondria was significantly different from D-, C- and H-group mitochondria. Also the density and diameter of the intramembrane particles on the mitochondrial inner membrane of D-group mitochondria compared to C- and H-group mitochondria were significantly different at the 95% level of confidence. Between C- and H-group mitochondria no differences of these parameters were observed. From these results it is clear that, depending on the pretreatment of the animals, a different substructure of the inner membrane of heart mitochondria is obtained.     

A quantitative study of intramembrane changes during cell junctional breakdown in the dystrophic rat retinal pigment epithelium

Previous electron microscope freeze-fracture and tracer studies have revealed that intercellular junctions in the retinal pigment epithelium (RPE) of Royal College of Surgeons (RCS) rats with inherited retinal dystrophy [5] break down between three and six postnatal weeks [6, 7]. In this study quantitative computer techniques were used to analyze the freeze-fracture changes in the dystrophic RPE. The following parameters were measured: length of tight junctional strands/micron2; number of tight junctional strand anastomoses/micron2; number of gap junctional aggregates/micron2; area of gap junctional aggregates/micron2; and density of background intramembrane particles/micron2. At three postnatal weeks, the dystrophic junctional complex membrane is similar to normal, but at 10 weeks and later there are dramatic decreases in tight junctional strand length/micron2 and number of anastomoses/micron2, as well as in the number/micron2 and area of gap junctions/micron2, while the density of background particles/micron2 is dramatically increased. Correlational analysis revealed that changes in gap and tight junctions were significantly related to each other and to the increase in background particle density. The diameter of background particles within the normal and post-breakdown dystrophic junctions was measured in order to see whether the dispersal of gap and tight junctional particles (8-10 nm) into the surrounding membrane contributes to the increased particle density. These measures showed that background particles in all size ranges were more numerous in the dystrophic RPE, but that the largest increase was in the smallest diameter particles (6-7 nm). Thus, while gap and tight junctional sized particles contribute to the increase, particles from other sources may also be involved. Particle density of apical and basal membranes in the normal and in the 10 week and older dystrophic RPE was analyzed to study the effects of tight junctional breakdown on the distribution of intramembrane particles. These measures showed that particle density was greater basally than apically in the normal RPE and that particle density in both membranes decreased slightly in the dystrophic RPE, but that their ratio remained unchanged. It has been shown previously that even a single intact tight junctional strand is sufficient to maintain differences in particle density between apical and basal surfaces [14, 15] and in the majority of abnormal dystrophic junctional complexes at least one tight junctional strand remains intact.(ABSTRACT TRUNCATED AT 400 WORDS)     

Freeze-fracture study of heart mitochondria in the condensed or orthodox state

Rat heart mitochondria were isolated and forced in a well-defined metabolic state. After freeze-fracturing, the intramembrane particle dimension and density on both fracture faces of the inner mitochondrial membrane were measured. No significant differences could be calculated between the diameter of the membrane particles in the five different states. However, the particle density on the fracture faces of the inner mitochondrial membrane in the condensed configuration is significantly smaller than in the orthodox configuration on the 99.5% level of confidence. These results are compared with the literature, where conflicting data have been published about these particle densities.     

Freeze-fracture study of heart mitochondria in the condensed or orthodox state

Rat heart mitochondria were isolated and forced in a well-defined metabolic state. After freeze-fracturing, the intramembrane particle dimension and density on both fracture faces of the inner mitochondrial membrane were measured. No significant differences could be calculated between the diameter of the membrane particles in the five different states. However, the particle density on the fracture faces of the inner mitochondrial membrane in the condensed configuration is significantly smaller than in the orthodox configuration on the 99.5% level of confidence. These results are compared with the literature, where conflicting data have been published about these particle densities.     

Chemical co-treatments and intramembrane particle patching in the poly(ethylene glycol)-induced fusion of turkey and human erythrocytes

Several chemical co-treatments were used to lower the threshold concentrations of poly(ethylene glycol) (PEG) required to induce fusion between turkey erythrocytes and between human erythrocytes. Concanavalin A was used in conjunction with 25% (w/w) PEG to induce turkey erythrocyte fusion. The fusion percentage increased with increasing concentrations of concanavalin A and the duration of concanavalin A treatment. In samples with high percentages of fusion, numerous hemispherical intramembrane particle-free zones (bubbles) in the plasma membrane were revealed by freeze-fracture electron microscopy. However, concanavalin A treatment did not facilitate fusion between human erythrocytes even at 35% PEG, although slight intramembrane particle patching was observed under this condition. Spermidine (0.05% w/v), trichloroacetic acid (100 mM) and ethanol (4% v/v) were found to promote fusion of human erythrocytes in 25% PEG. In all of these cases, intramembrane particle patching was observed by freeze-fracture electron microscopy in the presence of PEG. When applied alone, only ethanol caused a slight intramembrane particle patching. Neither dimethylsulfoxide (2% v/v), lysophosphatidylcholine (lysoPC, 0.15 mM), nor polylysine (mol. wt. 1000-4000, 0.05% w/v) promoted fusion of human erythrocyte in 25% PEG. None of these chemical treatments, alone, or in combination with PEG, caused intramembrane particle patching. We conclude that the positive effect of chemical treatments on PEG-induced cell fusion is closely related to the formation of intramembrane particle-free zones on the plasma membrane.     

