Endothelin 3 induces skin pigmentation in a keratin-driven inducible mouse model

Endothelin 3 (Edn3) is a ligand important to developing neural crest cells (NCC). Some NCC eventually migrate into the skin and give rise to the pigment-forming melanocytes found in hair follicles. Edn3's effects on NCC have been largely explored through spontaneous mutants and cell culture experiments. These studies have shown the Endothelin receptor B/Edn3 signaling pathway to be important in the proliferation/survival and differentiation of developing melanocytes. To supplement these investigations I have created doxycycline-responsive transgenic mice which conditionally over-express Edn3. These mice will help us clarify Edn3's role during the development of early embryonic melanoblasts, differentiating melanocyte precursors in the skin, and fully differentiated melanocytes in the hair follicle. The transgene mediated expression of Edn3 was predominantly confined to the roof plate of the neural tube and surface ectoderm in embryos and postnatally in the epidermal keratinocytes of the skin. Relative to littermate controls, transgenics develop increased pigmentation on most areas of the skin. My doxycycline-based temporal studies have shown that both embryonic and postnatal events are important for establishing and maintaining pigmented skin. The study of my Edn3 transgenic mice may offer some insight into the genetics behind benign dermal pigmentation and offer clues about the time periods important in establishing these conditions. This apparently abnormal development is echoed in a benign condition of human skin. Cases of dermal melanocytosis, such as common freckles, Mongolian spotting, and nevus of Ito demonstrate histological and etiological characteristics similar to those of the transgenic mice generated in this study.

Estudio molecular en dos hermanas afectadas por ictiosis congénita autosómica recesiva : descripción de una nueva mutación causal en TGM1

Se describe la variante homocigota c.320-2A>G de TGM1 en dos hermanas con ictiosis congénita autosómica recesiva. El clonaje de los transcritos generados por esta variante permitió identificar tres mecanismos moleculares de splicing alternativos.

Inhibition of 125I-epidermal growth factor binding to murine fibroblasts and keratinocytes by irradiation with ultraviolet-B light

Treatment of murine Swiss 3T3 fibroblasts and XB/2 keratinocytes with UV-B light (302 nm) resulted in a dose-dependent inhibition of [125I] epidermal growth factor (EGF) binding. The light dose required to achieve 50% inhibition of binding in both cell types was 80–85 J/m2 Decreased [125I] platelet-derived growth factor binding was not evoked even by light doses of up to 280 J/m2 UV-B irradiation did not stimultate phosphorylation of the 80 kd protein substrate for protein kinase C. Furthermore, its effect on [125I]EGF binding was not altered as a consequence of protein kinase C down-regulation following prolonged exposure of cells to phorbol esters. These results indicate that UV-B-induced transmodulation of the epidermal growth factor receptor is a specific event mediated through a protein kinase C-indepen dent pathway. Transfer of culture medium from irradiated cells to untreated control cells showed this effect was not induced as a result of transforming growth factor α release and subsequent binding to the EGF receptor in these cells.

Regulation of Bcl-xL expression in human keratinocytes by cell–substratum adhesion and the epidermal growth factor receptor

Cell–substratum adhesion is an essential requirement for survival of human neonatal keratinocytes in vitro. Similarly, activation of the epidermal growth factor receptor (EGF-R) has recently been implicated not only in cell cycle progression but also in survival of normal keratinocytes. The mechanisms by which either cell–substratum adhesion or EGF-R activation protect keratinocytes from programmed cell death are poorly understood. Here we describe that blockade of the EGF-R and inhibition of substratum adhesion share a common downstream event, the down-regulation of the cell death protector Bcl-xL. Expression of Bcl-xL protein was down-regulated during forced suspension culture of keratinocytes, concurrent with large-scale apoptosis. Similarly, EGF-R blockade was accompanied by down-regulation of Bcl-xL steady-state mRNA and protein levels to an extent comparable to that observed in forced suspension culture. However, down-regulation of Bcl-xL expression by EGF-R blockade was not accompanied by apoptosis; in this case, a second signal, generated by passaging, was required to induce rapid and large-scale apoptosis. These findings are consistent with the conclusions that (i) Bcl-xL represents a shared molecular target for signaling through cell-substrate adhesion receptors and the EGF-R, and (ii) reduced levels of Bcl-xL expression through EGF-R blockade lower the tolerance of keratinocytes for cell death signals generated by cellular stress.

