Animal-vegetal polarity in the plasma membrane of a molluscan egg: a quantitative freeze-fracture study

Using freeze-fracture electron microscopy, the numerical particle distribution in the fertilized Nassarius egg plasma membrane has been analyzed in four areas at different positions along the animal-vegetal axis of the egg. These areas can be distinguished by distinct microvilli patterns and differences in microvilli densities. In all areas, more IMPs (intramembrane particles) are present on the P face than on the corresponding E face. The ratio of the number of IMPs present on E and P face is similar in all areas (0.48-0.55) except for the most animal part of the vegetal hemisphere, where relatively more IMPs remain attached to the exterior half of the fractured membrane (E/P ratio = 0.88). The IMP density at the vegetal pole of the egg is considerably higher than in the animal hemisphere and in the animal part of the vegetal hemisphere. This difference is due to an increased number of IMPs in all size classes (4-18 nm). In the area adjacent to the vegetal pole the density of particles is also higher than in the two more animal areas, but here the difference is exclusively due to the smaller IMP size classes (4-8 nm). Statistical analysis of our data reveals that the area adjacent to the vegetal pole patch is significantly different from the other areas with respect to the distribution of the IMPs over the different IMP size classes. These results demonstrate the polar organization of the Nassarius egg plasma membrane. The possible role of this surface heterogeneity in the spatial organization of the egg cell and the later embryo is discussed.     

The plasma-membrance IMP pattern as related to animal/vegetal polarity in the amphibian egg

Freeze-fracture electron microscopy of the plasma membrane of the fertilized, uncleaved Xenopus egg shows that intramembranous particles (IMPs) range in size from ca. 50 to 200 Å and that more IMPs are attached to the E-face than to the P-face. The overall IMP densities of the animal and the vegetal hemisphere do not differ significantly. IMP-free regions (?, ca. 0.1 μm) on the tips of surface protrusions were irregularly distributed in the animal and the vegetal half (E-face) occupying ca. 8.5 and 2%, respectively of the free area. The relative densities for 16 different IMP sizes have been compared, on the basis of seven animal and seven vegetal halves, counting (E-faces only) ca. 10,000 IMPs in each hemisphere. For IMP sizes of ≤81 Å, a significant difference (P < 0.0005) was found, more small IMPs being present in the animal half. Some evidence for IMP-associated thin elements was found. These findings are discussed in relation to plasma membrane anisotropy and the morphogenetic role of the egg cortex.     

Freeze-fracture study of plasma membranes in wild type and daunorubicin-resistant Ehrlich ascites tumor and P388 leukemia cells

The plasma membrane is considered to play a major role in the development and maintenance of the multidrug resistance (MDR) phenotype, a role which may in part be mediated by an inducible 170 kD transmembrane protein (P-170). The present freeze-fracture study of plasma membranes of daunorubicin-resistant Ehrlich ascites and P388 leukemia cells demonstrated a significant increase in the density of intramembrane particles (IMP) in the P-face, but not the E-face, of resistant sublines compared with wild type cells. Furthermore, a three-dimensional histogram plot of the diameters of P-face IMPs in Ehrlich ascites tumor cells showed the emergence of a subpopulation of 9 X 11 nm IMPs not found in wild type cells. The size of these IMPs would be consistent with a MW of approximately 340 kD, thus indicating that P-170, shown to be present in both resistant cell lines by Western blot analysis and immunohistochemical staining, exists as a dimer in the plasma membrane. Incubation with the calcium channel blocker verapamil, in concentrations known to inhibit daunorubicin efflux in resistant cells, showed evidence of membrane disturbance in the form of IMP clustering in both wild type and resistant Ehrlich ascites tumor cells. However, incubation with daunorubicin itself did not alter the freeze-fracture morphology of the plasma membranes.     

The ultrastructural effects of β-amyloid peptide on cultured PC12 cells: changes in cytoplasmic and intramembranous features.

