The ‘Abtropfung Phenomenon’ Revisited: Dermal Nevus Cells from Congenital Nevi Cannot Activate Matrix Metalloproteinase 2 (MMP‐2)

Since Unna's Abtropfung hypothesis, the process of migration of nevus cells in the dermis remains unknown. To investigate its mechanisms, we studied the role of gelatinases in dermal nevus cells obtained from congenital pigmented nevi, which are major actors in the remodeling of basement membrane proteins. Our previous studies have shown that dermal nevus cells express pro‐matrix metalloproteinase (MMP)‐2 exclusively and cannot return to the dermis when seeded together with keratinocytes on top of the dermis in a skin reconstruction model. To examine why MMP‐2 was not in its active form, we used Western blot to study the expression of members of the MMP‐2 activation pathway (membrane type 1‐MMP and tissue inhibitor of metalloproteinase‐2), which proved to be normally expressed. To induce the dermal passage of nevus cells artificially, we also tried to activate gelatinases with phorbol‐12‐myristate‐13‐acetate and epidermal growth factor, using epidermis reconstructed with nevus cells. No migration in the dermis could be triggered. We conclude that the absence of active MMP‐2 is due to a functional blockade of its activation pathway and may prevent dermal nevus cells from reaching the dermal compartment in skin reconstructs. Furthermore, our findings reinforce the concept that dermal nevus cells originating from congenital nevi are in a quiescent status.     

The 'Abtropfung phenomenon' revisited: Dermal nevus cells from congenital nevi cannot activate matrix metalloproteinase 2 (MMP-2)

Since Unna's Abtropfung hypothesis, the process of migration of nevus cells in the dermis remains unknown. To investigate its mechanisms, we studied the role of gelatinases in dermal nevus cells obtained from congenital pigmented nevi, which are major actors in the remodeling of basement membrane proteins. Our previous studies have shown that dermal nevus cells express pro-matrix metalloproteinase (MMP)-2 exclusively and cannot return to the dermis when seeded together with keratinocytes on top of the dermis in a skin reconstruction model. To examine why MMP-2 was not in its active form, we used Western blot to study the expression of members of the MMP-2 activation pathway (membrane type 1-MMP and tissue inhibitor of metalloproteinase-2), which proved to be normally expressed. To induce the dermal passage of nevus cells artificially, we also tried to activate gelatinases with phorbol-12-myristate-13-acetate and epidermal growth factor, using epidermis reconstructed with nevus cells. No migration in the dermis could be triggered. We conclude that the absence of active MMP-2 is due to a functional blockade of its activation pathway and may prevent dermal nevus cells from reaching the dermal compartment in skin reconstructs. Furthermore, our findings reinforce the concept that dermal nevus cells originating from congenital nevi are in a quiescent status.     

An Ex Vivo Study of Congenital Pigmented Nevi in Epidermal Reconstructs

In order to study morphologic and functional characteristics of pigment cells in congenital pigmented nevi, autologous or heterologous reconstructs have been made using normal keratinocytes and nevus cells from the dermal-epidermal junction or from the dermis. All these cells, keratinocytes and nevus cells, were used as cell suspensions immediately after dissociation from the tissues or after subsequent brief cultivation in a serum-free medium. Reconstructed epidermis were cultured for 15 days at the air-liquid interface with or without ultraviolet (UV) B exposure. The reconstructs were examined macroscopically (formation of hyperpigmented macules), histologically (pigment cell nesting) and ultrastructurally (pigment structure and transfer). Typical nesting of nevus cells was observed in the dermal-epidermal junction or in the superficial dermis associated with macroscopically detectable small pigmented macules. UVB exposure induced an upward migration of nevus cells in the suprabasal layers of the epidermis. This tissue model can be considered as an excellent system for the ex vivo reproduction of pigmented nevi and as an assay of the sensitivity of nevus cells towards UVB irradiation.     

An ex vivo study of congenital pigmented nevi in epidermal reconstructs.

In order to study morphologic and functional characteristics of pigment cells in congenital pigmented nevi, autologous or heterologous reconstructs have been made using normal keratinocytes and nevus cells from the dermal-epidermal junction or from the dermis. All these cells, keratinocytes and nevus cells, were used as cell suspensions immediately after dissociation from the tissues or after subsequent brief cultivation in a serum-free medium. Reconstructed epidermis were cultured for 15 days at the air-liquid interface with or without ultraviolet (UV) B exposure. The reconstructs were examined macroscopically (formation of hyperpigmented macules), histologically (pigment cell nesting) and ultrastructurally (pigment structure and transfer). Typical nesting of nevus cells was observed in the dermal-epidermal junction or in the superficial dermis associated with macroscopically detectable small pigmented macules. UVB exposure induced an upward migration of nevus cells in the suprabasal layers of the epidermis. This tissue model can be considered as an excellent system for the ex vivo reproduction of pigmented nevi and as an assay of the sensitivity of nevus cells towards UVB irradiation.     