Multiphoton high-resolution 3D imaging of Langerhans cells and keratinocytes in the mouse skin model adopted for epidermal powdered immunization

Langerhans cells (LCs) can be targeted with DNA-coated gold micro-projectiles ("Gene Gun") to induce potent cellular and humoral immune responses. It is likely that the relative volumetric distribution of LCs and keratinocytes within the epidermis impacts on the efficacy of Gene Gun immunization protocols. This study quantified the three-dimensional (3D) distribution of LCs and keratinocytes in the mouse skin model with a near-infrared multiphoton laser-scanning microscope (NIR-MPLSM). Stratum corneum (SC) and viable epidermal thickness measured with MPLSM was found in close agreement with conventional histology. LCs were located in the vertical plane at a mean depth of 14.9 mum, less than 3 mum above the dermo-epidermal boundary and with a normal histogram distribution. This likely corresponds to the fact that LCs reside in the suprabasal layer (stratum germinativum). The nuclear volume of keratinocytes was found to be approximately 1.4 times larger than that of resident LCs (88.6 mum3). Importantly, the ratio of LCs to keratinocytes in mouse ear skin (1:15) is more than three times higher than that reported for human breast skin (1:53). Accordingly, cross-presentation may be more significant in clinical Gene Gun applications than in pre-clinical mouse studies. These interspecies differences should be considered in pre-clinical trials using mouse models.

Active regulation of the epidermal calcium profile

A distinct calcium profile is strongly implicated in regulating the multi-layered structure of the epidermis. However, the mechanisms that govern the regulation of this calcium profile are currently unclear. It clearly depends on the relatively impermeable barrier of the stratum corneum (passive regulation) but may also depend on calcium exchanges between keratinocytes and extracellular fluid (active regulation). Using a mathematical model that treats the viable sublayers of unwounded human and murine epidermis as porous media and assumes that their calcium profiles are passively regulated, we demonstrate that these profiles are also actively regulated. To obtain this result, we found that diffusion governs extracellular calcium motion in the viable epidermis and hence intracellular calcium is the main source of the epidermal calcium profile. Then, by comparison with experimental calcium profiles and combination with a hypothesised cell velocity distribution in the viable epidermis, we found that the net influx of calcium ions into keratinocytes from extracellular fluid may be constant and positive throughout the stratum basale and stratum spinosum, and that there is a net outflux of these ions in the stratum granulosum. Hence the calcium exchange between keratinocytes and extracellular fluid differs distinctly between the stratum granulosum and the underlying sublayers, and these differences actively regulate the epidermal calcium profile. Our results also indicate that plasma membrane dysfunction may be an early event during keratinocyte disintegration in the stratum granulosum.

Characterisation of a human skin equivalent model to study the effects of ultraviolet B radiation on keratinocytes

The incidences of skin cancers resulting from chronic ultraviolet radiation (UVR) exposure are on the incline both in Australia and globally. Hence, the cellular and molecular pathways associated with UVR-induced photocarcinogenesis urgently need to be elucidated, in order to develop more robust preventative and treatment strategies against skin cancers. In vitro investigations into the effects of UVR (in particular the highly-mutagenic UVB wavelength) have, to date, mainly involved the use of cell culture and animal models. However, these models possess biological disparities to native skin, which to some extent have limited their relevance to the in vivo situation. To address this, we characterised a 3-dimensional, tissue-engineered human skin equivalent (HSE) model (consisting of primary human keratinocytes cultured on a dermal-derived scaffold) as a representation of a more physiologically-relevant platform to study keratinocyte responses to UVB. Significantly, we demonstrate that this model retains several important epidermal properties of native skin. Moreover, UVB-irradiation of the HSE constructs was shown to induce key markers of photodamage in the HSE keratinocytes, including the formation of cyclobutane pyrimidine dimers, the activation of apoptotic pathways, the accumulation of p53 and the secretion of inflammatory cytokines. Importantly, we also demonstrate that the UVB-exposed HSE constructs retain the capacity for epidermal repair and regeneration following photodamage. Together, our results demonstrate the potential of this skin equivalent model as a tool to study various aspects of the acute responses of human keratinocytes to UVB radiation damage.

