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Query: UNIPROT:P06889 (
Mol
)
630,302
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Cytoplasmic poly(A)+ RNA was isolated from normal rat liver and Novikoff ascites hepatoma cells, translated in vitro using rabbit reticulocyte lysate system and the translational products were assayed by immunoprecipitation with antibodies specific for Novikoff hepatoma principal cytokeratins p39, p49 (a group of hepatic cytokeratins C, D, and E) and p56. The identity of the precipitated antigens was further confirmed by two-dimensional polyacrylamide gel electrophoresis. Only the Novikoff hepatoma poly(A)+ RNA contained translatable mRNA coding for the p39
cytokeratin
while the p49 and p56 cytokeratins were translated from both the normal rat liver and Novikoff hepatoma poly(A)+ RNAs. Immunoprecipitations employing monoclonal antibody specific for p39 also recovered significant quantities of p56 and 49K cytokeratins, presumably due to oligomeric associations of these proteins with p39 immediately after in vitro synthesis. Similar results were observed after experiments with anti-p56 monoclonal antibody in which p39, not reactive with this antibody, was recovered in immunoprecipitates. Overall, the two-dimensional gel fluorograms of cytokeratins synthesized in vitro from NAH or liver poly(A)+ RNA are quite similar to isolated antigenic and
cytokeratin
profiles reported previously. These results suggest that overt posttranslational processing is not likely responsible for the diversity of cytokeratins observed in the liver.
Mol
Cell Biochem 1986 Apr
PMID:In vitro translation of rat liver and Novikoff hepatoma cytokeratin mRNAs. 242 66
We have determined the sequence of cloned cDNAs derived from a 1,665-nucleotide mRNA which transiently accumulates during Xenopus laevis embryogenesis. Computer analysis of the deduced amino acid sequence revealed that this mRNA encodes a 47-kilodalton type I intermediate filament subunit, i.e., a
cytokeratin
. As is common to all intermediate filament subunits so far examined, the predicted polypeptide, named XK70, contains N- and C-terminal domains flanking a central alpha-helical rod domain. The overall amino acid homology between XK70 and a human 50-kilodalton type I keratin is 47%; homology within the alpha-helical domain is 57%. The N-terminal domain, which is not completely contained in our cDNAs, is basic, contains 42% serine plus alanine, and includes five copies of a six-amino-acid repeating unit. The C-terminal domain has a high alpha-helical content and contains a region with sequence homology to the C-terminal domains of other type I and type III intermediate filament proteins. We suggest that different keratin filament subtypes may have different functional roles during amphibian oogenesis and embryogenesis.
Mol
Cell Biol 1985 Oct
PMID:Developmentally regulated cytokeratin gene in Xenopus laevis. 242 72
Hepatocellular carcinoma cells obtained from ascitic fluid after diethylnitrosamine treatment of Sewall Wright strain-2 guinea pigs produce solid (primary) tumors, lymph-node metastases and malignant ascites when reinjected into animals of the same strain. When brought into culture the cells settle, form multilayer cultures and can be maintained in passage. In addition to epithelium-specific
cytokeratin
intermediate filaments (IF), these latter cells, like most cultured cells, also contain vimentin. Hepatocellular carcinoma cells in solid tumors and in metastatic tumors retain their original keratin IF and in general do not have an additional vimentin-IF system. When the tumor cells are present in ascites they develop vimentin-IF in addition to
cytokeratin
filaments. Vimentin is gradually lost when these cells sediment onto the peritoneal surface and proliferate continuously to form papillary projections, or when they are detected as circumscribed metastases. It seems likely, therefore, that in this system the synthesis of an additional vimentin cytoskeleton is related to reduced cell-to-cell contact and to the ability of the cells to survive individually or as cell clusters in body fluids, without being part of a cohesive tissue.
