Filipin as a cholesterol probe. II. Filipin-cholesterol interaction in red blood cell membranes

Filipin, a mixture of polyene antibiotics which form complexes with cholesterol, perturbs membrane lipid organization, and causes hemolysis of erythrocytes, is increasingly used as a cytochemical probe for the distribution of cholesterol in cell membranes. We used light (phase-contrast, dark-field and fluorescence) and electron microscopical techniques (whole-mount shadowing, negative staining, and freeze-fracture) to study the interaction of filipin with unfixed and glutaraldehyde-fixed human red blood cell (RBC) membranes. Lysis time and extent depended upon the cholesterol:filipin (C:F) ratio. Lysis was prevented by osmotic protection with high MW dextran. Filipin treated cells fluoresced, but variation in fluorescence intensity among unfixed as well as among fixed cells was evident both at low and high C:F ratios. Negatively stained preparations of unfixed cells lysed on grids or in suspension revealed ring- or C-shaped filipin-induced lesions (FIL) equipped with a veil-like appendage; single FIL, and FIL fused by their veils into aggregates, were shed from membranes. FIL at the surface proper of shadowed whole-mounts and of freeze-etched preparations of prefixed cells appeared as single, dispersed or aggregated cylinders protruding to variable heights above the membrane's plane; aggregated FIL were shed from cells. The freeze-fracture appearance of FIL differed in membranes fixed before or after filipin treatment. E- and P-faces of post-fixed membranes exhibited cylindrical protrusions and depressions, respectively; in essence, the reverse was found in pre-fixed RBC. Both pre- and post-fixed membranes showed considerable variation in the number of FIL on individual cells whether incubated at high (1:1) or low (1:5) C:F ratios, or for a short (10 min) or a long (80-180 min) time. Aggregation and shedding of FIL was evident in all preparations. Thin layer chromatography of the incubation fluid after sedimentation of cells showed that membrane cholesterol was shed from incubated cells. The presented data question the feasibility of filipin as a probe for the topographical distribution of cholesterol in cell membranes.     

Resistance of the stationary-phase plasma membrane of Candida albicans to filipin-induced deformation

Abstract Yeast cells of Candida albicans were treated with the polyene antibiotic filipin which specifically binds with sterol and induces morphological lesions in membranes. The plasma membrane in the exponential phase revealed numerous filipin-induced deformations. In contrast, most areas of the plasma membrane in the stationary phase resisted filipin-induced deformation, even though the cell wall did not prevent the entrance of filipin. These facts suggest that the organisation or physicochemical properties of the plasma membrane in the stationary phase is different from that in the exponential phase.     

The lens membrane skeleton contains structures preferentially enriched in spectrin-actin or tropomodulin-actin complexes

The spectrin-based membrane skeleton plays an important role in determining the distributions and densities of receptors, ion channels, and pumps, thus influencing cell shape and deformability, cell polarity, and adhesion. In the paradigmatic human erythrocyte, short tropomodulin-capped actin filaments are cross-linked by spectrin into a hexagonal network, yet the extent to which this type of actin filament organization is utilized in the membrane skeletons of nonerythroid cells is not known. Here, we show that associations of tropomodulin and spectrin with actin in bovine lens fiber cells are distinct from that of the erythrocyte and imply a very different molecular organization. Mechanical disruption of the lens fiber cell membrane skeleton releases tropomodulin and actin-containing oligomeric complexes that can be isolated by gel filtration column chromatography, sucrose gradient centrifugation and immunoadsorption. These tropomodulin-actin complexes do not contain spectrin. Instead, spectrin is associated with actin in different complexes that do not contain tropomodulin. Immunofluorescence staining of isolated fiber cells further demonstrates that tropomodulin does not precisely colocalize with spectrin along the lateral membranes of lens fiber cells. Taken together, our data suggest that tropomodulin-capped actin filaments and spectrin-cross-linked actin filaments are assembled in distinct structures in the lens fiber cell membrane skeleton, indicating that it is organized quite differently from that of the erythrocyte membrane skeleton.     

