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Transplantation of human iPS cell-derived airway cells on vitrigel membrane into rat nasal cavity / コラーゲンビトリゲル膜を用いたヒトiPS細胞由来気道上皮細胞のラット鼻腔への移植Kuwata, Fumihiko 25 July 2022 (has links)
京都大学 / 新制・課程博士 / 博士(医学) / 甲第24129号 / 医博第4869号 / 新制||医||1059(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 平井 豊博, 教授 中島 貴子, 教授 森本 尚樹 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Collagen X is dispensable for hypertrophic differentiation and endochondral ossification of human iPSC-derived chondrocytes / X型コラーゲンはヒトiPS細胞由来軟骨細胞の肥大化および内軟骨性骨化に必須ではないKamakura, Takeshi 24 July 2023 (has links)
京都大学 / 新制・課程博士 / 博士(医科学) / 甲第24843号 / 医科博第151号 / 新制||医科||10(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 齋藤, 潤, 教授 遊佐, 宏介, 教授 松田, 秀一 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Cardiogenic differentiation of induced pluripotent stem cells for regeneration of the ischemic heartBuccini, Stephanie M. January 2013 (has links)
No description available.
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Comparative study of immunodeficient rat strains in engraftment of hiPSC-derived airway epithelia / ヒトiPS細胞由来気道上皮移植における免疫不全ラット系統の比較検討林, 泰之 23 May 2024 (has links)
京都大学 / 新制・課程博士 / 博士(医学) / 甲第25488号 / 医博第5088号 / 新制||医||1073(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 後藤 慎平, 教授 平井 豊博, 教授 浅野 雅秀 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Geração de células de pluripotência induzida (iPS) humanas utilizando vetores lentivirais e determinação do perfil de integração lentiviral / Generation of human induced pluripotent stem (iPS) cell using lentiviral vector and determination of the lentiviral integration profileReis, Luiza Cunha Junqueira 28 November 2012 (has links)
As células iPS surgiram com a promessa de contornar as limitações das células-tronco embrionárias, como questões éticas, segurança, compatibilidade e disponibilidade. Essas células podem ser obtidas a partir de células somáticas de indivíduos normais ou de pacientes com doenças genéticas, fazendo destas uma importante ferramenta para o screening de drogas, modelos de doenças e testes toxicológicos. Grandes avanços ocorreram na reprogramação de células diferenciadas pela expressão forçada de fatores de transcrição (FT), principalmente, através de vetores lentivirais (VL), que proporcionam uma reprogramação eficiente. Entretanto, a inserção lentiviral no genoma humano e sua influência na reprogramação é pouco conhecida. Neste trabalho, avaliamos o perfil de inserção dos VL utilizados na geração de iPS. As iPS foram geradas e caracterizadas por nosso grupo a partir de fibroblastos humanos transduzidos com VL contendo 3 FT [SOX2, TCL-1A e C-MYC (célula TSM)], e de células mesenquimais derivadas de tecido adiposo com um vetor lentiviral policistrônico contendo 4 FT [OCT4, SOX2, KLF4 e C-MYC (iPS 4FT)]. Cinco colônias isoladas de cada iPS foram mapeadas e analisadas quanto aos sítios de inserção pela técnica de LM-PCR. O DNA genômico digerido foi amplificado com um primer específico para o LTR viral e outro para um linker sintético. Os produtos foram clonados, sequenciados, e analisados em bancos de dados para identificar similaridades com o genoma humano, entre outras análises. Na célula TSM, 176 sequências, obtidas com a técnica de LM-PCR, apresentaram identidade com o genoma humano, sendo que cerca de 50% ocorreram em regiões gênicas com 94% destas em introns. Já nas iPS 4FT, 251 sequências apresentaram identidade, com cerca de 45% atingindo genes, 92% destas em introns. As inserções distribuíram-se por todos os cromossomos, com preferência pelos cromossomos 16, 17 e 20 para a TSM e pelos cromossomos 11, 15 e 17 para a iPS 4FT. Analisamos a distância da inserção ao sítio