Global ETD Search

21	Generation of human induced pluripotent stem cells using non-synthetic mRNA Rohani, Leili, Fabian, Claire, Holland, Heidrun, Naaldijk, Yahaira, Dressel, Ralf, Löffler-Wirth, Henry, Binder, Hans, Arnold, A., Stolzing, Alexandra 27 June 2016 (has links) (PDF) Here we describe some of the crucial steps to generate induced pluripotent stemcells (iPSCs) usingmRNA transfection. Our approach uses a V. virus-derived capping enzyme instead of a cap-analog, ensuring 100% proper cap orientation for in vitro transcribedmRNA. V. virus\' 2′-O-Methyltransferase enzymecreates a cap1 structure found in higher eukaryotes and has higher translation efficiency compared to other methods. Use of the polymeric transfection reagent polyethylenimine proved superior to other transfection methods. The mRNA created via this method did not trigger an intracellular immune response via human IFN-gamma (hIFN-γ) or alpha (hIFN-α) release, thus circumventing the use of suppressors. Resulting mRNA and protein were expressed at high levels for over 48 h, thus obviating daily transfections. Using this method, we demonstrated swift activation of pluripotency associated genes in human fibroblasts. Low oxygen conditions further facilitated colony formation. Differentiation into different germ layers was confirmed via teratoma assay. Reprogramming with non-synthetic mRNA holds great promise for safe generation of iPSCs of human origin. Using the protocols described herein we hope to make this method more accessible to other groups as a fast, inexpensive, and non-viral reprogramming approach. induzierte pluripotente Stammzelle Reprogrammierung mRNA Boten-RNA Induced pluripotent stem cell reprogramming mRNA ddc:610
22	Mesenchyme Induces Embryonic and Induced Pluripotent Stem Cells to a Distal Lung Epithelial Cell Phenotype Fox, Emily 11 December 2012 (has links) Derivation of lung epithelial cells from stem cells remains a challenging task, due in part to a lack of understanding of the molecular mediators driving commitment of endoderm to an early lung lineage. Reciprocal signalling between the lung mesenchyme and epithelium is crucial for proper differentiation and branching morphogenesis to occur. We hypothesized that the combination of signalling pathways comprising early epithelial-mesenchymal interactions and the 3-D spatial environment are required for induction of embryonic and induced pluripotent stem cells (ESC and iPSC, respectively) into a lung cell phenotype with the hallmarks of the distal niche. Aggregating early lung mesenchyme with endoderm-induced ESC and iPSC resulted in differentiation to an NKX2.1 and pro-SFTPC positive lineage. The differentiating cells organized into tubular structures and became polarized epithelial cells. Ultrastructure analysis revealed precursors of lamellar bodies, and Sftpb mRNA expression was detected. Quantification of the differentiation using an Nkx2.1-reporter ESC line revealed that 80% were committed to an early lung lineage, a vast improvement over what has previously been published. The FGF growth factor family comprises well-known mediators of growth and differentiation during the development of many organs, including the lung. We found that FGF2 signalling through the FGFR2iiic receptor isoform was mediating the commitment of the stem cells to an early lung epithelial phenotype, as defined by NKX2.1/proSFTPC expression. FGF7 signalling through the FGFR2iiib receptor was found to be important for the maturation and morphogenesis of the NKX2.1/proSFTPC positive lineage, but did not play a role in the initial commitment. The addition of FGF2 to endoderm-induced ESC or iPSC in the absence of mesenchyme was able to commit the cells to an NKX2.1-positive lineage, but no proSFTPC was detected. Furthermore,the cells did not become polarized and no longer organized into tubular structures. These findings suggest that while FGF2 is important for initial commitment, additional mesenchyme components including matrix proteins, supporting cell lineages and other growth factors are crucial for an efficient differentiation to an early lung epithelial cell lineage. Lung Development embryonic stem cells Induced Pluripotent Stem cells 0379 0719
