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Élucidation d'un nouveau mécanisme d'inactivation de Php4 en réponse au ferVachon, Philippe January 2014 (has links)
Le fer est un cofacteur essentiel à la croissance des organismes. Cependant, un surplus de fer conduit à la production de dérivés toxiques de l’oxygène qui sont dangereux pour les cellules. La concentration intracellulaire de fer doit donc être régulée. Lorsque la biodisponibilité du fer s’amenuise, la plupart des cellules augmentent leur acquisition du fer environnemental tout en réduisant sa consommation en réprimant plusieurs voies métaboliques fer-dépendantes non-essentielles. Alors que les mécanismes qui régissent l’augmentation de l’acquisition du fer sont assez bien caractérisés, les composantes qui contrôlent la promotion de l’économie du fer sont largement méconnues. Mes travaux ont porté sur l’étude des mécanismes de contrôle de l’économie du fer chez la levure à fission Schizosaccharomyces pombe. Php4, une sous-unité du complexe liant les boîtes CCAAT, est responsable de la répression des gènes codants pour des protéines qui utilisent du fer lorsque ce dernier est en faible concentration. Il est déjà connu qu’en présence de fer, l’expression du gène php4+ est réprimée via le facteur de transcription Fep1. De plus, la protéine Php4 est inactivée et exportée hors du noyau lorsque les cellules croissent en présence de fer. Ce processus est dépendant à la fois de la présence de l’exportine Crm1 et de la monothiol glutarédoxine Grx4. L’objectif de recherche est de découvrir le mécanisme par lequel Grx4 inhibe Php4 en réponse à la présence de fer. L’approche du double-hybride a été utilisée pour quantifier la force de l’interaction entre Php4 et Grx4 et identifier les domaines de ces protéines qui y participent. Ce système nous a permis de déterminer que Php4 interagit de façon constitutive avec le domaine thiorédoxine (TRX) de Grx4, alors que l’interaction entre Php4 et le domaine glutarédoxine (GRX) est dépendante de la présence de fer. Nous avons déterminé que la cystéine 35 du domaine TRX et la cystéine 172 du domaine GRX sont essentiels pour l’interaction de chacun de ces domaines avec Php4. Des régions minimales de Php4 nécessaires pour son interaction avec chacun des domaines GRX et TRX ont aussi été identifiées. Par la suite, nous avons démontré que l’expression du domaine GRX seul de Grx4 est suffisante pour l’inactivation de Php4 en présence de fer. Puis, par des essais de fluorescence par complémentation bimoléculaire (BiFC), nous avons démontré que le domaine GRX de Grx4 interagit de façon fer-dépendante avec Php4 et qu’il est suffisant pour l’exportation de Php4 hors du noyau en présence de fer. Ces résultats révèlent que le mécanisme par lequel Php4 est inhibé en présence de fer dépend de son interaction avec le domaine GRX de Grx4. À la suite des résultats obtenus, un modèle illustrant l’interaction fer-dépendante entre Grx4 et Php4 suggère la présence potentielle d’un centre fer-soufre qui pourrait expliquer la nature de l’interaction fer-dépendante entre les deux protéines.
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Régulation du transcriptome codant et non-codant chez Schizosaccharomyces pombe: facteurs et mécanismes impliqués dans la maturation 3’ des ARNs et la terminaison de la transcriptionLemay, Jean-François January 2016 (has links)
La synthèse d’un ARNm eucaryotique dépend d’une suite d’étapes qui inclut notamment l’ajout d’une queue poly(A) à son extrémité 3’. Au noyau, la queue poly(A) des ARNms est liée par PABPN1 (poly(A)-binding protein nuclear 1). PABPN1 fut notamment caractérisée, d’après des études in vitro, pour stimuler la réaction de polyadénylation en plus de contrôler la taille ultime des queues poly(A). Cela dit, la ou les fonction(s) biologique(s) de PABPN1 est/sont cependant largement méconnue(s). Chez Schizosaccharomyces pombe (S. pombe), Pab2 est l’orthologue présumé de PABPN1. Or, mes travaux indiquent que Pab2 est fonctionnellement différente de PABPN1 à l’égard de son rôle sur le processus général de polyadénylation. Ainsi, in vivo, l’absence de Pab2 entraîne l’expression et l’accumulation d’un groupe limité d’ARNs hyperadénylés parmi lesquels se trouvent de nombreux petits ARNs nucléolaires non-codants (snoRNAs) lesquels constituent normalement un groupe abondant d’ARN poly(A)-. Mes résultats supportent ainsi un mécanisme par lequel des snoRNAs immatures poly(A)+, sont convertis en une forme mature poly(A)- par le biais de Pab2 et de l’activité 3’-->5’ exoribonucléase de l’exosome à ARN. Ces observations sont inusitées dans la mesure où elles associent une fonction pour une PABP dans la maturation d'ARNs non-codants, contrairement à la notion que les PABPs travaillent exclusivement au niveau des ARNms, en plus de procurer une nouvelle perspective face au mécanisme de recrutement de l'exosome à ARN à des substrats poly(A)+.
