Global ETD Search

21	ROLE OF TET2 IN LUMINAL DIFFERENTIATION AND HORMONE THERAPY RESPONSE IN BREAST CANCER Mi Ran Kim (8066174) 03 December 2019 (has links) <p>Epigenetic mechanisms, including DNA methylation, play an important role in regulation of stem cell fate and tumorigenesis. The Ten-Eleven-Translocation 2 (TET2) is a core enzyme for DNA demethylation by catalyzing the conversion of 5-methylcytosine (5mC) to 5-hydromethylcytosine (5hmC). It has been shown that TET2 is the main regulator of hematopoietic stem cell homeostasis and loss of TET2 is highly associated with hematopoietic malignancies. Our previous work has also shown that loss of TET2 expression is linked to promotion of an epithelial-mesenchymal-transition phenotype and expansion of a breast cancer stem cell-like population with skewed asymmetric cell division in vitro; however, the in vivo role that TET2 plays in regulation of mammary stem cell (MaSC) fate and development of mammary pathology has yet to be determined. Here, using our newly established mammary-specific Tet2-knockout mouse model, the data reveals for the first time that TET2 plays a pivotal role in mammary gland development via directing MaSC to luminal lineage commitment in vivo. Furthermore, we find that TET2 coordinates with FOXP1 to target and demethylate FOXA1, GATA3, and ESR1, key transcription factors that orchestrate mammary luminal lineage specification and endocrine response and are often silenced by DNA methylation in aggressive human breast cancers. Finally, loss of TET2 expression leads to promotion of mammary tumor development with defective luminal cell differentiation and tamoxifen resistance in a PyMT;Tet2 deletion breast cancer mouse model. As a result, this study provides a previously unidentified role for TET2 in governing luminal lineage specification and endocrine response that underlies resistance to anti-estrogen treatments.</p> Cancer Cell Biology Mammary stem cell Epigenetics, DNA demethylation Luminal differentiation TET2 FOXP1 Breast cancer
22	Somatic and Germline Disruption of Protein Phosphatase 2A in Cancer: Challenges of Using Established Tools to Study PP2A Inhibition Mazhar, Sahar 01 June 2020 (has links) No description available. Biomedical Research Oncology Genetics PP2A antibody validation PP2Ac cancer predisposition PP2Ac demethylation germline variant
23	A Comprehensive View of the Epigenetic Landscape Part I: DNA Methylation, Passive and Active DNA Demethylation Pathways and Histone Variants Sadakierska-Chudy, Anna, Kostrzewa, Richard M., Filip, Małgorzata 01 January 2015 (has links) In multicellular organisms, all the cells are genetically identical but turn genes on or off at the right time to promote differentiation into specific cell types. The regulation of higher-order chromatin structure is essential for genome-wide reprogramming and for tissue-specific patterns of gene expression. The complexity of the genome is regulated by epigenetic mechanisms, which act at the level of DNA, histones, and nucleosomes. Epigenetic machinery is involved in many biological processes, including genomic imprinting, X-chromosome inactivation, heterochromatin formation, and transcriptional regulation, as well as DNA damage repair. In this review, we summarize the recent understanding of DNA methylation, cytosine derivatives, active and passive demethylation pathways as well as histone variants. DNA methylation is one of the well-characterized epigenetic signaling tools. Cytosine methylation of promoter regions usually represses transcription but methylation in the gene body may have a positive correlation with gene expression. The attachment of a methyl group to cytosine residue in the DNA sequence is catalyzed by enzymes of the DNA methyltransferase family. Recent studies have shown that the Ten-Eleven translocation family enzymes are involved in stepwise oxidation of 5-methylcytosine, creating new cytosine derivatives including 5-hydroxymethylcytosine, 5-formylcytosine, and 5-carboxylcytosine. Additionally, histone variants into nucleosomes create another strategy to regulate the structure and function of chromatin. The replacement of canonical histones with specialized histone variants regulates accessibility of DNA, and thus may affect multiple biological processes, such as replication, transcription, DNA repair, and play a role in various disorders such as cancer. cytosine variants DNA methylation DNA methyltransferases histone variants passive and active demethylation TET family enzymes Biomedical Sciences