Summary The fine structural features of cultured PC12 cells were investigated after treatment for 1, 3, or 5 days with different concentrations of the vascular form of β- 1–40 (β-AP). PC12 cells treated with β-AP showed time- and concentration-dependent lysosomal system activation and cell toxicity. We observed increases in the number and size of cytoplasmic lysosomes as indicated by increased acid phosphatase reactivity. Some lysosomes were in the form of multivesicular bodies or large residual bodies that appeared to arise by autophagia or by endocytotic uptake. Double-sided plasma membrane invaginations were observed to give rise to increasingly extensive intracytoplasmic vacuolization that was correlated with duration of β-AP treatment. Freeze-fracture studies of the intramembranous particle (IMP) population in the plasma membrane P-face showed that both control and β-AP treated cells had two major P-face IMP populations, small-diameter (4–8 nm) IMPs, and large-diameter (≤ 9nm) IMPs. The larger category of IMPs was found to possess a greater average diameter in the β-AP treated cells than in the control cells. These IMPs could represent modifications to existing transmembranous receptors, channels, or transducing molecules by the β-AP. These results demonstrate that β-AP can induce time- and concentration-dependent ultrastructural changes in PC12 cell membranes.     

Freeze-fracture study of plasma membranes in wild type and daunorubicin-resistant Ehrlich ascites tumor and P388 leukemia cells

The plasma membrane is considered to play a major role in the development and maintenance of the multidrug resistance (MDR) phenotype, a role which may in part be mediated by an inducible 170 kD transmembrane protein (P-170). The present freeze-fracture study of plasma membranes of daunorubicin-resistant Ehrlich ascites and P388 leukemia cells demonstrated a significant increase in the density of intramembrane particles (IMP) in the P-face, but not the E-face, of resistant sublines compared with wild type cells. Furthermore, a three-dimensional histogram plot of the diameters of P-face IMPs in Ehrlich ascites tumor cells showed the emergence of a subpopulation of 9 × 11 nm IMPs not found in wild type cells. The size of these IMPs would be consistent with a MW of approximately 340 kD, thus indicating that P-170, shown to be present in both resistant cell lines by Western blot analysis and immunohistochemical staining, exists as a dimer in the plasma membrane. Incubation with the calcium channel blocker verapamil, in concentrations known to inhibit daunorubicin efflux in resistant cells, showed evidence of membrane disturbance in the form of IMP clustering in both wild type and resistant Ehrlich ascites tumor cells. However, incubation with daunorubicin itself did not alter the freeze-fracture morphology of the plasma membranes.     

Membrane particle distribution in the sternal epithelia of the terrestrial isopod Porcellio scaber latr. (Crustacea, oniscidea) during CaCO(3) deposit formation and resorption, a freeze-etch analysis.

The anterior sternal epithelium of terrestrial isopods transports cuticular Ca(2+) to and from large sternal CaCO(3) deposits. We analyzed the anterior and posterior sternal epithelium by the means of the freeze-etch technique and measured the size distribution and density of intramembrane particles (IMPs) during three different molting stages. At least three IMP size classes around 4.5, 7.7, and 9.4 nm can be distinguished on the P-face of the apical and basolateral plasma membrane. An additional size class of around 12.8 nm is restricted to the apical compartment. In the anterior sternal epithelium, the density of these large particles changes by a factor of 1.9 during the molt cycle, suggesting a role in CaCO(3) formation and/or resorption. The density of the smaller IMPs rises transiently by a factor of 1.3 in the posterior sternal epithelium only. The IMP density of the basolateral plasma membrane increases significantly by a factor of 1.4 and 1.3 in the anterior and posterior sternal epithelia, respectively. The results indicate that increases in the IMP density contribute to the differentiation to an increased transport activity during the cyclic enlargements of the plasma membrane surface area in the anterior sternal epithelium.     

