Intermediate filament expression and lifespan potential in human somatic cell hybrids

Summary Limited lifespan human diploid fibroblast cells have been fused with the HeLa derived cell line HEB 7A which possesses transformed growth characteristics and unlimited division potential. HEB 7A expresses keratin intermediate filaments, while the fibroblast cells express only vimentin intermediate filaments. Independently arising clones of hybrids were examined for the presence of keratin by indirect immunofluorescence. Of 11 limited lifespan hybrids, all were keratin negative and possessed the growth characteristics of the fibroblast parent. Of 8 transformed hybrids, 6 arising early after fusion and 2 arising late, all were keratin-positive and simultaneously expressed the transformed growth characteristics of loss of density dependent growth inhibition, low serum dependence, and anchorage independence. It is concluded that the growth properties of these hybrids are associated with the type of intermediate filament expressed. The intermediate filament expression is therefore a marker of proliferative potential in these hybrids. This work was supported by grant no. AG 02664 from NIA (to C.L.B.) and by grant nos. 1R01 HD 18129-01 from NIH and PCM83-09068 from NSF (to R.H.S.). Editor’s Statement The tight correlation between the expression of the intermediate filaments of the immortal parent in hybrids of limited lifespan fibroblasts and HeLa cells with the transformed phenotype is of interest. It may offer important clues to the mechanism involved in cellular senescence. Gordon H. Sato     

Expression of keratin and vimentin intermediate filaments in rabbit bladder epithelial cells at different stages of benzo[a]pyrene-induced neoplastic progression

Rabbit bladder epithelium, grown on collagen gels and exposed to the chemical carcinogen benzo[a]pyrene, produced nontumorigenic altered foci as well as tumorigenic epithelial cell lines during 120-180 d in culture. Immunofluorescence studies revealed extensive keratin filaments in both primary epithelial cells and benzo[a]pyrene-induced altered epithelial foci but showed no detectable vimentin filaments. The absence of vimentin expression in these cells was confirmed by two- dimensional gel electrophoresis. In contrast, immunofluorescence staining of the cloned benzo[a]pyrene-transformed rabbit bladder epithelial cell line, RBC-1, revealed a reduction in filamentous keratin concomitant with the expression of vimentin filaments. The epithelial nature of this cell line was established by the observation that cells injected into nude mice formed well-differentiated adenocarcinomas. Frozen sections of such tumors showed strong staining with antikeratins antibodies, but no detectable staining with antivimentin antibodies. These results demonstrated a differential expression of intermediate filament type in cells at different stages of neoplastic progression and in cells maintained in different growth environments. It is apparent that the expression of intermediate filaments throughout neoplastic progression is best studied by use of an in vivo model system in parallel with culture studies.     

Density-dependent expression of keratins in transformed rat liver cell lines

Immunomorphological examination of the distribution of three keratins in cultured rat liver-derived epithelial cell lines of the IAR series was performed in order to find out the effects of neoplastic evolution on the expression of these epithelium-specific markers. Specific monoclonal antibodies were used to reveal various intermediate filament proteins: keratins with molecular masses of 55, 49 or 40 kD (K55, K49 or K40), and vimentin. The expression of keratins was negligible in sparse and dense cultures of non-transformed lines, which had typical epithelial morphology. The examined keratins were also absent in the sparse cultures of transformed lines, which have lost partially or completely the morphological features of epithelia. However, cells in dense cultures of most transformed lines contained numerous keratin filaments. It is suggested that the paradoxical increase of keratin expression after transformation is due to increased saturation density of transformed cultures; this high density favours the expression. As shown by the experiments with culture wounding, the effects of density are local and reversible. While K55 was present in all the cells of dense cultures, the expression of the other two keratins was dependent on the cell position within these cultures. It is suggested that the expression of the latter two keratins, besides high cell density, also requires the presence (K40) or the absence (K49) of cell-substratum contacts. Possible mechanisms of the effects of cell density on the expression of keratins are discussed.     

Keratin filament disruption in interphase and mitotic cells--how is it induced?