Virchows Arch B Cell Pathol Incl
Mol
Pathol 1986
PMID:Changing intermediate-sized filament patterns in metastatic hepatocellular carcinoma cells of the guinea pig. 242 67
Cytokeratins are constituent proteins of intermediate filaments (IFs) that form heterotypic tetrameric IF subunits containing two polypeptide chains of each of the two
cytokeratin
subfamilies, i.e. the acidic (type I) and the basic (type II). To locate the molecular domains involved in the formation of these heterotypic complexes, we have developed a binding assay in which total cellular or cytoskeletal polypeptides, or proteolytically prepared
cytokeratin
fragments, are separated by one-, or two-dimensional gel electrophoresis, blot-transferred on to nitrocellulose paper and probed with radio-iodinated purified
cytokeratin
polypeptides or fragments thereof, using buffers of various ionic strengths with or without 4 M-urea. Using these polypeptides in the binding assay, specific heterotypic binding was observed between complementary
cytokeratin
polypeptides of the two subfamilies (but not with other IF proteins) and between the corresponding alpha-helical rod domain fragments. Both rod coils 1 and 2 of the type II cytokeratin 8 bound to the rod (coils 1 and 2) fragment of type I cytokeratins, and this binding occurred at both low and high ionic strengths. The results obtained indicate that: (1) the binding between
cytokeratin
polypeptides of the complementary type is stronger and more selective than interactions of cytokeratins with other IF and non-IF proteins; (2) both the head and the tail portions of the proteins are not required for heterotypic complex formation; (3) the complementarity information located in the alpha-helical portions of the rod domain, and in short sequences immediately flanking them, is sufficient to discriminate between the two types of cytokeratins and to secure the formation of heterotypic
cytokeratin
complexes; (4) both coils 1 and 2 of the rod can contribute to this association; and (5) the formation of the heterotypic
cytokeratin
complex is not critically dependent upon ionic interactions. Our results are further compatible with the concept that the heterotypic binding takes place between
cytokeratin
homodimer coiled-coils.
J
Mol
Biol 1987 Sep 20
PMID:Cytokeratin domains involved in heterotypic complex formation determined by in-vitro binding assays. 244 97
We have analyzed the expression of
cytokeratin
polypeptides in subcolumnar reserve cells of the human uterine endocervical mucosa and the other epithelial cells using immunoperoxidase and immunofluorescence microscopy as well as by applying two-dimensional gel electrophoresis to microdissected cytoskeletal preparations. Endocervical columnar cells were uniformly positive for antibodies directed against the simple epithelium-type cytokeratins nos. 7, 8, 18, and 19, while a variable proportion of these cells was stained by an antibody against
cytokeratin
no. 4. Reserve cells were not only positive for cytokeratins nos. 8 (weakly and variably) and 19 but were also decorated by antibody KA 1, which reacts with cytokeratins present in stratified squamous epithelia. This last antibody selectively decorated reserve cells even when they were flat and inconspicuous. Antibody KA 1 uniformly stained the ectocervical squamous epithelium, the basal cells of which were also decorated by antibodies directed against cytokeratins nos. 8 (weakly and variably) and 19. Ectocervical suprabasal cells were positive, to a variable extent, for antibodies against cytokeratins nos. 4, 10/11, and 13. Gel electrophoresis revealed the presence of squamous-type cytokeratins nos. 5 and 17 in reserve cell-rich, but not in reserve cell-free, endocervical mucosa. We also analyzed the distribution pattern of these cells, as revealed by antibody KA 1, in the endocervical mucosa of 26 uteri. In all the specimens examined reserve cells were present, but their numbers exhibited considerable variation. In some cases these cells were confined to small islets localized deep within the cervical canal and lacked any continuity with the squamous epithelium. The expression of cytokeratins nos. 5 and 17 in reserve cells indicates that these cells have undergone a low level of squamous differentiation. The additional expression of cytokeratins nos. 8 and 19 in these cells points to a relationship with simple epithelial cells. The present data would seem to favor the view that reserve cells originate in situ from the columnar epithelium; however, this would imply an acquisition of new differentiation properties.
Virchows Arch B Cell Pathol Incl
Mol
Pathol 1987
PMID:Characterization of subcolumnar reserve cells and other epithelia of human uterine cervix. Demonstration of diverse cytokeratin polypeptides in reserve cells. 244 98
In order to study human bile duct cells in vitro, cystic ducts were obtained during cholecystectomy and treated with collagenase and mechanical abrasion to isolate biliary epithelial cells. The culture medium was supplemented with 50% of a bovine bile duct conditioned medium obtained by incubating minced bovine extrahepatic bile ducts for 24 hr in Dulbecco's modified Eagle's medium. Cells grew in monolayer and showed contact inhibition at confluency. The epithelial origin of primary cultures was verified by their growth pattern, ultrastructure, and indirect immunofluorescence for
cytokeratin
. The cultures showed specific immunofluorescence for lysozyme, collagen types I, III, and IV, fibronectin, and laminin, but were negative for collagen type V and factor VIII-associated antigen. Thus, these cultures provide an experimental model for the in vitro study of biliary atresia and other bile duct diseases.
Exp
Mol
Pathol 1988 Jun
PMID:Characterization of human extrahepatic biliary duct epithelial cells in culture. 245 76
The small RNP complexes of defined morphology and biochemical composition termed prosomes, first isolated from the cytoplasm associated with repressed mRNA (Martins de Sa, C., M.-F. Grossi de Sa, O. Akhayat, F. Broders, and K. Scherrer. J.