24	Involvement of DNA Methylation and CpG Endonuclease Activity in Environmental Carcinogenesis and Cancer Chemoprevention Li, Long 16 May 2006 (has links) No description available. Biology, Molecular DNA Methylation Demethylation Carcinogenesis Loss of Imprinting Cancer Chemoprevention Environmental Carcinogens
25	Chemical methods to increase the reactivity of lignin : In the context of green chemistry and education for sustainable development Birgersson, Erica January 2015 (has links) The research concerning lignin in high value applications has increased during the last years due to its renewability and availability in the black liquor from pulp mills. Today the major part of kraft lignin found in the black liquor is used as fuel to gain energy in the recovery boiler. Lignin functions as natural glue in plants so that the function of kraft lignin as a phenol replacement in wood adhesives has been researched. Due to lignin's low reactivity the molecule must be modified prior to use. Demethylation is a method to increase the phenolic content in lignin to produce more reactive sites. Thiol mediated and iodine mediated demethylation was performed. Demethylated lignin was characterized by changes in phenolic and hydroxylic groups, molecular mass, elemental composition and other properties using methods including UV, SEC and 31 P NMR. The results showed a decrease in the phenolic content contrary to the increase that was expected. Really low yields were also gained which makes the results non-representative. Size evaluation showed that the percentage of high molecular content in the demethylated lignin sample had increased, which point towards the loss of low molecular mass fractions. Due to demethylation lignin may have been more hydrophilic and soluble in DMF and water. In addition to this bond cleavage may have produced smaller fragments which also increase the solubility. The results point towards the loss of smaller fragments in the DMF and water phases. The applied demethylation methods were evaluated in context of green chemistry. Production, waste, involving chemicals and efficiency were discussed and analyzed. The applied demethylation methods use DMF as solvent which is not a green alternative, greener solvents such as water or other energy adding methods could be used to make the process greener. The use ofNaOMe produces methanol as a byproduct which could be eliminated by using NaOH, future studies on the efficiency of the bases in the needs to be done. Nature science has a reputation of being hard and firm. By bringing in social issues in science education new ways of looking at science opens up. A social problem and at the same time an environmental problem in today's society is the large plastic mountain in the Pacific Ocean. An educational material of the "Samhallsfragor med Naturvetenskapligt Innehiill",SNI, (Societal issues with scientific content) principle has been evaluated with respect to the abilities that can developed together with whether students increase their science knowledge through this. The study showed that students can develop almost all abilities described in the curriculum and their knowledge in science by this type of material. Keywords Biomaterial, lignin reactivity, thiol mediated demethylation, iodine mediated demethylation, green chemistry, SNl-fall. / Forskning kring lignin i produkter har ökat under de senaste åren på grund av lignins fornyelsebarhet och tillganglighet i svartluten från massabruken. Idag används den största delen av sulfatligninet från svartluten som bränsle for att producera energi i sodapannan. Lignin fungerar som ett naturligt lim i växter och på grund av detta undersöks funktionen av kraftlignin som fenolersättning i trälim. Med anledning av ligninmolekylens låga reaktivitet behover lignin modifieras fore användning i produkter. Demetylering är en metod för att öka fenolhalten i lignin och skapa en högre reaktivitet. I denna studie utfördes Tiolmedierad och jodidmedierad demetylering. Det demetylerade ligninet utvärderades med avseende på forändringar i fenol-och hydroxylgrupper, molekylvikt, elementarsammansättning och andra egenskaper med hjälp av olika metoder,inklusive UV, SEC och 31 P NMR. Resultaten visade en minskning i fenolinnehall i motsats till den ökning som förväntades. Riktigt låga utbyten påvisades också vilket gör att resultaten inte är representativa. Storleksutvärdering visade att andelen med högt molekylviktsinnehåll i det