La formation de l’extrémité 3’ d’un ARN est un processus étroitement lié à la terminaison de sa transcription. Pour les gènes codants, la terminaison transcriptionnelle est initiée par le clivage endonucléolytique du pré-ARNm. Ce clivage génère une extrémité d’ARN 5’ libre laquelle sera ciblée par une exoribonucléase 5'-->3’ afin de mener à bien l’éviction de l’ARNPII de la matrice d’ADN (terminaison transcriptionnelle de type torpedo). Au contraire, chez Saccharomyces cerevisiae (S. cerevisiae), la majorité des gènes non-codants, incluant les snoRNAs, dépendent plutôt du complexe NNS (Nrd1/Nab3/Sen1) pour la terminaison de leur transcription. Cela dit, il est incertain si le complexe NNS est conservé chez d’autres espèces. À cet égard, mes travaux indiquent que S. pombe est dépourvu d’un mécanisme de terminaison de la transcription de type NNS. Seb1, l’orthologue présumé de Nrd1 chez S. pombe, s’associe plutôt à la machinerie de clivage et de polyadénylation et influence la sélection de site de polyadénylation à l’échelle du génome. Mes résultats supportent ainsi l’utilisation de la machinerie de maturation 3’ des ARNms comme principal vecteur de terminaison transcriptionnelle chez S. pombe et identifient Seb1 comme un facteur clé de ce processus.
L’évènement transcriptionnel étant hautement complexe, des erreurs peuvent arriver de manière stochastique menant à l’accumulation d’ARNs aberrants potentiellement néfastes pour la cellule. Or, mes travaux ont mis en lumière un mécanisme de surveillance co-transcriptionnel des ARNs impliquant l’exosome à ARN et lié à la terminaison de la transcription. Pour ce faire, l’exosome à ARN promeut la terminaison transcriptionnelle via la dégradation d’une extrémité 3’ libre d’ARN devenue émergente suite au recul de l’ARNPII le long de la matrice d’ADN (phénomène de backtracking). Mes résultats supportent ainsi une terminaison de la transcription de type torpedo inversé (3'-->5’) réévaluant par la même occasion le concept voulant que la terminaison de la transcription s’effectue uniquement selon une orientation 5’-->3’.
Somme toute, mes travaux de doctorat auront permis d’identifier et de caractériser plus en détail les facteurs et mécanismes impliqués dans la maturation 3’ et la terminaison de la transcription des gènes codants et non-codants chez l’organisme modèle S. pombe.
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The cell cycle and DNA damage-dependent regulation of Cdt1 in schizosaccharomyces pombeShepherd, Marianne E. A. January 2012 (has links)
Cdt1 is a conserved and essential eukaryotic protein that is required for the licensing step of DNA replication. In order to control replication licensing and ensure a single round of DNA replication occurs per cell cycle, Cdt1 is subject to strict regulation. In Metazoa and S. pombe, Cdt1 is targeted for ubiquitylation and proteolysis in S phase and after DNA damage by the CRL4Cdt2 ubiquitin ligase. CRL4Cdt2 is activated in Metazoa by an unusual mechanism that requires an interaction between the substrate and chromatin-loaded proliferating cell nuclear antigen (PCNA). This study addressed the involvement of PCNA in S. pombe Cdt1 proteolysis. A mutational analysis was undertaken to establish whether the Cdt1-PCNA interaction is conserved in S. pombe and the extent to which it regulates CRL4Cdt2-dependent turnover of the protein. S. pombe Cdt1 was shown to interact with PCNA in vivo and two variant PCNA-interacting peptide (PIP) motifs were identified in the protein. The two motifs function near-redundantly to promote both the Cdt1-PCNA interaction and the CRL4Cdt2-dependent proteolysis of Cdt1 in S phase and after DNA damage. The mutational analysis also resulted in the characterisation of two in-frame AUG codons in the cdt1+ reading frame. The second in-frame AUG codon was shown to be the principal initiator codon and was required to maintain wildtype Cdt1 protein levels and cell viability. CRL4Cdt2 is emerging as an important regulator of proteins that are involved in the control of cell cycle progression and the maintenance of genome stability. However, there are a number of outstanding questions regarding the mechanism and regulation of CRL4Cdt2. In order to address these questions, a genomics approach was taken to identify novel genes involved in Cdt1 regulation. A screen of non-essential S. pombe genes identified 17 candidate genes that, when inactivated, caused up-regulation of Cdt1. Unexpectedly, deletion of genes involved in homologous recombination resulted in a Rad3-dependent up-regulation of Cdt1. Further work is required to establish the biological significance of this finding.
