Biochemical Characterization Of An Acid-Adaptive Type III DNA Methyltransferase From Helicobacter Pylori 26695 And Its Biological Significance

Banerjee, Arun

07 1900

Enzyme DNA methylation is an important biochemical process that imprints DNA with additional information. DNA methylation is catalyzed by S-adenosyl-L-methionine (AdoMet)-dependent methyltraferases (MTases). Prokaryotic DNA MTases are usually components of restriction-modification(R-M) systems that enable cells to resist propagation of foreign genomes that would otherwise kill them. Based on the position methyl group transfer on the bases in DNA, MTases are classified into two groups-exocyclic or amino MTases and endocyclic or ring MTases. The amino MTases methylate exocyclic amino nitrogen to form either N6-methyladenine or n4-methycytosine. N6-methyaladenine is mostly found in the genomes of bacteria, archaea protists and fungi. Helicobacter pylori is a gram-negative, flagellated, fastidious bacterium that colonizes the highly acidic environment of the gastric mucosa. Frequently and persistence of H.paylori infection in humans make it attractive model for studying the host- pathogen interaction mechanisms. Analysis of the genome sequence of H.pylori strains 26695, J99.HPAGI, and G27 revealed an abundance of restriction-modification (R-M) systems. Most of the R-M system genes are either conserved among the strains or specific to each strain. Strain specific genes are responsible for different phenotypes in several host adapted pathogens such as H.pylori. Many of the R-M gene homologues exhibit different usages of condon bias and lower G+C content from the average genes suggesting horizontal transfer of the R-M system genes in H. Pylori. Genome analysis of strain 26695 showed the presence of three putative type III R-M systems and hp0592-hp0593 constitutes one such type III R-M system. Based on the conserved motif arrangements, HP0593 MTases belongs to the subgroups of MTases. The amino acid sequence of HP0593 MTases has 38% sequence identity to Ecop11 MTases and EcoP151 MTase, both of which belongs to type IIIR-M systems therefore, it was important to study in detail previously unexplored role of this putative type III DNA MTase (HP0593) in H. Pylori. Investigation of methyltransferease activity and sequence specifically of putative DNA adenine MTase (HP0593) HP0593 (N6-adenine) - DNA MTase is a member of a type III R-M system in H. pylori strain 26695. HP0593 MTase has been cloned, over expressed and purified heterologously in Escherichia coli. Matrix-assisted laser desorption ionization mass spectrometry (MALDI-MS) was carried out with purified HP0593 and profile showed a single peak with expected molecular mass of 70.6kDa. The protein was determined as-5.8. HP0593 MTase exits predominantly as monomer and a small fraction as dimer in solution as determined by size exclusion chromatography and glutaraldehyde cross-linking studies. The recognition sequence of the purified MTase was determined as 5’GCAG-3’ and the target base of methylation is adenine. Dot-blot assay using antibodies that reacted specifically with DNA containing m6A modification confirmed that HP0593 MTase is an adenine specific MTase. Exocyclic MTase have a conserved catalytic motif (D/N/S/SPPY/F/W). Most interestingly, the amino acid sequence analysis of HP0593 MTase revealed the presence of a PCQ-like motif, which is the catalytic motif for C5-cytosine MTase in addition to DPPY motif. In order to check the role of both these MTase by glycine. HP0593 –Y107G and C54G mutant proteins were purified to near homogeneity. It was found that the Y107G mutant protein was catalytically inactive as compared to wild-type HP0593 MTase. On the other hand the C54G mutant protein was found to be as active as the wild-type HP0593 MTase indicating that HP0593 MTase is an adenine MTase and not a C5- cytosine MTase. Kinetic and catalytic properties of HP0593 DNA adenine methyltransferase DNA binding studies were carried out by electrophoretic mobility shift assay using DNA having cognate site and either in absence or presence of AdoHcy or sinefungin. In all the three cases two different DNA-protein complexes were observed-a fast running complex I and a slow running complex 2. It can be surmised that the fast running complex could be HP0593 monomer-DNA and the slow running complex could be a HP0593 dimer-DNA complex. With non specific DNA (lacking 5’-GCAG-3’ sequences) no complexes were formed even in the presence of cofactors. Based on the above observations it is suggested that a specific interactions of HP0593 MTase