de início de transcrição (TSS), e inserções próximas a ilhas CpG, que em geral correspondem a regiões regulatórias. A maior proporção de inserção ocorreu a partir de ±30Kb de distância desses sítios. Os sítios frágeis e as regiões repetitivas do genoma foram atingidas, mas com uma frequência baixa. Os resultados mostraram uma preferência de inserção lentiviral por regiões gênicas nas iPS, indicando a possível participação de proteínas como LEDGF/p75 na integração nas células estudadas. Este trabalho mostrou que o local da integração pode contribuir para a reprogramação e, apesar de possíveis efeitos negativos das integrações, estas as células iPS ainda são uma ferramenta importante para estudos in vitro. E identificar fatores que influenciem a seleção do sítio de inserção é importante para determinar regiões cromossômicas \"seguras\" para a integração, aumentando a segurança no uso clínico. / The induced pluripotent stem (iPS) cells came with the promise of circumvent some of the limitations in the use of embryonic stem cells, like ethical issues, biological safety, immune compatibility and availability. This cells can be generated from somatic cells of normal individuals or from patients with some genetic disease, making then an important tool for drug screening, construction of disease models and toxicological trials. Great advances have happened in reprogramming differentiated cells through the forced exogenous expression of transcription factors (TF), mostly by lentiviral vectors (LV), which provide an efficient reprogramming. However, the lentiviral insertion in the human genome and its influence in reprogramming is not well known. In this work, we evaluate the insertion profile of LV used to generate human iPS cells. The iPS cells were generated, by our group, from human fibroblasts transduced by LV containing 3 TF [SOX2, TCL-1A and C-MYC (TSM reprogrammed cell)], and from mesenchymal cells derived from human adipose tissue transduced by a polycistronic LV containing 4 TF [OCT4, SOX2, KLF4 and C-MYC (iPS 4TF)]. Five isolated colonies of each iPS cell were mapped and analyzed for the insertion sites through LM-PCR technique. The digested genomic DNA was amplified with a primer for the viral LTR e another for a synthetic linker. The products were cloned, sequenced and analyzed in database to identify similarities with the human genome, among other analyzes. In TSM cell, 176 sequences, derived from the LM-PCR technique, presented identity with the human genome, and about 50% of those occurred in genic regions with 94% in introns. In iPS 4TF, 251 sequences showed identity, with about 45% reaching genes, 92% of these in introns. The insertions were distributed on all chromosomes, with preference for the 16, 17 and 20 for the TSM cell, and for the 11, 15 and 17 for the iPS 4TF. We analyzed the distance of the insertion from de transcription start site, and insertions near CpG islands, which, overall, correspond to regulatory regions. The highest proportion of insertion occurred starting ±30Kb distance from these sites. The fragile sites and the repetitive regions of the genome were also reached, but with low frequency. The results showed a preference of lentiviral insertion for genic regions in iPS, indicating the potential participation of proteins like LEDGF/p75 in integration in the cells of this work. This work shows that the integration site may contribute to the reprogramming, and, despite possible negative effects of integration, these iPS cells are still an important tool for in vitro studies. Identify factors that influence the selection of insertion site is important for determination of \"safe\" chromosomal regions for the integration, increasing the safe in clinical use.