23	REGULATION OF TELOMERASE EXPRESSION IN STEM CELL REPROGRAMMING Sachs, Patrick 25 January 2010 (has links) A great need exists for an abundant, easily accessible source of patient-specific cells that will function for use in regenerative medicine. One promising source is the adult stem cell derived from adipose tissue (ASCs). Isolated from waste lipoaspiration, these cells could serve as a readily available source for the regeneration of damaged tissues. To further define the biology of ASCs, we have isolated multiple cell strains from different adipose tissue sources, indicating wide-spread distribution in the body. We find that a widely used set of cell surface markers fail to distinguish ASCs from normal fibroblasts. However, our ASC isolations are multipotent while fibroblasts show no differentiation potential. In further contrast to fibroblasts, these cells also show expression of genes associated with pluripotent cells, Oct-4, SOX2, and NANOG. Together, our data suggest that while the cell surface profile of ASCs do not distinguish them from normal fibroblasts and their lack of telomerase shows their limited proliferation capacity, the expression of genes closely linked to pluripotency and their differentiation capacity clearly define ASCs as multipotent stem cells. iPS cells are another promising cell type for tissue regeneration, due to their expression of hTERT and their capacity to differentiate into all three germ layers. Interestingly, telomerase is activated during the induction process, accomplished by the exogenous expression of four genes in normal, non-hTERT-expressing fibroblasts. To elucidate the mechanisms behind this activation, we examined the overexpression of these four factors in BJ fibroblasts and ASCs, which resulted in undetectable hTERT expression. We then demonstrated a lack of an acetylated histone H3K9 with the opposing di-methylation, indicative of a closed chromatin state at the hTERT promoter. Subsequent treatment of cells with TSA alone showed an upregulation of hTERT mRNA without telomerase activity. However, telomerase activity was found when ASCs, but not BJs were treated with TSA and all four factors, indicating differential regulation of hTERT in cells of similar mesenchymal origins. Our data suggest that while hTERT’s expression is universally dependent on the presence of a relaxed chromatin state and sufficient transactivating factors, other cell to cell differences can prevent its expression. Telomerase regulation hTERT iPS Induced pluripotent stem cells Medical Genetics Medical Sciences Medicine and Health Sciences
24	Development and Testing of a Tissue Engineered Cardiac Construct for Treatment of Chronic Heart Failure Lancaster, Jordan, Lancaster, Jordan January 2016 (has links) There is a growing epidemic of chronic heart failure (CHF) in the developed world. The costs associated with providing care is profound and despite our best efforts, new, more effective treatments for CHF are needed; 50% of patients diagnosed with CHF are dead within 5 years. Current paradigms rely heavily on pharmacologic interventions, which merely help manage the disease. Surgical interventions may also be considered for late stage CHF patients such as heart transplant or left ventricular assist device (LVAD) but require burdensome and invasive surgical procedures. In addition they are costly, and require the need for life long immunosuppressive and anticoagulant therapies respectively. Despite our best intentions, the long-term prognosis for CHF patients remains poor. With over a decade of clinical investigation taken place, data from cell-based therapy trials remains inconsistent. While demonstrating safety, limited efficacy has been reported and to date, no stem cell therapy has been approved by the FDA. Despite these shortcomings important lessons have been learned that can be applied to future developments. Retrospective analysis of early cell-based clinical trial data has suggested that variations in isolated cell number, viability, and potency from donor to donor in autologous preparations yielded wide discrepancies in functional outcomes. In addition, sub culturing adult stem cells, even for short periods of time in 2D polystyrene environments void of complementary cell populations and extra cellular matrix protein interactions, may alter the therapeutic potential of a given cell. As a solution, allogeneic approaches where donor cell quality and potency can be assessed and optimized may help achieve functional benefits. Furthermore, co-dosing with multiple cell populations or developing 3D sub-culture environments that more closely mimic the in vivo milieu may ultimately yield more potent therapeutic cell populations. While these alterations may improve cell-based therapy outcomes, other solutions have been proposed such as tissue engineering. While the concept of tissue engineering is not new, advancements in biomaterials, bioreactor design and cell sources have greatly enhanced the reality of these preparations. Previously, one of the greatest limitations to tissue engineering is overcoming the cell requirements for developing and testing where millions if not billions of cells are required. Cell sourcing limitations appear to have been solved with