We have studied the lability of keratin intermediate filaments in epithelial cell lines to try to understand the molecular mechanism that cause the ultrastructural transition from 10 nm filaments to the ball-like aggregates containing 2 to 3 nm filaments. Our results suggest that different growth conditions used in different laboratories may explain some but not all of the discrepancies in the literature on mitotic keratin filament disruption. Such disruption is not only cell type, but also subclone dependent and can be manipulated in one instance by altering the NaHCO3 concentration of the growth medium. An apparently similar filament to aggregate transition can be induced in interphase cells of some epithelial cell lines by incubation in a cold hypotonic buffer, or when cells are pretreated with phorbol ester and then incubated in cold physiological saline. A putative dialyzable and heat-stable factor present in medium conditioned by the growth of particular epithelial cell types may be required for disruption. Keratin polypeptide phosphorylation may play a role in filament labilization.     

Ovarian surface epithelium: autonomous production of connective tissue-type extracellular matrix.

The ovarian surface epithelium (OSE) is known to contribute to postovulatory repair of the ovarian cortex by proliferation and migration over the site of follicular rupture, and by deposition of a basement membrane. We examined the production of other extracellular matrix components in culture by OSE cells of the rat (ROSE), using immunofluorescence microscopy, electron microscopy, and proline incorporation. We compared recently explanted cells in low passage, the immortal line ROSE 239, whose growth pattern resembles low passage cultures, and the immortal line ROSE 199, which forms ridges and papillae. The epithelial nature of all three cell types was confirmed by the presence of keratin and laminin. All three cell types secreted collagen types I and III and at least one (ROSE 199) produced highly polymerized banded fibrils, which are characteristic for stromal or interstitial extracellular matrix. Simultaneous production of collagen types I and III, keratin, and laminin by cloned subpopulations ruled out an origin of the lines in mixed epithelial/fibroblast populations. The results demonstrate that OSE has the capacity to synthesize major components of connective tissue stroma. They suggest that this epithelium, in addition to its postulated proteolytic role, may also express synthetic activity in the remodelling of the ovarian cortical stroma. A capacity of OSE cells to produce stromal components autonomously might be an important factor in the formation of ovarian surface papillae and in neoplastic progression of OSE-derived ovarian carcinomas.     

Human ovarian surface epithelium in primary culture

The ovarian surface epithelium (OSE) represents a minute fraction of the cell mass of the ovary but gives rise to over 80% of human ovarian carcinomas. No experimental models for the study of human OSE exist. To characterize OSE cells in culture, explants of ovarian surface from normal ovary of premenopausal women were grown on plastic, glass, and collagen gel in 25% fetal bovine serum/Waymouth's medium 752/1. About 25% of explants produced epithelial outgrowths. Morphologically, these outgrowths resembled OSE in vivo and endothelial and mesothelial cells in culture, but they differed from cultured ovarian stromal, granulosa, and luteal cells. Only OSE among ovarian cell types were intensely keratin positive by immunofluorescence. Keratin also distinguished OSE cells from the keratin-negative endothelial cells. Most but not all OSE colonies tested showed 17 beta-hydroxysteroid dehydrogenase (HSD) activity, which was absent in peritoneal mesothelial cells. Colonies from most patients were limited to a few millimetres and became stationary within a few weeks. Changes that accompanied cessation of growth included senescence, increased keratin content, or the formation of multicellular papillary aggregates. With time, OSE cells tended to assume a fibroblast-like morphology but remained keratin positive and continued to resemble OSE by scanning electron microscopy (SEM). Subcultured OSE cells persisted in a stationary keratin-positive form for many weeks. Throughout this study, all pavementlike epithelial outgrowths that were contiguous with an explant stained for keratin; thus, such colonies can be assumed to be OSE. Conversely, fibroblast-shaped cells may represent OSE as indicated by keratin content and SEM appearance. The methods presented here permit culture of normal human OSE under conditions in which the cells exhibit morphologic plasticity, variable 17 beta-HSD activity, and presence of keratin.     

Epithelial-specific keratin gene expression: identification of a 300 base-pair controlling segment.

