Global ETD Search

11	The molecular basis of the genetic mosaicism in hereditary tyrosinemia (HT1) / Etresia van Dyk Van Dyk, Etresia January 2011 (has links) Hereditary tyrosinemia type 1 (HT1) is an autosomal recessive disorder of the tyrosine degradation pathway. The defective fumarylacetoacetate hydrolase enzyme causes the accumulation of upstream metabolites such as fumarylacetoacetate (FAA), maleylacetoacetate (MAA), succinylacetone (SA) and p-hydroxyphenylpyruvic acid (pHPPA). In vitro and in vivo studies showed that the accumulation of these metabolites are detrimental to cell homeostasis, by inducing cell cycle arrest, apoptosis, and endoplasmic reticulum stress, depleting GSH, inhibiting DNA ligase, causing chromosomal instability, etc. For in vivo studies different models of HT1 were developed. Most notably was the fah deficient mouse, whose neonatally lethal phenotype is rescued by the administration of 2-(2-nitro-4-trifluoromethylbenzoyl)-1,3-cyclohexanedione (NTBC). Although, this model most closely resembles the human phenotype with elevated tyrosine levels and the development of hepatocellular carcinoma (HCC), the model is not human genome based. Both the in vitro and in vivo studies suggested that DNA repair is affected in HT1. However, it is not yet clear which DNA repair mechanisms are affected and if only protein functionality is affected, or if expression of DNA repair proteins are also affected. Characteristic of HT1 is the high prevalence of HCC and the presence of liver mosaicism. The liver mosaicism observed in HT1 patients are the result of reversion of the inherited mutation to wild-type. The general consensus is that the reversion is the result of a true back mutation. However, the mechanism underlying the back mutation is still unresolved. It was suggested that cancer develops either through a chromosomal instability mutator phenotype, a microsatellite instability mutator phenotype, or a point mutation instability mutator phenotype. In HT1 only chromosomal instability was reported. The aims of this study were to contribute to the understanding of the molecular basis of the genetic mosaicism in hereditary tyrosinemia type 1. More specifically, determine whether baseand nucleotide DNA repair mechanisms are affected and to what extent, and to determine if microsatellite instability is found in HT1. To achieve these aims, a parallel approach was followed: i.e. to develop a HT1 hepatic cell model and to use HT1 related models and HT1 patient material. To assess the molecular basis of the genetic mosaicism in HT1, the comet assay, gene expression assays, microsatellite instability assays, high resolution melting and dideoxy sequencing techniques were employed. Results from the comet assay showed that the HT1 accumulating metabolites, SA and pHPPA, decreased the capacity of cells for base- and nucleotide excision repair. Gene expression assays showed that short term exposure to SA and/or pHPPA do not affect expression of hOGG1 or ERCC1. The expression of these genes were, however, low in HT1 patient samples. Microsatellite instability assays showed allelic imbalance on chromosome 7 of the mouse genome, and microsatellite instability in the lymphocytes of HT1 patients. Although high resolution melt and sequencing results did not reveal any de novo mutations in fah or hprt1, the appearance of de novo mutations on other parts of the genome can not be ruled out. To conclude, results presented in this thesis, for the first time show that in HT1 the initiating proteins of the base- and nucleotide repair mechanisms are affected, the gene expression of DNA repair proteins are low, and microsatellite instability is found in HT1. By contributing to the elucidation of the mechanism underlying the development of HT1-associated HCC, and providing evidence for the development of a mutator phenotype, the results presented in this thesis contributes to the understanding of the molecular mechanisms underlying the genetic mosaicism in HT1. In addition to these contributions, a hypothesis is posited, which suggests that a point mutation instability (PIN) mutator phenotype is the mechanism underlying the mutation reversions seen in HT1. / Thesis (Ph.D. (Biochemistry))--North-West University, Potchefstroom Campus, 2012 Hereditary tyrosinemia type1 Mosaicism Hepatocellular carcinoma DNA repair Genome instability Mutator phenotype
12	Cell Cycle Delay Stabilizes the Budding Yeast Genome Vinton, Peter J., Vinton, Peter J. January 2016 (has links) When damaged DNA is detected during replication, a checkpoint delays the cell cycle to allow time for repair. Here I show that continually delaying the cell cycle in the G2/M phase of the cell cycle stabilizes the genome of Saccharomyces cerevisiae in both checkpoint proficient and deficient cells; a phenomenon I call slow cycle stabilization (SCS). SCS stabilizes the genome in cells defective for DNA damage response (DDR), spindle checkpoint, and telomere biology, as well as wild type (WT) cells. I verify SCS using genetic and chemical means and further substantiate SCS using three different Saccharomyces cerevisiae chromosome systems. ER erv14 genome instability genome stability slow cell cycle cell cycle delay