the discovery and development of induced pluripotent stem cell (iPSC) derived cell populations. First reported in 2007, they have the ability to generate embryonic like pluripotent stem cells without the ethical concerns of embryonic stem cells. These iPSCs hold tremendous potential for drug toxicology / screening, personalized medicine and cell therapies. The body of work described in this dissertation looks at developing and testing a tissue engineered cardiac patch to treat heart failure. For which, an emphasis has been to provide 1) structural support for engrafted cells and 2) a rapidly inducible vascular supply once implanted in vivo. Biomaterials were sourced that facilitate infill by multiple cell populations in 3D culture and the establishment of extra cellular matrix deposits. Together, these patches enhanced cellular development in vitro and result in long term functional improvements in small animal models for CHF. Additional feasibility work was performed in large animal models to permit upscaling and development of surgical implantation techniques to demonstrate clinical applicability Heart Failure Induced Pluripotent Stem Cells Infarct Left Ventricle Tissue Engineering Physiological Sciences Cardiomyocytes
25	Geração de células-tronco pluripotentes induzidas (hiPSCs) a partir de células somáticas de indivíduos com fenótipo de interesse para transfusões sanguíneas / Generation of induced pluripotent stem cells (hiPSCs) from somatic cells of individuals with interesting phenotypes for blood transfusion Catelli, Lucas Ferioli 28 November 2016 (has links) A demanda por transfusões sanguíneas tem aumentado no Brasil e o número de doações de sangue permanecem insuficientes. Há escassez de componentes de sangue para transfusão, principalmente de concentrados de células vermelhas do sangue. As células-tronco pluripotentes induzidas humanas (hiPSCs) possuem um grande potencial para se tornar uma fonte de CÉLULAS VERMELHAS DO SANGUE, pois podem se diferenciar em qualquer tipo celular, incluindo CÉLULAS VERMELHAS DO SANGUE de fenótipo específico. O objetivo deste trabalho é a geração de hiPSCs para partir de células mononucleares de sangue periférico (PBMCs) de candidatos a doação de sangue que possuem fenótipo eritrocitário de baixa imunogenicidade, bem como a diferenciação eritroide das hiPSCs geradas. As amostras de sangue periférico (PB) de 11 indivíduos foram coletadas e caracterizadas quanto ao genótipo para os seguintes antígenos eritrocitários: Sistema Rh (RHCE01/RHCE02/RHCE03/RHCE04/RHCE05), Kell (KEL01/KEL02), Duffy (FY01/FY02 and FY02N.01), Kidd (JK01/JK02) e MNS (GYPB03/GYPB04). Outros antígenos de grupos sanguíneos distintos foram determinados por meio de fenotipagem. Duas amostras (PBMCs PB02 e PB12) foram selecionadas para a reprogramação devido ausência de múltiplos antígenos eritrocitários e, portanto, considerados de baixa imunogenicidade. Os PBMCs foram enriquecidos em eritroblastos e em seguida, as células foram transfectadas com os vetores episomais pEB-C5 e pEB-Tg e então, co-cultivados sobre fibroblastos de embriões murinos (MEFs) até o surgimento de colônias semelhantes a hiPSCs (hiPSC PB02 e hiPSC PB12). Estas colônias foram transferidas para condições de cultivo próprias e posteriormente caracterizadas quanto à sua pluripotência. A expressão dos genes de pluripotência OCT4, SOX2 e NANOG demonstrou níveis de expressão maior em comparação às linhagens não pluripotentes. As análises de imunofenotipagem por citometria de fluxo revelaram que em torno de 86% das células expressaram Nanog, 88% Oct4 e 88% Sox2. Os níveis de expressão de genes de pluripotência e marcadores foram consistentes com o estado indiferenciado encontrado em células pluripotentes conhecidas. A análise funcional para avaliação da pluripotência foi realizado pela injeção das hiPScs em camundongos imunodeficientes, demonstrando a formação de teratoma nas linhagens geradas. A metodologia para diferenciação hematopoética das hiPSCs geradas a partir dos corpos embrioides estão em progresso. O potencial de diferenciação foi confirmado durante a padronização deste processo, utilizando ensaio de formação de colônias em metilcelulose. Uma média de 10,5 colônias de precursores eritroide foram obtidas a partir de 50x103 hiPSC PB02 em diferenciação e uma colônia mista (mieloide e linfoide) a partir de 15x103 hiPSC PB12 foram obtidas. Neste trabalho foi possível gerar duas linhagens de hiPSCs com fenótipos de antígenos eritrocitários de interesse que podem ser mantidas em cultura por um longo período (26 passagens) e demonstram um potencial de diferenciação hematopoética. / The demand for blood transfusion has increased in Brazil and the number of blood donations remains insufficient. Therefore, there