In vivo and in vitro evidence of dermal fibroblasts influence on human epidermal pigmentation

Using chimeric human epidermal reconstructs, we previously demonstrated that epidermal pigmentation is dependent upon the phototype of melanocytes. We report here several lines of experimental evidence for dermal modulation of human epidermal pigmentation. First, phototype II-III epidermal reconstructs grafted on the back of immunotolerant Swiss nu/nu mice developed a patchy pigmentation dependent on the presence of colonizing human or mouse fibroblasts. Similarly, human white Caucasoid split-thickness skin xenografted on the same mouse strain became black within 3 months and histochemistry revealed a phototype VI pattern of melanin distribution. In vitro, human fibroblasts colonizing human dead de-epidermized dermis (DDD) induced a decrease in epidermal pigmentation whereas mouse (Swiss nu/nu) fibroblasts increased epidermal pigmentation. Conditioned medium from mice (Swiss nu/nu) fibroblasts also increased pigmentation whereas conditioned medium from human fibroblasts had no significant effect. Lastly, epidermal reconstructs made with normal or vitiligo keratinocytes and/or normal or vitiligo melanocytes from the same donor grown on DDD originating from several donors of the same clinical phototype did not pigment similarly and no specific dermal influence was noted for vitiligo. Thus, fibroblast secretion and acellular dermal connective tissue itself significantly influence melanocyte proliferation and melanin distribution/degradation. Our study suggests that murine fibroblasts are more potent than human fibroblasts in secreting soluble factors which can act directly on pigmentation, such as SCF, or activate keratinocytes to produce basement membrane proteins or melanogenic factors.     

The usefulness of c-Kit in the immunohistochemical assessment of melanocytic lesions

C-Kit (CD117), the receptor for the stem cell factor, a growth factor for melanocyte migration and proliferation, has shown differential immunostaining in various benign and malignant melanocytic lesions. The purpose of this study is to compare c-Kit immunostaining in benign nevi and in primary and metastatic malignant melanomas, to determine whether c-Kit can aid in the differential diagnosis of these lesions. c-Kit immunostaining was performed in 60 cases of pigmented lesions, including 39 benign nevi (5 blue nevi, 5 intradermal nevi, 3 junctional nevi, 15 cases of primary compound nevus, 11 cases of Spitz nevus), 18 cases of primary malignant melanoma and 3 cases of metastatic melanoma. The vast majority of nevi and melanomas examined in this study were positive for c-Kit, with minimal differences between benign and malignant lesions. C-Kit cytoplasmatic immunoreactivity in the intraepidermal proliferating nevus cells, was detected in benign pigmented lesions as well as in malignant melanoma, increasing with the age of patients (P=0.007) in both groups. The patient's age at presentation appeared to be the variable able to cluster benign and malignant pigmented lesions. The percentage of c-Kit positive intraepidermal nevus cells was better associated with age despite other variables (P=0.014). The intensity and percentage of c-Kit positivity in the proliferating nevus cells in the dermis was significantly increased in malignant melanocytic lesions (P=0.015 and P=0.008) compared to benign lesions (compound melanocytic nevi, Spitz nevi, intradermal nevi, blue nevi). Immunostaning for c-Kit in metastatic melanomas was negative. Interestingly in two cases of melanoma occurring on a pre-existent nevus, the melanoma tumor cells showed strong cytoplasmatic and membranous positivity for c-kit, in contrast with the absence of any immunoreactivity in pre-existent intradermal nevus cells. C-Kit does not appear to be a strong immunohistochemical marker for distinguishing melanoma from melanocytic nevi, if we consider c-Kit expression in intraepidermal proliferating cells. The c-Kit expression in proliferating melanocytes in the dermis could help in the differential diagnosis between a superficial spreading melanoma (with dermis invasion) and a compound nevus or an intradermal nevus. Finally, c-Kit could be a good diagnostic tool for distinguishing benign compound nevi from malignant melanocytic lesions with dermis invasion and to differentiate metastatic melanoma from primary melanoma.     

