Characterization of intermediate filaments and their structural organization during epithelium formation in pigmented epithelial cells of the retina in vitro

Summary Retinal pigmented epithelial cells of chicken have circumferential microfilament bundles (CMBs) at the zonula adherens region. Isolated CMBs are polygons filled with a meshwork composed primarily of intermediate filaments; they show three major components of 200000, 55000, and 42000 daltons in SDS-gel electrophoresis. Here we have characterized the 55000-dalton protein immunochemically and ultrastructurally. Immunoblotting and immunofluorescence microscopy have shown that the 55000-dalton protein is an intermediate filament protein, vimentin.Vimentin filaments changed their distribution during differentiation of pigmented epithelial cells in culture. The protein in the elongated cells showed a fibroblast-type pattern of intermediate filaments. During epithelium formation, the filaments were uniformly distributed and formed a finer meshwork at the apical level. In pigmented epithelial cells that differentiated and matured in culture, vimentin and actin exhibited their characteristic behavior after treatment with colcemid. In the central to basal region of the cell, intermediate filaments formed thick perinuclear bundles. In the apical region, however, intermediate filaments changed in organization from a nonpolarized meshwork to a polarized bundle-like structure. Simultaneously, new actin bundles were formed, running parallel to the intermediate filaments. This suggests that there is some interaction between microfilaments and intermediate filaments in the apical region of these cells.     

Involvement of microtubules and 10-nm filaments in the movement and positioning of nuclei in syncytia

Previous studies (Holmes, K.V., and P.W. Choppin. J. Exp. Med. 124:501- 520; J. Cell Biol. 39:526-543) showed that infection of baby hamster kidney (BHK21-F) cells with the parainfluenza virus SV5 causes extensive cell fusion, that nuclei migrate in the syncytial cytoplasm and align in tightly-packed rows, and that microtubules are involved in nuclear movement and alignment. The role of microtubules, 10-nm filaments, and actin-containing microfilaments in this process has been investigated by immunofluorescence microscopy using specific antisera, time-lapse cinematography, and electron microscopy. During cell fusion, micro tubules and 10-nm filaments from many cells form large bundles which are localized between rows of nuclei. No organized bundles of actin fibers were detected in these areas, although actin fibers were observed in regions away from the aligned nuclei. Although colchicine disrupts microtubules and inhibits nuclear movement, cytochalasin B (CB; 20-50 microgram/ml) does not inhibit cell fusion or nuclear movement. However, CB alters the shape of the syncytium, resulting in long filamentous processes extending from a central region. When these processes from neighboring cells make contact, fusion occurs, and nuclei migrate through the channels which are formed. Electron and immunofluorescence microscopy reveal bundles of microtubules and 10-nm filaments in parallel arrays within these processes, but no bundles of microfilaments were detected. The effect of CB on the structural integrity of microfilaments at this high concentration (20 microgram/ml) was demonstrated by the disappearance of filaments interacting with heavy meromyosin. Cycloheximide (20 microgram/ml) inhibits protein synthesis but does not affect cell fusion, the formation of microtubules and 10-nm filament bundles, or nuclear migration and alignment; thus, continued protein synthesis is not required. The association of microtubules and 10-nm filaments with nuclear migration and alignment suggests that microtubules and 10-nm filaments are two components in a system which serves both cytoskeletal and force-generating functions in intracellular movement and position of nuclei.     

Antibodies as probes of cellular differentiation and cytoskeletal organization in the mouse blastocyst