Towards a quantitative theory of epidermal calcium profile formation in unwounded skin

We propose and mathematically examine a theory of calcium profile formation in unwounded mammalian epidermis based on: changes in keratinocyte proliferation, fluid and calcium exchange with the extracellular fluid during these cells' passage through the epidermal sublayers, and the barrier functions of both the stratum corneum and tight junctions localised in the stratum granulosum. Using this theory, we develop a mathematical model that predicts epidermal sublayer transit times, partitioning of the epidermal calcium gradient between intracellular and extracellular domains, and the permeability of the tight junction barrier to calcium ions. Comparison of our model's predictions of epidermal transit times with experimental data indicates that keratinocytes lose at least 87% of their volume during their disintegration to become corneocytes. Intracellular calcium is suggested as the main contributor to the epidermal calcium gradient, with its distribution actively regulated by a phenotypic switch in calcium exchange between keratinocytes and extracellular fluid present at the boundary between the stratum spinosum and the stratum granulosum. Formation of the extracellular calcium distribution, which rises in concentration through the stratum granulosum towards the skin surface, is attributed to a tight junction barrier in this sublayer possessing permeability to calcium ions that is less than 15 nm/s in human epidermis and less than 37 nm/s in murine epidermis. Future experimental work may refine the presented theory and reduce the mathematical uncertainty present in the model predictions.

Genome-wide analysis of p63 binding sites identifies AP-2 factors as co-regulators of epidermal differentiation

The p63 transcription factor (TP63) is critical in development, growth and differentiation of stratifying epithelia. This is highlighted by the severity of congenital abnormalities caused by TP63 mutations in humans, the dramatic phenotypes in knockout mice and de-regulation of TP63 expression in neoplasia altering the tumour suppressive roles of the TP53 family. In order to define the normal role played by TP63 and provide the basis for better understanding how this network is perturbed in disease, we used chromatin immunoprecipitation combined with massively parallel sequencing (ChIP-seq) to identify >7500 high-confidence TP63-binding regions across the entire genome, in primary human neonatal foreskin keratinocytes (HFKs). Using integrative strategies, we demonstrate that only a subset of these sites are bound by TP53 in response to DNA damage. We identify a role for TP63 in transcriptional regulation of multiple genes genetically linked to cleft palate and identify AP-2alpha (TFAP2A) as a co-regulator of a subset of these genes. We further demonstrate that AP-2gamma (TFAP2C) can bind a subset of these regions and that acute depletion of either TFAP2A or TFAP2C alone is sufficient to reduce terminal differentiation of organotypic epidermal skin equivalents, indicating overlapping physiological functions with TP63.