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Generation and function of glucose-responsive insulin producing cells derived from human induced pluripotent stem cellsManzar, Gohar Shahwar 01 August 2015 (has links)
Type I diabetes (T1D) is caused by autoimmune destruction of pancreatic β-cells. Immediate consequences of T1D are severe weight loss, ketoacidosis and death unless insulin is administered. The long-term consequences of T1D are dysregulation of metabolism leading to cardiovascular complications, neuropathy and kidney insufficiency. It is estimated that 3 million Americans have T1D, and its prevalence among young individuals is progressively rising. Islet transplantation is the most effective way to treat T1D. Unfortunately, there is a chronic shortage of cadaveric organ donors to treat all of the patients on the waiting list. Thus, an alternative source of insulin producing cells (IPCs) could significantly improve patient treatment. Our lab seeks to establish human induced pluripotent stem (iPS) cells as a novel source of IPCs that are patient tailored. The aim of this thesis was to 1) compare the differentiation of T1D and nondiabetic (ND) patient-derived iPS cells into IPCs, and 2) devise an effective protocol for differentiating skin fibroblast-derived T1D iPS cells into functional, glucose-responsive IPCs. Initially, T1D iPS cells were differentiated into IPCs. However, the yield was very poor. We hypothesized that epigenetic barriers were prevalent in T1D iPS cells, limiting their differentiation into IPCs. To address this problem, we utilized 5-aza-2’-deoxycytidine (5-aza-DC), a potent demethylating agent that inhibits the DNA methyltransferase (Dnmt). We reasoned that the use of a demethylation agent might induce a more labile, permissive state, allowing for greater cell responses to differentiation stimuli. Typically, after the differentiation of T1D iPS cells, several cell cluster types are obtained, namely compact cell clusters and hollow cysts. 5-aza-DC treatment appeared to convert all of the cell clusters into characteristic islet-like compact structures. In contrast, in untreated T1D IPC cultures, we observed the dominant presence of many hollow cysts with only a few tight spheroids. The hollow cysts stained negative for insulin whereas the rare solid spheroids highly expressed insulin. Flow cytometry analysis indicated a much greater percentage of Pdx1+ and insulin+ cells in 5-Aza-DC-treated cultures. These cells express markers typical of pancreatic β-cells, possessed insulin granules in similar quantities as islets, and were glucose-responsive. When transplanted in immunodeficient mice that had developed streptozotozin-induced diabetes, there was a dramatic decrease of hyperglycemia within 28 days. These mice effectively managed glucose challenge by recovering to normoglycemia, whereas nontransplanted mice did not. Altogether, our data for the first time reveal a very high yield of functional IPCs derived from human iPS cells derived from a patient with T1D, which presents a novel alternative source of IPCs that could be used to treat T1D.
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Modifying the common marmoset monkey (Callithrix jacchus) genome: transgenesis and targeted gene modification in vivo and in vitroKahland, Tobias Sören 20 November 2015 (has links)
No description available.
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Modeling sporadic Alzheimer's disease using induced pluripotent stem cellsMcLaughlin, Heather Ward 01 January 2015 (has links)
Despite being the leading cause of neurodegeneration and dementia in the aging brain, the cause of Alzheimer's disease (AD) remains unknown in most patients. The terminal pathological hallmarks of abnormal protein aggregation and neuronal cell death are well-known from the post-mortem brain tissue of Alzheimer's disease patients, but research into the earliest stages of disease development is hindered by limited model systems. In this thesis, an in vitro human neuronal system was derived from induced pluripotent stem (iPS) cell lines reprogrammed from dermal fibroblasts of AD patients and age-matched controls. This allows us to investigate the cellular mechanisms of AD neurodegeneration in the human neurons of sporadic AD (SAD) patients, whose development of the disease cannot be explained by our current understanding of AD. We show that neural progenitors and neurons derived from SAD patients show an unexpected expression profile of enhanced neuronal gene expression resulting in premature differentiation in the SAD neuronal cells. This difference is accompanied by the decreased binding of the repressor element 1-silencing transcription/neuron-restrictive silencer factor (REST/NRSF) transcriptional inhibitor of neuronal differentiation in the SAD neuronal cells. The SAD neuronal cells also have increased production of \(amyloid-\beta\) and higher levels of tau protein, the main components of the plaques and tangles in the AD brain.