To elucidate the elements required for regulation of keratin expression in epidermis, we have linked a short, 300 base pair segment, corresponding to the promoter region of a human K#14 gene, to the chloramphenicol-acetyl-transferase gene. This construct was introduced into various mammalian cell lines and primary cultures via Ca3(PO4)2 precipitation. The 300 base pair segment from the keratin gene promoter region was active in all epithelial cells studied including transformed, simple epithelial cells such as HeLa and ME-180, cell lines derived from stratified epithelium, such as SCC-12, as well as primary cultures of epithelial cells. The construct was inactive in all non-epithelial cells tested including fibroblasts and melanocytes. The segment does not function as a silencer in nonepithelial cells but it can function as an enhancer in epithelial cells. Using the polymerase chain reaction we have constructed a series of deletions of the promoter and have localized an essential function within a 40 bp sequence. We conclude that we have identified the keratin gene promoter that is sufficient to confer epithelial-specific expression.     

Microinjection of IFA antibody induces intermediate filament aggregates in epithelial cell lines but perinuclear coils in fibroblast-like lines.

The murine monoclonal IFA antibody recognizes a conserved sequence present in almost all intermediate filament (IF) proteins. When IFA antibody was injected into 13 different primary or established cell lines, striking differences were detected between epithelial and fibroblastic cell lines. In epithelial cells keratin IFs were broken down within 4 h into numerous spheroid aggregates scattered throughout the cytoplasm. Keratin aggregates were first detected in the cytoplasmic periphery. In contrast, in fibroblastic cells, injection of IFA antibody led to the formation of perinuclear coils of vimentin. IFA antibody at a concentration of greater than 1 mg/ml had to be injected to initiate these transitions. When HeLa cells, which contain separate networks of vimentin and keratin filaments, were injected with IFA antibody, vimentin did not form perinuclear coils but was instead found together with keratin in aggregates. Electron micrographs of HeLa cells injected with IFA antibody showed that the aggregates have diameters between 0.5 and 2.6 microns and resembled the keratin aggregates observed in certain mitotic epithelial cells. Although the ultrastructural studies support an association of some aggregates with desmosomes, aggregates were, however, also induced by injection of IFA antibody into human keratinocytes in low calcium medium under conditions where desmosomes were not present.     

Various keratin antibodies produce immunohistochemical staining of human myocardium and myometrium

Summary Various polyclonal and monoclonal antibodies to keratins were used to stain different human muscle tissues by paired immunofluorescence and the unlabelled antibody peroxidase-anti-peroxidase method. In the myocardium, distinct coloration of the intercalated discs was produced by two polyclonal reagents to human epidermal keratins but not by two monoclonal antibodies to cytokeratins from pig renal tubular cells. In the myometrium — mainly in the middle layer of the uterine wall — cytoplasmic coloration of a varying fraction of the smooth muscle bundles was produced, especially by one of the polyclonal and by both monoclonal reagents. The staining was often confined to the perinuclear region. The keratin-positive myometrial cells usually coexpressed vimentin and actin in various proportions. These findings indicated that intermediate filaments of the keratin type, or antigenically similar elements, are not restricted to cells of epithelial origin. Other types of muscle cells did not react with keratin antibodies, but keratin-positive macrophages were occasionally found in tongue musculature and in inflamed epicardium. Altogether, our observations emphasize that keratin reactivity cannot be considered specific for epithelial (or mesothelial) cells without reservation.Supported by the Norwegian Cancer Society, Jahre's Fund, and the Norwegian Research Council for Science and the Humanities     