Altered plasma membrane ultrastructure in multidrug-resistant cells

Multidrug resistance is mediated by P-glycoprotein, an integral plasma membrane component which is thought to function as a drug export pump. This model can explain drug resistance, but fails to account for the broader pleiotropy of the multidrug resistance phenotype. We report here a freeze-fracture study revealing increases in the densities of protoplasmic face intramembrane particles in multidrug-resistant Chinese hamster ovary (CHO) and human leukemic cells. The intramembrane particle density in a CHO cell revertant which had lost the characteristics of the multidrug resistance phenotype was indistinguishable from that of the drug-sensitive parental cell line. This demonstration of a global multidrug resistance-linked change in plasma membrane architecture may have significant implications for understanding the variety of concurrent membrane-related changes which are not easily explained by the current model for multidrug resistance.     

Morphology of proteoliposomes reconstituted with purified lac carrier protein from Escherichia coli

Proteoliposomes reconstituted with purified lac carrier protein from Escherichia coli were ultra-rapidly frozen and examined by freeze-fracture-etch electron microscopy. The proteoliposomes are greater than 95% unilamellar, and the majority are 30-150 nm in diameter. Fracture faces of proteoliposomes (at a protein:lipid molecular ratio of about 1:2500) display 7.0-nm diameter globular intramembrane particles uniformly distributed on convex and concave surfaces. Calculations of particle composition suggest that each intramembrane particle probably contains one or two molecules of the 46.5-kDa transmembranous lac carrier protein, depending on the correction factor for the thickness of the metal deposited to form the platinum/carbon replicas. Etched surfaces of the proteoliposomes are smooth. Incubation of the proteoliposomes with monoclonal antibody 4B1, which binds to an epitope in the lac carrier on the exterior of the proteoliposomes, dramatically alters the intramembrane particle distribution. After incubation with antibody, the convex (inner monolayer) fracture faces are nearly devoid of intramembrane particles, and an overall 4-fold reduction in the total number of intramembrane particles is observed.     

Calcium-dependent chloride current in rat cerebellar Purkinje cell membranes

The presence of calcium-dependent potential-activated chloride currents in the membranes of freshly isolated rat cerebellar Purkinje cells (12–15 days) was shown by the whole-cell patch clamp technique. Chloride currents appeared in a sodium-free external solution and reversibly disappeared in the absence of external chloride and calcium ions.     

Chikungunya Virus Vaccine Prepared by Tween-Ether Extraction

Chikungunya virus vaccines prepared by Tween 80 and ether inactivation of virus grown in green monkey kidney cell cultures were shown to be as immunogenic as comparable Formalin-inactivated vaccines. Both types of vaccine stimulated hemagglutination-inhibiting, complement-fixing, and neutralizing antibody and afforded protection to mice against a live virus challenge. It was shown after Tween-ether treatment of chikungunya virus that the infectivity of the virus was lost and the hemagglutinin titer was increased. By characterization of the resultant hemagglutinin by sucrose and cesium chloride density gradient centrifugation, it was found that the extracted particle was smaller in size and greater in density than the parent virus particle. Removal of lipid may account for the alterations in the physical characteristics of the infectious virus particle. Conditions for treatment of chikungunya virus with Tween and ether were found that preserved high titers of hemagglutinin as well as the immunogenicity of the virus preparations.     

Rearrangement of intramembrane particles as a possible mechanism for the release of acetylcholine

1. A chemiluminescent procedure for measuring acetylcholine (ACh) has recently been described. The procedure is based on the hydrolysis of ACh by acetylcholinesterase and on the oxidation of choline to betaine and H2O2 by choline oxidase. The H2O2 generated reacts with luminol in presence of peroxidase to produce a light emission. This method is sensitive in the pmol/ml range. 2. On isolated synaptosomes from electric organ, it is possible to obtain an estimate of the cytoplasmic ACh compartment by measuring the light emission after a single freezing and thawing cycle. The vesicular pool which resists several freezing and thawing cycles is then estimated by opening the compartment with a detergent. Increasing the intensity of stimulation of synaptosomes with different agents depletes the ACh content down to the vesicular pool. 3. The release of ACh is not associated with any change in the number of synaptic vesicles as seen in cryofractured synaptosomes. The only ultrastructural change detected common to all stimulations was a decreased density of P face intramembrane particles smaller than 11 nm and an increased density of E face 8 to 18 nm particles. The very significant particle changes were more intense for the conditions releasing more ACh. It is suggested that these particles are involved in the release of ACh from the cytoplasm. An attempt to directly correlate the release of ACh with intramembrane particle changes is discussed.     