demetylerade ligninproven hade ökat, vilket pekar mot förlust av lågmolekylära fraktioner. På grund av demetyleringen kan ligninet ha blivit mer hydrofilt och lösligt i DMF och vatten. Utöver detta kan bindningsklyvning ha skapat mindre fragment som också ökat lösligheten. Resultaten pekar mot förlust av mindre fragment i DMF-och vattenfaserna. De tillämpade demetyleringsmetoderna utvärderades med avseende på grön kemi. Produktion, avfall, kemikalier och effektivitet diskuterades och analyserades. De tillämpade demetyleringsmetoderna använder DMF som lösningsmedel, vilket inte är ett grönt alternativ. Grönare lösningsmedel såsom vatten, eller andra typer av energitillsättning, kan användas för att göra processen miljövänligare. Användandet av NaOMe i den thiolmedierade demethyleringen skapar metanol som en biprodukt vilket kan bytas ut mot vatten om NaOH istället används. Vidare studier behöver göras för att undersöka de båda baserna effektivitet. Naturvetenskapen har ett rykte om att vara hård och fast. Genom att föra in sociala frågor i den naturvetenskapliga utbildningen kan nya sätt att se på vetenskapen skapas. Ett samhälls problem och samtidigt ett miljöproblem i dagens sämhalle är det stora plast berget i Stillahavet. Ett undervisningsmaterial för"Samhällsfrågor Med Naturvetenskapligt Innehåll", SNI, principen har utvärderats med avseende på vilka förmågor som kan tränas tillsammans med huruvida eleverna kan öka sin vetenskapliga kunskap. Studien visade att eleverna kan utveckla nästan alia formågor som beskrivs i läroplanen och sina kunskaper inom naturvetenskapen genom denna typ av utbildningsmaterial. Nyckelord Biomaterial, ligninreaktivitet, tiol medierad demetylering, jodmedierad demetylering,grön kemi, SNI-fall. Biomaterial lignin reactivity thiol mediated demethylation iodine mediated demethylation green chemistry SNl-fall. Biomaterial lignin reaktivitet tiol medierad demetylering jod medierad demetylering gron kemi SNI-fall Chemical Sciences Kemi
26	Régulation réciproque et coopération transcriptionnelle du complexe ERRalpha-LSD1 / An interactive network between ERRα-LSD1 promotes gene transcription via H3K9 demethylation Carnesecchi, Julie 07 October 2014 (has links) Les récepteurs nucléaires sont des facteurs de transcription qui exercent leur fonction via le contrôle de la transcription de leurs gènes cibles, une régulation qui est dépendante de cofacteurs associés. Les complexes transcriptionnels ainsi formés dialogueront avec l’environnement chromatinien (méthylation de l’ADN, remodelage des nucléosomes, modifications post-traductionnelles des histones) afin de promouvoir la répression ou l’activation transcriptionnelle des cibles géniques de ces récepteurs. Ce projet a identifié une interaction entre la lysine déméthylase LSD1 et le récepteur nucléaire orphelin ERRα dans des cellules humaines de cancers du sein. LSD1 protège ERRα d’une dégradation protéasomale de manière indépendante de son activité catalytique. Par ailleurs, LSD1 déméthyle H3K9 et H3K4 in vivo, mais est incapable in vitro de déméthyler H3K9. La présence de ERRα révèle cette activité de LSD1 sur H3K9, suggérant que le complexe ERRα -LSD1 agit comme un régulateur positif de la transcription. En ce sens, ERRα et LSD1 régulent un nombre important de gènes communs identifiés par RNAseq. Ainsi, 10 gènes activés ont été sélectionnés et le recrutement de ERRα et LSD1 a été examiné sur ces cibles géniques. En association avec les résultats obtenus in vitro, nous avons observé in vivo qu’en absence de ERRα ou LSD1, les gènes activés par ces deux partenaires présentent une augmentation de la marque répressive H3K9me2 sans affecter H3K4me2 au niveau du site d’initiation de la transcription. En conclusion, LSD1 interagit avec ERRα et inhibe sa dégradation, conduisant à une coopération transcriptionnelle de ces protéines. Pour la première fois, un rôle direct de ERRα sur l’environnement chromatinien a été identifié via l’activité de LSD1 sur des marques répressives d’histones. / Nuclear receptors are transcription factors that cooperate with chromatin associated factors to promote their activities. These transcriptional complexes are able to modulate the chromatin landscape to repress or promote transcription. Interestingly, there is an intricate cross-talk between these complexes and the chromatin environment that can influence each other to coordinate gene expression led by nuclear receptors. Post-translational modifications of histones regulate in part, DNA