ABSTRACT
The solar ultraviolet (UV) radiation that reaches the Earth is composed of 95% of UVA (320 to 400 nm) and 5% of UVB (280 to 320 nm) radiation. UVB is carcinogenic, generating potentially mutagenic DNA lesions. The solar UVA radiation also causes DNA damage, but this fact does not fully account for its biological impact. UVA is absorbed by non-DNA cellular chromophores, generating reactive oxygen species such as singlet oxygen. Knowing the proteome mediates stress responses in cells, here we investigated the cellular effects of a non-cytotoxic dose of UVA radiation, equivalent to about 20 minutes of midday sun exposure, on the proteome of human keratinocytes. Using a combination of mass spectrometry-based proteomics, bioinformatics, and conventional biochemical assays, we analyzed two aspects of UVA-induced stress: spatial remodeling of the proteome in subcellular compartments 30 minutes after stress and long-term changes in protein levels and secretion (24 hours and 7 days postirradiation). In the first part of this thesis, we quantified and assigned subcellular localization for over 3000 proteins, of which about 600 potentially redistribute upon UVA exposure. Protein redistributions were accompanied by redox modulations, mitochondrial fragmentation and DNA damage. In the second part of the work, our results showed that primary human keratinocytes enter senescence upon exposure to a single dose of UVA, mounting antioxidant and inflammatory responses. Cells under UVA-induced senescence further elicit paracrine responses in neighboring premalignant HaCaT epithelial cells via inflammatory mediators. Altogether, these results reiterate the role of UVA radiation as a potent metabolic stressor in the skin
A radiação ultravioleta (UV) solar que atinge a superfície terrestre é composta por 95% de radiação UVA (320 a 400 nm) e 5% de radiação UVB (280 a 320 nm). A radiação UVB é carcinogênica e gera lesões potencialmente mutagênicas no DNA. A radiação UVA solar também gera danos no DNA, mas a genotoxicidade dessa radiação não explica inteiramente o seu impacto biológico. Atualmente, sabe-se que a radiação UVA é absorvida por cromóforos celulares, gerando espécies reativas de oxigênio, como o oxigênio singlete. Sabendo que o proteoma é um mediador de respostas ao estresse celular, nós investigamos os efeitos celulares de uma dose não-citotóxica de radiação UVA, equivalente a cerca de 20 minutos de exposição ao sol, no proteoma de queratinócitos humanos. Utilizando espectrometria de massas, bioinformática e ensaios bioquímicos convencionais, nós analisamos dois aspectos do estresse induzido por radiação UVA: o remodelamento espacial do proteoma 30 minutos depois do estresse e alterações nos níveis e na secreção de proteínas no longo prazo (24 horas e 7 dias depois da irradiação). Na primeira parte desta tese, nós quantificamos e atribuímos classificações de localização subcelular a mais de 3000 proteínas. Dentre essas proteínas, 600 tem potencialmente a sua distribuição subcelular alterada em resposta à radiação. As redistribuições subcelulares são acompanhadas de modulações redox, fragmentação mitocondrial e danos no DNA. Na segunda parte da tese, os nossos resultados mostraram que queratinócitos humanos primários entram em senescência sob exposição a uma única dose de radiação UVA, montando respostas antioxidantes e pró-inflamatórias. Células sob senescência induzida por UVA, por sua vez, desencadeiam respostas parácrinas em queratinócitos pré-tumorais (células HaCaT) por meio de mediadores inflamatórios. Em conjunto, esses resultados reiteram o papel da radiação UVA como um potente estressor metabólico em células da pele
Subject(s)
Skin , Ultraviolet Rays/adverse effects , Keratinocytes/chemistry , Proteomics/classification , Radiation Dosage , Mass Spectrometry/methods , DNA , Epithelial Cells/classification , Genotoxicity/adverse effects , HaCaT Cells/classification , Antioxidants/adverse effectsABSTRACT
Resumen Introducción: A pesar de que existen opciones terapéuticas para el tratamiento de defectos de la mucosa bucal, persiste la necesidad de encontrar sustitutos funcionales, anatómicos y estéticamente similares al tejido que se va a reemplazar, así como soluciones que reduzcan la morbilidad de los injertos autólogos. Objetivo: Determinar la compatibilidad clínica e histológica de aloinjertos equivalentes de mucosa bucal elaborados mediante ingeniería tisular en ratas no consanguíneas. Materiales y métodos: Se utilizó una muestra de mucosa bucal de ratas Sprague Dawley para la obtención de un cultivo de fibroblastos y otro de queratinocitos y fibroblastos. En ambos casos, se usó una membrana de colágeno comercial como soporte. Después de diez semanas de cultivo, las membranas resultantes se injertaron en cuatro ratas Wistar. La primera fase del estudio consistió en la elaboración de los tejidos análogos de mucosa bucal mediante ingeniería tisular, los cuales se implantaron en ratas Wistar inmunocompetentes; posteriormente, se evaluaron las características clínicas e histológicas del aloinjerto. Resultados: La evaluación in vivo de los tejidos análogos demostró que se habían integrado correctamente en los huéspedes inmunocompetentes, y se había logrado el aumento del biotipo periodontal y la creación de una zona con mayor queratinización. Desde el punto de vista histológico, el tejido adquirió características similares a las de la muestra de mucosa bucal de control, sin ningún tipo de reacción inflamatoria ni signos clínicos o histológicos de rechazo. Conclusión: Hubo compatibilidad clínica e histológica de los aloinjertos equivalentes de mucosa bucal obtenidos mediante ingeniería tisular.
