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Papel do miR-29a na regulação epigenética de células pluripotentes humanas / The role of miR-29a in epigenetic regulation of human pluripotent cellsLeite, Sarah Blima Paulino 31 August 2017 (has links)
As células-tronco embrionárias (CTEs), extraídas da massa celular interna do blastocisto, tem como características principais a capacidade de auto-renovação e a pluripotência. Durante o desenvolvimento, as células perdem seu potencial de diferenciação e adquirem um perfil de expressão gênica mais restrito, modulado por mecanismos epigenéticos, assim como por microRNAs. Membros da família miR-29 têm como transcritos alvos enzimas responsáveis pela metilação da citosina em 5mC (DNMT3a e 3b) e também da desmetilação (TET1, 2 e 3) do DNA, pela hidroxilação de 5mC em 5hmC. Recentes trabalhos sugerem que a modulação do miR-29 sobre estes alvos teria um papel no início da diferenciação em CTEs de camundongos e no aumento de eficiência da geração de iPS em células humanas. No presente trabalho, buscou-se compreender o papel regulatório do miR-29a em seus alvos epigenéticos no contexto da pluripotência e no início da diferenciação com atRA. Para tanto, duas linhagens celulares pluripotentes humanas (H1 e NTera- 2) foram submetidas a indução de diferenciação com atRA e ao ganho de função do miR-29a durante quatro dias de cultivo para análises de expressão gênica. Ademais, em NT2, realizamos ensaios funcionais por microscopia de imunofluorescência quantitativa para avaliar os efeitos do ganho e perda de função do miR-29a, DNMT3b e TET1, sobre a expressão nuclear de OCT4 e os perfis globais de 5mC e 5hmC após 96 horas de transfecção. Neste ensaio, também avaliamos o papel específico da regulação pós-transcricional de DNMT3b e TET1 pelo miR-29a, utilizando moléculas bloqueadoras dos sítios alvo (TSB) do miR-29a nestes transcritos. Observamos que sob a indução do atRA, os níveis de expressão do miR- 29a e de seus genes alvos (com exceção de DNMT3b), assim como dos marcadores de endoderme e ectoderme, aumentaram, seguido da diminuição dos marcadores de pluripotência em ambas as linhagens. A transfecção de moléculas mímicas do miR-29a, reduziu os níveis de seus transcritos alvos após dois e quatro dias em NT2 e H1, além de reduzir os níveis nucleares de DNMT3b em NT2. Ainda, ocorreu um aumento na expressão de genes da endoderme, mesoderme e ectoderme em H1 e a queda da expressão gênica e nuclear de OCT4 em NT2. Com o uso de siRNA específicos, demonstramos que o knockdown dos níveis nucleares de DNMT3b foi acompanhado de uma queda nos níveis globais de 5mC e um aumento de OCT4 e de 5hmC. Já o knockdown de TET1, elevou os níveis de 5mC, mas também os níveis de 5hmC e OCT4 nuclear. As avaliações com o uso de TSB contra os sítios de ligação do miR-29a em seus transcritos alvo, TET1 e DNMT3b, demonstraram que em células NT2, o bloqueio da ligação do miR endógeno aos seus alvos resultam no aumento dos níveis globais de 5hmC, indicando que a regulação póstranscricional destes alvos pelo miR-29 teria um importante papel na regulação epigenética de células pluripotentes. / Embryonic stem cells (CTEs), extracted from the internal cell mass of the blastocyst, are main characterized by the capacity for self-renewal and pluripotency. During development, the cells lose their differentiation potential and acquire a restricter gene expression profile, modulated by epigenetic mechanisms, as microRNAs. Members of the miR-29 family have as target transcripts enzymes for cytosine methylation in 5mC (DNMT3a and 3b) and for DNA demethylation (TET1, 2 and 3), by hydroxylation of 5mC in 5hmC. Recent studies suggest that the modulation of miR-29 on these targets plays a role in early differentiation of mouse CTEs and in increasing human iPS cell generation efficiency. In the present study, we sought to understand the regulatory role of miR-29a in its epigenetic targets in the context of pluripotency and in early differentiation with atRA. For this, two human pluripotent cell lines (H1 and NTera-2) were submitted to differentiation induction with atRA and function gain of miR-29a during four days of culture for gene expression analysis. Furthermore, in NT2, we performed functional assays by quantitative immunofluorescence microscopy to evaluate the gain- and loss-of-function of miR-29a, DNMT3b and TET1 in the OCT4 nuclear expression and global profiles of 5mC and 5hC, 96 hours posttransfection. In this assay, we also evaluated the specific role of post-transcriptional regulation of DNMT3b and TET1 by miR-29a, using target site blocking molecules (TSB) of miR-29a. We observed that under the induction of atRA, the miR-29a