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Query: CAS:68238-35-7 (Keratin)
 986 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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.
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PMID:Microinjection of IFA antibody induces intermediate filament aggregates in epithelial cell lines but perinuclear coils in fibroblast-like lines. 137 81

Growth and differentiation of keratinocytes in a serum-free medium (keratinocyte growth medium or KGM) was studied and compared to that under conditions in which serum and feeder cell layers were used. Cells were grown in KGM containing 0.1 mM calcium (KGM/low calcium), KGM containing 1.2 mM calcium (KGM/normal calcium), or Dulbecco's modified Eagles medium containing 5% fetal calf serum and 1.8 mM calcium in presence of mitomycin treated 3T3 M cells (DMEM/5% FCS). Plating efficiency and rate of growth were similar in the three media till confluence. In postconfluent cultures, protein and DNA content of cells attached to the plate in KGM/low-calcium dishes decreased as an increased number of cells were shed into the medium. Cell shedding was much less evident in the presence of normal calcium. Cells grown in KGM/low calcium had a higher rate of cell proliferation (3H-thymidine incorporation into cellular DNA) than cells grown in normal calcium. Transglutaminase activity, involucrin content, and cornified envelope formation were greatest in cells grown in KGM/normal calcium, intermediate in cells grown in DMEM/5% FCS, and least in cells grown in KGM/low calcium. Keratin profiles from cells grown in KGM/low calcium showed a lower percentage of high molecular weight bands compared to the keratin profiles from cells grown in the presence of normal calcium. Keratinocytes in KGM/low calcium grew as a monolayer of cuboidal cells with few features of differentiation, whereas cells grown in KGM/normal calcium stratified into multilayered islands (3-5 layers) surmounted by 2-4 layers of enucleated cells with thickened cornified envelopes. Cells grown in KGM/normal calcium also contained tonofilaments and lamellar bodies unlike cells grown in KGM/low calcium. Cells grown in DMEM/5% FCS also formed stratified layers comparable to cells grown in KGM/normal calcium but lacked cornified cells, keratohyalin granules, tonofilament bundles, and lamellar bodies. These studies indicate the usefulness of serum-free conditions for the culture of human keratinocytes and confirm the importance of extracellular calcium in keratinocyte differentiation.
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PMID:Biochemical and morphological characterization of growth and differentiation of normal human neonatal keratinocytes in a serum-free medium. 245 Jan 2

The human uterine cervix consists of an endocervical canal lined with a single layer of columnar mucus-secreting cells and an outer ectocervix covered by a stratified squamous epithelium. We report here the culture of human endocervical epithelial cells (HEnE) and human ectocervical epithelial cells (HEcE) in serum-free medium (KGM). Both HEnE and HEcE cultures were composed of keratinocytelike cells which formed desmosomal contacts and stratified in the presence of high concentrations of calcium ions. Cells with a pleomorphic epithelial morphology were observed in HEnE cultures, but not in HEcE cultures. Keratin 18, which is characteristic of endocervix in vivo, was detected by indirect immunofluorescent staining in all HEnE cells but was never detected in cultured HEcE. HEcE expressed keratin 13 which is characteristic of ectocervix in vivo. Although keratin 13 was never detected in primary HEnE cultures, it was expressed in passaged HEnE cultures grown in medium with high concentrations of calcium and in late passage HEnE cultures. HEnE underwent an average of 15.1 population doublings during serial culture. Mean colony-forming efficiency during Passages 2 to 3 was 14.7% and mean population doubling time was 17.8 h. HEcE cultures underwent significantly more population doublings (29.0) than HEnE cultures, whereas colony-forming efficiencies and doubling times were similar to those determined for HEnE. HEnE and HEcE cells may be useful in developing in vitro models of cervical squamous metaplasia and for exploring the interactions between target cell differentiation, carcinogens, and papillomaviruses in the development of cervical neoplasia.
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PMID:Growth and characterization of epithelial cells from normal human uterine ectocervix and endocervix. 247 74

