Targeting Myotonic Dystrophy with Small Molecules

Coonrod, Leslie, Coonrod, Leslie

January 2012

Myotonic dystrophy (DM) is one of the most common forms of muscular dystrophy, characterized by its hallmark symptom myotonia. DM is an autosomal dominant disease caused by a toxic gain of function RNA. The toxic RNA is produced from expanded non-coding CTG/CCTG repeats, and these CUG/CCUG repeats sequester a family of RNA binding proteins. The Muscleblind-like (MBNL) family of RNA binding proteins are sequestered to the expanded CUG/CCUG repeats. The MBNL proteins are regulators of alternative splicing, and their sequestration to the toxic RNA leads to mis-splicing events, which are believed to cause the symptoms observed in DM patients. A previously reported screen for small molecules used to identify compounds that could disrupt MBNL from binding the toxic CUG repeats found that pentamidine was able to rescue splicing defects associated with DM. Herein, we present a new class of molecules (phenolsulphonphthaleins) that inhibited MBNL1/CUG repeat complex formation in a competitive electrophoretic mobility shift assay (EMSA). Additionally, one of these molecules, bromophenol blue (BPB), acted in a synergistic manner with the previously described inhibitor pentamidine. We also demonstrated that the halogenation of the phenolsulphonphthalein dyes is an important factor for activity. Moreover, we presentant analysis of a series of methylene linker variants of pentamidine that revealed heptamidine (an analog of pentamidine) could reverse splicing defects in a DM1 tissue culture model and rescue myotonia in a DM1 mouse model. Finally, we report on a new crystal structure of CUG repeats, crystallized in the context of a GAAA tetraloop/receptor which facilitated ordered packing within the crystal. This structure was consistent with previous structures showing that the repeats are essentially A-form RNA, despite having a U-U mismatch every third base pair. We also identified six types of U-U mismatch in the context of the 5'CUG/3'GUC motif, suggesting that the interactions between the uridines are dynamic. This structure also contains the highest resolution GAAA tetraloop/receptor structure (1.95 Å) reported to date. This dissertation includes previously unpublished co-authored material.