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Geração de células de pluripotência induzida (iPS) humanas utilizando vetores lentivirais e determinação do perfil de integração lentiviral / Generation of human induced pluripotent stem (iPS) cell using lentiviral vector and determination of the lentiviral integration profileLuiza Cunha Junqueira Reis 28 November 2012 (has links)
As células iPS surgiram com a promessa de contornar as limitações das células-tronco embrionárias, como questões éticas, segurança, compatibilidade e disponibilidade. Essas células podem ser obtidas a partir de células somáticas de indivíduos normais ou de pacientes com doenças genéticas, fazendo destas uma importante ferramenta para o screening de drogas, modelos de doenças e testes toxicológicos. Grandes avanços ocorreram na reprogramação de células diferenciadas pela expressão forçada de fatores de transcrição (FT), principalmente, através de vetores lentivirais (VL), que proporcionam uma reprogramação eficiente. Entretanto, a inserção lentiviral no genoma humano e sua influência na reprogramação é pouco conhecida. Neste trabalho, avaliamos o perfil de inserção dos VL utilizados na geração de iPS. As iPS foram geradas e caracterizadas por nosso grupo a partir de fibroblastos humanos transduzidos com VL contendo 3 FT [SOX2, TCL-1A e C-MYC (célula TSM)], e de células mesenquimais derivadas de tecido adiposo com um vetor lentiviral policistrônico contendo 4 FT [OCT4, SOX2, KLF4 e C-MYC (iPS 4FT)]. Cinco colônias isoladas de cada iPS foram mapeadas e analisadas quanto aos sítios de inserção pela técnica de LM-PCR. O DNA genômico digerido foi amplificado com um primer específico para o LTR viral e outro para um linker sintético. Os produtos foram clonados, sequenciados, e analisados em bancos de dados para identificar similaridades com o genoma humano, entre outras análises. Na célula TSM, 176 sequências, obtidas com a técnica de LM-PCR, apresentaram identidade com o genoma humano, sendo que cerca de 50% ocorreram em regiões gênicas com 94% destas em introns. Já nas iPS 4FT, 251 sequências apresentaram identidade, com cerca de 45% atingindo genes, 92% destas em introns. As inserções distribuíram-se por todos os cromossomos, com preferência pelos cromossomos 16, 17 e 20 para a TSM e pelos cromossomos 11, 15 e 17 para a iPS 4FT. Analisamos a distância da inserção ao sítio de início de transcrição (TSS), e inserções próximas a ilhas CpG, que em geral correspondem a regiões regulatórias. A maior proporção de inserção ocorreu a partir de ±30Kb de distância desses sítios. Os sítios frágeis e as regiões repetitivas do genoma foram atingidas, mas com uma frequência baixa. Os resultados mostraram uma preferência de inserção lentiviral por regiões gênicas nas iPS, indicando a possível participação de proteínas como LEDGF/p75 na integração nas células estudadas. Este trabalho mostrou que o local da integração pode contribuir para a reprogramação e, apesar de possíveis efeitos negativos das integrações, estas as células iPS ainda são uma ferramenta importante para estudos in vitro. E identificar fatores que influenciem a seleção do sítio de inserção é importante para determinar regiões cromossômicas \"seguras\" para a integração, aumentando a segurança no uso clínico. / The induced pluripotent stem (iPS) cells came with the promise of circumvent some of the limitations in the use of embryonic stem cells, like ethical issues, biological safety, immune compatibility and availability. This cells can be generated from somatic cells of normal individuals or from patients with some genetic disease, making then an important tool for drug screening, construction of disease models and toxicological trials. Great advances have happened in reprogramming differentiated cells through the forced exogenous expression of transcription factors (TF), mostly by lentiviral vectors (LV), which provide an efficient reprogramming. However, the lentiviral insertion in the human genome and its influence in reprogramming is not well known. In this work, we evaluate the insertion profile of LV used to generate human iPS cells. The iPS cells were generated, by our group, from human fibroblasts transduced by LV containing 3 TF [SOX2, TCL-1A and C-MYC (TSM reprogrammed cell)], and from mesenchymal cells derived from human adipose tissue transduced by a polycistronic LV containing 4 TF [OCT4, SOX2, KLF4 