Daniel Asselineau

Aging Alters Functionally Human Dermal Papillary Fibroblasts but Not Reticular Fibroblasts: A New View of Skin Morphogenesis and Aging

Understanding the contribution of the dermis in skin aging is a key question, since this tissue is particularly important for skin integrity, and because its properties can affect the epidermis. Characteristics of matched pairs of dermal papillary and reticular fibroblasts (Fp and Fr) were investigated throughout aging, comparing morphology, secretion of cytokines, MMPs/TIMPs, growth potential, and interaction with epidermal keratinocytes. We observed that Fp populations were characterized by a higher proportion of small cells with low granularity and a higher growth potential than Fr populations. However, these differences became less marked with increasing age of donors. Aging was also associated with changes in the secretion activity of both Fp and Fr. Using a reconstructed skin model, we evidenced that Fp and Fr cells do not possess equivalent capacities to sustain keratinopoiesis. Comparing Fp and Fr from young donors, we noticed that dermal equivalents containing Fp were more potent to promote epidermal morphogenesis than those containing Fr. These data emphasize the complexity of dermal fibroblast biology and document the specific functional properties of Fp and Fr. Our results suggest a new model of skin aging in which marked alterations of Fp may affect the histological characteristics of skin.

UVA exposure of human skin reconstructed in vitro induces apoptosis of dermal fibroblasts: subsequent connective tissue repair and implications in photoaging.

The skin reconstructed in vitro has been previously shown to be a useful model to investigate the effects of UVB exposure (). The present study describes the response to UVA irradiation. Major alterations were observed within the dermal compartment. Apoptosis of fibroblasts located in the superficial area of the dermal equivalent was observed as soon as 6 h after irradiation, leading to their disappearance after 48 h. This effect was obtained without major alterations of epidermal keratinocytes suggesting a differential cell type sensitivity to UVA radiations. In addition, collagenase I was secreted by dermal fibroblasts. The UVA dermal effects could be observed even after removal of the epidermis during the post irradiation period, demonstrating that they were independent of the keratinocyte response. The analysis of the tissue regeneration during the following 2 weeks revealed a connective tissue repair via fibroblasts proliferation, migration and active synthesis of extracellular matrix proteins such as fibronectin and procollagen I. This cellular recolonization of the superficial part of the dermal equivalent was due to activation of surviving fibroblasts located deeply in the dermal equivalent. The direct damage in the dermis and the subsequent connective tissue repair may contribute to the formation of UVA-induced dermal alterations.

Direct role of human dermal fibroblasts and indirect participation of epidermal keratinocytes in MMP-1 production after UV-B irradiation.

Abstract. In vivo, matrix metalloproteinases are produced in response to ultraviolet B (UV-B) irradiation and are considered to be involved in connective tissue alterations observed in photoaging. The respective roles of keratinocytes and fibroblasts in UV-B-induced MMP-1 production were investigated in monolayer cultures of keratinocytes and fibroblasts as well as in an epidermis model reconstructed in vitro. In contrast to fibroblasts, which secreted MMP-1 in response to UV-B irradiation, no accumulation of MMP-1 was observed after UV-B irradiation of keratinocytes. However, culture medium from UV-B-irradiated keratinocytes, which showed an increase in IL-1α and IL-6, induced MMP-1 production by human fibroblasts, suggesting that UV-B irradiation modulates MMP-1 production via both direct and indirect mechanisms.

Ultraviolet b induces hyperproliferation and modification of epidermal differentiation in normal human skin grafted on to nude mice

Background  For ethical and technical reasons, the in vivo biological effects of ultraviolet (UV) radiation on skin are difficult to study in human volunteers. The use of human skin grafted on to nude mice may circumvent this difficulty.

