Purification of an 80,000-dalton protein that is a component of the isolated microvillus cytoskeleton, and its localization in nonmuscle cells

The microvillus cytoskeleton, isolated from chicken intestinal epithelial cell brush borders, is known to contain five major protein components, the 110,000-dalton polypeptide, villin (95,000 daltons), fimbrin (68,000 daltons), actin (43,000 daltons), and calmodulin (17,000 daltons). In this paper we describe our first step in studying the minor components of the isolated core. We have so far identified and purified an 80,000-dalton polypeptide that was present in the isolated structure in approximately 0.7% the molar abundance of actin. Antibodies to the 80,000-dalton component did not react with other microvillus core proteins, and, when used in indirect immunofluorescence microscopy, they stained the microvilli of intestinal epithelial cells fixed in situ. The 80,000-dalton component therefore appears to be a newly-identified, authentic component of intestinal microvilli in vivo and of isolated microvillus cores. Immunological studies demonstrate that the 80,000-dalton component is widely distributed in nonmuscle cells. Indirect immunofluorescence microscopy reveals that it is particularly enriched in surface structures, such as blebs, microvilli, and retraction fibers of cultured cells.     

The phenotype of triparental hepatoma cell hybrids depends on the fusion sequence used to generate them

Villin is a major protein of the microfilament bundle which makes up the core of each microvillus of the brush border of the intestinal epithelial cell. Using antibodies to villin in indirect immunofluorescence microscopy on isolated cells and on frozen tissue sections, the protein is readily detectable in the microvilli of the brush border of both intestinal and renal epithelial cells. However, villin could not be detected in tissue culture cells either by immunofluorescence microscopy or by immune replica procedures. When native villin was microinjected into such cells and its distribution visualized by immunofluorescence microscopy, the protein was found to be associated with microfilamentous structures. Moreover, preferential association of the villin into the microfilaments at the leading edges of the living cell was observed. Since villin behaves in vitro as a calcium-regulated F-actin bundling protein, we discuss the possibility that villin is immunologically distinct but functionally related to putative calcium-regulatory factors assumed to be present in cultured cells.     

The p36 substrate of tyrosine-specific protein kinases co-localizes with non-erythrocyte alpha-spectrin antigen, p230, in surface lamina of cultured fibroblasts

Biochemical and immunofluorescence studies have demonstrated that p36, a major substrate for the tyrosine-specific protein kinases induced by several sarcoma viruses and epidermal growth factor, is associated with plasma membranes and detergent-resistant cytoskeletal structures of cultured cells. We have used here polyclonal antisera and monoclonal antibodies in indirect immunofluorescence microscopy to study the subcellular location of p36 and the p230, which is a subplasmalemmal polypeptide showing immunologic cross-reactivity with erythrocyte alpha-spectrin. Both p36 and p230 showed a diffuse distribution in fixed and permeabilized cells and were localized in a surface lamina-like network in Triton-extracted cells. In double-staining experiments, an extensive co-distribution between these proteins was seen in detergent-treated cultured fibroblasts. These results, together with our previous work, suggest that the p36 protein is an integral part of the detergent-resistant proteinaceous network at the cytoplasmic face of the plasma membrane.     

Immunofluorescent and immunochemical evidence for the expression of cytovillin in the microvilli of a wide range of cultured human cells

