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Histone modifications after DNA damage affect survival in Schizosaccharomyces pombe / Rajput, Abdul Mateen January 2010 (has links)
S. cerevisiae Ada2 and Bre1 has a role in histone post-translational modifications. Deletion of these genes causes deficiency in acetylation (Ada2) or ubiquitination (Bre1) of histones. Further, mutants lacking these genes or homologous genes showed different phenotypes in human and S. cerevisiae while treated with DNA damaging agents 4-NQO and MMS. Bre1 deficient cells showed 4-NQO sensitivity in S. cerevisiae and resistance in human cells. Since it has been shown that S. pombe is more close to mammals in chromatin regulation we wanted to examine S. pombe response against MMS and 4-NQO. By homologous recombination, genes were deleted and mutants were treated with different concentration of both the genotoxins. In accordance with a previous study, Ada2Δ showed sensitivity to MMS while Brl1Δ & Brl2Δ grew as wild type. Surprisingly, unlike S. cerevisiae, S. pombe showed resistance to 4-NQO and has a phenotype similar to the one found in human cells.
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Structural and functional characterisation of Mcb1 and the MCMᴹᶜᵇ¹ complex in Schizosaccharomyces pombeSchnick, Jasmin January 2014 (has links)
The MCM helicase plays an important role in eukaryotic DNA replication, unwinding double stranded DNA ahead of the replication fork. MCM is a hetero-hexamer consisting of the six related proteins, Mcm2-Mcm7. The distantly related MCM-binding protein (MCM-BP) was first identified in a screen for proteins interacting with MCM2-7 in human cells and was found to specifically interact with Mcm3-7 but not Mcm2. It is conserved in most eukaryotes and seems to play an important role in DNA replication but its exact function is not clear yet. This study contributes to the understanding of the fission yeast homologue of MCM-BP, named Mcb1, but also of MCM-BP in general. Results presented in this thesis document the initial biochemical characterisation of the complex Mcb1 forms with Mcm proteins, the MCMᴹᶜᵇ¹ complex. Interactions of Mcb1 with Mcm proteins, potential interaction sites between the proteins and the size of the complex were analysed using a variety of methods, including tandem affinity purification, co-immunoprecipitation, sucrose gradients and in vitro pull-down assays. Sequence analysis and structure prediction were utilised to gain some insight into Mcb1 and MCM-BP ancestry and structure. Results presented here indicate that fission yeast Mcb1 shares homology with Mcm proteins and forms a complex with Mcm3-Mcm7 but not Mcm2 and thus replaces the latter in an alternative high molecular weight complex that is likely to have an MCM-like appearance. Deletion of mcb1⁺ showed that Mcb1 is essential in fission yeast. To examine the cellular function of the protein, temperature-sensitive mutants were generated. Inactivation of Mcb1 leads to an increase in DNA damage and cell cycle arrest in G2-phase depending on the activation of the Chk1 dependent DNA damage checkpoint. Similar observations were made when Mcb1 was overexpressed, indicating that certain levels of the protein are important for accurate DNA replication. Construction of truncated versions of Mcb1 suggested that almost the full-length protein is needed for proper function.
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Identification and characterisation of homologous recombination genes in Schizosaccharomyces pombeMoss, Jennifer January 2011 (has links)
DNA double-strand breaks (DSBs) are highly genotoxic lesions, which can promote chromosomal rearrangements and tumorigenesis through oncogene activation or loss of heterozygosity (LOH) at tumour suppressor loci. To identify new genes involved in DSB repair and genome stability, an S. pombe deletion library was screened for mutants which exhibited sensitivity to the DNA damaging agents bleomycin and/or MMS. 192 mutants were isolated which exhibited increased sensitivity to one or both of these agents. These mutants were further analysed in a sectoring assay and mutants sought which exhibited elevated levels of break-induced loss and rearrangement of a non-essential minichromosome. Using this approach 57 genes were identified, including all known homologous recombination (HR) and DNA damage checkpoint genes present in the library. Further, quantitative analysis of DSB repair indicated that 25 of these genes functioned to promote efficient HR repair, thus representing a comprehensive HR gene set in fission yeast. Included in this gene set are 10 genes not previously implicated in HR repair; nse5⁺, nse6⁺, ddb1⁺, cdt2⁺, alm1⁺, snz1⁺, kin1⁺, pal1⁺, SPAC31G5.18c⁺ and SPCC613.03⁺. Detailed characterisation of ddb1Δ and cdt2Δ established a role for the Ddb1-Cul4Cdt2 ubiquitin ligase complex in HR. The findings presented here support a model in which break-induced Rad3 and Ddb1-Cul4Cdt2 ubiquitin ligase-dependent Spd1 degradation promotes ribonucleotide reductase activation and nucleotide biosynthesis, which is required for post-synaptic ssDNA gap filling during HR repair. Lastly, the role of HR genes in suppressing chromosome loss and rearrangements was examined. A striking inverse correlation between levels of gene conversion and levels of both chromosome loss and LOH was observed across the HR gene deletion set. These findings support a common and likely evolutionarily conserved role for HR genes in suppressing both chromosome loss and break-induced chromosomal rearrangements resulting from extensive end processing associated with failed HR repair.