CUG repeats

Myotonic dystrophy

RNA structure

Small molecules

Toxic RNA

Elementos repetitivos na regulação da transcrição de Mycoplasma hyopneumoniae

Cattani, Amanda Malvessi

January 2016

Mycoplasma hyopneumoniae é uma bactéria de tamanho diminuto, caracterizada por um genoma pequeno, com baixo conteúdo GC. Está associada com doenças respiratórias de suínos, resultando em prejuízos produtivos e econômicos na indústria animal. A presença de sequências de DNA repetitivas, que ocorrem em grandes quantidades em células eucarióticas, vem sendo cada vez mais identificadas em genomas de procariotos, sendo também associadas a um potencial papel regulador. Uma vez que a regulação da transcrição nesses organismos ainda é pouco entendida, o objetivo do presente estudo foi realizar uma busca in silico por elementos repetitivos nas regiões intergênicas do genoma de M. hyopneumoniae linhagem 7448. Dois tipos de repetições foram selecionados para a busca inicial: tandem e palindromes. Regiões intergênicas de até 500 pb a montante do sítio de início da tradução de todas as CDSs do genoma de M. hyopneumoniae linhagem 7448 foram utilizadas para a predição. Para cada tipo de elemento dois programas computacionais independentes foram utilizados. As predições in silico resultaram em 144 repetições em tandem e 1.171 palindromes. O DNA repetitivo se encontra distribuído a montante de 86% das unidades transcricionais de M. hyopneumoniae linhagem 7448. Análises comparativas entre genomas de micoplasmas demonstraram diferentes níveis de conservação dos elementos repetitivos entre linhagens patogênicas e não-patogênicas. Linhagens patogênicas revelaram uma conservação de 59%, enquanto que a não patogênica, somente de 46%. Através de ensaios de amplificação quantitativa de DNA, foi observado diferentes níveis de expressão em genes codificantes para importantes proteínas, como glicina hidroximetiltransferase, lipoproteína, adesinas e proteína ligadora de GTP. Os genes codificantes para essas proteínas divergiam no número de repetições palindromes e tandens na sua respectiva região intergênica. Além disso, repetições encontradas em 206 genes já descritos como regulados em diferentes condições em M. hyopneumoniae linhagem 232 mostraram aproximadamente 80% de conservação em relação à linhagem M. hyopneumoniae linhagem 7448. Todos esses resultados sugerem um potencial papel regulador das repetições de DNA em tandem e palindromes em Mycoplasma. / Mycoplasma hyopneumoniae is a diminutive bacterium, characterized by a small genome with a low GC content. It is commonly associated with swine respiratory diseases, resulting in productivity and economic losses in the animal industry. Repetitive DNA, which occurs in large quantities in eukaryotic cells, has been increasingly identified in prokaryotic genomes, and has been associated with a potential regulatory function. Once transcription regulation in these organisms is still poorly understood, the aim of the current study was to perform an in silico search of repeat elements in the genomic intergenic regions of M. hyopneumoniae strain 7448. Two types of repeats were selected for initial search: Tandem and Palindromic. Intergenic regions up to 500 bp upstream from start codon of M. hyopneumoniae strain 7448 CDSs were used as input for the software’s prediction. For each type of repeat sequence, two independent software packages were used. Computational analysis results in 144 tandem repeats and 1,171 palindrome elements. The repeats were distributed in the upstream region of 86% of transcriptional units of M. hyopneumoniae strain 7448. Comparative analysis between distinct mycoplasmas, demonstrate different indices of repeat conservation among pathogenic and non-pathogenic strains. Pathogenic strains revealed 59% conservation, while non-pathogenic only 46%. Through assays of quantitative amplification of DNA, different levels of expression in genes coding important proteins have been demonstrated, as glycine hydroxymethyltransferase, lipoprotein, adhesins and GTP-binding protein. These protein coding genes differ in number of palindromes or tandem repeats in respective upstream regions. In addition, repeats found in 206 genes already described to be regulated in different grow conditions in M. hyopneumoniae strain 232 showed almost 80% of conservation in relation to M. hyopneumoniae strain 7448. All these findings, suggests a potential regulatory role of tandem and palindrome DNA repeats.

Mycoplasma hyopneumoniae

Transcrição genética

Tandem

Palindrome

DNA repeats

Transcriptional regulation

Functional analysis of the role of the Nanog tryptophan repeat in ES cells

Zhang, Jingchao

January 2016

Nanog is a transcription factor that plays a central part in the gene regulatory network that maintains and induces pluripotency of embryonic stem cells (ESCs). However, the molecular basis by which Nanog achieves its functions is not fully understood. At the centre of C-terminal domain of Nanog a tryptophan repeat (WR) is located, comprising 10 penta-peptide repeats each starting with a tryptophan. A mutant form of Nanog (Nanog-W10A) in which all 10 tryptophan residues have been substituted by alanine has an impaired capacity to drive LIF-independent self-renewal and a reduced efficiency in reprogramming primed epiblast stem cells to naïve pluripotency. To understand how the WR contributes to Nanog function, Nanog-W10A-ERT2 was introduced into Nanog null cells. Upon hydroxytamoxifen addition, the Nanog-ERT2 fusion proteins were detected on chromatin within 1 hour, allowing a comparison of genome-wide transcriptional responses to Nanog and Nanog-W10A by microarray. When treated with LIF, Nanog-W10A can activate most of Nanog targets as efficiently as Nanog. In contrast, Nanog-W10A did not efficiently repress most Nanog targets, including Otx2 and Tcf15 that were previously suggested to prime ESCs for differentiation. The microarray experiments performed in the absence of LIF signalling showed that Nanog and LIF co-regulate an extensive list of targets, including Klf4 and Mras. When LIF is absent, wildtype Nanog can still activate pro-self-renewal factors, including Esrrb and repress differentiation-priming factor, such as Tcf15 and Otx2. In contrast, in the absence of LIF, the activation of pro-self-renewal factors Klf4 and Mras is reduced. In addition, activation of Esrrb by Nanog-W10A induction delays but does not prevent differentiation. These effects allow the de-repression of Otx2 and Tcf15 by Nanog-W10A to dominate. Therefore, the function of Nanog is not only mediated by the activation of pro-self-renewal genes, but also repression of pro-differentiation signals. The functional significance of the repression of Nanog targets was further exemplified by the robust capacity of Otx2 to dominate over the self-renewal signals and to drive differentiation. The Otx2 protein is a direct interacting partner of Nanog that binds the Nanog WR tryptophan residues. The previously identified Otx2 “tail domain” comprises two imperfectly aligned repeats and aromatic residues of each repeat align with aromatic residues of the Sox2 “SXS/TY” motif previously identified to mediate the interaction between Sox2 and Nanog. Aromatic residues of Otx2 were demonstrated to directly interact with both Nanog and Sox2. The interactions between Otx2, Nanog and Sox2 are essential for Otx2 functions in driving ESCs differentiation, as Otx2 mutants with alanine substitutions of the aromatic residues in both or either of the repeats have reduced efficiency to drive differentiation. As Nanog and Sox2 may co-occupy many loci important in maintaining ESC self-renewal, Otx2 may be able to “read” the Nanog/Sox2 co-binding sites to dissolve the pluripotent networks. In summary, the repression function of Nanog is located within the Nanog WR region and represents an important module of Nanog in fine-tuning the balance between self-renewal and differentiation. This module involving Nanog WR can also be recognised by differentiation-priming factor Otx2 and may represent an initial step during the exit of differentiation.