accessibility and the activities of nuclear receptors. One of these histone modifiers is LSD1, which is known to demethylate lysines 4 (H3K4) and 9 (H3K9) on histone 3. This manuscript focuses on the discovered LSD1-ERRα complex in human cancer cell lines. LSD1 interacts with ERRα, hence, modulates ERRα protein stability via a demethylation independent manner. Moreover, LSD1 is able to demethylate H3K4me2 in vitro but not H3K9me2. Interestingly, we observed that ERRα is able to switch LSD1 activity toward H3K9me2 to promote gene transcription without any additional cofactor in vitro. To confirm this effect in vivo, a transcriptomic analysis on mammary cancer cells was performed and highlights common target genes between ERRα and LSD1. We selected 10 genes activated by both and verified ERRα and LSD1 recruitment on these targets. Moreover, upon knock-down of ERRα or LSD1, the transcriptional start sites of activated genes -bound and regulated by both proteins- are enriched in the repressive mark H3K9me2. Altogether, these results describe a positive regulation of ERRα by LSD1 which in turn, drives the demethylase activity on H3K9me2 to promote transcription. Finally, these data highlight a direct function of ERRα on chromatin landscape. ERRα LSD1 Chromatine Transcription Stabilité protéique Déméthylation Récepteur nucléaire Histone ERRα LSD1 Chromatin Transcription Protein stability Demethylation Nuclear receptor Histone
27	Functional analysis of active DNA demethylation in tomato / Analyse fonctionnelle de la déméthylation d'ADN actif en tomate Liu, Ruie 29 November 2016 (has links) La méthylation de l'ADN génomique est l'un des principaux mécanismes épigénétiques qui conduisent à des changements stables et héréditaires de l'expression des gènes sans que cela s’accompagne de la modification de la séquence d'ADN sous-jacente. Elle fait référence à l'addition d'un groupement méthyl sur le carbone 5 des cytosines (5meC). Ces dernières années, l’étude des mécanismes régulant la mise en place et le maintien de de cette méthylation est devenu un thème de recherche importante, en raison de son rôle essentiel dans la régulation du fonctionnement du génome des plantes et des mammifères. La distribution des 5meC sur l’ensemble du génome d’un organisme, encore appelé méthylome, peut être déterminée par différentes méthodes dont le séquençage de l’ADN génomique après traitement au bisulfite de sodium (WGBS ou méthyl C séq). Chez les végétaux, la méthylation de l’ADN peut se produire dans tous les contextes de séquence incluant les motifs symétriques CG et CHG et le contexte dissymétrique CHH (H pouvant être A, T ou C). En fonction du contexte de séquence, la méthylation des cytosines est mise en place et maintenue par trois types différents d'ADN méthyltransférase. [ ] Chez la plante-modèle Arabidopsis, la déméthylation active de l'ADN joue un rôle essentiel dans l'empreinte maternelle et la déméthylation l’ADN génomique lors du développement de l’albumen, mais elles ne semblent pas jouer de rôle essentiel pendant le développement de la plante chez cette espèce. La méthylation de l’ADN génomique peut aussi être perdue après la réplication de l’ADN, lorsque les mécanismes devant assurer son maintien ne sont pas actifs. On parle alors de déméthylation passive de l’ADN génomique. [ ] En conclusion, les observations présentées dans ce travail fournissent un cadre de travail permettant d’analyser les mécanismes moléculaires responsables de la déméthylation de l'ADN se produisant pendant la maturation des fruits de tomate. Ici, nous présentons une analyse complète des conséquences d’une réduction de l’expression du gène de SlDML2 sur le trancriptome et le métabolome des fruits, tout au long de leur développement. La corrélation entre les profils d’expression de gènes réalisées lors de ce travail ( variété WVA106) et les changements de la distribution de la méthylation de l’ADN telles que décrites chez la variété Ailsa craig montre qu’en plus d'un rôle général dans la régulation des gènes directement impliqués dans plusieurs voies métaboliques, plusieurs gènes codant pour des facteurs de transcription ainsi que des régulateurs épigénétiques sont également susceptibles d'être directement contrôlés par la méthylation de leur région promotrice. Cependant, nous ne pouvions pas établir une relation stricte entre la diminution de la méthylation de l'ADN et l'induction de l'expression des gènes, car de nombreux gènes présentant une diminution du niveau de méthylation de