is a shortage of blood components for transfusion, mainly concentrates of red blood cells (RBCs). Human induced pluripotent stem cells (hiPSCs) have great potential to become a source of RBCs, because they can differentiate into every cellular type, including RBCs of a particular phenotype. The objective of this work was to generate hiPSC from mononuclear cells of peripheral blood (PBMCs) from blood donors who presented low immunogenic phenotype for transfusion, and erythroid differentiation of the generated hiPSCs. Peripheral blood samples from 11 individuals were collected and characterized for the following erythrocyte antigens: Rh system (RHCE01/RHCE02/RHCE03/RHCE04/RHCE05), Kell (KEL01/KEL02), Duffy (FY01/FY02 and FY02N.01), Kidd (JK01/JK02), MNS (GYPB03/GYPB04). Additionally, other antigens of different blood groups were determined by phenotyping. The samples PBMC PB02 and PBMC PB12 were chosen for iPS generation due to their multiple negative erythrocyte antigens. They were isolated, expanded into erythroblasts, and transfected using the reprogramming episomal vectors PEB-C5 and PEB-Tg. This population was co-cultured on mouse embryonic fibroblasts (MEFs) until the appearance of hiPSC like colonies (hiPSC PB02 and hiPSC PB12). These colonies were transferred to human embryonic stem cells (hESCs) culture conditions and characterized regarding their pluripotency. The expression of OCT4, SOX2 and NANOG pluripotency genes demonstrated that the expression of both lineages was higher in comparison with non-pluripotent lineages. Immunophenotyping performed by flow cytometry revealed that 86% of cells expressed Nanog, 88% Oct4 and 88% Sox2. Expression levels of pluripotency genes and markers were consistent with undifferentiated state found in known pluripotent cells. Functional analysis for pluripotency was achieved by the hiPSC injection in immunodeficient mice showing that both hiPSC cell lines were able to induce teratoma tumor. The hematopoietic differentiation potential was confirmed using methylcellulose assay, with an average of 10.5 erythroid colonies from 50x103 single cells and a mixed colonies of myeloid and lymphoid cells) and finally a colony composed of white cells from 15x103 PB12 hiPSC. In conclusion, it was possible to generate a hiPSC from a red blood cell phenotype that are negative for multiple antigens, and this cell line can be maintained for a long period in culture (26 passages) and show potential for hematopoietic differentiation. antígenos eritrocitários células-tronco pluripotentes induzidas diferenciação hematopoética Erythrocyte antigens Hematopoietic differentiation Induced Pluripotent Stem Cells
26	Studying the molecular consequences of the t(1;11) balanced translocation using iPSCs derived from carriers and within family controls Makedonopoulou, Paraskevi January 2016 (has links) Schizophrenia is a major psychiatric disorder that affects 1% of the world population and is among the 10 leading worldwide causes of disability. Disrupted-In- Schizophrenia (DISC1) is one of the most studied risk genes for mental illness and is disrupted by a balanced translocation between chromosomes 1 and 11 that co-segregates with major mental illness in a single large Scottish family. DISC1 is a scaffold protein with numerous interactors and has been shown to hold key roles in neuronal progenitor proliferation, migration, cells signalling and synapse formation and maintenance. The studies herein provide the platform in order to investigate the molecular and cellular consequences of the t(1;11) translocation using induced pluripotent stem cells (iPSCs)-derived neural precursor cells and neurons from within-family carriers and controls. Towards this end, several iPSC lines have been converted into neural progenitor cells (NPCs) and differentiated into physiologically active forebrain neurons following well-characterised protocols. These cells were characterised in terms of basic marker expression at each developmental stage. Inter-line variation was observed in all subsequent experiments but overall t(1;11) lines did not generate less neuronal or less proliferating cells compared to control lines. Furthermore, the expression pattern of genes disrupted by the t(1;11) translocation was investigated by RT-qPCR. DISC1 was reduced by ~50% in the translocation lines, both neural precursors and neurons. This observation corresponds to previous findings in lymphoblastoid cell lines (LBCs) derived from members of the same family. Moreover, DISC1 expression was found to increase as neural precursors differentiation to neurons. Two other genes are disrupted by the t(1;11) translocation;DISC2 and DISC1FP1. Their expression was detectable, but below the threshold of