The correlation of DNA repair protein Mre11 with lung adenocarcinoma

Hsieh, Kun-chou

18 August 2011

In recent decade, lung cancers had the highest incidence and mortality rate among all cancers in Taiwan. Among lung cancers, adenocarcinoma was the most frequent type. The chemotherapy was still the main choice in treating lung cancer by the mechanism of destroying DNA, but the response rate kept low. The function of DNA repair makes cancer cells resistant to chemotherapy. Therefore, this study focused on the effect of cancer cell growth by silencing Mre11. The first part of this study was to make a tissue microarray consisting of adenocarcinoma from 57 patients. Immunohistochemistry staining for Mre11 was done. The correlation of Mre11 expression and clinical variables with survival was analyzed. The second part was tried to knockdown Mre11 in A549 cell by shRNA. Another A549 cell line containing empty vector was selected as control group. These cell lines were then ready for XTT method, soft agar colony formation assay, flow cytometry and nude mice assay. In the clinical data, the absence of lymph node and distant site metastasis were good prognosis factor for longer survival. Although the high expression on Mre11 had longer survival, this variable was not a true independent factor. On XTT method and soft agar colony formation assay, the A549 cells with Mre11 knockdown had a slower proliferation and fewer colony numbers, respectively. The cell cycle demonstrated an elevated G0/G1 and S phase and depressed G2/M phase in A549 cells with Mre11 knockdown. The tumor arising from A549 cells with Mre11 knockdown in the nude mice also had a smaller size. Based on the above study, inhibition of Mre11 may result in a reduction of tumor growth and provide another choice to treat lung cancer.

tumor growth

cell cycle

DNA repair

lung adenocarcinoma

Mre11

ゲノムストレスに対する細胞応答機構の解明

河村, 香寿美

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(人間・環境学) / 甲第21874号 / 人博第903号 / 新制||人||215(附属図書館) / 2018||人博||903(吉田南総合図書館) / 京都大学大学院人間・環境学研究科相関環境学専攻 / (主査)准教授 小林 純也, 教授 宮下 英明, 准教授 三浦 智行 / 学位規則第4条第1項該当 / Doctor of Human and Environmental Studies / Kyoto University / DGAM

genome instability

stress response

MRE11

nucleolin

DNA repair

361

Cellular and Viral Factors Governing DNA-PK Activation During Adenovirus Infection

Chen, Christopher L.

18 April 2022

No description available.

Microbiology

adenovirus

DNA damage

DNA-PK

Ku86

Mre11

E4 ORF3

ELUCIDATION OF FACTORS IMPACTING HOMOLOGOUS RECOMBINATION IN MAMMALIAN MEIOSIS

Cherry, Sheila M.

January 2007

No description available.

Biology, Genetics

meiosis

recombination

synapsis

Mre11

MLH1

Pms2

Mechanisms and regulation of dsDNA break repair in the Sulfolobus genus of thermophilic archaea

Bray, Sian Marian

January 2019

DNA is constantly subjected to chemical and mechanical damage. The ability to repair the lesions sustained is essential for all life. Double stranded DNA (dsDNA) breaks are especially toxic as both antiparallel strands of DNA are severed. The most high fidelity mechanism available to repair this damage is homologous recombination, a mechanism that uses homology from the sister chromatid to replace any lost information. Key proteins involved in maintaining genomic stability this way are conserved in all domains of life. One such component is the Mre11/Rad50 complex that is involved in the initial recognition of damage and recruitment of subsequent repair factors. Understanding the function of this DNA repair complex and any associated proteins has implications for human cancers and aging. The proteins of thermophilic archaea present an excellent opportunity to study these systems in a robust, tractable and eukaryote-like system. Archaea are in many ways biochemically unique, for example they are the only domain capable of methanogenesis. However archaea share a high level of homology with eukaryotes in many essential cellular processes such as DNA replication, homologous recombination and protein degradation. In thermophilic archaea the mre11/rad50 genes are clustered in an operon with the herA/nurA genes that form a helicase/nuclease complex. This has lead to speculation that the four proteins work together during homologous recombination to produce the 3' overhangs required by RadA to identify homology. As part of this investigation I have performed extensive bioinformatic searches of a variety of archaeal/bacterial systems. These analyses have revealed operonic linkages to other known recombinational helicase/nucleases, such as AddAB and RecBCD. These genomic linkages are especially prevalent in thermophilic organisms suggesting their functional relevance is particularly acute in organisms exposed to a high amount of genomic stress. Comparison of the evolutionary trees, constructed for each protein, makes a single genomic linkage event the most likely scenario, but cannot definitively exclude other possibilities. Exhaustive attempts were made to demonstrate an interaction between Mre11/Rad50 and HerA/NurA. Despite analysis by nickel/cobalt pulldown, immunoprecipitation, analytical gel filtration, ITC and OCTET an interaction could not be confirmed or definitively dismissed. However in the process an interesting Rad50 tetrameric assembly was identified and attempts were made to crystalize it. Hexameric helicases and translocases are key to the replication and DNA packaging of all cellular life and multiple viruses. The hexameric translocase HerA is a robust model for investigating the common features of multimeric ATPases as it is extremely stable and experimentally tractable. Here it is revealed that HerA exists in a dynamic equilibrium fluctuating between hexameric and heptameric forms with rapidly interchanging subunits. This equilibrium can be shifted to heptamer by buffering conditions or towards the hexamer by the physical interaction with the partnering nuclease NurA, raising the possibility that these alternate states may play a role in translocase assembly or function. A novel C-terminal brace, (revealed by a collaborative crystallographic structure) is investigated; as well as stabilizing the assembly, this brace reaches over the ATPase active site of its neighbouring subunit. It is seemingly involved in the conversion of energy generated by ATP hydrolysis into physical movement in the central channel of the hexamer. The regulation of homologous recombination is extremely important to prevent aberrant activity, resulting in mutations and genome reorganization. In eukaryotic organisms, it is well established that post-translational modifications and protein turnover at the proteosome play important roles in this control. In particular, there is significant interest currently in the ubiquination-proteasome destruction pathway as a mechanism for extracting DNA repair components from chromatin at the termination of the DNA repair process. To date no Ubiquitin proteins have been identified in the Archaea, however related proteins URMs/SAMPs (Ubiquitin Related Modifier/Small Archaeal Modifier Protein) have previously been identified. URMs are thought to have evolved from a common antecedent to eukaryotic ubiquitin and likely represent an evolutionary 'missing link' in the adaption of sulphur transfer proteins for covalent modifications. There has been speculation that Urm1 may play a similar role to ubiquitin in the proteasome degradation pathway and we have recently provided evidence to corroborate this. Here the potential for modification of Mre11/Rad50/HerA/NurA by Urm1 was investigated. Indeed Rad50 shows evidence of clear urmylation both in vivo and in vitro. Western blotting and mass spec analysis confirmed the covalent attachment of Urm1 to Rad50. Furthermore I present preliminary evidence that this urmylation can lead to the destruction of Rad50 via a direct physical interaction with the proteasome. This is the first evidence of such a regulatory system for Rad50. Investigating the urmylation and destruction of Rad50 was closely linked to investigating the archaeal proteasome, a close homologue of the eukaryotic proteasome. To date the majority of archaeal core proteasomes examined were believed to consist of only two subunits; alpha and beta. The subunits are arranged into heptameric rings, which then form an alpha/beta/beta/alpha stack with a single channel running through the centre of all four rings. Here we reveal that in Sulfolobus species the inner catalytic chambers are made up of mixed beta rings composed of two subunits. The first plays a crucial structural role but appears catalytically inert, while the second conveys catalytic activity. Here we investigate an inactive complex, containing only the structural beta subunit, and an active complex, containing both beta subunits. First, electron microscopy was performed on both complexes revealing the expected four-layered toroidal stack. Both complexes were subsequently investigated crystallographically. A 3.8 Å structure was determined for the inactive complex. As well as being one of the few archaeal core proteasome structures, this is also an important first step towards structurally investigating the novel three-subunit proteasome. The discovery of active and inactive beta subunits in the archaea brings them even closer to eukaryotic proteasomal systems, making the archaea even more valuable as model systems.