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Bioinformatical and experimental analysis of gene expression regulation through RNAi and alternative polyadenylationSchlackow, Margarita January 2014 (has links)
Polyadenylation signals in yeast are not very well defined and are believed to be largely degenerate. Here, we present a computational and experimental genome-wide analysis of polyadenylation signals in Schizosaccharomyces pombe (S. pombe), identifying the canonical AATAAA motif as the most frequent and functional signal. RNA-Seq data from cells grown under various physiological conditions were used to map 3’UTRs, which classify as commonly heterogenic. We have shown that many genes have alternative 3’UTRs. Our results are summarised and can be accessed in a user-friendly online database Pomb(A). It has been shown that convergent genes require trans elements, like Cohesin, for efficient transcription termination. We demonstrate that convergent genes lacking Cohesin are generally associated with longer overlapping transcripts. Furthermore, we analysed ChIP-chip data of Rad21 and Mis4 as well as other Cohesin and loading complex subunits and show that regions of Rad21/Mis4 co-localisation are generally associated with highly transcribed genes. They are also cohesive, while sites with Rad21 only are less cohesive. Rad21/Mis4 co-localisation sites are in close proximity to annotated origins of replication, suggesting that cohesive sites may facilitate replication. microRNAs (miRNAs) are well studies in higher eukaryotes and participate on post-transcriptional gene silencing by degrading target mRNA or blocking translation. It is believed that miRNAs do not exist in yeast. We reanalyzed miRNA presence in yeast using recently available small RNA data sets. Potential miRNA genes and targets in S. pombe were computationally predicted based on the described alternative 3’UTR data and further experimentally tested. Dicer is an enzyme, which recognizes long dsRNA substrates and cleaves them into siRNA e↵ector molecules, essential for gene silencing. Dicer has been thought to be a purely cytoplasmic protein. However, we employed ChIP-Seq and dsRNA RNA-Seq data to show that Dicer localises in the nucleus of mammalian cells and associates with the chromatin on numerous loci. Furthermore, we present evidence that Dicer processes long dsRNA into siRNA in the nucleus and the lack of Dicer causes the accumulation of long dsRNA. This consequently induces the interferon response pathway, which ultimately leads to apoptosis and cell death.
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Caractérisation de la sous-unité bêta du translocon chez la levure Schizosaccharomyces pombeLeroux, Alexandre 12 1900 (has links)
La sécrétion des protéines est un processus essentiel à la vie. Chez les eucaryotes, les protéines sécrétées transitent dans le réticulum endoplasmique par le pore de translocation. Le translocon est composé de trois sous-unités fondamentales nommées Sec61α, β et γ chez les mammifères, ou Sec61p, Sbh1p et Sss1p chez les levures. Tandis que le rôle des sous-unités α et γ est bien connu, celui de la sous-unité β demeure énigmatique. Plusieurs phénotypes distincts sont associés à cette protéine dans différents organismes, mais le haut niveau de conservation de séquence suggère plutôt une fonction universelle conservée. Récemment, Feng et al. (2007) ont montré que le domaine transmembranaire (TMD) de Sbh1p était suffisant pour complémenter plusieurs phénotypes associés à la délétion du gène chez Saccharomyces cerevisiae, suggérant un rôle important de cette région. L’objectif de mon projet de recherche consiste à étudier la fonction biologique de la sous-unité β du translocon et de son TMD chez Schizosaccharomyces pombe. Dans cette levure, j’ai découvert que le gène sbh1+ n’était pas essentiel à la viabilité à 30oC, mais qu’il était requis pour la croissance à basse température. La délétion de sbh1+ entraîne une sensibilité aux stress de la paroi cellulaire et une diminution de la sécrétion des protéines à 23oC. La surexpression de Sbh1p diminue elle aussi la sécrétion des protéines et altère la morphologie cellulaire. Ces phénotypes sont distincts de ceux observés chez S. cerevisiae, où la délétion des deux paralogues de Sec61β entraîne une sensibilité à haute température plutôt qu’à basse température. Malgré cela, les homologues de Sec61β de S. pombe et de S. cerevisiae sont tout deux capables de complémenter la thermosensibilité respective de chaque levure. La complémentation est possible même avec l’homologue humain de Sec61β, indiquant la conservation d’une fonction de Sec61β de la levure à l’homme. Remarquablement, le TMD de Sec61β de S. pombe, de S. cerevisiae et de l’humain sont suffisants pour complémenter la délétion génomique autant chez la levure à fission que chez la levure à bourgeons. Globalement, ces observations indiquent que le TMD de Sec61β exerce une fonction cellulaire conservée à travers les