Terapias alternativas para o diabetes mellitus tipo 1: caracterização funcional do gene Txnip na diferenciação ß-pancreática e desenvolvimento de biomaterial inovador para microencapsulamento celular / Alternative therapies for type 1 diabetes mellitus: functional characterization of Txnip gene during -pancreatic differentiation and generation of an innovative biomaterial for cell microencapsulation

O diabetes mellitus do tipo 1 (DM1) é uma doença causada pela destruição autoimune das células-ß produtoras de insulina do pâncreas. O transplante de ilhotas pancreáticas é um procedimento tecnicamente simples sendo uma alternativa terapêutica interessante para o DM1. Entretanto, a oferta limitada de pâncreas de doadores falecidos e a necessidade de imunossupressão crônica são fatores que limitam a aplicabilidade dessa modalidade de transplante. Neste trabalho foram estudadas duas estratégias que visam oferecer soluções aos fatores limitantes do transplante de ilhotas pancreáticas. Na primeira parte do trabalho, o mecanismo molecular que dirige o processo de diferenciação de células-tronco embrionárias murinas (murine embryonic stem cells, mESCs) em células produtoras de insulina (insulin producing cells, IPCs) foi analisado visando otimizar o processo de diferenciação. Nós selecionamos o gene Thioredoxin interacting protein (Txnip), diferencialmente expresso ao longo da diferenciação ß-pancreática, para realizar um estudo funcional através da modificação genética de mESCs. Os resultados obtidos permitiram verificar que a inibição de Txnip na diferenciação ß-pancreática pode induzir a diferenciação de IPCs com maior expressão de marcadores de células- e mais responsivas ao estímulo de glicose. Além disso, o modelo de zebrafish permitiu elucidar in vivo o papel de Txnip durante a organogênese pancreática, revelando que a inibição desse gene é capaz de aumentar a massa de células-ß através do estimulo de células presentes no ducto extra-pancreático. Dessa forma, a inibição de Txnip pode aprimorar os protocolos para obtenção de IPCs a partir de células-tronco pluripotentes. A exposição crônica a agentes imunossupressores diabetogênicos e a perda de componentes de matriz extracelular durante o isolamento de ilhotas pancreáticas são causas para a perda de funcionalidade do enxerto. Dessa forma, na segunda parte do trabalho, um biomaterial inovador foi desenvolvido, contendo um polímero de laminina (polilaminina, PLn) para o encapsulamento e a imunoproteção de ilhotas pancreáticas. As cápsulas produzidas com o biomaterial desenvolvido, Bioprotect-Pln, são térmica- e mecanicamente estáveis, além de serem biocompatíveis e capazes de imunoproteger ilhotas pancreáticas humanas in vitro. O encapsulamento com Bioprotect-Pln preserva a funcionalidade de ilhotas pancreáticas. Além disso, quando cápsulas vazias de Bioprotect-Pln foram implantadas em camundongos imunocompetentes, houve atenuação da resposta inflamatória ao implante, uma das principais causas para perda de funcionalidade de enxertos encapsulados. Os resultados obtidos indicam que a presença de polilaminina na malha capsular induz uma resposta anti-inflamatória que pode beneficiar a preservação do enxerto de ilhotas pancreáticas encapsuladas. Atualmente, o transplante de ilhotas pancreáticas é visto como a terapia celular mais promissora para atingir a independência de insulina em pacientes de DM1, porém, a aplicabilidade desse transplante ainda é limitada. Este trabalho contribuiu para a elucidação dos mecanismos moleculares que podem aprimorar o processo de diferenciação de célulastronco pluripotentes em IPCs, estabelecendo uma fonte alternativa de células para a terapiade reposição, e, também, estabeleceu um biomaterial inovador, capaz de diminuir a resposta inflamatória ao implante de microcápsulas e de imunoproteger células microencapsuladas. Desta forma, este trabalho contribui para o estabelecimento da terapia de reposição celular para pacientes de DM1