Caracterização funcional de diferentes componentes das vias metabólicas de resposta ao dano DNA no fungo filamentoso \'Aspergillus nidulan\' / Functional characterization of different components of the metabolic pathways involved in the filamentous fungi Aspergillus nidulans DNA damage response

Malavazi, Iran

25 July 2007

O complexo Mre11 (Mre11/Rad50/Nbs1) é uma componente chave da resposta celular ao dano ao DNA em humanos e recentes observações sugerem que estas proteínas são em parte responsáveis pela interface ente o ensoreamento do dano ao DNA, seu reparo e as funções das proteínas envolvidas nos pontos de checagem do ciclo celular. Em Aspergillus nidulans, a partir de um screening para o isolamento de letais sintéticos na ausência de dineína, o gene sldIRAD50 foi clonado como um desses letais sintéticos através da complementação do fenótipo de deficiência de conidiação do mutante. Foi identificada uma transversão G-C na posição 2509 (Ala-692-Pro) no mutante sldI1444 a qual está presente na região de dobradiça da proteína. Essa mutação causa sensibilidade a vários agentes mutagênicos. Uma linhagem mutante sldIRAD50::pyrG foi construída a qual apresentou também vários defeitos na reposta celular ao dano ao DNA incluindo sensibilidade a várias drogas mutagênicas, defeito no ponto de checagem de replicação do DNA e na viabilidade dos ascosporos. Além disso, o gene sldIRAD50 interage geneticamente com bimEAPC1 para o controle do spindle pole checkpoint durante a segregação cromossômica sugerindo um novo papel para o complexo Mre11. Em atuação paralela com o complexo Mre11, duas proteínas quinases ditas apicais, ATM e ATR coordenam a transdução do sinal do dano ao DNA para proteínas efetoras do reparo. A proteína ATM está mutada na síndrome de instabilidade cromossômica herdada Ataxia Telangiectasia. Para a caracterização do homologo de ATM em A. nidulans AtmA, uma linhagem mutante atmAATM foi isolada. Esse mutante apresentou falha na reposta ao dano ao DNA, como seus homólogos em vários outros organismos mostrando defeitos no ponto de checagem intrafase S e G2/M, além de sensibilidade a camptothecin e bleomicina. Ainda, o extrato protéico bruto desse mutante não foi capaz de fosforilar o homologo de NBS1 em A. nidulans, ScaA. Além das conhecidas funções de ATM na resposta ao dano ao DNA, foi verificado que o mutante atmAATM apresentou uma acelerada cinética de divisão nuclear e severos defeitos no estabelecimento e manutenção do eixo de crescimento polarizado, evidenciando uma função ainda não descrita para ATM no crescimento polar. Provavelmente, AtmA regula a função e/ou localização de proteínas chaves para a formação do eixo de polarização. Diante disso, para investigar as vias metabólicas que são controladas por esse gene, o perfil transcricional do mutante atmAATM, em comparação com a linhagem selvagem foi verificado em diferentes condições de crescimento. Os resultados indicaram um importante papel da via das pentoses fosfato na proliferação celular monitorada pela AtmA. Além disso, foram identificados vários genes com a expressão do mRNA diminuída envolvidos no crescimento polarizado, na síntese de ácido fosfatídico e de ergosterol e no tráfico intracelular, secreção e transporte vesicular. Buscando identificar genes que participam da resposta celular ao dano ao DNA causado pela droga anti topoisomerase I, camptothecin, foram utilizados filtros de macroarray de A. nidulans contendo 2787 genes deste organismo para monitorar a expressão gênica da linhagem selvagem e do mutante uvsBATR, num experimento de indução com CPT por 30, 60 e 120 minutos. Os resultados revelaram um total de 1512 e 1700 genes modulados na linhagem selvagem e uvsBATR respectivamente, em pelo menos um ponto experimental. Seis desses genes que apresentaram aumento da expressão de mRNA na linhagem selvagem e diminuição da linhagem uvsBATR foram caracterizados: fhdA (que codifica para uma proteína com domínio fork-head associated), tprA (uma proteína hipotética que apresenta o domínio tetratrico peptide repeat), mshA (um homólogo MutS6 envolvido em mismatch repair), phbA (um homólogo da prohibitina), uvsCRAD51 e cshA (homólogo da proteína CSB envolvida no reparo por excisão de nucleotídeos e ligada a Síndrome de Cockayne). A indução transcricional desses genes na presença de CPT requer a função de uvsBATR. Estes genes foram deletados e surpreendentemente apenas uvsCRAD51 apresentou sensibilidade a CPT, enquanto os outros mostraram sensibilidade a outros agentes que causam dano ao DNA e estresse oxidativo. Além disso, com exceção de uvsCRAD51, a deleção desses genes leva a supressão parcial da sensibilidade a menadiona e paraquat do mutante uvsBATR. Esses resultados indicaram um comportamento heterogêneo de sensibilidade durante o crescimento na presença de agentes que causam dano direto ou indireto ao DNA, evidenciando que o perfil transcricional não é determinante para predizer a função de um gene na proteção da célula a determinada droga que causa dano ao DNA. / The Mre11 protein complex (Mre11/Rad50/Nbs1) has emerged as a central component in the human cellular DNA damage response, and recent observations suggest that these proteins are at least partially responsible for the linking of DNA damage detection to DNA repair and cell cycle checkpoint functions. In Aspergillus nidulans, the sldI1444D mutant was isolated in a screen for dynein synthetic lethals. The sldIRAD50 gene was cloned by complementation of the sporulation deficiency phenotype of this mutant. A transversion G-C at the position 2509 (Ala-692-Proamino acid change) in the sldI1444D mutant causes sensitivity to several DNAdamaging agents. The mutation sldI1 occurs at the CXXC hinge domain of Rad50. An inactivation strain sldIRAD50::pyrG was constructed. Besides sensitivity to a number of DNA-damaging agents, this deletion strain was also impaired in the DNA replication checkpoint response and in ascospore viability. Also, sldIRAD50::pyrG geneticaly interacted with bimEAPC1, acting in the spindle pole checkpoint control during segregation, suggesting a new possible role of Mre11 complex. In parallel to the Mre11 complex, two apical quinases ATM and ATR respond to DNA damage and transduce the signal to effector proteins. In humans, mutations in ATM cause the devastating neurodegenerative disease Ataxia Telangiectasia. Here we characterized the homolog of ATM (AtmA) in the filamentous fungus A. nidulans. The deletion strain atmA presented defects in the DNA damage response as previously shown in other model organisms including intra S-phase and G2/M checkpoint defects, sensitivity to camptothecin and bleomycin. Also, the crude extract from the mutant strain did not phosphorylate the NBS1 homologue ScaA. In addition to its expected role in the DNA damage response, the atmA mutant showed increased nuclear division kinetics and severe defects in polarized hyphal growth, indicating a novel feature for the ATM gene. Probably, AtmA regulates the function and/or localization of landmark proteins required for the formation of a polarity axis. We extended these studies by investigating which pathways are controlled by AtmA during proliferation and polar growth by comparatively determining the transcriptional profile of A. nidulans wild type and atmA mutant strains in different growth conditions. Our results indicated an important role of the pentose phosphate pathway in the fungal proliferation during endogenous DNA damage and polar growth monitored by the AtmA kinase. Furthermore, we identified several genes that have decreased mRNA expression in the atmA mutant that are involved in the formation of polarized hyphae and control of polar growth; in the biosynthesis of phosphatidic acid and ergosterol; and intracellular trafficking, secretion, and vesicular transport. In order to identify genes that responded to the DNA damage mediated by the anti- toposomerase I drug, camptothecin, we used an A. nidulans macroarray carrying sequences of 2,787 genes from this fungus to monitor gene expression of both wild-type and uvsBATR in a time-point experiment where mycelium was exposed to 60, 90 and 120 minutes to the drug. The results revealed a total of 1,512 and 1,700 genes in the wild-type and uvsBATR deletion mutant strain that displayed statistically significant difference in at least one experimental time-point. We characterized six genes that have increased mRNA expression in the presence of CPT in the wild-type strain relative to the uvsBATR mutant strain: fhdA (encoding a fork head associated domain protein), tprA (encoding a hypothetical protein that contains a tetratrico peptide repeat), mshA (encoding a MutS homologue involved in mismatch repair), phbA (encoding a prohibitin homologue), uvsCRAD51 (the homologue of the RAD51 gene), and cshA (encoding a homologue of the excision repair protein ERCC-6 [Cockaynes syndrome protein]). The induced transcript levels of these genes in the presence of CPT required uvsBATR. These genes were deleted, and surprisingly, only the uvsCRAD51 mutant strain was sensitive to CPT; however, the others displayed sensitivity to a range of DNA-damaging and oxidative stress agents. Moreover, with the exception of UvsC, deletion of each of these genes partially suppressed the sensitivity of the uvsB strain to menadione and paraquat. These results indicated a very complex and heterogeneous sensitivity behavior during growth in the presence of agents that directly or indirectly cause DNA damage and the transcriptional response to DNAdamaging agents does not necessarily identify the genes that protect against these agents.

Aspergillus nidulans

Aspergillus nidulans

ATM e crescimento polar

complexo Mre11

dano ao DNA

DNA damage

microarray

microarray

Mre11 complex. ATM

polar growth

Réparation des cassures double brin de l'adn chez les mammifères : rôle des protéines MRE11 et BLM dans l’initiation de la ligature d’extrémités non homologues (NHEJ ) / « DNA double strand break repair in mammalian cells : role of MRE11 and BLM proteins at the initiation of Non Homologous End Joining (NHEJ)