espèces. / Protein secretion is an essential biological process. In eukaryotes, secreted proteins transit into the endoplasmic reticulum through the translocon pore. The core of the translocation channel is composed of three subunits called Sec61α, β and γ in mammals, or Sec61p, Sbh1p and Sss1p in yeasts. While the role of the α and γ subunit is well understood, the function of the β subunit remains ill-defined. Although numerous species-specific phenotypes have been reported for this protein, the striking sequence conservation among species argue in favour of a universal role. Recently, Feng et al. (2007) reported the surprising finding that the transmembrane domain (TMD) of Sbh1p was sufficient to complement different functions of the entire protein in Saccharomyces cerevisiae, suggesting an important role for this region. The aim of my project was to explore the biological function of the translocon β subunit and its TMD in Schizosaccharomyces pombe. In this yeast, we found that the sbh1+ gene is unessential for viability at 30oC, but is required for growth at low temperature. Knockout of sbh1+ results in sensitivity to cell-wall stress and reduced protein secretion at 23oC. Overexpression of Sbh1p also diminishes protein secretion and results in an elongated cell shape. These phenotypes contrast with those observed S. cerevisiae, as deletion of both Sec61β paralogs in this yeast results in heat sensitivity instead of cold sensitivity. Nevertheless, Sec61β homologs from both S. pombe and S. cerevisiae complement the respective temperature sensitivity of either yeast. This functional complementation can also be accomplished by the human homolog of the translocon β subunit, indicating that a fundamental function of Sec61β is conserved from yeast to human. Remarkably, the TMD of Sec61β homologs from S. pombe, S. cerevisiae and human are sufficient to complement the gene knockout in both fission and budding yeasts. Together, these observations indicate that the TMD of Sec61β exerts a cellular function that is conserved across species.
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Le vieillissement chronologique de Schizosaccharomyces pombe : Implication des voies de détection du glucoseRoux, Antoine E. 04 1900 (has links)
La première augmentation de la longévité en laboratoire fût observée à la suite d’une intervention nutritionnelle consistant en une réduction de l’apport alimentaire chez le rat. Plus tard, ce phénomène a été reproduit dans de très nombreuses espèces et référé en tant que restriction calorique. Le développement des techniques de biologie moléculaire moderne a permis de montrer dans des organismes modèles simples que cette flexibilité du processus de vieillissement était régulée par des facteurs génétiques. De fait, plusieurs mécanismes cellulaires ont alors pu être identifiés comme responsables de ce contrôle du vieillissement. Ces voies de régulation ont révélées être conservées entre les espèces, depuis les levures jusqu’aux organismes multicellulaires tels que le nématode, la mouche ou la souris, suggérant l’existence d’un programme universel de vieillissement dans le vivant.
La levure s’est avéré à plusieurs reprises être un modèle puissant et fiable pour la découverte de gènes impliqués dans ce phénomène. Mon étude a consisté au développement d’un nouveau modèle unicellulaire d’étude du vieillissement à travers l’espèce Schizosaccharomyces pombe appelée aussi levure à fission. La première étape de mon travail a montré que les voies de détection des nutriments gouvernées par la sérine/thréonine protéine kinase A (Pka1) et la sérine/thréonine kinase Sck2 contrôlent le vieillissement chronologique de ces cellules comme il était connu dans la levure Saccharomyces cerevisiae. Ceci permit de valider l’utilisation de la levure à fission pour l’étude du vieillissement. Ensuite, nous avons analysé plus en détail l’effet pro-vieillissement du glucose en étudiant le rôle de sa détection par le récepteur membranaire Git3 couplé à la protéine G (Gpa2) en amont de la kinase Pka1. La perte du signal du glucose par la délétion de Git3 imite partiellement l’effet d’augmentation de longévité obtenu par baisse de la concentration en glucose dans le milieu. De plus, l’effet néfaste du signal du glucose est maintenu en absence de tout métabolisme du glucose suite à la mutation des hexokinases, premières enzymes de la glycolyse. L’ensemble de ces résultats suggèrent que la signalisation du glucose est prédominante sur son métabolisme pour son effet pro-vieillissement. D’autre part, à la fois la suppression de cette signalisation et la baisse de niveau de glucose disponible allongent la durée de vie en corrélation avec une augmentation de la résistance au stress, une hausse d’activité mitochondriale et une baisse de production de radicaux libres. Finalement, le criblage d’une banque de surexpression d’ADNc a permis d’identifier plusieurs gènes candidats responsables de ces effets en aval de la voie de signalisation Git3/PKA.