expression levels and its target genes (except of DNMT3b), further the markers of endoderm and ectoderm, increased, followed by decreased pluripotency markers in both cell lines. Transfection of mimic molecules of miR-29a reduced the levels of their target transcripts after two and four days in NT2 and H1, and reduced nuclear levels of DNMT3b in NT2. In addition, the expression of endoderm, mesoderm and ectoderm genes increased in H1 and gene and nuclear expression of OCT4 decreased in NT2. With the use of specific siRNA, we demonstrated that the knockdown of nuclear levels of DNMT3b was accompanied by a drop in global 5mC levels and an increase of OCT4 and 5hmC. While, the knockdown of TET1 increased the levels of 5mC, 5hmC and nuclear OCT4. Evaluations using TSB against the miR- 29a binding sites in their target transcripts, TET1 and DNMT3b, show that in NT2 cells blocking the binding of endogenous miR to their targets results in an increase in global 5hmC levels, indicating that the post-transcriptional regulation of these targets by miR-29 would play an important role in the epigenetic regulation of pluripotent cells.
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DNA Methylation and Gene Expression Profiling for Parkinson’s Biomarker DiscoveryJanuary 2019 (has links)
abstract: Parkinson’s disease (PD) is a progressive neurodegenerative disorder, diagnosed late in
the disease by a series of motor deficits that manifest over years or decades. It is characterized by degeneration of mid-brain dopaminergic neurons with a high prevalence of dementia associated with the spread of pathology to cortical regions. Patients exhibiting symptoms have already undergone significant neuronal loss without chance for recovery. Analysis of disease specific changes in gene expression directly from human patients can uncover invaluable clues about a still unknown etiology, the potential of which grows exponentially as additional gene regulatory measures are questioned. Epigenetic mechanisms are emerging as important components of neurodegeneration, including PD; the extent to which methylation changes correlate with disease progression has not yet been reported. This collection of work aims to define multiple layers of PD that will work toward developing biomarkers that not only could improve diagnostic accuracy, but also push the boundaries of the disease detection timeline. I examined changes in gene expression, alternative splicing of those gene products, and the regulatory mechanism of DNA methylation in the Parkinson’s disease system, as well as the pathologically related Alzheimer’s disease (AD). I first used RNA sequencing (RNAseq) to evaluate differential gene expression and alternative splicing in the posterior cingulate cortex of patients with PD and PD with dementia (PDD). Next, I performed a longitudinal genome-wide methylation study surveying ~850K CpG methylation sites in whole blood from 189 PD patients and 191 control individuals obtained at both a baseline and at a follow-up visit after 2 years. I also considered how symptom management medications could affect the regulatory mechanism of DNA methylation. In the last chapter of this work, I intersected RNAseq and DNA methylation array datasets from whole blood patient samples for integrated differential analyses of both PD and AD. Changes in gene expression and DNA methylation reveal clear patterns of pathway dysregulation that can be seen across brain and blood, from one study to the next. I present a thorough survey of molecular changes occurring within the idiopathic Parkinson’s disease patient and propose candidate targets for potential molecular biomarkers. / Dissertation/Thesis / Doctoral Dissertation Molecular and Cellular Biology 2019
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MULTIGENERATIONAL GENOMIC AND EPIGENETIC EFFECTS OF MANUFACTURED SILVER NANOMATERIALS IN <em>CAENORHABDITIS ELEGANS</em>Wamucho, Anye 01 January 2019 (has links)
There has been an increase in the incorporation of silver nanomaterials into consumer products due to their antimicrobial properties. Therefore there is potential for silver nanoparticles (Ag-NPs) to leach out into the environment during different life-cycle stages of these nanomaterial-containing products. Concern about the toxicity of Ag-NPs has led to investigations into their toxic effects on a variety of organisms mainly using acute and sub-chronic, single-generation exposures. The focus of this project was to understand the effects of long-term continuous multigenerational exposure to AgNO3 and Ag-NPs in both pristine and environmentally transformed forms, on the model organism, Caenorhabditis elegans, a soil nematode.
