The intermediate-sized filaments in rat kangaroo PtK2 cells. II. Structure and composition of isolated filaments.

When cultured cells of the rat kangaroo cell line PtK2 grown on plastic or glass surfaces are lysed and extracted with combinations of low and high salt buffers and the non-ionic detergent Triton X-100 cytoskeletal preparations are obtained that show an enrichment of 6 to 11 nm thick filaments. The arrays of these filaments have been examined by various light and electron microscopic techniques, including ultrathin sectioning, whole mount transmission electron microscopy, negative staining, and indirect immunofluorescence microscopy. In addition, 6 to 11 nm filaments isolated from these cells with similar extraction procedures and with centrifugation techniques have been examined by electron microscopy. The arrays of these isolated intermediate-sized filaments, their ultrastructure and their specific decoration by certain antibodies present in normal rabbit sera as well as by guinea pig antibodies against purified bovine prekeratin is demonstrated. When preparations enriched in these intermediate-sized filaments are examined by SDS-polyacrylamide gel electrophoresis a corresponding enrichment of three polypeptide bands with apparent molecular weights of about 45 000, 52 000 and 58 000 (the latter component sometimes appears split into two bands) is observed, besides some residual actin and a few high molecular weight bands. The morphology of the isolated filaments, their immunological reaction with antibodies decorating prekeratin-containing structures, and the sizes of their constitutive polypeptides suggest that these filaments are closely related to prekeratin-containing filaments observed in a variety of epithelial cells.     

Intermediate-sized filaments present in Sertoli cells are of the vimentin type.

The cytoplasmic structure of Sertoli cells of rat testes has been studied by electron microscopy of ultrathin sections. Sertoli cells contain numerous intermediate-sized (7-11 nm) filaments which form a meshwork extending throughout the whole cytoplasm. Often the frequency of such filaments appears especially high in juxtanuclear and cortical regions, including the apical recesses containing the spermatids. Examination of frozen sections of testes by indirect immunofluorescence microscopy using guinea pig antibodies to prekeratin and vimentin has shown the absence of intermediate-sized filaments of the cytokeratin type in all cells of the testes but the presence of filaments of the vimentin type in Sertoli cells as well as in cells of the interstitial space. These results show that the intermediate-sized filaments, abundant in Sertoli cells, are of the vimentin type. In addition we conclude that the "germ epithelium" differs from others true epithelia by the absence of cytokeratin filaments and typical desmosomes and, in Sertoli cells, the presence of vimentin filaments, suggestive of a mesenchymal character or derivation.     

Intermediate-sized filaments of the prekeratin type in myoepithelial cells

Myoepithelial cells from mammary glands, the modified sweat glands of bovine muzzle, and salivary glands have been studied by electron microscopy and by immunofluorescence microscopy in frozen sections in an attempt to further characterize the type of intermediate-sized filaments present in these cells. Electron microscopy has shown that all myoepithelial cells contain extensive meshworks of intermediate-sized (7--11-nm) filaments, many of which are anchored at typical desmosomes or hemidesmosomes. The intermediate-sized filaments are also intimately associated with masses of contractile elements, identified as bundles of typical 5--6-nm microfilaments and with characteristically spaced dense bodies. This organization resembles that described for various smooth muscle cells. In immunofluorescence microscopy, using antibodies specific for the various classes of intermediate-sized filaments, the myoepithelial cells are strongly decorated by antibodies to prekeratin. They are not specifically stained by antibodies to vimentin, which stain mesenchymal cells, nor by antibodies to chick gizzard desmin, which decorate fibrils in smooth muscle Z bands and intercalated disks in skeletal and cardiac muscle of mammals. Myoepithelial cells are also strongly stained by antibodies to actin. The observations show (a) that the epithelial character, as indicated by the presence of intermediate-sized filaments of the prekeratin type, is maintained in the differentiated contractile myoepithelial cell, and (b) that desmin and desmin-containing filaments are not generally associated with musclelike cell specialization for contraction but are specific to myogenic differentiation. The data also suggest that in myoepithelial cells prekeratin filaments are arranged--and might function--in a manner similar to the desmin filaments in smooth muscle cells.     

The intermediate-sized filaments in rat kangaroo PtK2 cells. I. Morphology in situ.