Terminal differentiation can be induced in cultured basal cells by either increasing the Ca2+ level in the medium from 0.05 to 1.4 mM or by exposure to the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA). If Ca2+ and TPA act by a common mechanism, then a common pattern of protein synthesis and/or phosphorylation would be expected. Computer-assisted analysis of radioactively labeled polypeptides separated by two-dimensional-polyacrylamide gel electrophoresis was utilized to study protein synthesis and phosphorylation. Within 1 h of increasing the Ca2+ level in the medium, the synthesis of 57 polypeptides was altered by 2-fold or more. Similarly, exposure to TPA for 1 h affected the synthesis of 106 polypeptides. Sixteen polypeptides were affected by both Ca2+ and TPA; the synthesis of nine was increased and seven was decreased, with changes in the same direction for both effectors. By 4 h, the synthesis of 32 polypeptides was similarly modulated by both Ca2+ and TPA. Only one polypeptide which was increased at 1 h was still elevated at 4 h. These results suggest that a common dynamic program of protein synthesis, likely to be related to terminal keratinocyte differentiation, is induced by both Ca2+ and TPA. Overall phosphorylation of epidermal proteins was increased after 30 min of TPA treatment, but was not increased by Ca2+ at this time. Keratin polypeptides were heavily phosphorylated in low Ca2+ medium, but the level or pattern of phosphorylation of these proteins was not altered by either Ca2+ or TPA. Although phosphorylation of a minor polypeptide (pI 5.1/Mr 45,000) was increased 2-3-fold by both Ca2+ and TPA, most of the specific protein phosphorylation changes induced in keratinocytes by Ca2+ and TPA appear to be unique. Thus, if protein phosphorylation is an early signal for epidermal differentiation by each effector, only a single apparent common substrate is involved and multiple kinases are activated. Alternatively, substrate specificity of a single kinase may be differentially altered by each effector.
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PMID:Induction of common patterns of polypeptide synthesis and phosphorylation by calcium and 12-O-tetradecanoylphorbol-13-acetate in mouse epidermal cell culture. 355 6

Modification of the ionic calcium concentration in the culture medium markedly alters the pattern of proliferation and differentiation in cultured mouse epidermal cells. When medium calcium is lowered to 0.05--0.1 mM, keratinocytes proliferate rapidly with a high growth fraction and do not stratify, but continue to synthesize keratin. The cells grow as a monolayer for several months and can be subcultured and cloned in low Ca++ medium. Ultrastructural examination of cells cultured under low Ca++ conditions reveals widened intercellular spaces, abundant microvilli and perinuclear organization of tonofilaments and cellular organelles. Desmosomes are absent. Epidermal cells growing as a monolayer in low Ca++ can be induced to terminally differentiate by adding calcium to the level normally found in the culture medium (1.2 mM). Cell-to-cell contact occurs rapidly and desmosomes form within 2 hr. The cells stratify by 1--2 days and terminally differentiate with cell sloughing by 3--4 days. After Ca++ addition, DNA synthesis decreases with a lag of 5--10 hr and is totally inhibited within 34 hr. In contrast, RNA and protein synthesis continue at 40--50% of the low Ca++ level at day 3, a time when many cells are detaching from the culture dish. Keratin synthesis is unaffected by the Ca++ switch.
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PMID:Calcium regulation of growth and differentiation of mouse epidermal cells in culture. 615 76

The pattern of proliferation and differentiation in cultured mouse epidermal cells in markedly altered by modifying the ionic calcium concentration in the culture medium. When medium calcium is lowered from 1.44 mM to 0.05-0.1 mM, keratinocytes proliferate rapidly with a high growth fraction, do not stratify, but continue to synthesize keratin. The cells grow as a monolayer for several months and can be subcultured in low Ca++ medium. Ultrastructural examination of cells cultured under low Ca++ conditions reveals widened intercellular spaces with an absence of desmosomes. Microvilli are numerous, and tonofilaments and cellular organelles are organized perinuclearly. Epidermal cells growing as a monolayer in low Ca++ can be identified to terminally differentiate by adding calcium to the level normally found in the culture medium. Contact between cells occurs rapidly and desmosomes form within 2 hours. The cells stratify in 1-2 days and terminally differentiate in 3-4 days. After Ca++ addition, DNA synthesis decreases after a lag of 5-10 hours and is totally inhibited within 36 hours. In contrast, RNA and protein synthesis continue at 40-50% of the control level at Day 3, a time when many cells are detaching from the culture dish. Keratin synthesis is unaffected by the Ca++ switch. Manipulation of epidermal proliferation and differentiation by altering extracellular calcium levels should enhance the usefulness of epidermal cell cultures in the study of differentiation and carcinogenesis.
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PMID:Growth and differentiation of mouse epidermal cells in culture: effects of extracellular calcium. 723 94

