Tritrichomonas foetus: Localization of filipin-sterol complexes in cell membranes

The polyene antibiotic, filipin, was used as a probe for the detection of sterols in the freeze-fractured plasma membrane and the flagellar membranes of the pathogenic protozoa, Tritrichomonas foetus. A homogeneous distribution of filipin-sterol complexes was seen throughout the plasma membrane, and the membrane of the three anterior and the one recurrent flagella. No or very few filipin-sterol complexes were observed in some specialized regions such as the base of the flagella (necklace), the portion of the recurrent flagellum, and that part of the cell body to which the flagellum was attached. The density of filipin-sterol complexes varied from one cell to the other. In some cells, about 205 complexes/μm² were seen. A larger number of filipin-sterol complexes were observed on both faces of the membrane of cytoplasmic structures, probably corresponding to vacuoles. No complexes were seen in the nuclear membrane and in the membrane of the endoplasmic reticulum. Very few or no complexes were observed in the membrane of the hydrogenosomes. Treatment of living cells with filipin induced aggregation of filipin-sterol complexes at some points of the plasma membrane.     

Asymmetric distribution and temperature-dependent clustering of filipin-sterol complexes in the nuclear membrane of Ehrlich ascites tumor cells

When Ehrlich ascites tumor (EAT) cells were fixed at 4 degrees C and freeze-fractured, patchy areas having no intramembrane particles were visible in the nuclear envelope. The particle free areas (PFAs) were not seen on fixation at 28 degrees C, indicating that appearance of PFAs was caused by a kind of thermotropic phase separation. The PFAs were detected only in the nuclear membrane, and not in the plasma membrane. Most of them were present in the outer membrane of the nuclear envelope. In cells fixed at 4 degrees C, and treated with filipin all the filipin-sterol complexes appeared in clusters located in the PFAs. In contrast, the filipin-sterol complexes were evenly distributed in cells fixed at 28 degrees C. This suggests that at low temperature, molecules of cholesterol gather in the PFAs. Temperature-dependent cluster formation was seen only in the complexes of the nuclear membrane, suggesting that the cholesterol in the nuclear membrane is more mobile than that in the plasma membrane. In addition, the distribution of filipin-sterol complexes in the nuclear envelope was asymmetric. The complexes were seen only in the outer (cytoplasmic), but not in the inner (nucleoplasmic) membrane of the nuclear envelope, reflecting differences in the structural, and presumably functional, characteristics of the outer and inner nuclear membranes.     

Filipin/sterol complexes in fertilized and unfertilized sea urchin egg membranes

Sea urchin (Arbacia punctulata) eggs and zygotes were treated with filipin in an effort to examine changes in membrane sterols at fertilization. The plasma membrane of treated unfertilized eggs possessed numerous filipin/sterol complexes, while fewer complexes were associated with membranes delimiting cortical granules, demonstrating that the plasmalemma is relatively rich in β-hydroxysterols in comparison to cortical granule membrane. Following fusion with the plasmalemma, membrane formerly delimiting cortical granules underwent a dramatic alteration in sterol composition, as indicated by a rapid increase in the number of filipin/sterol complexes. In contrast, portions of the zygote plasma membrane, derived from the plasmalemma of the unfertilized egg, displayed little or no change in filipin/sterol composition. Other than regions of the plasma membrane engaged in endocytosis, the plasmalemma of the zygote possessed a homogeneous distribution of filipin/sterol complexes and appeared similar to that of the unfertilized egg. These results demonstrate that following its fusion with the egg plasmalemma, membranes, formerly delimiting cortical granules, undergo a dramatic alteration in sterol composition. Changes in the localization of filipin/sterol complexes are discussed in reference to alterations in egg plasmalemmal function at fertilization.     