616.02

AT-repeat polymorphisms of the human CTLA-4 gene : associations with autoimmune diabetes and allele-specific variation of expression /

Lowe, Robert M. J.,

January 2003

Thesis (Ph. D.)--University of Washington, 2003. / Vita. Includes bibliographical references (leaves 105-118).

Genetic Characterization and Analysis of Cis and Trans-elements That Facilitate Genome Stability in Saccharomyces cerevisiae

Jones, Hope

January 2010

Chromosomal fragile sites are specific loci associated with a high frequency of breakage and recombination. A cell's ability to repair and/or replicate through a lesion is prerequisite to the maintenance of genomic stability. An improved understanding of fragile site biology and its contribution to replication defects and genomic instability is critical for prevention, intervention, and diagnosis of genetic diseases such as cancer. This work seeks to identify and characterize both trans and cis fragile sites associated elements involved in instability onset and progression. An array of Saccharomyces cerevisiae isogenic DNA repair deficient mutants were utilized to identify genes contributing to the stability or instability of a natural fragile site ~ 403 kb from the left telomere on chromosome VII. Findings suggest that the RAD52 epistasis group, the MRX complex, non-homologous end-joining (NHEJ) pathways, MUS81 and SGS1 helicases, translesion polymerases, and a majority of the post replication repair (PRR) proteins are all required for faithful replication of the 403 fragile site and likely other fragile sites as well. In contrast I found that MMS2, previously thought to be specific to the PRR pathway, is required to prevent the fusion of repetitive elements within the 403 site. mgs1 (homolog of the human Werner helicase interacting protein, WHIP) and pol3-13 (a subunit of the DNA polymerase delta) mutants also exhibited reduced instability in checkpoint deficient cells. These findings suggest previously uncharacterized function of Mgs1, Pol3 and Mms2 in regulation of genome regions at risk of replication damage. We further find the presence of inverted repeats (IR) are sufficient to induce instability. Two IR's proximal to the 403 site consistently fuse to generate acentric and dicentric chromosomes involving the 403 fragile site and a newly identified site on chromosome VII as well. The frequency of fusion events is aggravated by chromatin traffic stressors such as tRNA transcription induced fork stalling and replisome termination regions.

Chromosome instability

Dicentric

DNA replication

Inverted repeats

Transcription

INTER-KINGDOM EPIGENETICS: CHARACTERIZATION OF MAIZE B1 TANDEM REPEAT-MEDIATED SILENCING IN DROSOPHILA MELANOGASTER

McEachern, Lori A.

