Global ETD Search

1	Allele-Specific Gene Expression in the Laboratory Mouse Zwemer, Lillian January 2012 (has links) Traditionally, autosomal genes, when expressed, are assumed to express both alleles equally. Exceptions to this tenet include genes for which a specific genotypic polymorphism controls expression level, as well as genes for which monoallelic expression is epigenetically dictated. In this work, we discovered and characterized allele-specific gene expression in a variety of tissues using multiple techniques. We used cell lines and fresh tissue from reciprocal crosses of F1 heterozygous mice and the homozygous parental strains. We relied on a variety of high-throughput genomic techniques including RNA-Seq and DNA SNP-arrays to examine multiple types of allele-specific expression. We searched for novel examples of random autosomal monoallelic expression (RMAE) by using DNA SNP-arrays and cDNA from lymphoblast and fibroblast clonal cell lines of heterozygous mice. We found that of the approximately 1,350 autosomal genes we assessed, over 10% showed evidence of RMAE in at least one cell type. This allele-specific expression was stable over long periods in cell culture and encompassed a variety of gene types, some of which also exhibit RMAE in human clonal lines. Additionally, for a subset of RMAE genes, there seemed to be preferential inactivation of one allele; this monoallelic expression was still considered random, as from clone to clone the gene could be expressed either monoallelically or biallelically. In a second set of experiments we developed an analysis pipeline to examine RNASeq data for allele-specific expression. Using a pilot data set, we assessed the murine liver for parent-of-origin monoallelic expression, examining both known and candidate novel imprinted genes. We observed imprinted monoallelic expression in the adult liver for some, but not all, imprinted genes that have been reported in studies of embryonic tissue. The results suggest that there are few, if any, novel imprinted genes to be discovered in the mouse liver. This pilot data set also allowed examination of the genetic basis of allele specific gene expression. In keeping with recent reports, we found evidence for genetically based allele-specific expression, ranging from mild to greater than 4-fold allelic imbalance. We examined the extent to which this allelic imbalance correlated with total expression levels in the parental strains. allele-specific epigenetic eQTL imprinting monoallelic sequencing genetics
2	Allele specific gene expression in the major histocompatibility complex Plant, Katharine January 2012 (has links) The Major Histocompatibility Complex (MHC) is a highly polymorphic region of the genome located on chromosome 6p21 in which genetic diversity has been associated with susceptibility to many autoimmune, infectious and other common diseases. Despite strong associations between disease and variation in the MHC that have been identified initially from serological testing and more recently by genome-wide association studies, functional insights into how specific variants may be altering disease susceptibility remain poorly understood in most cases. It is predicted that gene expression will play a significant role in the modulation of disease susceptibility and so further understanding of allele specific gene expression in the MHC will be necessary to help define the function of disease associated variants in this region. This thesis aimed to define allele specific gene expression in the MHC by characterising specific candidate genes together locus-wide approaches in order to try and resolve functional variants. Gene expression was analysed in both lymphoblastoid cell lines (LCLs) and primary human peripheral blood mononuclear cells (PBMCs). Data is presented validating a novel haplotype-specific MHC microarray and fine mapping putative local, likely cis-acting, regulatory variants. This was done by expression quantitative trait mapping for two cohorts of healthy volunteers. A transcription factor ZFP57, encoded in the MHC, was found to show significant differential allelic expression relating to specific single nucleotide polymorphisms (SNPs) and possession of HLA-type. This provided new insights into reported disease associations, notably HIV-1 infection and cancer. The function of ZFP57 was further investigated in terms of genome-wide DNA binding sites by ChIP-seq together with its binding co-factor KAP1. Allele-specific gene expression was also demonstrated for several classical HLA genes including the HLA-C and HLA-DQ genes, fine mapping specific putative regulatory variants. This provided new insights into disease association, notably variants of HLA-DQB1 and susceptibility to leprosy. The applicability and sensitivity of the technique of RNA sequencing (mRNA-seq) for allele-specific quantification of gene expression was investigated for different allelic ratios of RNA from LCLs homozygous for sequence across the MHC. Significant challenges were identified in successful application of this technique to MHC genes while high levels of accuracy were observed dependent on read depth in non-MHC genes. This thesis provides new insights into the extent and nature of allele-specific gene expression in the MHC, experimental approaches that can be used and insights gained into disease susceptibility for this important genomic region. 616.079