The Three-Dimensional Human Skin Reconstruct Model: a Tool to Study Normal Skin and Melanoma Progression

Most in vitro studies in experimental skin biology have been done in 2-dimensional (2D) monocultures, while accumulating evidence suggests that cells behave differently when they are grown within a 3D extra-cellular matrix and also interact with other cells (1-5). Mouse models have been broadly utilized to study tissue morphogenesis in vivo. However mouse and human skin have significant differences in cellular architecture and physiology, which makes it difficult to extrapolate mouse studies to humans. Since melanocytes in mouse skin are mostly localized in hair follicles, they have distinct biological properties from those of humans, which locate primarily at the basal layer of the epidermis. The recent development of 3D human skin reconstruct models has enabled the field to investigate cell-matrix and cell-cell interactions between different cell types. The reconstructs consist of a "dermis" with fibroblasts embedded in a collagen I matrix, an "epidermis", which is comprised of stratified, differentiated keratinocytes and a functional basement membrane, which separates epidermis from dermis. Collagen provides scaffolding, nutrient delivery, and potential for cell-to-cell interaction. The 3D skin models incorporating melanocytic cells recapitulate natural features of melanocyte homeostasis and melanoma progression in human skin. As in vivo, melanocytes in reconstructed skin are localized at the basement membrane interspersed with basal layer keratinocytes. Melanoma cells exhibit the same characteristics reflecting the original tumor stage (RGP, VGP and metastatic melanoma cells) in vivo. Recently, dermal stem cells have been identified in the human dermis (6). These multi-potent stem cells can migrate to the epidermis and differentiate to melanocytes.     

Interactions of Melanocytes and Melanoma Cells With the Microenvironment

Normal or malignant melanocytes interact with the microenvironment through the release of soluble factors from cells and through direct cell-cell contact. Melanoma cells produce a large number of different growth factors and cytokines that affect angiogenesis, stroma formation, motility, and the inflammatory and immune response. Most of the angiogenic growth factors produced by melanoma cells are also mitogenic for fibroblasts. The mechanisms and the receptors involved in direct cell-cell contacts of melanocytes and melanoma cells are largely unknown, but the regulatory role of keratinocytes for melanocytic cells appears at several levels. Keratinocytes induce a dendritic morphology in melanocytes, and control proliferation to maintain a constant keratinocyte/melanocyte ratio during exponential growth. Expression of cell surface adhesion receptors is controlled by keratinocytes on melanocytes and nevus cells but not on advanced melanoma cells. These studies underline the complex interactions between skin cells. The escape of melanocytes from the control by keratinocytes may be a hallmark of nevus cells, and the constitutive production of various growth factors and cytokines appears to represent a major characteristic of melanoma cells.     

Fibroblasts play a regulatory role in the control of pigmentation in reconstructed human skin from skin types I and II

Human melanocytes in monolayer culture are extremely dependent on a wide range of soluble signals for their proliferation and melanogenesis. The advent of three-dimensional models of reconstructed skin allows one to ask questions of how these cells are regulated within a setting which more closely approximates normal skin. The purpose of this study was to investigate to what extent melanocytes within a reconstructed skin model are sensitive to regulation by dermal fibroblasts, basement membrane (BM) proteins and the addition of alpha-melanocyte-stimulating hormone (alpha-MSH). Sterilized acellular de-epidermized dermis (prepared to retain BM proteins or deliberately denuded of BM by enzymatic treatment) from skin type I or II was reconstituted with fibroblasts, melanocytes and keratinocytes. In all but one case (9/10), cell donors were skin type I or II. The presence of BM antigens was found to be necessary for positional orientation of the melanocytes; in the absence of BM, melanocytes moved into the upper keratinocyte layer pigmenting spontaneously. Addition of fibroblasts suppressed the extent of spontaneous pigmentation of melanocytes within this model. Neither alpha-MSH nor cholera toxin induced pigmentation in this model despite the fact that melanocytes clearly had the ability to synthesize pigment.     

Mechanical Properties of Growing Melanocytic Nevi and the Progression to Melanoma

Melanocytic nevi are benign proliferations that sometimes turn into malignant melanoma in a way that is still unclear from the biochemical and genetic point of view. Diagnostic and prognostic tools are then mostly based on dermoscopic examination and morphological analysis of histological tissues. To investigate the role of mechanics and geometry in the morpholgical dynamics of melanocytic nevi, we study a computation model for cell proliferation in a layered non-linear elastic tissue. Numerical simulations suggest that the morphology of the nevus is correlated to the initial location of the proliferating cell starting the growth process and to the mechanical properties of the tissue. Our results also support that melanocytes are subject to compressive stresses that fluctuate widely in the nevus and depend on the growth stage. Numerical simulations of cells in the epidermis releasing matrix metalloproteinases display an accelerated invasion of the dermis by destroying the basal membrane. Moreover, we suggest experimentally that osmotic stress and collagen inhibit growth in primary melanoma cells while the effect is much weaker in metastatic cells. Knowing that morphological features of nevi might also reflect geometry and mechanics rather than malignancy could be relevant for diagnostic purposes.     