Grabarz, Anastazja

23 September 2011

Les cassures double brin de l’ADN (CDB) sont des lésions qui peuvent conduire à des réarrangements génétiques. Deux voies sont impliquées dans la réparation de ces dommages: la recombinaison homologue (HR) et la ligature d’extrémités nonhomologues (NHEJ).Au laboratoire un substrat intrachromosomique permettant de mesurer l’efficacité et la fidélité du NHEJ à été mis en place (Guirouilh-Barbat 2004). Cette approche a permis de démontrer l’existence d’une voie alternative à KU qui utilise des microhomologies présentes de part et d’autre de la cassure - le NHEJ alternatif (Guirouilh-Barbat 2004, Guirouilh-Barbat et Rass 2007). Les travaux de ma thèse consistent à caractériser les principaux acteurs de cette voie. En absence de KU, cette voie alternative du NHEJ, s'initierait tout d’abord parla résection d'extrémités d’ADN non protégées. Nous avons montré que l’activité nucléasique de MRE11 est nécessaire à ce mécanisme. La surexpression de MRE11 conduit à une stimulation du NHEJ, contrairement à l’extinction de la protéine par siRNA, résultant en une baisse de son efficacité de deux fois. Nos résultats montrent également que les protéines RAD50 et CtIP agissent dans la même voie que MRE11. De plus, dans les cellules déficientes pour XRCC4, la MIRIN – un inhibiteur du complexe MRN - conduit à une chute de l'efficacité de la réparation, démontrant le rôle de MRE11 dans la voie alternative du NHEJ. Nous avons aussi montré que MRE11 peut agir de manière dépendante et indépendante de la kinase ATM (Rass et Grabarz, Nat Struct Mol Biol 2009). L'initiation de la résection de la cassure doit être ensuite poursuivie par une dégradation plus importante de l'ADN qui est assuré par les protéines Exo1 et Sgs1/Dna2 chez la levure. Chez les mammifères, des études in vitro suggèrent un modèle similaire à deux étapes. Nous avons choisi de nous intéresser au rôle de la protéine BLM, qui est l’un des homologues humains de la RecQ hélicase Sgs1, dans la résection. Nos expériences montrent que l’absence de BLM diminue l’efficacité du NHEJ. De plus, l’extinction de BLM conduit à une augmentation d’évènements infidèles lors de la réparation par NHEJ et l’apparition d’évènements de résection de grande taille (>200nt). Ceci suggère que BLM protège contre de longues résections lors de la mise en place du NHEJ alternatif. De manière cohérente, BLM est impliquée dans la protection contre la résection dépendante de CtIP lors des étapes précoces de la recombinaison homologue. En conclusion, nos résultats montrent un rôle prédominant de BLM dans la protection contre un excès de résection médiée par CtIP. BLM interagit avec 53BP1 aux sites de dommages de manière dépendante d’ATM afin de réguler le processus de résection, en contrecarrant l’action de BRCA1. Ceci souligne à nouveau le rôle essentiel de BLM dans la protection contre la résection et la favorisation de la conversion génique sans crossing-over, ce qui est primordial pour le maintien de la stabilité du génome. / DNA double strand breaks (DSBs) are highly cytotoxic lesions, which can lead to genetic rearrangements. Two pathways are responsible for repairing these lesions : homologous recombination (HR) and non homologous end joining (NHEJ). In our laboratory, an intrachromosomal substrate has been established in order to measure the efficiency and the fidelity of NHEJ in living cells (Guirouilh-Barbat 2004). This approach led us to identify a KU-independent alternative pathway, which uses microhomologies in the proximity of the junction to accomplish repair – the alternative NHEJ (Guirouilh-Barbat 2004, Guirouilh-Barbat et Rass 2007). The goal of my thesis consisted in identifying and characterising major actors of this pathway. In the absence of KU, alternative NHEJ would be initiated by ssDNA resection of damaged ends. We showed that the nuclease activity of MRE11 is necessary for this mechanism. MRE11 overexpression leads to a two fold stimulation of NHEJ efficiency, while the extinction of MRE11 by siRNA results in a two fold decrease. Our results demonstrate that the proteins RAD50 and CtIP act in the same pathway as MRE11. Moreover, in cells deficient for XRCC4, MIRIN – an inhibitor of the MRN complex – leads to a decrease in repair efficiency, implicating MRE11 in alternative NHEJ. We also showed that MRE11 can act in an ATM-dependent and independent manner (Rass et Grabarz Nat Struct Mol Biol 2009). The initiation of break resection needs to be pursued by a more extensive degradation of DNA, which is accomplished in yeast by the proteins Exo1 and Sgs1/Dna2. In human cells, in vitro studies have recently proposed a similar model of a two-step break resection. We chose to elucidate the role of one of the human homologs of Sgs1 – the RecQ helicase BLM – in the resection process. Our experiments show, that he absence of BLM decreases the efficiency of end joining by NHEJ, accompanied by an increase in error-prone events, especially long-range deletions (>200nt). This suggests that BLM protects against extensive resection during alternative NHEJ. Furthermore, BLM is implicated in the protection against CtIP-dependent resection at the initiation of HR. In conclusion, our results show a major role of BLM in protecting against an excess of resection, mediated by the MRN cofactor – CtIP. BLM interacts with 53BP1 at sites of damage, in an ATM-dependent manner, in order to regulate the resection process and counteract BRCA1 activity. This underlines the novel role of BLM in the protection against resection and favouring gene conversion events without crossing-over, which is substantial for maintaining genomic integrity.

NHEJ

Cassure double brin

Réparation

Complexe MRN

BLM

Syndrome de Bloom

Résection

MRE11

NHEJ

Double strand breaks

Rapair

MRN complex

BLM

Bloom Syndrome

Resection

MRE11

Biochemical Characterization Of Saccharomyces cerevisiae Mre11/Rad50/Xrs2 Using Telomeric DNA : A Role For The Endonucleolytic Activity Of Mre11 In Telomere Length Maintenance And Its Regulation By Rad50