A previous multigenerational C. elegans study, showed increased sensitivity in terms of reproductive toxicity, in response to AgNO3 and Ag-NPs, but not sulfidized Ag-NPs (sAg-NPs), with increasing generations of exposure. The reproductive toxicity persisted in subsequently unexposed generations even after rescue from the exposure. We hypothesized that genomic mutations and/or epigenetic changes were possible mechanisms by which the reproductive toxicity was inherited. We investigated the potential for induction of germline mutations in C. elegans after exposures for ten generations to AgNO3, Ag-NPs, and sAg-NPs using whole genome DNA sequencing. Epigenetic changes at histone methylation markers, (H3K4me2 and H3K9me3), and DNA methylation at adenosine (N6-methyl-2’-deoxyadenosine) were investigated after multigenerational exposure as well as after rescue from the exposure using enzyme-linked immunosorbent assays (ELISA) and liquid chromatography with tandem mass spectrometry (LC-MS/MS), respectively. Expression levels of the genes of methyltransferases and demethylases, associated with the histone methylation markers and DNA methylation, were also examined.
Our results for germline mutations reveal no significant differences between the nematodes exposed to AgNO3 or pristine Ag-NPs when compared to controls. The significant increase in the number of transversion was observed only for sAg-NPs. However, a trend toward an increase in the total number of mutations was observed in all Ag treatments with some of those mutations having a predicted moderate or high impact. This potentially contributed towards reproductive as well as growth toxicity shown previously after ten generations of exposure in every treatment.. These results did not entirely support the multigenerational reproductive toxicity observed previously. Epigenetic responses at histone methylation markers revealed opposite patterns between pristine and transformed Ag-NPs with Ag-NPs causing a significant increase while exposure to sAg-NPs resulted in significant decrease in methylation at H3K4me2 mark. The increase in H3K4me2 levels was also inherited by subsequent unexposed generations rescued from Ag-NP exposure. Only sAg-NPs caused a significant decrease in methylation at H3K9me3 mark. Changes in mRNA levels for histone methyltransferases and demethylase corresponded with the histone methylation levels affected by Ag-NPs and sAg-NPs. For DNA methylation, a significant increase was observed only for AgNO3, which was not inherited after the rescue.
In conclusion, while germline mutations with a high or moderate impact may affect reproduction, our results do not support this as a mechanism for the heritable increase in C. elegans sensitivity to reproductive toxicity from AgNO3 and pristine Ag-NPs. The epigenetic changes, however, do show partial correlation with the observed reproductive toxicity. The reproductive multigenerational effects of AgNO3 can be attributed to changes in DNA methylation whereas that of Ag-NPs can be attributed to changes in histone methylation. Further studies, focused on the investigation of changes in histone and DNA methylation levels at specific loci using chromatin immunoprecipitation sequencing (ChIP-Seq) and methylated DNA immunoprecipitation sequencing (MeDIP-Seq), respectively, are warranted for a better understanding of the impact of such changes.
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An Analysis of Between-Cow Variation in Innate Immunity in Relation to Mastitis SeverityKorkmaz, Filiz 01 January 2018 (has links)
Bovine mastitis remains one of the costliest diseases affecting the dairy industry. Individual susceptibility to mastitis and severity of infection varies between animals and can only be partially explained by genetics. As such, understanding how genetic predisposition coordinately interacts with epigenetic modifications and environmental exposures is necessary to bridge the gap in missing heritability. The role of DNA methylation in regulating the response to bacterial lipopolysaccharide (LPS) was first determined by performing reduced representation bisulfite sequencing on fibroblasts isolated from heifers at 5- and 16-months of age that exhibit an age-dependent up-regulation in LPS-responsiveness. More than 14,000 differentially methylated sites were identified between the two sets of cultures with a trend towards decreased methylation with age. Young cultures were also hyper-methylated in gene promoters regulated by NF-κB and exhibited lower expression in genes that regulate the innate immune response, suggesting that methylation contributes to gene regulation in fibroblast innate response.