Human ovarian surface epithelium in primary culture

Summary The ovarian surface epithelium (OSE) represents a minute fraction of the cell mass of the ovary but gives rise to over 80% of human ovarian carcinomas. No experimental models for the study of human OSE exist. To characterize OSE cells in culture, explants of ovarian surface from normal ovary of premenopausal women were grown on plastic, glass, and collagen gel in 25% fetal bovine serum/Waymouth's medium 752/1. About 25% of explants produced epithelial outgrowths. Morphologically, these outgrowths resembled OSE in vivo and endothelial and mesothelial cells in culture, but they differed from cultured ovarian stromal, granulosa, and luteal cells. Only OSE among ovarian cell types were intensely keratin positive by immunofluorescence. Keratin also distinguished OSE cells from the keratin-negative endothelial cells. Most but not all OSE colonies tested showed 17β-hydroxysteroid dehydrogenase (HSD) activity, which was absent in peritoneal mesothelial cells. Colonies from most patients were limited to a few millimetres and became stationary within a few weeks. Changes that accompanied cessation of growth included senescence, increased keratin content, or the formation of multicellular papillary aggregates. With time, OSE cells tended to assume a fibroblast-like morphology but remained keratin positive and continued to resemble OSE by scanning electron microscopy (SEM). Subcultured OSE cells persisted in a stationary keratin-positive form for many weeks. Throughout this study, all pavementlike epithelial outgrowths that were contiguous with an explant stained for keratin; thus, such colonies can be assumed to be OSE. Conversely, fibroblast-shaped cells may represent OSE as indicated by keratin content and SEM appearance. The methods presented here permit culture of normal human OSE under conditions in which the cells exhibit morphologic plasticity, variable 17β-HSD activity, and presence of keratin. Supported by a grant and a research associateship to N. A. by the National Cancer Institute of Canada.     

Keratin filaments of epithelial and taste-bud cells in the circumvallate papillae of adult and developing mice

Summary Keratin filaments of epithelial- and taste-bud cells in the circumvallate papillae of adult and developing mice were studied by immunocytochemistry using monoclonal antikeratin antibodies (PKK2 and PKK3) and by conventional electron microscopy. Elongated cells (type-I,-II, and-III cells) of the taste buds were stained by PKK3 antibody, which reacts with 45-kdalton keratin, whereas basal cells of the taste buds and surrounding epithelial cells showed negative staining with PKK3. Such PKK3-reactive cells occurred at 0 day after birth, when taste-buds first appeared in the dorsal surface epithelium of the papillae. Thus 45-kdalton keratin seems to be an excellent immunocytochemical marker for identifying taste-bud cells. Epithelial cells in all layers of the trench wall and basal layer cells of the dorsal surface contained densely aggregated bundles of keratin filaments that reacted with PKK2 antibody, but not with PKK3. In contrast, taste-bud cells and spinous and granular layer cells of the dorsal surface possessed loose aggregated bundles of filaments that reacted with PKK3, but not with PKK2. These results suggest that the aggregation and distribution pattern of keratin filaments may reflect differences in the keratin subtypes that comprise these filaments.     

'Hard' and 'soft' principles defining the structure, function and regulation of keratin intermediate filaments.

Keratins make up the largest subgroup of intermediate filament proteins and represent the most abundant proteins in epithelial cells. They exist as highly dynamic networks of cytoplasmic 10-12 nm filaments that are obligate heteropolymers involving type I and type II keratins. The primary function of keratins is to protect epithelial cells from mechanical and nonmechanical stresses that result in cell death. Other emerging functions include roles in cell signaling, the stress response and apoptosis, as well as unique roles that are keratin specific and tissue specific. The role of keratins in a number of human skin, hair, ocular, oral and liver diseases is now established and meshes well with the evidence gathered from transgenic mouse models. The phenotypes associated with defects in keratin proteins are subject to significant modulation by functional redundancy within the family and modifier genes as well. Keratin filaments undergo complex regulation involving post-translational modifications and interactions with self and with various classes of associated proteins.     