with DNA occurs on cognate recognition site. The activity of HP0593 MTase is optional at pH 5.5. This is a unique property in context of natural adaptation of H. pylori in its acidic niche. When initial velocities were plotted against varying concentrations of duplex DNA having a single 5’GCAG-3’ site a rectangular hyperbola was obtained confirming that HP0593 MTase obeys michaelis menten kinetics. From non-linear regression analysis of the plot of initial velocity versus DNA concentration Km (DNA) and kcat were calculated. Analysis of initial velocity with AdoMet as a substrate showed that two molecules of AdoMet bind to HP0593 MTase. The nonlinear dependence of methylation activity on enzyme concentration indicated that more than one molecule of methylation activity on enzyme concentration indicated that more than one molecule of enzyme is required for its activity. Metal ion cofactors such as CO 2, Mn2+ and Mg2+ stimulated the HP09593 MTase activity. As Mn2+ showed maximum stimulation of methyaltion activity compared to other metal ions, surface plasmon resonance spectroscopy was used to determine the kinetics of DNA binding by HP0593 MTase in the absence and presence of Mn2+. In the presence of Mn2+, HP0593 MTase showed~1000-fold increase in affinity to duplex DNA. DNA MTase bind substrates in random or sequential order. Preincubation study demonstrated that the preformed enzyme-DNA complex is competent than the preformed enzyme-AdoMet complex. This suggests that MTase binds to DNA first followed by AdoMet. Isotope partitioning analysis indicated that HP0593 MTase shows a distributive mechanism of methylation DNA having more than one recognition site. Effects of inactivation of HP0593 DNA MTase in Helicobacter pylori 26695 strain and its functional role. DNA dot-blot assay using hp0593 gene specific primer showed that this gene is present in 25.15% of the clinical strains checked suggesting that hp0593 is strain-specific gene. Strain-specific genes in many host-adapted pathogene impart strain specific phenotype. Wild-type 26695 strain grew slightly faster at the initial phase of growth in PH 4.5 compared to pH 7.4. A~5-fold enhanced level of hp0593 mRNA expression was growth under acidic condition HP0593 MTase could play an important role in H. pylori physiology through methylation. To elucidate the possible role(s) played by the MTase in H.pylori physiology, an hp0593 knock-out in 26695 strain was generated by chloramphenecol cassette mediated insertional gene inactivation. Growth kinetic study was carried out with both wild-type and hp0593 knock-out strain at pH7.4, the growth of the hp0593 strain. At pH 4.5 no major differences were observed in the growth compared to the wild-type hp0593 knock-out strain. To further investigate the effect of the knock-out, cell-morphology study was carried out after growing the strains at pH 7.4 till mid-exponential phase. Transmission electron microscopy studies reveled changes in cell shape, presence of sheathed structure and production of outer membrane vesicles (OMVs) in the hp0593 knock out strain. OMVs contain effectors molecules during infection helps in pathogenicity caused by H.pylori.This is the first report where inactivation of DNA MTase causes shedding of vesicles. OMVs are also known to modulate the production of IL-8 by gastic epitheial cells. To check weather H.pylori strains could produce IL-8, both wild-type and hp0593 knock-out strains were co-cultured with AGS cell infected with the hp0593 knock out strain. This was further confirmed by semi-quantitative RT-PCR analysis. To analyze the different phenotypes observed in the hp0593 knock-out strain, transcriptome profile were compared by microarray and RT-PCR analysis. In thehp0593 knock-out strain peptidologlycan and murein synthesis genes like pbp2, murC and neu4 showed upregulation which could be responsible for the changes in cell shape presence of sheathed structure and OMVs production. The RT-PCR data showed ~9-fold down-regulation of dank chaperone which might play a key role in slow growth phenotype in the hp0593 knock-out strain. Considering the occurrence of GCAG sequence in the potential promoter regions of physiologically important genes such as dank, neuA, murC, fliH, filP and cag5, the results presented in this study provide impetus for exploring the role of HP0593 DNA MTase in the cellular processes of H.pylori. However, R-M systems are not absolutely essential, but different methylation patterns may contribute to strain-specific epigenetic gene regulation and may contribute to variability among the strains.