Ghosal, Gargi

04 1900

Meiotic recombination is a prerequisite for exchange of genetic information in all Sexually reproducing organisms. This process is initiated by the formation of double stranded breaks (DSBs) in DNA followed by homology directed repair. The process is subjected to surveillance mechanisms that control DSB formation and allow for repair of DSBs by halting cell cycle progression. Interestingly, though generation of DSBs is an Essential event in meiosis they are nevertheless regarded as the most lethal forms of DNA damage. If left unrepaired a single DSB can lead to gene deletion, duplication, translocations and missegregation of large chromosome fragments leading to cell death. In Saccharomyces cerevisiae, genetic screens for mutants defective in meiotic recombination led to the identification of a group of genes called the RAD52 epistasis group which includes RAD50, RAD51, RAD52, RAD54, RAD55, RAD57, RAD59, MRE11 and XRS2. A subset of these genes, namely MRE11, RAD50 and XRS2, have been shown by genetic studies to be essential for several nuclear events including sensing DSBs, double strand break repair (DSBR) by homologous recombination (HR) and non homologous end joining (NHEJ), telomere length maintenance, cell cycle activation in response to DSBs, mitotic and meiotic recombination. In vitro, Mre11 displays Mn2+-dependent endonuclease activity on ssDNA, 3'-5' Exonuclease on single- and double-stranded DNA, strand annealing and weak hairpin Opening activities. Mutational analyses have revealed two functional domains in Mre11- Then terminal nuclease domain involved in telomere length maintenance and DSB Processing and the C terminal DNA binding domain involved in DSB formation during Meiosis. Rad50, a 153 kDa protein shares homology with the SMC (Structural Maintenance of Chromosome) family of proteins which are involved in chromosome Condensation and cohesion. It consists of a bipartite N- and C terminal Walker A and Walker B motifs separated by a heptad repeat sequence which folds into an antiparallel Coiled-coil structure. The heptad repeats are separated by a metal binding globular region the Zn hook. Rad50 is an ATP-dependent DNA-binding protein. hRad50 regulates the exonuclease activity of hMre11. Unlike Mre11 and Rad50, which are evolutionarily conserved, Xrs2 is found only in S. cerevisiae and Nbs1 in mammals. Xrs2 appears to be sequence non-specific DNA- binding protein. Xrs2 in yeast or Nbs1 is its counterpart in mammals target Mre11 and Rad50 to the sites of DNA damage and mediate S-phase cell cycle checkpoint activation. Mutations in either one of the MRX subunits results in defects in repair of DSBs, activation of cell cycle checkpoint and shortened telomeres leading to genomic instability. Hypomorphic mutations in MRE11 and NBS1 lead to genetic disorders- A-TLD (ataxia-telangiectasia-like disorder) and NBS (Nijmegen breakage syndrome) respectively, that are phenotypic ally related to AT (ataxia-telangiectasia) caused by mutations in ATM. Patients with AT, A-TLD or NBS syndromes are hypersensitive to radiomimetic agents and are predisposed to cancer. Several lines of evidence suggest that S. cerevisiae strains bearing mre11Δ, rad50Δ or xrs2Δ display shortening of telomeres. Telomeres are the nucleoprotein ends of all linear eukaryotic chromosomes that are important in maintaining the integrity of the genome.Telomeres are comprised of repetitive G rich sequence most of which is double stranded but the extreme 3' end protrudes to form 3' single stranded overhang called the G tail. elopers are essential in preventing end-end fusion of chromosome, are important for chromosome replication, segregation and genome stability. Genetic studies have implicated the MRX complex in both telomerase-dependent and independent telomere length maintenance. Studies have indicated a direct role for S. cerevisiae MRE11 in the proper establishment of telomere end-structure. However, the molecular mechanism of MRX at telomeres is poorly understood. To understand the role(s) of MRX complex at telomeres, it is important to elucidate the biochemical activities of MRX complex as well as its individual subunits on the telomere DNA structures. Since, Mre11 complex is known to function in several processes related to DNA metabolism it becomes imperative to study the function of Mre11 complex on DNA substrates in the context of a given nuclear process. The 3' single trended telomeric sequence is capable of acquiring folded conformation(s) as a mechanism of end protection which is mediated by several telomere-specific and nonspecific ending proteins. In mammals, the 3' ssDNA has been demonstrated to fold into tloop configuration mediated by some of the components of sheltrin protein complex, wherein the ssDNA invades the duplex DNA resulting in the formation of a displacement loop (D loop). Evidence for the formation of t-loop has been shown in vitro with human telomeres. However, the formation of t-loops has not been demonstrated in S. cerevisiae. Nevertheless, there is growing body of evidence which suggests the formation of alternative DNA structures such as G4 DNA at the yeast telomeres. G quadruplexes (G quartets or G4 DNA) are thermodynamically stable structures formed by Hoogsteen base pairing between guanine residues. In a G quartet the four guanine residues are paired, where each guanine residue is an electron acceptor and a donor and stabilized by a metal cation. The presence of G rich motifs at the promoter regions, rDNA, telomeres and recombination hot spots indicate that G4 DNA has important functions in vivo. Although the existence of G4 DNA has been the subject of much debate, the identification of several proteins that promote (Rap1, Hop1, Topo I, TEBPβ), modify and resolve (POT1, TERT, KEM1, GQN1, BLM, WRN, Rte1) G4 DNA, together with the direct visualization of G4 DNA using G4 DNA specific antibodies and RNA interference have provided compelling for the existence of G4 DNA in vivo. To elucidate the function of MRX complex or its individual subunits at telomeres, the biochemical activities of purified MRX complex and its individual subunits on G4 DNA, D loop, duplex DNA and G rich ssDNA has been analyzed in this study. G4 DNA was assembled from S. cerevisiae telomeric sequence. G4 DNA was isolated and its identity was ascertained by chemical probing and circular dichroism. S. cerevisiae MRE11 and XRS2 was cloned and expressed in E. coli BL21 (DE3)plysS. S. cerevisiae RAD50 in pPM231 vector in S. cerevisiae BJ5464 strain was a gift from Dr. Patrick Sung (Yale University). Mre11, Rad50 and Xrs2 were overexpressed and purified to >98% homogeneity. The identity of the proteins was ascertained by Western bloting using polyclonal antibodies. Using purified proteins heterotrimeric MRX and heterodimeric MR and MX protein complexes were formed in the absence of ATP, DNA or Mn2+. The ability of M/R/X to bind to telomeric DNA substrates was studied by electrophoretic mobility shift assays. Mre11, Rad50, Xrs2 and MRX displayed higher binding affinity for G4 DNA over D loop, ss- or dsDNA. MRX bound G4 DNA more efficiently compared to its individual subunits as 10-fold lower concentration of MRX was able to shift the DNA into the protein-DNA complex. The protein-G4 DNA complexes were