3	Syntheses and DNA Interactions of Acridine and Phenothiazine Based Photosensitizers Wilson, Beth 04 December 2006 (has links) Photosensitizing molecules and/or metal complexes that interact with DNA via intercalation and groove binding have potential applications as molecular structural probes, as footprinting reagents and in photodynamic therapeutics. To this regard, small molecules that bind to DNA and the energetics involved in these interactions, acridine-based therapeutics, photosensitization, photodynamic therapy, phenothiazine-mediated photosensitization, DNA photocleavage reaction mechanisms and photosensitizing metal complexes are introduced in Chapter I. Next, in Chapter II, the synthesis of a photonuclease consisting of a 3,6-acridinediamine chromophore attached to four metal-coordinating imidazole rings is described. The DNA photocleavage yields, emission quantum yields, and thermal denaturation studies by this acridine-imadazole conjugate in the presence of 16 metal salts are also reported. In Chapter III is the synthesis of a bisacridine covalently tethered to a copper(II)-binding pyridine linker. Additionally, DNA photocleavage studies as well as DNA binding affinity and binding mode(s) of this bisacridine incorporating the copper(II)-binding pyridine linker are examined. The syntheses, characterization, DNA photocleavage studies, DNA thermal denaturation, and viscometric measurements of three new phenothiazinium photosensitizers are described in Chapters IV and V. Collectively, markedly enhanced DNA photocleavage yields are observed in the presence of metals (Chapters II-III) or in comparison to a parent molecule, Chapters II and IV. DNA melting isotherms show higher levels of duplex stabilization with the acridines, specifically in the presence of several metals (Chapter II-III) as well as with the phenothiazine-based ligands (Chapters IV-V). Moreover, different DNA binding modes were observed depending on metal complexation (Chapter III) and nucleic acid structure (Chapter IV). Finally, Chapter VI describes a small project implemented as a National Science Foundation pedagogical laboratory exercise in which a non-invasive procedure for DNA isolation from human cheek cells was utilized with the polymerase chain reaction to amplify alleles encoding a single nucleotide polymorphism involved in normal human color vision. acridine DNA photosensitization metal-assisted photocleavage phenothiazine photodynamic therapy Chemistry
4	Gene Expression and DNA Methylation in Acute Lymphoblastic Leukemia Nordlund, Jessica January 2012 (has links) Pediatric acute lymphoblastic leukemia (ALL) is the most common malignancy in children, which results from the malignant transformation of progenitor cells in the bone marrow into leukemic cells. The precise mechanisms for this transformation are not well defined, however recent studies suggest that aberrant regulation of gene expression or DNA methylation may play an important role. Hence, the aim of this thesis was to use novel methods to investigate genome-wide gene expression and DNA methylation patterns in a large collection of primary ALL cells from pediatric patients. With these studies, we aimed to increase the understanding of factors that regulate gene expression and DNA methylation in ALL. In the first study of the thesis we found that data obtained from genome-wide digital gene expression analysis enabled excellent cytogenetic subtype-specific classification of ALL cells and revealed new features of gene expression within the disease, such as prevalent antisense transcription and alternative polyadenylation. In the second study we used technology developed for large-scale single nucleotide polymorphism (SNP) genotyping for quantitative analysis of allele-specific gene expression (ASE), revealing widespread ASE in ALL cells. Analysis of DNA methylation in promoter regions of the genes displaying ASE using DNA-microarrays revealed frequent regulation of gene expression by DNA methylation. In the third study, using the same DNA methylation array, we identified differences in the DNA methylation patterns in ALL cells at diagnosis compared to healthy mononuclear cells from the bone marrow of the same children at remission. In the fourth study we measured the DNA methylation of >450,000 CpG sites across the genome in a large collection of ALL samples and non-leukemic control cells. We found that ALL cells displayed highly divergent DNA methylation patterns depending on their cytogenetic subtype and widespread regions of differential methylation were enriched for repressive histone marks. DNA methylation levels at distinct regions in the genome were substantially increased at relapse compared to matched cells from diagnosis. Collectively, the results presented in this thesis provide new insights into the patterns of gene expression and epigenetic changes in ALL and further increase our understanding of the development and progression of the disease, which will hopefully lead to better treatment options in the future. Digital gene expression Allele-specific gene expression DNA methylation Epigenetics Acute lymphoblastic leukemia
5	Genome-wide Analysis of F1 Hybrids to Determine the Initiation of Epigenetic Silencing in Maize Yang, Diya 08 January 2021 (has links) No description available. Bioinformatics Biology Epigenetic silencing small RNAs RNA-directed DNA methylation maize F1 hybrid allele-specific loci
6	Transcriptome-Wide Study of Transcriptional Kinetics in Human Cells Jin, Bowen 26 May 2023 (has links) No description available. Bioinformatics Genetics single-cell RNA-seq transcriptional burst allele-specific expression eQTL transcription factor
