Functional studies of new protein-protein interactions potentially involved in homologous recombination in hyperthermophilic archaea : study of interactions between PCNA and Mre11-Rad50 complex & Primase and RadA / Études fonctionnelles des nouvelles interactions protéine-protéine impliquées potentiellement dans la recombinaison homologue chez les archées hyperthermophiles

Lu, Yang

30 November 2018

Les archées hyperthermophiles ont une température optimale de croissance supérieure à 80°C.Les cellules exposées à un stress thermique subissent une augmentation de la sensibilité aux agents induisant des cassures double brin de l’ADN. Les études sur les eucaryotes et bactéries ont démontré que la recombinaison homologue joue un rôle essentiel non seulement dans la réparation de l’ADN, mais aussi dans le redémarrage des arrêts de la fourche de réplication. Les enzymes associées aux étapes initiales de la recombinaison homologue chez les archées sont homologues à celles des eucaryotes, et différentes des analogues bactériens. De plus, plusieurs études ont démontré que les protéines impliquées dans la recombinaison homologue sont essentielles chez les archées hyperthermophiles, soulignant l’importance biologique de cette voie de réparation chez ces organismes particuliers. Le rôle de la recombinaison homologue pour la stabilité génomique a été bien étudié chez les eucaryotes et les bactéries, cependant, peu de ses propriétés fonctionnelles ont été étudiées chez les archées hyperthermophiles. Pour mieux comprendre le mécanisme de recombinaison homologue impliquée au niveau de la maintenance génomique chez les archées, un réseau d’interactions protéine-protéines a été révélé précédemment au laboratoire à partir des protéines de Pyrococcus abyssi. Ces travaux ont démontré de nouvelles interactions où interviennent les protéines de la réplication et les protéines de la recombinaison de l’ADN. L’objet de cette étude de thèse est de présenter deux interactions : PCNA/Mre11-rad50 (MR) complexe et Primase/RadA. Pour la première fois chez P. furiosus, une interaction physique et fonctionnelle a été démontrée entre le PCNA et le complexe MR (l’initiateur de HR). Un motif, situé en position Cterminale de Mre11, permet l’interaction avec PCNA.PCNA stimule l’activité endonucléase du complexe MR à distance proche de l’extrémité 5’ d’une cassure double brin. Cette propriété est en accord avec l’intervention ultérieure des enzymes assurant la suite du mécanisme de réparation par recombinaison homologue. Par ailleurs, les protéines RadA, Primase et P41 ont été produites et purifiées. Leurs fonctions enzymatiques ont été confirmées. Cependant, nous n’avons pas pu caractériser la fonction de l’association de RadA/Primase. / Hyperthermophilic archaea (HA) are found in high-temperature environments and grow optimally above 80°C. Usually, cells exposed to heat stress display an increased sensitivity to agents inducing double-stranded DNA breaks (DSBs). Studies in Eukaryotes and Bacteria have revealed that homologous recombination (HR) plays a crucial role not only in DNA DSBs repair, but also in the collapsed/stalled DNA replication fork restart.Recombinase and various HR-associated enzymes in archaea specifically resemble the eukaryotic homologues, rather than bacterial homologues.Furthermore, several studies have demonstrated the necessity of HR proteins in HA, suggesting that, HR is an important mechanism in HA. HR influencing genome stability has been well studied in Eukaryotes andBacteria, however, few of its functional properties have been studied in HA.To better understand how HR mechanism is involved in the archaeal genome maintenance process, a previous work proposed a protein-protein interaction network based on Pyrococcus abyssi proteins. Through the network, new interactions involving proteins from DNA replication and DNA recombination were highlighted. The targets of the study presented here for two protein interaction are: PCNA/Mre11-rad50 complex (MR complex) and Primase/RadA. For the first time in P. furiosus, we showed both physical and functional interactions between PCNA (Maestro in DNA replication) and MR complex (initiator of HR). We have identified a PCNA-interaction motif (PIP) located in the C-terminal of Mre11, and shown that PCNA stimulated MR complex endonuclease cleavage proximal to the s’ strand of DNA DSBs at physiological ionic strength. For the second interaction, we have purified the proteins PabRadA/PfuRadA, PabPrimase and PabP41, and confirmed its enzymatic functions. However, we were not able to characterize the function of Primase/RadA association.

