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Gene expression in cultured cellsFioroni, Orietta Maria January 1989 (has links)
Dedifferentiation is the process by which specialised quiescent cells give rise to heterotrophic, dividing cells. This process may be initiated in vivo as a response to wounding, or in vitro during culture initiation. This thesis is concerned with evaluating whether the process of dedifferentiation and maintenance of the fast-dividing, dedifferentiated state by culture, is dependant upon major changes in gene expression. In particular, the role of transcription, as mirrored by changes in steady state mRNA levels, in these putative changes in gene expression has been investigated. Mechanically isolated Asparagus officinalis mesophyll cells were used to study dedifferentiating cells, and suspension cultures of Petunia hybrida to investigate the established dedifferentiated state. This thesis shows that dedifferentiation in Asparagus officinalis is accompanied by major changes in the steady state mRNA profiles of the cells. A group of novel transcripts appearing in dedifferentiating asparagus cells were termed DDl, and targeted for further study. Two cDNA clones coding for DDl transcripts were isolated and characterised, and antibodies to DDl raised for serological work. Only minor differences were found between the steady state mRNA populations of Petunia hybrida cultured cells and seedlings, and these were mainly caused by transcripts disappearing in culture; no transcripts specific to the suspension culture system were detected. The results presented in this thesis are used to foward the hypothesis that changes in gene expression involving de novo transcription may only occur in response to major changes in environmental conditions. It is suggested that the basal transcription pattern for cells in established state is probably common to all cell types with regards to primary cell functions such as growth, division and catabolism. In such established states, the control of metabolism probably resides within the biochemical pathways utilised by the cell at any moment in time.
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Proteome and phosphoproteome dynamic change during cell dedifferentiation in Arabidopsis thalianaChitteti, Brahmananda Reddy 11 August 2007 (has links)
Cell dedifferentiation is a cell fate switching process in which a differentiated cell reverts to a status with competence for cell division and organ regeneration like an embryonic stem cell. Although the phenomenon of cell dedifferentiation has been known for over two and a half centuries in plants, little is known of the underlying mechanisms. Here, the proteome map of Arabidopsis cotyledons has been established and investigated the dynamic change of the cotyledon proteome in the time course of cell dedifferentiation. Among the 353 distinct genes, corresponding to 500 2-DE gel protein spots identified with high confidence, 12% have over twofold differential regulations within the first 48 h of induction of cell dedifferentiation. The distributions of these genes among different Gene Ontology categories and gene differential regulations within each of the categories have been examined. In addition, the cotyledon phosphoproteome has been investigated using Pro-Q Diamond Phosphoprotein in Gel Stain followed by mass spectrometry analyses. Among the 53 identified putative phosphoproteins, nine are differentially regulated during cell dedifferentiation. Arabidopsis cotyledon proteome at four different time points after the induction of cell dedifferentiation with MudPIT approach has been investigated and analyzed the protein quantity change using two labelree methods, the Spectral Count (SC) and SEQUEST Cross Correlation Coefficient (ÓXcorr) methods. Among the 662 MudPIT identified proteins, one hundred forty eight displayed differential regulation. The up-regulated proteins include transcription factors, calmodulins, translational regulators, and stress response proteins. The Spectral Count and the cross correlation coefficient quantification results are highly consistent in over 81% of the differentially regulated proteins. These studies have provided significant new insight into cell dedifferentiation process in Arabidopsis thaliana and also enhanced the Arabidopsis cotyledon proteome database established using gel based and non gel based methods. The results show that cell dedifferentiation involves extensive protein quantitative and qualitative changes in almost every cellular compartment and cellular process. Proteins like 14-3-3 proteins, Translational controlled tumor protein (TCTP) and its possible interaction protein-Translational elongation factor eEF1 alpha chain, GTP binding nuclear protein RAN2, GTP binding protein SAR1B and several other hypothetical and expressed proteins and nine other phosphoproteins showed significant differential expression during early dedifferentiation. Deciphering the molecular mechanisms regulating the cellular dedifferentiation certainly enhances the understandings and mechanisms of reprogramming all types of differentiated cells including animal cells.