stable as >0.8 M NaCl as required to dissociate 50% of protein-G4 DNA complexes. Efficient competition by poly(dG), which is known to fold into G4 DNA, suggested that the protein-G4 DNA complex was specific. Competition experiments with tetra-[N-methyl- pyridyl]-porphyrin suggested that M/R/X recognizes distinct determinants and makes specific interactions with G4 DNA. G4 DNA is highly polymorphic and can exist as intramolecular or intermolecular (parallel and antiparallel) structures. High affinity binding of Mre11 to G4 DNA (parallel) over G2' DNA (antiparallel), ss- and dsDNA suggests the existence of parallel G4 DNA structures at the telomeres and that G4 DNA may be the natural substrate for MRX complex in vivo. Telomeres are elongated by telomerase that requires access to the 3' G-tail for its activity. Formation of G4 DNA structures renders the 3' G-tail inaccessible to telomerase thereby inhibiting telomere elongation. To elucidate the functional relevance of high affinity of M/R/X for G4 DNA, the ability of the complex to generate the appropriate DNA structure for telomere elongation has been analyzed. In this study, I considered the possibility that MRX could act as: (a) a helicase that opens up the G4 DNA structures making it accessible to telomerase or (b) as a nuclease that cleaves the G4 DNA generating substrates for telomerase. Helicase assay with Mre11, Xrs2, MX and MRX on G4 DNA and duplex DNA showed no detectable DNA unwinding activity. Interestingly, nuclease assays with Mre11 on G4 DNA showed that Mre11 cleaved G4 DNA in Mn2+-dependent manner and the cleavage was mapped to the G residues at the stacks of G quartets. Mre11 cleaved telomeric duplex DNA in the center of TGTG repeat sequence, G rich ssDNA at 5' G residue in an array of 3 G residues and D loop structure preferentially at the 5' ends at TG residues. Significantly, the endonuclease activity of Mre11 was abrogated by Rad50. Xrs2 had no effect on the endonuclease activity of Mre11. Structural studies on Rad50 and Mre11 showed that binding of ATP by Rad50 positions the Rad50 catalytic domain in close proximity to the nuclease active site of Mre11. In yeast, disruption of ATP binding Walker motifs results in a null phenotype, suggesting that ATP is required for Rad50 functions in vivo. hRad50 is known to regulate the exonuclease activity of hMre11 in the presence of ATP. Therefore, can ATP modulate the effect of S. cerevisiae (Sc) Rad50 on ScMre11? To address this question, I monitored the ATPase activity of Rad50 in the absence or presence of DNA. Rad50 hydrolyzed ATP in a DNA-independent manner; however, ATPase activity was enhanced in the presence of Mre11 and Xrs2. However, Rad50 exhibited a low turnover indicating that ATP could function as a switch molecule. Based on these observations, the effect of ATP on the nuclease activity was examined. The binding of ATP and its hydrolysis by Rad50 attenuated the inhibition exerted by Rad50 on the Mre11 endonuclease activity. Cleavage of G4 DNA, D loop, duplex DNA and ssDNA required ATP hydrolysis, since no cleavage product was observed when ADP or ATPγS was substituted for ATP. This observation was corroborated using a hairpin DNA substrate that mimics a intermediate in VDJ recombination, thereby confirming the generality of regulation of Rad50 on the endonuclease activity of Mre11. Does Rad50 regulate the exonuclease activity of Mre11 as well? To address this question, exonuclease activity of Mre11, MR and MRX on 3' labeled duplex DNA and G4 DNA was assayed. Rad50 had no measurable effect on the exonuclease activity of Mre11. Based on previous studies and my observations, I propose a model for the role of MRX in telomere length maintenance and its regulation by the ATP-binding pocket of Rad50. MRX binds telomeric DNA substrates in a non-productive complex, which is converted to a catalytically active complex upon binding of ATP by Rad50. ATP induces conformational changes, repositioning the complex such that the catalytic site of Mre11 now has access to the substrate. Following cleavage of DNA by Mre11, the release of ADP and inorganic phosphate, generate the cleaved product. The cleaved DNA is now accessible to telomerase or telomere binding proteins. In summary, the data presented in my PhD thesis demonstrates that Mre11 is a structure- and sequence-specific endonuclease. The natural substrate for telomerase is the 3' ssDNA. G quartets at telomeres not only protect the ends from degradation but also make the ends inaccessible for telomerase activity. Genetic studies have shown that cells proficient for telomerase activity but lacking any one of the components of the MRX complex display shortening in telomere length. The ability of Mre11 to cleave G4 DNA at the stacks of G quartets therefore, suggests a mechanism by which the 3' ssDNA is rendered accessible to telomerase or other telomere binding proteins. Yeast telomeres are characterized by the presence of subtelomeric Y' elements proximal to the terminal TG1- 3 repeat sequences. The Y' element has been shown to be amplified by telomerase in a fraction of mutants with short telomeres. The mechanism by which Y' DNA is amplified is unclear. The ability of Mre11 to cleave telomere duplex DNA at the center of TGTG repeats could contribute to the generation of appropriate substrate for elongation by telomerase, thereby contributing to Y' DNA amplification. Telomere length is maintained by homeostasis between processes that contribute to telomere elongation and those that cause attrition in telomeric ends. Overelongated telomeres are brought to wild type telomere size by a unique recombinational single step deletion process termed telomere rapid deletion (TRD). TRD involves invasion of the elongated 3' G tail into the proximal telomeric tract resulting in the formation of the D loop structure. Following branch migration the D-loop is nicked and resolved into a deleted telomere and a circular liner product. Cells deleted for MRE11, RAD50 or XRS2 are deficient in TRD process. It has been hypothesized that Mre11 could be a candidate for cleaving the D-loop structure. The endonuclease activity of Mre11 on D-loop structure, preferentially at the 5' ends at TG residues demonstrated in this study, show that Mre11 could function as the nuclease required to generate the deleted telomere in TRD. MRX complex is involved in several processes involving DNA metabolism. It is important that the activities of the complex are regulated in the in vivo context. Complex formation and the interaction of the individual subunits with nucleotide cofactors and metal ions constitute a mode of regulation. This study shows that Rad50 regulates the endonuclease, but not exonuclease activity of Mre11. The binding of ATP and its hydrolysis by Rad50 brings in the regulatory factor necessary to keep the uncontrolled nuclease activity of MRX in check, thus preventing any deleterious effects on telomere length. Telomere maintenance by telomerase is activated in 80% of cancer cells. Inhibition of telomerase by G quartets provides a new drug targets for potential anti-cancer drugs. It is, therefore, likely that understanding the biological consequences of G quadruplex interactions would provide a better insight in development of therapeutics for cancer.

