Differences of expression of cytoskeletal proteins in cultured rat hepatocytes and hepatoma cells

Cytoskeletal elements, enriched in intermediate-sized filaments and insoluble in buffers of high salt concentrations and Triton X-100, were isolated from various cultures of rat hepatocytes and hepatoma cells, and their proteins were studied by one- and two-dimensional gel electrophoresis and immunofluorescence microscopy. The cells examined included several permanent cell lines (MH₁C₁, HTC, hepatoma 72/22, clone 12 from Gunn rat hepatocytes, and cell clones from normal rat hepatocytes), as well as freshly dissociated hepatocytes that were cultured and allowed to attach to substratum for increasing periods of time, beginning at 24 h after removal of the liver from the animal. Filaments containing vimentin, which were not found in hepatocytes grown in liver tissue, were detected in most of the cultured hepatocytes and hepatoma cells, except in MH₁C₁ cells, and were shown to be newly synthesized during the first days of primary culture. Maintenance of expression of filaments containing proteins immunologically related to epidermal prekeratin (‘cytokeratins’) was observed in all cells examined but HTC cells. Detailed comparison of the cytokeratin polypeptides present in various hepatocyte and hepatoma cell cultures showed that, in some of the cultured epithelial liver cells, cytokeratins are expressed which are identical with, or similar to, those of normal hepatocytes grown in the liver. On the other hand, differences in cytokeratin polypeptides were also found among different hepatocyte-derived cell cultures. Changes of expression of cytoskeletal proteins were found to occur even in cloned cell populations, and cells positive for certain cytokeratins could be seen next to other cells that were negative.The results demonstrate that profound changes of cytoskeletal composition, especially concerning intermediate filament protein patterns, can occur during culturing in vitro. Moreover, we show that different intermediate filament proteins can be expressed in different hepatocyte-derived cell cultures and that changes of cytoskeletal composition can occur in a given cell population, without obvious effects on cell growth rate and cell morphology. During culturing of hepatocytes and hepatoma cells, there seems to be a general tendency to induce the production of vimentin filaments as well as to maintain the production of cytokeratins similar to the hepatocyte-specific cytokeratins in liver tissue. However, the demonstrated exceptions speak against a role of these filament proteins as prerequisites for the growth of an epithelial cell in vitro. Rather, the presence of filaments containing certain cytokeratins and of desmosomes in epithelial cells growing in vitro seems to reflect the synthesis of specific differentiation markers which may be lost, independently, in some cells during culturing.     

Modulation of cytokeratin and actin gene expression and fibrillar organization in cultured rat hepatocytes.

Intermediate filaments of rat hepatocytes are composed of cytokeratins 8 and 18 (CK8 and CK18, respectively). Recent work from our laboratory has indicated a close relationship between the synthesis of these cytokeratins, their organization into intermediate filaments, and the promotion of growth and differentiation of cultured rat hepatocytes by insulin, epidermal growth factor, and dexamethasone. In the present study, we examined the mRNA expression, level of protein synthesis, and fibrillar distribution of cytokeratins 8 and 18 and actin in hepatocytes, isolated from normal and dexamethasone-injected rats and cultured as monolayers or spheroids in the presence of insulin, or from normal rat hepatocytes, cultured as monolayers in the presence of dexamethasone, insulin, and dimethyl sulfoxide. The CK8 mRNA level was lower in hepatocytes isolated from noninjected rats and cultured as either monolayers or spheroids, than in those from dexamethasone-injected rats. However, the CK18 mRNA level varied in a manner that was different from that of CK8 mRNA, showing that the modes of expression of the two genes were independent. The various changes in hepatocyte culture conditions led to variations in albumin mRNA levels that largely followed those observed in CK8 mRNA levels. In the case of actin, the amount of mRNAs varied from relatively high levels in hepatocyte monolayers to extremely low levels in hepatocyte spheroids, even though in both cases the cells were isolated from dexamethasone-injected rats. These changes in mRNA levels did not necessarily correlate with changes in the synthesis of cytokeratins 8 and 18, and actin. Changes in culture conditions induced a major reorganization in the distribution of cytokeratin intermediate filaments and actin filament between the region near the surface membrane and the cytoplasm. The most divergent patterns in cytokeratin intermediate filaments and actin filament distributions were observed between hepatocytes cultured as spheroidal aggregates and as monolayers in the presence of dimethyl sulfoxide. The former condition resulted in patterns of cytokeratin and actin gene expression and fibrillar organization that best matched those in situ. In the latter condition, inappropriate patterns were obtained, in spite of the fact that dimethyl sulfoxide treated hepatocytes are known to exhibit survival and functional activities equivalent to that of hepatocyte spheroids. These results demonstrate for the first time that the survival and functional activity (i.e., albumin production) of rat hepatocytes in vitro is not necessarily correlated with a particular pattern of cytokeratin and actin gene expression and fibrillar arrangement.     