Indirect immunofluorescence microscopy has been used to detect cytoskeletal proteins, which allow a distinction between the two cell types present in the mouse blastocyst: i.e. the cells of the inner cell mass (ICM) and the outer trophoblastic cells. Antibodies against three classes of intermediate-sized filaments (cytokeratins, desmin and vimentin), as well as antibodies against actin and tubulin were studied. Antibodies against prekeratin stain the outer trophoblastic cells but not the ICM in agreement with the findings on adult tissues that cytokeratins are a marker for various epithelial cells. Interestingly, vimentin filaments typical of mesenchymal cells as well as of cells growing in culture seem to be absent in both cell types of the blastocyst. Thus, the cytokeratins of the trophoblastic cells seem to be the first intermediate-sized filaments expressed in embryogenesis. Antibodies to tubulin and actin show that microtubules and microfilaments are ubiquitous structures, although microfilaments have a noticeably different organization in the two cell types. In addition, since early embryogenic multipotential cells show close similarities to teratocarcinomic cells, a comparison is made between the cells of the blastocyst, embryonal carcinoma cells (EC cells) and an epithelial endodermal cell line (PYS2 cells) derived from EC cells. EC cells display vimentin filaments whereas PYS2 cells show both vimentin and cytokeratin filaments. The results emphasize the usefulness of antibodies specific for different classes of intermediate filaments in further embryological studies, and suggest that cells of the blastocyst and EC cells differ with respect to vimentin filaments.     

Viscoelastic properties of vimentin compared with other filamentous biopolymer networks

The cytoplasm of vertebrate cells contains three distinct filamentous biopolymers, the microtubules, microfilaments, and intermediate filaments. The basic structural elements of these three filaments are linear polymers of the proteins tubulin, actin, and vimentin or another related intermediate filament protein, respectively. The viscoelastic properties of cytoplasmic filaments are likely to be relevant to their biologic function, because their extreme length and rodlike structure dominate the rheologic behavior of cytoplasm, and changes in their structure may cause gel-sol transitions observed when cells are activated or begin to move. This paper describes parallel measurements of the viscoelasticity of tubulin, actin, and vimentin polymers. The rheologic differences among the three types of cytoplasmic polymers suggest possible specialized roles for the different classes of filaments in vivo. Actin forms networks of highest rigidity that fluidize at high strains, consistent with a role in cell motility in which stable protrusions can deform rapidly in response to controlled filament rupture. Vimentin networks, which have not previously been studied by rheologic methods, exhibit some unusual viscoelastic properties not shared by actin or tubulin. They are less rigid (have lower shear moduli) at low strain but harden at high strains and resist breakage, suggesting they maintain cell integrity. The differences between F-actin and vimentin are optimal for the formation of a composite material with a range of properties that cannot be achieved by either polymer alone. Microtubules are unlikely to contribute significantly to interphase cell rheology alone, but may help stabilize the other networks.     

Intermediate (10 nm) filaments in human malignant mesothelioma.

Human malignant mesotheliomas were studied by electron microscopy. Three main types of cells were seen--submesothelial epithelioid cells, epithelial lining cells and fibroblast-like cells. In submesothelial epithelioid cells prominent arrays of intermediate (10 nm) filaments were often seen attached to plasma membrane, mitochondria, nuclei and concentric whorls of rough endoplasmic reticulum. The other types of cell found in the tumors, epithelial lining cells and fibroblast-like cells, lacked such distinct filaments. The intermediate filaments were especially abundant in cells with extensive whorling of endoplasmic reticulum. The association of intermediate filaments with such deranged cytoplasmic organization suggests that they play a role in the altered behavior of malignant cells.     

On the role of microfilaments in cell-shape-mediated growth control of lens epithelial cells

With regard to the fact that, in anchorage-dependent lens epithelial cells, DNA synthesis can be switched on and off by cell flattening and cell rounding, respectively, the state of the microfilaments has been followed by labelling actin with FL-phalloidin during cell-shape alterations. Cell flattening proved to be accompanied by both a structural organization of actin filaments into stress fibres and an enlargement of the area of the cell nucleus. Cell rounding, on the other hand, caused the microfilament bundles to disappear and the area of the nucleus to become smaller. From the time course of the inhibition of DNA synthesis by cytochalasin B, it was inferred that functionally intact microfilaments are required for the entrance of the cells into DNA synthesis but not for the maintenance of ongoing DNA synthesis. The assumption has been made that the tension, generated by microfilaments during cell spreading, will affect the state of the plasma membrane as well as the shape and the structure of the nucleus, which in turn seems to be preparatory for cells to enter the cycle.     