quantification. Similarly, DISC1/DISC1FP1 chimeric transcripts corresponding to such transcripts previously identifies in LBCs from the family were detectable, but not quantifiable. A fourth gene, TSNAX, was also investigated because it is located in close proximity to, and undergoes intergenic splicing with, DISC1. Interestingly, TSNAX was found to be altered in some but not all time points studied, in the translocation carriers compared to control lines. In addition to breakpoint gene expression profiling, iPSC-derived material was used to investigate neuronal differentiation. There seemed to be attenuation in BIII-TUBULIN expression at two weeks post-differentiation, while NESTIN, MAP2 and GFAP expression was similar between translocation carrier and control lines at all time points studied. I also had access to targeted mice designed to mimic the derived chromosome 1 of the t(1;11) balanced translocation. Using RT-qPCR Disc1 expression was found to be 50% lower in heterozygous mice compared to wild types, and I detected a similar profile of chimeric transcript expression as detected in translocation carrier-derived LBCs. These observations support my gene expression studies of the human cells and indicate that the iPSC-derived neural precursors and neurons can be studied in parallel with the genome edited mice to obtain meaningful insights into the mechanism by which the t(1;11) translocation confers substantially elevated risk of major mental illness. In conclusion, the studies described in this thesis provide an experimental platform for investigation of the effects of the t(1;11) translocation upon function and gene and protein expression in material derived from translocation carriers and in brain tissue from a corresponding mouse model.
27	Role of Fibroblast Growth Factor 2 in Maintenance of Multipotency in Human Dermal Fibroblasts Treated with Xenopus Laevis Egg Extract Fractions Kole, Denis 28 April 2014 (has links) Current usage of human embryonic stem cells (hES) and induced pluripotent stem cells (iPS) in clinical therapies and personalized medicine are limited as a result of ethical, technical and medical problems that arise from isolation and generation of these cells. Isolation of hES cells faces ethical problems associated with their derivation from human pre-implantation embryos. The most controversial aspect of hES cell isolation targets the generation of autologous hES cell lines which requires the transfer of a somatic-cell nucleus from the patient to an enucleated oocyte. While already established embryonic stem cell lines from IVF embryos can be used in a similar manner, lack of genetic identity can cause therapy rejection from the host, and prevent their use in personalized medicine. Induced pluripotent stem cells on the other hand, are generated from somatic cells that have been reprogrammed in vitro to behave like stem cells. While these cells can potentially be used for personalized medicine without the risk of rejection by the host system, derivation methods prevent their therapeutic use. The most efficient method used to generate iPS cells involves usage of viral particles which can result in viral DNA being integrated in the host cellâ€™s genome and render these cells non-compliant for clinical therapies. Other methods not involving viral particles exist as well, but the reprogramming efficiency is too low and technical problems with generating large enough numbers of cells prevent these methods from being feasible approaches for clinical therapies. Direct reprogramming of a differentiated cell into a developmentally more plastic cell would offer alternatives to applications in regenerative medicine that currently depend on either embryonic stem cells (ES), adult stem cells or iPS cells. We hypothesize that Xenopus laevis egg cytoplasmic extract contains critical factors needed for reprogramming that may allow for non-viral, chemically defined derivation of human induced pluripotent/multipotent cells which can be maintained by addition of exogenous FGF2. In this thesis we investigated a new method for generation of multipotent cells through determining the ability of select fractions of Xenopus laevis egg extract to induce multipotency in already differentiated cells. We were able to identify select fractions from the extract that in combination with exogenously added FGF2 can reprogram and maintain the reprogrammed cells in an undifferentiated state. The findings of this work also determined that Xenopus laevis egg extract mRNA is required for achieving full reprogramming. The body of work presented in this thesis showed the ability of FGF2 isoforms to bind and activate select FGF receptor tyrosine kinases, act as extracellular mitogenic factors to support growth of hES cells in an undifferentiated state as well bind to nuclear DNA and affect expression of endogenous genes. Moreover, we showed that all FGF2 isoforms can induce expression of stem cell specific proteins in human dermal fibroblasts as well as extend lifespan of human dermal fibroblasts in vitro. In this work we identified HECW1, the gene coding for E3 ubiquitin ligase NEDL1, as a novel nuclear target for all FGF2 isoforms and showed that overexpression of recombinant FGF2 isoforms in human dermal fibroblasts can down regulate expression of HECW1 gene. Induced pluripotent stem cells Pluripotency FGF2 Cellular reprogramming Stem cells Xenopus laevis egg extract