Membrane Particle Distribution in the Sternal Epithelia of the Terrestrial Isopod Porcellio scaber Latr. (Crustacea, Oniscidea) during CaCO3 Deposit Formation and Resorption, a Freeze-Etch Analysis

The anterior sternal epithelium of terrestrial isopods transports cuticular Ca²⁺ to and from large sternal CaCO₃ deposits. We analyzed the anterior and posterior sternal epithelium by the means of the freeze-etch technique and measured the size distribution and density of intramembrane particles (IMPs) during three different molting stages. At least three IMP size classes around 4.5, 7.7, and 9.4 nm can be distinguished on the P-face of the apical and basolateral plasma membrane. An additional size class of around 12.8 nm is restricted to the apical compartment. In the anterior sternal epithelium, the density of these large particles changes by a factor of 1.9 during the molt cycle, suggesting a role in CaCO₃ formation and/or resorption. The density of the smaller IMPs rises transiently by a factor of 1.3 in the posterior sternal epithelium only. The IMP density of the basolateral plasma membrane increases significantly by a factor of 1.4 and 1.3 in the anterior and posterior sternal epithelia, respectively. The results indicate that increases in the IMP density contribute to the differentiation to an increased transport activity during the cyclic enlargements of the plasma membrane surface area in the anterior sternal epithelium.     

Distribution of intramembranous particles and filipin-sterol complexes in mouse sperm membranes: polyene antibiotic filipin treatment

The distribution of intramembranous particles (IMPs) and membrane filipin-sterol complexes (FSC) was examined ultrastructurally in mouse spermatozoa from the male reproductive tract and ejaculates. IMPs were qualitatively analyzed on freeze-fracture replicas of glutaraldehyde-fixed tissue, while membrane FSC were quantitatively analyzed on replicas of filipin-treated cells. The distribution pattern of IMPs of mouse spermatozoa was fundamentally similar to that of other mammalian spermatozoa. 1) In the head, the plasma membrane had a heterogeneous population density, e.g., few IMPs on the acrosomal region, particularly few on the marginal segment, and somewhat regularly arranged IMPs on the postacrosomal region. The acrosomal membrane had many IMPs in hexagonal arrays. The nuclear membrane had many IMPs on the P-face, few IMPs on the variegated E-face, and an intense population density on the P-face of the basal plate. 2) In the neck, the plasma membrane had many IMPs with square arrangements of small IMPs in some areas on the P-face; the redundant nuclear membrane had a few IMPs on both P- and E-faces. 3) In the tail, the plasma membrane had diagonal rows of IMPs in some areas amongst larger IMPs on the middle piece, while it had "zippers" composed of IMPs running parallel to the axis on the principal piece. The distribution of sperm membrane FSC may be summarized as follows: 1) In the head, the acrosomal plasma membrane, which was heavily labeled with filipin, had much more FSC in the equatorial segment than in the marginal segment throughout the study. The postacrosomal plasma membrane generally had no FSC, but some sperm in ejaculates were slightly positive to filipin. The acrosomal membranes (both outer and inner) had no FSC. The nuclear membrane in the main part of the head had less FSC in vas deferens and ejaculated sperm than in the epididymal sperm. The nuclear membrane on the basal plate had no FSC. 2) In the neck, the plasma membrane had little FSC. The redundant nuclear envelope had scattered FSC with a higher incidence in the epididymal sperm than in those from the vas deferens and ejaculates. The membrane scroll, which was elongated from the extreme caudal end of the redundant nuclear envelope, had abundant FSC in the vas deferens and ejaculated sperm. 3) The tail plasma membrane (both middle and principal piece), which was weakly labeled with filipin, had less FSC in sperm from the vas deferens and ejaculates than in those from the epididymis. The limiting membrane covering the mitochondria had no FSC.     

A freeze-fracture study of perinatal changes of intramembranous particles in microvilli of absorptive cells in mouse small intestine

Summary Perinatal changes in the appearance of intramembranous particles (IMPs) of microvilli of enterocytes were analyzed quantitatively. In both the jejunum and the ileum, the IMP density on the P-face showed no significant changes from day 17 of gestation to day 5 of postnatal life. It increased between day 5 and day 12, reached a maximum at day 21, and thereafter decreased slightly. The IMP density on the E-face remained almost constant during the perinatal period in both intestinal parts. Measurements of particle diameters proved that neither the P-face nor the E-face membrane showed significant differences in either mean value or size distribution among different age groups.This study has revealed that the perinatal change in the IMP density on the P-face of microvilli correlates well with changes in the activity of certain enzymes found in the membranes of microvilli, e.g. disaccharidase and aminopeptidase.This study was supported by a Grant-in-Aid for Scientific Research to T. Yamamoto from the Ministry of Education, Science and Culture of Japan     