Previously, TLR4 expression was shown to differ in the age-dependent fibroblast model, however, it was not known if variation in TLR4 expression would affect mastitis severity. Therefore, fibroblasts were isolated from sixty lactating, adult Holstein cows and their expression of TLR4, along with LPS-induced production of IL-8 and IL-6, was used to rank the animals from high to low. Six high responders and six low responders were then experimentally infected in one mammary gland with E. coli. Overall, severity of mastitis was quite variable, with a few notable differences between high and low responders. High responding animals had an earlier increase in somatic cell count and febrile response that coincided with more efficient bacterial clearance. However, tissue damage and milk production did not differ between the two groups, indicating that while rapid up-regulation of the innate response addresses bacterial clearance, subsequent down-regulation is required to alleviate damage within the mammary gland.
Finally, one-week old bull calves were subjected to treatment with either saline or LPS to determine if neonatal exposure to endotoxin would make calves less responsive to a second LPS challenge at 32-days of age. The initial treatment showed a large effect of LPS as measured by higher plasma IL-6 and TNF-α concentrations in calves treated with LPS over saline. Subsequent treatment of all 10 calves with LPS showed a very similar response between the two treatment groups and significant inter-animal variability in clinical response. Fibroblasts and monocyte-derived-macrophages (MDMs) were also isolated following initial treatment to determine if any changes occurred at the cellular level as a result of LPS exposure. Fibroblasts isolated from calves at 20-days of age had a very low response to LPS that did not differ between the early life treatments. MDMs isolated from calves at 28-days of age were more responsive to LPS, but again no differences were detected between the early life treatments. In summary, our results suggest that DNA methylation likely plays a role in the cellular response to LPS and may partially contribute to differences between animals in severity of E. coli mastitis, however, the appropriate in vitro phenotype to detect susceptible animals still needs to be characterized before epigenetic biomarkers can be identified, and perhaps modified by environmental interventions.
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Molecular mechanisms of skeletal muscle atrophyEbert, Scott Matthew 01 December 2012 (has links)
Skeletal muscle atrophy is a common and often debilitating complication of diverse stresses including muscle disuse, fasting, aging, critical illness and many chronic illnesses. However, the pathogenesis of muscle atrophy is still poorly understood. The thesis herein describes my studies investigating the molecular mechanisms of skeletal muscle atrophy. Using mouse skeletal muscle and cultured skeletal myotubes as experimental systems, I discovered a novel stress-induced pathway in skeletal muscle that causes muscle atrophy.
The pathway begins with stress-induced expression of ATF4, a basic leucine zipper (bZIP) transcription factor with an evolutionarily ancient role in cellular stress responses. I found that diverse stresses including fasting and muscle disuse increase expression of ATF4 in skeletal muscle. ATF4 then activates the growth arrest and DNA damage-inducible 45a (Gadd45a) gene, leading to increased expression of Gadd45a protein, an essential and inducible subunit of DNA demethylase complexes. Gadd45a localizes to skeletal myonuclei where it interacts with and stimulates demethylation of a specific region in the promoter of the cyclin dependent kinase inhibitor 1a (Cdkn1a) gene. By demethylating the Cdkn1a promoter, Gadd45a activates the Cdkn1a gene, leading to increased expression of Cdkn1a protein, also known as p21WAF1/CIP1. Cdkn1a stimulates protein breakdown (a critical pro-atrophy process) and inhibits anabolic signaling, protein synthesis and PGC-1α expression (processes that maintain healthy skeletal muscle and protect against atrophy). As a result, Cdkn1a causes skeletal muscle fibers to undergo atrophy.
Importantly, interventions that reduce any one component of this pathway (ATF4, Gadd45a or Cdkn1a) reduce skeletal muscle atrophy during fasting, muscle disuse, and perhaps other skeletal muscle stresses such as illness and aging. Conversely, forced expression of any one component of this pathway is sufficient to cause skeletal muscle fiber atrophy in the absence of upstream stress. These data suggest the ATF4/Gadd45a/Cdkn1a pathway as a potential therapeutic target.