28	Stem cells: an overview of therapeutic approaches Brubaker, Chelsee 01 November 2017 (has links) The complexity of life exhibited in humans and other living creatures has drawn many to investigate the principles associated with organismal growth and development. A few broad questions: How do tissues develop into specified organs? How are these tissues maintained? Do they become different tissues? Scientific research has incessantly been seeking answers to these as well as a plethora of other questions. While on a quest to better understand developmental biology, investigators discovered unique populations of stem cells within a variety of tissues, which retain both varying degrees of developmental plasticity and their potential for self-regeneration. This thesis provides a brief review discussing the development and history of stem cells in medicine and associated research on these cells and their potential clinical applications. Substantial attention has been paid to pluripotent embryonic stem cells (ESC) and induced pluripotent stem cells (iPSC) which are able to be recapitulate ESC properties through the in vitro reprogramming of somatic cells. While, the ethical and legal issues have greatly hindered the use of ESCs this has made the benefit of iPSCs so great. An interconnected network of pluripotency-associated genes, integrates external signals and exerts control to maintain the state of pluripotency. Recent research has proven the pluripotency regulatory network to be flexible such that the underlying principles promise unprecedented opportunities for scientific study and regenerative medicine. Additional topics reviewed here include vast clinical applications of stem cells as well as their notable limitations. Biology Clinical medicine Embryonic stem cells Genome engineering Induced pluripotent stem cells Reprogramming Stem cells
29	Geração de células-tronco pluripotentes induzidas (iPSCs) a partir de células de pacientes com anemia aplástica adquirida / Induced pluripotent stem cells (iPSCs) generation from acquired aplastic anemia patients Tellechea, Maria Florencia 12 April 2016 (has links) A anemia aplástica (AA) é uma doença hematológica rara caracterizada pela hipocelularidade da medula óssea, o que provoca pancitopenia. Esta pode ser de origem genética (associada a encurtamento telomérico) ou adquirida (não-associada a desgaste excessivo dos telômeros). Na forma adquirida, a ativação anormal de linfócitos T provoca a destruição das células hematopoéticas. O mecanismo que leva a essa destruição ainda não foi elucidado. Um dos tratamentos mais eficazes para repovoar a medula óssea hipocelular é o transplante com célulastronco hematopoéticas (CTHs). Porém, uma grande porcentagem de pacientes não se beneficia de nenhum tratamento, fazendo-se necessário o desenvolvimento de novas alternativas para terapia. A geração de células-tronco pluripotentes induzidas (iPSCs) a partir de células somáticas (reprogramação) representa uma ferramenta promissora para o estudo de doenças e para o desenvolvimento de possíveis terapias paciente-especificas, como transplantes autólogos. Neste trabalho, avaliamos a capacidade de reprogramação de fibroblastos e eritroblastos de pacientes com AA adquirida. Metodologias de reprogramação utilizando lentivírus ou plasmídeos epissomais não integrativos foram testadas em células de quatro pacientes e de um controle saudável. Eritroblastos dos quatro pacientes e do controle foram reprogramados utilizando os plasmídeos não integrativos. As iPSCs geradas apresentaram-se similares a células-tronco embrionárias quanto à morfologia, expressão dos marcadores de pluripotência OCT4, SOX2, NANOG, SSEA-4, Tra-1-60 e Tra-1-81, e capacidade de diferenciação in vitro em corpos embrioides (EBs). A dinâmica telomérica das células pré- e pós-reprogramação foi avaliada em diferentes passagens utilizando a técnica de flow-FISH. O comprimento telomérico foi aumentado nas iPSCs quando comparado às células parentais o que indica que a célula foi completamente reprogramada. No