The apoptotic process of human bladder carcinoma T24 cells induced by retinoid

Breakdown of the cytoskeletal network and redistribution of cytoplasmic organelles are early events of programmed cell death. Previous studies showed that retinoic acid induces programmed cell death in many tumor cell lines and that cytokeratins, particularly cytokeratin 18, are affected in the early events of apoptosis. In this study, patterns of cytoplasmic intermediate filaments (cytokeratin 18), actin filaments, and microtubules, as well as Bax and Bcl-2 proteins in human bladder carcinoma T24 cells were examined before and after retinoic acid treatment by immunocytochemistry and conventional electron microscopy. Our results demonstrate that the redistribution of Bax and Bcl-2 proteins in the subcellular compartment of T24 cells is correlated with reorganization of the cytoplasmic intermediate filament network and that cytokeratins are cleaved by caspases, as revealed by the M30 antibody which recognizes a specific caspase cleavage site within cytokeratin 18. The cytoskeletal architectures of microtubules are not significantly affected in the early apoptotic process, from our observations. We suggest that the breakdown in the intermediate filament network associated with the aggregation of mitochondria and lysosome may be a crucial event in the apoptotic process and that aggregation of cytoplasmic Bax may accelerate apoptotic death.     

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.     

Tissue type-specific expression of intermediate filament proteins in a cultured epithelial cell line from bovine mammary gland

Different clonal cell lines have been isolated from cultures of mammary gland epithelium of lactating cow’s udder and have been grown in culture media containing high concentrations of hydrocortisone, insulin, and prolactin. These cell (BMGE+H), which grow in monolayers of typical epithelial appearance, are not tightly packed, but leave intercellular spaces spanned by desmosomal bridges. The cells contain extended arrays of cytokeratin fibrils, arranged in bundles attached to desmosomes. Gel electophoresis show that they synthesize cytokeratins similar, if not identical, to those found in bovine epidermis and udder, including two large (mol wt 58,500 and 59,000) and basic (pH range: 7-8) and two small (mol wt 45,500 and 50,000) and acidic (pH 5.32 and 5.36) components that also occur in phosphorylated forms. Two further cytokeratins of mol wts 44,000 (approximately pH 5.7) and 53,000 (pH 6.3) are detected as minor cytokeratins in some cell clones. BMGE+H cells do not produce vimentin filaments as determined by immunofluorescence microscopy and gel electrophoresis. By contrast, BMGE-H cells, which have emerged from the same original culture but have been grown without hormones added, are not only morphologically different, but also contain vimentin filaments and a different set of cytokeratins, the most striking difference being the absence of the two acidic cytokeratins of mol wt 50,000 and 45,500. Cells of the BMGE+H line are characterized by an unusual epithelial morphology and represent the first example of a nonmalignant permanent cell line in vitro that produces cytokeratin but not vimentin filaments. The results show that (a) tissue-specific patterns of intermediate filament expression can be maintained in permanent epithelial cell lines in culture, at least under certain growth conditions; (b) loss of expression of relatively large, basic cytokeratins is not an inevitable consequence of growth of epithelial cells in vitro. Our results further show that, during culturing, different cell clones with different cytoskeletal composition can emerge from the same cell population and suggest that the presence of certain hormones may have an influence on the expression of intermediate filament proteins.     

Brush cells of rodent gallbladder and stomach epithelia express neurofilaments.