Interaction of the polyene antibiotic filipin with model and natural membranes containing plant sterols

The interaction of the polyene antibiotic, filipin, with individual or mixed plant sterols (stigmasterol, sitosterol, campesterol and 24-methylpollinastanol) incorporated into large unilamellar vesicles (LUV) of soybean phosphatidylcholine (PC) as well as the filipin interaction with purified membrane fractions from maize roots containing these sterols was investigated by ultraviolet (UV) absorption and and circular dichroism (CD) spectroscopy. With both types of membrane preparation, dramatic changes in the UV absorption and CD spectra of the antibiotic were evidenced. When LUV containing stigmasterol, sitosterol and/or campesterol were incubated with low filipin concentrations (i.e., for filipin/sterol molar ratios (rst) lower than 1), CD signal characteristic of the formation of filipin-sterol complexes were observed. At higher rst values, the filipin-sterol interaction was shown to be in competition with a filipin-phospholipid interaction. With 24-methylpollinastanol-containing LUV, the filipin-phospholipid interaction was detected even at rst values lower than 1, which suggests a lower affinity of filipin for this sterol and emphasizes the structural differences between delta 5-sterols and 9 beta,19-cyclopropylsterols. With sterol-free soybean PC LUV, a filipin-phospholipid interaction could also be evidenced. With maize root cell membranes containing either delta 5-sterols or 9 beta,19-cyclopropylsterols, CD spectra similar to those obtained in the presence of LUV having these sterols as components were observed. Thus, the protein component of the membranes does not appear to be an important feature.     

Filipin-sterol complexes in molluscan gill ciliated epithelial cell membranes: intercalation into ciliary necklaces and induction of gap junctional particle arrays

Summary Freeze-fracture electron microscopy has been used in conjunction with the antibiotic filipin to investigate possible differences in the distribution of sterols in ciliary and somatic cell membranes of scallop and mussel gill epithelial cells. Contrary to previous reports, we find that filipin-sterol lesions can occur among the strands of the ciliary necklace but they are partially excluded from the smooth neck region above the necklace where the membrane is tightly apposed to the axonemal microtubules. No obvious differences in filipin-sterol lesions occur in the membranes of mussel gill cilia of varying mechanical sensitivity. Although abundant in the apical plasma membrane, filipin-sterol complexes are rare within the membranes of microvilli. Filipin-sterol lesions form outside the loosely parallel particle strands of septate junctions, sometimes increasing their relative orderliness. At sufficiently high density, filipin-sterol protrusions within the plasma membrane result in mass aggregation of gap junctions, possibly through recruitment of unorganized connexons.     

Distribution of sterol-specific complexes in a continually shearing region of a plasma membrane and at procaryotic-eucaryotic cell junctions

A narrow zone of plasma membrane between the head and body of a protozoan from termites undergoes continual in-plane shear because the head rotates continuously in the same direction relative to the cell body (Tamm, S.L., and S. Tamm, 1974, Proc. Natl. Acad. Sci. USA 71:4589- 4593). Using filipin and digitonin as cytochemical probes for cholesterol and related 3-beta-hydroxysterols, we found a high level of sterol-specific complexes, visible as membrane lesions in thin sections, in both shearing and nonshearing regions of the membrane, indicating no difference in sterol content. This confirmed previous observations that any region of the fluid membrane can undergo shear, but that this occurs only at certain locations due to cell geometry and proximity to rotating cytoskeletal structures. Filipin and digitonin did not disrupt the plasma membrane at the junctions with ectosymbiotic rod and fusiform bacteria (i.e., membrane pockets and ridges). However, pepsin degradation of dense material coating the junctional membranes resulted in a positive response of these regions to filipin. Fluorescence microscopy revealed a bright halo around each rod bacterium, due to filipin-sterol binding in the sides of the membrane pockets, but no fluorescence at the bottom of the pockets; the same fluorescence pattern was found in pepsin-treated cells despite the presence of sterols throughout the pocket membrane, as shown by electron microscopy. These findings indicate that (a) regional constraints may restrict the ability of filipin to interact with sterols or form visible membrane lesions, and (b) a negative response to filipin, assayed by either electron or fluorescence microscopy, is not sufficient to demonstrate low membrane sterol concentration, particularly in membrane domains characterized by closely associated proteins.     