Melanosome transfer between melanocytes and keratinocytes

RESUMO: A pele é o maior órgão do corpo humano e a sua pigmentação é essencial para a sua coloração e proteção contra os efeitos nocivos da radiação ultravioleta (UV). A pigmentação da pele resulta essencialmente de três processos: a síntese e o armazenamento de melanina pelos melanócitos, em organelos especializados denominados melanossomas; o transporte dos melanossomas dentro dos melanócitos; e finalmente, a transferência dos melanossomas para os queratinócitos adjacentes. Nos queratinócitos, a melanina migra para a região perinuclear apical da célula para formar um escudo protetor,responsável pela proteção do DNA dos danos causados pela radiação UV. Os melanócitos estão localizados na camada basal da epiderme e contactam com 30-40 queratinócitos. Em conjunto, estas células formam a “unidade melano-epidérmica”. Apesar dos processos de síntese e transporte de melanina nos melanócitos estarem bastante bem caracterizados, os mecanismos moleculares subjacentes à transferência inter-celular de melanina são menos conhecidos e ainda controversos. Dados preliminares obtidos pelo nosso grupo, que se basearam na observação de amostras de pele humana por microscopia electrónica, indicam que a forma predominante de transferência de melanina na epiderme consiste na exocitose dos melanossomas pelos melanócitos e subsequente endocitose da melanina por queratinócitos. Para além disso sabe-se que as proteínas Rab, que controlam o tráfego membranar, estão envolvidas em várias etapas de pigmentação da pele, nomeadamente na biogénese e no transporte de melanina. Assim, dado o seu papel fundamental nestes processos, questionámo-nos sobre o seu envolvimento na transferência de melanina. Com este trabalho, propomo-nos a expandir o conhecimento atual sobre a transferência de melanina na pele, através do estudo detalhado dos seus mecanismos moleculares, identificando as proteínas Rab que regulam o processo. Pretendemos também confirmar o modelo de exo/endocitose como sendo o mecanismo principal de transferência de melanina. Primeiro, explorámos a regulação da secreção de melanina pelos melanócitos e analisámos o papel de proteínas Rab neste processo. Os resultados foram obtidos recorrendo a um método in vitro, desenvolvido previamente no laboratório, que avalia a quantidade de melanina segregada para o meio de cultura por espectrofotometria, e ainda por microscopia, contando o número de melanossomas transferidos para os queratinócitos. Através de co-culturas de melanócitos e queratinócitos, verificou-se que os queratinócitos estimulam a libertação de melanina dos melanócitos para o meio extra-celular, bem como a sua transferência para os queratinócitos. Além disso, a proteína Rab11b foi identificada como um regulador da exocitose de melanina e da sua transferência para os queratinócitos. De facto, a diminuição da expressão de Rab11b em melanócitos provocou a redução da secreção de melanina estimulada por queratinócitos, bem como da transferência desta. Em segundo lugar, para complementar o nosso estudo, centrámos a nossa investigação na internalização de melanina por queratinócitos. Especificamente, usando uma biblioteca de siRNA, explorámos o envolvimento de proteínas Rab na captação de melanina por queratinócitos. Como primeira abordagem, usámos esferas fluorescentes como substituto de melanina, avaliando os resultados por citometria de fluxo. No entanto, este método revelou-se ineficaz uma vez que a internalização destas esferas é independente do recetor PAR-2 (recetor 2 ativado por protease), que foi previamente descrito como essencial na captação de melanina por queratinócitos Posteriormente, foi desenvolvido um novo protocolo de endocitose baseado em microscopia, usando melanossomas sem a membrana envolvente (melanocores) purificados do meio de cultura de melanócitos, incluindo um programa informático especialmente desenhado para realizar uma análise semi-automatizada. Após internalização, os melanocores acumulam-se na região perinuclear dos queratinócitos, em estruturas que se assemelham ao escudo supranuclear observado na pele humana. Seguidamente, o envolvimento do recetor PAR-2 na captação de melanocores por queratinócitos foi confirmado, utilizando o novo protocolo de endocitose desenvolvido. Para além disso, a necessidade de quatro proteínas Rab foi identificada na internalização de melanocores por queratinócitos. A redução da expressão de Rab1a ou Rab5b em queratinócitos diminuiu significativamente o nível de internalização de melanocores, enquanto o silenciamento da expressão de Rab2a ou Rab14 aumentou a quantidade de melanocores internalizados por estas células. Em conclusão, os resultados apresentados corroboram as observações anteriores, obtidas em amostras de pele humana, e sugerem que o mecanismo de transferência predominante é a exocitose de melanina pelos melanócitos, induzida por queratinócitos, seguida por endocitose pelos queratinócitos. A pigmentação da pele tem implicações tanto ao nível da cosmética, como ao nível médico, relacionadas com foto-envelhecimento e com doenças pigmentares. Assim sendo, ao esclarecer quais os mecanismos moleculares que regulam a transferência de melanina na pele, este trabalho pode conduzir ao desenvolvimento de novas estratégias para modular a pigmentação da pele.