Cholesterol localization in the membranes of granular cells in the bladder epithelium of the frog during stimulated water transport

The polyene antibiotic filipin has been used to characterize the cholesterol distribution in the membranes of resting and ADH-stimulated frog urinary bladder in freeze-fracture replicas. In general, the intracellular membranes takes up filipin only insignificantly. An exception is the cholesterol rich granule membrane. Both density and polarity of filipin-induced deformations were evaluated, and the asymmetry in membrane cholesterol was analysed. Upon ADH-stimulation of water flow both density and polarity of filipin-induced deformations altered differently in apical and basolateral regions of the plasma membrane. This difference is presumably due to the stretching of the basolateral membrane as a result of swelling, on the one hand, and to incorporation of aggregate containing membranes into the apical membrane, on the other one. The results obtained may suggest that the appearance of ADH-induced intramembranous particle aggregates in the apical membrane be accompanied with a relative cholesterol decrease in this apical membrane.     

Increase in cholesterol in the apical plasma membrane of uterine epithelial cells during early pregnancy in the rat

Freeze-fracture cytochemistry with the cholesterol-binding antibiotic filipin has been used to examine the plasma membrane of uterine epithelial cells at different stages of pregnancy in the rat. We find many more filipin-induced lesions on day 6 of pregnancy than on day 1 and suggest that this indicates a higher cholesterol content at this time. Since day 6 of pregnancy is the time at which blastocysts implant in the rat uterus, we consider the possible significance of an increased cholesterol content for implantation.     

Spectrin properties and the elasticity of the red blood cell membrane skeleton

Two models of spectrin elasticity are developed and compared to experimental measurements of the red blood cell (RBC) membrane shear modulus through the use of an elastic finite element model of the RBC membrane skeleton. The two molecular models of spectrin are: (i) An entropic spring model of spectrin as a flexible chain. This is a model proposed by several previous authors. (ii) An elastic model of a helical coiled-coil which expands by increasing helical pitch. In previous papers, we have computed the relationship between the stiffness of a single spectrin molecule (K) and the shear modulus of a network (μ), and have shown that this behavior is strongly dependent upon network topology. For realistic network models of the RBC membrane skeleton, we equate μ to micropipette measurements of RBCs and predict K for spectrin that is consistent with the coiled-coil molecular model. The value of spectrin stiffness derived from the entropic molecular model would need to be at least 30 times greater to match the experimental results. Thus, the conclusion of this study is that a helical coiled-coil model for spectrin is more realistic than a purely entropic model.     

Interaction of the exported malaria protein Pf332 with the red blood cell membrane skeleton

Intra-erythrocytic Plasmodium falciparum malaria parasites synthesize and export numerous proteins into the red blood cell (RBC) cytosol, where some bind to the RBC membrane skeleton. These interactions are responsible for the altered antigenic, morphological and functional properties of parasite-infected red blood cells (IRBCs). Plasmodium falciparum protein 332 (Pf332) is a large parasite protein that associates with the membrane skeleton and who's function has recently been elucidated. Using recombinant fragments of Pf332 in in vitro interaction assays, we have localised the specific domain within Pf332 that binds to the RBC membrane skeleton to an 86 residue sequence proximal to the C-terminus of Pf332. We have shown that this region partakes in a specific and saturable interaction with actin (K_d = 0.60 µM) but has no detectable affinity for spectrin. The only exported malaria protein previously known to bind to actin is PfEMP3 but here we demonstrate that there is no competition for actin-binding between PfEMP3 and Pf332, suggesting that they bind to different target sequences in actin.     

Cholesterol distribution and structural differentiation in the sarcoplasmic reticulum of rat cardiac muscle cells

Summary The polyene compound, filipin, was used as a probe to localize cholesterol in the membranes of the rat cardiac muscle cell, with particular reference to the sarcoplasmic reticulum (SR). Filipin binds specifically to cholesterol (and related 3--hydroxysterols) in membranes, producing distinct deformations which can be viewed by freeze-fracture and used as markers for the presence of cholesterol-rich regions in the membrane plane. In freeze-fracture replicas of filipin-treated rat myocardium, the muscle cells revealed abundant deformations in their plasma membranes, no deformations in mitochondrial membranes, and an intermediate response in the SR. These results are in agreement with the levels of cholesterol reported in isolated fractions of the different membrane types, and confirm the specificity of filipin action. Within the SR, the filipin-induced deformations were not randomly distributed but occurred more commonly in free SR at or near the Z-region of the sarcomere than in other parts of the free SR or the junctional SR. This finding is interpreted as evidence for a non-homogeneous distribution of cholesterol in cardiac muscle cell SR. The possible significance of cholesterol in relation to structural differentiation and function of the SR is discussed.     

