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Epigenética da reprogramação em células germinativas embrionárias caninas / Epigenetics of reprogramming in canine embryonic germ cellsAline Fernanda de Souza 16 February 2017 (has links)
As células germinativas primordiais (CGPs) são as precursoras dos gametas, capazes de gerar um novo indivíduo os quais transmitirão os materiais genéticos para as futuras gerações. Normalmente, a linha germinal de mamífero é determinada por fatores genéticos e epigenéticos que possuem funções essenciais para guiar na direção e desenvolvimento das CGPs, bem como das células germinativas embrionárias (CGEs). A reprogramação epigenética é fundamental para a regulação do genoma durante o desenvolvimento das células germinativas responsáveis por originar a linhagem gametogênica nos mamíferos. A metilação e desmetilação em CGPs são um evento único, essencial para apagar a memória epigenética e também prevenir transmissões de epimutações para a próxima geração. Assim, o completo entendimento das vias e mecanismos para a migração inicial e diferenciação destas células em CGEs podem ser importantes para identificar e corrigir falhas possíveis nesses processos, o que será importante, no futuro, para o desenvolvimento e desempenho reprodutivo. A maioria dos estudos com CGPs e CGEs é realizado em camundongos, porém nem sempre esta espécie torna-se o melhor modelo de estudo quando se quer transpor esses conhecimentos a humanos. O cão doméstico (Canis lúpus familiaris) apresenta-se como um modelo ideal para o estudo do desenvolvimento em mamíferos, pois possui inúmeras similaridades com a bioquímica, fisiologia e genética. Deste modo, torna-se interessante expandir os estudos sobre as CGPs e CGEs na espécie canina, a fim de mostrar a importância de diferentes modelos que se assemelham a seres humanos. Portanto, objetiva-se, nesta proposta, identificar qual é a dinâmica de marcadores pluripotentes, germinativos e epigenéticos que são importantes para o desenvolvimento das CGPs e CGEs caninas. Para tal procedimento, essa pesquisa foi dividida em duas fases: a primeira, consiste no processo in vivo, desde o desenvolvimento inicial do embrião até a completa formação da crista gônadal. Análises de RTq-PCR e imunofluorescência para marcadores pluripotentes POU5F1 (OCT4) e NANOG, germinativos DDX4 (VASA), DAZL e DPPA3 (STELLA) e epigenéticos 5mC, 5hmC, H3K27me3 e H3K9me2 foram realizados para criar um perfil de genes que são importantes para o desenvolvimento das CGPs caninas. Prosseguiu-se para a segunda fase in vitro, que incide na derivação e caracterização das CGEs caninas. Ensaios de Fosfatase Alcalina, imunofluorescência para os marcadores: pluripotente POU5F1 (OCT4), germinativos DDX4 (VASA), DAZL e DPPA3 (STELLA), mesodérmico THY-1 (CD90) e epigenéticos 5mC, 5hmC, H3K27me3 e H3K9me2, RT-qPCR para os genes NANOG e DDX4 e formação de teratoma foram efetivados para comprovar a linhagem de células CGEs. Como resultado in vivo, percebe-se que diferentes padrões de marcações e genes foram expressos nas CGPs, comprovando que a espécie canina se assemelha mais com os humanos do que com os camundongos. Os resultados in vitro mostraram que foi possível derivar as células CGEs e que estas conseguem reter sua pluripotencialidade e que diminuem a expressão dos genes germinativos. Porém, essas células tendem a se diferenciar em outros tecidos somáticos, mesmo com a adição de suplementos, fato também notado em CGEs humanas. / Primordial germ cells (PGCs) are known as the only cells capable of generating a new individual, they originate the gametes which then will transmit genetic material to future generations. Normally, the mammalian germ line is determined by genetic and epigenetic factors that have essential functions to guide the direction and development of PGCs as well as embryonic germ cells (EGCs). Epigenetic reprogramming is fundamental for the regulation of the genome during the development of the germ cells responsible for originating the gametogenic lineage in mammals. Methylation and demethylation in PGCs is a unique event, essential for erasing epigenetic memory and also preventing transmissions of epimutations to the next generation. Thus, the understanding of the patterns of differentiation of PGCs in EGCs can be important in identifying and correcting possible failures in these processes, which will be important in the future for development and reproductive performance. Most of the studies with PGCs in EGCs are carried out in mice, but this species is not always the best model of study when transposing this knowledge