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

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

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

Assemblage de répétitions de la séquence 601 dans le génome de Saccharomyces cerevisiae pour dicter l'espacement des nucléosomes in vivo / Repeats assembly of the 601 sequence into Saccharomyces cerevisiae's genome to dictate nucleosome spacing in vivo

Lancrey, Astrid

18 May 2018

Le positionnement des nucléosomes le long des génomes eucaryotes est crucial étant donné qu’il affecte l’accessibilité de l’ADN à des protéines impliquées dans la transcription, la réplication, ou encore la réparation de l’ADN. Si il est aujourd’hui admis que les remodeleurs de chromatine ainsi que les préférences des nucléosomes pour certains motifs d’ADN constituent les deux principaux déterminants du positionnement des nucléosomes in vivo, leur importance relative fait encore l’objet de controverses. Dans le cadre de cette problématique nous avons développé une stratégie d’assemblage de répétitions de la séquence 601 positionnante de nucléosome directement dans le génome de Saccharomyces cerevisiae. Cette technique assistée par la technologie CRISPR/Cas9 et des oligonucléotides chevauchants s’est révélée très efficace et a permis d’assembler des répétitions sur une étendue d’environ 15 kilobases. Nous avons ainsi pu isoler trois souches se caractérisant par trois longueurs d’ADN de liaison de respectivement 20, 50 et 90 paires de bases séparant deux 601 consécutifs tout le long des répétitions. Ces longueurs d’ADN de liaison ont été choisies du fait de leur compatibilité avec les modèles de la fibre de 30 nm étudiés in vitro et parce qu’elles sont fréquemment observées chez les eucaryotes. Nous avons ensuite regardé si ces répétitions de la séquence 601 suffisent à dicter la succession des nucléosomes de S. cerevisiae selon le pas de chromatine attendu. Pour cela, nous avons eu recours à une approche de MNase-seq afin d’analyser les positions des dyades des nucléosomes dans les répétitions. Les résultats de ces analyses révèlent de façon intéressante l’incapacité de la séquence 601 à positionner le nucléosome dans ce contexte cellulaire et cela malgré l’étendue de la région de 601 répétés constituée. Nous avons également analysé le positionnement des nucléosomes chez ces trois mêmes souches suite à l’inactivation de Chd1, l’un des deux principaux architectes du paysage nucléosomal chez la levure, afin de s’affranchir de son potentiel effet sur le positionnement des nucléosomes dans la région 601. Nos résultats montrent que l’absence de Chd1 ne permet pas de rétablir un positionnement des nucléosomes sur les monomères de 601, suggérant que le 601 n’est pas positionnant in vivo ou que la région répétée est sous l’influence d’autres facteurs de remodelage. D’un point de vue méthodologique, notre technique de construction de répétitions in vivo permet d’envisager des approches simplifiées de biologie synthétique pour la construction de librairies de répétitions dans le génome de S. cerevisiae. / Nucleosome positioning along eukaryotic genomes is crucial as it influences DNA accessibility for DNA binding proteins involved in DNA replication, transcription and repair. It is now accepted that both nucleosome preferences for some DNA sequences and remodeling factors play an important role in nucleosome positioning in vivo. However their relative importance remains a matter of debate. To investigate the role played by DNA sequence in nucleosome positioning in a cellular context we developped a strategy to assemble tandem DNA repeats of a nucleosome positioning sequence directly into Saccharomyces cerevisiae’s genome. This method is assisted by CRISPR/Cas9 and overlapping oligonucleotides and it turned out to be very efficient as it allowed to synthetize about 15 kilobases of tandem DNA repeats inside a yeast chromosome. Using this apporoach we obtained three yeast strains differing by the DNA linker length separating two consecutive monomeres of the 601 nucleosome positioning sequence. We chose three lengths of linker (20, 50 and 90 pb) for two reasons. First, they are compatible with the formation of a 30 nm chromatin fiber in vitro, and second, nucleosome repeat length of 167, 197 and 237 pb are found in eukaryotic genomes. We then verified if nucleosomes are effectively positioned according to the theoretic DNA linker lengths we designed in the “601” repeated region. To that goal we performed MNase-seq analysis to deduce nucleosomes dyads positions in the repeats. Interestingly our results show that the 601 sequence is not able to dictate strong nucleosomes positioning differing from the natural nucleosome repeat length of about 165 pb along the repeats in an in vivo context. We further investigated positions of dyads in the same three strains after inactivating the gene coding for the chromatin remodeler Chd1, which could potentially be responsible of the nucleosomes organization in the repeated area. Our results show no effect of Chd1, indicating that the “601” sequence has no positionning effect in vivo or that other trans-acting factors are implicated in nucleosome positioning in the engineered repeats. Finally, this work provides a new fast and simple approach for synthetic DNA repeats construction inside the yeast genome and could easily be applied for other synthetic chromatin engineering approaches.