7	Computational analysis of effects and interactions among human variants in complex diseases Valentini, Samuel 18 October 2022 (has links) In the last years, Genome-Wide Associations Studies (GWAS) found many variants associated with complex diseases. However, the biological and molecular links between these variants and phenotypes are still mostly unknown. Also, even if sample sizes are constantly increasing, the associated variants do not explain all the heritability estimated for many traits. Many hypotheses have been proposed to explain the problem: from variant-variant interactions, the effect of rare and ultra-rare coding variants and also technical biases related to sequencing or statistic on sexual chromosomes. In this thesis, we mainly explore the hypothesis of variant-variant interaction and, briefly, the rare coding variants hypothesis while also considering possible molecular effects like allele-specific expression and the effects of variants on protein interfaces. Some parts of the thesis are also devoted to explore the implementation of efficient computational tools to explore these effects and to perform scalable genotyping of germline single nucleotide polymorphisms (SNPs) in huge datasets. The main part of the thesis regards the development of a new resource to identify putative variant-variant interactions. In particular, we integrated ChIP-seq data from ENCODE, transcription factor binding motifs from several resources and genotype and transcript level data from GTeX and TCGA. This new dataset allows us to formalize new models, to make hypothesis and to find putative novel associations and interactions between (mainly non-coding) germline variants and phenotypes, like cancer-specific phenotypes. In particular, we focused on the characterization of breast cancer and Alzheimer’s Disease GWAS risk variants, looking for putative variants’ interactions. Recently, the study of rare variants has become feasible thanks to the biobanks that made available genotypes and clinical data of thousands of patients. We characterize and explore the possible effects of rare coding inherited polymorphisms on protein interfaces in the UKBioBank trying to understand if the change in structure of protein can be one of the causes of complex diseases. Another part of the thesis explores variants as causal molecular effect for allele-specific expression. In particular, we describe UTRs variants that can alter the post-transcriptional regulation in mRNA leading to a phenomenon where an allele is more expressed than the other. Finally, we show those variants can have prognostic significance in breast cancer. This thesis work introduces results and computational tools that can be useful to a broad community of researcher studying human polymorphisms effects. Settore BIO/11 - Biologia Molecolare
8	METHODS AND ANALYSES IN THE STUDY OF HUMAN DNA METHYLATION Hu, Ke 01 June 2018 (has links) No description available. Genetics Bioinformatics Computer Science
9	Cis-acting Genetic Variants that Alter ERCC5 Regulation as a Prototype to Characterize cis-regulation of Key Protective Genes in Normal Bronchial Epithelial Cells Zhang, Xiaolu January 2016 (has links) No description available. Genetics Medicine Molecular Biology lung cancer risk DNA polymorphism ERCC5 allele-specific expression
10	Parâmetros populacionais e forenses de polimorfismos indel e detecção alelo-específica / Population and forensic parameters of indel polymorphysms and allelespecific detection Rodrigues, Maria Luisa de Barros 13 July 2018 (has links) Polimorfismos do tipo indel são os mais abundantes depois dos SNPs, representando 3,6 milhões das variantes caracterizadas pelo projeto 1000 Genomes. Com uma distribuição que pode ser estimada em mais de um indel a cada 1000 pb, são facilmente encontrados em regiões de interesse. A baixa taxa de mutação e a possibilidade de desenhar primers alelo-específicos são as principais características dos indels que os diferenciam de STRs. O uso de primers aleloespecíficos na detecção e dosagem de misturas de DNA apresenta maior sensibilidade e acurácia que as técnicas usualmente empregadas. Aqui foram descritos, para 10 lócus indel, pares de primers flanqueadores e alelo-específicos para ambos os alelos (inserção e deleção) e foi realizado o estudo populacional em 160 indivíduos. A determinação de fenótipos e avaliação de especificidade dos primers, dos quais 28 foram específicos, foi realizada por PCR convencional seguida de PAGE. As análises populacionais e forenses mostraram que esses lócus apresentam alta variabilidade (heterozigose de 30-50%) e consequentemente, alta informatividade. Os valores de PIC, PE e PD variaram de 0,2763 a 0,3750; 0,1381 a 0,1875 e 0,4978 a 0,6250 respectivamente. Os valores cumulativos de PCE e PCD foram respectivamente 0,8508 e 0,9999. Assim, esse conjunto de indels é indicado para serem testados na detecção e quantificação de misturas de DNA a partir da amplificação alelo-específica. / Indels polymorphisms are the most abundant after SNPs, representing 3.6 million of the variants characterized by the 1000 Genomes project. With a distribution that can be estimated at more than one indel per 1000 bp, they are easily found in regions of interest. The low mutation rate and the possibility of designing allele-specific primers are the main characteristics of the indels that differentiate them from STRs. The use of allele-specific primers in the detection and dosage of DNA mixtures is more sensitive and accurate than regularly employed techniques. Here, for 10 indel loci, pairs of flanking primers and allele-specific primers, for both alleles (insertion and deletion), were described and a population study was performed on 160 individuals. Determining phenotypes and evaluation of primers specificity, of which 28 were specific, was performed by conventional PCR followed by PAGE. In population and forensic analysis, these loci showed high variability (heterozygosis of 30-50%) and consequently high informativeness. The values of PIC, PE and PD ranged from 0.2763 to 0.3750, 0.1381 to 0.1875 and 0.49978 to 0.6250 respectively. Combined values of PCE and PCD were respectively 0.8508 and 0.9999. Thus, this set of indels is indicated to be tested for detection and quantification of DNA mixtures using the allele-specific amplification method. Allele-specific primers DNA mixture Forensic parameters Indel Indel Mistura de DNA Parâmetros forenses Parâmetros populacionais Population parameters Primer aleloespecífico

Search results