It has been suggested that brush cells (BCs), a distinct type of cell occurring in various epithelia of the respiratory and gastrointestinal tracts, may function as receptor cells. The major characteristics of BCs are a prominent brush border and an unusually highly ordered arrangement of cytoskeletal elements (F-actin, microtubules, and intermediate filaments). In this study we aimed to characterize the nature of the intermediate filaments in BCs by light and electron microscopic immunostaining. Gallbladder and stomach specimens from mice and rats, respectively, were fixed in various solutions, embedded either in paraffin or epoxy resin, and processed for immunodetection. Commercially available, well-characterized antibodies against neurofilaments, peripherin, and cytokeratin peptide 18 were used. The polyclonal antiserum cocktail to neurofilaments was applied as a supplement in a double-labeling procedure with anti-actin and anti-cytokeratin 18 antibodies. The results demonstrate that the BCs of both organs express two types of intermediate filaments, i.e., neurofilaments and cytokeratin 18 filaments, and that these have a compartmentalized distribution in the cytoplasm. BCs do not express peripherin. The immunodetection of intermediate filaments distinctive for mature neurons in BCs supports their putative receptor function. The co-expression of neurofilaments and cytokeratins is shown for the first time in healthy tissues.     

Modulation of milk protein synthesis through alteration of the cytoskeleton in mouse mammary epithelial cells cultured on a reconstituted basement membrane

Recent studies indicate that the cytoskeleton may be involved in modulating tissue-specific gene expression in mammalian cells. We have studied the role of the cytoskeleton in regulating milk protein synthesis and secretion by primary mouse mammary epithelial cells cultured on a reconstituted basement membrane that promotes differentiation. After 8 days in culture, cells were treated with cytochalasin D (CD) (0.5-1 micrograms/ml) to alter actin filaments or acrylamide (Ac) (5 mM) to alter intermediate filaments (cytokeratins). CD inhibited synthesis of most proteins in a concentration-dependent manner, with beta-casein being the first affected. In contrast, Ac increased protein synthesis and secretion by 17-31% after a 12 hr treatment. Polyacrylamide gel electrophoresis of total secreted proteins indicates that synthetic rates of most proteins were increased equally by Ac treatment. This increase is apparently controlled at the level of translation, because control and Ac-treated cells contained the same amount of poly-A+ RNA, and neither CD nor Ac altered mRNA levels for beta-casein. There was also no indication that either CD or Ac can induce the expression of milk proteins in quiescent cells cultured on a plastic substratum. In conjunction with the biochemical studies, changes in cytoskeletal morphology caused by the drug treatments were analyzed by immunofluorescence microscopy. As has been observed in other cell types, low concentrations of CD caused cells to round up by disrupting actin filaments. Ac treatment slightly decreased the intensity of actin staining, but no changes in microfilament organization were observed. Ac-treated cells showed slight disorganization of the cytokeratin filaments, with some peripheral interfibrillar bundling, but the cytokeratin network did not collapse and no retraction of cell extensions or breakdown of cell-cell contacts was observed. These results confirm previous reports that the actin cytoskeleton may play a role in regulating tissue-specific protein synthesis. How Ac stimulates protein synthesis is unknown, but it is unlikely that this effect is directly mediated through intermediate filaments.     

An epithelial cell line with elongated myoid morphology derived from bovine mammary gland : Expression of cytokeratins and desmosomal plaque proteins in unusual arrays

Cells of a clonal line (BMGE + HM) selected from bovine mammary gland epithelial cell cultures are described which, after reaching confluence, do not assume typical epithelioid morphology, but form elongated cells with long slender processes extending over the surfaces of other cells. However, cells of this line which display non-epithelioid morphology and are exceptionally rich in actin microfilaments are identified as epithelial cells by their synthesis of cytokeratins and desmosomal plaque proteins, as demonstrated by immunofluorescence and immunoelectron microscopy and by gel electrophoresis of cytoskeletal proteins. The cells do not produce vimentin and desmin filaments. The specific cytokeratin polypeptides of these myoid cells are identical to those present in normal epithelioid BMGE + H cells but are arranged in unusual arrays of meshworks of finely dispersed, non-fasciated filaments and granular structures. Desmosomal plaque proteins, notably desmoplakins, are abundant, but the electron microscopic appearance of the desmosomes is abnormal in that most of them are associated with a second accessory plaque formed at a distance of 0.1-0.15 micron from the normal desmosomal plaque. Both cytokeratin filaments and desmosomal structures are found throughout the whole cytoplasm, including the extended cell processes. The existence of an epithelial cell line with such an unusual morphology demonstrates the importance of non-morphological criteria in identifying epithelium-derived cells. Our findings also indicate that dramatic differences of cell shape and organization of epithelial cells need not necessarily be associated with changes in the expression of specific cytoskeletal proteins. The possible origin of this cell line from myoepithelial cells is discussed.     

