Disease-linked connexin26 S17F promotes volar skin abnormalities and mild wound healing defects in mice.

Several mutant mice have been generated to model connexin (Cx)-linked skin diseases; however, the role of connexins in skin maintenance and during wound healing remains to be fully elucidated. Here we generated a novel, viable, and fertile mouse (Cx26CK14-S17F/+) with the keratitis-ichthyosis-deafness mutant (Cx26S17F) driven by the cytokeratin 14 promoter. This mutant mouse mirrors several Cx26-linked human skin pathologies suggesting that the etiology of Cx26-linked skin disease indeed stems from epidermal expression of the Cx26 mutant. Cx26CK14-S17F/+ foot pad epidermis formed severe palmoplantar keratoderma, which expressed elevated levels of Cx26 and filaggrin. Primary keratinocytes isolated from Cx26CK14-S17F/+ neonates exhibited reduced gap junctional intercellular communication and migration. Furthermore, Cx26CK14-S17F/+ mouse skin wound closure was normal but repaired epidermis appeared hyperplastic with elevated expression of cytokeratin 6. Taken together, we suggest that the Cx26S17F mutant disturbs keratinocyte differentiation and epidermal remodeling following wound closure. We further posit that Cx26 contributes to epidermal homeostasis by regulating keratinocyte differentiation, and that mice harboring a disease-linked Cx26 mutant display epidermal abnormalities yet retain most wound healing properties.

The Clouston syndrome mutation connexin30 A88V leads to hyperproliferation of sebaceous glands and hearing impairments in mice.

Distinct mutations in the gap junction protein connexin30 (Cx30) can cause the ectodermal dysplasia Clouston syndrome in humans. We have generated a new mouse line expressing the Clouston syndrome mutation Cx30A88V under the control of the endogenous Cx30 promoter. Our results show that the mutated Cx30A88V protein is incorporated in gap junctional plaques of the epidermis. Homozygous Cx30A88V mice reveal hyperproliferative and enlarged sebaceous glands as well as a mild palmoplantar hyperkeratosis. Additionally, homozygous mutant mice show an altered hearing profile compared to control mice. We conclude that the Cx30A88V mutation triggers hyperproliferation in the skin and changes the cochlear homeostasis in mice.

The connexin26 S17F mouse mutant represents a model for the human hereditary keratitis-ichthyosis-deafness syndrome.

Mutations in the GJB2 gene coding for connexin26 (Cx26) can cause a variety of deafness and hereditary hyperproliferative skin disorders in humans. In this study, we investigated the Cx26S17F mutation in mice, which had been identified to cause the keratitis-ichthyosis-deafness (KID) syndrome in humans. The KID syndrome is characterized by keratitis and chronic progressive corneal neovascularization, skin hyperplasia, sensorineural hearing loss and increased carcinogenic potential. We have generated a conditional mouse mutant, in which the floxed wild-type Cx26-coding DNA can be deleted and the Cx26S17F mutation is expressed under control of the endogenous Cx26 promoter. Homozygous mutants are not viable, whereas the surviving heterozygous mice show hyperplasia of tail and foot epidermis, wounded tails and annular tail restrictions, and are smaller than their wild-type littermates. Analyses of auditory brainstem responses (ABRs) indicate an ∼35 dB increased hearing threshold in these mice, which is likely due to the reduction of the endocochlear potential by 20-40%. Our results indicate that the Cx26S17F protein, which does not form functional gap junction channels or hemichannels, alters epidermal proliferation and differentiation in the heterozygous state. In the inner ear, reduced intercellular coupling by heteromeric channels composed of Cx26S17F and Cx30 could contribute to hearing impairment in heterozygous mice, while remaining wild-type Cx26 may be sufficient to stabilize Cx30 and partially maintain cochlear homeostasis. The phenotype of heterozygous mice resembles many of the symptoms of the human KID syndrome. Thus, these mice represent an appropriate model to further investigate the disease mechanism.