Interactions of Plasmodium falciparum erythrocyte membrane protein 3 with the red blood cell membrane skeleton

Plasmodium falciparum parasites express and traffick numerous proteins into the red blood cell (RBC), where some associate specifically with the membrane skeleton. Importantly, these interactions underlie the major alterations to the modified structural and functional properties of the parasite-infected RBC. P. falciparum Erythrocyte Membrane Protein 3 (PfEMP3) is one such parasite protein that is found in association with the membrane skeleton. Using recombinant PfEMP3 proteins in vitro, we have identified the region of PfEMP3 that binds to the RBC membrane skeleton, specifically to spectrin and actin. Kinetic studies revealed that residues 38-97 of PfEMP3 bound to purified spectrin with moderately high affinity (K(D(kin))=8.5 x 10(-8) M). Subsequent deletion mapping analysis further defined the binding domain to a 14-residue sequence (IFEIRLKRSLAQVL; K(D(kin))=3.8 x 10(-7) M). Interestingly, this same domain also bound to F-actin in a specific and saturable manner. These interactions are of physiological relevance as evidenced by the binding of this region to the membrane skeleton of inside-out RBCs and when introduced into resealed RBCs. Identification of a 14-residue region of PfEMP3 that binds to both spectrin and actin provides insight into the potential function of PfEMP3 in P. falciparum-infected RBCs.     

Influence of network topology on the elasticity of the red blood cell membrane skeleton.

A finite-element network model is used to investigate the influence of the topology of the red blood cell membrane skeleton on its macroscopic mechanical properties. Network topology is characterized by the number of spectrin oligomers per actin junction (phi a) and the number of spectrin dimers per self-association junction (phi s). If it is assumed that all associated spectrin is in tetrameric form, with six tetramers per actin junction (i.e., phi a = 6.0 and phi s = 2.0), then the topology of the skeleton may be modeled by a random Delaunay triangular network. Recent images of the RBC membrane skeleton suggest that the values for these topological parameters are in the range of 4.2 < phi a < 5.5 and 2.1 < phi s < 2.3. Model networks that simulate these realistic topologies exhibit values of the shear modulus that vary by more than an order of magnitude relative to triangular networks. This indicates that networks with relatively sparse nontriangular topologies may be needed to model the RBC membrane skeleton accurately. The model is also used to simulate skeletal alterations associated with hereditary spherocytosis and Southeast Asian ovalocytosis.     

Stress-free state of the red blood cell membrane and the deformation of its skeleton

The response of a red blood cell (RBC) to deformation depends on its membrane, a composite of a lipid bilayer and a skeleton, which is a closed, twodimensional network of spectrin tetramers as its bonds. The deformation of the skeleton and its lateral redistribution are studied in terms of the RBC resting state for a fixed geometry of the RBC, partially aspirated into a micropipette. The geometry of the RBC skeleton in its initial state is taken to be either two concentric circles, a references biconcave shape or a sphere. It is assumed that in its initial state the skeleton is distributed laterally in a homogeneous manner with its bonds either unstressed, presenting its stress-free state, or prestressed. The lateral distribution was calculated using a variational calculation. It was assumed that the spectrin tetramer bonds exhibit a linear elasticity. The results showed a significant effect of the initial skeleton geometry on its lateral distribution in the deformed state. The proposed model is used to analyze the measurements of skeleton extension ratios by the method of applying two modes of RBC micropipette aspiration.     