La recherche sur les mécanismes moléculaires du vieillissement propose une nouvelle approche, un nouvel angle de vue, pour la compréhension des fonctions cellulaires et promet d’apporter de précieuses clefs pour mieux comprendre certaines maladies. En effet, le vieillissement est la première cause d’apparition de nombreuses affections comme les cancers, les maladies cardiovasculaires et métaboliques ou les maladies neurodégénératives tels que les syndromes d’Alzheimer et de Parkinson. / The first increase in life span due to man’s intervention was obtained with rats subjected to a diet reduced in calorie intake. Later, this phenomenon was repeated with many other species and referred as diet restriction or calorie restriction. The development of modern Molecular Biology approaches and the use of simple model organisms demonstrated that the rate of aging was regulated by genetic traits. Indeed, several cellular mechanisms were identified as responsible for the control of aging. These regulatory pathways appear to be conserved throughout species, from yeast to multicellular organisms like nematode, fly and mice, thus suggesting the existence of a universal program of aging.
Yeast proved several times to be a powerful and reliable model for discovering genes involved in the regulation of aging. My study consisted in developing Schizosaccharomyces pombe (also called fission yeast) as a new unicellular model to study aging. The first step of my work was to show that pathways of nutrient detection through kinases involving Pka1 and Sck2 control chronological aging in S. pombe, as it was previously demonstrated in Saccharomyces cerevisiae. This first work validated the use of fission yeast for the study of aging. Subsequently, we analysed in more detail the pro-aging effect of glucose focusing on the role of its signalling through the G-protein Gpa2-coupled membrane receptor Git3, which acts upstream of Pka1. The loss of the glucose signal due to deletion of Git3 mimics partially the effect of increasing longevity by reducing glucose in the medium. Moreover, detrimental effects of glucose signal are maintained in absence of sugar metabolism following loss of hexokinases, the first enzymes of glycolysis. Together, these results suggest that the pro-aging effects of glucose signalling are predominant over those due to metabolism of this sugar. Moreover, both obliteration of this signalling pathway and decrease of glucose availability extend life span, and correlate with an increase in stress resistance, in mitochondrial activity and a lower production of free radicals. Finally, screening a cDNA-overexpression library allowed us to identify several genes candidates responsible for the effects on longevity downstream of Git3/Pka1.
Research in the molecular mechanisms of aging propose holds the promise to bring precious clues as to this mysterious processes affecting all living creatures, and paves the way to unravel the underlying causes of many human diseases. Indeed, aging is the first cause of numerous late-onset pathologies including cancers, cardiovascular diseases or neurodegenerative diseases like Alzheimer and Parkinson syndromes.
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Role proteinů rodiny CSL v odpovědi na oxidativní stres u Schizosaccharomyces pombe / The role of CSL proteins in oxidative stress response of Schizosaccharomyces pombeTvarůžková, Jarmila January 2015 (has links)
Oxidative stress represents a complex and intensely studied phenomenon tightly linked to a range of human diseases, and to aging in many organisms. A plethora of key cellular regulators, including the Notch signaling pathway, have been recently described to respond to the cellular redox status. We have characterized the role of CSL (CBF1/Su(H)/LAG-1) proteins, the effectors of Notch signaling pathway in metazoa, in oxidative stress response in fission yeast. Schizosaccharomyces pombe contains two CSL paralogs, Cbf11 and Cbf12, that have antagonistic functions in the regulation of cell cycle and cellular adhesion. Both proteins are able to bind the canonical CSL motif and activate transcription and, thus, function as genuine CSL transcription factors. We have determined that the strain lacking cbf11 is resistant to hydrogen peroxide but not to menadione, a source of superoxide anion radical. Using double knock-outs to assess genetic interactions we have revealed that the resistance of cbf11 knock-out is dependent on the antioxidants catalase and sulfiredoxin. Genes encoding these antioxidants are under transcriptional control of the Sty1 MAP kinase pathway and the Pap1 transcription factor which are also required for the resistance of Δcbf11 cells. Cbf12 is believed to play only a minor role in...