to humans. In canines, no study has ever been reported on canine PGCs and maybe the Canine species has become interesting as a new animal model for studies. It is known that the study material of human embryos are scarce samples and difficult to obtain, so it is necessary to use other animal models, such as the Canids, which also resemble humans. Dogs were the first fundamental models for the development of bone marrow transplantation in humans, but also made valuable contributions to the development of therapies for cardiovascular and orthopedic diseases. Then, it has become interesting to expand the studies on PGCs in the canine species in order to show the importance of different models that might resemble humans. Therefore, we had how proposal identify which were pluripotent, germinative and epigenetic markers that are important for the development of PGCs and canine EGCs. It research was divided into two phases: the first consists of the in vivo process, from the initial development of the embryo to the complete formation of the gonadal ridge. We analyzed through the techniques of real-time PCR (RT-qPCR) and immunofluorescence for pluripotent markers POU5F1 (OCT4) and NANOG, germline DDX4 (VASA), DAZL and DPPA3 (STELLA) and epigenetic 5mC, 5hmC, H3K27me3 and H3K9me2 were performed to create a profile of genes that are important for the development of canine PGCs. We proceeded to the second in vitro phase, which focuses on the derivation and characterization of canine EGCs. Alkaline Phosphatase (AP), immunofluorescence for the markers: pluripotent POU5F1 (OCT4), germinative DDX4 (VASA), DAZL and DPPA3 (STELLA), mesodermal THY-1 (CD90) and epigenetic 5mC, 5hmC, H3K27me3 and H3K9me2. We also analyzed RT-qPCR for NANOG and DDX4 genes and teratoma formation were performed to prove the EGCs cell lineage. As a result in vivo, different marking patterns and genes had been expressed in CGPs, proving that the canine species is more similar to humans than to mice. The in vitro results showed that it was possible to derive the EGCs and that they are able to retain their pluripotency and decrease the expression of the germinative genes. However, these cells continue to differentiate into other somatic tissues, even with the addition of supplements, a fact also noted in human CGEs.
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Epigenética da reprogramação em células germinativas embrionárias caninas / Epigenetics of reprogramming in canine embryonic germ cellsSouza, Aline Fernanda de 16 February 2017 (has links)
As células germinativas primordiais (CGPs) são as precursoras dos gametas, capazes de gerar um novo indivíduo os quais transmitirão os materiais genéticos para as futuras gerações. Normalmente, a linha germinal de mamífero é determinada por fatores genéticos e epigenéticos que possuem funções essenciais para guiar na direção e desenvolvimento das CGPs, bem como das células germinativas embrionárias (CGEs). A reprogramação epigenética é fundamental para a regulação do genoma durante o desenvolvimento das células germinativas responsáveis por originar a linhagem gametogênica nos mamíferos. A metilação e desmetilação em CGPs são um evento único, essencial para apagar a memória epigenética e também prevenir transmissões de epimutações para a próxima geração. Assim, o completo entendimento das vias e mecanismos para a migração inicial e diferenciação destas células em CGEs podem ser importantes para identificar e corrigir falhas possíveis nesses processos, o que será importante, no futuro, para o desenvolvimento e desempenho reprodutivo. A maioria dos estudos com CGPs e CGEs é realizado em camundongos, porém nem sempre esta espécie torna-se o melhor modelo de estudo quando se quer transpor esses conhecimentos a humanos. O cão doméstico (Canis lúpus familiaris) apresenta-se como um modelo ideal para o estudo do desenvolvimento em mamíferos, pois possui inúmeras similaridades com a bioquímica, fisiologia e genética. Deste modo, torna-se interessante expandir os estudos sobre as CGPs e CGEs na espécie canina, a fim de mostrar a importância de diferentes modelos que se assemelham a seres humanos. Portanto, objetiva-se, nesta proposta, identificar qual é a dinâmica de marcadores pluripotentes, germinativos e epigenéticos que são importantes para o desenvolvimento das CGPs e CGEs caninas. Para tal procedimento, essa pesquisa foi dividida em duas fases: a primeira, consiste no processo in vivo, desde o desenvolvimento inicial do embrião até a completa formação da crista gônadal. Análises de RTq-PCR e imunofluorescência para marcadores pluripotentes