presente trabalho, células de pacientes com AA adquirida foram reprogramadas a um estado de pluripotência por meio de um método não integrativo. As iPSCs geradas serão essenciais para futuros ensaios de diferenciação hematopoética, o que poderá contribuir para o entendimento dos mecanismos envolvidos no desenvolvimento dessa doença. Além disso, a diferenciação dessas células livres de transgenes poderá servir como uma alternativa terapêutica para os pacientes com AA como, por exemplo, em transplantes autólogos / Aplastic anemia (AA) is a rare hematological disease characterized by bone marrow hypocellularity that leads to pancytopenia. Its origin can be genetic (associated with telomere shortening) or acquired (non-associated with telomere shortening). The acquired form exhibit T lymphocytes abnormal activation, which leads to hematopoietic cells destruction. The mechanisms behind this phenomenon are still unclear. One of the most effective treatments for hypocelullar bone marrow repopulation is hematopoietic stem cell (HSCs) transplantation. However, a large percentage of patients do not benefit from any of the available treatments. This highlights the need to develop new therapeutic strategies. The generation of induced pluripotent stem cells (iPSCs) from somatic cells (reprogramming) represents a powerful tool for disease modeling and for the development of patient-specific therapies such as autologous transplants. In this study, we evaluate the capacity of reprogramming acquired AA patients\' fibroblasts and erythroblasts. Reprogramming methods using lentivirus or non-integrative episomal plasmids were tested in four patients\' cells and in cells from one healthy donor. Erythroblasts from these four patients and healthy donor were reprogrammed using non-integrative plasmids. The iPSCs resembled human embryonic stem cells in morphology, in the expression of pluripotent markers such as OCT4, SOX2, NANOG, SSEA-4, Tra-1-60 and Tra-1-81, and in in vitro differentiation (capacity to form embryoid bodies). The telomere dynamics of the cells before and after reprogramming was assessed along passaging using flow-FISH. The telomere length in the iPSCs was increased when compared to the parental cells. Thus, acquire AA patients\' cells could be reprogrammed to a pluripotent state by a nonintegrative method. The iPSCs will be essential for future hematopoietic differentiation assays that could contribute to the understanding of the mechanisms involved in the disease development. Furthermore, the differentiation of transgene-free cells may serve as an alternative therapy for patients with AA such as autologous transplants Acquired aplastic anemia Anemia aplástica adquirida Induced pluripotent stem cells iPSCs Telomeres Telômeros
30	Investigation of the cell- and non-cell autonomous impact of the C9orf72 mutation on human induced pluripotent stem cell-derived astrocytes Zhao, Chen January 2016 (has links) Amyotrophic lateral sclerosis (ALS) is a late onset neurodegenerative disorder characterised by selective loss of upper and lower motor neurons (MNs). Recently, the GGGGCC (G4C2) hexanucleotide repeat expansion in chromosome 9 open reading frame 72 (C9orf72) has been identified as the most common genetic cause of ALS, highlighting the importance of studying the pathogenic mechanisms underlying this mutation. Accumulating evidence implicates that ALS is a multisystem and multifactor disease. Specifically, non-neuronal cells, astrocytes in particular, are also affected by toxicity mediated by ALS-related mutations, and they can contribute to neurodegeneration, suggesting astrocytes as a key player in ALS pathogenesis. Here, a human induced pluripotent stem cells (iPSCs)-based in vitro model of ALS was established to investigate the impact of the C9orf72 mutation on astrocyte behaviour—both cell- and non-cell autonomous. Work in this study shows that patient iPSC-derived astrocytes recapitulate key pathological features associated with C9orf72-mediated ALS, such as formation of G4C2 repeat RNA foci, production of dipeptide repeat (DPR) proteins and reduced viability under basal conditions compared to controls. Moreover, C9orf72 mutant astrocytes in co-culture result in reduced viability and structural defects of human MNs. Importantly, correction of the G4C2 repeat expansion in mutant astrocytes through targeted gene editing reverses these phenotypes, strongly confirming that the C9orf72 mutation is responsible for the observed findings. Altogether, this iPSC-based in vitro model provides a valuable platform to gain better understandings of ALS pathophysiology and can be used for future exploration of potential therapeutic drugs.

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