13	Functional characterization of the DNA glycosylase, methyl-CpG binding domain protein 4 (MBD4) Meng, Huan January 2013 (has links) DNA methylation is a major form of epigenetic modification and involves the addition of a methyl group covalently to the 5-position of the cytosine pyrimidine ring, mostly within the context of CpG dinucleotides in vertebrate somatic cells. Methylation of CpG dinucleotides at promoter regions is generally associated with transcriptional repression. In this context, the methyl-CpG binding proteins (MeCPs) that are capable of recognition of methylated CpG dinucleotides are proposed to play a central role in DNA methylation associated transcriptional repression. Methyl-CpG binding domain protein 4 (MBD4) is an MeCP that possesses a glycosylase domain at its C-terminal, which can excise and repair both G:T and G:U mutations derived from DNA deamination at CpG dinucleotides, in addition to its Nterminal MBD binding domain. MBD4 has been associated with a number of pathways including DNA repair, apoptosis, transcriptional repression, and possibly DNA demethylation processes. However, the precise contribution of MBD4 to these processes remains unclear. To explore the functional repertoire of MBD4 I decided to undertake multiple protein interaction studies to identify potential partner proteins. I performed yeast 2-hybrid screens with an 11.5 day mouse embryonic cDNA library and multiple mass spectrometry of immunoprecipitates of tagged versions of MBD4 that were over-expressed in human cell lines. I detected ~380 potential interacting candidates with these assays. A significant number of candidates were detected in both assay systems. Chosen candidates were further validated by reciprocal co-IP of expressed partners and by immunofluorescence (IF) microscopy to determine their potential co-localisation in mouse and human cell lines. Subsequently, I identified the intervening domain of MBD4 as a novel protein interaction region for tested candidates. My analysis suggests that MBD4 can have a role in regulation of post-replication methyl-error repair/methylation machinery through its direct interaction with DNMT1 (previously shown), UHRF1 (novel) and USP7 (novel), as well as possible cross-talk to histone modification and chromatin remodelling pathways, through partners such as PRMT5 and ACF1. Interestingly the transcription regulatory components KAP1 and CFP1 not only interact with but also dramatically influence the stability of exogenously expressed MBD4 in human cells. In general positive validation by IP and IF demonstrates the robustness of the initial screens, and implies that MBD4 may impact upon several transcriptional and epigenetic networks along with a number of nuclear pathways that include transcriptional repression, DNA repair and RNA processing. To test for transcriptional aberration in the absence of Mbd4 function I profiled two independent mouse cell lines that lack MBD4 activity using Illumina MouseWG-6 v2.0 Expression BeadChip arrays. A number of genes were identified that are significantly up- or down- regulated in both Mbd4-/- MEFs. This included mis-expression of insulin-like growth factor-binding proteins and two paternally imprinted genes Dio3 and H19. The cohort of genes that were mis-expressed in the Mbd4-/- MEFs overlap with genes that responsed to tamoxifen exposure in an ER-positive ZR-75-1 xenograft model. In response to this observation I identified a potential interaction between MBD4 and estrogen receptor α (ERα) by co-IP and IF co-localisation. This suggests that MBD4 might potentiate transcription of estrogen regulated genes via a direct interaction with ERα, supporting a possible link between replication repair remodelling and steroid/thyroid hormone receptor transcriptional regulation. Additionally I performed a pathway analysis by which several developmental genes including Sox9, Klf2 and Klf4, were prioritised as possible MBD4 targets. On this basis I propose a role for MBD4 in acquired diseases such as cancers and autoimmune diseases via transcriptional regulation. I also performed a comparison of MBD4 DNA binding activity with MBD4 homologues from the Medaka fish (Oryzias latipes) and the amphibian, Xenopus laevis. I could show that DNA binding specificity to a series of methylated and mismatched probes is conserved regardless of the poor sequence conservation of the MBD domain of MBD4 between the species. I conclude that MBD4 is integrated in multiple pathways in the nucleus that includes DNA repair, chromatin remodelling, transcriptional regulation and genome stability. 572.8