Evaluation of the Protective Effect of Sunscreens on In Vitro Reconstructed Human Skin Exposed to UVB or UVA Irradiation

Abstract We have previously shown that skin reconstructed in vitro is a useful model to study the effects of UVB and UVA exposure. Wavelength-specific biological damage has been identified such as the formation of sunburn cells (SBC) and pyrimidine dimers after UVB irradiation and alterations of dermal fibroblasts after UVA exposure. These specific effects were selected to evaluate the protection afforded by two sunscreens after topical application on the skin surface. Simplified formulations having different absorption spectra but similar sun protection factors were used. One contained a classical UVB absorber, 2-ethylhexyl-p-methoxycinnamate. The other contained a broad-spectrum absorber called Mexoryl® SX, characterized by its strong absorbing potency in the UVA range. Both filters were used at 5% in a simple water/oil vehicle. The evaluation of photoprotection on in vitro reconstructed skin revealed good efficiency for both preparations in preventing UVB-induced damage, as shown by SBC counting and pyrimidine dimer immunostaining. By contrast, only the Mexoryl® SX-containing preparation was able to efficiently prevent UVA-specific damage such as dermal fibroblast disappearance. Our data further support the fact that skin reconstructed in vitro is a reliable system to evaluate the photoprotection provided by different sunscreens against specific UVB and UVA biological damage.

Clues to epidermal cancer proneness revealed by reconstruction of DNA repair-deficient xeroderma pigmentosum skin in vitro

Sun exposure has been clearly implicated in premature skin aging and neoplastic development. These features are exacerbated in patients with xeroderma pigmentosum (XP), a hereditary disease, the biochemical hallmark of which is a severe deficiency in the nucleotide excision repair of UV-induced DNA lesions. To develop an organotypic model of DNA repair deficiency, we have cultured several strains of primary XP keratinocytes and XP fibroblasts from skin biopsies of XP patients. XP skin comprising both a full-thickness epidermis and a dermal equivalent was succesfully reconstructed in vitro. Satisfactory features of stratification were obtained, but the expression of epidermal differentiation products, such as keratin K10 and loricrin, was delayed and reduced. In addition, the proliferation of XP keratinocytes was more rapid than that of normal keratinocytes. Moreover, increased deposition of cell attachment proteins, α-6 and β-1 integrins, was observed in the basement membrane zone, and β-1 integrin subunit, the expression of which is normally confined to basal keratinocytes, extended into several suprabasal cell layers. Most strikingly, the in vitro reconstructed XP skin displayed numerous proliferative epidermal invasions within dermal equivalents. Epidermal invasion and higher proliferation rate are reminiscent of early steps of neoplasia. Compared with normal skin, the DNA repair deficiency of in vitro reconstructed XP skin was documented by long-lasting persistence of UVB-induced DNA damage in all epidermal layers, including the basal layer from which carcinoma develops. The availability of in vitro reconstructed XP skin provides opportunities for research in the fields of photoaging, photocarcinogenesis, and tissue therapy.

The role of fibroblasts in dermal vascularization and remodeling of reconstructed human skin after transplantation onto the nude mouse

&NA; The vascularization and the dermal remodeling of two different types of human skin reconstructed “in vitro” and grafted onto the nude mouse were studied. They were composed of human keratinocytes grown either on a human acellular deepidermized dermis (DED), or on a lattice composed of human fibroblasts embedded in bovine type I collagen, a living dermal equivalent (LDE). At different stages after grafting, the transplants were harvested and processed for an immunohistological study with species-specific and non-species-specific antibodies. At one month after grafting, the two types of grafted dermis contained blood vessels whose vascular basement membranes were labeled with a mouse-specific anti-type IV collagen antibody. With an antibody specific for human type IV collagen, a constant labeling of the vascular basement membrane was only observed in the LDE containing fibroblasts. In the DED, a constant association of the mouse endothelial cells with human type IV collagen was observed at early stages after grafting. At later stages, the human type IV collagen progressively disappeared. On the other hand, the dermal-epidermal junction underneath the human epidermis contained human type IV collagen in the two types of reconstructed skin. Labeling with the species-specific antibodies directed against human or murine type I collagen showed that the ratio murine type I collagen versus human type I collagen increased with time, suggesting that the DED is progressively invaded by mouse fibroblasts that produce the mouse collagen. On the other hand, in the LDE, the preexisting bovine