19 August 2010

Transgenic organisms are a valuable tool for studying epigenetics, as they provide significant insight into the evolutionary conservation of epigenetic control sequences, the interacting proteins, and the underlying molecular mechanisms. Paramutation is an epigenetic phenomenon in which the epigenetic status and expression level of one allele is heritably altered after pairing with another. At the b1 locus in maize, a control region consisting of seven 853 bp tandem repeats is required for paramutation. To study the conservation of the epigenetic mechanisms underlying maize b1 paramutation, I created transgenic Drosophila carrying the maize b1 control region flanked by FRT sites and adjacent to the Drosophila white reporter gene. The maize b1 tandem repeats caused epigenetic silencing in Drosophila, as white expression consistently increased following repeat removal. A single copy of the tandem repeat sequence was sufficient to cause silencing, and silencing strength increased as the number of repeats increased. Trans interactions, such as pairing-sensitive silencing, were also observed and appear to require a threshold number of b1 tandem repeats, similar to paramutation in maize. Analysis of transcription from the repeats showed that the b1 tandem repeats are transcribed from both strands in Drosophila, as they are in maize. Bidirectional transcription was found to extend to the regions flanking the repeats, and persisted in “repeats-out” transgenes following repeat removal. However, aberrant transcription was lost when a zero-repeat transgene was moved to a new genomic position, suggesting that it may be due to an epigenetic mark that is retained from the previous silenced state. A search for modifiers of b1 repeat-mediated silencing demonstrated that Polycomb group proteins are involved. Together, these results indicate considerable conservation of an epigenetic silencing process between the plant and animal kingdoms. Genomic imprinting is a related epigenetic process in which parent-specific epigenetic states are inherited and maintained in progeny. The conservation of epigenetic mechanisms was further explored via an in-depth review of the molecular mechanisms underlying genomic imprinting in plants, mammals and insects, and identification of potentially imprinted genes in Drosophila by microarray analysis.

Epigenetics

Drosophila melanogaster

Paramutation

Tandem repeats

Transcription

Silencing

Genomic imprinting

Role of the Breast Cancer Susceptibility 2 BRC Repeats in Homologous Recombination

Cealic, Iulia

08 January 2013

Homologous recombination (HR) is a faithful mechanism for the repair of double-stranded DNA breaks (DSBs) and plays a critical role in maintaining the integrity of genomic DNA. The product of the Breast Cancer Susceptibility 2 (BRCA2) gene functions as a recombination mediator in HR-directed repair of DSBs. BRCA2 interacts directly with RAD51, the central recombinase of HR, through highly conserved repetitive motifs of 30-40 amino acids, named BRC repeats, and regulates the formation of the RAD51-ssDNA nucleoprotein filament. There is significant variability in the number of BRC repeats among taxa. However, all mammalian BRCA2 orthologs have eight BRC repeats, which display different characteristics in in vitro studies of RAD51-ssDNA nucleoprotein filament. To test the importance of the number of BRC repeats and to evaluate the role of individual BRC repeats in HR, BRCA2 variants bearing different combinations of BRC repeats were generated using BAC-recombineering, expressed in murine hybridoma cells, and assayed for the ability to stimulate HR using a gene targeting assay. The BRCA2 variant bearing BRC repeats 1 to 4 decreased the efficiency of HR and increased the level of Rad51 protein, whereas the BRCA2 variant bearing BRC repeats 5 to 8 significantly stimulated HR, but had no effect on the level of Rad51. These results supported the hypothesis that BRC repeats are not functionally equivalent, but rather have different, perhaps reinforcing functions in HR. / Canadian Institutes of Health Research