Occurrence and distribution of filipin-sterol complexes in chloroplast envelope membranes of algae and higher plants as visualized by freeze-fracture

Summary The occurrence and planar distribution of 3--hydroxysterols in chloroplast envelope membranes of different algae and higher plants has been studied with the freeze-fracture technique using the polyene antibiotic filipin as cytochemical marker. The inner chloroplast envelope membrane in all organisms studied is devoid of filipin-sterol complexes. The outer chloroplast envelope membranes of isolated higher plant chloroplasts (spinach, pea) and of chloroplasts of the mossPolytrichum piliferum are lacking filipin-sterol complexes, thus indicating a very low concentration of 3--hydroxysterols in chloroplast envelope membranes of higher plants. In contrast filipin-sterol complexes are abundant in the outer chloroplast envelope membrane of the flagellatesChlamydomonas reinhardii, Cryptomonas erosa, andEuglena gracilis. The chloroplast-ER surrounding the plastid ofCryptomonas erosa also exhibits filipin-sterol complexes. Functional and phylogenetic aspects of these observations are discussed.Medizinische Cytobiologie, Westfälische Wilhelms-Universität, Westring 3, D-4400 Münster, Federal Republic of Germany.     

Localization of filipin-sterol complexes in cell membranes of eosinophils

The polyene antibiotic filipin was used as a probe for the detection of cholesterol in the cell membranes of eosinophils isolated from the peritoneal exudate of rats. A homogenous distribution of filipin-sterol complexes was observed, both in thin sections and freeze-fracture replicas throughout the whole plasma membrane but not in the membrane of pynocytic vesicles, Golgi complex, endoplasmic reticulum, mitochondria and the nucleus. Few complexes were seen in freeze-fracture replicas showing the membrane of the specific granules. Treatment of living cells with filipin induced aggregation of filipin-sterol complexes at some points of the plasma membrane.     

Localization of filipin-sterol complexes in cell membranes of eosinophils

Summary The polyene antibiotic filipin was used as a probe for the detection of cholesterol in the cell membranes of eosinophils isolated from the peritoneal exudate of rats. A homogenous distribution of filipin-sterol complexes was observed, both in thin sections and freeze-fracture replicas throughout the whole plasma membrane but not in the membrane of pynocytic vesicles, Golgi complex, endoplasmic reticulum, mitochondria and the nucleus. Few complexes were seen in freeze-fracture replicas showing the membrane of the specific granules. Treatment of living cells with filipin induced aggregation of filipin-sterol complexes at some points of the plasma membrane.     

Rings of membrane sterols surround the openings of vesicles and fenestrae, in capillary endothelium

We investigated the distribution of sterols in the cell membrane of microvascular endothelium (mouse pancreas, diaphragm, brain, heart, lung, kidney, thyroid, adrenal, and liver) with the polyene antibiotic filipin, which reportedly has binding specificity for free 3-beta- hydroxysterols. In some experiments, concomitantly, cell-surface anionic sites were detected with cationized ferritin. Vessels were perfused in situ with PBS, followed by light fixation and filipin administration for 10 to 60 min. Tissues were further processed for thin-section and freeze-fracture electron microscopy. Short exposure (10 min) to filipin-glutaraldehyde solution resulted in the initial appearance, on many areas, of rings of characteristic filipin-sterol complexes within the rim surrounding stomata of most plasmalemmal vesicles, transendothelial channels, and fenestrae. Such rings were absent from the rims of the large openings of the sinusoid endothelium (liver, adrenal), coated pits and phagocytic vacuoles. After longer exposure (30-60 min), filipin-sterol complexes labeled randomly the rest of plasma membrane (except for coated pits, and partially the interstrand areas of junctions), and also marked most plasmalemmal vesicles. These peristomal rings of sterols were displayed mostly on the P face, and, at their full development, consisted of 6-8 units around a vesicle stoma, and 10-12 units around a fenestra. At their level, the intramembranous particles and the cell surface anionic sites were virtually excluded. Peristomal rings of sterols were also detected on the plasma membrane of pericytes and smooth muscle cells of the microvascular wall, which otherwise were poorly labeled with filipin- sterol complexes as compared to endothelial plasmalemma. It is presumed that the peristomal rings of cholesterol may represent important contributors to the local transient stabilization of plasma membrane and to the phase separation between cell membrane and vesicle membrane at a certain stage of their fusion/fission process.     

