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Nanog Regulates Chromatin Organization in Mouse Stem CellsTang, Calvin Chun Man 28 November 2013 (has links)
Mouse embryonic stem cells (ESCs) are known to possess an “open” global chromatin architecture characterized by dispersed chromatin fibres throughout the nucleus. This is in contrast to differentiated cell types, where chromatin generally congregates into numerous compact domains. Core transcription factors in ESCs regulate many genes involved in maintaining pluripotency and previous research has hinted a connection between these factors and chromatin organization. My hypothesis is that Nanog, one of the core transcription factors, functions in maintaining an “open” chromatin organization in mouse ESCs. In this study, the chromatin organization in ESCs expressing varying levels of Nanog was examined at the sub-micron level through electron spectroscopic imaging. An inverse correlation was identified between Nanog expression level and the chromatin fibre density in constitutive heterochromatic regions. Furthermore, global chromatin in the more differentiated epiblast stem cells became less compact upon Nanog overexpression. Altogether, these findings support the idea that Nanog plays a role in maintaining dispersed chromatin in mouse ESCs.
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Nanog Regulates Chromatin Organization in Mouse Stem CellsTang, Calvin Chun Man 28 November 2013 (has links)
Mouse embryonic stem cells (ESCs) are known to possess an “open” global chromatin architecture characterized by dispersed chromatin fibres throughout the nucleus. This is in contrast to differentiated cell types, where chromatin generally congregates into numerous compact domains. Core transcription factors in ESCs regulate many genes involved in maintaining pluripotency and previous research has hinted a connection between these factors and chromatin organization. My hypothesis is that Nanog, one of the core transcription factors, functions in maintaining an “open” chromatin organization in mouse ESCs. In this study, the chromatin organization in ESCs expressing varying levels of Nanog was examined at the sub-micron level through electron spectroscopic imaging. An inverse correlation was identified between Nanog expression level and the chromatin fibre density in constitutive heterochromatic regions. Furthermore, global chromatin in the more differentiated epiblast stem cells became less compact upon Nanog overexpression. Altogether, these findings support the idea that Nanog plays a role in maintaining dispersed chromatin in mouse ESCs.
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Characterizing the Organization within Alternative Lengthening of Telomere Associated-promyelocytic Leukemia Nuclear BodiesLarsen, Andrew 07 January 2011 (has links)
In the absence of telomerase activity, a subset of cancerous and immortalized cells maintain telomere length by means of a poorly understood mechanism, termed alternative lengthening of telomeres (ALT). Many details of telomere maintenance in ALT positive cells remain unclear, but significant evidence implicates a homologous recombination mechanism. ALT specific nuclear structures, known as ALT-associated promyelocytic leukemia nuclear bodies (APBs), are thought to serve as the site of telomere extension. Using electron spectroscopic imaging we have demonstrated that APBs contain substantial amounts of nucleic acid sequestered within the bodies. In contrast, promyelocytic leukemia nuclear bodies in non-ALT cell lines contain no significant nucleic acid. We show that the nucleic acid found in APBs is not RNA and provide evidence that it is in fact telomeric repeat DNA. This evidence supports a role for APBs to sequester extrachromosomal telomeric DNA in order to suppress the activation of DNA repair.
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Characterizing the Organization within Alternative Lengthening of Telomere Associated-promyelocytic Leukemia Nuclear BodiesLarsen, Andrew 07 January 2011 (has links)
In the absence of telomerase activity, a subset of cancerous and immortalized cells maintain telomere length by means of a poorly understood mechanism, termed alternative lengthening of telomeres (ALT). Many details of telomere maintenance in ALT positive cells remain unclear, but significant evidence implicates a homologous recombination mechanism. ALT specific nuclear structures, known as ALT-associated promyelocytic leukemia nuclear bodies (APBs), are thought to serve as the site of telomere extension. Using electron spectroscopic imaging we have demonstrated that APBs contain substantial amounts of nucleic acid sequestered within the bodies. In contrast, promyelocytic leukemia nuclear bodies in non-ALT cell lines contain no significant nucleic acid. We show that the nucleic acid found in APBs is not RNA and provide evidence that it is in fact telomeric repeat DNA. This evidence supports a role for APBs to sequester extrachromosomal telomeric DNA in order to suppress the activation of DNA repair.
