Epidermal keratin and epidermal prekeratin

Protein composition of cornified cell envelopes of epidermal keratinocytes

Terminally differentiated mammalian epidermal cells are lined with a 15 nm thick layer of proteins cross-linked by isodipeptide and disulfide bonds, called the cornified cell envelope (CE). A number of proteins, including involucrin, loricrin, cystatin A, filaggrin, a cysteine-rich protein (CRP) and the ‘small proline-rich’ proteins (SPRRs) have been reported to be components of this complex, but little information has been obtained as to their relative abundances because the acute insolubility of the CEs has precluded direct methods of analysis. To address this question, we have determined the amino acid compositions of isolated CEs, and then modelled them in terms of linear combinations of the candidate proteins. The results show that stratum corneum CEs have a loricrin content of 65–70% (w/w) in human, and 80–85% in mouse. In human epidermal CEs, the secondary contributors are filaggrin and CRP (each approximately 10%), with smaller amounts of involucrin, SPRR and cystatin A (2-5% each) also present. Mouse epidermal CEs have about the same amount of filaggrin and somewhat more SPRR, but only trace amounts of the other proteins. In marked contrast, the major constituents of the CEs of cultured keratinocytes induced to terminal differentiation in vitro are cystatin A, involucrin and CRP (each approximately 30%). No significant amount of loricrin was detected except in sloughed mouse cells, which represent a more advanced state of terminal differentiation than attached cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Mallory bodies: lesions of hepatocytes containing proteins of the keratin-myosin-epidermin group

Mallory's alcoholic hyalin in hepatocytes was found also in other diseases and is now referred to as Mallory bodies. Data concerning their histochemical, immuno and electron microscopic properties are partly contradictory. In this study, early stages of Mallory bodies reacted strongly with configurational technics for myosins; affinity tended to decrease when material with the properties of keratohyalin and the matrix of stratum corneum was formed. Thus, many Mallory bodies contained histochemically distinct myoid and keratin-like proteins. Electron microscopists demonstrated thick and thin filaments resembling contractile systems in Mallory bodies; the failure of immunologists to visualize actomyosin may be due to the heterogeneity of these proteins. The currently popular term prekeratin has been applied to a variety of substances extracted from epidermis, hoof and hair under different conditions. The prekeratin of recent immunofluorescence studies seems to contain mainly epidermin and low molecular matrix proteins; both were studied extensively by chemists. Epithelial filaments, including tonofibrils and contractile fibrils regarded as a subgroup of myofibrils, were well known half a century ago, but were banished by electron microscopy. Observations in this study and data on epidermal actomyosin indicate that different proteins of the k-m-e-f group can indeed coexist in epithelial cells. The formation and resolution of Mallory bodies can be regarded as an example of the well known shifts of epithelial cells between secretory and keratinizing states.

The extraction and characterization of bovine epidermal alpha-keratin

1. The alpha-fibrous protein (alpha-keratin) component of bovine epidermis has been extracted and characterized. 2. Prekeratin, a multichain unit of the epidermal tonofilaments, was shown to consist of six different polypeptide chains on polyacrylamide-gel systems containing sodium dodecyl sulphate or sodium decyl sulphate with discontinuous gel buffers, but only three chains were seen when a gel system containing sodium dodecyl sulphate with a continuous gel buffer was used. 3. Extraction of the 'keratinized' stratum corneum and the living part of the epidermis with urea buffers at pH 7.6 or 9.0 released 60% of the total dry weight of the tissues in the form of alpha-helical polypeptides. 4. The numbers, relative amounts and properties of the extracted polypeptides were the same as the subunits of prekeratin and thus are derived from the tonofilaments in situ. 5. The subunits of prekeratin and the polypeptides extracted from the living cell layers contained an average of six cysteine residues, but those from the stratum corneum contained an average of three intrachain disulphide bonds. 6. The polypeptide chains aggregated through non-covalent interactions in vitro into filaments that were similar to the tonofilaments. 7. Since the polypeptides could be released from the stratum corneum without breaking covalent bonds, it is concluded that such bonds do not cross-link the tonofilaments and non-fibrous keratohyalin. It is suggested that the tonofilaments and keratohyalin of bovine epidermis are associated by secondary bonding forces.