Interaction of filipin with junctional membrane at different stages of the junction's life history

The relationship of filipin-sterol complexes to tight and gap junctions during their formation, maturation, internalization, and degradation was studied in separate cell lines. Filipin-sterol complexes tended to be excluded from mature junctions in tight junction forming COLO 316 cells and gap junction forming SW-13 cells. Once internalized, unlabeled junctional membrane appeared to fuse with heavily labeled vesicles, presumably lysosomes. Although the absence of filipin-sterol complexes from junctional membrane does not necessarily reflect the absolute sterol content of this membrane, the fact that filipin-sterol complexes are largely excluded from these areas indicates that this membrane is different from surrounding membrane. The absence of filipin-sterol complexes also permits the visualization of 'mixing' of this specialized unlabeled membrane domain with other filipin labeled membrane systems.     

Leishmania mexicana: distribution of intramembranous particles and filipin sterol complexes in amastigotes and promastigotes

The density and distribution of intramembranous particles was analyzed in freeze fracture replicas of the plasma membrane of amastigotes, and infective as well as noninfective promastigotes of Leishmania mexicana amazonensis. The density of intramembranous particles on both protoplasmic and extracellular faces was higher in infective than in noninfective promastigotes and it was lower in amastigotes than in promastigotes. Amastigotes purified immediately after tissue homogenization were surrounded by a membrane which corresponded to the membrane which lined the endocytic vacuoles where the parasites were located within the tissue macrophages. Aggregation of the particles was seen in the flagellar membrane at the point of emergence of the flagellum from the flagellar pocket. Differences in the organization of the particles were seen in the membrane which lined the flagellar pocket of amastigotes and promastigotes. The polyene antibiotic, filipin, was used as a probe for the detection of sterols in the plasma membrane of L. m. amazonensis. The effect of filipin in the parasite's structure was analyzed by scanning electron microscopy and by transmission electron microscopy of thin sections and freeze fracture replicas. Filipin sterol complexes were distributed throughout the membrane which lined the cell body, the flagellar pocket, and the flagellum. No filipin sterol complexes were seen in the cell body-flagellar adhesion zone. The density of filipin sterol complexes was lower in the membrane lining the flagellum than in that lining the cell body of promastigotes.     

Fluorescent in situ visualization of sterols in Arabidopsis roots

Sterols are eukaryotic membrane components with crucial roles in diverse cellular processes. Elucidation of sterol function relies on development of tools for in situ sterol visualization. Here we describe protocols for in situ sterol localization in Arabidopsis thaliana root cells, using filipin as a specific probe for detection of fluorescent filipin-sterol complexes. Currently, filipin is the only established tool for sterol visualization in plants. Filipin labeling can be performed on aldehyde-fixed samples, largely preserving fluorescent proteins and being compatible with immunocytochemistry. Filipin can also be applied for probing live cells, taking into account the fact that it inhibits sterol-dependent endocytosis. The experimental procedures described are designed for fluorescence detection by confocal laser-scanning microscopy with excitation of filipin-sterol complexes at 364 nm. The protocols require 1 d for sterol covisualization with fluorescent proteins in fixed or live roots and 2 d for immunocytochemistry on whole-mount roots.     