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Atomic Force Microscopic, Electron Spectroscopic Imaging and Molecular Simulation Investigations of the Assembly and Structures of Collagen ConstructsSu, Ning 13 August 2013 (has links)
Collagen is one of the major protein constituents in mammals and is present in all tissues and organs with the exceptions of keratin tissues such as hair and nails. Collagen monomers self-aggregate into a number of structures. In order to understand the physical bases for the structural polymorphism observed in collagen, a good starting point is one of the simplest collagen aggregates, segmental long spacing (SLS) collagen. Although SLS collagen formation induced by the presence of adenosine 5’-triphosphate is widely known, effects of other triphosphates, on the other hand, are much less studied. By varying the pH, it is discovered that all the nucleoside 5’-triphophsates, as well as inorganic triphosphate, are able to induce SLS formation over certain pH ranges. Adenosine 5’-diphosphate and para-nitrophenylphosphate cannot induce SLS formation at any pH. Based on the pH ranges at which SLS collagen can be formed, it is concluded the triphosphate functionality, with one negative charge per phosphate group, is primarily responsible for the formation of SLS collagen. Since inorganic triphosphate is able to induce SLS collagen formation, the presence of the nucleoside is optional for the assembly process; however if present, the assembly process prefers the nucleosides carrying acidic protons. Using electron spectroscopic imaging (ESI) technique, it is found phosphorus, present only in nucleotides but not in polypeptides, is localized in certain regions of SLS collagen, forming a unique banding pattern transverse the long axis of the SLS collagen. Nitrogen mapping indicates the localization of phosphorus is not due to accumulation of materials. The phosphorus banding pattern demonstrates an excellent consistency across SLS collagen assembled from both bovine and recombinant human collagen monomers. Results from molecular simulation are consistent with the experimental results. All threephosphate groups seem to be involved in the assembly process to some degree. In the last chapter of the thesis, a reliable protocol to synthesis native type collagen fibers is introduced.
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Atomic Force Microscopic, Electron Spectroscopic Imaging and Molecular Simulation Investigations of the Assembly and Structures of Collagen ConstructsSu, Ning 13 August 2013 (has links)
Collagen is one of the major protein constituents in mammals and is present in all tissues and organs with the exceptions of keratin tissues such as hair and nails. Collagen monomers self-aggregate into a number of structures. In order to understand the physical bases for the structural polymorphism observed in collagen, a good starting point is one of the simplest collagen aggregates, segmental long spacing (SLS) collagen. Although SLS collagen formation induced by the presence of adenosine 5’-triphosphate is widely known, effects of other triphosphates, on the other hand, are much less studied. By varying the pH, it is discovered that all the nucleoside 5’-triphophsates, as well as inorganic triphosphate, are able to induce SLS formation over certain pH ranges. Adenosine 5’-diphosphate and para-nitrophenylphosphate cannot induce SLS formation at any pH. Based on the pH ranges at which SLS collagen can be formed, it is concluded the triphosphate functionality, with one negative charge per phosphate group, is primarily responsible for the formation of SLS collagen. Since inorganic triphosphate is able to induce SLS collagen formation, the presence of the nucleoside is optional for the assembly process; however if present, the assembly process prefers the nucleosides carrying acidic protons. Using electron spectroscopic imaging (ESI) technique, it is found phosphorus, present only in nucleotides but not in polypeptides, is localized in certain regions of SLS collagen, forming a unique banding pattern transverse the long axis of the SLS collagen. Nitrogen mapping indicates the localization of phosphorus is not due to accumulation of materials. The phosphorus banding pattern demonstrates an excellent consistency across SLS collagen assembled from both bovine and recombinant human collagen monomers. Results from molecular simulation are consistent with the experimental results. All threephosphate groups seem to be involved in the assembly process to some degree. In the last chapter of the thesis, a reliable protocol to synthesis native type collagen fibers is introduced.
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