Epidermolytic hyperkeratosis is a hereditary skin disorder characterized by blistering and a marked thickening of the stratum corneum. In one family, affected individuals exhibited a mutation in the highly conserved carboxyl terminal of the rod domain of keratin 1. In two other families, affected individuals had mutations in the highly conserved amino terminal of the rod domain of keratin 10. Structural analysis of these mutations predicts that heterodimer formation would be unaffected, although filament assembly and elongation would be severely compromised. These data imply that an intact keratin intermediate filament network is required for the maintenance of both cellular and tissue integrity.
To assess the effect of transforming growth factor (,3 on the skin in vivo, we have targeted its expression to the epidermis of transgenic mice. To ensure that active TGF-P1 was expressed, we used a porcine TGF-fji cDNA with mutations of Cys-223 --Ser and Cys-225 --Ser, which allow constitutive activation. Mice expressing the mutant transforming growth factor ,13 transgene exhibited a marked phenotype at birth. The skin was very shiny and tautly stretched. These animals were rigid and appeared to be restricted in their ability to move and breathe; death occurred within 24 hr. Histologically, the most prominent features of the skin were a compact orthohyperkeratosis and a reduction in the number of hair follicles. Pulse-labeling studies with 5-bromodeoxyuridine demonstrated a marked reduction in the number of replicating cells in the epidermis and hair follicles. Thus, the macro-and microscopic appearance of these mice, as well as their neonatal lethality, most likely result from inhibition of normal skin development and suppression of epithelial cell proliferation by the overexpression of transforming growth factor Pi.
The epidermal cornified cell envelope (CE) is a complex protein–lipid composite that replaces the plasma membrane of terminally differentiated keratinocytes. This lamellar structure is essential for the barrier function of the skin and has the ability to prevent the loss of water and ions and to protect from environmental hazards. The major protein of the epidermal CE is loricrin, contributing ∼70% by mass. We have generated mice that are deficient for this protein. These mice showed a delay in the formation of the skin barrier in embryonic development. At birth, homozygous mutant mice weighed less than control littermates and showed skin abnormalities, such as congenital erythroderma with a shiny, translucent skin. Tape stripping experiments suggested that the stratum corneum stability was reduced in newborn Lor−/− mice compared with wild-type controls. Isolated mutant CEs were more easily fragmented by sonication in vitro, indicating a greater susceptibility to mechanical stress. Nevertheless, we did not detect impaired epidermal barrier function in these mice. Surprisingly, the skin phenotype disappeared 4–5 d after birth. At least one of the compensatory mechanisms preventing a more severe skin phenotype in newborn Lor−/− mice is an increase in the expression of other CE components, such as SPRRP2D and SPRRP2H, members of the family of “small proline rich proteins”, and repetin, a member of the “fused gene” subgroup of the S100 gene family.
The murine genome is known to have two keratin 6 (K6) genes, mouse K6 (MK6)a and MK6b. These genes display a complex expression pattern with constitutive expression in the epithelia of oral mucosa, hair follicles, and nail beds. We generated mice deficient for both genes through embryonic stem cell technology. The majority of MK6a/b−/− mice die of starvation within the first two weeks of life. This is due to a localized disintegration of the dorsal tongue epithelium, which results in the build up of a plaque of cell debris that severely impairs feeding. However, ∼25% of MK6a/b−/− mice survive to adulthood. Remarkably, the surviving MK6a/b−/− mice have normal hair and nails. To our surprise, we discovered MK6 staining both in the hair follicle and the nail bed of MK6a/b−/− mice, indicating the presence of a third MK6 gene. We cloned this previously unknown murine keratin gene and found it to be highly homologous to human K6hf, which is expressed in hair follicles. We therefore termed this gene MK6 hair follicle (MK6hf). The presence of MK6hf in the MK6a/b−/− follicles and nails offers an explanation for the absence of hair and nail defects in MK6a/b−/− animals.
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