14	Investigating the recombinational response to replication fork barriers in fission yeast Jalan, Manisha January 2016 (has links) Timely completion of DNA replication in each cell cycle is crucial for maintaining genomic integrity. This is often challenged by the presence of various replication fork barriers (RFBs). On collision with a RFB, the fate of the replication fork remains uncertain. In some cases, the integrity of the fork is maintained until the barrier is removed or the fork is rescued by merging with the incoming fork. However, fork stalling can cause dissociation of all of the associated replication proteins (fork collapse). If this occurs, the cell's recombination machinery can intervene to help restart replication in a process called recombination-dependent replication (RDR). Programmed protein-DNA barriers like the Replication Terminator Sequence-1 (RTS1) have been used to demonstrate that replication fork blockage can induce recombination. However, it remains unclear how efficiently this recombination gives rise to replication restart and whether the restarted replication fork exhibits the same fidelity as an origin-derived fork. It is also unknown whether accidental replication barriers induce recombination in the same manner as programmed barriers. In this study, I introduce recombination reporters at various sites downstream of RTS1 to obtain information on both the fidelity and efficiency of replication restart. I find that unlike break induced replication (BIR), the restarted fork gives rise to hyper-recombination at least 75 kb downstream of the barrier. Surprisingly, fork convergence, rather than inducing recombination, acts to prevent or curtail genetic instability associated with RDR. I also investigate a number of genetic factors that have a role in either preventing or promoting genome instability associated with the progression of the restarted fork. To compare RTS1 with an accidental protein-DNA barrier, a novel site-specific barrier system (called MarBl) was established based on the human mariner transposase, Hsmar1, binding to its transposon end. Replication fork blockage at MarBl strongly induces recombination, more so than at RTS1. This appears to be a general feature of accidental barriers as introduction of the E. coli TusB-TerB site-specific barrier in S. pombe gives rise to a similar effect. Here, I compare and contrast accidental barriers with programmed barriers. I observe that there is very little replication restart, if any, at MarBl measured by direct repeat recombination downstream. This points to the fact that accidental barriers do not trigger fork collapse in the same way as programmed RFBs and that the increased recombination that they cause may be a consequence of the inability of replication forks to terminate correctly, owing to the bi-directional nature of the barrier. Several genetic factors are assessed for their impact on MarBl-induced recombination, which further highlights both similarities and differences with RTS1-induced recombination. 572
15	Genome instability induced by triplex forming mirror repeats in S.cerevisiae Kim, Hyun-Min 07 April 2009 (has links) The main goal of this research is to understand molecular mechanisms of GAA/TTC-associated genetic instability in a model eukaryotic organism, S. cerevisiae. We demonstrate that expanded GAA/TTC repeats represent a threat to eukaryotic genome integrity by triggering double-strand breaks and gross chromosomal rearrangements. The fragility potential strongly depends on the length of the tracts and orientation of the repeats relative to the replication origin and to block replication fork progression. MutSbeta complex and endonuclease activity of MutLalpha play an important role in facilitation of fragility. In addition to GAA/TTC triplex forming repeats, non-GAA polypurine polypyrimidine mirror repeats that are prone to the formation of similar structures were found to be hotspots for rearrangements in humans and other model organisms. These include H-DNA forming sequences located in the major breakpoint cluster region at BCL2, intron 21 of PKD1, and promoter region of C-MYC. Lastly, we have investigated the effect of the triplex-binding small molecules, azacyanines, on GAA-mediated fragility using the chromosomal arm loss assay. We have found that in vivo, azacyanines stimulate (GAA/TTC)-mediated arm loss in a dose dependent manner in actively dividing cells. Azacyanines treatment enhances the GAA-induced replication arrest. We discovered that also, azacyanines at concentrations that induce fragility also inhibit cell growth. Over 60% of yeast cells are arrested at G2/M stage of the cell cycle. This implies an activation of DNA-damage checkpoint response. Mismatch repair Anticancer Triplex TTC Trinucleotide repeat GAA Genome instability Chromosomes Chromosome abnormalities Eukaryotic cells Cells