Telomeric DNA

Saccharomyces Cerevisiae

Rad50

MRX-Mre11/Rad50/Xrs2

Telomerase

G-Quadruplexes

DNA Recombiantion

DNA Repair

Human Genome

MRX Complex

Mre11

Double Strand Break Repair (DSBR)

Biochemical Genetics

Caracterização funcional de diferentes componentes das vias metabólicas de resposta ao dano DNA no fungo filamentoso \'Aspergillus nidulan\' / Functional characterization of different components of the metabolic pathways involved in the filamentous fungi Aspergillus nidulans DNA damage response

Iran Malavazi

25 July 2007

O complexo Mre11 (Mre11/Rad50/Nbs1) é uma componente chave da resposta celular ao dano ao DNA em humanos e recentes observações sugerem que estas proteínas são em parte responsáveis pela interface ente o ensoreamento do dano ao DNA, seu reparo e as funções das proteínas envolvidas nos pontos de checagem do ciclo celular. Em Aspergillus nidulans, a partir de um screening para o isolamento de letais sintéticos na ausência de dineína, o gene sldIRAD50 foi clonado como um desses letais sintéticos através da complementação do fenótipo de deficiência de conidiação do mutante. Foi identificada uma transversão G-C na posição 2509 (Ala-692-Pro) no mutante sldI1444 a qual está presente na região de dobradiça da proteína. Essa mutação causa sensibilidade a vários agentes mutagênicos. Uma linhagem mutante sldIRAD50::pyrG foi construída a qual apresentou também vários defeitos na reposta celular ao dano ao DNA incluindo sensibilidade a várias drogas mutagênicas, defeito no ponto de checagem de replicação do DNA e na viabilidade dos ascosporos. Além disso, o gene sldIRAD50 interage geneticamente com bimEAPC1 para o controle do spindle pole checkpoint durante a segregação cromossômica sugerindo um novo papel para o complexo Mre11. Em atuação paralela com o complexo Mre11, duas proteínas quinases ditas apicais, ATM e ATR coordenam a transdução do sinal do dano ao DNA para proteínas efetoras do reparo. A proteína ATM está mutada na síndrome de instabilidade cromossômica herdada Ataxia Telangiectasia. Para a caracterização do homologo de ATM em A. nidulans AtmA, uma linhagem mutante atmAATM foi isolada. Esse mutante apresentou falha na reposta ao dano ao DNA, como seus homólogos em vários outros organismos mostrando defeitos no ponto de checagem intrafase S e G2/M, além de sensibilidade a camptothecin e bleomicina. Ainda, o extrato protéico bruto desse mutante não foi capaz de fosforilar o homologo de NBS1 em A. nidulans, ScaA. Além das conhecidas funções de ATM na resposta ao dano ao DNA, foi verificado que o mutante atmAATM apresentou uma acelerada cinética de divisão nuclear e severos defeitos no estabelecimento e manutenção do eixo de crescimento polarizado, evidenciando uma função ainda não descrita para ATM no crescimento polar. Provavelmente, AtmA regula a função e/ou localização de proteínas chaves para a formação do eixo de polarização. Diante disso, para investigar as vias metabólicas que são controladas por esse gene, o perfil transcricional do mutante atmAATM, em comparação com a linhagem selvagem foi verificado em diferentes condições de crescimento. Os resultados indicaram um importante papel da via das pentoses fosfato na proliferação celular monitorada pela AtmA. Além disso, foram identificados vários genes com a expressão do mRNA diminuída envolvidos no crescimento polarizado, na síntese de ácido fosfatídico e de ergosterol e no tráfico intracelular, secreção e transporte vesicular. Buscando identificar genes que participam da resposta celular ao dano ao DNA causado pela droga anti topoisomerase I, camptothecin, foram utilizados filtros de macroarray de A. nidulans contendo 2787 genes deste organismo para monitorar a expressão gênica da linhagem selvagem e do mutante uvsBATR, num experimento de indução com CPT por 30, 60 e 120 minutos. Os resultados revelaram um total de 1512 e 1700 genes modulados na linhagem selvagem e uvsBATR respectivamente, em pelo menos um ponto experimental. Seis desses genes que apresentaram aumento da expressão de mRNA na linhagem selvagem e diminuição da linhagem uvsBATR foram caracterizados: fhdA (que codifica para uma proteína com domínio fork-head associated), tprA (uma proteína hipotética que apresenta o domínio tetratrico peptide repeat), mshA (um homólogo MutS6 envolvido em mismatch repair), phbA (um homólogo da prohibitina), uvsCRAD51 e cshA (homólogo da proteína CSB envolvida no reparo por excisão de nucleotídeos e ligada a Síndrome de Cockayne). A indução transcricional desses genes na presença de CPT requer a função de uvsBATR. Estes genes foram deletados e surpreendentemente apenas uvsCRAD51 apresentou sensibilidade a CPT, enquanto os outros mostraram sensibilidade a outros agentes que causam dano ao DNA e estresse oxidativo. Além disso, com exceção de uvsCRAD51, a deleção desses genes leva a supressão parcial da sensibilidade a menadiona e paraquat do mutante uvsBATR. Esses resultados indicaram um comportamento heterogêneo de sensibilidade durante o crescimento na presença de agentes que causam dano direto ou indireto ao DNA, evidenciando que o perfil transcricional não é determinante para predizer a função de um gene na proteção da célula a determinada droga que causa dano ao DNA. / The Mre11 protein complex (Mre11/Rad50/Nbs1) has emerged as a central component in the human cellular DNA damage response, and recent observations suggest that these proteins are at least partially responsible for the linking of DNA damage detection to DNA repair and cell cycle checkpoint functions. In Aspergillus nidulans, the sldI1444D mutant was isolated in a screen for dynein synthetic lethals. The sldIRAD50 gene was cloned by complementation of the sporulation deficiency phenotype of this mutant. A transversion G-C at the position 2509 (Ala-692-Proamino acid change) in the sldI1444D mutant causes sensitivity to several DNAdamaging agents. The mutation sldI1 occurs at the CXXC hinge domain of Rad50. An inactivation strain sldIRAD50::pyrG was constructed. Besides sensitivity to a number of DNA-damaging agents, this deletion strain was also impaired in the DNA replication checkpoint response and in ascospore viability. Also, sldIRAD50::pyrG geneticaly interacted with bimEAPC1, acting in the spindle pole checkpoint control during segregation, suggesting a new possible role of Mre11 complex. In parallel to the Mre11 complex, two apical quinases ATM and ATR respond to DNA damage and transduce the signal to effector proteins. In humans, mutations in ATM cause the devastating neurodegenerative disease Ataxia Telangiectasia. Here we characterized the homolog of ATM (AtmA) in the filamentous fungus A. nidulans. The deletion strain atmA presented defects in the DNA damage response as previously shown in other model organisms including intra S-phase and G2/M checkpoint defects, sensitivity to camptothecin and bleomycin. Also, the crude extract from the mutant strain did not phosphorylate the NBS1 homologue ScaA. In addition to its expected role in the DNA damage response, the atmA mutant showed increased nuclear division kinetics and severe defects in polarized hyphal growth, indicating a novel feature for the ATM gene. Probably, AtmA regulates the function and/or localization of landmark proteins required for the formation of a polarity axis. We extended these studies by investigating which pathways are controlled by AtmA during proliferation and polar growth by comparatively determining the transcriptional profile of A. nidulans wild type and atmA mutant strains in different growth conditions. Our results indicated an important role of the pentose phosphate pathway in the fungal proliferation during endogenous DNA damage and polar growth monitored by the AtmA kinase. Furthermore, we identified several genes that have decreased mRNA expression in the atmA mutant that are involved in the formation of polarized hyphae and control of polar growth; in the biosynthesis of phosphatidic acid and ergosterol; and intracellular trafficking, secretion, and vesicular transport. In order to identify genes that responded to the DNA damage mediated by the anti- toposomerase I drug, camptothecin, we used an A. nidulans macroarray carrying sequences of 2,787 genes from this fungus to monitor gene expression of both wild-type and uvsBATR in a time-point experiment where mycelium was exposed to 60, 90 and 120 minutes to the drug. The results revealed a total of 1,512 and 1,700 genes in the wild-type and uvsBATR deletion mutant strain that displayed statistically significant difference in at least one experimental time-point. We characterized six genes that have increased mRNA expression in the presence of CPT in the wild-type strain relative to the uvsBATR mutant strain: fhdA (encoding a fork head associated domain protein), tprA (encoding a hypothetical protein that contains a tetratrico peptide repeat), mshA (encoding a MutS homologue involved in mismatch repair), phbA (encoding a prohibitin homologue), uvsCRAD51 (the homologue of the RAD51 gene), and cshA (encoding a homologue of the excision repair protein ERCC-6 [Cockaynes syndrome protein]). The induced transcript levels of these genes in the presence of CPT required uvsBATR. These genes were deleted, and surprisingly, only the uvsCRAD51 mutant strain was sensitive to CPT; however, the others displayed sensitivity to a range of DNA-damaging and oxidative stress agents. Moreover, with the exception of UvsC, deletion of each of these genes partially suppressed the sensitivity of the uvsB strain to menadione and paraquat. These results indicated a very complex and heterogeneous sensitivity behavior during growth in the presence of agents that directly or indirectly cause DNA damage and the transcriptional response to DNAdamaging agents does not necessarily identify the genes that protect against these agents.