DNA Methyltransferase - Biochemistry

Helicobacter pylori 26695

DNA Adenine Methyltransferase

HP0593 Gene

H. pylori

Adenine Methyltransferase

DNA Adenine MTase

Type III R-M Systems

Bacteriology

The magnetoencephalographic signature of catechol-O-methyltransferase

Farrell, Sarah Marie

January 2013

Catechol-O-methyltransferase (COMT) metabolizes catechols, notably dopamine. The COMT Val158Met polymorphism influences its enzyme activity, and multiple neural correlates of this genotype on dopaminergic phenotypes have been reported, particularly with regards to working memory. COMT activity can also be regulated pharmacologically by COMT inhibitors. The ‘inverted-U’ relationship between dopamine signalling and cognitive performance predicts that the effects of COMT inhibition will differ according to COMT genotype. The goal of this thesis was to better understand COMT’s impact on brain function and behaviour. Here, 33 subjects homozygous for COMT Val158 (‘Val homozygotes’) and 34 homozygous for COMT Met158 (‘Met homozygotes’) were randomly assigned, double-blind, to a single dose of the brain-penetrant COMT inhibitor tolcapone (200mg) or placebo. They completed the N-back task of working memory, an emotional face processing task, and a gambling task, in a magnetoencephalography (MEG) scanner, allowing both behavioural performance and neural activity to be investigated. The data presented in this thesis confirm that COMT activity influences performance on, and neural activity during, the N-back task, in a way consistent with the inverted-U model of dopamine function. The effect on risky decision making is novel, and indicates that COMT plays roles in domains beyond working memory, and that such domains may also follow an inverted-U. Neural activity during the faces task and the gambling task also show COMT-modulated differences. The behavioural results show that the direction of effect of a drug can be influenced by sequence variation in its target gene. They are of translational relevance, since COMT inhibitors are used in the adjunctive treatment of Parkinson’s disease and are under evaluation in schizophrenia and other disorders. The MEG data show that for the three tasks, there are effects of Val158Met genotype, of tolcapone, and their interaction, on neural activity (for example, the P300 during N-back), revealing a complex temporal and spatial pattern which sheds some light on the neural processing underlying these tasks and their previously reported fMRI correlates.

612.8

Farnesoic acid 0-methyltransferase (FAMET) is an essential molt regulator in the shrimp, Litopenaeus vannamei

Hui, Ho-lam, Jerome., 許浩霖.

January 2005

published_or_final_version / abstract / Zoology / Master / Master of Philosophy

Molecular cloning.

Methyltransferase.

Litopenaeus - Physiology.

Litopenaeus - Molecular genetics.

Betaine Homocysteine Methyltransferase, Disease and Diet: The Use of Proton Nuclear Magnetic Resonance on Biological Methylamines