Archée hyperthermophile

Complexe PCNA/Mre11-Rad50

DNA Primase

Recombinase RadA

Hyperthermophilic archaea

DNA repair/replication/recombination

PCNA/MR complex

Primase/RadA

Faktory ovlivňující odpověď kolorektálního karcinomu na chemoterapeutickou léčbu / The study of the factors affecting colorectal cancer chemotherapy

Dolníková, Alexandra

January 2019

Application of cytotoxic chemotherapy still remains the essential treatment strategy in advanced colorectal cancer. The intrinsic and acquired drug resistance represents one of the reasons that may even lead to failure of cancer therapy. The DNA damage response pathways have been shown to play an important role in the development of chemoresistance. There is sufficient evidence showing the high-frequency deregulated expression of many DNA repair genes across multiple cancer types. An example of such gene in colorectal cancer is MRE11, which encodes protein known as a sensor of DNA double-strand breaks. In year 2016, there was a substantial study published by our group at The Department of Molecular Biology of Cancer (IEM CAS, Prague), the study analysed the association of polymorphisms in predicted microRNA target sites of double-strand breaks (DSBs) repair genes, including MRE11, and clinical outcome and efficacy of chemotherapy in colorectal cancer. Our hypothesis, based on the mentioned study, is that specifically and exactly defined microRNAs with ability to regulate certain DNA repair proteins may not only affect the survival of colorectal cancer cells, but also the sensitivity to chemotherapy. In practical part of the submitted thesis we have identified miR-140 as a potential regulator of...

Étude du rôle de la phosphorylation du complexe Mre11-Rad50-Xrs2 dans le maintien de l'intégrité génomique

Simoneau, Antoine

11 1900

L'ADN de chaque cellule est constamment soumis à des stress pouvant compromettre son intégrité. Les bris double-brins sont probablement les dommages les plus nocifs pour la cellule et peuvent être des sources de réarrangements chromosomiques majeurs et mener au cancer s’ils sont mal réparés. La recombinaison homologue et la jonction d’extrémités non-homologues (JENH) sont deux voies fondamentalement différentes utilisées pour réparer ce type de dommage. Or, les mécanismes régulant le choix entre ces deux voies pour la réparation des bris double-brins demeurent nébuleux. Le complexe Mre11-Rad50-Xrs2 (MRX) est le premier acteur à être recruté à ce type de bris où il contribue à la réparation par recombinaison homologue ou JENH. À l’intersection de ces deux voies, il est donc idéalement placé pour orienter le choix de réparation. Ce mémoire met en lumière deux systèmes distincts de phosphorylation du complexe MRX régulant spécifiquement le JENH. L’un dépend de la progression du cycle cellulaire et inhibe le JENH, tandis que l’autre requiert la présence de dommages à l’ADN et est nécessaire au JENH. Ensembles, nos résultats suggèrent que le complexe MRX intègre différents phospho-stimuli pour réguler le choix de la voie de réparation. / The genome of every cell is constantly subjected to stresses that could compromise its integrity. DNA double-strand breaks (DSB) are amongst the most damaging events for a cell and can lead to gross chromosomal rearrangements, cell death and cancer if improperly repaired. Homologous recombination and non-homologous end joining (NHEJ) are the main repair pathways responsible for the repair of DSBs. However, the mechanistic basis of both pathways is fundamentally different and the regulation of the choice between both for the repair of DSBs remains largely misunderstood. The Mre11-Rad50-Xrs2 (MRX) complex acts as a DSB first responder and contributes to repair by both homologous recombination and NHEJ. Being at the crossroads of both DSB repair pathways, the MRX complex is therefore in a convenient position to influence the repair choice. This thesis unravels two distinct phosphorylation systems modifying the MRX complex and specifically regulating repair by NHEJ. The first relies on cell cycle progression and inhibits NHEJ, while the second requires the presence of DNA damage and is necessary for efficient NHEJ. Together, our results suggest a model in which the MRX complex would act as an integrator of phospho-stimuli in order to regulate the DSB repair pathway choice.