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Regulação do fator de transcrição MEF2C pela quinase de adesão focal = implicações na homeostase dos cardiomiócitos = Regulation of transcription factor MEF2C by focal adhesion kinase: implications in the homeostasis of cardiomyocytes / Regulation of transcription factor MEF2C by focal adhesion kinase : implications in the homeostasis of cardiomyocytesCardoso, Alisson Campos, 1983- 21 August 2018 (has links)
Orientador: Orientador : Kleber Gomes Franchini / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-21T12:58:21Z (GMT). No. of bitstreams: 1
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Previous issue date: 2012 / Resumo: Durante os primeiros dias do desenvolvimento pós-natal, os miócitos cardíacos perdem a capacidade de proliferação, sendo o crescimento adicional do coração decorrente de hipertrofia e não hiperplasia dos miócitos cardíacos. No entanto, em situações de estresse os miócitos cardíacos diferenciados podem apresentar desdiferenciação e reestabelecimento do ciclo celular. Os mecanismos envolvidos nesse fenômeno são ainda pouco compreendidos. No presente estudo, demonstramos que a ativação do fator de transcrição MEF2C (Myocyte Enhancer Factor 2-C) tem papel crítico no processo de desdiferenciação de miócitos cardíacos. Essa conclusão foi obtida por meio de experimentos de ganho de função pela superexpressão de MEF2C em miócitos ventriculares de ratos neonatos em cultura (MVRNs). Demonstramos que a superexpressão de MEF2C em MVRNs induziu a desdiferenciação e a ativação de mecanismos envolvidos na progressão do ciclo celular. Esses resultados foram obtidos por meio de experimentos de microarranjo de DNA, PCR em tempo real, western blotting e análise do fenótipo celular por microscopias de luz, confocal e eletrônica de transmissão. Esses fenômenos foram atenuados pela superexpressão da quinase de adesão focal (FAK), uma proteína que reconhecidamente exerce efeitos pró-hipertróficos em miócitos cardíacos adultos. Experimentos in vivo e in vitro demonstraram a interação direta entre o fator de transcrição MEF2C e a FAK. Estudos com base em ensaios de reação cruzada associada à espectrometria de massas, dinâmica molecular, espalhamento de raios-X a baixos ângulos e mutação sítio dirigida, demonstraram que as hélices 1 e 4 do domínio FAT da FAK interagem diretamente com a domínio de ligação ao DNA do dímero de MEF2C. Estudos de afinidade e de gel shift demonstraram que a porção FAT da FAK desloca a interação MEF2C/DNA in vitro. Ensaios de gene repórter demonstraram que a FAK, mediada pela região C-terminal, diminui a atividade transcricional de MEF2C em células C2C12. O conjunto de dados demonstra que a ativação do fator de transcrição MEF2C em MVRNs induz a desdiferenciação e ativação de mecanismos de progressão do ciclo celular e que a FAK impede esses efeitos através da interação inibitória no domínio de ligação de MEF2C ao DNA / Abstract: During the first days of postnatal development, cardiac myocytes lose their ability to proliferate, and the further growth of the heart is due to hypertrophy and not hyperplasia of cardiac myocytes. However, in response to stress, cardiac myocytes may have dedifferentiation and re-establishment of the cell cycle. The mechanisms involved in this phenomenon are still poorly understood. In the present study, we demonstrated that activation of the transcription factor MEF2C (myocyte enhancer factor 2-C) plays a critical role in the process of dedifferentiation of cardiac myocytes. This conclusion was obtained by gain-of-function experiments through overexpressing MEF2C in neonatal rat ventricular myocytes in culture (NRVMs). We also showed that overexpression of MEF2C in NRVMs induced the dedifferentiation and activation of mechanisms involved on cell cycle progression. These results were obtained by DNA microarray experiments, real time PCR, western blotting and cell phenotype analysis by light microscopy, confocal and electronic transmission. These effects were attenuated by overexpression of focal