Stress-induced alignment of actin filaments and the mechanics of cytogel

Experimental evidence suggests that anisotropic stress induces alignment of intracellular actin filaments. We develop a model for this phenomenon, which includes a parameter reflecting the sensitivity of the microfilament network to changes in the stress field. When applied to a uniform cell sheet at rest, the model predicts that for sufficiently large values of the sensitivity parameter, all the actin filaments will spontaneously align in a single direction. Stress alignment can also be caused by a change in external conditions, and as an example of this we apply our model to the initial response of embryonic epidermis to wounding. Our solutions in this case are able to reflect the actin cable that has been found at the wound edge in recent experiments; the cable consists of microfilaments aligned with stress at the wound boundary of the epithelium. These applications suggest that stress-induced alignment of actin filaments could play a key role in some biological systems. This is the first attempt to include the alignment phenomenon in a mechanical model of cytogel.     

Novel redistribution of myosin-containing filaments in cultured keratinocytes identified by a human monoclonal autoantibody

Summary A time-dependent redistribution of microfilaments was observed in cultured human keratinocytes using a human monoclonal autoantibody specific for myosin. Immunofluorescent staining revealed that 5 days after plating keratinocytes in either 0.1 mM or 2.0 mM Ca⁺⁺, myosin was distributed uniformly throughout the cytoplasm. At day 6, parallel arrays of myosin-containing microfilaments were prominent in the cell peripheries. At day 7 the microfilaments formed circumferential rings. The distribution of the microfilaments was disrupted by cytochalasin but not by colchicine, indicating that this novel distribution of myosin was not dependent on colchicine-sensitive vimentin intermediate filaments. The time-dependent redistribution of myosin was not influenced by cell population density, cell shape or cell cycle phase, except for mitotic cells in which myosin was distributed diffusely through the cytoplasm. If, as suggested by Kolega (9), microfilaments align parallel to the direction of applied tension, the redistribution of myosin-containing microfilaments in cultured keratinocytes may reflect the increased tension between cells resulting from increasing strength of cell-cell junctions over time. In sectioned human skin, myosin was localized in the peripheral cytoplasm of stratified epidermal cells. Tensions arising from the numerous desmosomal junctions between cellsin vivo could account for this distribution of myosin. Supported by grant NS-23537 (V. A. L.) from the National Institutes of Health, Bethesda, MD, and by the Mayo Foundation. C. L. W. is recipient of the Kermit E. Osserman and Blanche McClure Fellowship, 1987, National Myasthenia Gravis Foundation.     

On the Role of Microfilaments In Cell-Shape-Mediated Growth Control of Lens Epithelial Cells

With regard to the fact that, in anchorage-dependent lens epithelial cells, DNA synthesis can be switched on and off by cell flattening and cell rounding, respectively, the state of the microfilaments has been followed by labelling actin with FL-phalloidin during cell-shape alterations. Cell flattening proved to be accompanied by both a structural organization of actin filaments into stress fibres and an enlargement of the area of the cell nucleus. Cell rounding, on the other hand, caused the microfilament bundles to disappear and the area of the nucleus to become smaller. From the time course of the inhibition of DNA synthesis by cytochalasin B, it was inferred that functionally intact microfilaments are required for the entrance of the cells into DNA synthesis but not for the maintenance of ongoing DNA synthesis. the assumption has been made that the tension, generated by microfilaments during cell spreading, will affect the state of the plasma membrane as well as the shape and the structure of the nucleus, which in turn seems to be preparatory for cells to enter the cycle.     

The role of myosin II motor activity in distributing myosin asymmetrically and coupling protrusive activity to cell translocation

Nonmuscle myosin IIA and IIB distribute preferentially toward opposite ends of migrating endothelial cells. To understand the mechanism and function of this behavior, myosin II was examined in cells treated with the motor inhibitor, blebbistatin. Blebbistatin at > or = 30 microM inhibited anterior redistribution of myosin IIA, with 100 microM blebbistatin causing posterior accumulation. Posterior accumulation of myosin IIB was unaffected. Time-lapse cinemicrography showed myosin IIA entering lamellipodia shortly after their formation, but failing to move into lamellipodia in blebbistatin. Thus, myosin II requires motor activity to move forward onto F-actin in protrusions. However, this movement is inhibited by myosin filament assembly, because whole myosin was delayed relative to a tailless fragment. Inhibiting myosin's forward movement reduced coupling between protrusive activity and translocation of the cell body: In untreated cells, body movement followed advancing lamellipodia, whereas blebbistatin-treated cells extended protrusions without displacement of the body or with a longer delay before movement. Anterior cytoplasm of blebbistatin-treated cells contained disorganized bundles of parallel microfilaments, but anterior F-actin bundles in untreated cells were mostly oriented perpendicular to movement. Myosin II may ordinarily move anteriorly on actin filaments and pull crossed filaments into antiparallel bundles, with the resulting realignment pulling the cell body forward.     