Lactation affects expression of intermediate filaments in human breast epithelium

The human breast contains two epithelial lineages, luminal epithelial and myoepithelial. Specific patterns of expression of intermediate filaments have previously been demonstrated in the resting breast. To determine how terminal differentiation and lactation influenced expression of intermediate filaments in breast epithelial cells, we used Western blot analysis to measure the levels of vimentin, alpha-smooth muscle actin, keratin 14, and keratin 18 in the resting and lactating breast. Confocal immunofluorescence was used to determine the subcellular site of localization of the intermediate filaments. Vimentin was localised to myoepithelial cells in both the resting and lactating gland. There was a four-fold increase in vimentin protein levels in lactating tissue relative to resting tissue, and this may be related to increased cellular activity of the myoepithelial cells which surround secretory alveoli. Alpha-smooth muscle actin and keratin 14 were detected in myoepithelial cells, and similar levels of expression were found in lactating and resting tissue. In the resting breast, keratin 18 and keratin 8 were detected in luminal epithelial cells in a filamentous form, whereas in lactating tissue it was present in a punctate form in luminal cells and also seen as granules in the lumen of alveoli. Our results indicate that intermediate filament expression patterns are altered in the lactating human breast, and this may reflect their role in the fully functional gland.     

Establishment and characterization of three immortal bovine muscular epithelial cell lines

We have established three immortal bovine muscular epithelial (BME) cell lines, one spontaneously immortalized (BMES), the second SV40LT-mediated (BMEV) and the third hTERT-mediated (BMET). The morphology of the three immortal cell lines was similar to that of early passage primary BME cells. Each of the immortal cell lines made cytokeratin, a typical epithelial marker. BMET grew faster than the other immortal lines and the BME cells, in 10% FBS-DMEM medium, whereas neither the primary cells nor the three immortal cell lines grew in 0.5% FBS-DMEM. The primary BME cells and the immortal cell lines, with the exception of BMES, made increasing amounts of p53 protein when treated with doxorubicin, a DNA damaging agent. On the other hand, almost half of the cells in populations of the three immortal cell lines may lack p16(INK4a) regulatory function, compared to primary BME cells that were growth arrested by enforced expression of p16(INK4a). In soft-agar assays, the primary cells and immortal cell lines proved to be less transformed in phenotype than HeLa cells. The three immortal epithelial-type cell lines reported here are the first cell lines established from muscle tissue of bovine or other species.     

Early expression of vimenti in human mammary cultures

Summary The intermediate filaments of most epithelial cells in vivo consist solely of cytokeratins. Using monoclonal antibodies to vimentin or keratin, we have examined the expression of vimentin in homologous specimens of frozen tissue sections and primary cultures of normal human mammary epithelium. In frozen sections, only epithelial cells reacted with the antikeratin antibody, whereas antivimentin reactivity was associated with stromal cells. All epithelial cultures were positive for cytokeratin and in addition coexpressed vimentin as strongly as cultured fibroblasts and as early as the 4th d after initiation of the culture. Two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblot analysis of cytoskeletal preparations of secondary cultures of normal mammary epithelium have also demonstrated the appearance of a moiety identical to the vimentin found in cultured fibroblasts. Our observations are consistent with the hypothesis that vimentin expression is induced, possibly as a result of changes in cell shape or growth rate, when cells are freed from three-dimensional restirctions imposed by the tissue of origin     

Behavior of cells seeded in isolated fibronectin matrices

Cell-free fibronectin matrix (FN-matrix) isolated from chick embryo fibroblasts was used to study cell-matrix interaction. After 24 h, most fibroblastic cells, including those without cell surface fibronectin, adopted bipolar fusiform morphology. Cells grew in parallel arrays and aligned with each other apparently along FN-matrix. Since the orientation of fibronectin fibers was determined by chick embryo fibroblasts, our results suggested that intercellular organization of "matrix-using" cell type may be influenced by "matrix-producing" cell type. Whereas the elongation and alignment effects induced by FN-matrix have been detected in fibroblasts (both normal and transformed), myoblast, aortic endothelial cells, neural cell lines (B103 and RT4D1), and cardiac muscle cells, similar effects are not detected in bone marrow hemopoietic cells, circulating lymphocytic T and B cells, and sympathetic neurons. For epithelial cells, FN-matrix has varying effects. Elongation and alignment effects are detected only in transformed epithelial cells with a great reduction in keratin expression. The morphology of normal or transformed epithelial cells with abundant keratin appears unaffected by FN-matrix. FN-matrix reduced the growth of several transformed fibroblastic lines up to 25%, but did not restore the appearance of actin stress fibers and the normal migratory activities of Rous sarcoma virus-transformed rat cells.     