Collectively, my studies demonstrate that the sequential, stress-induced expression of ATF4, Gadd45a and Cdkn1a is a critical process in the pathogenesis of skeletal muscle atrophy. This significantly advances our understanding of how muscle atrophy occurs and it opens up new avenues of investigation into the causes and treatment of muscle atrophy.
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Rôles des variations épigénétiques transgénérationnelles dans la résistance quantitative à la hernie chez Arabidopsis thaliana / Role of the transgenerational epigenetic variation in quantitative resistance to clubroot in Arabidopsis thalianaLiegard, Benjamin 09 November 2018 (has links)
Des études récentes ont montré que la variabilité de l’épigénome des plantes est un acteur important dans la réponse des plantes aux stress abiotiques et biotiques. La hernie, causée par le protiste Plasmodiophora brassicae, est une maladie racinaire majeure des Brassicaceae cultivées dont la résistance quantitative est considérée comme résultant principalement de la ségrégation de multiples allèles. L'objectif de ma thèse est d'établir s'il existe, chez Arabidopsis thaliana, une variabilité épigénétique héritable à l'origine de variations de la réponse à l’infection par la hernie. Pour répondre à cet objectif, une approche non ciblée d’épigénétique quantitative a été réalisée en utilisant la population épiRIL ddm1-2 x Col-0. Dix-sept QTL sous contrôle épigénétique (QTLépi), regroupés en 6 régions génomiques, ont ainsi été détectés, 5 d’entre eux étant sous la dépendance de la température.Finalement, deux régions identifiées comme impliquées dans la réponse à la hernie ont été caractérisées plus finement. La région du gène majeur de résistance à la hernie RPB1, qui colocalise avec 3 QTLépi, présente une variation génomique prépondérante dans les écotypes d’Arabidopsis potentiellement due à des mouvements d’éléments transposables. Le QTL Pb-At5.2 est sous le contrôle d’une épimutation régulant l’état de méthylation et l’expression de deux gènes NLR. Les résultats obtenus montrent que la résistance quantitative à la hernie est associée à des variations de la méthylation de l’ADN stables et héritables suggérant un modèle complexe de régulation de la résistance où la combinai / Recent studies have shown that plant epigenome variability is an important factor in plant response to abiotic and biotic stress. Clubroot caused by the protist Plasmodiophora brassicae is a major disease of Brassicaceae whose quantitative resistance is supposed to result from many allele segregation. The aim of my work is to understand if, in Arabidopsis thaliana, an inherited epigenetic variability can lead to variations in clubroot resistance. For that, an untargeted approach of quantitative epigenetics was carried out using the epiRIL population ddm1-2 x Col-0. Seventeen QTL under epigenetic control (QTLepi), clustered in 6 genomic regions, were detected, 5 of them being temperature-dependant.Finally, two regions previously identified as involved in clubroot response were finely studied. The region of the major clubroot resistance gene RPB1, which colocalizes with three QTLepi, shows major genomic variations in Arabidopsis ecotypes potentially due to movements of transposable elements. The QTL Pb-At5.2 is depending on one epimutation controlling the methylation state and the expression of two NLR genes. The results obtained demonstrate that the clubroot quantitative resistance is associated with inherited stable DNA methylation variations suggesting a complex model of resistance regulation where favourable alleles and epialleles association is necessary to obtain an optimal resistance.