Type 1 diabetes mellitus (DM1) is a disease caused by the autoimmune destruction of insulin-producing pancreatic ß-cells. Pancreatic islet transplantation is a technically simple procedure and an interesting alternative therapy for DM1, however, the limited supply of cadaveric donated pancreas and the need of life-long immunosuppression are factors which limit its applicability. In the present work, two strategies were employed aiming at establishing viable solutions for the factors limiting pancreatic islet transplantation. In the first part of this study, the molecular mechanism which drives differentiation of murine embryonic stem cells (mESCs) into insulin producing cells (IPCs) was analyzed in order to optimize the differentiation process. The Thioredoxin interacting protein (Txnip) gene, which is differentially expressed along -pancreatic differentiation, was selected to undergo a functional analysis by genetically modifying mESCs. The results allowed us to verify that Txnip inhibition during the ß-pancreatic differentiation process can induce differentiation of IPCs displaying higher expression of ß-cell markers and being more responsive to glucose stimuli. In addition, the zebrafish model allowed us to elucidate in vivo the role of Txnip during pancreatic organogenesis, revealing that its inhibition is able to increase the mass of ß-cells through stimulation of extra-pancreatic ductal cells. Therefore, Txnip inhibition may turbinate IPCs differentiation from pluripotent stem cells. The chronic exposure to diabetogenic immunosuppressive agents and the loss of extracellular matrix components during isolation of pancreatic islets are probable causes for the loss of pancreatic islet graft functionality. Therefore, in the second part of this study, an innovative biomaterial was developed by incorporating a laminin polymer (polylaminin, PLn) for the encapsulation and immunoprotection of pancreatic islets. The capsules produced with the novel biomaterial, Bioprotect-Pln, are biocompatible, thermally and mechanically stable and are able to immunoprotect human pancreatic islets in vitro. Encapsulation with Bioprotect-Pln preserves the functionality of pancreatic islets. In addition, when empty Bioprotect-Pln capsules were implanted into immunocompetent mice, an attenuation of the inflammatory response to the implant occurred, this being one of the main causes of encapsulated graft loss. The results indicate that polylaminin addition to the capsular mesh induces an anti-inflammatory response which may favor preservation of the engrafted encapsulated pancreatic islets. Pancreatic islet transplantation is currently seen as the most promising cell therapy to achieve insulin independence in DM1 patients, however, the applicability of this transplant is still limited. This work contributed to the elucidation of the molecular mechanisms which can turbinate the differentiation of pluripotent stem cells into IPCs, establishing an alternative source of cells for the replacement therapy, and, also, established an innovative biomaterial which is able to decrease the inflammatory response to the graft, thereby immunoprotecting the microencapsulated cells. Therefore, this work contributes to the establishment of the cell replacement therapy for DM1 patients

Atelocollagen-based Hydrogels Crosslinked with Oxidised Polysaccharides as Cell Encapsulation Matrix for Engineered Bioactive Stromal Tissue

Tissue stroma is responsible for extracellular matrix (ECM) formation and secretion of factors that coordinate the behaviour of the surrounding cells through the microenvironment created. It's inability to spontaneously regenerate makes it a good candidate for research studies such as testing various tissue engineered products capable of replacing the stroma in order to assure normal tissue regeneration and function. In this study, a bioactive stroma was obtained considering two main components: 1) the artificial ECM formed using atelocollagen-oxidized polysaccharides hydrogels in which the polysaccharide compound (oxidised gellan or pullulan) has the role of crosslinker and 2) encapsulated stromal cells (dermal fibroblasts, ovarian theca-interstitial and granulosa cells). The cell-hosting ability of the hydrogels is demonstrated by a good diffusion of globular proteins (albumin) while the fibrillar morphology proves to be optimal for cell adhesion. These structural properties and cytocompatibility of the components maintain good cell viability and cell encapsulation for more than 12 days. Nevertheless, the results indicate some differences favouring the gellan crosslinked hydrogels. Ovarian stromal cells functionality was maintained as indicated by hormone secretion, confirming cell-cell signalling in encapsulated and co-culture conditions. In vivo implantation shows the regenerative potential of the cell-populated hydrogels as they are integrated into the natural tissue. The possibility of cryopreserving the hydrogel-cell system, while maintaining both cell viability and hydrogel structural integrity underlines the potential of these ready-to-use hydrogels as bioactive stroma for multipurpose tissue regeneration.