Molecular structure of the axolemma of developing axons following altered gliogenesis in rat optic nerve

Axonal and axolemmal development of fibers from rat optic nerves in which gliogenesis was severely delayed by systemic injection of 5-azacytidine (5-AZ) was examined by freeze-fracture electron microscopy. In neonatal (0-2 days) rat optic nerves, all fibers lack myelin, whereas in the adult, virtually all axons are myelinated. The axolemma of neonatal premyelinated fibers is relatively undifferentiated. The P-fracture face (P-face) displays a moderate (approximately 550/micron 2) density of intramembranous particles (IMPs), whereas the E-fracture face (E-face) has few IMPs (approximately 125/micron 2) present. By 14 days of age, approximately 25% of the axons within control optic nerves are ensheathed or myelinated, with the remaining axons premyelinated. The ensheathed and myelinated fibers display increased axonal diameter compared to premyelinated axons, and these larger caliber fibers exhibit marked axonal membrane differentiation. Notably, the P-face IMP density of ensheathed and myelinated fibers is substantially increased compared to premyelinated axolemma, and, at nodes of Ranvier, the density of E-face particles is moderately high (approximately 1300/micron 2), in comparison to internodal or premyelinated E-face axolemma. In optic nerves from 14-day-old 5-AZ-treated rats, few oligodendrocytes are present, and the percentage of myelinated fibers is markedly reduced. Despite delayed gliogenesis, some unensheathed axons within 5-AZ-treated optic nerves display an increased axonal diameter compared to premyelinated fibers. Most of these large caliber fibers also exhibit a substantial increase in P-face IMP density. Small (less than 0.4 micron) diameter unensheathed axons within treated optic nerves maintain a P-face IMP density similar to that of control premyelinated fibers. Regions of increased E-face particle density were not observed. The results demonstrate that some aspects of axolemma differentiation continue despite delayed gliogenesis and the absence of glial ensheathment, and suggest that axolemmal ultrastructure is, at least in part, independent of glial cell association.     

Detection of plasma membrane cholesterol by filipin during microvillogenesis and ciliogenesis in quail oviduct

Using filipin as a probe for the presence of membrane cholesterol, the evolution of cholesterol distribution in the apical plasma membrane was studied during estrogen-induced ciliogenesis in quail oviduct and compared with the distribution of intramembrane particles (IMPs). Ciliary growth is preceded by the first step of microvillus differentiation. Microvilli emerge in membrane domains rich in IMPs and devoid of filipin-cholesterol (f-c) complexes. However growing microvillus membrane shows f-c complexes. During ciliary growth, microvilli lengthen from 0.5 to 2 microns, indicating that the microvillar membrane is not a membrane reservoir for ciliogenesis. During ciliary growth, the characteristic ciliary necklace IMP rows appear progressively at the base of cilia. The first IMP row is organized in a membrane circlet lacking of f-c complexes, whereas the new shaft membrane in the middle of the circlet exhibits numerous complexes. These two different domains of the cilia keep their specificity during ciliary growth. Only the ciliary tip shows fewer complexes than the shaft membrane. The apical membrane of differentiated ciliated cells is thus composed of various domains, the ciliary shaft full of f-c complexes and poor in IMPs, the ciliary necklace is devoid of f-c complexes and rich in IMPs, the microvilli membrane is rich in both IMPs and f-c complexes, and the interciliary membrane is poor in both f-c complexes and IMPs, whereas the undifferentiated cells exhibit an apical membrane in which f-c complexes and IMPs are distributed homogeneously.     