16	Regulation and Targeting of the FANCD2 Activation in DNA Repair Caceres, Valentina Celeste 01 January 2015 (has links) Fanconi anemia (FA) is a genome instability syndrome that is clinically manifested by bone marrow failure, congenital defects, and elevated cancer susceptibility. The FA pathway is known to regulate the repair of DNA interstrand crosslinks in part through DNA homologous recombination (HR) repair. Up to today 16 FA proteins have been discovered that may participate in the common pathway. Cells that have mutations in the FA genes are hypersensitive to DNA damaging agents and display chromosome instability. A key regulatory event in the FA pathway is monoubiquitination of FANCD2-FANCI heterodimer that is mediated by a multi-component E3 ubiquitin ligase complex called FA core complex. Current model suggests that once the FANCD2-FANCI heterodimer is monoubiquitinated it relocates to chromatin where it interacts with other key repair proteins to facilitate DNA repair. More than 90% of the FA cases are presumed to be associated with defects in the monoubiquitination reaction, suggesting the significance of the modification in the pathogenesis of the disease. Despite the significance, the molecular interplay between the FA core complex and the FANCD2-FANCI heterodimer remains enigmatic. We are interested in the assembly mechanism of the various FA subcomplexes into the core complex, and we are actively investigating how the FANCD2-FANCI heterodimer is recruited to these putative subcomplexes. As the FA pathway is a crucial determinant for cellular resistance to DNA damaging agents, there have been hypotheses that disruption of this pathway may be beneficial in enhancing chemosensitivity of certain cancer cells. In collaboration with Dr. Cai’s chemistry lab, we will develop a screen platform to identify a small molecules to interrupt the monoubiquitination reaction. Completion of these studies will enhance the much-needed knowledge of the key enzymatic reaction in the pathway, and perhaps the information can be used for development of novel chemotherapeutic strategies. DNA repair fanconi anemia genome instability homologous recombination ubiquitin Biochemistry Cell Biology Molecular Biology
17	Formation of Dicentric and Acentric Chromosomes, by a Template Switch Mechanism, in Budding Yeast Paek, Andrew Luther January 2010 (has links) Chromosomal rearrangements occur in all organisms and are important both in the evolution of species and in pathology. In this dissertation I show that in Saccharomyces cerevisiae, or budding yeast, one type of chromosomal rearrangement occurs when inverted repeats fuse, likely during DNA replication by a novel mechanism termed "faulty template switching". This fusion can lead to the formation of either a dicentric or acentric chromosome, depending on the direction of the replication fork. Dicentric chromosomes are inherently unstable due to their abnormal number of centromeres, and thus undergo additional chromosomal rearrangements and chromosome loss. Acentric Chromosomes Budding Yeast Dicentric Chromosomes Genome Instability Inverted Repeats Template Switching
18	BIOCHEMICAL CHARACTERIZATION OF HUMAN MISMATCH RECOGNITION PROTEINS MUTSα AND MUTSβ Tian, Lei 01 January 2010 (has links) The integrity of an organism's genome depends on the fidelity of DNA replication and the efficiency of DNA repair. The DNA mismatch repair (MMR) system, which is highly conserved from prokaryotes to eukaryotes, plays an important role in maintaining genome stability by correcting base-base mismatches and insertion/deletion (ID) mispairs generated during DNA replication and other DNA transactions. Mismatch recognition is a critical step in MMR. Two mismatch recognition proteins, MutSα (MSH2-MSH6 heterodimer) and MutSβ (MSH2-MSH3 heterodimer), have been identified in eukaryotic cells. MutSα and MutSβ have partially overlapping functions, with MutSα recognizing primarily base-base mismatches and 1-2 nt ID mispairs and MutSβ recognizing 2-16-nt ID heteroduplexes. The goal of this dissertation research was to understand the mechanism underlying differential mismatch recognition by human MutSα and MutSβ and to characterize the unique functions of human MutSα and MutSβ in MMR. In this study, recombinant human MutSα and MutSβ were purified. Binding of the proteins to a T-G mispair and a 2-nt ID mispair was analyzed by gel-mobility assay; ATP/ADP binding was characterized using a UV cross-linking assay; ATPase activity was measured using an ATPase assay; MutSα amd MutSβ’s mismatch repair activity was evaluated using a reconstituted in vitro MMR assay. Our studies revealed that the preferential processing of base-base and ID heteroduplexes by MutSα and MutSβ respectively, is determined by the significant differences in the ATPase and ADP binding activities of MutSα and MutSβ, and the high ratio of MutSα:MutSβ in human cells. Our studies also demonstrated that MutSβ interacts similarly with a (CAG)n hairpin and a mismatch, and that excess MutSβ does not inhibit (CAG)n hairpin repair in vitro. These studies provide insight into the determinants of the differential DNA repair specificity of MutSα and MutSβ, the mechanism of mismatch repair initiation, and the mechanism of (CAG)n hairpin processing and repair, which plays a role in the etiology and progression of several human neurological diseases. Genome instability mismatch repair MutSα MutSβ Trinucleotide repeat Biochemistry Chemistry Medical Toxicology