An organotypic model of skin to study photodamage and photoprotection in vitro

Acute or repetitive sun exposures are known to elicit cutaneous damages such as sunburn but also long-term effects such as photoaging or cancers. Determination of early biological events occurring after ultraviolet (UV) exposure is essential for photoprotection. Using skin reconstructed in vitro containing both a dermal equivalent and a fully differentiated epidermis, the effects of UV light (UVB and UVA) were investigated. UVB-induced damage was essentially epidermal, with the typical sunburn cells and DNA lesions, whereas UVA radiation-induced damage was mostly located within the dermal compartment. The model and end points used for UVB- and UVA-induced damages appeared to be very useful for the in vitro evaluation of sunscreens after topical application, in particular to investigate its protective effects against the effects of UVR, and allowed us to distinguish the efficiency of absorbers depending on their absorption spectrum.

The use of reconstructed human skin to evaluate UV-induced modifications and sunscreen efficacy.

Abstract Biological and clinical effects of sun exposures are characterized by short‐term reactions, i.e. sunburn reaction and suntan, as well as long‐term consequences corresponding to photoaging and photocancers. We have developed several human in vitro three‐dimensional models in order to assess both the photodamage and the photoprotection afforded by sunscreens. Using a full thickness reconstructed skin comprising a differentiated epidermis and a living dermal equivalent, UVB‐ and UVA‐induced biological markers could be found at both the keratinocyte and the fibroblast level. Typical markers of the sunburn reaction could be reproduced in that model as well as dermal damages related to the photoaging process. Another model of reconstructed epidermis, comprising keratinocytes but also melanocytes and Langerhans cells, has been developed. The study of the UV‐induced pigmentation as possible using the pigmented reconstructed epidermis and allowing to reproduce the epidermal melanin unit. The assessment of cellular parameters related to UV‐induced immunosuppression could be performed using the reconstructed epidermis containing Langerhans cells. Exposure to solar‐simulated radiation provokes morphological alterations and the reduction in numbers of Langerhans cells within the exposed epidermis. Using all these models, the efficiency of sunscreens could be envisaged after topical application. The results showed that appropriate sunscreens could efficiently prevent the damage described above.

Matrix Metalloproteinase-1 Production Observed After Solar-Simulated Radiation Exposure is Assumed by Dermal Fibroblasts but Involves a Paracrine Activation Through Epidermal Keratinocytes¶

Chronic exposure of human skin to solar UV radiation leads to serious dermal damages, a hallmark of photoaging. In vivo, acute UV radiation has been shown previously to induce various matrix‐degrading proteases. Among them, matrix metalloproteinase‐1 (MMP‐1) has been suggested to be involved in skin photodamage. The purpose of this study was to investigate the effects of solar‐simulated radiation (SSR) on MMP‐1 production in normal human skin cells. SSR exposure of human skin reconstructed in vitro comprising both a differentiated epidermis and a fibroblast‐populated dermal equivalent led to an increase in MMP‐1 production, which was abolished when epidermis was removed immediately after SSR exposure. In addition, SSR exposure of differentiated keratinocytes grown on an acellular collagen gel did not induce MMP‐1 production. Experiments on cell cultures grown on plastic confirmed that keratinocytes failed, in contrast with fibroblasts, to produce MMP‐1 in response to SSR exposure. However, when conditioned medium from SSR‐exposed keratinocytes was added to human fibroblasts in culture, MMP‐1 production was induced. Altogether, these data show that MMP‐1 production observed after SSR exposure involved the release of soluble epidermal factors, which could modulate its production by dermal fibroblasts.