Global ETD Search

621	Interaction of P1 Plasmid Partition Components with the Bacterial Chromosome Yu, Analyn R. 29 July 2010 (has links) P1 is a low copy number plasmid that uses a dedicated partition system that actively ensures each daughter cell inherits a copy of the plasmid. P1 plasmid partition is a positioning reaction, ensuring that each plasmid copy is correctly localized to the one-quarter and three-quarter position or midcell in an E. coli cell prior to partition. The factors involved in this positioning process are not well understood. I utilized cell biology techniques and E. coli mukB mutants that produce cells with chromosomal condensation defects to study the role of the bacterial chromosome and P1 ParA as possible localization signals. P1 plasmid prefers to localize to the bacterial nucleoid even when the chromosome is perturbed. ParA is necessary for plasmid localization to the chromosome. In this study, live cell microscopy analysis of ParA indicates that an interaction between P1 ParA and the E. coli nucleoid may underlie the localization mechanism of the plasmid partition system. P1 plasmid partition system plasmid localization bacterial chromosome 0307 0410 0369
622	Interaction of P1 Plasmid Partition Components with the Bacterial Chromosome Yu, Analyn R. 29 July 2010 (has links) P1 is a low copy number plasmid that uses a dedicated partition system that actively ensures each daughter cell inherits a copy of the plasmid. P1 plasmid partition is a positioning reaction, ensuring that each plasmid copy is correctly localized to the one-quarter and three-quarter position or midcell in an E. coli cell prior to partition. The factors involved in this positioning process are not well understood. I utilized cell biology techniques and E. coli mukB mutants that produce cells with chromosomal condensation defects to study the role of the bacterial chromosome and P1 ParA as possible localization signals. P1 plasmid prefers to localize to the bacterial nucleoid even when the chromosome is perturbed. ParA is necessary for plasmid localization to the chromosome. In this study, live cell microscopy analysis of ParA indicates that an interaction between P1 ParA and the E. coli nucleoid may underlie the localization mechanism of the plasmid partition system. P1 plasmid partition system plasmid localization bacterial chromosome 0307 0410 0369
623	Deciphering the Role of Aft1p in Chromosome Stability Hamza, Akil 25 January 2012 (has links) The Saccharomyces cerevisiae iron-responsive transcription factor, Aft1p, has a well established role in regulating iron homeostasis through the transcriptional induction of iron-regulon genes. However, recent studies have implicated Aft1p in other cellular processes independent of iron-regulation such as chromosome stability. In addition, chromosome spreads and two-hybrid data suggest that Aft1p interacts with and co-localizes with kinetochore proteins, however the cellular implications of this have not been established. Here, we demonstrate that Aft1p associates with the kinetochore complex through Iml3p. Furthermore, we show that Aft1p, like Iml3p, is required for the increased association of cohesin with the pericentromere and that aft1Δ cells display sister chromatid cohesion defects in both mitosis and meiosis. Our work defines a new role for Aft1p in the sister chromatid cohesion pathway. Aft1 Iml3 kinetochore cohesion cohesin centromere chromosome stability Ctf19 Chl4 Scc1 mitosis meiosis Rec8 budding yeast
624	Inverted repeats as a source of eukaryotic genome instability Narayanan, Vidhya 08 July 2008 (has links) Chromosomal rearrangements play a major role in the evolution of eukaryotic genomes. Genomic aberrations are also a hallmark of many tumors and are associated with a number of hereditary diseases in humans. The presence of repetitive sequences that can adopt non-canonical DNA structures is one of the factors which can predispose chromosomal regions where they reside to instability. Palindromic sequences (inverted repeats with or without a unique sequence between them) that can adopt hairpin or cruciform structures are frequently found in regions that are prone for gross chromosomal rearrangements (GCRs) in somatic and germ cells in different organisms. Direct physical evidence was obtained that double-strand breaks (DSBs) occur at the location of long inverted repeats, a triggering event for the genomic instability. However, the mechanisms by which palindromic sequences lead to chromosomal fragility are largely unknown. The overall goal of this research is to elucidate the mechanisms of DSB and GCR generation by palindromic sequences in yeast, Saccharomyces cerevisiae. Chromosomal fragility Gene amplification Replication Palindromic sequences Genome instability Eukaryotic cells Chromosome abnormalities Mutation (Biology)
625	The Control of the Epigenome Lezcano, Magda January 2006 (has links) The genetic information required for the existence of a living cell of any kind is encoded in the sequence information scripted in the double helix DNA. A modern trend in biology struggles to come to grip with the amazing fact that there are so many different cell types in our body and that they are directed from the same genomic blueprint. It is clear, that the key to this feature is provided by epigenetic information that dictates how, where and when genes should be expressed. Epigenetic states “dress up” the genome by packaging it in chromatin conformations that differentially regulate accessibility for key nuclear factors and in coordination with differential localizations within the nucleus will dictate the ultimate task, expression. In the imprinted Igf2/H19 domain, this feature is determined by the interaction between the chromatin insulator protein CTCF and the unmethylated H19 imprinting control region. Here I show that CTCF interacts with many sites genome-wide and that these sites are generally protected from DNA methylation, suggesting that CTCF function has been recruited to manifest novel imprinted states during mammalian development. This thesis also describes the discovery of an epigenetically regulated network of intra and