19	The molecular basis of the genetic mosaicism in hereditary tyrosinemia (HT1) / Etresia van Dyk Van Dyk, Etresia January 2011 (has links) Hereditary tyrosinemia type 1 (HT1) is an autosomal recessive disorder of the tyrosine degradation pathway. The defective fumarylacetoacetate hydrolase enzyme causes the accumulation of upstream metabolites such as fumarylacetoacetate (FAA), maleylacetoacetate (MAA), succinylacetone (SA) and p-hydroxyphenylpyruvic acid (pHPPA). In vitro and in vivo studies showed that the accumulation of these metabolites are detrimental to cell homeostasis, by inducing cell cycle arrest, apoptosis, and endoplasmic reticulum stress, depleting GSH, inhibiting DNA ligase, causing chromosomal instability, etc. For in vivo studies different models of HT1 were developed. Most notably was the fah deficient mouse, whose neonatally lethal phenotype is rescued by the administration of 2-(2-nitro-4-trifluoromethylbenzoyl)-1,3-cyclohexanedione (NTBC). Although, this model most closely resembles the human phenotype with elevated tyrosine levels and the development of hepatocellular carcinoma (HCC), the model is not human genome based. Both the in vitro and in vivo studies suggested that DNA repair is affected in HT1. However, it is not yet clear which DNA repair mechanisms are affected and if only protein functionality is affected, or if expression of DNA repair proteins are also affected. Characteristic of HT1 is the high prevalence of HCC and the presence of liver mosaicism. The liver mosaicism observed in HT1 patients are the result of reversion of the inherited mutation to wild-type. The general consensus is that the reversion is the result of a true back mutation. However, the mechanism underlying the back mutation is still unresolved. It was suggested that cancer develops either through a chromosomal instability mutator phenotype, a microsatellite instability mutator phenotype, or a point mutation instability mutator phenotype. In HT1 only chromosomal instability was reported. The aims of this study were to contribute to the understanding of the molecular basis of the genetic mosaicism in hereditary tyrosinemia type 1. More specifically, determine whether baseand nucleotide DNA repair mechanisms are affected and to what extent, and to determine if microsatellite instability is found in HT1. To achieve these aims, a parallel approach was followed: i.e. to develop a HT1 hepatic cell model and to use HT1 related models and HT1 patient material. To assess the molecular basis of the genetic mosaicism in HT1, the comet assay, gene expression assays, microsatellite instability assays, high resolution melting and dideoxy sequencing techniques were employed. Results from the comet assay showed that the HT1 accumulating metabolites, SA and pHPPA, decreased the capacity of cells for base- and nucleotide excision repair. Gene expression assays showed that short term exposure to SA and/or pHPPA do not affect expression of hOGG1 or ERCC1. The expression of these genes were, however, low in HT1 patient samples. Microsatellite instability assays showed allelic imbalance on chromosome 7 of the mouse genome, and microsatellite instability in the lymphocytes of HT1 patients. Although high resolution melt and sequencing results did not reveal any de novo mutations in fah or hprt1, the appearance of de novo mutations on other parts of the genome can not be ruled out. To conclude, results presented in this thesis, for the first time show that in HT1 the initiating proteins of the base- and nucleotide repair mechanisms are affected, the gene expression of DNA repair proteins are low, and microsatellite instability is found in HT1. By contributing to the elucidation of the mechanism underlying the development of HT1-associated HCC, and providing evidence for the development of a mutator phenotype, the results presented in this thesis contributes to the understanding of the molecular mechanisms underlying the genetic mosaicism in HT1. In addition to these contributions, a hypothesis is posited, which suggests that a point mutation instability (PIN) mutator phenotype is the mechanism underlying the mutation reversions seen in HT1. / Thesis (Ph.D. (Biochemistry))--North-West University, Potchefstroom Campus, 2012 Hereditary tyrosinemia type1 Mosaicism Hepatocellular carcinoma DNA repair Genome instability Mutator phenotype
20	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)

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