Comparison of Long‐Term Survival of Pigmented Epidermal Reconstructs Cultured In Vitro vs. Xenografted on Nude Mice

Epidermal reconstructs incorporating pigment cells have been used in vitro over the last decade to study the physiology of the epidermal melanin unit. However, the major limitation of this technology is the duration of the assays, which need to be completed within 2–3 weeks to obviate the problem of epidermal senescence and excessive terminal differentiation. This becomes a major problem for studying long‐term biological phenomena in photoprotection and epidermal skin cancers. We report here a simplified surgical technique in immunotolerant mice allowing long‐term studies. The creation of a vascularized mouse skin flap is the key point of the surgical procedure. Long‐term pigmentation of the xenografts seemed macroscopically successful, but surprisingly microscopy at 11 and 16 weeks postgrafting showed mostly dermal pigment aggregates and rare Melan‐A positive dermal and epidermal pigment cells. In the same reconstructs maintained in vitro, dermal pigment and dermal pigment cells were never noted. It could be speculated that in our model, the colonization of the xenografted dead human dermis by murine cells influences melanocyte survival.     

Comparison of long-term survival of pigmented epidermal reconstructs cultured in vitro vs. xenografted on nude mice

Epidermal reconstructs incorporating pigment cells have been used in vitro over the last decade to study the physiology of the epidermal melanin unit. However, the major limitation of this technology is the duration of the assays, which need to be completed within 2-3 weeks to obviate the problem of epidermal senescence and excessive terminal differentiation. This becomes a major problem for studying long-term biological phenomena in photoprotection and epidermal skin cancers. We report here a simplified surgical technique in immunotolerant mice allowing long-term studies. The creation of a vascularized mouse skin flap is the key point of the surgical procedure. Long-term pigmentation of the xenografts seemed macroscopically successful, but surprisingly microscopy at 11 and 16 weeks postgrafting showed mostly dermal pigment aggregates and rare Melan-A positive dermal and epidermal pigment cells. In the same reconstructs maintained in vitro, dermal pigment and dermal pigment cells were never noted. It could be speculated that in our model, the colonization of the xenografted dead human dermis by murine cells influences melanocyte survival.     

Use of monoclonal antibody 225.28S in the study of nevus cells in culture

The aim of this work is to identify and purify cultured nevus cells. We used for our study monoclonal antibody 225.28S. This antibody reacts with a surface antigen which is expressed by nevus cells and melanoma cells, but it does not react with normal melanocytes. We studied 10 dermic nevi and we observed that antigenic determinant survives in cultured nevus cells. These results allowed us to employ the method of panning for purify cultured nevus cells.     

Monoclonal Antibody MAT-1 Against Human Tyrosinase Can Detect Melanogenic Cells on Formalin-Fixed Paraffin-Embedded Sections

Immunohistochemical localization of tyrosinase was examined with a monoclonal antibody (MoAb MAT-1) against human tyrosinase on routine formalin-fixed paraffin-embedded sections of 3 normal skin specimens, 15 melanocytic tumors (6 pigmented nevi, 3 juvenile melanomas and 6 malignant melanomas) and 3 non-melanocytic tumors. In the melanotic melanomas, almost all tumor cells were clearly stained with the antibody. In the nevocytic nevi, the nevus cells in lower epidermis and upper dermis were positive for MoAb MAT-1, but negative in middle and lower dermis. All three juvenile melanomas, one amelanotic melanoma, and three non-melanocytic tumors were entirely negative for MoAb MAT-1. Thus, MoAb MAT-1 could recognize the cells with melanogenic activity on routine formalin-fixed paraffin-embedded sections. However, the staining quality was not adequate for normal epidermal melanocytes, indicating that small technical innovations in the immunostaining process such as formalin fixation after PBS washing are required. Nevertheless, MoAb MAT-1 can be expected to be very useful for identifying melanogenic cells on paraffin-embedded sections, because we have to date no other antibody available for it.     