POU5F1 (OCT4) e NANOG, germinativos DDX4 (VASA), DAZL e DPPA3 (STELLA) e epigenéticos 5mC, 5hmC, H3K27me3 e H3K9me2 foram realizados para criar um perfil de genes que são importantes para o desenvolvimento das CGPs caninas. Prosseguiu-se para a segunda fase in vitro, que incide na derivação e caracterização das CGEs caninas. Ensaios de Fosfatase Alcalina, imunofluorescência para os marcadores: pluripotente POU5F1 (OCT4), germinativos DDX4 (VASA), DAZL e DPPA3 (STELLA), mesodérmico THY-1 (CD90) e epigenéticos 5mC, 5hmC, H3K27me3 e H3K9me2, RT-qPCR para os genes NANOG e DDX4 e formação de teratoma foram efetivados para comprovar a linhagem de células CGEs. Como resultado in vivo, percebe-se que diferentes padrões de marcações e genes foram expressos nas CGPs, comprovando que a espécie canina se assemelha mais com os humanos do que com os camundongos. Os resultados in vitro mostraram que foi possível derivar as células CGEs e que estas conseguem reter sua pluripotencialidade e que diminuem a expressão dos genes germinativos. Porém, essas células tendem a se diferenciar em outros tecidos somáticos, mesmo com a adição de suplementos, fato também notado em CGEs humanas. / Primordial germ cells (PGCs) are known as the only cells capable of generating a new individual, they originate the gametes which then will transmit genetic material to future generations. Normally, the mammalian germ line is determined by genetic and epigenetic factors that have essential functions to guide the direction and development of PGCs as well as embryonic germ cells (EGCs). Epigenetic reprogramming is fundamental for the regulation of the genome during the development of the germ cells responsible for originating the gametogenic lineage in mammals. Methylation and demethylation in PGCs is a unique event, essential for erasing epigenetic memory and also preventing transmissions of epimutations to the next generation. Thus, the understanding of the patterns of differentiation of PGCs in EGCs can be important in identifying and correcting possible failures in these processes, which will be important in the future for development and reproductive performance. Most of the studies with PGCs in EGCs are carried out in mice, but this species is not always the best model of study when transposing this knowledge to humans. In canines, no study has ever been reported on canine PGCs and maybe the Canine species has become interesting as a new animal model for studies. It is known that the study material of human embryos are scarce samples and difficult to obtain, so it is necessary to use other animal models, such as the Canids, which also resemble humans. Dogs were the first fundamental models for the development of bone marrow transplantation in humans, but also made valuable contributions to the development of therapies for cardiovascular and orthopedic diseases. Then, it has become interesting to expand the studies on PGCs in the canine species in order to show the importance of different models that might resemble humans. Therefore, we had how proposal identify which were pluripotent, germinative and epigenetic markers that are important for the development of PGCs and canine EGCs. It research was divided into two phases: the first consists of the in vivo process, from the initial development of the embryo to the complete formation of the gonadal ridge. We analyzed through the techniques of real-time PCR (RT-qPCR) and immunofluorescence for pluripotent markers POU5F1 (OCT4) and NANOG, germline DDX4 (VASA), DAZL and DPPA3 (STELLA) and epigenetic 5mC, 5hmC, H3K27me3 and H3K9me2 were performed to create a profile of genes that are important for the development of canine PGCs. We proceeded to the second in vitro phase, which focuses on the derivation and characterization of canine EGCs. Alkaline Phosphatase (AP), immunofluorescence for the markers: pluripotent POU5F1 (OCT4), germinative DDX4 (VASA), DAZL and DPPA3 (STELLA), mesodermal THY-1 (CD90) and epigenetic 5mC, 5hmC, H3K27me3 and H3K9me2. We also analyzed RT-qPCR for NANOG and DDX4 genes and teratoma formation were performed to prove the EGCs cell lineage. As a result in vivo, different marking patterns and genes had been expressed in CGPs, proving that the canine species is more similar to humans than to mice. The in vitro results showed that it was possible to derive the EGCs and that they are able to retain their pluripotency and decrease the expression of the germinative genes. However, these cells continue to differentiate into other somatic tissues, even with the addition of supplements, a fact also noted in human CGEs.