----------------ABSTRACT: Skin pigmentation is achieved through the highly regulated production of the pigment melanin in specialized organelles, termed melanosomes within melanocytes. These are transported from their site of synthesis to the melanocyte periphery before being transferred to keratinocytes where melanin forms a supra-nuclear cap to protect the DNA from UVinduced damage. Together, melanocytes and keratinocytes form a functional complex, termed “epidermal-melanin unit”, that confers color and photoprotective properties to the skin. Skin pigmentation requires three processes: the biogenesis of melanin; its intracelular transport within the melanocyte to the cell periphery; and the melanin transfer to keratinocytes. The first two processes have been extensively characterized. However, despite significant advances that have been made over the past few years, the mechanisms underlying inter-cellular transfer of pigment from melanocytes to keratinocytes remain controversial.Preliminary studies from our group using electron microscopy and human skin samples found evidence for a mechanism of coupled exocytosis-endocytosis. Rab GTPases are master regulators of intracellular trafficking and have already been implicated in several steps of skin pigmentation. Thus, we proposed to explore and characterize the molecular mechanisms of melanin transfer and the role of Rab GTPases in this process. Moreover, we investigated whether the exo/endocytosis model is the main mechanism of melanin transfer. We first focused on melanin exocytosis by melanocytes. Then, we started to investigate the key regulatory Rab proteins involved in this step by establishing an in vitro tissue culture model of melanin secretion. Using co-cultures of melanocytes and keratinocytes, we found that keratinocytes stimulate melanin release and transfer. Moreover, depletion of Rab11b decreases keratinocyte-induced melanin exocytosis by melanocytes. In order to determine whether melanin exocytosis is a predominant mechanism of melanin transfer, the amount of melanin transferred to keratinocytes was then assayed in conditions where melanin exocytosis was inhibited. Indeed, Rab11b depletion resulted in a significant decrease in melanin uptake by keratinocytes. Taken together, these observations suggest that Rab11b mediates melanosome exocytosis from melanocytes and transfer to keratinocytes. To complement and extend our study, we of melanin by keratinocytes. Thus, we aimed to explore the effect of depleting Rab GTPases on melanin uptake and trafficking within keratinocytes. As a first approach, we used fluorescent microspheres as a melanin surrogate. However, the uptake of microspheres was observed to be independent of PAR-2, a receptor that is required for melanin uptakecentred our attention in the internalization of melanin by keratinocytes. Thus, we aimed to explore the effect of depleting Rab GTPases on melanin uptake and trafficking within keratinocytes. As a first approach, we used fluorescent microspheres as a melanin surrogate. However, the uptake of microspheres was observed to be independent of PAR-2, a receptor that is required for melanin uptake.Therefore, we concluded that microspheres were uptaken by keratinocytes through a different pathway than melanin. Subsequently, we developed a microscopy-based endocytosis assay using purified melanocores (melanosomes lacking the limiting membrane) from melanocytes, including a program to perform a semi-automated analysis. Melanocores are taken up by keratinocytes and accumulate in structures in the perinuclear area that resemble the physiological supranuclear cap observed in human skin. We then confirmed the involvement of PAR-2 receptor in the uptake of melanocores by keratinocytes, using the newly developed assay. Furthermore, we identified the role of four Rab GTPases on the uptake of melanocores by keratinocytes. Depletion of Rab1a and Rab5b from keratinocytes significantly reduced the uptake of melanocores, whereas Rab2a, and Rab14 silencing increased the amount the melanocores internalized by XB2 keratinocytes. In conclusion, we present evidence supporting keratinocyte-inducedmelanosome exocytosis from melanocytes, followed by endocytosis of the melanin core by keratinocytes as the predominant mechanism of melanin transfer in skin. Although advances have been made, there is a need for more effective and safer therapies directed at pigmentation disorders and also treatments for cosmetic applications. Hence, the understanding of the above mechanisms of skin pigmentation will lead to a greater appreciation of the molecular machinery underlying human skin pigmentation and could interest the pharmaceutical and cosmetic industries.