Human skin reconstruct models: a new application for studies of melanocyte and melanoma biology

Studies of melanocyte and melanoma biology using monocultures of cells are limited because of culture-induced morphology changes and expression of genes related to growth, migration, and invasion, which do not reflect the in situ phenotype of normal melanocytes, nevus cells, or melanoma cells from biologically early progression stages. The development of organotypic cultures of human skin, in which culture artifacts are greatly diminished and cell-matrix and cell-cell interactions between different cell types can be investigated in a three-dimensional system, has opened a new era for melanoma research. Long-term in vivo studies, especially important for melanomagenesis and melanoma metastasis have become possible through grafting of skin reconstructs to immunodeficient laboratory animals. In this review, principles and different methods of skin reconstruction are introduced with focus on the application for pigment cell biology.     

Collagen XVII is expressed in malignant but not in benign melanocytic tumors and it can mediate antibody induced melanoma apoptosis

The 180?kDa transmembrane collagen XVII is known to anchor undifferentiated keratinocytes to the basement membrane in hemidesmosomes while constitutively shedding a 120?kDa ectodomain. Inherited mutations or auto-antibodies targeting collagen XVII cause blistering skin disease. Collagen XVII is down-regulated in mature keratinocytes but re-expressed in skin cancer. By recently detecting collagen XVII in melanocyte hyperplasia, here we tested its expression in benign and malignant melanocytic tumors using endodomain and ectodomain selective antibodies. We found the full-length collagen XVII protein in proliferating tissue melanocytes, basal keratinocytes and squamous cell carcinoma whereas resting melanocytes were negative. Furthermore, the cell-residual 60?kDa endodomain was exclusively detected in 62/79 primary and 15/18 metastatic melanomas, 8/9 melanoma cell lines, HT199 metastatic melanoma xenografts and atypical nests in 8/63 dysplastic nevi. The rest of 19 nevi including common, blue and Spitz subtypes were also negative. In line with the defective ectodomain, sequencing of COL17A1 gene revealed aberrations in the ectodomain coding region including point mutations. Collagen XVII immunoreaction-stained spindle cell melanomas, showed partly overlapping profiles with those of S100B, Melan A and HMB45. It was concentrated at vertical melanoma fronts and statistically associated with invasive phenotype. Antibody targeting the extracellular aa507-529 terminus of collagen XVII endodomain promoted apoptosis and cell adhesion, while inhibiting proliferation in HT199 cells. These results suggest that the accumulation of collagen XVII endodomain in melanocytic tumors is associated with malignant transformation to be a potential marker of malignancy and a target for antibody-induced melanoma apoptosis.     

Identification of functional markers in a self-assembled skin substitute in vitro

Some functional parameters were identified and assessed in a tissue-engineered self-assembled skin substitute. This skin substitute was produced using fibroblasts and keratinocytes isolated from adult human skin. Keratinocytes were seeded on a dermal layer, composed of two fibroblast sheets cultured for 35 d. The epidermal cells formed a stratified and cornified epidermis and expressed differentiation markers, notably involucrin and transglutaminase. Interestingly and for the first time, the receptor for vitamin D3 was detected in all of the epidermal cell layers of the skin substitute, as it is reported for normal human skin. This observation suggests that keratinocytes retain key receptors during their differentiation in the skin model. A network of collagen fibers was observed by electron microscopy in the dermal layer of the model. In the dermis, collagen fibers remodeling and assembly is dependent on enzymes, notably prolyl-4-hydroxylase. For the first time in a skin construct, the expression of prolyl-4-hydroxylase was detected in dermal fibroblasts by in situ hybridization. The secretion of collagenases by the cells seeded in our skin substitute was confirmed by zymography. We conclude that the self-assembly approach allows the maintenance of several functional activities of human skin cells in a skin model in vitro.     

Application of morphometric methods to the cytologic study of intradermal nevi.

Twenty-one intradermal nevi were studied by morphometric methods in an attempt to morphologically characterize the two types of nevus cell--epithelioids, type A, and fusiforms, type C--and to quantify the differences between them. Morphometric parameters of the intradermal nevi were compared with similar parameters of melanocytes and melanoma cells so that the maturation rates of the nevi cells could be established and to see if the parameters might indicate the degree of malignancy. Superficial nevus cells were differentiated from deep cells by their larger size and larger nuclear area. Nuclear area appeared to have potential for differentiating benign from malignant tumors. Decrease in cellular area appeared to indicate maturation rather than atrophy. Melanoma cells were differentiated by their larger size. Cell nuclear perimeter appeared to have confirmatory value, while cell perimeter was inconclusive.