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Insights Into Molecular Regulation Of Cardiomyocyte Differentiation Of Mouse Pluripotent Stem CellsAbbey, Deepti 07 1900 (has links) (PDF)
Pluripotent stem cells (PSCs) are specialized cells, which have remarkable ability to maintain in an undifferentiated state and are capable of undergoing differentiation to three germ-layer lineage cell types, under differentiation-enabling conditions. PSCs include embryonic stem (ES)-cells, embryonal carcinoma (EC)-cells and embryonic germ (EG)-cells. ES-cells are derived from the inner cell mass (ICM) of day 3.5 blastocysts (mouse). On the other hand, EC- and EG-cells have different source of origin and exhibit some differences in terms of their differentiation abilities and culture requirements. These PSCs act as an ideal in-vitro model system to study early mammalian development and cell differentiation and, they could potentially be used for experimental cell-based therapy for a number of diseases. However, one of the problems encountered is the immune rejection of transplanted cells. For this, immune-matched induced pluripotent stem (iPS)-cells have been derived from somatic cells, by forced expression of a few stemness genes. Although, human PSCs lines are being experimented, their cell-therapeutic potential is still far from being thoroughly tested due to lack of our understanding regarding lineage-specific differentiation, homing and structural-functional integration of differentiated cell types in the host environment. To understand these mechanisms, it is desirable to have fluorescently-marked PSCs and their differentiated cell-types, which could facilitate experimental cell transplantation studies.
In this regard, our laboratory has earlier generated enhanced green fluorescent protein (EGFP)-expressing FVB/N transgenic ‘green’ mouse: GU-3 line (Devgan et al., 2003). This transgenic mouse has been an excellent source of intrinsically green fluorescent cell types. Recently, we have derived a ‘GS-2’ ES-cell line from the GU-3 mouse line (Singh et al., 2012). Additionally, we envisaged the need for developing an iPS-cell line from the GU-3 mouse and then use them for studying cell differentiation. Thus, aims of the study described in the thesis are to: (1) develop an experimental system to derive EGFP-expressing fluorescently-marked iPS-cell line from a genetically non-permissive FVB/N mouse strain, characterize the established iPS-cell line and achieve differentiation of various cell types from EGFP-expressing iPS-cell line; (2) to study differentiation phenomenon, in particular to cardiac lineage, using select-cardiogenesis
modulators and (3) to assess the gene-expression profiles and signaling system associated with cardiomyocyte differentiation of PSCs.
This thesis is divided into four chapters with the 1st chapter being a review of literature followed by three data chapters. In the chapter I of the thesis, a comprehensive up-to¬date review of literature is provided pertaining to PSCs, their classification, derivation strategies especially for reprogramming of somatic cells for iPSC generation, their differentiation potential and characterization, particularly to cardiac lineage. Various molecular regulators involved in cardiac differentiation of PSCs with emphasis on epigenetic regulation involving DNA methylation and signaling pathways involved are described in detail. Subsequently, various approaches used for enhanced cardiac differentiation of PSCs and the therapeutic potential of PSC-derived differentiated cell types to treat disease(s) are discussed.