Complexe Mre11-Rad50-Xrs2

bris double-brins

réponse aux dommages à l'ADN

recombinaison homologue

JENH

syndrome de Nimègue

Tel1/ATM

résection

CDK

Mre11-Rad50-Xrs2 complex

double-strand break

cell cycle

DNA damage response

DNA damage checkpoints

homologous recombination

NHEJ

Nijmegen breakage sundrome

Tel1/ATM

CDK

Étude du rôle de la phosphorylation du complexe Mre11-Rad50-Xrs2 dans le maintien de l'intégrité génomique

Simoneau, Antoine

11 1900

L'ADN de chaque cellule est constamment soumis à des stress pouvant compromettre son intégrité. Les bris double-brins sont probablement les dommages les plus nocifs pour la cellule et peuvent être des sources de réarrangements chromosomiques majeurs et mener au cancer s’ils sont mal réparés. La recombinaison homologue et la jonction d’extrémités non-homologues (JENH) sont deux voies fondamentalement différentes utilisées pour réparer ce type de dommage. Or, les mécanismes régulant le choix entre ces deux voies pour la réparation des bris double-brins demeurent nébuleux. Le complexe Mre11-Rad50-Xrs2 (MRX) est le premier acteur à être recruté à ce type de bris où il contribue à la réparation par recombinaison homologue ou JENH. À l’intersection de ces deux voies, il est donc idéalement placé pour orienter le choix de réparation. Ce mémoire met en lumière deux systèmes distincts de phosphorylation du complexe MRX régulant spécifiquement le JENH. L’un dépend de la progression du cycle cellulaire et inhibe le JENH, tandis que l’autre requiert la présence de dommages à l’ADN et est nécessaire au JENH. Ensembles, nos résultats suggèrent que le complexe MRX intègre différents phospho-stimuli pour réguler le choix de la voie de réparation. / The genome of every cell is constantly subjected to stresses that could compromise its integrity. DNA double-strand breaks (DSB) are amongst the most damaging events for a cell and can lead to gross chromosomal rearrangements, cell death and cancer if improperly repaired. Homologous recombination and non-homologous end joining (NHEJ) are the main repair pathways responsible for the repair of DSBs. However, the mechanistic basis of both pathways is fundamentally different and the regulation of the choice between both for the repair of DSBs remains largely misunderstood. The Mre11-Rad50-Xrs2 (MRX) complex acts as a DSB first responder and contributes to repair by both homologous recombination and NHEJ. Being at the crossroads of both DSB repair pathways, the MRX complex is therefore in a convenient position to influence the repair choice. This thesis unravels two distinct phosphorylation systems modifying the MRX complex and specifically regulating repair by NHEJ. The first relies on cell cycle progression and inhibits NHEJ, while the second requires the presence of DNA damage and is necessary for efficient NHEJ. Together, our results suggest a model in which the MRX complex would act as an integrator of phospho-stimuli in order to regulate the DSB repair pathway choice.

Complexe Mre11-Rad50-Xrs2

bris double-brins

réponse aux dommages à l'ADN

recombinaison homologue

JENH

syndrome de Nimègue

Tel1/ATM

résection

CDK

Mre11-Rad50-Xrs2 complex

double-strand break

cell cycle

DNA damage response

DNA damage checkpoints

homologous recombination

NHEJ

Nijmegen breakage sundrome

Tel1/ATM

CDK

The Role of Saccharomyces Cerevisiae MRX Complex and Sae2 in Maintenance of Genome Stability