Filipin-cholesterol complexes form in uncoated vesicle membrane derived from coated vesicles during receptor-mediated endocytosis of low density lipoprotein

Filipin has been widely used as an electron microscopic probe to detect 3-beta-hydroxysterols, principally cholesterol, in cellular membranes. When it complexes with sterol, it forms globular deposits that disrupt the planar organization of the membrane. Previous studies have shown that coated pits and coated vesicles, specialized membranes involved in receptor-mediated endocytosis, do not appear to bind filipin. This has led to the suggestion that these membranes are low in cholesterol compared with the remainder of the plasma membrane. Since coated endocytic vesicles become uncoated vesicles during the transport of internalized ligands to the lysosome, we have carried out studies to determine whether or not the membranes that surround these transport vesicles are unable to bind filipin and therefore, are also low in cholesterol. Cells were incubated with ferritin-conjugated ligands that bind to low density lipoprotein (LDL) receptors in coated pits. After allowing internalization of the conjugates, we fixed the cells in either the presence or absence of filipin. This permitted us to identify all of the vesicles involved in the transport of LDL to the lysosome and to determine whether the membranes of these vesicles were able to bind filipin. We found that, coordinate with the dissociation of the clathrin coat from the endocytic vesicles, the membranes became sensitive to the formation of filipin-sterol complexes. Furthermore, all of the uncoated endocytic vesicle membranes, as well as the lysosomal membranes, bound filipin. This suggests either that coated membrane contains normal cholesterol levels, which is not easily detected with filipin, or that cholesterol rapidly moves into endocytic vesicles after the clathrin coat dissociates from the membrane.     

Distribution of filipin-sterol complexes on cultured muscle cells: cell- substratum contact areas associated with acetylcholine receptor clusters

Specialized areas within broad, close, cell-substratum contacts seen with reflection interference contrast microscopy in cultures of Xenopus embryonic muscle cells were studied. These areas usually contained a distinct pattern of light and dark spots suggesting that the closeness of apposition between the membrane and the substratum was irregular. They coincided with areas containing acetylcholine receptor clusters identified by fluorescence labeled alpha-bungarotoxin. Freeze-fracture of the cells confirmed these observations. The membrane in these areas was highly convoluted and contained aggregates of large P-face intramembrane particles (probably representing acetylcholine receptors). If cells were fixed and then treated with the sterol- specific antibiotic filipin before fracturing, the pattern of filipin- sterol complex distribution closely followed the pattern of cell- substratum contact. Filipin-sterol complexes were in low density in the regions where the membrane contained clustered intramembrane particles. These membrane regions were away from the substratum (bright white areas in reflection interference contrast; depressions of the P-face in freeze-fracture). Filipin-sterol complexes were also in reduced density where the membrane was very close to the substratum (dark areas in reflection interference contrast; bulges of the P-face in freeze- fracture). These areas were not associated with clustered acetylcholine receptors (aggregated particles). This result suggests that filipin treatment causes little or no artefact in either acetylcholine receptor distribution or membrane topography of fixed cells and that the distribution of filipin-sterol complexes may closely parallel the microheterogeneity of membranes that exist in living cells.     

Freeze-fracture localization of filipin-sterol complexes in plasma- and cyto-membranes of Pneumocystis carinii

The polyene antibiotic, filipin, was used as the probe for demonstrating sterols in the freeze-fractured plasma- and cytomembranes of Pneumocystis carinii. The distribution of filipin-sterol complexes was homogeneous on the plasma membrane throughout all developmental stages from trophozoite to cyst; however, the density of the complexes gradually decreased with the progress of development. In the trophozoite, the density of the complexes was 485 +/- 42/micron2 on the P face and 341 +/- 27/micron2 on the E face. It was 249 +/- 50 on the P face and 132 +/- 48 on the E face in the precyst and 138 +/- 24 and 59 +/- 20, respectively, in the cyst. The membranes of nucleus, mitochondria, and small round bodies showed more or fewer complexes while no complexes were found in the membranes of one endoplasmic reticulum. In nuclear and mitochondrial membranes, some small scattered clusters of complexes were observed. Two types of vacuoles were distinguished: one having many complexes in its membrane and the other having none at all.     