BRCA2

BRC repeats

Homologous recombination

Gene targeting

Rad51

Microsatellite Evolution in The Yeast Genome - A Genomic Approach

Merkel, Angelika

January 2008

Microsatellites are short (1-6bp long) highly polymorphic tandem repeats, found in all genomes analyzed so far. Popular genetic markers for many applications including population genetics, pedigree analysis, genetic mapping and linkage analysis, some microsatellites also can cause a variety of human neurodegenerative diseases and may act as agents of adaptive evolution through the regulation of gene expression. As a consequence of these diverse uses and functions, the mutational and evolutionary dynamics of microsatellite sequences have gained much attention in recent years. Mostly, the focus of studies investigating microsatellite evolution has been to develop more refined evolutionary models for estimating parameters such as genetic distance or linkage disequilibrium. However, there is an incentive in using our understanding of the evolutionary processes that affect these sequences to examine the functional implications of microsatellite evolution. What has emerged from nearly two decades of study are highly complex mutational dynamics, with mutation rates varying across species, loci and alleles, and a multitude of potential influences on these rates, most of which are not yet fully understood. The increasing availability of whole genome sequences has immensely extended the scope for studying microsatellite evolution. For example, where once it was common to examine single loci, it is now possible to examine microsatellites using genome wide approaches. In the first part of my dissertation I discuss approaches and issues associated with detecting microsatellites in genomic data. In Chapter 2 I undertook a meta-analysis of studies investigating the distribution of microsatellites in yeast and showed that studies comparing the distribution of microsatellites in genomic data can be fraught due to the application of different definitions for microsatellites by different investigators. In particular, I found that variation in how investigators choose the repeat unit size of a microsatellite, handle imperfections in the array and especially the choice of minimum array length used, leads to a large divergence in results and can distort the conclusions drawn from such studies, particularly where inter-specific comparisons are being made. In a review of the currently available suite of bioinformatics tools (Chapter 3), I further showed that this bias extends beyond a solely theoretical controversy into a methodological issue because most software tools not only incorporate different definitions for the key parameters used to define microsatellites, but also employ different strategies to search and filter for microsatellites in genomic data. In this chapter I provide an overview of the available tools and a practical guide to help other researchers choose the appropriate tool for their research purpose. In the second part of my thesis, I use the analytical framework developed from the previous chapters to explore the biological significance of microsatellites exploiting the well annotated genome of the model organism Saccharomyces cerevisiae (baker’s yeast). Several studies in different organisms have indicated spatial associations between microsatellites and individual genomic features, such as transposable elements, recombinational hotspots, GC-content or local substitution rate. In Chapter 4, I summarized these studies and tested some of the underlying hypotheses on microsatellite distribution in the yeast genome using Generalized Linear Models (GLM) and wavelet transformation. I found that microsatellite type and distribution within the genome is strongly governed by local sequence composition and negative selection in coding regions, and that microsatellite frequency is inversely correlated with SNP density reflecting the stabilizing effect point mutations have on microsatellites. Microsatellites may also be markers for recent genome modifications, due to their depletion in regions nearby LTR transposons, and elements of potential structural importance, since I found associations with features such as meiotic double strand breaks, regulatory sites and nucleosomes. Microsatellites are subject to local genomic influences, particularly on small (1-2kb) scales. Although, these local scale influences might not be as dominant as other factors on a genome-wide scale they are certainly of importance with respect to individual loci. Analysis of locus conservation across 40 related yeast strains (Chapter 5) showed no bias in the type of microsatellites conserved, only a negative influence of coding sequences, which supports again the idea that microsatellites evolve neutrally. Polymorphism was rare, and despite a positive correlation with array length, there was no relationship with either genomic fraction or repeat size. However, the analysis also revealed a non-random distribution of microsatellites in genes of functionally distinct groups. For example, conserved microsatellites (similar to general microsatellites in yeast) are mostly found in genes associated with the regulation of biological and cellular processes. Polymorphic loci show further an association with the organization and biogenesis of cellular components, morphogenesis, development of anatomical structures and pheromone response, which, is absent for monomorphic loci. Whether this distribution is an indication of functionality or simply neutral mutation (e.g. genetic hitch-hiking) is debatable since most conserved microsatellites, particularly variable loci, are located within genes that show low selective constraints. Overall, microsatellites appear as neutrally evolving sequences, but owing to the sheer number of loci within a single genome, individual loci may well acquire some functionality. More work is definitely needed in this area, particularly experimental studies, such as reporter-gene expression assays, to confirm phenotypic effects.

microsatellites

short tandem repeats

software

comperative genomics

yeast

Eukaryotic replication, cis-acting elements, and instability of trinucleotide repeats

Rindler, Paul Michael.

January 2009

Thesis (Ph. D.)--University of Oklahoma. / Includes bibliographical references.