Aspergillus nidulans

ATM e crescimento polar

complexo Mre11

dano ao DNA

microarray

Aspergillus nidulans

DNA damage

microarray

Mre11 complex. ATM

polar growth

Regulation of DNA Double Strand Break Response

Chen, Chen

January 2014

<p>To ensure genomic integrity, dividing cells implement multiple checkpoint pathways during the course of the cell cycle. In response to DNA damage, cells may either halt the progression of the cycle (cell cycle arrest) or undergo apoptosis. This choice depends on the extent of damage and the cell's capacity for DNA repair. Cell cycle arrest induced by double-stranded DNA breaks relies on the activation of the ataxia-telangiectasia (ATM) protein kinase, which phosphorylates cell cycle effectors (e.g., Chk2 and p53) to inhibit cell cycle progression. ATM is an S/T-Q directed kinase that is critical for the cellular response to double-stranded DNA breaks. Following DNA damage, ATM is activated and recruited to sites of DNA damage by the MRN protein complex (Mre11-Rad50-Nbs1 proteins) where ATM phosphorylates multiple substrates to trigger a cell cycle arrest. In cancer cells, this regulation may be faulty and cell division may proceed even in the presence of damaged DNA. We show here that the RSK kinase, often elevated in cancers, can suppress DSB-induced ATM activation in both Xenopus egg extracts and human tumor cell lines. In analyzing each step in ATM activation, we have found that RSK disrupts the binding of the MRN complex to DSB DNA. RSK can directly phosphorylate the Mre11 protein at Ser 676 both in vitro and in intact cells and can thereby inhibit loading of Mre11 onto DSB DNA. Accordingly, mutation of Ser 676 to Ala can reverse inhibition of the DSB response by RSK. Collectively, these data point to Mre11 as an important locus of RSK-mediated checkpoint inhibition acting upstream of ATM activation.</p><p>The phosphorylation of Mre11 on Ser 676 is antagonized by phosphatases. Here, we screened for phosphatases that target this site and identified PP5 as a candidate. This finding is consistent with the fact that PP5 is required for the ATM-mediated DNA damage response, indicating that PP5 may promote DSB-induced, ATM-dependent DNA damage response by targeting Mre11 upstream of ATM.</p> / Dissertation

Pharmacology

Biology

Cellular biology

Cell cycle arrest

Double strand break

Mre11

Rsk kinase

Xenopus egg extract