Abstract Introduction: Although there are therapeutic options for the treatment of oral mucosa defects, the need for functional, anatomical and aesthetically similar substitutes persists, as well as for solutions to reduce autologous grafts morbidity. Objective: To determine clinical and histological compatibility of equivalent oral mucosa allografts generated through tissue engineering in non-consanguineous rats. Materials and methods: We used a sample of oral mucosa from Sprague Dawley rats to obtain a fibroblast culture and a keratinocytes and fibroblasts co-culture. In both cases, we used a commercial collagen membrane as "scaffold". After ten weeks of culture, we grafted the resulting membranes into four Wistar rats. The first phase of the study was the development of the oral mucosa equivalents generated by tissue engineering. Then, we implanted them in immunocompetent Wistar rats, and finally we evaluated the clinical and histological features of the allografts. Results: In vivo evaluation of mucosal substitutes showed a correct integration of artificial oral mucosa in immunocompetent hosts, with an increase in periodontal biotype and the creation of a zone with increased keratinization. Histologically, the tissue was similar to the control oral mucosa sample with no inflammatory reaction nor clinical or histological rejection signs. Conclusion: The equivalent oral mucosa allografts generated by tissue engineering showed clinical and histological compatibility.
Subject(s)
Animals , Rats , Keratinocytes/cytology , Tissue Engineering , Allografts , Mouth Mucosa/cytology , Keratinocytes/chemistry , Rats, Wistar , Rats, Sprague-Dawley , Fibroblasts , Mouth Mucosa/chemistrySubject(s)
Humans , Desmosomes/physiology , Intercellular Junctions/physiology , Keratinocytes/ultrastructure , Desmosomes/chemistry , Desmosomes/ultrastructure , Immunoglobulins/chemistry , Integrins/chemistry , Integrins/physiology , Intercellular Junctions/physiology , Keratinocytes/chemistry , Cell Adhesion Molecules/physiology , Pemphigoid, Bullous , Self-Evaluation ProgramsABSTRACT
A specialized tissue type, the keratinizing epithelium, protects terrestrial mammals from water loss and noxious physical, chemical and mechanical insults. This barrier between the body and the environment is constantly maintained by reproduction of inner living epidermal keratinocytes which undergo a process of terminal differentiation and then migrate to the surface as interlocking layers of dead stratum corneum cells. These cells provide the bulwark of mechanical and chemical protection, and together with their intercellular lipid surroundings, confer water-impermeability. Much of this barrier function is provided by the cornified cell envelope (CE), an extremely tough protein/lipid polymer structure formed just below the cytoplasmic membrane and subsequently resides on the exterior of the dead cornified cells. It consists of two parts: a protein envelope and a lipid envelope. The protein envelope is thought to contribute to the biomechanical properties of the CE as a result of cross-linking of specialized CE structural proteins by both disulfide bonds and N(epsilon)-(gamma-glutamyl)lysine isopeptide bonds formed by transglutaminases. Some of the structural proteins involved include involucrin, loricrin, small proline rich proteins, keratin intermediate filaments, elafin, cystatin A, and desmosomal proteins. The lipid envelope is located on the exterior of and covalently attached by ester bonds to the protein envelope and consists of a monomolecular layer of omega-hydroxyceramides. These not only serve of provide a Teflon-like coating to the cell, but also interdigitate with the intercellular lipid lamellae perhaps in a Velcro-like fashion. In fact the CE is a common feature of all stratified squamous epithelia, although its precise composition, structure and barrier function requirements vary widely between epithelia. Recent work has shown that a number of diseases which display defective epidermal barrier function, generically known as ichthyoses, are the result of genetic defects of the synthesis of either CE proteins, the transglutaminase 1 cross-linking enzyme, or defective metabolism of skin lipids.