We have previously purified a Mr 75,000 protein, cytovillin, from cultured human choriocarcinoma cells (JEG-3) and shown that this protein was specifically confined to the microvillus membrane of these cells. I have now studied the expression and the subcellular distribution of cytovillin in eighteen normal and transformed human cell lines and strains by using immunoblotting and indirect immunofluorescence microscopy. In all cell types, cytovillin was highly enriched in cell surface protrusions. When cell types were ranked according to their staining intensity, choriocarcinoma was highest, then amniotic epithelial cells, other choriocarcinoma cells and tumor cells, and finally fibroblastoid cells. The latter only gave faint diffuse fluorescence on the plasma membrane and, occasionally, on the microvilli. However, detergent extracts of all cell types could be shown to contain cytovillin by the use of immunoblotting techniques. Metabolic pulse-chase labelling experiments with JEG-3 cells demonstrated synthesis of cytovillin as a single-chain polypeptide. No precursor forms or specific proteolytic cleavage products could be seen either by immunoblotting or immunoprecipitation. The protein was found to be very stable with a biologic half-life of about 25 hours. The pI determined by isoelectric focusing was 6.1. These results were consistent with cytovillin being an integral component of the microvilli and other surface extensions of all human cell types examined.     

Identification of a 100 kD protein associated with microtubules, intermediate filaments and coated vesicles in cultured cells

We have obtained several hybridoma clones producing antibodies to microtubule-associated proteins (MAPs) from bovine brain. Interaction of one of these antibodies, named RN 17, with cultured cells was studied by indirect immunofluorescence and immunoelectron microscopy. RN 17 antibody recognized both high molecular weight (HMW) MAPs, MAP 1 and MAP 2, in immunoblotting reaction with brain microtubules. In lysates of cultured cells, it bound to a protein doublet with a molecular weight of 100 kD. By immunofluorescence microscopy we showed that RN 17 antibody stained cytoplasmic fibrils, mitotic spindles and small particles in the cytoplasm of various cultured cells. The cytoplasmic fibrils were identified as both microtubules and intermediate filaments by double fluorescence microscopy and by their response to colcemid and 0.6 M KCl. This identification was confirmed by immunoelectron microscopy which also showed that the particles stained by RN 17 antibody are coated vesicles. Thus, cultured non-neural cells may contain a novel protein that binds to microtubules, intermediate filaments, and coated vesicles.     

Cytovillin and other microvillar proteins of human choriocarcinoma cells

Microvilli were isolated from cultured human JEG-3 choriocarcinoma cells using a gentle shearing method. The protein components of the isolated microvilli were examined by sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotting. The major Mr 42,000 and Mr 100,000 polypeptide bands reacted with anti-actin and anti-alpha-actinin antisera, respectively. Extraction of the isolated JEG-3 microvilli with Triton X-100 left an insoluble cytoskeletal residue containing mainly actin, alpha-actin, and polypeptides of Mr 200,000, 55,000 and 35,000. The Mr 35,000 polypeptide remained insoluble only at high concentrations of free Ca2+. Immunoblotting analysis of the JEG-3 microvilli indicated that they were devoid of tropomyosin, although the total JEG-3 protein lysates gave a strong positive reaction with anti-tropomyosin antiserum. The different subcellular localization of cytovillin and tropomyosin was also shown by indirect immunofluorescence microscopy. Cytovillin, an Mr 75,000 microvillus-specific membrane protein of JEG-3 cells, existed in an oligomeric form (dimer or trimer) as shown by gel filtration of Triton X-100 solubilized microvillar proteins and by native polyacrylamide gel electrophoresis of purified cytovillin. Disulfide bridges were not involved in the aggregation, because the mobility of cytovillin was similar under reducing and nonreducing conditions in SDS-PAGE. Cytovillin was shown to be closely related to ezrin, a minor component of chicken intestinal brush border microvilli.     

Localization of capping protein in chicken epithelial cells by immunofluorescence and biochemical fractionation