adhesion kinase (FAK) protein known to exert pro-hypertrophic effects on adult cardiac myocytes. In vivo and in vitro experiments demonstrated the direct interaction between the transcription factor MEF2C and FAK. A model based on crosslinking technology coupled with mass spectrometry, small angle X-ray scattering and the site directed mutation analyses indicated that alpha-helices 1 and 4 of FAK FAT domain interacts directly with the DNA binding domain of MEF2C dimer. Affinity studies and gel shift assay demonstrated that the FAK FAT domain displaces the MEF2C/DNA interaction in vitro. Reporter gene assays demonstrated that FAK, mediated by the C-terminal region, decreases the transcriptional activity of MEF2C in C2C12 cells. The data set shows that the activation of the transcription factor MEF2C in MVRNs induces dedifferentiation and activation of cell cycle progression and that FAK prevents these effects by inhibitory interaction with DNA binding domain of MEF2C / Doutorado / Biologia Estrutural, Celular, Molecular e do Desenvolvimento / Doutor em Ciências
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Dissecting Somatic Cell Reprogramming by MicroRNAs and Small Molecules: A DissertationLi, Zhonghan 12 March 2012 (has links)
Somatic cells could be reprogrammed into an ES-like state called induced pluripotent stem cells (iPSCs) by expression of four transcriptional factors: Oct4, Sox2, Klf4 and cMyc. iPSCs have full potentials to generate cells of all lineages and have become a valuable tool to understand human development and disease pathogenesis. However, reprogramming process suffers from extremely low efficiency and the molecular mechanism remains poorly understood.
This dissertation is focused on studying the role of small non-coding RNAs (microRNAs) and kinases during the reprogramming process in order to understand how it is regulated and why only a small percentage of cells could achieve fully reprogrammed state. We demonstrate that loss of microRNA biogenesis pathway abolished the potential of mouse embryonic fibroblasts (MEFs) to be reprogrammed and revealed that several clusters of mES-specific microRNAs were highly induced by four factors during early stage of reprogramming. Among them, miR-93 and 106b were further confirmed to enhance iPSC generation by promoting mesenchymal-to-epithelial transition (MET) and targeting key p53 and TGFβ pathway components: p21 and Tgfbr2, which are important barrier genes to the process.
To expand our view of microRNAs function during reprogramming, a systematic approach was used to analyze microRNA expression profile in iPSC-enriched early cell population. From a list of candiate microRNAs, miR-135b was found to be most highly induced and promoted reprogramming. Subsequent analysis revealed that it targeted an extracellular matrix network by directly modulating key regulator Wisp1. By regulating several downstream ECM genes including Tgfbi, Nov, Dkk2 and Igfbp5, Wisp1 coordinated IGF, TGFβ and Wnt signaling pathways, all of which were strongly involved in the reprogramming process. Therefore, we have identified a microRNA-regulated network that modulates somatic cell reprogramming, involving both intracellular and extracellular networks.
In addition to microRNAs, in order to identify new regulators and signaling pathways of reprogramming, we utilized small molecule kinase inhibitors. A collection of 244 kinase inhibitors were screened for both enhancers and inhibitors of the process. We identified that inhibition of several novel kinases including p38, IP3K and Aurora kinase could significantly enhance iPSC generation, the effects of which were also confirmed by RNAi of specific target genes. Further characterization revealed that inhibition of Aurora A kinase enhanced phosphorylation and inactivation of GSK3β, a process mediated by Akt kinase. All together, in this dissertation, we have identified novel role of both small non-coding RNAs and kinases in regulating the reprogramming of MEFs to iPSCs.
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