Differential effect of extracellular matrix derived from papillary and reticular fibroblasts on epidermal development in vitro.

Papillary and reticular fibroblasts have different effects on keratinocyte proliferation and differentiation. The aim of this study was to investigate whether these effects are caused by differential secretion of soluble factors or by differential generation of extracellular matrix from papillary and reticular fibroblasts. To study the effect of soluble factors, keratinocyte monolayer cultures were grown in papillary or reticular fibroblast-conditioned medium. To study the effect of extracellular matrix, keratinocytes were grown on papillary or reticular-derived matrix. Conditioned medium from papillary or reticular fibroblasts did not differentially affect keratinocyte viability or epidermal development. However, keratinocyte viability was increased when grown on matrix derived from papillary, compared with reticular, fibroblasts. In addition, the longevity of the epidermis was increased when cultured on papillary fibroblast-derived matrix skin equivalents compared with reticular-derived matrix skin equivalents. The findings indicate that the matrix secreted by papillary and reticular fibroblasts is the main causal factor to account for the differences in keratinocyte growth and viability observed in our study. Differences in response to soluble factors between both populations were less significant. Matrix components specific to the papillary dermis may account for the preferential growth of keratinocytes on papillary dermis.

TGF-ß1 induces differentiation of papillary fibroblasts to reticular fibroblasts in monolayer culture but not in human skin equivalents.

UNLABELLED: Fibroblasts isolated from the papillary and reticular dermis are different from each other in vitro. If papillary fibroblasts are subjected to prolonged serial passaging they will differentiate into reticular fibroblasts. Reticular fibroblasts have been shown to resemble myofibroblasts in several ways. TGF-ß1 is the most important factor involved in myofibroblast differentiation. AIMS: we investigated if TGF-ß1 can induce differentiation of papillary fibroblasts into reticular fibroblasts, in monolayer cultures and in human skin equivalents. METHOD: Monolayer cultures of and human skin equivalents generated with papillary fibroblasts were stimulated with TGF-ß1. The expression of markers specific for reticular and papillary fibroblasts was measured by qPCR and immunohistochemical analysis in monolayer cultures. In human skin equivalents, the morphology and the expression of several markers was analysed and compared to untreated papillary and reticular human skin equivalents. RESULTS: Monolayer cultures of papillary fibroblasts started to express a reticular marker profile after stimulation with TGF-ß1. Human skin equivalents generated with papillary fibroblast and stimulated with TGF-ß1 were similar to papillary control equivalents and did not obtain reticular characteristics. Expression of reticular markers was only found in the lower layers of TGF-ß1-stimulated papillary skin equivalents. CONCLUSIONS: TGF-ß1 can induce differentiation to reticular fibroblasts in monolayer cultures of papillary fibroblasts. In skin equivalents no such effects were found. The major difference between these experiments is the presence of extracellular matrix in skin equivalents. Therefore, we hypothesize that the matrix secreted by papillary fibroblasts protects them from TGF-ß1 induced differentiation.

Effects of serially passaged fibroblasts on dermal and epidermal morphogenesis in human skin equivalents.

Serial passaging has a profound effect on primary cells. Since serially passaged cells show signs of cellular aging, serial passaging is used as an in vitro model of aging. To relate the effect of in vitro aging more to in vivo aging, we generated human skin equivalents (HSEs). We investigated if HSEs generated with late passage fibroblasts show characteristics of aged skin when compared with HSEs generated with early passage fibroblasts. Late passage fibroblasts had enlarged cell bodies and were more often positive for myofibroblast marker α-smooth muscle actin, senescence associated ß-galactosidase and p16 compared with early passage fibroblasts. Skin equivalents generated with late passage fibroblasts had a thinner dermis, which could partly be explained by increased matrix metalloproteinase-1 secretion. In equivalents generated with late passage fibroblasts epidermal expression of keratin 6 was increased, and of keratin 10 slightly decreased. However, epidermal proliferation, epidermal thickness and basement membrane formation were not affected. In conclusion, compared with HSEs generated with early passage fibroblasts, HSEs generated with late passage fibroblasts showed changes in the dermis, but no or minimal changes in the basement membrane and the epidermis.

Papillary fibroblasts differentiate into reticular fibroblasts after prolonged in vitro culture.

The dermis can be divided into two morphologically different layers: the papillary and reticular dermis. Fibroblasts isolated from these layers behave differently when cultured in vitro. During skin ageing, the papillary dermis decreases in volume. Based on the functional differences in vitro, it is hypothesized that the loss of papillary fibroblasts contributes to skin ageing. In this study, we aimed to mimic certain aspects of skin ageing by using high-passage cultures of reticular and papillary fibroblasts and investigated the effect of these cells on skin morphogenesis in reconstructed human skin equivalents. Skin equivalents generated with reticular fibroblasts showed a reduced terminal differentiation and fewer proliferating basal keratinocytes. Aged in vitro papillary fibroblasts had increased expression of biomarkers specific to reticular fibroblasts. The phenotype and morphology of skin equivalents generated with high-passage papillary fibroblasts resembled that of reticular fibroblasts. This demonstrates that papillary fibroblasts can differentiate into reticular fibroblasts in vitro. Therefore, we hypothesize that papillary fibroblasts represent an undifferentiated phenotype, while reticular fibroblasts represent a more differentiated population. The differentiation process could be a new target for anti-skin-ageing strategies.

Marine-derived nutrient improves epidermal and dermal structure and prolongs the life span of reconstructed human skin equivalents.

INTRODUCTION: Imedeen™ is a cosmeceutical that provides nutrients to the skin. One of its active ingredients is the Marine Complex™ (MC). AIM: The aim of this study was to evaluate whether MC affects skin morphogenesis differently in female and male human skin equivalents (HSEs). METHODS: Human skin equivalents were established with cells obtained from female or male donors between 30 and 45 years of age and cultured for seven or 11 weeks in the presence or absence of MC. Using immunohistochemistry, we examined early differentiation by keratin 10 expression, (hyper)proliferation by keratin 17 and Ki67, and basement membrane composition by laminin 332 and collagen type VII. In addition, the expression of collagen type I and the secretion of pro-collagen I were measured. RESULTS: Marine Complex strongly increased the number of Ki67-positive epidermal cells in female HSEs. In the dermis, MC significantly stimulated the amount of secreted pro-collagen I and increased the deposition of laminin 332 and collagen type VII. Furthermore, MC prolonged the viable phase of HSEs by slowing down its natural degradation. After 11 weeks of culturing, the MC-treated HSEs showed higher numbers of viable epidermal cell layers and a thicker dermal extracellular matrix compared with controls. In contrast, these effects were less pronounced in male HSEs. CONCLUSION: The MC nutrient positively stimulated overall HSE tissue formation and prolonged the longevity of both female and male HSEs. The ability of MC to stimulate the deposition of basement membrane and dermal components can be used to combat 2 human skin aging in vivo.

Different gene expression patterns in human papillary and reticular fibroblasts.

The dermis contains two distinct layers: the papillary and the reticular layers. In vitro cultures of the fibroblasts from these layers show that they are different. However, no molecular markers to differentiate between the two subtypes of fibroblasts are known. We performed gene expression analysis on cultured fibroblasts isolated from the papillary and reticular dermis. In all, 116 genes were found to be expressed differentially. Of these, 13 were validated by quantitative reverse transcriptase-PCR analysis and two markers could be validated at the protein level in monolayer cultures. Three markers showed differential expression in in vivo skin sections. The identified, characteristic markers of the two fibroblast subpopulations provide useful tools to perform functional studies on reticular and papillary fibroblasts.