Keratinocyte differentiation in psoriasis was examined using a panel of monospecific monoclonal antibodies to keratins (K), including two recently developed monoclonal antibodies raised to carboxy terminal peptides of K6 (LL020) and K16 (LL025). Keratinocytes from normal skin, untreated psoriatic plaques and non-lesional psoriatic skin, were cultured using multiple in vitro systems. Time-lapse cinephotography was used to measure the intermitotic time of normal and psoriatic keratinocytes in both low calcium-defined and serum-containing media. The intermitotic time did not differ significantly between psoriatic and normal keratinocytes. Keratin expression of psoriatic and normal keratinocytes in vitro was examined by both gel electrophoresis and immunocytochemistry. K6, K16 and K17 were detected suprabasally in all culture systems in vitro, but only in interfollicular psoriatic epidermis in vivo, and not in normal skin. Small subpopulations of keratinocytes expressed simple epithelial keratins K7, K8, K18 and K19 in cultures on plastic substrates, but these keratins were absent in skin equivalents of normal or psoriatic skin. No psoriasis-specific pattern of differentiation was found in vitro. As the K6 peptide antibody reacted with basal cells of normal skin, probably due to K5 cross-reactivity, K16 expression determined by LL025 was found to be the most sensitive indicator of the psoriatic state of differentiation, and this antibody is recommended for future work on psoriasis. K17 had a distinct pattern of tissue distribution in normal skin: K17, but not K16, was present in basal myoepithelial cells in sweat glands, and the deep outer root sheath, but K17 distribution paralleled that of K16 in suprabasal psoriatic epidermis. As keratins K6, K16 and K17 are expressed in keratinocyte hyperproliferation, when high levels of certain cytokines are also expressed, the role of growth factors and regulatory nuclear transcription factors in the control of K6, K16 and K17 expression in psoriasis requires further study, in order to provide insight into the relationship between proliferation and differentiation.
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PMID:Keratins (K16 and K17) as markers of keratinocyte hyperproliferation in psoriasis in vivo and in vitro. 757 75

Calcium concentration influences keratinocyte differentiation, and, following injury, keratinocytes move through an environment of changing calcium levels. Because these migrating cells in wounds invariably express collagenase 1, we assessed if modulation of calcium levels regulates collagenase 1 production by primary human keratinocytes. Accurately reflecting the confined spatial pattern of enzyme production seen in vivo, collagenase 1 mRNA was expressed only by keratinocytes migrating from foci of differentiated cells. Treatment with calcium ionophores A23187 or thapsigargin markedly inhibited the basal and phorbol 12-myristate 13-acetate-(PMA) stimulated accumulation of keratinocyte collagenase 1 in the medium but did not affect collagenase 1 production by control or PMA-treated fibroblasts. A23187-mediated inhibition of collagenase 1 protein was not associated with a decrease in mRNA levels but rather was controlled by a selective and reversible block of enzyme secretion. This block in secretion was likely not due to altered protein folding as the proenzyme within A23187-treated cells remained capable of autolytic activation upon treatment with p-aminophenylmercuric acetate. In contrast, 92-kDa gelatinase mRNA and secreted protein levels were coordinately reduced by A23187. Keratin 14 expression, a basal keratinocyte marker, was reduced with PMA treatment, but A23187 did not affect keratin 14 expression. In human wounds, both basal and suprabasal keratinocytes at the migrating front of epidermis stained for keratin 14, but only the basal cells expressed collagenase 1. These data suggest that collagenase 1 production is not necessarily linked with expression of basal cell markers and that modulation of intracellular calcium levels can block secretion of collagenase 1 by keratinocytes which have moved away from the stratum basalis and from their natural substrate.
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PMID:Modulation of intracellular calcium levels inhibits secretion of collagenase 1 by migrating keratinocytes. 916 68