The system of the intermediate-sized filaments (IF) of rat kangaroo PtK2 cells which can be specifically demonstrated by immunofluorescence microscopy using certain rabbit autoantibodies and guinea pig antibodies against bovine hoof prekeratin has been studied by electron microscopy. The characteristic ornamental, curved arrays of this system are shown after fixation in situ in both thin sections and whole-cell-preparations to represent bundles of 6 to 11 nm thick filaments extending through the whole cytoplasm, although in some cells they appear to be enriched in the perinuclear region. While many individual IF are recognized in the cytoplasm the tendency of such filaments to aggregate laterally into bundles is one of their prominent features. Among such bundle formations one form that consists of tightly packed IF cemented together in a dense osmiophilic matrix is especially conspicious. The appearance and mode of arrangement of the IF is not significantly altered in cells treated with colcemid and/or cytochalasin B. Spatial relationships of IF with microfilament-containing cables and microtubules as well as with membranous structures are also described. IF are heterogeneous in width and reveal an unstained, apparently hollow core, indicative of a tubular organization. Many IF show small, sometimes periodically arranged lateral projections which seem to be involved in IF cross-linking. Associations with polyribosomes are common. The changes in the IF system during mitosis have also been examined. The structural details of the IF as well as their possible role as cytoskeletal elements involved in the control of cell shape and cytoplasmic architecture are discussed in relation to data on various intermediate-sized filaments from other cell types. The close similarity of the IF of PtK2 cells to aggregates of prekeratin filaments is emphasized. It is suggested that PtK2 cells represent an epithelial cell line growing in a state of balanced semi-keratinization.     

Simultaneous expression of two different types of intermediate sized filaments in mouse keratinocytes proliferating in vitro.

The intermediate-sized filaments present in epidermal keratinocytes derived from mouse skin and in an established cell line (HEL) derived from spontaneous transformation of murine keratinocytes grown in vitro, have been examined by immunofluorescence microscopy, using antibodies directed against subunit proteins of different classes of intermediate-sized filaments, as well as by electron microscopy and gel electrophoresis of cytoskeletal preparations highly enriched in intermediate-sized filaments. The keratinocytes derived from neonatal skin, which are capable of only limited replication in vitro, show only a single type of intermediate-sized filaments, i.e., the tonofibril-like arrays of filaments containing prekeratin. HEL cells, which proliferate indefinitely in vitro, retain the tonofilament-like structures typical of differentiated epidermal cells but in addition display intermediate-sized filaments of the vimentin type, i.e., the filament system typically found in mesenchymal and mesenchyme-derived cells. We discuss the possibility that (i) the advent of vimentin-type filaments in epidermal cells in culture is related either to the transformed state or the in vitro growth conditions as such and (ii) other differentiated epithelial cells proliferating in vitro may have more than one system of intermediate-sized filaments.     

Simultaneous Expression of Two Different Types of Intermediate Sized Filaments in Mouse Keratinocytes Proliferating in vitro

The intermediate-sized filaments present in epidermal keratinocytes derived from mouse skin and in an established cell line (HEL) derived from spontaneous transformation of murine keratinocytes grown in vitro, have been examined by immunofluorescence microscopy, using antibodies directed against subunit proteins of different classes of intermediate-sized filaments, as well as by electron microscopy and gel electrophoresis of cytoskeletal preparations highly enriched in intermediate-sized filaments. The keratinocytes derived from neonatal skin, which are capable of only limited replication in vitro, show only a single type of intermediate-sized filaments, i.e., the tonofibril-like arrays of filaments containing prekeratin. HEL cells, which proliferate indefinitely in vitro, retain the tonofilament-like structures typical of differentiated epidermal cells but in addition display intermediate-sized filaments of the vimentin type, i.e., the filament system typically found in mesenchymal and mesenchyme-derived cells. We discuss the possibility that (i) the advent of vimentin-type filaments in epidermal cells in culture is related either to the transformed state or the in vitro growth conditions as such and (ii) other differentiated epithelial cells proliferating in vitro may have more than one system of intermediate-sized filaments.     