Biochemical and immunological identification of cytokeratin proteins present in hepatocytes of mammalian liver tissue

Hepatocytes of mammalian liver are known to contain intermediate-sized filaments of tonofilament morphology. Unlike many other epithelial cells, including cultured hepatocytes and hepatoma cells, hepatocytes present in normal liver tissue have been reported not to react, in significant intensity, with various preparations of antibodies to human and bovine epidermal prekeratin [2,6]. We have therefore examined, by biochemical and immunological methods, the cytoskeletal composition of hepatocytes grown in the body.Cytoskeletal preparations from hepatocytes of mouse and rat liver tissue resistant to high salt buffer and Triton X-100 are enriched in tangles of intermediate filaments and contain, besides some residual microfilamentous actin, a characteristic set of polypeptides. One- and two-dimensional gel electrophoresis reveals the presence of two major cytokeratin components, which appear as ‘pairs’ of isoelectric variants (component A, M_r 55 000, apparent pI values, 6.40 and 6.45; component D, M_r 49000, apparent pI values 5.43 and 5.38), and five minor components (M_r range from 41000 to 53 000), most of them also as ‘pairs’ of polypeptides slightly different in isoelectric pH value. These polypeptide patterns are very similar in mouse and rat liver although some minor but significant differences have been noted between the two species. The polypeptide patterns of liver cytoskeletons are also similar to—but clearly not identical with—the cytoskeletal protein patterns observed in other epithelial tissues and cells, including various lines of cultured rat hepatocytes and hepatoma cells.Guinea pig antibodies raised against individual cytokeratin proteins of mouse liver and against certain prekeratin polypeptides present in desmosome-attached tonofilaments of bovine muzzle are described which differ from previously described prekeratin antibodies. These prekeratin antibodies not only react with filament bundles of the prekeratin type present in many cultured epithelial cells (e.g. murine HEL, human HeLa, rat kangaroo PtK2) and various epithelial tissues, but also allow the detection of the cytokeratin components present in parenchymal cells of liver and pancreas of various species, man included. Immunofluorescence microscopy on frozen sections of liver using these antibodies reveals a novel structure, i.e. a three-dimensional filament meshwork extending throughout the whole cytoplasm of the hepatocyte, with higher intensity of staining in pericanalicular regions.The results show that parenchymal cells of normal liver and pancreas contain filaments of the cytokeratin type that are related to but not identical with epidermal prekeratin. The hepatocyte filaments appear to be different from prekeratin-type filaments present in epidermis and several other epithelial cells, both in some antigenic determinants exposed and in polypeptide composition. Our findings support the concept of the existence of a family of intermediate filament proteins, cytokeratins, containing many different polypeptides that are expressed in different epithelial cells in certain characteristic subsets in a cell type-specific mode.     

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.     

Cytokeratin filament modulation in pulmonary microvessel endothelial cells by vasoactive agents and culture confluency.

Recently, bovine pulmonary microvascular endothelial cells (PMV) were shown to contain cytokeratin 8 and 19 intermediate filaments (Patton et al., 1990). In this study, we examine the effect of culture contiguity and vasoactive agents on the content and assembly of cytokeratins in PMV. Immunofluorescent staining of PMV cultures show a progressive increase in cytokeratin filament assembly. In freshly plated PMV, keratin appears as hazy staining (less than 4 hr) and later organizes into keratin 'plaques' (4 days) associated with cell-cell contacts; post confluent (greater than 7 days) PMV cultures contain fully assembled cytokeratin filaments which extend to the cell periphery and approach filaments in apposed cells. Vimentin filaments are also present in freshly plated PMV cultures but unlike cytokeratins, become less filamentous at confluency. This cell density-dependent modulation of cytokeratins is also demonstrated by densitometric analysis of autoradiographs of 35S-methionine labeled keratins in which PMV keratin content is elevated at high cell densities, while vimentin content remains constant. Desmoplakins I and II, components of desmosomes, could not be demonstrated in PMV by immunoblotting. PMV treated with permeability modulating agents (4 x 10(-3) M EGTA, 1 microM cytochalasin B, 1 microM bradykinin, 1 microM A23187, and 1 microM PMA) exhibit border retraction and altered keratin filament staining. From these studies we conclude: 1) cytokeratin 8 and 19 containing intermediate filaments are present in confluent PMV cultures with vimentin but without desmosomes, 2) the state of assembly of PMV cytokeratin and vimentin filaments appears to be oppositely affected by culture contiguity, and 3) treatment of monolayers with vasoactive agents alters the state of assembly of cytokeratin filaments. We speculate that modulation of cytokeratin assembly in PMV may be involved in regulation of pulmonary microvascular structure and function.     