Keratin 14 (K14) is believed to play a pivotal role in the maintenance of epidermal cell shape and contributing to their resistance to mechanical trauma, thereby protecting the cells from lysing. Mice harboring a K14 null mutation produce phenotypic characteristics of epidermolysis bullosa simplex, a skin blistering disease (Lloyd et al., 1995, J Cell Biol 129:1329-1344). K14 null animals die several days after birth, making the detailed study of the consequences of K14 deletion in epidermal cell physiology in vivo particularly difficult. To define the consequences of K14 loss more precisely, we used an in vitro approach by isolating K14-/- cell lines and studying epidermal differentiation in the K14 null background. Several keratinocyte cell lines were generated from 6-day-old mice homozygous for a targeted disruption of the K14 gene (lines designated MKC-5, MKC-23, and MKC-33) and from their wild-type littermates (lines designated MKC-1 and MKC-6). Under low Ca2+ (0.066 mM) and low serum (2%) conditions, both wild-type and mutant cells were able to adhere to collagen type I-coated dishes and form epithelial sheets. They maintained basal epidermal cell characteristics and continued to proliferate without obvious signs of terminal differentiation; however, K14-/- cells proliferated two- to threefold slower than did their wild-type counterparts. The distribution of K5, the natural partner of K14, at the immunofluorescence level was also normal looking in the K14-/- MKC-5 cells, but with fewer filaments detectable, consistent with the approximately 20% reduction in K5 detectable on immunoblots. K17 expression was increased approximately 40% in the K14-/- cells. The levels of K15 and K16 were not different in the MKC-5 and MKC-6 cell lines, suggesting that they are not contributing factors to the stabilization of K5 in the mutant cells. K8, K19, and vimentin were undetectable in both lines. Both MKC-5 and MKC-6 cells underwent morphological and biochemical differentiation in response to a switch to high Ca2+ medium. These findings indicate that K14-/- MKC-5 cells preserve the morphological, biochemical, and physiological characteristics of epidermal cells for an extensive period of time in vitro, likely due to the compensatory expression of K17. The culturing capacity of these cells also permits the analysis of keratinocyte growth and differentiation in the absence of K14. In addition, the culturing methods we describe will be useful for the generation of epithelial cell lines from a wealth of increasingly available knockout mouse strains with early lethality.
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PMID:In vitro characteristics of early epidermal progenitors isolated from keratin 14 (K14)-deficient mice: insights into the role of keratin 17 in mouse keratinocytes. 1043 Jan 81

Wool follicle matrix cell cultures were initiated as explants from Tukidale (carpet wool) sheep primary follicle bulbs after removal of the outer root sheath. Successful explantation required coculture on collagen with intact dermal papillae. Cells had a typical epidermal morphology (pavements of flattened. polyhedral cells). Extracellular matrix from dermal papillae, conditioned media, separation of dermal papilla from bulb matrices by tissue culture inserts and feeder layers were unable to support matrix cell explantation. Cultures could be maintained for up to 14 passages during which time the cells became larger with an increased cytoplasmic/nuclear ratio and irregular outline. Proliferation of matrix cells was greater on laminin than with either collagen type I or type IV. Proliferation was considerably reduced under serum-free conditions. This was most apparent at low calcium (0.09 mmol/L). By Northern hybridization matrix cells were found to express keratin K18 at all stages of culture. Keratin K 1.15 expression was evident by the tenth passage. The wool-specific keratin K2.10 was not detected. The data demonstrate that successful wool matrix cell culture is achievable. Keratin gene expression occurs in these cells and varies with the stage of culture.
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PMID:Wool follicle matrix cells: culture conditions and keratin expression in vitro. 1073 69


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