Immunoelectronmicroscopic localization of extracellular matrix components produced by bovine corneal endothelial cells in vitro

Bovine corneal endothelial cells deposit an extracellular matrix in short-term cultures, which contains various morphologically distinct structures when analysed by electron microscopy after negative staining. Amongst these were long-spacing fibers with a 150 nm periodicity, which appeared also to be assembled into more complex hexagonal lattices. Another structure was fine filaments, 10-40 nm in diameter, which occasionally exhibited 67 nm periodic cross-striation. Non-striated 10-20 nm filaments sometimes formed radially oriented bundles arranged in networks and fuzzy granular material was associated with the filaments in the bundles. Often, these bundles extended into solitary filaments, 10-20 nm in diameter, with a smooth surface. In addition, amorphous patches were seen, which contained dense aggregates of fibrillar and granular material. In longer-term cultures, some of the structures coalesced to form large fibrillar bundles. By using specific antibodies to various extracellular matrix components and immunolabeling with gold some of these structures could be identified as to their protein composition. Whereas fibronectin antibodies labeled a variety of structures--fine filaments with granular materials, radially oriented bundles, patchy amorphous aggregates and small granular material scattered throughout the background--type III collagen antibody predominantly labeled filaments with periodic banding (10-40 nm in diameter). A small amount of type III specific labeling was also observed over the networks of radially oriented fibrils and fine filaments associated with granular material. Type IV collagen and laminin antibodies localized in areas of the patchy amorphous aggregates. Type VI collagen antibodies, on the other hand, labeled fine filaments and the gold particles showed a pattern of 100 nm periodicity. Many of the fine 10-20 nm filaments exhibited a tubular appearance on cross-section, but they were not reactive with any of the antibodies used. Also negative were the long-spacing fibers and assemblies--including hexagonal lattices--containing this structural element.     

Caldesmon is necessary for maintaining the actin and intermediate filaments in cultured bladder smooth muscle cells

Caldesmon (CaD), a component of microfilaments in all cells and thin filaments in smooth muscle cells, is known to bind to actin, tropomyosin, calmodulin, and myosin and to inhibit actin-activated ATP hydrolysis by smooth muscle myosin. Thus, it is believed to regulate smooth muscle contraction, cell motility and the cytoskeletal structure. Using bladder smooth muscle cell cultures and RNA interference (RNAi) technique, we show that the organization of actin into microfilaments in the cytoskeleton is diminished by siRNA-mediated CaD silencing. CaD silencing significantly decreased the amount of polymerized actin (F-actin), but the expression of actin was not altered. Additionally, we find that CaD is associated with 10 nm intermediate-sized filaments (IF) and in vitro binding assay reveals that it binds to vimentin and desmin proteins. Assembly of vimentin and desmin into IF is also affected by CaD silencing, although their expression is not significantly altered when CaD is silenced. Electronmicroscopic analyses of the siRNA-treated cells showed the presence of myosin filaments and a few surrounding actin filaments, but the distribution of microfilament bundles was sparse. Interestingly, the decrease in CaD expression had no effect on tubulin expression and distribution of microtubules in these cells. These results demonstrate that CaD is necessary for the maintenance of actin microfilaments and intermediate-sized filaments in the cytoskeletal structure. This finding raises the possibility that the cytoskeletal structure in smooth muscle is affected when CaD expression is altered, as in smooth muscle de-differentiation and hypertrophy seen in certain pathological conditions.     

Intermediate-sized filaments of human endothelial cells.

Human endothelial cells prepared from unbilical cords are characterized in parallel by electron microscopy and indirect immunofluorescence microscopy using specific antibodies against different classes of intermediate-sized filaments. The strongly developed, loose bundles of intermediate-sized filaments typically found in these cells are not decorated by antibodies against prekeratin or antibodies against smooth muscle desmin. They are, however, strongly decorated by antibodies directed against murine "vimentin," i.e., the 57,000 mol wt polypeptide which is the major protein of the intermediate-sized filaments predominant in various cells of mesenchymal origin. Cytoskeletal preparations greatly enriched in intermediate-sized filaments show the enrichment of a polypeptide band comigrating with murine vimentin. This shows that the intermediate-sized filaments that are abundant in human endothelial cells are predominantly of the vimentin type and can be demonstrated by their cross-reaction with the vimentin of rodents. These data also strengthen the evidence for several subclasses of intermediate-sized filaments, which can be distinguished by immunological procedures.     

Reconstitution of intermediate filaments from a higher plant.

Immunological studies have shown that plants contain intermediate-filament antigens, but it is not known whether these proteins are capable in themselves of forming filaments. To address this problem, a detergent-resistant and high-salt-insoluble fraction from carrot (Daucus carota L.) suspension cells was solubilized with 9 M-urea and then subjected to a two-step dialysis procedure, devised for the reconstitution of animal intermediate filaments. This induced the self-assembly of 10 nm filaments and large bundles of filaments. The predominant components of reconstituted material were polypeptides with apparent molecular masses between 58 and 62 kDa. These polypeptides immunoblotted with two monoclonal antibodies known to show broad cross-reactivity with intermediate filaments across the phylogenetic spectrum. This establishes that the antigens are able to self-assemble into intermediate-sized filaments.     