Composition and expression of spectrin-based membrane skeletons in non-erythroid cells

Cellular differentiation is often accompanied by the expression of specialized plasma membrane proteins which accumulate in discrete regions. The biogenesis of these specialized membrane domains involves the assembly and co-localisation of a spectrin-based membrane skeleton. While the constituents of the membrane skeleton in non-erythroid cells are often immunologically related to erythroid spectrin, ankyrin, and protein 4.1, there are structural and functional differences between the isoforms of these membrane skeleton polypeptides, as well as highly variable patterns of expression during cellular differentiation. We consider this heterogeneity of structure and expression during development in the context of the hypothesis that non-erythroid spectrin, ankyrin, and protein 4.1 are involved in the formation of specialized membrane domains.     

Native ultrastructure of the red cell cytoskeleton by cryo-electron tomography

Erythrocytes possess a spectrin-based cytoskeleton that provides elasticity and mechanical stability necessary to survive the shear forces within the microvasculature. The architecture of this membrane skeleton and the nature of its intermolecular contacts determine the mechanical properties of the skeleton and confer the characteristic biconcave shape of red cells. We have used cryo-electron tomography to evaluate the three-dimensional topology in intact, unexpanded membrane skeletons from mouse erythrocytes frozen in physiological buffer. The tomograms reveal a complex network of spectrin filaments converging at actin-based nodes and a gradual decrease in both the density and the thickness of the network from the center to the edge of the cell. The average contour length of spectrin filaments connecting junctional complexes is 46 ± 15 nm, indicating that the spectrin heterotetramer in the native membrane skeleton is a fraction of its fully extended length (∼190 nm). Higher-order oligomers of spectrin were prevalent, with hexamers and octamers seen between virtually every junctional complex in the network. Based on comparisons with expanded skeletons, we propose that the oligomeric state of spectrin is in a dynamic equilibrium that facilitates remodeling of the network as the cell changes shape in response to shear stress.     

Freeze-fracture studies of photoreceptor membranes: new observations bearing upon the distribution of cholesterol

We performed electron microscopy of replicas from freeze-fractured retinas exposed during or after fixation to the cholesterol-binding antibiotic, filipin. We observed characteristic filipin-induced perturbations throughout the disk and plasma membranes of retinal rod outer segments of various species. It is evident that a prolonged exposure to filipin in fixative enhances rather than reduces presumptive cholesterol detection in the vertebrate photoreceptor cell. In agreement with the pattern seen in our previous study (Andrews, L.D., and A. I. Cohen, 1979, J. Cell Biol., 81:215-228), filipin-binding in membranes exhibiting particle-free patches seemed largely confined to these patches. Favorably fractured photoreceptors exhibited marked filipin-binding in apical inner segment plasma membrane topologically confluent with and proximate to the outer segment plasma membrane, which was comparatively free of filipin binding. A possible boundary between these differing membrane domains was suggested in a number of replicas exhibiting lower filipin binding to the apical plasma membrane of the inner segment in the area surrounding the cilium. This area contains a structure (Andrews, L. D., 1982, Freeze-fracture studies of vertebrate photoreceptors, In Structure of the Eye, J. G. Hollyfield and E. Acosta Vidrio, editors, Elsevier/North-Holland, New York, 11-23) that resembles the active zones of the nerve terminals for the frog neuromuscular junction. These observations lead us to hypothesize that these structures may function to direct vesicle fusion to occur near them, in a domain of membrane more closely resembling outer than inner segment plasma membrane. The above evidence supports the views that (a) all disk membranes contain cholesterol, but the particle-free patches present in some disks trap cholesterol from contiguous particulate membrane regions; (b) contiguous inner and outer segment membranes may greatly differ in cholesterol content; and (c) the suggested higher cholesterol in the inner segment than in the outer segment plasma membrane may help direct newly inserted photopigment molecules to the outer segment.     

