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DNA topological stress during DNA replication in Saccharomyces cerevisiaeMinchell, Nicola E. January 2019 (has links)
DNA topological stress impedes normal DNA replication. If topological stress is allowed to build up in front of the replication fork, the fork rotates to overcome the stress, leading to formation of DNA pre-catenanes. The formation of DNA pre-catenanes is therefore a marker of DNA topological stress. In this study, I have examined how transcription linked DNA topological stress impacts on fork rotation and on endogenous DNA damage. Transcription, similar to replication, affects the topology of the DNA; and collision between the two machineries is likely to lead to high levels of DNA topological stress. I found that the frequency of fork rotation during DNA replication, increases with the number of genes present on a plasmid. Interestingly, I also found that this increase in pre-catenation is dependent on the cohesin complex. Cohesin and transcription are known to be linked, as transcription leads to the translocation of cohesin along budding yeast DNA away from its loading sites. Cohesin plays a major role in establishing chromosomal structure, influencing gene expression and genetic inheritance. In this work, I have analysed the relationship between cohesin and the generation of topological stress and found that topological stress associated with cohesin can lead to DNA replication stress and DNA damage.
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Discovering inhibitors of human Bloom syndrome protein (BLM)Chen, Xiangrong January 2019 (has links)
No description available.
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Metabolic dysfunction and impairments in the DNA Damage Response : dissecting a pathomechanistic link between Microcephalic Primordial Dwarfisms and cancer cachexiaMacpherson, Annie January 2017 (has links)
No description available.
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High-throughput assessment of small open reading frame translation in Drosophila melanogasterMumtaz, Muhammad Ali Shahzad January 2016 (has links)
Hundreds of thousands of putative small ORFs (smORFs) sequences are present in eukaryotic genomes, potentially coding for peptides less than 100 amino acids. smORFs have been deemed non-coding on the basis of their high numbers and their small size that makes it extremely challenging to assess their functionality both bioinformatically and biochemically. The recently developed Ribo-Seq technique, which is the deep sequencing of ribosome footprints, has generated significant controversy by showing extensive translation of smORFs outside of annotated protein coding regions, including putative non-coding RNAs.. Our lab adapted the Ribo-Seq technique by combining it with the polysome fractionation in order to assess smORF translation in Drosophila S2 cells. This thesis provides a high-throughput assessment of smORF translation in Drosophila melanogaster by firstly implementing complementary techniques such as transfection-tagging and Mass spectrometry methods in order to provide an independent corroboration of the S2 cell data (Chapter 3). Secondly, the in order to expand the catalogue of smORFs that are translated, I significantly improve upon the yield and sequencing efficiency of the Poly-Ribo-Seq protocol while adapting it to Drosophila embryos and then implementing it across embryogenesis divided in to Early, Mid and Late stages (Chapter 4). Currently, there is still a lot of debate in the field with regards to Ribo-Seq data analysis, and various computational metrics have been developed aimed at discerning 'real' translation events to background noise. Chapter 5 explores some of the metrics developed and establishes a translation cut-off suitable for designating small ORFs as translated. Altogether, the improvements introduced to the protocol and my data analysis shows the translation of 500 annotated smORFs, 500 smORFs in long non-coding RNAs and 5,000 uORFs, of which only one-third of each type of smORF has previous evidence of translation. These findings strengthen the establishment of smORFs as a distinct class of genes that significantly expand the protein coding complement of the genome.
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Characterisation of the avian TopBP1 protein and its functionsSkouteri, Meliti January 2017 (has links)
One of the proteins that lie at the heart of the DNA Damage Response (DDR) is Topoisomerase II-binding protein I (TopBP1). TopBP1 was initially identified and has been extensively studied in the yeast model organisms. However, the lack of readily available tools, including genetically defined mutant cell lines, has rendered the characterisation of TopBP1 in higher eukaryotes more challenging. Sequence information obtained from the characterisation of the gallus gallus TopBP1 mRNA revealed a different splicing pattern at the 5'end to the one reported in the Genome Browser. Our assembled TopBP1 mRNA sequence containing a novel open reading frame (ORF) enabled the creation of a conditional knockout cell line of TopBP1 in DT40, which has been impossible with the use of the annotated cDNA sequence. Thus the avian TopBP1 ORF identified herein contained the necessary function(s) to sustain viability of DT40 cells in the absence of the endogenous protein. Additionally, the establishment of an isogenic set of stable cell lines from the chicken B cell line DT40 by targeted deletion of the TopBP1 alleles revealed a gene dosage-dependent reduction of the TopBP1 protein levels and functions. This work establishes a novel gene-dosage system that can be used for the knock in of point mutations within the endogenous TopBP1 locus. Using this system, a novel characterisation of knock-in point mutants of the ATR Activation Domain (AAD) of TopBP1 was carried out, providing in vivo evidence of its DDR function(s). Finally, a stably integrated overexpression system (SIOS) capable of producing increased amounts of a protein of interest has been established in DT40 cells. SIOS represents an easy to use versatile system for various experimental purposes in the field of DT40. The work presented in this thesis represents a novel characterisation of the avian TopBP1 mRNA and the TopBP1 protein and its functions. This is crucial to gain insight into the mechanistics of the DDR network and the genetic instability characterising cancer development.