Freeze-Fracture Analysis of Plasma Membranes of CHO Cells Stably Expressing Aquaporins 1-5

Several studies suggest that aquaporin water channels can be identified in membranes by freeze-fracture electron microscopy. For this report, Chinese Hamster ovary cells were stably transfected with cDNAs encoding aquaporins 1–5. Measurement of the osmotic water permeability of the cells confirmed that functional protein was expressed and delivered to the plasma membrane. By freeze-fracture electron microscopy, a 20% increase in intramembrane particle (IMP) density was found in plasma membranes of cells expressing AQP2, 3 and 5, and a 100% increase was measured in AQP1-expressing cells, when compared to mock-transfected cells. On membranes of cells expressing AQP4, large aggregates of IMPs were organized into orthogonal arrays, which occupied 10–20% of the membrane surface. IMP aggregates were never seen in AQP2-transfected cells. Hexagonally packed IMP clusters were detected in ∼5% of the membranes from AQP3-expressing cells. Particle size-distribution analysis of rotary shadowed IMPs showed a significant shift from 13.5 (control cells) to 8.5 nm or less in AQP-expressing cells; size distribution analysis of unidirectionally shadowed IMPs also showed a significant change when compared to control. Some IMPs in AQP expressing cells had features consistent with the idea that aquaporins are assembled as tetramers. The results demonstrate that in transfected CHO cells, AQP transfection modifies the general appearance and number of IMPs on the plasma membrane, and show that only AQP4 assembles into well-defined IMP arrays. Received: 17 March 1998/Revised: 19 June 1998     

Components of the plasma membrane of growing axons. II. Diffusion of membrane protein complexes

Intramembrane particles (IMPs) of the plasmalemma of mature, synapsing neurons are evenly distributed along the axon shaft. In contrast, IMPs of growing olfactory axons form density gradients: IMP density decreases with increasing distance from the perikarya, with a slope that depends upon IMP size (Small, R., and K. H. Pfenninger, 1984, J. Cell Biol., 98: 1422-1433). These IMP density gradients resemble Gaussian tails, but they are much more accurately described by the equations formulated for diffusion in a system with a moving boundary (a Stefan Problem), using constants that are dependent upon IMP size. The resulting model predicts a shallow, nearly linear IMP density profile at early stages of growth. Later, this profile becomes gradually transformed into a steep nonlinear gradient as axon elongation proceeds. This prediction is borne out by the experimental evidence. The diffusion coefficients calculated from this model range from 0.5 to 1.8 X 10(-7) cm2/s for IMPs between 14.8 and 3.6 nm, respectively. These diffusion coefficients are linearly dependent upon the inverse IMP diameter in accordance with the Stokes-Einstein relationship. The measured viscosity is approximately 7 centipoise. Our findings indicate (a) that most IMPs in growing axons reach distal locations by lateral diffusion in the plasma membrane, (b) that IMPs-- or complexes of integral membrane proteins--can diffuse at considerably higher rates than previously reported for iso-concentration systems, and (c) that the laws of diffusion determined for macroscopic systems are applicable to the submicroscopic membrane system.     

Membrane particles and gap junctions in the retinas of two species of cephalopods,Octopus ocellatus and Sepiella japonica

To study correlation between membrane structure and photoreceptor function, we compared the size and density of intramembrane particles (IMPs) in various membrane compartments of freeze-fractured retinas in a cuttle-fish, Sepiella japonica, and an octopus, Octopus ocellatus. Distribution of gap junctions in the retinas was also examined. Similar results were obtained in the two species. P-faces of both rhabdomeric microvillar membrane and non-rhabdomeric plasma membrane of the apical process were characterized by a random distribution of dense IMPs (ca. 5500-6500/microns2), which showed a unimodal size distribution with a mean diameter of ca. 10 nm. Unlike other invertebrate ocelli, the plasma membrane of the cell body in both the outer and inner segments had significantly denser P-face particles (ca. 7500-8000/microns2) than the rhabdomeric microvillar membrane. The size distribution of IMPs in each part of the membrane was also unimodal, but with a mean diameter of ca. 8 nm. In tangential fractures, each lamella of the myeloid body showed a patchwork of P-faces with irregularly arranged, dense particles and E-faces with orderly patterened granulation. Density and size distribution of the P-face particles in the myeloid membrane resembled those in the rhabdomeric microvillar membrane. The plasma membranes of the supporting cell and the gial cell had relatively sparse P-face particles (ca. 1500-3000/microns2). In addition to the previously reported gap junctions, which connected visual cell inner segments with each other, directly or via collaterals, small gap junctions were found between the visual cell axons and presumed efferent nerve fibres in the plexiform layer. Large-sized gap junctions provided mutual connections for both supporting cells and glial cells. In conclusion, IMPs of 10 nm in mean diameter in the microvillar and non-microvillar parts of the apical process plasma membrane and in the myeloid membrane represent the molecules or their clusters of two photopigments in the cephalopod visual cell, rhodopsin and retinochrome, respectively, and electrical transmission plays a role in visual cell-efferent nerve interactions.     