l'ADN dans leur région promotrice pendant la maturation des fruits sauvages correspondent à des gènes normalement réprimés. Ceci suggère que la méthylation active de l'ADN serait nécessaire à leur répression pendant le processus de maturation. Ainsi la relation entre la déméthylation de l'ADN et l'expression des gènes pourrait être plus complexe et ne se limiterait pas à la simple hypothèse de départ de ce travail: la déméthylation de l'ADN est nécessaire à l'expression de gènes induits au cours de la maturation. La déméthylation active de l'ADN pourrait également être nécessaire à la répression de gènes exprimés uniquement lors des phases précoces du développement des fruits et réprimés lors du murissement. / DNA methylation is one of the epigenetic mechanisms that lead to stable and heritable changes in gene expression without alteration on DNA sequence. DNA methylation refers to the addition of a methyl group to the fifth position of the cytosine ring. In recent years, DNA methylation is becoming more and more widely studied, because of its importance in mammals and plants. Methylated cytosines distribution can be determined across the genome at single-nucleotide resolution, that is methylome, using whole genome bisulfite-sequencing (BS-seq) approaches. [ ] Solanum lycopersicum (tomato) is an important agronomic crop and the main model to study the development and ripening process of climacteric fleshy fruit. Recent studies have now shown that the development and ripening of fleshy fruits relies on the establishment and maintenance of differential transcription patterns and complex regulatory pathways that involve both genetic and hormonal controls are operating at these developmental phases. However, it appears that a full understanding of fruit development and ripening will not be achieved based only on genetic models as suggested by recent studies, which showing an important decrease in global methylation level and demethylation at specific promoters during fruit ripening. [ ] In conclusion, the observations presented in this work provide a framework for analysis of the molecular mechanism of DNA demethylation during fruit ripening of tomato. Here, we provide a comprehensive analysis of the knock down SlDML2 on the trancriptome, metaoblom and DNA methylation in the promoter analysis. The large transcriptional reprogramming that occured in mutant during fruit ripeing was correlated alterations in DNA methylation. Here we highlight the central role of active DNA demethylation during tomato fruit ripening. In addition to a general role in the regulation of genes directly involved in several metabolic pathways, we also found that several transcription factors as well as epigenetic regulators are also likely under direct methylation control. However, we could not establish a district relationship between DNA reduction of DNA methylation and induction of gene expression, as not all DEGs containing a type-a DMRs (decreased DNA methylation during fruit ripening) do not correspond to genes normally induced in WT and repressed in transgenic plants. Some were corresponding to an opposite situation and in a few cases more complex methylation pattern (several DMRs) were also found. Indeed these conclusions are based on methylation analysis obtained in another variety. They might however reflect the situation of WVA106 fruits, although some variations are expectable when the methylome of DML RNAi fruits will be analyzed. Hence the relationship between DNA demethylation and gene expression might be more complex than expected, and not limited to the starting hypothesis of this work: DNA demethylation is an absolute requirement for the expression of critical ripening induced genes. This is indeed clearly in this study, but the analysis presented here also suggest that DNA demethylation might also be necessary for the repression of several genes as well. In addition, from the rencent study in Arabidopsis, ROS1 were found preferentially targets transposable elements (TEs) which are closer to protein coding genes and intergenic regions, which suggesting that ROS1 may prevent DNA methylation spreading from TEs to nearby genes. While in tomato, as our analysis, we found the methylation level of promoter of a number of genes was altered during fruit ripening, therefore, through methylome analysis, we will also get the preference of DNA methylation on TE, this analysis will give us idea that demethylation in fleshy fruit may has other distinct function as it is in Arabidopsis. Déméthylation d'ADN Mûrissement des fruits Régions différentiellement méthylées Expression du gène Tomate DNA demethylation Fruit ripening Differently methylated regions Gene expression Tomato