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Etude des voies de silencing transciptionnel indépendantes de la méthylation ADN chez Arabidopsis thaliana / Study of transcriptional gene silencing pathways independent of DNA methylationBourguet, Pierre 07 December 2018 (has links)
Le silencing transcriptionnel limite la transcription des gènes et des éléments transposables dont l’expression pourrait être délétère à la cellule. Il dépend d’une diversité de modifications de la chromatine comme la méthylation ADN ou les marques répressives des histones. De façon à mieux comprendre les mécanismes moléculaires à l’origine du silencing transcriptionnel, nous avons mené une approche de génétique directe à l’aide d’un transgène soumis au silencing dans la plante modèle Arabidopsis thaliana. Cette stratégie nous a permis d'isoler à la fois des mutants déficients pour le maintien du silencing transcriptionnel et des mutations qui empêchent la réactivation transcriptionnelle des éléments transposables en réponse à un stress thermique. Nous avons caractérisé les défauts provoqués par ces mutations en combinant des approches de biologie moléculaire, de cytologie et de génomique.Nous montrons ainsi que MED14, la sous-unité centrale du complexe Mediator, et UVH6, composant du complexe TFIIH, sont requis pour la transcription de l'hétérochromatine en stress thermique. MED14 stimule aussi la transcription de l'hétérochromatine en l'absence de stress, mais ne semble fonctionner qu'en présence de la méthylation ADN. En plus de cette fonction originale, nous identifions un nouveau rôle de MED14 dans le maintien de la méthylation ADN, possiblement via la voie de méthylation ADN dirigée par les petits ARN.Par ailleurs, nos résultats nous ont permis d’identifier le rôle des protéines MAIN et MAIL1, qui définissent une voie de silencing transcriptionnelle indépendante des voies connues jusqu'alors. De façon intéressante, MAIN et MAIL1 possèdent un domaine protéique partagé avec les éléments transposables, qui aurait successivement été capturé par les éléments transposables et leur hôte au cours de l’histoire évolutive des plantes à fleurs.Enfin, en isolant une nouvelle mutation du gène POL2A, nous confirmons le rôle de l’ADN polymérase epsilon dans le silencing transcriptionnel et caractérisons les propriétés chromatiniennes qui dépendent de POL2A. Nous montrons que les défauts de silencing des mutants pol2a corrèlent avec une désorganisation importante de l’hétérochromatine sans diminution drastique des marques qui y sont associées. Au contraire, nous détectons une hyperméthylation ADN prononcée dans le mutant, et explorons différentes hypothèses pour expliquer ce phénotype particulier. Nos données suggèrent que plusieurs mécanismes moléculaires sont à l’origine des défauts des mutants pol2a. Elles confirment le rôle prépondérant de la chromométhylase CMT3 dans la régulation de la méthylation ADN, et suggèrent qu’un stress réplicatif pourrait causer une hyperméthylation de l’ADN.Dans l’ensemble, ces travaux de thèse proposent des pistes de travail dont l’exploration pourrait permettre d’expliquer les effets des déficiences réplicatives dans le maintien du silencing transcriptionnel et de l’homéostasie de la méthylation ADN. Ils suggèrent en outre que MED14 a une fonction dédiée à la transcription de l’hétérochromatine qui pourrait stimuler le maintien de la méthylation ADN. / Transcriptional gene silencing hinders deleterious transcription of some genes and transposable elements. Silencing is maintained by numerous chromatin modifications such as DNA methylation and repressive histone marks. To better understand the molecular mechanisms of silencing, we conducted a forward genetic screen using a transgene reporter system targeted by transcriptional gene silencing in the model plant Arabidopsis thaliana. We isolated a first type of mutants with diminished maintenance of silencing and a second category that displayed deficient release of transgene silencing upon heat stress. We then combined molecular, cytological and genomic methods to characterize the defects associated with these mutations.First, we show that the Mediator subunit MED14 and the TFIIH complex subunit UVH6 are required for heat-stress-induced release of silencing. We further show that MED14, but not UVH6, promotes transcriptional activation of transposable elements in mutant contexts where silencing is defective. Importantly, MED14 is only required when DNA methylation is not affected, suggesting that MED14 has a specialized function to promote transcription of heterochromatin. Furthermore, we show that MED14 promote DNA methylation at targets regulated by RNA-directed DNA methylation.Characterizing mutants from the first category, we unveil the contribution of the MAIN and MAIL1 proteins into transcriptional gene silencing, and show that they likely act through a pathway independent of known silencing factors. Interestingly, MAIN and MAIL1 bear a protein domain that is shared with transposable elements, and that has been captured by transposable elements and genes throughout the evolutionary history of flower plants.Additionally, we confirm the involvement of the DNA polymerase epsilon in transcriptional gene silencing by isolating a new mutation of the POL2A gene among mutants of the first category. We characterize the effects of the pol2a mutation on several heterochromatin properties, and show that the pol2a mutant retains high levels of heterochromatin marks despite having highly disorganized heterochromatin. We actually detect a strong elevation of DNA methylation in the pol2a mutant and explore different hypothesis to explain this unusual phenotype. We show that increased expression of the CMT3 chromomethylase is a likely cause, but that additional molecular mechanisms are probably involved. Further exploration suggests that constitutive replicative stress occurring in pol2a mutants could be an additional cause of DNA hypermethylation.To summarize, this work provide putative causes for DNA hypermethylation and silencing defects in a situation of replicative deficiency. Further investigation will be required to identify the molecular components involved in the mechanism. Our data further suggest that MED14 has a function dedicated to heterochromatin transcription that could promote DNA methylation maintenance.