中等纤维在几种人体上皮细胞有丝分裂过程中的行为

By indirect immunofluorescence microscopy and electron microscopy, we studied the behavior of intermediate filaments during mitosis in three human epithelial cell lines, derived from normal epidermis (PcaSE-1, from a cancer patient), stratified epithelium (CNE, from nasopharyngeal carcinoma) and simple epithelium (SPC-A-1 from lung adenocarcinoma) respectively. CNE cells and SPC-A-1 cells express two different intermediate filament systems; keratin filaments and vimentin filaments, but PcaSE-1 cells only express keratin filaments. The keratin filament system in PcaSE-1 cells remained intact and encircled the developing mitotic spindle as the cells entered mitosis. In contrast, in CNE cells and SPC-A-1 cells, keratin filaments appeared to disassemble into amorphous cytoplasmic bodies during mitosis. However, their vimentin filaments remained morphologically intact throughout mitosis. We propose; (1) The disassembly of keratin filaments in mitotic epithelial cells is more or less associated with the degree of their cell malignancy rather than with the abundance of keratin filaments in interphase. (2) Intermediate filaments may be involved in the positioning and/or centering of the spindle during mitosis. (3) The possible function of vimentin filament system in CNE cells is positioning and orientation of chromosomes.     

Expression and distribution of vimentin and keratin filaments in heterokaryons of human fibroblasts and amnion epithelial cells

The expression of intermediate filaments of the keratin- and the vimentin-type was studied in heterokaryons of human fibroblasts and amnion epithelial cells by immunofluorescence microscopy. Fibroblasts and their homokaryons showed a fibrillar, vimentin-specific fluorescence throughout the cytoplasm but were negative when stained for keratin. Amnion epithelial cells and their homokaryons, on the other hand, showed a keratin-specific fibrillar staining, and only some of them contained also detectable vimentin. When suspended epithelial cells were fused with adherent fibroblasts, keratin fibrils spread within 3 h into the fibroblasts, intermixing with the vimentin fibrils. 1-3 d after fusion, both vimentin and keratin filaments were expressed as typical fibrillar cytoplasmic arrays, and the distribution of keratin in heterokaryons resembled closely that of vimentin. A typical cell-to-cell arrangement of keratin fibrils, seen in cultures of amnion epithelial cells, could also be found between heterokaryons. Treatment of the cultures with vinblastine sulphate induced coiling of the vimentin filaments in both homo- and heterokaryons, whereas the keratin organization was only slightly affected. Our results show that both vimentin and keratin filaments are incorporated into the cytoskeleton of heterokaryons formed between fibroblasts and epithelial cells, and that they behave in the same way as in their parental cells. Both epithelial and fibroblastic characteristics thus appear to the coexpressed in such heterokaryons.     

Microfilaments and intermediate filaments in epithelial cells transformed by murine sarcoma or leukemia viruses

The murine epithelial cell line MMC-E was used to study changes in the cytoskeletal organization associated with viral transformation of epithelial cells by two different viruses. The cells were transformed with Moloney mouse sarcoma virus (MSV) or murine leukemia virus (MuLV). The expression of actin, myosin and of intermediate filament proteins in the cells was then studied. In MMC-E cells actin and myosin were organized as belt-like structures at the edges of the border cells of the cell islands and also circumferentially in the cells inside the islands. The major change after transformation was the decrease of the actomyosin containing belt extending from cell to cell at the borders of the cell islands. Both MMC-E cells and the MSV-transformed cells contained keratin as a juxtanuclear granular aggregate whereas the MuLV-transformed cells showed bright fibrillar arrays of keratin. Both virus-transformed cell lines showed enhanced vimentin-specific fluorescence and analysis of their cytoskeletal polypeptides confirmed the result. Similar molecular forms of keratin polypeptides were seen in all cells by immunoblotting. Viral transformation of MMC-E epithelial cells thus leads to different changes in their cytoskeletal organization depending on the transforming viral or cellular gene.