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Analysis of nucleotide synthesis and homologous recombination repair in Schizosaccharomyces pombeBlaikley, Elizabeth Jane January 2014 (has links)
Nucleotide synthesis is a conserved and highly regulated response to DNA damage, required for the efficient repair of DNA double strand breaks (DSB) by homologous recombination (HR). This is essential to prevent loss of heterozygosity (LOH) and maintain genome stability. The aim of this study was to identify new genes important for HR through roles in damage-induced nucleotide synthesis. A screen was performed to identify S. pombe gene deletion strains whose DSB sensitivity was suppressed by deleting the ribonucleotide reductase (RNR) inhibitor spd1<sup>+</sup> to promote nucleotide synthesis. The screen identified a number of genes including ddb1<sup>+</sup>, cdt2<sup>+</sup>, rad3<sup>+</sup> and csn1<sup>+</sup> which have known roles in nucleotide synthesis. Distinct roles were identified for the DNA damage checkpoint in suppressing LOH. rad3<sup>+</sup>, rad26<sup>+</sup>, rad17<sup>+</sup> and the rad9<sup>+</sup>, rad1<sup>+</sup> and hus1<sup>+</sup> genes encoding the 9-1-1 complex were required for DNA damage-induced nucleotide synthesis through Cdt2 induction to promote Spd1 degradation. The HR repair defect of rad3<sup>+</sup> and rad26<sup>+</sup> deletion strains was partially suppressed by spd1<sup>+</sup> deletion. However, the HR repair defect of rad17<sup>+</sup>, rad9<sup>+</sup>, rad1<sup>+</sup> and hus1<sup>+</sup> deletion strains was not suppressed. An additional role was confirmed for Rad17 and the 9-1-1 complex in preventing LOH by promoting DSB resection. A role was identified for the Gcn5 histone acetyl transferase (HAT) protein module, consisting of Gcn5, Ngg1, Ada2 and Sgf29, in suppressing DSB sensitivity by promoting nucleotide synthesis. This was independent of Cdt2 or RNR protein levels. The Gcn5 HAT module was also found to regulate DSB repair pathway choice consistent with previous observations. Deletion of gcn5<sup>+</sup>, ngg1<sup>+</sup> or ada2<sup>+</sup> decreased HR and increased non-homologous end joining. Surprisingly, deletion of spd1<sup>+</sup> in a gcn5∆, ngg1∆ or ada2∆ background also promoted HR. This predicts a role for nucleotide pools in regulating DSB repair pathway choice. Eleven other candidates showed repeatable suppression of DSB sensitivity following spd1<sup>+</sup> deletion. However many of these candidates did not show reduced nucleotide levels. This suggests deleting spd1<sup>+</sup> may also suppress DSB sensitivity by a different mechanism.
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Étude du rôle de la calnexine de Schizosaccharomyces pombe dans le repliement et la sécrétion de protéinesTanguay, Pierre-Luc January 2003 (has links)
Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.