Lee, Martin Bryce

January 2006

Homocysteine, an independent risk factor for cardiovascular disease, is methylated in the liver via the zinc metalloenzyme betaine-homocysteine methyltransferase (BHMT). Established assays for BHMT include a radiochemical assay, a colorometric assay, an HPLC assay and an in vivo microbiological assay. These techniques are either unsuitable for substrate specificity studies, or are unable to give kinetic measurements. BHMT was purified from liver and measured directly and kinetically by a novel ¹H-NMR spectroscopic assay. The disappearance of substrates and the formation of products are monitored simultaneously. Using 2 mM glycine betaine and homocysteine as substrates in 20 mM phosphate buffer (pH = 7.5) and measuring the production of N,N-dimethylglycine the CV is 6.3% (n = 6) and the detection limit is 6 nkatal. An endpoint assay for BHMT activity was also developed and had CV = 5.3%, n = 6, with a detection limit of 2 nkatal. The NMR spectroscopic assay was used to determine the substrate specificity with a library of alternative substrates. Analysis of betaine analogues with different chain length, α-substitution, substitution of the nitrogen and carboxyl moieties demonstrated that BHMT is inactive if there is any steric crowding of the nitrogen or α-carbon positions. BHMT is capable of using group VI heteroatom betaines as methyl donors, with much faster rates than glycine betaine. For glycine betaine the Km was 0.19 ± 0.03 mM with a Vmax of 17 ± 0.7 nMol min-1 mg-1. The same assay was used to detect and partially characterise a BHMT activity from hagfish liver that is similar to that of the mammalian enzyme. NMR spectroscopy was adapted for measurements of glycine betaine in urine, along with other medically significant methylamines. These were shown to be valid for clinical use and in animal studies. A novel metabolite of the sulfonium analogue of glycine betaine (methylsulfinylmethanoate) was identified in rats.

Betaine Homocysteine Methyltransferase

Cardiovascular disease

Nuclear Magnetic Resonance

SPECIFICITY DETERMINANTS OF ArmA, A RIBOSOMAL RNA METHYLTRANSFERASE THAT CONFERS ANTIBIOTIC RESISTANCE

Zarubica, Tamara

15 September 2010

Bacterial resistance to 4,6-type aminoglycoside antibiotics, which target the 30S ribosomal subunit, has been traced to the arm/rmt family of rRNA methyltransferases. These plasmid-encoded enzymes transfer a methyl group from S-adenosylmethionine to N7 of the buried G1405 in the aminoglycoside binding site of 16S rRNA in the 30S ribosomal subunit. Neither 16S rRNA alone nor intact 70S ribosome is an efficient substrate for armA methyltransferase. To more fully characterize this family of enzymes, xiii we have investigated the substrate requirements of ArmA. We determined the Mg2+ dependence of ArmA activity and found that the enzyme could recognize both translationally active and translationally inactive forms of 30S subunits. To identify the site of interaction between ArmA and the 30S subunit, we used hydroxyl radical cleavage of 16S rRNA mediated by ferrous iron chelated to several sites on the ArmA molecule that were mutated to cysteine. This data suggests that significant conformational changes in 30S structure are involved in binding of ArmA. We hypothesized that a precursor intermediate in the biogenesis of the 30S subunit might be the optimal substrate for ArmA enzymes in vivo. To test this, we prepared 30S particles partially depleted of proteins by treatment with increasing concentrations of LiCl and assayed them for ArmA methylation. Even low concentrations of LiCl alter the 30S particles and greatly diminish their susceptibility to methylation. Additionally, a previously identified pre-30S particle isolated from an E. coli culture was assayed for its ability to support methylation by ArmA and found to be inferior to intact 30S particles as a methylation substrate. Thus, testing of immature particles prepared from in vitro and in vivo sources suggest that ArmA works very late in the 30S biogenesis pathway. Initiation factor 3 (IF3), a factor that only binds fully mature 30S particles, does not inhibit the ArmA methylation, while kasugamycin methyltransferase (KsgA) abolishes ArmA activity by sharing the same binding site with ArmA. From aforementioned experiments, we conclude that ArmA is most active toward 30S ribosomal subunits that are at or very near full maturation.