Differentiation of rat lens epithelial cells in tissue culture. II. Effects of cytochalasins B and D on actin organization and differentiation

Cytochalasins B and D were used to investigate the involvement of microfilaments in the differentiation of rat lens epithelial cells in tissue culture. Two questions were asked: (1) Does the organization of microfilaments change upon morphological differentiation of the lens epithelial cell? (2) Is the change in the organization of microfilaments required for the production of the differentiation-specific protein, γ-crystallin? Cytochalasin B arborized differentiating lens epithelial cells and had no effect on the undifferentiated cells. Immunofluorescent staining of these two types of cells revealed significant differences in the organization of actin. Actin appeared as longitudinal filaments in the differentiating cells, while it appeared in a diffuse nonfibrillar form in the undifferentiated cells. This indicated changes in the organization of actin during differentiation. Cytochalasin B caused a decline in cell number at 10^?6–10^?5M. However, only that concentration which caused arborization of cells and disruption of microfilaments (10^?5M) inhibited morphological differentiation and production of γ-crystallin. Cytochalasin D (10^?7–10^?5M) did not cause a dramatic decrease in cell number; nevertheless, it induced the arborization of cells and disruption of microfilaments at lower concentrations (10^?7–10^?6M) and inhibited morphological differentiation and production of γ-crystallin at lower concentrations (10^?7–10^?6M) than did cytochalasin B. Thus, only those concentrations of cytochalasins which disrupt microfilaments and prevent their organization into filamentous form seem to inhibit differentiation. This suggests that the organization of actin is required for the program of differentiation of the lens epithelial cells.     

The internal affairs of an integrin

Integrins are adhesion receptors that exchange signals between the extracellular and intracellular compartments. From their cell surface transmembrane location, they interact with extracellular matrix ligands or cellular counter-receptors, translating external cues into signals that affect cytoskeletal organization, cell shape and motility. Conversely, intracellular events may modify the affinities of integrins for external ligands. Inside the cell, integrins connect with cytoskeletal structures that, until recently, were thought to be exclusively actin microfilaments. We comment on the case of the epithelial integrin, alpha(6)beta(4), which may instead interact with intermediate filaments. This integrin was recently shown by several laboratories to be part of the hemidesmosome complex, an epithelial adhesive structure that is the plasma membrane anchoring site for keratin-containing intermediate filaments.     

Alignment of desmosomes in stratifying human epidermis

Summary Cultured human epithelial cells stained with antibody to desmosomal proteins by indirect immunofluorescence showed linear arrays of desmosomes en face between stratified cells. To confirm that an extensive linear pattern existed on the cell surface, subconfluent cultures were viewed using scanning electron microscopy. Aligned arrays of blunt protrusions lying parallel to each other and extending in the direction of the long axis of the cell were observed on the surface of groups of superficial cells in intact cultures. That this pattern was indeed related to desmosomal distribution was verified by transmission microscopy of thin sections cut in a plane between the upper and lower surfaces of flattened stratified cells to view desmosomes directly. A similar arrangement of desmosomes was seen in intact tissue, using epidermal sheets separated from newborn foreskin. The same pattern found in flattened cells was sometimes apparent in more rounded basal cells where the cytoplasm was beginning to extend. Since desmosomal plaques are associated with keratin filaments, the alignment of desmosomes must occur in association with cytoskeletal changes as cells become flattened toward the distal epithelial surface. The primary initiation of desmosomal alignment remains to be investigated. However, the present findings demonstrate an increasingly regular membrane-cytoskeletal spatial interaction as stratified epithelial cells of skin mature.     