We have localized capping protein in epithelial cells of several chicken tissues using affinity-purified polyclonal antibodies and immunofluorescence. Capping protein has a distribution in each tissue coincident with proteins of the cell-cell junctional complex, which includes the zonula adherens, zonula occludens, and desmosome. "En face" views of the epithelial cells showed capping protein distributed in a polygonal pattern coincident with cell boundaries in intestinal epithelium, sensory epithelium of the cochlea, and the pigmented epithelium of the retina and at regions of cell-cell contact between chick embryo kidney cells in culture. "Edge-on" views obtained by confocal microscopy of intact single intestinal epithelial cells and of retinal pigmented epithelium showed that capping protein is located in the apical region of the epithelial cells coincident with the junctional complexes. These images do not resolve the individual types of junctions of the junctional complex. Immunolabeling of microvilli or stereocilia was faint or not detectable. Capping protein was also detected in the cytoplasm of intact intestinal epithelial cells and in nuclei of cells in the pigmented retina and in the kidney cell cultures, but not in nuclei of cells of the intestinal epithelium or sensory epithelium. Biochemical fractionation of isolated intestinal epithelial cells shows capping protein in the brush border fraction, which contains the junctional complexes, and in the soluble fraction. These results are consistent with the results of the immunolabeling experiments. Highly purified microvilli of the brush borders also contained capping protein; this result was unexpected based on the low intensity of immunofluorescence staining of microvilli and stereocilia. The microvilli were not contaminated with junctional complexes, as defined by the absence of several markers for cell junctions. The cause and significance of this discrepancy is not certain at this time. Since capping protein binds the barbed end of actin filaments in vitro, we hypothesize that capping protein is bound to the barbed ends of actin filaments associated with one or more of the junctions of the junctional complex.     

Development of an optimized protocol for primary culture of smooth muscle cells from rat thoracic aortas

Primary culture of smooth muscle cells has been widely used as a valuable tool to study the molecular mechanisms underlying atherosclerosis and restenosis. Currently, tissue explants and enzymatic digestion methods are frequently applied to produce smooth muscle cells. Explants method is time consuming, usually taking several weeks. The enzymatic digestion method requires large amounts of proteolytic enzymes to generate enough cells for cardiovascular research. The present study reports an optimized method by combining both techniques to obtain high purity smooth muscle cells. The cultured cells exhibited the characteristic “hills and valleys” growth pattern as observed by phase contrast microscopy and showed α-SM-actin positive staining by indirect immunocytochemistry and immunofluorescence. Purity of the cells is guaranteed by the lack of von Willebrand Factor immunoreactivity. Finally, the cultured cells well proliferate on oxidized-LDL stimulation, suggesting the practical utility of this new method.     

Immunolocalization of the 33 kD protein in the microvilli of rabbit small-intestinal epithelial cells

Rabbit small-intestinal microvilli isolated by a Ca²⁺ precipitation method contain a 33 kD protein, which has not been observed in microvilli isolated in the presence of Ca²⁺-chelators. The intracellular localization of this protein in rabbit intestinal epithelial cells was studied by immunofluorescence and immunoperoxidase microscopy, and was compared with that of aminopeptidase M, a well-known microvillus membrane-bound enzyme. The results obtained show that the 33 kD protein is located in the inside of the microvillus, but not in the terminal web of the epithelial cell. The protein may also be located on the basolateral surface of the cell.     

Cultured chick yolk sac epithelium: structure and IgG surface binding

The chick yolk sac endoderm transports maternal immunoglobulin G (IgG) from the yolk into the embryo during development, providing the newly hatched chick with passive immunity until it becomes immunocompetent. To study this transport process, chick yolk sac endodermal cells isolated from embryos of 6 to 18 days of incubation were grown in vitro on a collagen substrate. The cultured cells possessed a remarkable structural similarity to the in vivo tissue and reformed a polarized confluent epithelium with tight junctions and desmosomes joining the cells at their apical margins. In addition, the cells exhibited apical microvilli, numerous phagolysosomes in the cytoplasm and retained the expression of the yolk sac endoderm-specific enzyme marker, cysteine lyase. Importantly, the cultured cells retained the ability to specifically bind IgG as demonstrated by indirect immunofluorescence. Chicken IgG bound to the cultured cells at 4 degrees C in a diffuse pattern that clustered into a punctate pattern when a second antibody was used. Cultures from yolk sacs of day 6 through day 18 of development all demonstrated this immunofluorescent labeling for at least 14 days in culture. These results demonstrate that cultured yolk sac endoderm maintains its differentiated morphology and ability to bind IgG.     