and C-MYC (iPS 4TF)]. Five isolated colonies of each iPS cell were mapped and analyzed for the insertion sites through LM-PCR technique. The digested genomic DNA was amplified with a primer for the viral LTR e another for a synthetic linker. The products were cloned, sequenced and analyzed in database to identify similarities with the human genome, among other analyzes. In TSM cell, 176 sequences, derived from the LM-PCR technique, presented identity with the human genome, and about 50% of those occurred in genic regions with 94% in introns. In iPS 4TF, 251 sequences showed identity, with about 45% reaching genes, 92% of these in introns. The insertions were distributed on all chromosomes, with preference for the 16, 17 and 20 for the TSM cell, and for the 11, 15 and 17 for the iPS 4TF. We analyzed the distance of the insertion from de transcription start site, and insertions near CpG islands, which, overall, correspond to regulatory regions. The highest proportion of insertion occurred starting ±30Kb distance from these sites. The fragile sites and the repetitive regions of the genome were also reached, but with low frequency. The results showed a preference of lentiviral insertion for genic regions in iPS, indicating the potential participation of proteins like LEDGF/p75 in integration in the cells of this work. This work shows that the integration site may contribute to the reprogramming, and, despite possible negative effects of integration, these iPS cells are still an important tool for in vitro studies. Identify factors that influence the selection of insertion site is important for determination of \"safe\" chromosomal regions for the integration, increasing the safe in clinical use.
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Reprogramação de células mesenquimais de tecido adiposo em células-tronco pluripotentes por meio de proteína de fusão TAT / Nuclear reprogramming of adipose-tissue mesenchymal stem cells into pluripotent stem cells using TAT fusion proteinBassaneze, Vinícius 23 February 2012 (has links)
Os vírus são eficazes na transferência de genes em células devido aos seus mecanismos especializados. No entanto, vírus como veículos de entrega de genes podem acarretar em problemas, particularmente quando proposto para reprogramar células somáticas em células-tronco pluripotentes induzidas (iPS) visando utilização terapêutica. No presente estudo, procurou-se desenvolver um sistema alternativo para entregar diretamente proteínas nucleares (Oct4, Sox2, KLF4, e c-Myc) fusionadas com o domínio de transdução de proteína TAT, para promover a reprogramação de fibroblastos embrionários de camundongos (MEF) ou células mesenquimais derivadas de tecido adiposo humano (hASC) em células iPS. Primeiramente o PTD TAT ou TAT- foi fundido a proteína verde fluorescente (GFP) como modelo para prova de princípio e padronização detalhada. Inesperadamente, TAT-GFP produzido e secretado pelas células NIH-3T3 produtora não foi capaz de ser detectado no meio de cultura por verificação quantitativa fluorimétrica, nem foi capaz de ser detectada em células-alvo, por citometria de fluxo, depois de co-cultura em transwells. Essa observação pode ser explicada por: (1) ineficiência desse tipo de célula em secretar proteínas e (2) falta de resistência à clivagem por endoproteases furinas. Para contornar esses fatores limitantes usou-se citometria de fluxo para avaliar as melhores condições para a transfecção por seis diferentes tipos de células (CHO, NIH-3T3, HT1080, HEK-293A, HEK-293t e COS-7) com TAT (modificada para ser resistente à furinas) fundido a GFP. Células 293t-TAT-GFP exibiram a maior eficiência de transfecção e também de secreção. O mesmo pôde ser observado para as seis linhagens celulares expressando fatores de transcrição nucleares TAT, determinados por ELISA. Em seguida, diferentes estratégias de entrega foram testadas. A primeira foi baseada na co-cultura de uma mistura de células produtoras com MEF ou hASC. No entanto, não foi possível observar a reprogramação devido à morte celular. A segunda foi baseada na concentração de meio condicionado de cultura de células por centrifugação usando colunas Amicon, trocando o meio a cada 24h, em quatro ciclos. No entanto, apesar da presença de algumas colônias após 20-30 dias, nenhuma colônia verdadeira iPS foi obtida. Na sequência, as células foram tratadas com cada proteína de forma