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Epigenetic changes in breast cancerHinshelwood, Rebecca, Garvan Institute of Medical Research, UNSW January 2009 (has links)
Changes in the epigenetic landscape are widespread in neoplasia, with de novo methylation and histone repressive marks commonly occurring in association with gene silencing. However, understanding the dynamics of epigenetic changes is often hindered due to the absence of adequate in vitro model systems that accurately reflect events occurring in vivo. Human mammary epithelial cells (HMECs) grown under standard culture conditions enter a growth arrest termed selection, but a subpopulation is able to escape from arrest and continue to proliferate. These cells, called post-selection cells, have many of the hallmarks seen in the earliest lesions of breast cancer, including transcriptional silencing and hypermethylation of the p16INK4A tumour suppressor gene. The overall aim of my thesis was to use post-selection HMECs as model system to identify and dissect the mechanism involved in early epigenetic aberrations. Firstly, using a microarray approach, I found that multiple members of the TGF-β signalling pathway were concordantly suppressed in post-selection cells, and this was associated with functional disruption of the TGF-β pathway. Interestingly, concordant gene suppression was not associated with aberrant DNA methylation, but with repressive chromatin remodelling. Secondly, to further understand the mechanism underpinning epigenetic silencing, I demonstrated using laser capture technology, that p16INK4A silencing is a precursor to DNA methylation and histone remodelling. Thirdly, I found that individual post-selection HMEC strains during the early passages shared a common 'wave' pattern of regional-specific methylation within the p16INK4A CpG island. Interestingly, the 'wave' pattern of early de novo methylation correlated with the apparent footprint of nucleosomes within the p16INK4A CpG island. Lastly, to further characterise the properties of the HMEC culture system, I demonstrated that post-selection cells do not possess a natural tumour-inducing property when transplanted into the mammary fat pad of immunocompromised mice. However, post-selection HMECs were associated with high expression of a variety of stem/progenitor markers, as well as stem/progenitor associated polycomb genes, thus demonstrating that these cells share some common features of stem/progenitor cells. The research presented in this thesis demonstrate that epigenetic changes occur early in the growth of post-selection HMECs and many of these changes are common in breast cancer.
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Phase variable methyltransferases and their role in gene regulation in pathogenic bacteriaStefanie Dowideit Unknown Date (has links)
Previous work carried out in our laboratory has identified that phase variation of type III R-M systems found in Haemophilus influenzae, Neisseria meningitidis and N. gonorrhoeae is reversible, and occurs at high frequency, as seen both through mod::lacZ fusions, and by measuring changes in repeat tract length. In addition, phase variation of the methyltransferases results in coordinated switching of expression of a distinct group of genes in each of the strains studied so far. WE have termed this phenomenon the PHASEVARION, for phase variable regulon, to identify the set of genes whose expression is affected by moe phase variation. Many of the genes found to be regulated by mod phase variation are known virulence factors and even include some genes investigated as candidates for vaccine development (Srikhanta et al., 2005 and 2009. The aims of this project was to further the investigation of how these R-M systems regulated the expression of genes which hitherto had not been predicted to phase vary. The first step in the process of investigating how phase variable R-M systems influence expression of unrelated genes is to identify the DNA sequences methylated by the methyltransferases of interest. As discussed in Chapter 3, elucidation of the ModA1 methylation target site was in part facilitated by predictions that the phase variable methyltransferase found in H. influenzae strain Rd methylated the same sequence as did HinfIII, isolated from H. influenzae strain Rf. This hypothesis was confirmed by methylation dependent inhibition of digestion, revealing that ModA1 methylates the second A in its recognition sequence, 5’-CGAAT-3’. Once confirmed, the genes found to be regulated by modA1 phase variation in the initial phasevarion study could be investigated for the presence of ModA1 methylation sites within their promoters or upstream of their transcriptional regulators. Two