Phosphatidylserine binding sites in erythroid spectrin: location and implications for membrane stability

The erythrocyte membrane is a composite structure consisting of a lipid bilayer tethered to the spectrin-based membrane skeleton. Two complexes of spectrin with other proteins are known to participate in the attachment. Spectrin has also been shown to interact with phosphatidylserine (PS), a component of the lipid bilayer, which is confined to its inner leaflet. That there may be multiple sites of interaction with PS in the spectrin sequence has been inferred, but they have not hitherto been identified. Here we have explored the interaction of PS-containing liposomes with native alpha- and beta-spectrin chains and with recombinant spectrin fragments encompassing the entire sequences of both chains. We show that both alpha-spectrin and beta-spectrin bind PS and that sites of high affinity are located within 8 of the 38 triple-helical structural repeats which make up the bulk of both chains; these are alpha8, alpha9-10, beta2, beta3, beta4, beta12, beta13, and beta14, and PS affinity was also found in the nonhomologous N-terminal domain of the beta-chain. No other fragments of either chain showed appreciable binding. Binding of spectrin and its constituent chains to mixed liposomes of PS and phosphatidylcholine (PC) depended on the proportion of PS. Binding of spectrin dimers to PS liposomes was inhibited by single repeats containing PS binding sites. It is noteworthy that the PS binding sites in beta-spectrin are grouped in close proximity to the sites of attachment both of ankyrin and of 4.1R, the proteins engaged in attachment of spectrin to the membrane. We conjecture that direct interaction of spectrin with PS in the membrane may modulate its interactions with the proteins and that (considering also the known affinity of 4.1R for PS) the formation of PS-rich lipid domains, which have been observed in the red cell membrane, may be a result.     

Spectrin interacts with EVL (Enabled/vasodilator-stimulated phosphoprotein-like protein), a protein involved in actin polymerization

BACKGROUND INFORMATION: The alpha- and beta-spectrin chains constitute the filaments of the spectrin-based skeleton, which was first identified in erythrocytes. The discovery of analogous structures at plasma membranes of eukaryotic cells has led to investigations of the role of this spectrin skeleton in many cellular processes. The alphaII-spectrin chain expressed in nucleated cells harbours in its central region several functional motifs, including an SH3 (Src homology 3) domain. RESULTS: Using yeast two-hybrid screening, we have identified EVL [Enabled/VASP (vasodilator-stimulated phosphoprotein)-like protein] as a new potential partner of the alphaII-spectrin SH3 domain. In the present study, we investigated the interaction of the alphaII-spectrin SH3 domain with EVL and compared this with other proteins related to EVL [Mena (mammalian Enabled) and VASP]. We confirmed the in vitro interaction between EVL and the alphaII-spectrin SH3 domain by GST (glutathione S-transferase) pull-down assays, and showed that the co-expression of EVL with the alphaII-spectrin SH3 domain in COS-7 cells resulted in the partial delocalization of the SH3 domain from cytoplasm to filopodia and lamellipodia, where it was co-localized with EVL. In kidney epithelial and COS-7 cells, we demonstrated the co-immunoprecipitation of the alphaII-spectrin chain with over-expressed EVL. Immunofluorescence studies showed that the over-expression of EVL in COS-7 cells promoted the formation of filopodia and lamellipodia, and the expressed EVL was detected in filopodial tips and the leading edge of lamellipodia. In these cells over-expressing EVL, the alphaII-spectrin membrane labelling lagged behind EVL staining in lamellipodia and filopodia, with co-localization of these two stains in the contact area. In kidney epithelial cell lines, focused co-localization of spectrin with expressed EVL was observed in the membrane of the lateral domain, where the cell-cell contacts are reinforced. CONCLUSIONS: The possible link between the spectrin-based skeleton and actin via the EVL protein suggests a new way of integrating the spectrin-based skeleton in areas of dynamic actin reorganization.     

Filipin-induced lesions in planar phospholipid bilayers imaged by atomic force microscopy.