Vimentin Filaments Follow the Preexisting Cytokeratin Network during Epithelial–Mesenchymal Transition of Cultured Neonatal Rat Hepatocytes

Changes in cell cytoskeleton are known to play an important role in differentiation and embryogenesis and also in carcinogenesis. Previous studies indicated that neonatal hepatocytes undergo an epithelial–mesenchymal transition when cultured in a serum-free medium for several days. Here we show by Western blotting of neonatal rat liver cells cultured for 3 days that vimentin and cytokeratin were expressed by these cells. Epidermal growth factor treatment induced high coexpression of vimentin and cytokeratin filaments in hepatocytes from neonatal livers, as detected by double immunofluorescence microscopy. Confocal scanning laser microscopy was used to determine the spatial and cell distribution of cytokeratin and vimentin intermediate filament networks. Vimentin-expressing hepatocytes were mainly located on the periphery of epithelial clusters and presented a migratory morphology, suggesting that vimentin expression was related to the loss of cell–cell contact. Short vimentin filaments were mainly located at the cytoplasmic sites behind the extending lamella. Horizontal and vertical dual imaging of double immunofluorescence with anti-vimentin and anti-cytokeratin antibodies indicated that both filaments colocalize strongly. Three-dimensional reconstruction of serial optical sections revealed that newly synthesized vimentin distributed following the preexisting cytokeratin network and, when present, both filament scaffolds codistributed inside cultured hepatocytes. Immunoelectron microscopy performed in whole-mount-extracted cultured cells revealed that both filaments are closely interrelated but independent. However, a high degree of immunogold colocalization was found in the knots of the filament network. Further experiments with colce- mide and cytochalasin treatment indicated that vimentin filament distribution, but not cytokeratin, was dependent on an intact microtubule network. These results are consistent with a mechanism of vimentin assembly, whereby growth of vimentin intermediate filaments is dependent on microtubules in topographically restricted cytoplasmic sites, in close relation to the cytokeratin cytoskeleton and to changes in cell–cell contact and cell shape.     

Synthesis and phosphorylation of cytoskeleton components in foetal,regenerating and adult normal rat hepatocytes during culture

Summary Detergent insoluble material (DIM) was prepared by gentle treatment with detergent from foetal, regenerating and adult normal rat hepatocytes cultured for various times. It retained to some degree the morphology of the cells. After incubation of intact cells with ³⁵S-methionine, most of the labelled DIM proteins were found to be components of the cytoskeleton. They included several cytokeratins, vimentin and actin. The synthesis rate varied with the age of animals and culture conditions. The high synthetic rate of vimentin in foetal and regenerating hepatocytes could be associated with cell proliferation. No correlation was found between cytokeratin synthesis and hepatocyte growth. Most of the cytoskeleton proteins could be phosphorylated in intact cells and in DIM from cultured hepatocytes. However the degree of phosphorylation of these proteins was not related to their synthetic rate. The decreased phosphorylation level in cultured adult rat hepatocytes could be related to the rapid loss of specific functions.     

Differential phosphorylation of CK8 and CK18 by 12-O-tetradecanoyl-phorbol-13-acetate in primary cultures of mouse hepatocytes.

The phosphorylation of cytokeratin was investigated in primary cultures of hepatocytes. The two hepatocyte cytokeratins CK8 and CK18 (55,000 and 49,000 M_r, respectively) were phosphorylated, CK8 being more phosphorylated than CK18. Treatment of the hepatocytes with 150 nM 12-O-tetradecanoyl-phorbol-13-acetate (TPA) an activator of protein kinase C induced a transient increase in the level of phosphorylation of CK8 but not CK18. This effect was maximal after 15 min of TPA treatment and was maintained for up to 3 h. After 22 h of treatment with TPA, which down-regulates protein kinase C, CK8 phosphorylation was returned to the basal level. Further addition of TPA to the 22-h treated cells did not cause an increase in CK8 phosphorylation. Indirect immunofluorescence microscopy with a monoclonal antibody to CK8 indicated that while the addition of TPA induced the formation of granular cytokeratin aggregates in some hepatocytes, in most hepatocytes no major changes in the intermediate filament network were observed. Staining for actin showed that actin microfilaments were rapidly reorganized after the treatment and a loss of stress fibres were observed. We propose that CK8 is an in vitro substrate for protein kinase C and that the specific phosphorylation of CK8 plays a role in protein kinase C signal transduction.     