such methylation target sites were located just upstream of the dnaK ORF. Transcriptional start site analysis of the dnaK gene revealed three transcripiotnal start sites, one of which is unduced by heat shock. Exactly 10 nucleotides upstream of this heat shock induced transcriptional start site lies one of these ModA1 methylation target sequences. Ongoing invetigations are looking into the importance of this ModA1 site located within the dnaK promoter, and whether this is the site responsible for ModA1 dependent variations in dnaK expression. Although numerous methods were investigated for their potential to identify all sites methylated by the different modA alleles, the only method which resulted in identification of any methylation target sites was methylation dependent inhibition of restriction. This method allowed us to confirm the ModA1 recongition sequence, and to discover the methylation sequence, and adenine targeted by the modA13 allele, which is found in many clinically relevant N. gonorrhoeae strains. As will be discussed in Chapter 5, ModA13 dependent inhibition of restriction was first observed when the Neisserial plasmid pCmGFP was extracted from modA13 ON and modA13::kan cells, and further investigated and confirmed using a Southern blot approach to determine whether ModA13 dependent inhibtion could be detected as differential methylation of the chromosome. It was found that ModA13 recognised the sequence 5’-AGAAA-3’, with methylation occurring on the second last A. This sequence was mapped not only to the genes found to be regulated by modA13 phase variation, but also to the entire FA1090 chromosome, and this information will be used in future studies to investigate the direct molecular mechanisms by which modA13 phase variation results in subpopulations with different phenotypes in relation to antimicrobial resistance and biofilm/cell invasion.
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Transcriptional Silencing in the Imprinted <i>Igf2-H19</i> Loci: The Mystique of EpigeneticsGinjala, Vasudeva January 2002 (has links)
<p>Genomic imprinting marks a subset of autosomal loci expressed in parent of origin-dependent monoallelic expression in a non-Mendelian fashion. To restore totipotency and to reset the imprint according to the sex of the individual, the mark must be erased during germline development. The imprinted <i>Igf2-H19</i> loci located distally on chromosome 7 in mouse and 11p15.5 in human, share common regulatory elements that regulate differential expression. Where the <i>H19 </i>is silenced when paternally inherited, the <i>Igf2</i> is silenced when maternally inherited. </p><p>The differentially methylated 5'-flank of <i>H19</i> gene, termed imprinting control region (ICR), shown to display a unique chromatin organisation harbours hypersensitive sites in linker regions flanked by positioned nucleosomes on the maternal allele. This unique chromatin conformation functions as a methylation-sensitive and unidirectional chromatin insulator, which later was found to depend on the chromatin insulator protein CTCF. </p><p>The <i>H19</i> ICR exhibits default-silencing functions in promoter-proximal positions. The maximal distance between the <i>H19</i> ICR and the promoter of the reporter gene required for this effect was 1.2 ± 0.3kb which can be compared to the 1.9 kb distance between the endogenous <i>H19 </i>ICR and <i>H19</i> promoter. Results suggest that the <i>H19</i> ICR adopts a chromatin conformation that must be separated by a minimal distance from pivotal <i>cis</i>-regulatory elements to avoid adverse effects on neighbouring promoters. </p><p>Poly(ADP-ribosy)lation represents a novel post-translational epigenetic mark that segregates with exclusively the maternal derived <i>H19</i> ICR and associated with factors that interact with the CTCF target sites. CTCF is itself poly(ADP-ribosy)lated and the poly(ADP-ribose) polymerase inhibitor 3-aminobenzamide relieves the insulator function of the <i>H19</i> ICR. </p><p>Designed zinc finger proteins were applied to examine if epigenetic marks provided an obstacle for targeted activation and silencing. The zinc finger protein ZFP809 with activator/repressor domain able to efficiently activate/silence the <i>IGF2</i> target. Murine hybrid cell lines of human chromosome 11, demonstrated that the ZFP809 overcame the epigenetic marks that repressed maternal <i>IGF2</i> and paternal <i>H19</i> allele, respectively. Results suggested that imprinted genes are not normally exposed to strong <i>cis</i>-regulatory elements and that the designed ZFPs can be exploited to develop a therapeutic method for rectifying epigenetic lesions.</p>
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