Morphological evidence for the existence of a more complex cytoskeleton in Amoeba proteus

Summary Various stabilization and extraction procedures were tested to demonstrate the ultrastructural organization of the cytoskeleton in normal, locomoting Amoeba proteus. Most reliable results were obtained after careful fixation in glutaraldehyde/lysine followed by prolonged extraction in a polyethylene glycol/Triton X-100 solution. Before dehydration in a graded series of ethanol and critical-point drying, the amoebae were split by the sandwich-technique, i.e., by mechanical cleavage of cells mounted between two poly-L-lysine-coated glass slides. Platinum-carbon replicas as well as thin sections prepared from such cell fragments revealed a cytoskeleton composed of at least four different types of filaments: (1) 5–7-nm filaments organized as a more or less ordered cortical network at the internal face of the plasma membrane and probably representing F-actin; (2) 10–12-nm filaments running separately or slightly aggregated through the cytoplasm and probably representing intermediate filaments; (3) 24–26-nm filaments forming a loose network and probably representing microtubules; and (4) 2–4-nm filaments as connecting elements between the other cytoskeleton constituents. Whereas microfilaments are responsible for protoplasmic streaming and other motile phenomena, the function of intermediate filaments and cytoplasmic microtubules in amoebae is still obscure.     

Fine structure of bovine lens epithelial cells in vitro in relation to modifications induced by a retinal extract (EDGF)

Cultured bovine lens epithelial cells are polygonal in shape. In confluent and multilayer cultures they exhibit elaborate arrays of 6 nm filaments, bundles of intermediate-sized filaments, and a fibrous meshwork of subcellular and intercellular material. Cells grown in the presence of a retinal extract (RE) have a higher growth rate, and are smaller and more regular in shape. In them the 6 nm filaments are mostly aligned in sheets, the intermediate-sized filaments form a fine network, and the cells are closely apposed to the plastic substratum. Some homogeneous material is formed intercellularly in older cultures. Cellular elongation, induced in the former cultures by the addition of RE, is accompanied by an alignment of cytoskeletal elements, including microtubules, parallel to the long axis. Other structural features are similar in all cell types. The response to RE is discussed in terms of shape modulations associated with the restricted expression of structural characteristics acquired in vitro.     

Human leukocytes as viewed by stereo high-voltage electronmicroscopy

Whole-mount preparations of adherent leukocytes were investigated by stereo high-voltage electronmicroscopy (HVEM) to determine the organization of the cytoplast in unstimulated, motile, and phagocytosing cells. A highly ordered structured cytoplast is revealed. All cytoplasmic organelles are held within an intricate network of fine strands, termed the microtrabecular lattice (MTL), which appears more complex in neutrophils than eosinophils or monocytes. In neutrophils, the tendency of the MTL to expand and contract during cell movement and the responding deformability of the granules appear to influence granule shape. This pleomorphism in granule shape is particularly prominent in exceptionally elongated neutrophils that have not established directionality and demonstrate the appearance of having two leading lamellipodia. Results suggest that the morphology of neutrophil granules is influenced by cell motility, and may account for the pleomorphic populations of granules observed by standard transmission EM. Examination of the cytoskeleton of these elongated cells after detergent extraction reveals separation of the centrosome into two solitary centrioles, with each centriole surrounded by an aster of microtubules. A complex network of microfilaments, intermediate filaments, and microtubules is integrated within a thin area of cytoplasm separating the two cell bodies. Interaction between the MTL, microfilaments, intermediate filaments, and microtubules probably influences granule translocation in these elongated cells. Phagocytosis stimulates a reorganization of the cytoplast; all organelles are found in more central areas of the cytoplasm, bordered by a thin area of hyaloplasm. The MTL appears to limit cytoplasmic granules to a compartment around phagocytic vacuoles, which probably provides the framework for efficient phagolysosome fusion.     