Localisation of the major high-molecular-weight protein on microtubules in vitro and in cultured cells

An antiserum has been produced which is specific for the major high-molecular-weight protein (HMW) associated with pig brain microtubules assembled in vitro. The HMW protein can be localised on the surface of brain microtubules assembled in vitro as a corase helix by using a peroxidase labelling technique. In cultured ovarian granulosa cells, by using indirect immunofluorescence, the HMW is present on cold- and colchicine-sensitive structures which have an intracellular distribution similar to microtubules. It seems likely, therefore, that the brain protein is representative of a class of proteins associated with non-neuronal cytoplasmic microtubules.     

Membrane molecules involved in adhesion properties of cultured sertoli cells

Membrane components involved in adhesion properties of cultured Sertoli cells have been studied by a combination of immunological and biochemical methods. An antiserum prepared against Sertoli cells induced reversible rounding and detachment of the cells from the culture dishes. The cell surface morphology during detachment was studied by scanning electron microscopy and indirect immunofluorescence. A Triton soluble fraction of crude membrane preparations inhibited the antibody-induced detachment. The antibodies recognized a restricted number of membrane glycoproteins [detectable as prominent bands on Sodium dodecylsulphate polyacrilamide gel electrophoresis (SDS-PAGE), M_r 170, 140, 80, and 48K] both in the Triton soluble fraction of crude membrane preparation and on intact Sertoli cells. The data suggest that the molecules involved in adhesion properties of cultured Sertoli cells are integral membrane glycoproteins exposing antigenic determinants at the cell surface.     

Immunolocalization of a putative unconventional myosin on the surface of motile mitochondria in locust photoreceptors

Light stimulation of locust (Schistocerca gregaria) photoreceptors results in an actin-dependent translocation of mitochondria towards the photoreceptive microvilli and an antagonistic movement of endoplasmic reticulum towards the cell body. Using immunocytochemical techniques, we have tried to identify myosin-like motors that may drive the light-induced organelle motility. A monoclonal antibody against the motor domain of Acanthamoeba myosin identifies a prominent 110-kDa protein on Western blots of locust retina. Cross-reactivity with two polyclonal anti-myosin antibodies and a monoclonal anti-myosin-I-antibody, together with ATP-dependent binding to actin filaments, provides evidence that the 110-kDa protein is an unconventional myosin. By indirect immunofluorescence, the 110-kDa protein has been localized to both photoreceptors and pigment cells within the retina. In the photoreceptor cells, the 110-kDa protein is bound to the surface of mitochondria. This putative unconventional myosin may thus be a motor protein involved in the light-induced translocation of mitochondria in photoreceptors.     

Spatial Distribution of Proteins Specific for Desmosomes and Adhaerens Junctions in Epithelial Cells Demonstrated by Double Immunofluorescence Microscopy

Abstract. The spatial relationships between the protein constituents of two junctional structures, adhaerens junctions and desmosomes, were determined by double immunofluorescence microscopy using marker proteins specific for these structures. Adhaerens junctions were visualized by immunofluorescent labeling for the membrane-associated protein vinculin and by their association with actin filaments. Desmosomal components were identified by labeling with anti-bodies to a group of minor desmosomal plaque proteins (DP1 antigens) and their association with filaments stained by cytokeratin antibodies. Double immunofluorescence microscopy of these components was performed in several tissues and cultured cells, including intact intestine, dissociated intestinal cells, and two morphologically different types of epithelial cells, cultured bovine kidney (MDBK), and mammary gland (BMGE) epithelial cells. This allowed the direct demonstration that each filament system is associated exclusively with its specific membrane-bound junctional protein. Vinculin and DP1-protein were found in distinct sites in the subapical intercellular junctional complex of intestinal epithelium and MDBK cells. Cell-substrate focal contacts contained vinculin and actin and showed no apparent relationships to the tonofilament system whereas intercellular contacts of BMGE cells were characterized by positive staining for DP1-protein and associated cytokeratin filaments. Immunolabeling of the cultured cells at different intervals after plating for the cytoskeletal elements and their membrane anchorage proteins was used to determine the temporal sequence of their organization. We propose that this approach may be used for the molecular definition and identification of cellular contacts and junctions as well as for studies of junction topology, dynamics of junction-cytoskeleton interactions, and junction biogenesis.     