EGFR signalling as a negative regulator of Notch1 gene transcription and function in proliferating keratinocytes and cancer.

The Notch1 gene has an important role in mammalian cell-fate decision and tumorigenesis. Upstream control mechanisms for transcription of this gene are still poorly understood. In a chemical genetics screen for small molecule activators of Notch signalling, we identified epidermal growth factor receptor (EGFR) as a key negative regulator of Notch1 gene expression in primary human keratinocytes, intact epidermis and skin squamous cell carcinomas (SCCs). The underlying mechanism for negative control of the Notch1 gene in human cells, as well as in a mouse model of EGFR-dependent skin carcinogenesis, involves transcriptional suppression of p53 by the EGFR effector c-Jun. Suppression of Notch signalling in cancer cells counteracts the differentiation-inducing effects of EGFR inhibitors while, at the same time, synergizing with these compounds in induction of apoptosis. Thus, our data reveal a key role of EGFR signalling in the negative regulation of Notch1 gene transcription, of potential relevance for combinatory approaches for cancer therapy.

The epithelial sodium channel mediates the directionality of galvanotaxis in human keratinocytes.

Cellular directional migration in an electric field (galvanotaxis) is one of the mechanisms guiding cell movement in embryogenesis and in skin epidermal repair. The epithelial sodium channel (ENaC), in addition to its function of regulating sodium transport in kidney, has recently been found to modulate cell locomotory speed. Here we tested whether ENaC has an additional function of mediating the directional migration of galvanotaxis in keratinocytes. Genetic depletion of ENaC completely blocks only galvanotaxis and does not decrease migration speed. Overexpression of ENaC is sufficient to drive galvanotaxis in otherwise unresponsive cells. Pharmacologic blockade or maintenance of the open state of ENaC also decreases or increases, respectively, galvanotaxis, suggesting that the channel open state is responsible for the response. Stable lamellipodial extensions formed at the cathodal sides of wild-type cells at the start of galvanotaxis; these were absent in the ENaC knockout keratinocytes, suggesting that ENaC mediates galvanotaxis by generating stable lamellipodia that steer cell migration. We provide evidence that ENaC is required for directional migration of keratinocytes in an electric field, supporting a role for ENaC in skin wound healing.

Assessment of apoptosis in epidermal lamellar cells in clinically normal horses and those with laminitis

Objective - To determine and compare the number, type, location, and distribution of apoptotic epidermal cells in the laminae of clinically normal horses and horses with laminitis.Sample Population - Formalin-fixed samples of digital lamellar tissue from 47 horses (including clinically normal horses [controls; n = 7], horses with acurte [4] and chronic [7] naturally acquired laminitis, and horses with black walnut extract-induced [11] or carbohydrate overload-induced [18] laminitis).Procedure - Blocks of paraffin-embedded lamellar tissues were stained for DNA fragmentation with the terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling (TUNEL) technique. Differential immunohistochemical staining for caspases 3 and 14 were used to confirm apoptosis.Results - the number of TUNEL-positive epidermal cells per 0.1 mm of primary laminae was significantly greater in the acute laminitis group than in the other groups. In the acute laminitis group, there were 17 and 1,025 times as many TUN EL-positive basal layer cells and keratinocytes, respectively, compared with the control group. Apoptosis of TUNEL-positive basal layer cells was confirmed by results of caspase 3 immunohistochemical staining. The TUNEL-positive keratinocytes did not stain for caspases 3 or 14.Conclusions and Clinical Relevance - the large number of apoptotic basal layer cells detected in the lamellar tissue of horses with acute naturally acquired laminitis suggests that apoptosis may be important in the development of acute laminitis. The role of the large number of TUNEL-positive keratinocytes detected in the interface of primary and secondary epidermal laminae of horses with acute laminitis remains to be elucidated.