interchromosomal complexes, identified by the invented 4C method. Importantly, the disruption of CTCF binding sites at the H19 imprinting control region not only disconnects this network, but also leads to significant changes in expression patterns in the interacting partners. Interestingly, CTCF plays an important role in the regulation of the replication timing not only of the Igf2 gene, but also of all other sequences binding this factor potentially by a cell cycle-specific relocation of CTCF-DNA complexes to subnuclear compartments. Finally, I show that epigenetic marks signifying active or inactive states can be gained and lost, respectively, upon exposure to stress. As many genes belonging to the apoptotic pathway are upregulated we propose that stress-induced epigenetic lesions represent a surveillance system marking the affected cells for death to the benefit of the individual. This important observation opens our minds to the view of new intrinsic mechanisms that the cell has in order to maintain proper gene expression, and in the case of misleads there are several check points that direct the cell to towards important survival decisions. Biology Epigenetics chromosome interactions replication timing histone modifications epigenetic surveillance Biologi Biology Biologi
626	Consequences of mitotic loss of heterozygosity on genomic imprinting in mouse embryonic stem cells Elves, Rachel Leigh 11 1900 (has links) Epigenetic differences between maternally inherited and paternally inherited chromosomes, such as CpG methylation, render the maternal and paternal genome functionally inequivalent, a phenomenon called genomic imprinting. This functional inequivalence is exemplified with imprinted genes, whose expression is parent-of-origin specific. The dosage of imprinted gene expression is disrupted in cells with uniparental disomy (UPD), which is an unequal parental contribution to the genome. I have derived mouse embryonic stem (ES) cell sub-lines with maternal UPD (mUPD) for mouse chromosome 6 (MMU6) to characterize regulation and maintenance of imprinted gene expression. The main finding from this study is that maintenance of imprinting in mitotic UPD is extremely variable. Imprint maintenance was shown to vary from gene to gene, and to vary between ES cell lines depending on the mechanism of loss of heterozygosity (LOH) in that cell line. Certain genes analyzed, such as Peg10, Sgce, Peg1, and Mit1 showed abnormal expression in ES cell lines for which they were mUPD. These abnormal expression levels are similar to that observed in ES cells with meiotically-derived full genome mUPD (parthenogenetic ES cells). Imprinted CpG methylation at the Peg1 promoter was found to be abnormal in all sub-lines with mUPD for Peg1. Two cell sub-lines which incurred LOH through mitotic recombination showed hypermethylation of Peg1, consistent with the presence of two maternal alleles. Surprisingly, a cell sub-line which incurred LOH through full chromosome duplication/loss showed hypomethylation of Peg1. The levels of methylation observed in these sub-lines correlates with expression, as the first two sub-lines showed a near-consistent reduction of Peg1, while the latter showed Peg1 levels close to wild-type. Altogether these results suggest that certain imprinted genes, like Peg1 and Peg10, have stricter imprinting maintenance, and as a result show abnormal expression in UPD. This strict imprint maintenance is disrupted, however, in UPD incurred through full chromosome duplication/loss, possibly because of the trisomic intermediate stage which occurs in this mechanism. Genomic imprinting Loss of heterozygosity Embryonic stem cells Mouse chromosome 6 Peg1 Mest
627	The characterisation of human X-linked polymorphic markers and their use in disease gene localisation and identification / Andrew James Donnelly. Donnelly, Andrew James January 1997 (has links) Copies of author's previously published works inserted. / Bibliography: leaves 321-370. / xv, 370, [21] leaves : ill. (chiefly col.) ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / The aim of the project presented in this thesis is to isolate microsatellite markers and to construct a high resolution genetic map of the human X chromosome using these and pre-existing microsatellite markers. AC dinucleotide repeat markers are isolated from a bacteriophage library for application to the genetic localisations of X-linked disease genes, particularly those responsible for non-specific mental retardation (MRX). The genetic map is used to refine the location of the disease gene segregating in five families affected with X-linked mental retardation. / Thesis (Ph.D.)--University of Adelaide, Dept. of Genetics, 1997 Human gene mapping. Genetics Research. Fragile X syndrome. X chromosome Abnormalities. Mental retardation.
628	The human gene map near the fragile X / by Graeme Kemble Suthers Suthers, Graeme Kemble January 1990 (has links) Typescript (Photocopy) / Includes published papers co-authored by the author at the end of volume 2 / Bibliography: leaves 195-237 of vol. 1 / 2 v. : ill ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--Dept. of Paediatrics, Faculty of Medicine, University of Adelaide, 1991 616.85/88042 20 Fragile X syndrome. Human chromosome abnormalities. Linkage (Genetics) Mental retardation Genetic aspects.
629	Globin gene mapping in the marsupial, Dasyurus viverrinus / by Brandon John Wainwright Wainwright, Brandon John January 1984 (has links) Bibliography: 31 unnumbered leaves at end of vol / vii, 143 leaves, [50] leaves, [31] leaves of plates : ill ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Genetics, 1984 599.2087/322/0994 19 Dasyuridae Cytology. Dasyuridae Genetics. Chromosome mapping. Globin.
630	Genetic marker studies in humans / John Charles Mulley Mulley, John Charles January 1985 (has links) Offprints of several author's journal articles inserted / Includes bibliography / xx, 285 leaves : ill ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Paediatrics, 1985 575.12 19 Linkage (Genetics) Chromosome mapping. Protease inhibitors Genetic aspects. Medical genetics.

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