Enhanced fusion of a nucleopolyhedrovirus with cultured cells by a virus enhancing factor from an entomopoxvirus

Fusion of Pseudaletia unipuncta nucleopolyhedrovirus with an armyworm cell line (SIE-MSH-805-F) was studied by means of three fluorescence assays that are based on the relief of fluorescence self-quenching of octadecylrhodamine B chloride (R18). A gradual increase in fluorescence intensity indicative of virus-cell fusion was observed by spectrofluorometry when R18-labeled polyhedron-derived virus was incubated with cultured cells. The fusion was enhanced by the virus enhancing factor (EF) from Pseudaletia separata entomopoxvirus. Lysosomotropic agents had little effect on the virus-cell fusion. The percentage of positively fluorescent cells, as determined by flow cytometry, gradually increased after the addition of labeled virus and was higher in the presence of the EF than in its absence. Confocal microscopy of cultured cells that had been combined with labeled virus showed that the fluorescence appeared first on their surface. The plasma membrane of cultured cells had specific affinity to the EF, as revealed by indirect immunofluorescence microscopy.     

Indirect immunofluorescence microscopy of microtubular structures in male germ cells of wildtype and l(3)pl (lethal-polyploid) Drosophila hydei.

Tubulin-containing structures of the male germ cells of Drosophila hydei crossreact in indirect immunofluorescence microscopy with antibody directed against homogeneous porcine brain tubulin. There is no detectable difference in reactivity between germ cells of wildtype flies and the mutant l(3)pl (lethal-polyploid) which is characterized by microtubular abnormalities. However, the technique of indirect immunofluorescence microscopy allows the direct visualization of several abnormalities in the arrangement of the microtubular system of the mutant, particularly in the axonemal complex.     

Diphtheria toxin receptor sites on membranes of cultured cells and erythrocytes demonstrated by fluorescence and electron microscopy

Diphtheria toxin (DT) receptor sites were identified on cell membranes by indirect immunofluorescence and immunoferritin labelling. The results obtained were correlated (1) with the binding of 125I-labelled DT (to the very same cell populations used in the ultrastructural studies), and (2) with toxin sensitivity as shown by inhibition of 14C-amino acid incorporation into protein. Binding and immunocytochemical studies were carried out at 0 degrees C to preclude internalization of DT. Receptor sites for DT were observed on functionally responsive, cultured human diploid (BUD-8) fibroblasts as well as on a small fraction of erythrocytes (RBC) of DT-susceptible species, i.e. human and sheep. On all BUD-8 cell sections DT receptor sites were located in annular patches and not on microvilli as had been observed in the KB epithelial cell line. Immunoferritin label was revealed on only 10% +/- 2.5 (SD) of human RBC in discreet loci along the cell membrane. Specificity of binding of DT to human fibroblast and RBC receptor sites was further demonstrated by competition between 125I-labeled and non-labelled DT. There was no specific binding to DT-treated cultured mouse L929 fibroblasts or to RBC of mouse of rat, species resistant to the toxin. Thus, direct ultrastructural immunocytochemical evidence is provided for the presence of specific cellular DT receptors on cultured cells and erythrocytes of species sensitive to DT, but not on those of species resistant to DT.     