Positionnement des nucléosomes

Chromatine

Levure

Séquence 601

ADN répété

CRISPR/Cas9

Nucleosome positioning

Chromatin

Yeast

601 sequence

DNA repeats

CRISPR/Cas9

The ICF syndrome and emergent players in DNA methylation and development : when studying a rare genetic disease sheds new light on an "old" field / Syndrome ICF et acteurs émergents dans la méthylation de l'ADN et le développement : l’étude d’une maladie génétique rare apporte un regard nouveau sur un « ancien » domaine

Grillo, Giacomo

06 July 2017

La méthylation de l'ADN est un processus vital pour le développement des mammifères. Sa distribution anormale,notamment au niveau des régions répétées du génome, est une signature pathologique. La découverte de maladies héréditaires touchant la stabilité du génome a permis des avancées considérables dans l'identification des acteurs et des mécanismes. Nous avons choisi d'étudier le syndrome ICF (Immunodéficience, instabilité Centromérique et anomalies Faciales), première maladie génétique identifiée avec des défauts de la méthylation de l’ADN, liés à une instabilité chromosomique. Lorsque j'ai commencé ma thèse, des mutations dans les gènes DNMT3B et ZBTB24 avaient été décrites comme causes génétiques du syndrome. Cependant, d'autres causes génétiques restaient inconnues. Nos travaux ont permis d'identifier deux nouveaux gènes, CDCA7 et HELLS, dont les mutations sont responsables du syndrome. J'ai montré que leur perte de fonction dans les cellules somatiques entraîne un défaut de méthylation des répétitions centromériques, suggérant leur rôle dans le maintien de la méthylation de l'ADN. Par conséquent, l'étude de l'étiologie d'une maladie génétique rare a permis d'identifier de nouveaux « gardiens » de la stabilité du génome, avec des fonctions jusqu'alors insoupçonnées dans les processus de méthylation de l'ADN et dans le développement. Au cours de mon doctorat, j'ai établi des cartes de méthylation des cellules de patients ICF afin d'identifier les cibles communes et distinctes de ces facteurs, ainsi que leurs caractéristiques génomiques et épigénomiques. Contrairement aux mutations de DNMT3B,celles de ZBTB24, CDCA7 et HELLS affectent la méthylation dans des régions pauvres en CpG, dans des régions intergéniques et dans des répétitions d'ADN intercalées. Plus généralement, ce sont les régions d'hétérochromatine qui sont les plus touchées et en particulier des clusters des gènes codants et non codants, dont certains sont exprimés de manière monoallélique. Pour mieux caractériser le rôle de ZBTB24 dans le développement et la méthylation de l'ADN,nous avons généré un modèle murin mutant qui nous a permis de monter que ZBTB24 était essentielle pour le développement embryonnaire précoce. De plus, ZBTB24 jouerait un rôle dans l'établissement de la méthylation des séquences répétées de l'ADN, à la fois en tandem ou intercalé. Fait intéressant, ZBTB24 semble être également impliqué dans l'établissement de la marque répressive H3K9me3, suggérant un rôle de la protéine dans le "dialogue" entre la méthylation de l'ADN et celle des histones. Dans l'ensemble, mon travail met l'accent sur la façon dont la méthylation de l'ADN et les marques d'hétérochromatine sont établies et maintenues à des gènes uniques et des répétitions de l'ADN, et fournit de nouveaux acteurs et mécanismes à considérer dans les études sur le maintien de la stabilité du génome. / DNA methylation is an essential process for the development of mammals. Its abnormal distribution, particularly at the level of the repeated regions of the genome, is a pathological signature. The discovery of hereditary diseases affecting DNA methylation and the stability of the genome allowed a considerable progress in the identification of their actors and mechanisms. We chose to study the ICF (Immunodeficiency, Centromeric Instability and Facial Abnormalities) syndrome, the first genetic disorder identified with defects in the distribution of DNA methylation, linked to chromosomal instability. When I started my PhD, mutations in two genes had been described to cause the ICF syndrome: DNMT3B and ZBTB24. However, the genetic origin of a subset of ICF patients remained unknown. We identified mutations in CDCA7 and HELLS as causative of the ICF syndrome. I showed that their loss of function in somatic cells results in the loss of DNA methylation at centromeric repeats, strongly suggestive of a role DNA methylation maintenance. Hence, the study of the aetiology of a genetic disease provided new candidate “guardians” of DNA repeats and genome stability, with virtually unknown functions but with exciting potential roles in the DNA methylation machinery and in development. During my PhD, I established methylation maps in ICF patients cells to identify common and distinct targets of these factors, as well as their genomic and epigenomic characteristics. In contrast to DNMT3B mutations, those in ZBTB24, CDCA7 and HELLS affect methylation at CpG-poor regions in intergenic genomic locations and at interspersed DNA repeats, and more generally, at genomic locations with heterochromatic features. Their integrity is required for the methylated status of coding and non-coding clusters of genes, some of which are expressed in a monoallelic manner. To better characterize the role of ZBTB24 in development and DNA methylation pathways, we generated a mouse model carrying mutations in ZBTB24. We showed that ZBTB24 is essential for early development, while it seemed to be dispensable for in vitro differentiation of murine ES cells. We implicated ZBTB24 in the establishment of DNA methylation at DNA repeats, both in tandem or interspersed, in differentiating ES cells. Interestingly, ZBTB24 seems to be also implicated in the establishment of the repressive mark H3K9me3 suggesting that ZBTB24 may indirectly control DNA methylation through an interplay with histone marks. As a whole, our work sheds light on how DNA methylation and heterochromatin marks are established and maintained at unique genes and DNA repeats, and provides new actors and mechanisms to consider in studies of the maintenance of genome stability.

Epigénétique

Maladies humaines

Répétitions d’ADN

Modèles murins

Développement précoce

Epigenetics

DNA methylation

Human diseases

Methylome

Heterochromatin

DNA repeats

Mouse models

Early development