28	Regulation of DNA methylation by DNA glycosylases MBD4 and TDG / Régulation de la methylation de l'ADN par les glycosylases MBD4 et TDG Ibrahim, Abdulkhaleg 19 May 2015 (has links) Chez les mammifères, la méthylation est une marque épigénétique ciblant la cytosine principalement dans un contexte CpG pour produire une 5mC. 5mC est très sensible à une déamination spontanée ou enzymatique, conduisant à la formation d'un mésappariement G/T. La 5mCpeut également être oxydée pour former successivement la 5hmC, la 5fC et la 5caC. Ces modifications de la 5mC participent aux processus actifs de déméthylation de l’ADN. Chez les mammifères, la thymine, dans le mésappariement G/T, est clivée par TDG et MBD4. TDG est également en mesure d'exciser 5fC et 5caC. Cette thèse avait pour but de clarifier la fonction de TDG et MBD4 dans la dynamique de la 5mC. Nous avons montré que MBD4 est associée aux protéines de réparation des mésappariements. Les tests enzymatiques, in vitro, montrent que le complexe MBD4/MMR a une activité bifonctionnelle (glycosylase/lyase) spécifique pour G/T, qui est régulée par la méthylation. Pour TDG, nous avons ciblé cette enzyme dans les cellules MEF et caractérisé la distribution des cytosines modifiées. Les résultats montrent des profils de méthylation/oxydation d'ADN qui sont régulés par TDG et surviennent principalement au niveau des répétitions de CA et dans les rétroéléments spécifiques de la lignée souris. / In mammals, methylation is an epigenetic mark targeting cytosine mainly in a CpG context, producing 5mC. 5mC is highly sensitive to a spontaneous or enzymatic deamination leading to G/Tmismatch. 5mC can also be oxidized to 5- 5hmC, 5fC and 5caC. These modifications of 5mC participate in the active demethylation processes. In mammals, the thymine in G/T mismatch is cleaved by TDG and MBD4 glycosylases. TDG is able also to excise the 5fC and 5caC.This thesis was to clarify the function of TDG and MBD4 in the dynamics of 5mC. We showed that MBD4 is associated with PMS2, MLH1, MSH2 and MSH6 proteins, four proteins involved in DNA mismatch repair (MMR). The in vitro enzymatic tests show that MBD4/MMR complex has a bifunctional glycosylase/lyase activity specific for G/T and is regulated by methylation.For TDG, we targeted this enzyme in MEF cells and characterized the distribution of modified cytosines. The results show that DNA methylation/oxidation patterns are regulated by TDG and occur mainly at CA repeats and at the mouse-lineage specific retro-elements. Déméthylation MBD4 TGD Glycosylase/lyase Rétro-éléments Oxydation Protéines de réparation Demethylation MBD4 TDG Glycosylases Retro-elements Oxidation Mismatch repair 572.8
29	Studies of Budding Yeast Transcription Factors Acting Downstream of Nutrient Signaling Pathways Nordberg, Niklas January 2012 (has links) Being able to respond to extracellular cues such as nutrients and growth factors is of vital importance to all living cells. Pathways have therefore evolved which can sense the extracellular status, transmit a signal through the cell and affect gene expression, which ultimately enables adaptation. Intriguingly, research has revealed that such signaling pathways responding to nutrient status are intrinsically linked to the lifespan of organisms, a phenomenon known as caloric restriction. This thesis utilizes budding yeast, Saccharomyces cerevisiae, as a model system to investigate how transcription factors affect gene expression in response to nutrient signaling pathways. Paper I investigates the role of the three homologous transcription factors Mig1, Mig2 and Mig3 in regulating gene expression in response to glucose. This is done by transcriptional profiling with microarrays of wild type yeast, as well as mutant strains where the MIG1, MIG2 and MIG3 genes have been deleted in all possible combinations. The results reveal that Mig1 and Mig2 act together, with Mig1 having a larger effect in general while Mig2 has a role specialized for high-glucose conditions. Using a strategy similar to that in paper I, paper II examines the roles of the two homologous transcription factors Gis1 and Rph1 in gene regulation. This study shows that Gis1 and Rph1 are both involved in nutrient signaling, acting in parallel with a large degree of redundancy. Furthermore, we