ArmA Methyltransferase

16S rRNA

Life Sciences

Gen-Umwelt-Interaktionen für die Catechol-O-Methyl-Transferase und ihre Auswirkungen auf die Verhaltensantwort der emotionalen Verarbeitung / Gene environment interactions for the catechol-o-methyl-transferase and its effects on emotional processing

Würflein, Heidi

January 2009

Gen-Umwelt-Interaktionen haben einen wichtigen Stellenwert für das Verständnis der Entstehung psychiatrischer Erkrankungen. Für die Catechol-O-Methyltransferase (COMT)konnte kürzlich gezeigt werden, dass diese die Gehirnaktivität moduliert, während der Verarberitung negativer Stimuli. Für positive Stimuli konnte kein Effekt nachgewiesen werden. In der vorliegenden Arbeit sollte nun geprüft werden, ob Lebensereignisse, als ein Umweltfaktor, für die emotionale Verarbeitung eine Rolle spielen. Um das herauszufinden untersuchten wir 81 gesunde Probanden mittels EEG während der Darbietung positiver und negativer emotionaler Bilder. Wie erwartet moduliert COMT die EPN (early posterior negativity) für negative Bilder, aber nicht für positive. Unter Berücksichtigung der Lebensereignisse konnte der fehlende Effekt der COMT bei der positiven Bedingung aufgelöst werden. Eine hohe Lebensereignis-Last führt dabei zu einer verminderten Gehirnaktivität für positive Stimuli, was sich aber nur für den Met/Met-Genotyp zeigt. Relevant scheint das vor allem für die Entwicklung von Depressionen zu sein, da depressive Patienten häufig ihre Umwelt als weniger positiv bewerten. / The interaction between genes and environment is highly relevant for our understanding of the development of psychiatric disorders. Recently it has been shown that the catechol-O-Methyltransferase genotype (COMT) modulates the brain activity during the processing of negative stimuli, but not for positive stimuli. Here we tested whether life stress, as an environmental factor, modulates this COMT genotype effect. Therefore, we measured the event-related brain potentials in 81 healthy subjects during the processing of positive and negative emotional pictures. As expected, we found that COMT modulates the neural correlates of emotional processing (the early posterior negativity, EPN), but only for negative and not for positive stimuli. Including the factor life stress we could explain this missing COMT effect for positive stimuli. We found that high life stress diminishes the positive evaluation of stimuli but only in subjects with the Met/Met genotype. This might be relevant for the development of depressions, as depressed patients often describe a lost of positive reinforcement.

Elektroencephalogramm

ddc:610

Imuno-expressão da DNMT1, DNMT3a e DNMT3b nos tumores odontogênicos / DNA Methyltransferase 1, 3A and 3B immunohistochemical expression in odontogenic tumours

Ferro, Leonardo Borges

11 October 2013

Os tumores odontogênicos são um grupo heterogéneo de lesões formadas a partir de tecidos que dão origem ao dente. A metilação do ADN, uma adição covalente de um grupo metilo na posição 5 de carbono de um nucleótideo de citosina, é considerado um importante regulador da expressão génica. A adição do radical metil é catalisada por ADN metiltransferases (DNMTs). Embora alguns estudos epigenéticos tenham sido realizados em tumores odontogênicos, um estudo com os três tipos de DNMTs em vários membros desse grupo está em falta. Este estudo analisa a expressão de DNMTs em tumores odontogênicos. Amostras de vinte ameloblastomas, dez Calcificante tumores odontogênicos císticos, dez calcificados tumores epiteliais, dez tumor odontogênico adenomatóide, dez tumores odontogênicos queratocísticos, quatro fibromas ameloblásticos, dois fibro-odontoma ameloblástico, quatro fibroma centrais odontogênicos, sete tecidos de fibromas odontogênicos periféricos e dez mixomas odontogênicos foram incluídos. DNMT1, 3A e 3B foram expressas no núcleo e / ou citoplasma de todos os tumores odontogênicos. A alta expressão de DNMTs em células de tumor odontogênico sugere metilação como um mecanismo importante para este grupo de tumores. / Odontogenic tumours are a heterogeneous group of lesions formed from tissues that give rise to the tooth. DNA methylation, a covalent addition of a methyl group to the 5-carbon position of a cytosine nucleotide, is considered an important regulator of gene expression. The addition of the methyl radical is catalyzed by DNA methyltransferases (DNMTs). Although some epigenetic studies have been conducted in odontogenic tumours, a study with the three types of DNMTs in several different members of this group is missing. This study analyzes the expression of DNMTs in odontogenic tumours. Formalin-fixed and paraffin-embedded tissue samples of twenty ameloblastomas, ten calcifying cystic odontogenic tumors, ten calcifying epithelial tumors, ten adenomatoid odontogenic tumors, ten keratocystic odontogenic tumors, five ameloblastic fibromas, two ameloblastic fibro-odontoma, four central odontogenic fibroma, seven peripheral odontogenic fibroma and ten odontogenic mixoma were included. DNMT1, 3A and 3B were expressed in the nucleus and/or cytoplasm of all odontogenic tumours. The high expression of DNMTs in odontogenic tumour cells suggests methylation as an important mechanism for this group of tumours.

