Epidermal keratin messenger RNAs: a heterogeneous family

Cell size as a determinant of the clone-forming ability of human keratinocytes

Keratinocytes isolated from human epidermis and subsequently cultured may form clones if they are 11 micron or less in diameter but are irreversibly committed to further enlargement and terminal differentiation if they are 12 micron or more in diameter. When a founding cell of 11 micron or less forms a small rapidly growing clone in culture, the cells of that clone are able to found new colonies even when their diameter is as great as 20 micron. As the clone becomes larger and grows more slowly, the maximal size of its clonogenic cells is reduced toward that of the epidermis. A cultured cell of up to 20 micron in diameter can, when it divides, give rise to clonogenic progeny smaller than itself, thus reversing the process of enlargement. Cells larger than 20 micron cannot divide and therefore cannot be rescued from terminal differentiation. It is concluded that when keratinocytes multiply rapidly, they extend reversibly the maximal size at which they are capable of generating clones into the range usually characteristic of terminally differentiating cells. It is proposed that this mechanism enables the keratinocyte to accommodate an increased rate of multiplication to its need to attain a large size during terminal differentiation.

Differential post-translational modification of human type I keratins synthesized in a rabbit reticulocyte cell-free system

The translation products synthesized in a rabbit reticulocyte lysate system, from total cellular mRNA from the human epithelial cell-line ME-180, have been examined. Keratin proteins are prominent among these translation products, and they precisely coelectrophorese in sodium dodecyl sulfate-polyacrylamide gels with keratins purified from the cells. Type-I, acidic, keratins which are acetylated in vivo, are also acetylated by the reticulocyte lysate. Examination by two-dimensional electrophoresis, of two acidic keratins known to be phosphorylated in vivo reveals that only one of these proteins is phosphorylated in the lysate system. Phosphorylation of this protein occurs after release of the completed polypeptide chain from the ribosome. The protein phosphorylated by the lysate is known to be the only ME-180 phosphokeratin modulated by cyclic AMP, reflecting in vitro the differential modification of ME-180 keratins in vivo.

Reactivity pattern of a monoclonal antikeratin antibody (KL1)

A monoclonal antibody against keratins (KL1) from normal human stratum corneum was obtained using hybridoma techniques. Spleen cells from immunized BALB/c mice were fused with NS1, a mouse myeloma cell line, to produce hybrids. Antibody activity to epidermal keratins was tested using an indirect immunofluorescence test on cryostat sections of human epidermis and rabbit lip. A stable clone producing antikeratin antibody was isolated and an ascitic fluid was produced and used as a source of antibody (IgG1 kappa). KL1 was characterized by its immunohistochemical staining of various epithelia and by its recognition of 55-57 kilodalton (kd) keratin polypeptide from normal epidermis using the immunoblot technique. Frozen and deparaffinized sections of normal human epidermis, mucosa, and esophagus were stained by this antibody only in the upper cell layers as demonstrated by both indirect immunofluorescence and immunoperoxidase techniques. Approximatively 80% of normal keratinocytes isolated after trypsinization were labeled by KL1 whereas most negative cells showed basement membrane zone antigens. This confirmed differences in the expression of medium-sized polypeptides between basal and supra-basal cells during the course of human epidermal differentiation. All epithelial cells from other human epithelia (thymus, thyroid, bronchial mucosa, stomach, intestines) were positive with KL1 whereas nonepithelial cells and tissues did not show any staining. In view of these results KL1 promises to be a useful tool in the exploration of human epithelial differentiation.

Prekeratin biosynthesis in human scalp epidermis

Analysis of human scalp epidermal prekeratin polypeptides by two-dimensional gel electrophoresis revealed that each of the bands observed in one-dimensional electrophoresis consisted of three to five polypeptides of the same molecular weight but differing in isoelectric points. It was possible to divide the polypeptides into two families, with isoelectric points in the ranges pH 6.0-8.0 and pH 5.0-5.5 respectively. Incorporation of radiolabelled amino acids into freshly excised pieces of scalp epidermis showed that some of the polypeptides had relatively greater contents of glycine and serine than others. Radiolabelled methionine and leucine were, in contrast, incorporated more or less uniformly into all the polypeptides. After incubation with 32P-labelled orthophosphate, relatively more intense labelling by 32P was observed in the higher molecular weight bands of each family. The most basic of the isoelectric variants in each case did not take up phosphate, implying that at least some of the variation in charge was due to different degrees of phosphorylation. Polyadenylated RNA isolated from scalp epidermis was translated in an RNA-dependent reticulocyte haemolysate system followed by immunoprecipitation and electrophoresis. The polypeptides isolated by using anti-(human scalp prekeratin) immunoglobulin G had similar electrophoretic mobilities in sodium dodecyl sulphate/polyacrylamide gels to authentic prekeratin polypeptides, but had different isoelectric properties. This suggested that the products of keratin gene expression undergo post-translational modification.

A subfamily of relatively large and basic cytokeratin polypeptides as defined by peptide mapping is represented by one or several polypeptides in epithelial cells

Epithelial cells contain a class of intermediate-sized filaments formed by proteins related to epidermal alpha-keratins ('cytokeratins'). Different epithelia can express different combinations of cytokeratin polypeptides widely varying in apparent mol. wt. (40 000-68 000) and isoelectric pH (5.0-8.5). We have separated, by two-dimensional gel electrophoresis, cytokeratin polypeptides from various tissues and cultured cells of man, cow, and rodents and examined their relatedness by tryptic peptide mapping. By this method, a subfamily of closely related cytokeratin polypeptides has been identified which comprises the relatively large (greater than or equal to mol. wt. 52 500 in human cells) and basic (pH greater than or equal to 6.0) polypeptides but not the smaller and acidic cytokeratins. In all species examined, the smallest polypeptide of this subfamily is cytokeratin A, which is widespread in many simple epithelia and is the first cytokeratin expressed during embryogenesis. This cytokeratin polypeptide subfamily is represented by at least one member in all epithelial and carcinoma cells examined, indicating that polypeptides of this subfamily serve an important role as tonofilament constitutents . Diverse stratified epithelia and tumours derived therefrom contain two or more polypeptides of this subfamily, and the patterns of expression in different cell types suggest that some polypeptides of this subfamily are specific for certain routes of epithelial differentiation.