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Investigating the role of RNA interference in the fission yeast Schizosaccharomyces japonicusChapman, Elliott January 2018 (has links)
RNA interference (RNAi) is a conserved pathway that plays key roles in heterochromatin formation, gene regulation and genome surveillance across a wide range of eukaryotes. One of the most utilised model organisms for studying the RNAi pathway is the fission yeast Schizosaccharomyces pombe. However, this species is somewhat atypical, in that it has not retained the ancestral role for RNAi in the silencing of mobile genetic elements. In contrast, the related fission yeast S. japonicus has a large and diverse retrotransposon complement that appears to give rise to abundant siRNAs. For this reason, we believe that S. japonicus may be a more suitable model for studying the role of RNAi in silencing mobile genetic elements, a function that is conserved in many higher eukaryotes. Functional analysis of the S. japonicus RNAi pathway proved more challenging than expected, as it was generally not possible to recover strains bearing deletions of core RNAi components (Ago1/Clr4/Rdp1/Arb1/Arb2). This suggests that a functional RNAi pathway may be required for viability in S. japonicus, unlike in S. pombe. However, disruption mutants were isolated for the sole Dicer ribonuclease Dcr1, at very low frequency. Analysis of these mutants revealed that disruption of Dcr1 impaired the generation of retrotransposon derived siRNAs, and caused de-repression of retroelement transcript accumulation and mobilisation in an element dependent manner. Surprisingly however, Dcr1 appeared dispensable for the maintenance of H3K9me2 at transposons, suggesting that, in contrast to S. pombe, silencing may occur principally at the post-transcriptional level. It is also possible that the isolated Dcr1 mutants represent rare survivors that are viable due to the presence of suppressor mutations elsewhere in the genome. I utilised my genome wide RNA sequencing data to help improve the annotation of the S. japonicus genome, with a specific focus on the retrotransposon complement. From this, I identified 12 new families of LTR retrotransposon, which increased the annotated retrotransposon complement by around 40% in S. japonicus. Finally, I characterised the integrative preference of the S. japonicus retrotransposon Tj1, and found that it shares characteristics associated with the S. cerevisiae retrotransposons Ty1 and Ty3, mostly integrating upstream of RNA PolIII transcribed tRNA genes. The findings of this work highlight some potentially key differences in the way the RNAi pathway functions across the fission yeast clade, both in terms of its importance for viability and its mode of action. The work undertaken here also contributes to the establishment of S. japonicus as a model for the study of RNA interference and genome regulation.
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A Role for Nucleoporin Nup211 in Centromere Structure and Function in Schizosaccharomyces PombeMorris, Corey January 2011 (has links)
Eukaryotic centromeres are the region upon which kinetochores assemble, directing attachment of spindle microtubules and faithful segregation of chromosomes during mitosis and meiosis. Except for a transient disruption in mitosis when chromosomes are segregated, centromeres of fission yeast Schizosaccharomyces pombe remain closely associated with the nuclear periphery. Similar to multicellular eukaryotic centromeres, they also maintain unique chromatin architecture, with a central core defined by the presence of the conserved centromeric histone H3 variant CENP-A, designated Cnp1 in S. pombe, that is flanked by histone H3 containing heterochromatin. While much progress has been made in understanding chromatin-associated factors important for proper centromere function, many questions remain. In order to gain a better understanding of the factors involved in centromeric chromatin structure, we affinity purified and defined by mass spectrometry interactions among select proteins that had been implicated in proper Cnp1 localization and centromere function. These biochemical purifications revealed several proteins that may be involved in Cnp1 localization. Purification and analyses of Cnp1 also led us to the identification of the Mlp1/Tpr nucleoporin homolog Nup211. We have found that Nup211 interacts with components of the inner nuclear basket of the nuclear pore, and co-purifies with centromeric chromatin proteins. Cells lacking Nup211 have substantial chromosome segregation defects, as observed by synthetic growth assay, flow cytometric analysis, and fluorescent microscopy. A series of immunoprecipitation experiments have revealed that Nup211 associates with centromeric DNA, and that, surprisingly, cells lacking Nup211 have increased histone H3 lysine 9 methylation, a marker of heterochromatin, and a reduction in Cnp1 levels at the central core. Moreover, cells lacking Nup211 have decreased transcription at centromeric loci, disruption of the stereotypical nucleosome structure found at the central core of S. pombe, and show striking changes in the distribution of heterochromatic foci in the nucleus. By demonstrating that Nup211 is essential for the maintenance of normal central core chromatin state, these studies have shed light on a novel role for Nup211 in proper centromere structure and function in S. pombe, and suggest that Nup211 may play a role in preventing the invasion of flanking pericentric heterochromatin into the central core of centromeres.