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Transcription regulation : models for combinatorial regulation and functional specificityThomas, David John January 2014 (has links)
Gene regulation id controlled by transcription factor proteins that bind to specific DNA sequences, known as transcription factor binding sites (TFBSs). Combinations of transcription factors working, co-operatively in cis-regulatory modules (CRMs), play a role in regulating gene expression. Current computational methods for TFBS prediction cannot distinguish between functional and non-functional sites, and predict very large numbers of false positives. The thesis focuses on the development of a novel computational model, based on artificial neural networks (ANNs), for the identification of functional TFBSs, and the CRMs within which they operate in the human genome. Datasets of 12,239 experimentally verified true positive (TP) TFBSs and 130,199 false positive (FP) TFBSs were extracted using a combination of position weight matrices from the JASPAR database and experimentally verified sites from the Encyclopedia of DNA elements (ENCODE). A number of machine learning alsgorithms were tested using a range of genetic information including gene expression, necleosome positioning, DNA methylation states and DNA entropy. The best model, that gave a mean area under the curve under a receiver operator characteristic curve of 0.800, was based on a feedforward ANN using backpropagation. This model was then used to predict functional TFBSs in a number of gene sets from the human genome. The predictions, combined with experimentally proven TFBSs from ENCODE, were used to investigate combinatorial patterns of TFBSs operating in CRMs. CRM patterns have been analysed in disease-associated genes located in linkage disequilibrium blocks containing SNPs obtained from Genome Wide Association Studies (GWAS). The potential for the model to make functional TFBS predictions to aid in the annotation of orphan genes of unknown function is discussed. In addition this thesis presents computational work on a number of smaller published studies.
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Investigations into the spatial distribution of γH2AX around a DNA double-strand break and the analysis of double-strand break mobilityOlukoga, Tomisin January 2018 (has links)
A hallmark of the cellular response to DNA double-strand breaks (DSBs) is histone H2AX phosphorylation by the protein kinase ATM. H2AX is unevenly distributed throughout chromatin and is rapidly phosphorylated to form γH2AX up to 2 megabases either side of DSBs. Studies in yeast systems have shown that while γH2A can spread in cis surrounding the break site, it can also spread in trans onto unbroken chromosomes located in close spatial proximity. Although the majority of data in the current literature presents the well characterised in cis spread of γH2AX, there are strong indications that it can also occur in trans in mammalian systems; analogous to the findings shown in yeast. This thesis lays out the steps taken to develop a novel system to address the spatial distribution of γH2AX around a nascent DSB. Since the first published live imaging experiments of the dynamics of chromatin by in vivo single particle tracking there has been extensive investigation into the regulation and biological function of movement of damaged DNA. In yeast, a relative consensus exists that DSB induction increases the movement of a DSB. In contrast to yeast however, data published of DSB movement in higher eukaryotes has been controversial, caused by conflicting results. Here, I developed a cell-based system, and utilised timelapse live cell imaging to show that a chromosomal locus containing a single endonuclease-induced DSB shows confined movement in comparison to an undamaged locus. Furthermore, this confined movement of a damaged locus is compounded by treatment with an ATM kinase inhibitor but not a DNA-PKcs kinase inhibitor, suggesting that the kinase activity of ATM and not the kinase activity of DNA-PKcs plays a significant role in the dynamics of DSBs.
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Investigating the role of the ATR-dependent DNA damage response in the aetiology of microcephalic primordial dwarfism disordersWalker, Sarah A. January 2012 (has links)
Repair of damage to the DNA is essential for the maintenance of genomic stability, both during embryonic development and normal growth. The cell has therefore evolved a complex array of interconnected pathways to ensure the appropriate response to DNA damage is initiated, such as cell cycle checkpoint arrest, activation of DNA repair pathways or induction of apoptotic processes. These co-ordinated signal transduction pathways have been termed the DNA damage response (DDR). A previous study showed that ATR-dependent damage responses were frequently defective in cell lines from patients with Microcephalic Primordial Dwarfism (MPD) disorders. In this thesis I have further characterised ATR–dependent damage response signalling in several cell lines from patients with various MPD disorders. I have shown that novel mutations in PCNT, which encodes a structural centrosomal protein, result in an MPD disorder and have characterised the associated ATRdependent DNA damage responses. I also contributed to the identification of mutations in ORC1, encoding a component of the DNA replication Origin Recognition Complex, in further MPD patients and examined origin licensing and Sphase progression in the patient derived cell lines. As a novel finding, I observed defects in the ATR-dependent G2/M checkpoint response in these cells. Additionally, I have characterised novel mutations in ATRIP, a gene encoding the obligate partner of ATR, in Seckel Syndrome patients, denoting a novel genetic defect in this condition. Finally, I have explored the role of PLK1 and AurA kinase in ATRdependent G2/M checkpoint control and provided compelling evidence of misregulation of this pathway in various MPD-patient derived cell lines. Collectively these data provide important functional insights into the genetic defects that cause MPD disorders and further explore the link between defective ATR-dependent damage response signalling and microcephaly.
