Explant cultures of atopic dermatitis biopsies maintain their epidermal characteristics in vitro.

Atopic dermatitis (AD) is a common inflammatory skin disorder characterised by various epidermal alterations. Filaggrin (FLG) mutations are a major predisposing factor for AD and much research has been focused on the FLG protein. Human skin equivalents (HSEs) might be useful tools for increasing our understanding of FLG in AD and to provide a tool for the screening of new therapies aimed at FLG replacement. Our aim is to establish an explant HSE (Ex-HSE) for AD by using non-lesional skin from AD patients wildtype for FLG or harbouring homozygous FLG mutations. These Ex-HSEs were evaluated as to whether they maintained their in vivo characteristics in vitro and whether FLG mutations affected the expression of various differentiation markers. FLG mutations did not affect the outgrowth from the biopsy for the establishment of Ex-HSEs. FLG expression was present in healthy skin and that of AD patients without FLG mutations and in their Ex-HSEs but was barely present in biopsies from patients with FLG mutations and their corresponding Ex-HSEs. AD Ex-HSEs and AD biopsies shared many similarities, i.e., proliferation and the expression of keratin 10 and loricrin, irrespective of FLG mutations. Neither KLK5 nor Lekti expression was affected by FLG mutations but was altered in the respective Ex-HSEs. Thus, Ex-HSEs established from biopsies taken from AD patients maintain their FLG genotype-phenotype in vitro and the expression of most proteins in vivo and in vitro remains similar. Our method is therefore promising as an alternative to genetic engineering approaches in the study of the role of FLG in AD.

In-vitro melanoma models: invasive growth is determined by dermal matrix and basement membrane.

A critical first step in the metastatic progression of cutaneous melanoma, invasive growth into the dermal compartment, would ideally be studied in the proper three-dimensional tissue microenvironment. In this study, we compared the growth and behavior of four melanoma cell lines originating from primary and metastatic human cutaneous melanomas (AN, RU, M14, and WK) in in-vitro human skin equivalents (HSEs) generated with four different dermal matrices: human fibroblast-seeded rat tail collagen, human fibroblast-derived matrix (FDM), noncellular human de-epidermized dermis (DED), and a novel fully cellular human DED with an intact pre-existent basement membrane. Melanoma cells showed proliferation in all HSEs, indicating that the microenvironment formed in all HSEs studied here allows the growth of melanoma cells in concert with epidermal keratinocytes for multiple weeks in vitro. Melanoma cells did not affect epidermal proliferation and terminal differentiation. Growth of melanoma cells in the dermal compartment, as a measure of invasive potential, differs markedly between the four types of in-vitro human melanoma models. Notably, the growth of melanoma cells in the dermal matrix was observed in all HSEs cultured with cell lines originating from metastatic melanoma, except for cDED-based HSEs, and the growth of melanoma cells of nonmetastatic origin was observed in the dermal compartment of FDM-based HSEs. Our results show that the type of dermal equivalent and the presence of an intact basement membrane should be taken into consideration when studying melanoma invasion using in-vitro HSEs.