Immunohistochemical distribution of simple-epithelial-type keratins and other intermediate filament proteins in the developing human pituitary gland

Summary An immunohistochemical study of the production of the intermediate filaments [vimentin, cytokeratin, and glial filament acidic protein (GFAP)] during development of the pituitary gland was made by use of fetal and adult human pituitary tissue. Among these intermediate filament proteins in the anterior and intermediate lobes of the pituitary, cytokeratin is the first to appear, followed by GFAP and vimentin. However, only cytokeratin is seen during the period of morphogenesis of the pituitary gland, with the type-II subfamily cytokeratin 8 being the earliest to appear. Among the simple-epithelial-type cytokeratins, cytokeratins 8 and 19 were observed within the pituitary primordium during morphogenesis. Cells immunoreactive for cytokeratins 8 and 19 showed a heterogeneous three-dimensional distribution pattern in Rathke's pouch. Both cytokeratins 8 and 19 tended to be strongly positive at sites in the pituitary primordium where cells had become more loosely arranged (i.e., areas far from the diencephalon) but were only weakly positive in areas in which the epithelial cells were densely packed (i.e., areas closely associated with the diencephalon). It is concluded that, during the period of morphogenesis, Rathke's pouch has the intermediate filaments characteristic of simple epithelium and shows different immunoreactivity for simple-epithelial-type cytokeratins from place to place according to the extent of cellular differentiation.     

Aggregation and loss of cytokeratin filament networks inhibit golgi organization in liver-derived epithelial cell lines

Intermediate filaments are one of the three major cytoskeletons. Some roles of intermediate filaments in cellular functions have emerged based on various diseases associated with mutations of cytokeratins. However, the precise functions of intermediate filament are still unclear. To resolve this, we manipulated intermediate filaments of cultured cells by expressing a mutant cytokeratin. Arginine 89 of cytokeratin18 plays an important role in intermediate filament assembly. The expression of green fluorescent protein-tagged cytokeratin18 arg89cys induced aggregations and loss of the intermediate filament network composed of cytokeratins in liver-derived epithelial cells, Huh7 and OUMS29, but only induced the formation of cytokeratin aggregates and did not affect the intermediate filament network of endogenous vimentin in HEK293. The expression of this mutant affected the distribution of Golgi apparatus and the reassembly of Golgi apparatus after perturbations by nocodazole or brefeldin A in both Huh7 and OUMS29, but not in HEK293. Our data show that loss of the original intermediate filament network, but not the existence of cytokeratin aggregates, induces redistribution of the Golgi apparatus. The original intact intermediate filament network is necessary for the organization of Golgi apparatus.     

Co-Expression of Cytokeratins and Vimentin in Sheep Cumulus-Oocyte Complexes. Alteration of Intermediate Filament Distribution by Acrylamide

The association between germ cells and somatic granulosa cells persists throughout the growth of the oocyte by means of foot processes of the cumulus corona cells that cross the zona pellucida. During meiotic maturation important nuclear and cytoplasmic events occur in cumulus-oocyte complex suggesting implication of cytoskeletal elements. Immunoblotting analysis of cytoskeletal proteins of the cumulus cells revealed the presence of vimentin polypeptide and of at least two cytokeratin polypeptides. Using immunofluorescence techniques on cryostat sections through frozen tissue, we provided evidence for the presence of cytokeratins of the simple epithelial type in addition to vimentin in sheep cumulus cells. These two types of intermediate filaments were localized throughout the cytoplasm and especially in the foot processes which cross the zona pellucida. The contact area between the two cell types was also labelled with the antibodies. Acrylamide treatment of cumulus-oocyte complexes involved a drastic disorganization of the intermediate filament network and triggered the isolation of the oocyte from its cumulus cells. This isolation resulted in resumption of meiosis. From these results it appears that intermediate filaments could participate in the process of gap junction loss and indirectly in the control of meiosis resumption.     