find that these two transcription factors change both target genes as well as the effects on transcription when the yeast cell transitions through different growth phases. Rph1 is a functional JmjC histone demethylase, and paper III investigates the connection between this activity and the transcriptional regulation studied in paper II. We find that rendering Rph1 catalytically inactive has little effect on its role in nutrient signaling and gene regulation, but subtly affects certain groups of genes. Paper IV reveals that Rph1 does not affect the chronological lifespan of yeast as does its homolog Gis1. However, deleting or overexpressing RPH1 has effects on the response to rapamycin and caffeine, inhibitors of the evolutionary conserved TORC1 complex affecting lifespan in both yeast and mammals. Budding yeast nutrient signaling glucose repression aging caloric restriction JmjC histone demethylation Mig1 Mig2 Mig3 Gis1 Rph1
30	Investigating the inhibitor and substrate diversity of the JmjC histone demethylases Schiller, Rachel Shamo January 2016 (has links) Epigenetic control of gene expression by histone post-translational modifications (PTMs) is a complex process regulated by proteins that can 'read', 'write' or 'erase' these PTMs. The histone lysine demethylase (KDM) family of epigenetic enzymes remove methyl modifications from lysines on histone tails. The Jumonji C domain (JmjC) family is the largest family of KDMs. Investigating the scope and mechanisms of the JmjC KDMs is of interest for understanding the diverse functions of the JmjC KDMs in vivo, as well as for the application of the basic science to medicinal chemistry design. The work described in this thesis aimed to biochemically investigate the inhibitor and substrate diversity of the JmjC KDMs, it led to the identification of new inhibitors and substrates and revealed a potential combinatorial dependence between adjacent histone PTMs. Structure-activity relationship studies gave rise to an n-octyl ester form of IOX1 with improved cellular potency and selectivity towards the KDM4 subfamily. This compound should find utility as a basis for the development of JmjC inhibitors and as a tool compound for biological studies. The rest of this thesis focused on the biochemical investigations of potential substrates and inhibitors for KDM3A, a JmjC demethylase with varied physiological functions. Kinetic characterisation of reported KDM3A substrates was used as the basis for evaluations of novel substrates and inhibitors. Further studies found TCA cycle intermediates to be moderate co-substrate competitive inhibitors of KDM3A. Biochemical investigations were carried out to study potential protein-protein interactions of KDM3A with intraflagellar transport proteins (IFTs), non-histone proteins involved in the formation of sperm flagellum. Work then addressed the exploration of novel in vitro substrates for KDM3 (KDM3A and JMJD1C) mediated catalysis, including: methylated arginines, lysine analogues, acetylated and formylated lysines. KDM3A, and other JmjC KDMs, were found to catalyse novel arginine demethylation reaction in vitro. Knowledge gained from studies with unnatural lysine analogues was utilised to search for additional novel PTM substrates for KDM3A. These results constitute the first evidence of JmjC KDM catalysed hydroxylation of an Nε-acetyllysine residue. The H3 K4me3 position seems to be required for acetyllysine substrate recognition, implying a combinatorial effect between PTMs. Preliminary results provide evidence that JMJD1C, a KDM3 protein previously reported to be inactive, may catalyse deacetylation in vitro. An additional novel reaction, observed with both KDM3A and JMJD1C, is deformylation of N<sup>ε</sup>-formyllysine residues on histone H3 fragment peptides. Interestingly, H3 K4 methylation was also observed to enhance the apparent deformylation of both KDM3A and JMJD1C catalysed reactions. Overall, findings in this thesis suggest that the catalytic activity of JmjC KDMs extends beyond lysine demethylation. In a cellular context, members of the KDM3 subfamily might provide a regulatory link between methylation and acylation marks. Such a link will further highlight the complex relationships between histone PTMs and the epigenetic enzymes that regulate them. The observed dependency of H3 K9 catalysis on H3 K4 methylation adds another layer of complexity to the epigenetic regulation by histone PTMs.

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