Helically twisted filaments in giant neurons of a whip spider.

In giant neurons of whip spider legs several filament types are detectable: filaments of 5 to 6 nm thickness as dense masses within the soma of the neuron, an intermediate-sized filament type limited to the dendritic processes forming irregularly wound bundles and finally twisted double filaments in the soma as well as in peripheral regions. The latter are usually aggregated in paracristalloid lattices of different length and diameter.     

Direct demonstration of the presence of two immunologically distinct intermediate-sized filament systems in the same cell by double immunofluorescence microscopy: Vimentin and cytokeratin fibers in cultured epithelial cells

The epithelial derived cell lines PtK2 and HeLa were characterized by double immunofluorescence microscopy using purified antibodies against vimentin and prekeratin. The results show that both cell types express simultaneously two immunologically distinct intermediate-sized filaments. Use of colcemid-treated cells confirms that the vimentin fibers and not the keratin-related fibers are rearranged into coils around the nucleus. In some cells staining of fibrous fragments is observed, which are perhaps involved in the synthesis or breakdown of this class of filaments. The concept that growing cells derived from differentiated cell types express not only the intermediate-sized filament system typical of the differentiated cell type but in addition contain intermediate-sized filaments of the vimentin type is discussed.     

Widespread occurrence of intermediate-sized filaments of the vimentin-type in cultured cells from diverse vertebrates.

Specific antibodies against vimentin, the major constitutive protein of intermediate-sized filaments present in cytoskeletons of mesenchymal cells of vertebrates, have been raised in guinea pigs. Antibodies to murine and human vimentin are of three types. The first two types produced against murine vimentin show an exclusive or preferential reaction with vimentin filaments of rodents. The third type raised against murine or human vimentin reacts with intermediate-sized filaments in species as diverse as mammals, birds and amphibia. This latter type is used here to show, both by immunoreplica techniques and by immunofluorescence microscopy, that almost all vertebrate cells growing in culture contain filaments of the vimentin type which are usually present in extended arrays. These immunological findings also suggest that the vimentin molecule contains both sequences conserved during evolution and regions different in different vertebrate species. The cells studied include not only cells of mesenchymal origin, but also cells derived from epithelia, in which it is now possible to demonstrate extensive arrays of vimentin filaments in interphase cells as well as intermediate-sized filaments of the prekeratin type. The data are consistent with the idea that most cells grown in culture contain intermediate-sized filaments of the vimentin type, irrespective of the state of differentiation of the cells from which they are derived.     

Relationships Between Cytoplasmic Filaments and Nuclear Envelope in Teleost (Pimelodus maculatus) Endothelial Cells

In the present report a characteristic pattern showed by cytoplasmic filaments (intermediate-sized and actin-like) in the perinuclear area of a freshwater teleost (Pimelodus maculatus) endothelial cells is described for the first time. Thus, many intermediate-sized filaments are directly inserted in the nuclear envelope, but others are connected to one another and to the nucleus through microfilaments. It is suggested that these particular relationships between the nucleus and cytoplasmic filaments are responsible not only for nuclear anchorage, but also for nuclear movements     

Molecular architecture of the neurofilament. II. Reassembly process of neurofilament L protein in vitro