Morphological detection of filipin-sterol complexes in the cytoplasmic membrane of staphylococcal L-form

Filipin, a sterol-specific antibiotic, and freeze-fracture electron microscopy were used to study the presence and distribution of sterol in the cytoplasmic membrane of stable staphylococcal L-form cells. Fixed cells were treated with filipin, and then observed by freeze-fracture electron microscopy. Freeze-fractured profiles of the L-form cells treated with filipin demonstrated irregular distribution of protuberances or pits of 25-30 nm, representing filipin-sterol complexes, on the proto-plasmic fracture face (PF) and exoplasmic fracture face (EF) of the cytoplasmic membrane. In contrast, no such structure was detected in the filipin-treated parent cells or protoplasts. The results suggest that some sterol molecules, which are usually not found in staphylococcal or other bacterial cells, emerged on the cytoplasmic membrane after the cells were converted to the stable L-form.     

Plasma membrane sterol complexation, generated by filipin, triggers signaling responses in tobacco cells

The effects of changes in plasma membrane (PM) sterol lateral organization and availability on the control of signaling pathways have been reported in various animal systems, but rarely assessed in plant cells. In the present study, the pentaene macrolide antibiotic filipin III, commonly used in animal systems as a sterol sequestrating agent, was applied to tobacco cells. We show that filipin can be used at a non-lethal concentration that still allows an homogeneous labeling of the plasma membrane and the formation of filipin-sterol complexes at the ultrastructural level. This filipin concentration triggers a rapid and transient NADPH oxidase-dependent production of reactive oxygen species, together with an increase in both medium alkalinization and conductivity. Pharmacological inhibition studies suggest that these signaling events may be regulated by phosphorylations and free calcium. By conducting FRAP experiments using the di-4-ANEPPDHQ probe and spectrofluorimetry using the Laurdan probe, we provide evidence for a filipin-induced increase in PM viscosity that is also regulated by phosphorylations. We conclude that filipin triggers ligand-independent signaling responses in plant cells. The present findings strongly suggest that changes in PM sterol availability could act as a sensor of the modifications of cell environment in plants leading to adaptive cell responses through regulated signaling processes.     

Freeze-Fracture Localization of Filipin-Sterol Complexes in Plasma- and Cyto-Membranes of Pneumocystis carinii1

The polyene antibiotic, filipin, was used as the probe for demonstrating sterols in the freeze-fractured plasma- and cytomembranes of Pneumocystis carinii. The distribution of filipin-sterol complexes was homogeneous on the plasma membrane throughout all developmental stages from trophozoite to cyst; however, the density of the complexes gradually decreased with the progress of development. In the trophozoite, the density of the complexes was 485 ± 42/μm² on the P face and 341 ± 27/μm² on the E face. It was 249 ± 50 on the P face and 132 ± 48 on the E face in the precyst and 138 ± 24 and 59 ± 20, respectively, in the cyst. The membranes of nucleus, mitochondria, and small round bodies showed more or fewer complexes while no complexes were found in the membranes of one endoplasmic reticulum. In nuclear and mitochondrial membranes, some small scattered clusters of complexes were observed. Two types of vacuoles were distinguished: one having many complexes in its membrane and the other having none at all.     

Transbilayer distribution of sterols in mycoplasma membranes: a review

The polyene antibiotic, filipin, binds to 3 beta-hydroxysterols. The initial rate of filipin-sterol association, monitored in a stopped-flow spectrophotometer, was first order in each reacting partner. The ratio of rate constants in intact mycoplasma cells relative to isolated, unsealed membranes provides an estimate of sterol distribution in the membrane bilayer. Cholesterol is distributed symmetrically in the bilayer of M. gallisepticum cells from the early exponential phase. However, in the M. capricolum membrane two-thirds of the unesterified cholesterol is localized in the outer leaflet; alkyl-sterols are distributed predominantly in the external monolayer. Cholesterol is translocated rapidly in the bilayer of M. capricolum cells. Exogenous phospholipids incorporated into the membrane had no effect on the cholesterol distribution in M. capricolum.