Elementos repetitivos na regulação da transcrição de Mycoplasma hyopneumoniae

Cattani, Amanda Malvessi

January 2016

Mycoplasma hyopneumoniae é uma bactéria de tamanho diminuto, caracterizada por um genoma pequeno, com baixo conteúdo GC. Está associada com doenças respiratórias de suínos, resultando em prejuízos produtivos e econômicos na indústria animal. A presença de sequências de DNA repetitivas, que ocorrem em grandes quantidades em células eucarióticas, vem sendo cada vez mais identificadas em genomas de procariotos, sendo também associadas a um potencial papel regulador. Uma vez que a regulação da transcrição nesses organismos ainda é pouco entendida, o objetivo do presente estudo foi realizar uma busca in silico por elementos repetitivos nas regiões intergênicas do genoma de M. hyopneumoniae linhagem 7448. Dois tipos de repetições foram selecionados para a busca inicial: tandem e palindromes. Regiões intergênicas de até 500 pb a montante do sítio de início da tradução de todas as CDSs do genoma de M. hyopneumoniae linhagem 7448 foram utilizadas para a predição. Para cada tipo de elemento dois programas computacionais independentes foram utilizados. As predições in silico resultaram em 144 repetições em tandem e 1.171 palindromes. O DNA repetitivo se encontra distribuído a montante de 86% das unidades transcricionais de M. hyopneumoniae linhagem 7448. Análises comparativas entre genomas de micoplasmas demonstraram diferentes níveis de conservação dos elementos repetitivos entre linhagens patogênicas e não-patogênicas. Linhagens patogênicas revelaram uma conservação de 59%, enquanto que a não patogênica, somente de 46%. Através de ensaios de amplificação quantitativa de DNA, foi observado diferentes níveis de expressão em genes codificantes para importantes proteínas, como glicina hidroximetiltransferase, lipoproteína, adesinas e proteína ligadora de GTP. Os genes codificantes para essas proteínas divergiam no número de repetições palindromes e tandens na sua respectiva região intergênica. Além disso, repetições encontradas em 206 genes já descritos como regulados em diferentes condições em M. hyopneumoniae linhagem 232 mostraram aproximadamente 80% de conservação em relação à linhagem M. hyopneumoniae linhagem 7448. Todos esses resultados sugerem um potencial papel regulador das repetições de DNA em tandem e palindromes em Mycoplasma. / Mycoplasma hyopneumoniae is a diminutive bacterium, characterized by a small genome with a low GC content. It is commonly associated with swine respiratory diseases, resulting in productivity and economic losses in the animal industry. Repetitive DNA, which occurs in large quantities in eukaryotic cells, has been increasingly identified in prokaryotic genomes, and has been associated with a potential regulatory function. Once transcription regulation in these organisms is still poorly understood, the aim of the current study was to perform an in silico search of repeat elements in the genomic intergenic regions of M. hyopneumoniae strain 7448. Two types of repeats were selected for initial search: Tandem and Palindromic. Intergenic regions up to 500 bp upstream from start codon of M. hyopneumoniae strain 7448 CDSs were used as input for the software’s prediction. For each type of repeat sequence, two independent software packages were used. Computational analysis results in 144 tandem repeats and 1,171 palindrome elements. The repeats were distributed in the upstream region of 86% of transcriptional units of M. hyopneumoniae strain 7448. Comparative analysis between distinct mycoplasmas, demonstrate different indices of repeat conservation among pathogenic and non-pathogenic strains. Pathogenic strains revealed 59% conservation, while non-pathogenic only 46%. Through assays of quantitative amplification of DNA, different levels of expression in genes coding important proteins have been demonstrated, as glycine hydroxymethyltransferase, lipoprotein, adhesins and GTP-binding protein. These protein coding genes differ in number of palindromes or tandem repeats in respective upstream regions. In addition, repeats found in 206 genes already described to be regulated in different grow conditions in M. hyopneumoniae strain 232 showed almost 80% of conservation in relation to M. hyopneumoniae strain 7448. All these findings, suggests a potential regulatory role of tandem and palindrome DNA repeats.

Mycoplasma hyopneumoniae

Transcrição genética

Tandem

Palindrome

DNA repeats

Transcriptional regulation