Reassembly of the neurofilament (NF) in vitro was studied by low-angle rotary shadowing electron microscopy. Various intermediate stages of the reassembly were reconstructed from the smallest molecular mass subunit (NF-L) under controlled reassembly conditions. NF-L in 6 M-urea took the form of spherical particles with a diameter of about 12 nm. NF-L aggregated into rodlets of 70 to 80 nm long in a low-salt solution at alkaline pH. By reducing the pH of the dialyzing solution to 6.6, a pair of rods was formed by association side-by-side. Increasing the temperature of low-salt solutions from 4 degrees C to 35 degrees C did not produce intermediate-sized filaments. The addition of Mg2+ to the dialyzing solution resulted in the formation of short intermediate-sized filaments even at 4 degrees C. Further dialysis of the short intermediate-sized filaments against reassembly solution containing both NaCl and MgCl2 at 37 degrees C failed to elongate them into longer filaments, suggesting that annealing does not contribute to the elongation of neurofilaments. Different roles for Mg+ and NaCl in neurofilament reassembly were indicated. While Mg2+ strengthened the lateral association between 70 to 80 nm rods, NaCl appeared to promote the end-to-end association of filaments preferentially. Longer filaments were formed by increasing the NaCl concentration. By dialyzing NF-L against a buffer containing 50 mM-NaCl in the absence of Mg2+, unraveled filaments were formed. The many unraveled filaments were composed of four 8 nm wide filaments, which have been called the subfilament or the protofibril. Time-course experiments of the reassembly were performed in the absence of Mg2+, in which condition the rate of neurofilament reassembly appeared to be reduced. Star-like clusters, about four protofibrils joined together at one end, were suggested to be the initial stage of the intermediate-sized filament formation. The following two-step elongation mechanism of neurofilaments was deduced from these results. The pairs of rods were added to the ends of the protofibrils of neurofilaments, and after all four protofibrils were elongated they were then packed into neurofilaments. Distribution of larger molecular mass subunits, NF-M and NF-H, was studied. Addition of NF-M or NF-H to NF-L did not change the assembly properties of neurofilaments. Unraveled filaments reconstituted from NF-L plus either NF-M or NF-H indicated that NF-M and NF-H are incorporated evenly into each protofibril.     

Modulation of the Shape of Epithelial Lens Cells in vitro Directed by a Retinal Extract Factor

We have shown previously [1] that bovine epithelial lens cells can be stimulated to divide and elongate by a retinal extract (RE). In this report we show that the morphological response to the stimulatory factor is directly related to the target-cell shape, and we describe how the cell shape can be modulated into morphologically different types. If the cells are grown continuously from the explant in the presence of the RE factor, they keep a typical regular pavement-like epithelial shape (type I), even after serial passages. If the same cells are cultured in the absence of the factor, they become extremely irregular in shape and enlarge enormously (type II), and during serial passage elongate spontaneously to a fibroblast-like pattern. However, when type II cells are stimulated by RE, they elongate dramatically into type III cells as described in [1], provided they are stimulated at the optimal cell density. We show that the transformation of one type to another is directly under the control of RE, and we demonstrate that the changes in cell morphology are accompanied by alterations in cytoplasmic actin filaments. Type I cells contain few microfilaments, while type II cells display actin-tropomyosin polygonal fibre networks that reform during conversion to type III cells and then to elongated stress fibres. The change from type I to type II cells is also accompanied by massive accumulation of surface-associated fibronectin. We conclude that factors obtained directly from the eye have a direct ability to control morphology and proliferation of ocular cells like lens cells perhaps by modulation of cellular adhesiveness mediated by surface fibronectin and reorganization of cytoplasmic actin-based filaments.     

Diversity of cytokeratins. Differentiation specific expression of cytokeratin polypeptides in epithelial cells and tissues

Epithelial cells contain a cytoskeletal system of intermediate-sized (7 to 11 nm) filaments formed by proteins related to epidermal keratins (cytokeratins). Cytoskeletal proteins from different epithelial tissues (e.g. epidermis and basaliomas, cornea, tongue, esophagus, liver, intestine, uterus) of various species (man, cow, rat, mouse) as well as from diverse cultured epithelial cells have been analyzed by one and two-dimensional gel electrophoresis. Major cytokeratin polypeptides are identified by immunological cross-reaction and phosphorylated cytokeratins by [³²P]phosphate labeling in vivo.It is shown that different epithelia exhibit different patterns of cytokeratin polypeptides varying in molecular weights (range: 40,000 to 68,000) and electrical charges (isoelectric pH range: 5 to 8.5). Basic cytokeratins, which usually represent the largest cytokeratins in those cells in which they occur, have been found in all stratified squamous epithelia examined, and in a murine keratinocyte line (HEL) but not in hepatocytes and intestinal cells, and in most other cell cultures including HeLa cells. Cell type-specificity of cytokeratin patterns is much more pronounced than species diversity. Anatomically related epithelia can express similar patterns of cytokeratin polypeptides. Carcinomas and cultured epithelial cells often continue to synthesize cytokeratins characteristic of their tissue of origin but may also produce, in addition or alternatively, other cytokeratins. It is concluded: (1) unlike other types of intermediate-sized filaments, cytokeratin filaments are highly heterogeneous in composition and can contain basic polypeptides: (2) structurally indistinguishable filaments of the same class, i.e. cytokeratin filaments, are formed, in different epithelial cells of the same species, by different proteins of the cytokeratin family; (3) vertebrate genomes contain relatively large numbers of different cytokeratin genes which are expressed in programs characteristic of specific routes of epithelial differentiation; (4) individual cytokeratins provide tissue- or cell type-specific markers that are useful in the definition and identification of the relatedness or the origin of epithelial and carcinoma cells.     