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Molekulární mechanismus účasti proteinů rodiny CSL v odpovědi na oxidativní stres u Schizosaccharomyces pombe / The molecular mechanism of CSL protein participation in oxidative stress response in Schizosaccharomyces pombeDaněk, Petr January 2015 (has links)
Redox homeostasis maintenance is important for proper organism and cell function, for while relatively low amount of reactive oxygen (and nitrogen) species contributes to the fine tuning of signal transduction, excessive concentration of ROS (oxidative stress) has demonstrably harmful effects and is tightly connected to many pathological states. Cells therefore evolved broad palette of antioxidant mechanisms that express striking level of conservation among different species. Large, intricate stress response signaling networks have been already described; nonetheless, novel molecules employed in stress-related signaling are still being discovered. Several studies recently suggested transcription factors CSL, proteins essential for regulation of metazoan development as effectors of Notch signaling, are also involved in response to oxidative stress. The fission yeast Schizosaccharomyces pombe, well established model of response to various stresses, comprises two paralogs of CSL proteins - Cbf11 and Cbf12. We have found cells depleted of cbf11 are highly resistant to hydrogen peroxide. This resistance appears to be caused by upregulation of important stress responsive genes including ctt1, gst2, pyp2, and atf1. Cbf11 is therefore negative regulator of these genes, which suppresses their expression...
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Antisense RNA-mediated gene silencing in fission yeastRaponi, Mitch, Biochemistry & Molecular Genetics, UNSW January 2001 (has links)
The major aims of this thesis were to investigate the influence of i) antisense gene location relative to the target gene locus (?????location effect?????), ii) double-stranded RNA (dsRNA) formation, and iii) over-expression of host-encoded proteins on antisense RNA-mediated gene regulation. To test the location effect hypothesis, strains were generated which contained the target lacZ gene at a fixed location and the antisense lacZ gene at various genomic locations including all arms of the three fission yeast chomosomes and in close proximity to the target gene locus. A long inverse-PCR protocol was developed to rapidly identify the precise site of antisense gene integration in the fission yeast transformants. No significant difference in lacZ suppression was observed when the antisense gene was integrated in close proximity to the target gene locus, compared with other genomic locations, indicating that target and antisense gene co-localisation is not a critical factor for efficient antisense RNA-mediated gene suppression in vivo. Instead, increased lacZ down-regulation correlated with an increase in the steady-state level of antisense RNA, which was dependent on genomic position effects and transgene copy number. In contrast, convergent transcription of an overlapping antisense lacZ gene was found to be very effective at inhibiting lacZ gene expression. DsRNA was also found to be a central component of antisense RNA-mediated gene silencing in fission yeast. It was shown that gene suppression could be enhanced by increasing the intracellular concentration of non-coding lacZ RNA, while expression of a lacZ panhandle RNA also inhibited beta-galactosidase activity. In addition, over-expression of the ATP-dependent RNA-helicase, ded1, was found to specifically enhance antisense RNA-mediated gene silencing. Through a unique overexpression screen, four novel factors were identified which specifically enhanced antisense RNA-mediated gene silencing by up to an additional 50%. The products of these antisense enhancing sequences (aes factors), all have natural associations with nucleic acids which is consistent with other proteins which have previously been identified to be involved in posttranscriptional gene silencing.
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The DNA damage and the DNA synthesis checkpoints converge at the MBF transcription factorIvanova, Tsvetomira Georgieva, 1978- 30 November 2012 (has links)
DNA damage is an ongoing threat to both the ability of the cell to faithfully transmit genetic information to its offspring as well as to its own survival. In order to maintain genomic integrity, eukaryotes have developed a highly conserved mechanism to detect, signal and repair damage in DNA, known as the DNA damage response (DDR). In fission yeast the two DDR pathways converge at the regulation of single transcriptional factor complex (MBF) resulting in opposite directions. We have shown that when the DNA-synthesis checkpoint is activated, Max1 is phosphorylated by Cds1 resulting in the abrogation of its binding to MBF. As a consequence, MBF-dependent transcription is maintained active until cells are able to overcome the replication challenge. In contrast, upon DNA damage, Chk1 the effector kinase of DNA damage checkpoint is activated and blocks the cell cycle progression, inducing DNA repair and repressing the MBF dependent transcription. We have revealed that Cdc10 is the target of the DNA-damage checkpoint and when cells are treated with MMS or are exposed to IR, Chk1 phosphorylates Cdc10 inducing the exit of MBF from chromatin. The consequence is that under these conditions, MBF-dependent transcription is repressed. Thus, Max1 and Cdc10 couple normal cell cycle regulation and the DNA-synthesis and DNA-damage checkpoints into MBF.
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