DNA methyltransferase

DNA metiltransferase

Methylation

Metilação

Odontogenic Tumours

Tumor odontogênico

Etude de la méthylation de l'ADN chez la bactérie pathogène d'insectes Photorhabdus luminescens / DNA methylation role in the insect pathogen bacterium Photorhabdus luminescens

Payelleville, Amaury

16 November 2018

Photorhabdus luminescens est une entérobactérie retrouvée en symbiose avec les nématodes du genre Heterorhabditis. Dans les sols, ce complexe némato-bactérien est pathogène d’insectes ravageurs et est utilisé en contrôle biologique. Le nématode pénètre dans l’insecte et libère la bactérie dans l’hémolymphe. Photorhabdus va ensuite se multiplier et secréter divers facteurs de virulence comme des toxines. L’insecte meurt de septicémie puis le nématode et la bactérie vont se nourrir du cadavre. Une fois les ressources épuisées, le complexe némato-bactérien va se reformer et sortir du cadavre à la recherche d’une nouvelle cible. Plusieurs exemples d’hétérogénéité phénotypique ont été décrits chez cette bactérie amenant chacun à la présence de sous-populations dans une culture bactérienne. Cette hétérogénéité phénotypique peut-être causée par des mécanismes épigénétiques et plus précisément par la méthylation de l’ADN. Chez les entérobactéries, la méthyltransférase Dam est très conservée. Elle méthyle les adénines des sites GATC et est impliquée dans la réparation des erreurs lors de la réplication de l’ADN, la régulation du cycle cellulaire mais aussi la régulation de divers gènes. Cette méthyltransférase est en compétition avec certain régulateurs transcriptionnel. Selon qui de la méthyltransférase ou du régulateur se fixera en premier, le gène sera ou non exprimé donnant naissance à deux sous-populations. Cette thèse a pour objectif de mettre en évidence les rôles de la méthyltransférase Dam chez Photorhabdus luminescens. Dans un premier temps, j’ai montré que la surexpression de Dam (Dam+) amène une diminution de la mobilité et du pouvoir pathogène de la bactérie mais à l’inverse augmente sa capacité à former des biofilms. Une analyse transcriptomique (RNAseq) a montré des différentiels d’expression de certains gènes impliqués dans les phénotypes observés. En recombinant la souche de Photorhabdus Dam+ avec les nématodes hôtes, l’effet sur la pathogénicité a été augmenté en comparaison des résultats après injection de la bactérie seule. L’établissement de la symbiose némato-bactérienne avec cette souche Dam+ n’est pas significativement impacté par rapport à la souche sauvage. Enfin l’analyse du méthylome (détection de tous les sites méthylés sur le génome grâce à la technique SMRT) de Photorhabdus dans diverses phases de croissance nous a permis de déterminer que la méthylation par Dam semble être stable aux différents temps de la croissance bactérienne testés chez Photorhabdus. Le méthylome de la souche Dam+ a confirmé l’hypothèse que cette surexpression augmentait le taux de méthylation des sites GATC sur le génome. La comparaison combinée entre le RNAseq et les sites GATC différentiellement méthylés entre la souche contrôle et Dam+ a mis