De novo synthesis and specific assembly of keratin filaments in nonepithelial cells after microinjection of mRNA for epidermal keratin

Poly(A)+ RNA isolated from bovine muzzle epidermis was microinjected into nonepithelial cells containing only intermediate-sized filaments of the vimentin type. In recipient cells keratin polypeptides are synthesized and assemble into intermediate-sized filaments at multiple dispersed sites. We describe the time course and the pattern of de novo assembly of keratin filaments within living cells. These filaments were indistinguishable, by immunofluorescence and immunoelectron microscopic criteria, from keratin filament arrays present in true epithelial cells. The presence of extended keratin fibril meshworks in these injected cells is compatible with cell growth and mitosis. Double immunolabeling revealed that newly assembled keratin was not codistributed with microfilament bundles, microtubules or vimentin filaments. We suggest that assembly mechanisms exist which in vivo sort out newly synthesized cytokeratin polypeptides from vimentin.     

Constitutive aggregates of intermediate-sized filaments of the vimentin and cytokeratin type in cultured hepatoma cells and their dispersal by butyrate

Cloned hepatoma cells ($\text{72}\text{22}$) derived from the liver of a rat treated with the carcinogen, diethylnitrosamine, exhibit a genetically stable, large, acentric, juxtanuclear, hyaline aggregate of loosely packed intermediate-sized (7–11 nm) filaments, interspersed with variable but minor amounts of microtubules, polyribosomes and membranous structures. Immunofluorescence microscopy shows that the these filaments react specifically with antibodies to bovine prekeratin and to murine vimentin. The aggregates contain aster-like foci common to the arrangement of both tonofilament-like and vimentin-containing intermediate-sized filaments, although both filament systems show different fibrillar patterns in other cytoplasmic regions. While the cytokeratin filament system is not significantly altered during exposure to colcemid, the vimentin in the abnormal aggregate is rearranged during such treatment into extensive and complex perinuclear ‘whorls’ of filaments. Treatment of the cells with butyrate results in a markedly flattened, hepatocyte-like morphology, a reappearance of typical actin-containing ‘cables’, and a progressive disintegration of the filament aggregate concomitant with a normal display of filaments of both the cytokeratin and vimentin type. The results show that (i) some cells contain aggregates consisting of two different types of intermediate-sized filaments oriented onto a common focal center; (ii) such an abnormal filament arrangement is clonally stable; (iii) the vimentin-type filaments contained in such aggregates are still susceptible to the action of antimitotic drugs and can be rearranged into characteristic perinuclear whorls; and (iv) this abnormal aggregate of intermediate filaments can be reverted to normal patterns upon treatment of the cells with butyrate.     

Change of cytokeratin filament organization during the cell cycle: selective masking of an immunologic determinant in interphase PtK2 cells

The organization of intermediate-sized filaments (IF) of the cytokeratin type was studied in cultures of PtK2 cells in which typical IF structures are maintained during mitosis, using a monoclonal antibody (KG 8.13). This antibody reacts, in immunoblotting experiments, with the larger of the two major cytokeratin polypeptides present in these cells but, using standard immunofluorescence microscopy procedures, does not react with the cytokeratin filaments abundant in interphase cells, in striking contrast to various antisera and other monoclonal cytokeratin antibodies. In the same cell cultures, however, the antibody does react with cytokeratin filaments of mitotic and early postmitotic cells. The specific reaction with cytokeratin filaments of mitotic cells only is due to the exposure of the specific immunologic determinant in mitosis and its masking in interphase cells. Treatment of interphase cells with both Triton X-100 as well as with methanol and acetone alters the cytokeratin filaments and allows them to react with this monoclonal antibody. A similar unmasking was noted after treatment with buffer containing 2 M urea or low concentrations of trypsin. We conclude that the organization of cytokeratin, albeit still arranged in typical IF, is altered during mitosis of PtK2 cells.