Filipin is a macrolide polyene with antifungal activity belonging to the same family of antibiotics as amphotericin B and nystatin. Despite the spectroscopy and electron microscopy studies of its interaction with natural membranes and membrane model systems, several aspects of its biochemical action, such as the role of membrane sterols, remain to be completely understood. We have used atomic force microscopy (AFM) to study the effect of filipin on dipalmitoylphosphatidylethanolamine bilayers in the presence and absence of cholesterol. The bilayers were prepared by Langmuir-Blodgett deposition over mica and imaged under water. It was shown that filipin-induced lesions could only be found in membranes with cholesterol. In close agreement with electron microscopy results, we have reported the presence of densely packed circular protrusions in the membrane with a mean diameter of 19 nm (corrected for convolution with AFM tip) and 0.4 nm height. Larger circular protrusions (90 nm diameter and 2.5 nm height) and doughnut-shaped lesions were also detected. These results demonstrate that filipin-induced lesions in membranes previously observed by electron microscopy are not biased by artifacts resulting from sample preparation. Filipin aggregates in aqueous solution could also be imaged for the first time. These polydisperse spherical structures were observed in samples with and without cholesterol.     

Crosslinking of isolated cytoskeletal proteins with hemoglobin: a possible damage inflicted to the red cell membrane

Crosslinking of isolated red cell membrane cytoskeletal proteins and hemoglobin mediated by H2O2 was studied. The products of spectrin and hemoglobin interaction were demonstrated electrophoretically to be high-molecular-weight polypeptides crosslinked by nondisulfide covalent bonds. The molecular weight of the protein bands correlated with various combinations of spectrin and hemoglobin chains and the relative amount of the different products was dependent on the molar ratio of the interacting proteins. Free hemin caused spectrin crosslinking as well, but globin in the absence of hemin was inactive. Since the H2O2-mediated reaction resulted in reduction of the spectrin tryptophan fluorescence, the latter was used to monitor the reaction progress under various conditions. Both oxyhemoglobin and methemoglobin were found to be most efficient, whereas cyanmethemoglobin and hemichrome were relatively inactive. Analysis of the data implied that tryptophan oxidation as well as spectrin conformational changes follow an iron-induced crosslinking of the interacting proteins. Actin, the second major protein in the red cell cytoskeleton, behaved similarly to spectrin. The intrinsic fluorescence intensity of both G- and F-actin was decreased upon addition of H2O2 to the mixture of hemoglobin and each of the actin forms. SDS-polyacrylamide gel electrophoresis revealed that G-actin crosslinked one or two hemoglobin chains. F-actin-hemoglobin interaction induced by H2O2 produced very high aggregates that could not penetrate the gel. It is suggested that crosslinking of cytoskeletal proteins in red cells containing membrane-associated hemoglobin provides a rationale for the loss of membrane flexibility.     

The cytoskeleton of the resting human blood platelet: structure of the membrane skeleton and its attachment to actin filaments

We used high-resolution EM and immunocytochemistry in combination with different specimen preparation techniques to resolve the ultrastructure of the resting platelet cytoskeleton. The periphery of the cytoskeleton, an electron-dense subplasmalemmal region in thin section electron micrographs, is a tightly woven planar sheet composed of a spectrin-rich network whose interstices contain GPIb/IX-actin-binding protein (ABP) complexes. This membrane skeleton connects to a system of curved actin filaments (F-actin) that emanate from a central oval core of F-actin cross-linked by ABP. The predominant interaction of the radial actin filaments with the membrane skeleton is along their sides, and the strongest connection between the membrane skeleton and F-actin is via ABP-GPIb ligands, although there is evidence for spectrin attaching to the ends of the radial actin filaments as well. Since a mechanical separation of the F-actin cores and radial F-actin-GPIb-ABP complexes from the underlying spectrin-rich skeleton leads to the latter's expansion, it follows that the spectrin-based skeleton of the resting cell may be held in a compressed form by interdigitating GPIb/IX complexes which are immobilized by radial F-actin-ABP anchors.     

Bone morphology of weanling rats from dams subjected to fluoride

Epithelial cells and surrounding free cells in the choroid plexus were examined cytochemically using filipin to clarify the distribution pattern of cholesterol within plasma membranes. The apical and basal membranes of the choroid epithelial cell are less susceptible to filipin than the lateral epithelial membrane and plasma membranes of adjacent mesenchymal cells such as macrophages and fibroblasts. Apical and basal domains of the epithelial membranes, which are relatively resistant to action of filipin, appear to have a slightly lower cholesterol content. We suggest that the apical and basal membranes may possess a unique membrane fluidity or stability that differs from that of the lateral epithelial, macrophage or fibroblast membranes.