Appearance and distribution of surface proteins of the human erythrocyte membrane. An electron microscope and immunochemical labeling study

We have used freeze-etching, before and after immunoferritin labeling, to visualize spectrin molecules and other surface proteins of the human erythrocyte membrane. After intramembrane particle aggregation was induced, spectrin molecules, identified by labeling with ferritin-conjugated antispectrin, were clustered on the cytoplasmic surface of the membrane in patches directly underlying the particle clusters. This labeling pattern confirms the involvement of spectrin in such particle aggregates, as previously inferred from indirect evidence. Ferritin-conjugated antihapten molecules, directed against external and cytoplasmic surface proteins of the erythrocyte membrane which had been covalently labeled nonspecifically with the hapten p-diazoniumphenyl-beta-D-lactoside, were similarly found in direct association with such intramembrane particle aggregates. This indicates that when spectrin and the intramembrane particles are aggregated, all the major proteins of the erythrocyte membrane are constrained to coaggregate with them. Although giving no direct information concerning the freedom of translational movement of proteins in the unperturbed erythrocyte membrane, these experiments suggest that a close dynamic association may exist between the integral and peripheral protein components of the membrane, such that immobilization of one component can restrict the lateral mobility of others.     

Spatial differentiation in photosynthetic and non-photosynthetic membranes of Rhodopseudomonas palustris.

The cytoplasmic membrane and the photosynthetic intracytoplasmic membranes of Rhodopseudomonas palustris are spatially differentiated into regions of extremely high intramembrane-particle density (4,400 to 9,800/micron 2) and areas of lower intramembrane-particle density (2,700 to 5,900/micron 2). The high intramembrane-particle-density areas were always seen in association with photosynthetic membrane stacks. This differentiation was also seen in those areas of the cytoplasmic membrane which adhere to the underlying intracytoplasmic membranes, implying that the cytoplasmic membrane too is differentiated for photosynthesis in these regions. Changes in intramembrane-particle size distribution in response to changes in light intensity during growth were measured. We found that, as light levels were decreased from 8,500 to 100 lx, the average particle diameter in the protoplasmic face of stacked intracytoplasmic and cytoplasmic membranes increased from 8.6 to 10.3 nm. We also observed a distinct periodicity in the sizes of the intramembrane particles found in the stacked regions--7.5, 10.0, 12.5, and 15.0 nm--with the larger-size peaks becoming more pronounced as light intensity decreased. This suggests that, as light levels decrease, subunits of discrete size are being added to a core particle. A comparison of propane jet-frozen cells versus fixed, glycerinated, and then frozen cells indicated that ultrarapid freezing leads to a higher quality of fine-structure preservation than does chemical fixation followed by glycerination and conventional freezing in Freon-12 or propane. The intramembrane particles appeared to be more regular in size, lacking the deformed or jagged appearance displayed in fixed preparations.     

Topographical relations of intramembrane particle distribution patterns in human sperm membranes

The distribution of intramembrane particles in human sperm membranes has been explored with particular reference to the topographical region of the sperm cell and the membranes' fracture face. Conspicuous differences in the size, arrangement, density, and lateral mobility of intramembrane particles between some topographically distinct membrane domains are demonstrated. The greatest regionality is exhibited by the plasma membrane. In sperm head regions, it shows a significant variability and changes its particle distribution during culture in capacitating medium. In contrast, little variability and no changes during the incubation are seen in the acrosomal and nuclear membranes. Striking is the difference in particle distribution on the E face of the outer acrosomal membrane between the acrosomal and equatorial regions. It is suggested that the invariable regional difference in the organization of the outer acrosomal membrane may bear on the different behavior of its two main domains during sperm capacitation and acrosome reaction.     

Regulation of the selective uptake of high density lipoprotein-associated cholesteryl esters by human fibroblasts and Hep G2 hepatoma cells