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Μελέτες επί της μιτοχονδριακής ριβονουκλεάσης Ρ από το σχιζοσακχαρομύκητα S. pombeΣταματοπούλου, Βασιλική 18 February 2009 (has links)
Η ριβονουκλεάση Ρ (RNase P) είναι μια πανταχού παρούσα ενδονουκλεάση, και σε πολλές περιπτώσεις αποτελεί ένα ριβοένζυμο, η οποία συμμετέχει στον μηχανισμό ωρίμανσης των πρόδρομων tRNAs. Στην πλειοψηφία των περιπτώσεων είναι ένα ριβονουκλεοπρωτεϊνικό σύμπλοκο που αποτελείται από μια RNA υπομονάδα και τουλάχιστον μια πρωτεϊνική υπομονάδα. Όσον αφορά τα ευκαρυωτικά κύτταρα, πιστεύεται πως υπάρχουν δυο διακριτές μορφές του ολοενζύμου, μια πυρηνική και μια μιτοχονδριακή. Στο Saccharomyces cerevisiae η μιτοχονδριακή RNase P διαθέτει μια RNA και μια πρωτεϊνική υπομονάδα που κωδικοποιούνται από ένα μιτοχονδριακό (rnpB) και ένα πυρηνικό γονίδιο, αντίστοιχα. Σε αυτήν την εργασία απομονώσαμε και μερικώς καθαρίσαμε την μιτοχονδριακή RNase P από τον Schizosaccharomyces pombe. Κλωνοποιήθηκε, επίσης, το γονίδιο που κωδικοποιεί την RNA υπομονάδα της μιτοχονδριακής RNase P. Αυτό το ένζυμο παρουσιάζει διαφορετική εξειδίκευση για τα υποστρώματα SupS1 (pre-tRNASer) και pre-tRNATyr και δεν απενεργοποιείται από την μικροκοκκική νουκλεάση. / Ribonuclease P is a universally conserved ribozyme that it is involved in the 5΄ maturation of precursors tRNAs. It is in most cases a ribonucleoprotein complex which comprises an RNA subunit and at least one protein subunit. Concerning the eukaruotic cells, it is expected that distinctive nuclear and mitochondrial RNase P activities exist. In Saccharomyces cerevisiae the mitochondrial RNase P consists of an RNA and a protein subunit encoded by a mitochondrial (rnpB) and a nuclear gene, respectively. In the present study we isolated and partially purified mitochondrial RNase P from Schizosaccharomyces pombe and we cloned the gene that encodes the mitochondrial RNase P RNA subunit. This enzyme exhibits different specificity on SupS1 and pre-tRNATyr substrates and is not inactivated by micrococcal nuclease.
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Structure Function Relationships in the 5' ETS of the Schizosaccharomyces pombe pre-rRNANellimarla, Srinivas 29 August 2012 (has links)
The 5’ external transcribed spacer (5’ ETS) of pre-ribosomal RNA, although highly variable in size and sequence, has been shown to be critical for the initiation of rRNA processing. This study further examined the 5’ ETS in Schizosaccharomyces pombe with respect to structural elements that underlie rRNA maturation. Initially, the 5’ ETS/18S rRNA junction region was examined by mutational analyses to detect cis-acting elements critical to known cleavage sites. The results indicated that sequence/structure in the junction region does not direct or strongly influence cleavage at the 5’ end of 18S rRNA. Systematic mutations also were used to examine the significance of previously suggested putative ribosomal protein binding sites or U3 snoRNA binding sites as well as other stem-loop sequences of regions IV, V and VI in the 5’ ETS. The results indicated that the putative U3 snoRNA binding sites were less critical than previously anticipated but have identified elements in regions IV and V with significant influence on the production of mature ribosomal RNA. In vitro studies of interactions between these elements and the U3 snoRNA or cellular protein also were initiated. The results of electrophoretic mobility shift assays indicated a strong interaction between region IV and the U3 snoRNA, suggesting that region IV probably contributes to the function of an important structure in the nucleolar precursor particle, which together with region V and probably other hairpins, may act to organize a stable processing domain. In contrast to the previous studies, which suggested as many as six intermediate cleavage sites in the 5’ ETS of S. pombe, re-examination of termini using hybridization and ligation-mediated RT-PCR indicated only two major cleavage sites. In general the 5’ ETS sequence mutants did not seem to influence the rRNA processing profile significantly but could dramatically affect the quantity of the product, an observation that provided further evidence of quality control, which helps ensure that only functional RNA is incorporated into mature ribosomes. Taken together the results illustrated that various sequence/structural elements in the 5’ ETS could influence or be critical for the maturation of rRNA. The results also support the possibility that the precursor molecule is first organized into one or more processing domains that direct the actual maturation processes. / This study was supported by the Natural Sciences and Engineering Research Council of Canada.
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Genome-wide patterns of histone modifications in fission yeastSinha, Indranil, January 2010 (has links)
Diss. (sammanfattning) Stockholm : Karolinska institutet, 2010.
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