Components of the plasma membrane of growing axons. I. Size and distribution of intramembrane particles

The plasmalemma of mature and growing olfactory axons of the bullfrog has been studied by freeze-fracture. Intramembrane particles (IMPs) of mature olfactory axons are found to be uniformly distributed along the shaft. However, during growth, a decreasing gradient of IMP density is evident along the somatofugal axis. The size histograms of axolemmal IMPs from different segments of growing nerve reveal regional differences in the particle composition. The distribution of each individual size class of particles along the growing nerve forms a decreasing gradient in the somatofugal direction; the slope of these gradients varies directly with particle diameter. These size-dependent density gradients are consistent with a process of lateral diffusion of membrane components that are inserted proximally into the plasma membrane. The membrane composition of the growth cone, however, appears to be independent of these diffusion gradients; it displays a mosaic pattern of discrete domains of high and low particle densities. The relative IMP profiles of these growth cone regions are similar to one another but contain higher densities of large IMPs than the neighboring axonal shaft. The shifting distributions of intramembrane particles that characterize the sprouting neuron give new insights into cellular processes that may underlie the establishment of the functional polarity of the neuron and into the dynamics of axolemmal maturation.     

Freeze-fracture cytochemistry of sympathetic ganglia. Distribution of filipin and tomatin induced membrane deformations in neurons and satellite cells

Application of filipin to sympathetic ganglia results in membrane deformations in both the neurons and the satellite cells. The plasma membranes of the principal ganglion cells show a non-homogeneous distribution of filipin induced deformations with fewer deformations in the perikaryal plasma membrane than in the nerve fiber membrane. The filipin induced membrane lesions are correlated to the number of IMPs of the neuronal membrane i.e. a high density of intramembrane particles (IMP) gives fewer deformations and vice versa. The membrane of the satellite cells contain a higher density of probe induced lesions than the neuronal membrane. The filipin induced deformations in the satellite cells are not correlated to the number of IMPs or to the number of orthogonal arrays of small particles (OAP). Specialized membrane areas such as the gap junction is always devoided of filipin induced lesions. A similar distribution of membrane lesions was found when tomatin was used instead of filipin. These results indicate a possible difference in lipid content between various parts of the neurons and between the neuronal and satellite cell plasma membrane in guinea pig sympathetic ganglia.     

Freeze-fracture analysis of phloem structure in plant tissue cultures. II. The sieve element plasma membrane

Sieve element plasma membranes reveal a unique distribution of intramembrane particles (IMPs) in tissue cultures fixed and cyroprotected prior to freeze-fracturing. Sieve element IMPs are smaller than those found in the plasma membranes of callus parenchyma cells from these same cultures. The PF/EF ratio of plasma membrane IMPs is 9.6 for parenchyma cells and 1.21 for sieve elements. The increased binding of IMPs to the sieve element E face may be related to the role of membrane proteins in the loading of sucrose and other molecules by these cells. The enlargement of the cell wall at the site of sieve area pores creates complementary ridges and depressions in the E and P fracture faces of sieve element plasma membranes. No alteration of IMP density is seen at the sieve area pore site.     