We have previously shown that the liver and steroidogenic tissues of rats in vivo and a wider range of cells in vitro, including human cells, selectively take up high density lipoprotein (HDL) cholesteryl esters without parallel uptake of HDL particles. This process is regulated in tissues of rats and in cultured rat cells according to their cholesterol status. In the present study, we examined regulation of HDL selective uptake in cultured human fibroblasts and Hep G2 hepatoma cells. The cholesterol content of these cells was modified by a 20-hr incubation with either low density lipoprotein (LDL) or free cholesterol. Uptake of HDL components was examined in a subsequent 4-6-hr assay using intracellularly trapped tracers: 125I-labeled N-methyl-tyramine-cellobiose-apoA-I (125I-NMTC-apoA-I) to trace apoA-I, and [3H]cholesteryl oleyl ether to trace cholesteryl esters. In the case of fibroblasts, pretreatment with either LDL or free cholesterol resulted in decreased selective uptake (total [3H]cholesteryl ether uptake minus that due to particle uptake as measured by 125I-NMTC-apoA-I). In contrast, HDL particle uptake increased with either form of cholesterol loading. The amount of HDL that was reversibly cell-associated (bound) was increased by prior exposure to free cholesterol, but was decreased by prior exposure to LDL. In the case of Hep G2 cells, exposure to free cholesterol only slightly increased HDL particle uptake; selective uptake decreased after both forms of cholesterol loading, and reversibly bound HDL increased after exposure to free cholesterol, but either did not change or decreased after exposure to LDL. It was excluded that either LDL carried over into the HDL uptake assay or that products secreted by the cultured cells influenced these results. Thus, selective uptake by cells of both hepatic and extrahepatic origin was down-regulated by cholesterol loading, under which conditions HDL particle uptake increased. Total HDL binding was not directly correlated with either the rate of selective uptake or the rate of HDL particle uptake or the cholesterol status of the cells, suggesting more than one type of HDL binding site.     

Membrane structure of nonactivated and activated human blood platelets as revealed by freeze-fracture: evidence for particle redistribution during platelet contraction

The distribution of intramembrane particles of nonactivated and activated human blood platelets was studied by freeze-fracture under various experimental conditions to see whether morphological evidence for a structural coupling between the platelet actomyosin system and the fibrin network in a retracting clot could be established. Membrane particles were evenly distributed in nonactivated platelets; the total number (E + P faces) was approximately 1,500/micrometers 2 of membrane, and there were two to three times more particles present on the E face than on the P face. Transformation of discoid platelets to "spiny spheres" by cooling did not change the particle distribution. Platelet activation and aggregation by serum or ADP caused no change in membrane particle density or distribution. Particle distribution was not changed in Ca2+-activated platelets fixed immediately before fibrin formation, but after fibrin formation and during clot retraction, particles were sometimes most frequent on the P face and tended to form distinct clusters, and aggregates of E face pits were observed. Blood platelets contain contractile proteins that are distinct as filaments in platelets in retracting clots. We suggest that the redistribution of particles seen in activated platelets during clot retraction reflects the esablishment of mechanical transmembrane links between the platelet actomyosin system and the fibrin net. The P-face particle clusters may represent sites of force transmission between actin filaments bonded to the inside of the membrane and the fibrin network at the outside. Thus, whereas membrane particles may not be directly involved in the attachment of actin filaments to membranes, the transmission of the force of the contractile system to an exterior substrate apparently involves the intramembrane particles.     

Ultrastructure of cell wall and thylakoid membranes of the thermophilic cyanobacterium Synechococcus lividus under the influence of temperature shifts

The ultrastructure of the cell wall and the thylakoid membranes of the thermophilic cyanobacterium Synechococcus lividus was studied by freezefracture electron microscopy after temperature shifts. Different fracture faces of the outer, the cytoplasmic and the thylakoid membranes were demonstrated when the preparation-temperature was in the range of the optimal growth temperature at 52°C or after fixation at 52°C. In the outer membrane of the cell wall two fracture faces with holes and 7.5 nm intramembrane particles were detected. On both the outer (EF) and inner (PF) leaflet of the cytoplasmic membrane randomly distributed particles were demonstrated. The particle density on the PF-face was approx. three times that of the EF-face. The EF-face of the thylakoid membrane exposed rows of particles with an average diameter of 10 nm. The spacing between the particle rows was 35–50 nm. This regular particle arrangement on the EF-face was demonstrated only in a few cases. Mostly the intramembrane particles were distributed randomly on the thylakoid fracture faces. The particle density of thylakoids with a random distribution was approx. in the same range both on the EF-and PF-face. The EF-particles fall into four groups of 9,10,11, and 12.5 nm. The main particle class was the 10 nm class. The PF-face exposed smaller particles with two maxima at 8.5–9 nm and 10 nm. When Synechococcus lividus OH-53s was chilled to temperatures below 30–35°C before the freeze-etch preparation a phase transition took place after the temperature shift. On the fracture faces of the thylakoid and cytoplasmic membranes particle depleted areas occurred. The size of the areas were different in both membranes and dependent on the velocity of cooling. Contrary to Synechococcus lividus OH-53s in the mesophilic Synechococcus strain 6910 the phase transition point was 15°C. The lower phase transition point may be due to a higher content of unsaturated fatty acids.Dedicated to Prof. D. Peters (Hamburg) on the occasion of the 65th anniversary of his birthday