Laminin in cultured mouse C1300 neuroblastoma cells: immunocytochemical localization by pre- and postembedding electron microscope procedures

Laminin was localized in cultured mouse C1300 neuroblastoma cells by applying the peroxidase-antiperoxidase technique in preembedding electron microscopy. The results were compared to those obtained by indirect immunofluorescence and by the colloidal gold second antibody method on Epon-embedded ultrathin sections. Laminin was found in the cell membranes and within the rough endoplasmic reticulum as well as in intracytoplasmic vacuoles. Plasma membranes of the neuroblastoma cells showed a patchy localization of laminin that was apparently involved in cell-to-substrate attachment and in gap junction-like intercellular connections. Under normal conditions, the Golgi cisternae contained no laminin. Pretreatment of cells with micromolar concentrations of monensin, however, lead to an accumulation of laminin within the Golgi cisternae. These results support a role for laminin as an adhesion protein in cultured neuroblastoma cells and indicate that laminin is transported through the Golgi complex.     

Evidence for receptor-mediated uptake of adenosine deaminase in rabbit kidney

We investigated the subcellular location of adenosine deaminase-complexing protein in the proximal renal tubules of rabbit kidney and its interaction with intravenously infused monomeric calf adenosine deaminase. Cortical tissue from non-infused animals, stained in suspension by the peroxidase-antiperoxidase method for complexing protein and embedded in resin, was examined by transmission electron microscopy. Positive staining indicated the presence of complexing protein on the surface of microvilli in the proximal tubules. Sections (1 micron) of resin-embedded cortex from infused rabbits, stained first for complexing protein and then for adenosine deaminase, were examined by light microscopy. After staining for complexing protein by indirect immunofluorescence, the sections were photographed and then immersed in buffer containing 6 M guanidine hydrochloride plus 2-mercaptoethanol for 3 hr at 60 degrees C to remove bound antibodies. The sections were then stained by the peroxidase-antiperoxidase method for infused enzyme. Vesicle-like apical structures, the basal membrane area and, as previously reported, the brush border of proximal tubule cells were positive for complexing protein. Vesicle-like structures and brush borders positive for complexing protein were also stained for adenosine deaminase. The basal membrane area did not stain. These results support the hypothesis that complexing protein can act as a receptor for adenosine deaminase.     

Presence in human epidermal cells of a soluble protein precursor of the cross-linked envelope: activation of the cross-linking by calcium ions.

Late in the terminal differentiation of epidermis and cultured epidermal cells, a protein envelope located beneath the plasma membrane becomes cross-linked by cellular transglutaminase. The process of cross-linking can be initiated in cultured epidermal cells by agents affecting cell membrane permeability--nonionic detergents, high salt concentrations and ionophores. These agents initiate the cross-linking process by making calcium ions available to the transglutaminase. A soluble precursor of the cross-linked envelope has been identified in crude extracts of cultured epidermal cells by its ability to incorporate labeled amines through the action of transglutaminase. The protein has been purified to homogeneity by gel filtration and chromatography on columns of DEAE-cellulose and hydroxyapatite. Comprising an estimated 5--10% of the soluble cell proteins, it has a molecular weight of about 92,000, is isoelectric at pH 4.5 +/- 0.3 and has an unusual amino acid composition (46% Glx residues). It is chemically and immunochemically unrelated to keratins. The following evidence confirms that the protein becomes incorporated into cross-linked envelopes: first, washed cross-linked envelopes bind antibody to the purified protein, as shown by indirect immunofluorescence; second, absorption of the antiserum with washed envelopes removes all detectable antibodies to the purified protein; and third, the protein cannot be extracted from keratinocytes after their envelopes have become cross-linked. Examination of sections of epidermis by immunofluorescence, using antiserum to the purified protein, reveals that in addition to the stratum corneum, the living cells of the outer half of the spinous layer react strongly. The envelope precursor is present in the cytoplasm, but becomes concentrated at the cell periphery, where it will be cross-linked later, when the cells have passed through the granular layer. The protein is also concentrated in a peripheral location in cultured epidermal cells.