Membrane differentiations of an absorptive epithelium covering embryonic trophotaeniae in a goodeid teleost

Summary The trophotaenial absorptive cells (TACs) in goodeid embryos facilitate nutrient absorption during prolonged periods of intraovarian gestation. In a study of membrane differentiations associated with solute and ligand transfer in the trophotaeniae of Xenotoca eiseni, embryos were incubated in vivo with cationized ferritin (CF) prior to freeze-cleaving. This exposure to high concentrations of an adsorptive ligand was meant to induce swelling of the endosomal compartment. Macromolecular trafficking in TACs occurs via an apical endocytic complex consisting of plasma membrane invaginations, a large population of small vesicles, uniformly thick apical tubules, and endosomes. Freeze-fracture replicas showed that the microvillar plasma membrane P-face of TACs was studded with intramembrane particles (IMPs) at a fairly high density, whereas that of the cell surface proper contained a distinctly lower density and the tubulovesicular endocytic pits contained almost no IMPs. The majority of small vesicles and apical tubules in a near surface position displayed P-fracture faces with only a few odd IMPs, indicating that membrane, shuttling between the apical plasma membrane and intracellular sorting organelles, obviously does not carry along many large-sized integral membrane proteins. The distended endosomal compartment had many P-face-associated particles primarily clustered into patches. Specializations of the lateral plasma membrane included 4–8 tight junctional strands, relatively large complements of gap junction proteins, and numerous plaques of desmosomal membrane particles. A system of lamellar cisternae underlay the lateral cell surface that was in continuity with the intraepithelial space by numerous tubular canals, giving rise to an intracellular amplification of the basolateral plasma membrane. Their outward openings appeared as tiny pits on the cytoplasmic faces of freeze-cleaved cell membrane. The density of IMPs on the P-faces of the surface plasma membrane was apparently lower than that on its invaginated lamellar complex. Hence, it is concluded that the mobility of integral membrane proteins in the plane of the membrane may be hampered in movement across the surface pores.Supported by the Deutsche Forschungsgemeinschaft (Schi 268/1-1)     

Evidence for a vertical displacement of intramembranous particles on the plasma membrane of Tetrahymena cells by a local anesthetic

We examined the effect of a local anesthetic, dibucaine, on the plasma membrane of Tetrahymena pyriformis strain NT-1 using freeze-fracture electron microscopy. Intramembranous particles (IMPs) were distributed homogeneously on the plasma membrane of untreated cells. But, when Tetrahymena cells had been treated with 1.3 mM dibucaine for 5 min at growth temperature, freeze-fracture micrographs of the plasma membrane showed marked alterations. Although IMPs showed an almost homogeneous distribution, their density was elevated markedly on the protoplasmic fracture (PF) face but greatly reduce on the exoplasmic fracture (EF) face. Areas around deciliated portions had a reverse IMP density distribution for the PF and EF faces. These results suggest that dibucaine induced vertical displacement of the IMPs in the plasma membrane.     

Characterization of the consequences of YidC depletion on the inner membrane proteome of E. coli using 2D blue native/SDS-PAGE

In the bacterium Escherichia coli, the essential inner membrane protein (IMP) YidC assists in the biogenesis of IMPs and IMP complexes. Our current ideas about the function of YidC are based on targeted approaches using only a handful of model IMPs. Proteome-wide approaches are required to further our understanding of the significance of YidC and to find new YidC substrates. Here, using two-dimensional blue native/SDS-PAGE methodology that is suitable for comparative analysis, we have characterized the consequences of YidC depletion for the steady-state levels and oligomeric state of the constituents of the inner membrane proteome. Our analysis showed that (i) YidC depletion reduces the levels of a variety of complexes without changing their composition, (ii) the levels of IMPs containing only soluble domains smaller than 100 amino acids are likely to be reduced upon YidC depletion, whereas the levels of IMPs with at least one soluble domain larger than 100 amino acids do not, and (iii) the levels of a number of proteins with established or putative chaperone activity (HflC, HflK, PpiD, OppA, GroEL and DnaK) are strongly increased in the inner membrane fraction upon YidC depletion. In the absence of YidC, these proteins may assist the folding of sizeable soluble domains of IMPs, thereby supporting their folding and oligomeric assembly. In conclusion, our analysis identifies many new IMPs/IMP complexes that depend on YidC for their biogenesis, responses that accompany depletion of YidC and an IMP characteristic that is associated with YidC dependence.