Mol
. Biol. 1986. 187:47-493), were found also in the nucleus (Grossi de Sa, M.-F., C. Martins de Sa, F. Harper, O. Coux, O. Akhayat, P. Gounon, J. K. Pal, Y. Florentin, and K. Scherrer. 1988. J. Cell Sci. 89:151-165). Immunofluorescence, immunoelectron microscopy, and immunochemical studies using mAbs directed against some of the prosomal proteins of duck erythroblasts indicate that in the cytoplasm of HeLa and PtK cells, prosome antigens are associated with the intermediate filament network of the
cytokeratin
type.
...
PMID:The association of prosomes with some of the intermediate filament networks of the animal cell. 245 30
The genes encoding intermediate filament (IF) proteins are expressed in a cell-lineage restricted fashion. To analyze the regulation of such genes, we studied
cytokeratin
and vimentin expression in hepatoma x fibroblast hybrids. These hybrids continued to express both hepatoma cell-derived cytokeratins and fibroblast-specific vimentin. Furthermore, the
cytokeratin
subunits that were produced were exclusively of rat hepatoma origin. Thus, IF protein genes were neither extinguished nor activated in cell hybrids, providing evidence for regulation in cis. This behavior contrasts sharply with that of most tissue-specific genes, which tend to be regulated in trans in hybrid cells.
Somat Cell
Mol
Genet 1989 Jul
PMID:Cytokeratin gene expression in hepatoma hybrid cells: evidence for regulation in cis. 247 62
The presence of intermediate filament proteins (IFP) in normal salivary gland tissue and investigated by immunohistochemical techniques on frozen sections. Cytokeratins (CKs) were seen in almost all normal epithelial cells. In the parotid gland and in palatal gland tissue, a co-expression of
cytokeratin
and glial fibrillary acidic protein (GFAP) was seen in some myoepithelial cells, but this was not apparent in the submandibular gland. In some pleomorphic adenomas, carcinomas in pleomorphic adenomas, one mucoepidermoid carcinoma, one mucus-producing adenopapillary carcinoma and one adenoid cystic carcinoma, cells expressing three different IFP classes were found (CKs, vimentin, GFAP). These cells were most often situated peripherally in the tumour cords or ducts. The
cytokeratin
pattern in these cells, as revealed by mAbs PKK1-3, was similar to that in normal myoepithelial cells. Furthermore, reactivity for a fourth class of IFP, desmin, could be seen in this cell type in two carcinomas in pleomorphic adenomas, and also in a few cells in a pleomorphic adenoma and an adenoid cystic carcinoma. Thus the pattern of IFP expression in salivary gland neoplasms, is very complex, and cannot always be related to the normal tissue.
Virchows Arch B Cell Pathol Incl
Mol
Pathol 1989
PMID:Glial fibrillary acidic protein and desmin in salivary neoplasms. Expression of four different types of intermediate filament proteins within the same cell type. 247 67
The stratified squamous epithelium of the oral gingiva and the hard palate is characterized by a tissue architecture and a cytoskeletal composition similar to, although not identical with, that of the epidermis and fundamentally different from that of the adjacent non-masticatory oral mucosa. Using immunocytochemistry with antibodies specific for individual cytokeratins, in situ hybridization and Northern blots of RNA with riboprobes specific for individual
cytokeratin
mRNAs, and gel electrophoresis of cytoskeletal proteins of microdissected biopsy tissue samples, we show changes in the pattern of expression of cytokeratins and their corresponding mRNAs in pathologically altered oral gingiva. Besides a frequently, although not consistently, observed increase in the number of cells producing cytokeratins 4 and 13 (which are normally found as abundant components in the sulcular epithelium and the alveolar mucosa but not in the oral gingiva) and a reduction in the number of cells producing cytokeratins 1, 10 and 11, the most extensive change was noted for cytokeratin 19, a frequent
cytokeratin
in diverse one-layered and complex epithelia. While in normal oral gingiva cytokeratin 19 is restricted to certain, sparsely scattered cells of --or near--the basal cell layer, probably neuroendocrine (Merkel) cells, in altered tissue of inflamed samples it can appear in larger regions of the basal cell layer(s) and, in apparently more advanced stages, also in a variable number of suprabasal cells. Specifically, our in situ hybridization experiments show that this altered suprabasal cytokeratin 19 expression is more extended at the mRNA than at the protein level, indicating that cytokeratin 19 mRNA synthesis may be a relatively early event during the alteration. These changes in
cytokeratin
expression under an external pathological influence are discussed in relation to other factors known to contribute to the expression of certain cytokeratins and with respect to changes occurring during dysplasia and malignant transformation of oral epithelia.
Virchows Arch B Cell Pathol Incl
Mol
Pathol 1989
PMID:Extensive changes in cytokeratin expression patterns in pathologically affected human gingiva. 248 Jun 86
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