Chapter-II describes the successful establishment of a permanent iPS-cell line (named ‘N9’ iPS-cell line) from the non-permissive FVB/N EGFP-transgenic GU-3 ‘green’ mouse. This chapter provides results pertaining to detailed derivation strategy and characterization of the ‘N9’ iPS-cell line which includes colony morphology, expansion (proliferation) efficiency, alkaline phosphatase staining, pluripotent markers’ expression analysis by qPCR and immunostaining approaches and karyotyping analysis. Further, in order to thoroughly assess the differentiation competence of the ‘N9’ iPS¬cell line, assessment of in-vitro and in-vivo differentiation potential of the ‘N9’ iPS-cell line by embryoid body (EB) formation and teratoma formation in nude mice and its detailed histological analysis showing three germ layer cell types and their derivatives were performed, followed by the generation of chimeric blastocysts by aggregation method. This established N9 iPS-cell line could potentially offer a suitable model system to study cardiac differentiation along with other established PSC lines such as the GS-2 and D3 ES-cell lines and the P19 EC-cell line.
Following the establishment of the system to study cardiac differentiation of PSC lines, efforts were made to understand the biology of cardiac differentiation of PSCs (wild¬type and EGFP-transgenic PSC lines and P19 EC-cell line) using small molecules as
modulators. Data pertaining to this is described in Chapter-III. The possible involvement of epigenetic regulation of cardiogenesis for example, DNA methylation changes in cardiogenesis-associated genes is studied using 5-aza cytidine as one of the chromatin modifiers. In order to understand the cardiac differentiation phenomenon, as a consequence of using 5-aza cytidine in cell culture, it was important to investigate its ability to induce/mediate cardiac differentiation. This involved an assessment by quantitating the cardiac beating phenotype and correlating this with enhanced cardiac-gene expression profiles. Further, DNA methylation regulation of cardiogenesis¬associated genes is described using various DNA methylation analysis techniques. Moreover, the possible involvement of other signaling members in mediating the cardiac differentiation is also studied using the P19 EC-cells. Results pertaining to the above findings are described in detail in the Chapter-III.
Chapter-IV is focused on various efforts made towards investigating the ability of ascorbic acid to enhance cardiac differentiation of mouse ES-cells (GS-2 and D3 lines). Ascorbic acid has been implicated to be influencing cardiogenesis and it is reported to enhance differentiation of various cell types under certain culture conditions. Results pertaining to enhancement of cardiac differentiation of PSCs using ascorbic acid are presented in this chapter. This included assessment by quantitating cardiac beating phenotype and its correlation with enhanced cardiogenesis-associated gene expression profiles. Besides, estimation on the sorted cardiomyocyte population, derived from PSCs was also made using mature-cardiac marker. The possible underlying signaling mechanism involved was also studied in detail, using specific inhibitors for pERK (U0126), integrin signaling (pFAK; PP2) and collagen synthesis (DHP), in order to ascertain their involvement in ascorbic acid-mediated cardiac differentiation of mouse ES-cells. Subsequent to the three data chapters (II-IV), separate sections are provided for ‘Summary and Conclusion’ and for ‘Bibliography’, cited in the thesis. The overall scope of the study has been to understand the basic biology of cardiac differentiation from PSCs (EC-cells, iPS-cells and transgenic and wild-type ES-cells) and to assess, by using certain small molecules, whether PSCs could be coaxed to enhance the differentiation to a particular cell type (cardiac). The data contained in this thesis addresses the above theme.
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microRNA expression profile of undifferentiated and differentiating pluripotent cells / microRNA Expressionsprofile in nicht differenzierten und differenzierten pluripotenten ZelllinienPantazi, Angeliki 29 September 2009 (has links)
No description available.
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