en évidence certains gènes candidats ressortant de ces deux analyses. En effet, certains gènes sont différentiellement exprimés dans les deux souches et ont un différentiel de méthylation au niveau de sites GATC dans leur région promotrice, l’étude détaillée de leur régulation par la méthylation fait maintenant partie des perspectives et permettront peut-être d’expliquer une partie des phénotypes observés chez Photorhabdus luminescens. / Photorhabdus luminescens is an Enterobacteriaceae found in soils in symbiosis with a nematode from the genus Heterorhabditis. This nemato-bacterial complex is highly pathogenic against insect pest crops and so used in biocontrol. The nematode enters into the insect and releases Photorhabdus in the hemolymph of the insect. Photorhabdus multiplies and produces diverse virulence factors as toxins. Insect die from septicemia and both nematodes and bacteria feed on the nutrients in the cadaver. Once nutrients are lacking, the nematodes and the bacteria reassociate and exit from the cadaver to find new insects to infect. Photorhabdus is switching between pathogenic and symbiotic state. This bacterium displays phenotypic heterogeneity as we observe subpopulations coexisting in a same bacterial culture. Phenotypic heterogeneity can be explained by epigenetic mechanisms such as DNA methylation. In Enterobacteriaceae, Dam methyltransferase is broadly distributed. It methylates the adenine of GATC sites. Dam is involved in post-replicative mismatch repair, cell-cycle regulation and also gene transcription regulation. This methyltransferase can be in competition with some transcriptional regulators. Depending on which will bind first on the promoter region, gene will be expressed or not, leading to the rise of two subpopulations. This thesis aims to understand roles of Dam in Photorhabdus luminescens. Overexpression of the methyltransferase leads to a decrease in motility and pathogenicity of Photorhabdus Dam+ strain whereas it increases biofilms formation. A transcriptomic analysis (RNAseq) revealed differential expression of genes involved in the observed phenotypes. Symbiosis establishment does not seem to be strongly impacted in Dam+ strain as the only difference observed when compared to the nematode associated with the control strain is the same as with bacteria alone (a delayed virulence). A methylome analysis was also done (screening of all methylated sites in the genome using SMRT sequencing) in several growth conditions which revealed that DNA methylation is stable over growth kinetics. Dam+ strain methylome analysis confirmed the hypothesis that Dam overexpression increases GATC methylation over the genome. Comparative analysis of methylome and RNAseq experiments between control and Dam+ strains highlighted several common genes. In fact, some genes are differentially expressed between both strains and also have GATC sites differentially methylated in their promoter region. Their transcription regulation by methylation is a future aim and may give some explanation for a part of the phenotypes observed in Photorhabdus luminescens.