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Analysis of the Ies6 subunit of the INO80 chromatin remodelling complexPhelps, Sarah January 2016 (has links)
The INO80 complex is a large ATPase chromatin remodeller which contains 15 accessory subunits in S.cerevisiae. Its subunits include the highly conserved ATPases Ruvb1 and Ruvb2, the actin-related proteins Arp5, Arp8, Act1 and Arp4, Actin, and a number of IES (I̱noE̱ighty S̱pecific) subunits Ies1, Ies2, Ies3, Ies4, Ies5 and Ies6, in addition to subunits Nhp10 and Taf14. All 15 of the accessory subunits are assembled around a catalytic core component known as Ino80. The INO80 complex has roles in transcription, DNA repair, replication, and chromosome segregation. These roles are in addition to its traditional nucleosome remodelling activities and the dispacement of H2A.Z from chromatin. Recent studies in S. cerevisiae have identified the subunit Ies6 as a critical component of the INO80 complex. Deletion of IES6, which encodes the small accessory subunit, clearly mimics the deletion f the gene encoding the catalytic subunit, INO80. Surprisingly, only one domain within Ies6 has been formally identified based on sequence analysis. This domain belongs to the L1_C class of domains. Such domains are commonly associated with DNA binding activity and transcription factors. This stud has further characterised the Ies6 subunit both genetically and biochemically. Genetically, it has demonstrated that single point mutations at regions of proposed subunit-subunit interaction between the Arp5 or Rvb2 subunits, or within the YL1_C are not sufficient to disrupt Ies6 function. However, expression of a double point mutation, ies6(K114E/Y125A), in combination with rad50 deletion, caused a sensitivity to replication inhibition, but not chromosome segregation inhibition, indicating a potential separation of function in this utant due to the loss due of only one of the biological functions of Ies6. Biochemically, we have confirmed that DBA binding capacity of Ies6 resides within the YL_C domain. In addition, although it has been demonstrated that the removal of H2A.Z acetylation exacerbates the increase in cellular ploidy observed in ies6 null cells, we found that overall levels of H2A.Z acetylation were not influenced by the loss of Ies6. This indicates that the role of H2A.Z acetylation in chromosome segregation may only affect ploidy status upon the loss of Ies6. In addition, work on the R2TP complex (which contains the INO80 APases Ruvb1/Ruvb2, and subunits Tah1 and Phi1) has revealed the recruitment mechanism for the molecular chaperone, Hsp90, and the telomere length regulation protein, Tel2. Together, the R2TP complex, Hsp90 and Tel2 promote the stabilisation and maturation of multi-protein complexes. These include Phosphatidylinositol 3-kinase-related kinases (PIKKs, a family of kinases involved i Serine and Threonine phosphorylation), subunits of the INO80 complex and subunits of the SWR1 chromatin remodelling complex (a partner comlex to INO80 that incorporates H2A.Z into chromatin).
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Dissecting the genotype to phenotype relationships of genomic disordersHart, Lesley Ruth January 2013 (has links)
Over the last decade, major advances in the development and application of microarray-based comparative genomic hybridisation (aCGH) technology have significantly contributed to our understanding of Genomic Disorders. My aims here were to provide insight into the genotype to phenotype relationships of three Genomic Disorders; CUL4B-deleted X-Linked Mental Retardation (XLMR), Wolf-Hirschhorn Syndrome (WHS) and 16p11.2 Copy Number Variant Disorder. CUL4B encodes a structural component of the Cullin-RING-ligase 4-containing class of E3 ubiquitin ligases. CUL4B-deleted XLMR represents a syndromal form of mental retardation whereby patients exhibit other clinical features aside from the MR, such as seizures, growth retardation and disrupted sexual development. I used CUL4B-deleted patient-derived cell lines to investigate the impacts of CUL4B loss on mitochondrial function. I have shown that loss of CUL4B is associated with a distinct set of mitochondrial phenotypes, identifying CUL4B-deleted XLMR as a disorder associated with mitochondrial dysfunction. Furthermore, I have uncovered a reciprocal relationship between CUL4B and Cereblon, providing evidence of a potential role for the CUL4-CRBN E3 ligase complex in maintaining mitochondrial function. Deletion or duplication of the 16p11.2 region is associated with macro-/microcephaly respectively. Here, I have evaluated the cellular consequences of 16p11.2 CNV, specifically with regards KCTD13 expression, DNA replication and checkpoint activation. WHS is typically caused by a small hemizygous telomeric deletion of the 4p16.1 region. Haploinsufficiency of 4p16.1 is associated with microcephaly, growth retardation and complex developmental abnormalities. I investigated the impacts of LETM1 copy number change in WHS patient-derived cells. Here, I have shown that copy number change of LETM1 specifically segregates with mitochondrial dysfunction, likely underlying the seizure phenotype exhibited by the large subgroup of WHS patients whose deletions incorporate LETM1 as well as the rarer instances of the reciprocal duplication. In this thesis I use patient-derived cell lines from three Genomic Disorders as a fundamental tool providing new pathomechanistic insight into the clinical presentation of these conditions.
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