丁酸对体外培养的人鼻咽癌上皮细胞的影响

无论是自发的、病毒引起的或致癌物诱发的恶性转化的哺乳类细胞的体外培养,其形态多发生改变,总是变得近似圆形,边缘突起短而少,细胞致密和折光性强,同时失去生长接触抑制,降低细胞与细胞之间和细胞与生长底物之间的粘着性等特性。近年报道了关于短链脂肪酸如丁酸(或丁酸钠)对细胞能产生明显的影响,能抑制培养细胞的分裂,可诱发一些上皮性细胞产生形态的改变,可使转化的细胞     

Possible involvement of microtubules and microfilaments of the epididymal epithelial cells in 17beta-estradiol synthesis

The rat epididymal epithelial cells revealed features of steroidogenic cells and released 17beta-estradiol (E2) into the culture medium. In steroidogenic cells, elements of the cytoskeleton due to their influence on organelle distribution are implicated in the regulation of steroidogenesis. In the present study, the morphology of cultured epididymal epithelial cells in light, scanning and transmission electron microscopes was evaluated. The organization of microtubules and microfilaments revealed by fluorescence microscopy, and the concentration of E2 in cultured medium were also studied. The epididymal epithelial cells were cultured in different conditions: in the medium with or without exogenous testosterone (T) and in the co-culture with Leydig cells as a source of androgens. The cells in co-culture located close to Leydig cells were rich in glycogen, PAS-positive substances and lipid droplets, in higher amount than the cells cultured with addition of exogenous testosterone. Stress fibers and microtubules of epididymal epithelial cells cultured with exogenous T and in co-culture with Leydig cells presented typical structure, and numerous granular protrusions appeared on the surface of the cells. Disorganization of microtubules and shortening of stress fibers as well as the smooth cell surface deprived of granular protrusions were observed in the epididymal epithelial cells cultured without T. Change of the cytoskeleton organization caused by the absence of androgen in culture medium resulted in an increased E2 secretion.     

Insoluble gamma-tubulin-containing structures are anchored to the apical network of intermediate filaments in polarized CACO-2 epithelial cells.

We have previously shown that a thin ( approximately 1 microm) layer of intermediate filaments located beneath the apical membrane of a variety of simple epithelial cells participates in the organization of apical microfilaments and microtubules. Here, I confirmed the apical distribution of gamma-tubulin-containing structures (potential microtubule-organizing centers) in CACO-2 cells and demonstrated perfect colocalization of centrosomes and nearly 50% of noncentrosomal gamma-tubulin with apical intermediate filaments, but not with apical F-actin. Furthermore, the antisense-oligonucleotide-mediated downregulation of cytokeratin 19, using two different antisense sequences, was more efficient than anticytoskeletal agents to delocalize centrosomes. Electron microscopy colocalization suggests that binding occurs at the outer boundary of the pericentriolar material. Type I cytokeratins 18 and 19 present in these cells specifically coimmunoprecipitated in multi-protein fragments of the cytoskeleton with gamma-tubulin. The size and shape of the fragments, visualized at the EM level, indicate that physical trapping is an unlikely explanation for this result. Drastic changes in the extraction protocol did not affect coimmunoprecipitation. These results from three independent techniques, indicate that insoluble gamma-tubulin-containing structures are attached to apical intermediate filaments.     

Mechanical tension induces lateral movement of intramembrane components of the tight junction: studies on mouse mammary cells in culture

Occluding junctions of mammary epithelial cells in nonproliferating primary culture occasionally display an atypical pattern of intramembrane strands oriented predominantly perpendicular, instead of roughly parallel, to the apical border of the junction. To test whether the orienting influence was a centripetal cytoskeletal tension often observed in epithelial sheets on fixed substrates, we seeded cells at low density; this allows them to spread maximally while forming a barely confluent pavement. The result was a fourfold increase in the percentage of junctions with the strongly aligned, atypical pattern. Closely similar configurations were observed as the earliest detectable effect of chelation of extracellular Ca++, which induced pronounced centripetal contraction of the cell body. Externally imposed tension, applied so as to stretch cells in one direction only, affected the positions of strands in stretched junctions as might be predicted, by flattening their undulations, increasing their alignment parallel to the apical border. Thus mechanical tension alone, whether inherent in the cytoskeleton or imposed on the cell surface by exogenous force, can cause coordinate lateral displacement of macromolecular assemblies within the membranes of both joined cells.