Méthyltransférase

Virulence

Régulation

Méthylome

RNAseq

Methyltransferase

Virulence

Regulation

Methylome

RNAseq

Imuno-expressão da DNMT1, DNMT3a e DNMT3b nos tumores odontogênicos / DNA Methyltransferase 1, 3A and 3B immunohistochemical expression in odontogenic tumours

Leonardo Borges Ferro

11 October 2013

Os tumores odontogênicos são um grupo heterogéneo de lesões formadas a partir de tecidos que dão origem ao dente. A metilação do ADN, uma adição covalente de um grupo metilo na posição 5 de carbono de um nucleótideo de citosina, é considerado um importante regulador da expressão génica. A adição do radical metil é catalisada por ADN metiltransferases (DNMTs). Embora alguns estudos epigenéticos tenham sido realizados em tumores odontogênicos, um estudo com os três tipos de DNMTs em vários membros desse grupo está em falta. Este estudo analisa a expressão de DNMTs em tumores odontogênicos. Amostras de vinte ameloblastomas, dez Calcificante tumores odontogênicos císticos, dez calcificados tumores epiteliais, dez tumor odontogênico adenomatóide, dez tumores odontogênicos queratocísticos, quatro fibromas ameloblásticos, dois fibro-odontoma ameloblástico, quatro fibroma centrais odontogênicos, sete tecidos de fibromas odontogênicos periféricos e dez mixomas odontogênicos foram incluídos. DNMT1, 3A e 3B foram expressas no núcleo e / ou citoplasma de todos os tumores odontogênicos. A alta expressão de DNMTs em células de tumor odontogênico sugere metilação como um mecanismo importante para este grupo de tumores. / Odontogenic tumours are a heterogeneous group of lesions formed from tissues that give rise to the tooth. DNA methylation, a covalent addition of a methyl group to the 5-carbon position of a cytosine nucleotide, is considered an important regulator of gene expression. The addition of the methyl radical is catalyzed by DNA methyltransferases (DNMTs). Although some epigenetic studies have been conducted in odontogenic tumours, a study with the three types of DNMTs in several different members of this group is missing. This study analyzes the expression of DNMTs in odontogenic tumours. Formalin-fixed and paraffin-embedded tissue samples of twenty ameloblastomas, ten calcifying cystic odontogenic tumors, ten calcifying epithelial tumors, ten adenomatoid odontogenic tumors, ten keratocystic odontogenic tumors, five ameloblastic fibromas, two ameloblastic fibro-odontoma, four central odontogenic fibroma, seven peripheral odontogenic fibroma and ten odontogenic mixoma were included. DNMT1, 3A and 3B were expressed in the nucleus and/or cytoplasm of all odontogenic tumours. The high expression of DNMTs in odontogenic tumour cells suggests methylation as an important mechanism for this group of tumours.

DNA metiltransferase

Metilação

Tumor odontogênico

DNA methyltransferase

Methylation

Odontogenic Tumours

Analyses of mRNA Cleavage by RelE and the Role of tRNA Methyltransferase TrmD Using Bacterial Ribosome Profiling

Hwang, Jae Yeon

01 June 2016

Protein synthesis is a fundamental and ultimate process in living cells. Cells possess sophisticated machineries and continuously carry out complex processes. Monitoring protein synthesis in living cells not only inform us about the mechanism of translation but also deepen our insights about all aspects of life. Understanding the structure and mechanism of the ribosome and its associated factors helped us enlarge our knowledge on protein synthesis. Recently, with the dramatic advances of high-throughput sequencing and bioinformatics, a new technique called ribosome profiling emerged. By retrieving mRNA fragments protected by translating ribosomes, ribosome profiling reveals global ribosome occupancy along mRNAs in living cells, which can inform us with the identity and quantity of proteins being made. Easily adapted to other organisms, ribosome profiling technique is expanding its application in revealing various cellular activities as well as the knowledge on protein synthesis. Here, we report the mechanism of translating mRNA cleavage by endoribonuclease RelE in vivo. RelE is an endoribonuclease that is induced during nutrient deficiency stress and specifically cleaves translating mRNAs upon binding to the ribosomal A site. Overexpression of RelE in living cells causes growth arrest by inhibiting global translation. We monitored RelE activity in vivo upon overexpression using ribosome profiling. The data show that RelE actively cuts translating mRNAs whenever the ribosomal A site is accessible, resulting in truncated mRNAs. RelE causes the ribosome complexes to accumulate near the 5' end of genes as the process of ribosome rescue, translation, and cleavage by RelE repeats. RelE cleavage specific sub-codon level ribosome profiling data also represent reading frame in Escherichia coli and sequence specificity of RelE cleavage in vivo. We report another ribosome profiling study on a methyltransferase TrmD in E. coli. TrmD is known to methylate G37 (the residue at 3' side of anticodon) of some tRNAs and be responsible for codon-anticodon interaction. We constructed a TrmD depletion E. coli strain, whose deletion results in lethality of cells. Resulting depletion of m1G37 in the strain leads to growth arrest. Lack of m1G37 of some tRNAs whose codons start with C showed frequent frameshift when translating the gene message in vitro. By using ribosome profiling, we successfully observed significant difference on translation process when codons interact with anticodons of tRNAs lacking m1G37. The data reveal slow translation rate or pauses on the tRNAs when missing the appropriate methylation, which corresponds to the previous biochemical data in vitro.

RelE

endoribonuclease

TrmD

methyltransferase

ribosome profiling

m1G37

Chemistry