independente, e as demais foram substituídas pelo retrovírus correspondente, trocando meio a cada 72h, em quatro ciclos. Essa estratégia, apesar de permitir verificar a função de cada proteína, também não resultou em reprogramação. Este achado pode ser explicado pela diferenciação celular induzida por BCS, que também é concentrado no processo. Assim, passou-se a adaptação de \"células produtoras\" em condições de cultura livre de soro, para enriquecer a produção dos fatores nucleares individuais, necessários para a reprogramação. A otimização sistematizada deste processo está sendo realizada em parceria com o IPT e deve resultar em quantidades de proteína de fusão suficientes para o teste final da hipótese proposta. Em conjunto, são apresentados os dados da geração de linhagens celulares expressando estavelmente os vários fatores de transcrição e estratégias para melhorar a eficiência necessária para a produção iPS. Esta nova estratégia garante uma produção eficiente de TAT fundida a fatores nucleares de reprogramação e sua eficácia para promover a reprogramação de células somáticas de maneira livre de vírus merece ser investigado futuramente / Viruses are effective at transferring genes into cells by its specialized mechanisms. However, viruses as gene delivery vehicles entail problems, particularly when proposed to reprogram somatic cells into induced pluripotent stem cells (iPS) for therapeutic uses. In the present study, we aimed to develop an alternative system for directly delivering nuclear proteins (Oct4, Sox2, Klf4, and c-Myc) fused with TAT protein transduction domain to promote reprogramming of mouse embryonic fibroblasts (MEF) or human adipose tissue derived mesenchymal cells (hASC) into iPS cells. First TAT- or TAT- PTD was fused to green fluorescent protein (GFP) as a proof of principle model and for detailed standardization. Unexpectedly, TAT-GFP produced and secreted by NIH-3T3 producer cells was not detected in the culture medium by quantitative fluorimetric verification, nor detected on target cells, by flow cytometry, after being co-cultured using transwells. This observation maybe explained by: (1) inefficiency of this cell type to be transfected and to secrete proteins and (2) lack of resistance to furin endoproteases cleavage on Golgi of TAT sequence. To circumvent these limiting factors we used flow cytometer to assess the best conditions for transfection in six different cell types (CHO, NIH-3T3, HT1080, HEK-293A, HEK-293t and COS-7) with TAT- (a modified PTD to be resistant to furin endoproteases) fused to GFP. 293t-TAT-GFP cells displayed the highest transfection efficiency and secretion levels. The same could be observed for the six cell lineages expressing TAT- nuclear transcription factors, determined by ELISA.Next, different delivery strategies were tested for TAT- nuclear transcription factor system. Co-culturing a mix of producer cells with MEF or hASC resulted in not reprogramming and this was associated with cell death. The second was based on the use of microconcentrated conditioned cell culture medium, changed every 24h, in four cycles. However, despite the presence of some emerging colonies after 20-30 days, no true iPS colonies were obtained. Then, cells were treated with each protein independently, and the others were replaced by the corresponding retrovirus, changing cell medium every 72h, in four cycles. We verified the reprogramming potential of each protein, but no true colonies were obtained.One possibility for this finding is that BCS is also concentrated by centrifugation and may induce cell differentiation. To circumvent these problems, we have started the adaptation of producer cells in a serum-free culture condition to enrich the production of the individual factors required for reprogramming. This optimization process is taking place in collaboration with the IPT and shall result in large amounts of the fusion protein to finally test the proposed hypothesis. Altogether, we presented the generation of several cell lines stably expressing the transcription factors and strategies to improve the efficiency required for iPS production. This novel strategy guarantees efficient production of TAT-fused reprogramming nuclear factors and its efficacy to promote somatic cells reprogramming in a virus-free manner deserves to be further investigated
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