Intermediate filament proteins in nonfilamentous structures: Transient disintegration and inclusion of subunit proteins in granular aggregates

The intermediate filament cytoskeleton of cultured bovine kidney epithelial cells and human HeLa cells changes dramatically during mitosis. The bundles of cytokeratin and vimentin filaments progressively unravel into protofilament-like threads of 2–4 nm diameter, and intermediate filament protein is included in numerous, variously sized (2–15 μm) spheroidal aggregates containing densely stained granular particles of 5–16 nm diameter. We describe these mitotic bodies in intact cells and in isolated cytoskeletons. In metaphase to anaphase of normal mitosis and after colcemid arrest of mitotic stages, many cells contain all their detectable cytokeratin and vimentin material in the form of such spheroidal aggregate bodies, whereas in other mitotic cells such bodies occur simultaneously with bundles of residual intermediate filaments. In telophase, the extended normal arrays of intermediate filament bundles are gradually reestablished. We find that vimentin and cytokeratins can be organized in structures other than intermediate filaments. Thus, at least during mitosis of some cell types, factors occur that promote unraveling of intermediate filaments into protofilament-like threads and organization of intermediate filament proteins into distinct granules that form large aggregate bodies. Some cells, at least certain epithelial and carcinoma cells, may contain factors effective in structural modulation and reorganization of intermediate filaments.     

Localization of cytokeratins in tissues of the rainbow trout: Fundamental differences in expression pattern between fish and higher vertebrates

Using a panel of antibodies against different cytokeratins in immunofluorescence microscopy on frozen tissue sections and two-dimensional gel electrophoresis of cytoskeletal proteins from these tissues, we have studied the tissue distribution of cytokeratins in a fish, the rainbow trout Salmo gairdneri. We have distinguished at least 14 different cytokeratin polypeptides in only a limited number of tissues, thus demonstrating the great complexity of the cytokeratin pattern in a fish species. The simplest cytokeratin pattern was that present in hepatocytes, comprising one type-II (L1) and two type-I (L2, L3) polypeptides that appear to be related to mammalian cytokeratins 8 and 18, respectively. Two or all three cytokeratins of this group were also identified in several other epithelial tissues, such as kidney. Epithelia associated with the digestive tract contained, in addition, other major tissue-specific cytokeratins, such as components D1-D3 (stomach, intestine and swim bladder) and B1 and B2 (biliary tract). With the exception of D1, all these polypeptides were also found in a cultured cell line (RTG-2). Epidermal keratinocytes contained D1 and six other major cytokeratins, termed E1-E6. The most complex cytokeratin pattern was that found in the gill epithelium. Surprisingly, antibodies specific for cytokeratins of the L1-L3 group also reacted with certain cell-sheet-forming tissues that are not considered typical epithelia and in higher vertebrates express primarily, if not exclusively, vimentin. Such tissues were (a) endothelia, including the pillar cells of the "gill filaments", (b) scale-associated cells, and (c) the ocular lens epithelium, and also several nonepithelial cell types, such as (d) fibroblasts and other mesenchymal cells, (e) chondrocytes, (f) certain vascular smooth muscle cells, and (g) astroglial cells of the optic nerve. The differences between the patterns of cytokeratin expression in this fish species and those of higher vertebrates are discussed. It is concluded that the diversity of cytokeratins has already been established in lower vertebrates such as fish, but that the tissue-expression pattern of certain cytokeratins has been restricted during vertebrate evolution. We discuss the value of antibodies specific for individual cytokeratin polypeptides as marker molecules indicating cell and tissue differentiation in fish histology, embryology, and pathology.     

Cell density and cell shape-related regulation of vimentin and cytokeratin synthesis : Inhibition of vimentin synthesis and appearance of a new 45 kD cytokeratin in dense epithelial cell cultures

The pattern of the intermediate type filament protein synthesis was examined in cultured bovine mammary gland epithelial (BMGE) cells under conditions of varied cell shape and cell-cell contact. In dense monolayer and suspension cultures BMGE cells expressed a new cytokeratin of 45 kD identified as a member of the acidic subfamily of cytokeratins. This polypeptide has a phosphorylated component and is dissociated from the cytokeratins complex in the presence of 6.5 M urea. The mRNA of the new cytokeratin accumulated in dense cell cultures, as revealed by in vitro translation in a cell-free system. In BMGE-H cells that express also vimentin, the synthesis of vimentin decreased dramatically in dense cell cultures, while the synthesis of the 45 kD cytokeratin was maximal under these conditions. The results suggest that the expression of certain cytokeratins and that of vimentin can be coordinately regulated by factors in the cellular environment that effect cell shape and cell surface contacts.