Ghodke, Indrajeet Laxman

January 2015

In eukaryotes, the repair of DSBs is accomplished through two broadly defined processes: Non-Homologous End Joining (NHEJ) and Homologous Recombination (HR). The central step of HR is pairing and exchange of strands between two homologous DNA molecules, which is catalyzed by the conserved Rad51/RecA family of proteins. Prior to this step, an essential step in all HR pathways i.e. 5'→3' resection of broken DNA ends to generate 3' single stranded DNA tails. At the molecular level, initiation of DNA end resection is accomplished through the concerted action of MRX complex (Mre11, Rad50 and Xrs2) and Sae2 protein. To elucidate the molecular basis underlying DSB end resection in S. cerevisiae mre11 nuclease deficient mutants, we have performed a comprehensive analysis of the role of S. cerevisiae Mre11 (henceforth called as ScMre11) in the processing of DSB ends using a variety of DNA substrates. We observed that S. cerevisiae Mre11(ScMre11) exhibits higher binding affinity for single- over double-stranded DNA and intermediates of recombination and repair and catalyzes robust unwinding of substrates possessing a3' single-stranded DNA overhang but not of 5' overhangs or blunt-ended DNA fragments. Furthermore, reconstitution of DSB end resection network in-vitro revealed that Rad50, Xrs2, and Sae2 potentiated the DNA unwinding activity of Mre11. Since the exonuclease activity of Mre11 is of the opposite polarity to that expected for resection of DSBs, unwinding activity of Mre11 in conjunction with Rad50, Xrs2, and Sae2 might provide an alternate mechanism for the generation of ssDNA intermediates for DSB end repair and HR. Additionally, ScMre11 displays strong homotypic as well as heterotypic interaction with Sae2. In summary, our results revealed important insights into the mechanism of DSB end processing and support a model in which Sae2, Rad50, and Xrs2 positively regulate the ScMre11-mediated DNA unwinding activity via their direct interactions or through allosteric effects on the DNA or cofactors. Prompted by the closer association of MRX and Sae2 during DSB end processing, we asked whether Sae2 and its endonuclease activity is required for cellular response to replication stress caused by DNA damage. Toward this end, we examined the sensitivity of S. cerevisiae wild type, sae2Δ and various SAE2 mutant strains defective in phosphorylation and nuclease activity in the presence of different genotoxic agents, which directly or indirectly generate DSBs during replication. We found that S. cerevisiae lacking SAE2 show decreased cell viability, altered cell cycle dynamics after DNA damage, and more specifically, that Sae2 endonuclease activity is essential for these biological functions. To corroborate the genetic evidences for role of SAE2 during replicative stress, we investigated SAE2 functions in-vitro. For this, we purified native Sae2 protein and nuclease dead mutant of Sae2 i.e. sae2G270D. Our studies revealed dimeric forms of both the wild type and mutant forms of Sae2. Furthermore, Sae2 displays higher binding affinity and catalytic activity with branched DNA structures, such as Holliday junction and replication forks. By using nuclease dead Sae2 protein i.e. sae2G270D, we confirmed that the endonuclease activity is not fortuitous and is intrinsic to Sae2 polypeptide. Furthermore, nuclease-defective Mre11 stimulates Sae2endonuclease activity. Mapping of the cleavage sites of Sae2 revealed a distinct preference for cleavage on the 5' end of the Holliday junction, suggesting the importance of Sae2 nuclease during recombination mediated restart of the reversed replication fork. In summary, our data clearly demonstrate a previously uncharacterized role for Sae2 nuclease activity in resection of DSB ends, processing of intermediates of DNA replication/repair and attenuation of DNA replication stress-related defects in S. cerevisiae.

Saccharomyces Cerevisiae MRX Complex

Genome Stability

DNA Repair

DNA Damage

DNA Double Strand Break

Non Homologous End Joining

Homologous Recombination

Saccharomyces Cerevisiae Sae2

DNA Replication

DNA Double Stranded Breaks Repair

Sae2 Protein

Saccharomyces cerevisiae Mre11

Biochemistry

Construction and Analysis of a Genome-Wide Insertion Library in Schizosaccharomyces pombe Reveals Novel Aspects of DNA Repair

Li, Yanhui

09 February 2015

No description available.

Genetics

Hermes transposon

S pombe

insertion mutant library

yeast deletion library

DNA barcode

pooling strategy

multiplexed high-throughput sequencing

DSB

DNA repair

NHEJ

Mre11-Rad50-Nbs1

Ctp1

essential genes

non-essential genes

non-coding RNA