Global ETD Search

71	Interactions of RecQ-Family Helicases with G-quadruplex Structures at the Single Molecule Level Budhathoki, Jagat B. 18 July 2016 (has links) No description available. Biophysics Biomechanics
72	Functional control of HIV-1 post-transcriptional gene expression by host cell factors Sharma, Amit 19 June 2012 (has links) No description available. Biology Cellular Biology Molecular Biology Virology HIV-1 Post-transcritional gene expression RNA helicase A Retrovirus, RNA helicases, Virology
73	Structural and functional characterisation of Mcb1 and the MCMᴹᶜᵇ¹ complex in Schizosaccharomyces pombe Schnick, 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. 572.8
74	Interactions cellules NK – Cellules Dendritiques : importance de la coopération entre TLR3 et les Hélicases RLR dans l’initiation d'une réponse innée antivirale / NK cell – dendritic cell cross-talk : cooperation between TLR3 and RLR for the initiation of a potent innate antiviral response Perrot, Ivan 30 September 2009 (has links) Diverses études ont souligné le rôle prépondérant du dialogue entre les cellules NK et les cellules dendritiques au cours des réponses immunes. Cependant, les récepteurs impliqués dans ce processus restent incertains. Au cours de ce travail, nous nous sommes attachés à identifier les récepteurs mis en jeu lors de la reconnaissance virale à l’aide de modèles humains et murins. Pour cela, nous avons mimé l’infection virale en utilisant deux ARN bicaténaires synthétiques – poly(AU) et poly(IC) – et montré qu’ils sont tous deux capables d’activer TLR3 mais que seul poly(IC) engage les hélicases RIG-I et MDA5. Les deux ARN induisent l’activation des cellules NK au sein des PBMC humaines, mais seul poly(IC) induit la production d’IFN-gamma. Les DC myéloïdes (mDC) sont requises pour cette activation sans nécessité d’un contact cellulaire entre les cellules NK et les mDC. En outre, les IFN de type I et l’IL-12 secrétés par les DC sont respectivement nécessaires à l’initiation du potentiel lytique et à la production d’IFN-gamma. Poly(IC), au contraire de poly(AU), a une action synergique avec l’IL-12 produite par les mDC pour induire la production d’IFN-gamma en agissant directement sur les cellules NK. Enfin, l’activation conjointe de TLR3 et des hélicases RLR sur les mDC et RIG-I sur les cellules NK, nécessaire à la production d’IFN-gama en réponse à l’ARN bicaténaire, a été confirmée à l’aide de souris déficientes pour TLR3 et Cardif et d’un ligand spécifique de RIG-I. En conclusion, nous rapportons pour la première fois la nécessité pour un composé microbien d’engager deux familles de récepteurs sur deux populations cellulaires distinctes pour induire une réponse innée éfficace. / Crosstalk between NK cells and DC is critical for the response to the microbial mimic poly(IC) but the dsRNA receptors involved in each cell types remained to be defined. We show herein that two dsRNA, poly(AU) and poly(IC), similarly engaged TLR3 while only poly(IC) triggered the RIG-I and MDA-5 helicases. Both dsRNA triggered NK cell activation within PBMC but only poly(IC) induced IFN-gamma. mDC were required for NK cell activation by the two dsRNA, suggesting that they triggered at least TLR3 on mDC. DsRNA induction of cytolytic potential and IFN-gamma production in NK cells did not require contact with mDC but was dependent on the secretion of type I IFN and IL-12, respectively. Poly(IC) but not poly(AU) synergized with mDC-derived IL-12 for high IFN-gamma production by acting directly on NK cells. Finally, the requirement of TLR3 and the RLR on mDC and the involvement of the RIG-I but not TLR3 on NK cells for the production of IFN-gamma induced by dsRNA was confirmed using TLR3 and Cardif deficient mice and RIG-I specific activator. This cooperation was further confirmed using inactivated FLU virus infected-target cells both in human and mouse system demonstrating that NK cells were able to sense viral material by a direct transfer from infected cells likely through lytic immunological synapse without prior infection of NK cells. Thus, we report for the first time the requirement of cotriggering Cellules NK Cellules dendritiques myéloïdes ARN bicaténaire Tlr3 Hélicases RLR IFN-gamma RIG-like Helicases NK cells Myeloid dendritic cells DsRNA Trl3 571.96
75	Les mécanismes d’initiation de la traduction de la polyprotéine Gag du Virus de l’Immunodéficience Humaine (VIH-1) / The translation initiation mechanisms of the Gag HIV-1 polyprotein Ameur, Melissa 04 November 2016 (has links) L'ARN génomique du Virus de l'Immunodéficience Humaine-1 (VIH-1) est multifonctionnel. Il constitue le génome encapsidé dans les virions et sert d'ARN messager pour la traduction des protéines virales Gag et Gag-Pol. La traduction de ces protéines dépend exclusivement de la machinerie traductionnelle cellulaire et est initiée par deux mécanismes différents : l'initiation canonique dépendante de la coiffe et l'initiation par entrée interne des ribosomes (IRES). Le VIH-1 présente deux IRES, l'un dans la région 5' non traduite (5'-UTR) qui est stimulé en phase G2/M du cycle cellulaire et l'autre dans la région codante de Gag. Ce dernier permet l'initiation de la traduction sur deux AUG en phase et conduit à la production de la protéine Gag pleine longueur mais également à la production d'une isoforme alternative de Gag, tronquée en région N-terminale. Le rôle de cette isoforme reste mal connu. Toutefois la mutation du second AUG chez VIH-1 et donc la suppression de la seconde isoforme de Gag provoque une diminution importante du taux de la réplication virale. La conservation structurelle et fonctionnelle de l'IRES Gag parmi les lentivirus suggère un rôle important de cette isoforme et de l'IRES gag dans le cycle viral. Nos travaux visent à comprendre à un niveau moléculaire les relations hôtes-pathogènes lors de la traduction des messagers viraux. Je me suis particulièrement intéressée aux rôles de la sous unité ribosomale 40S et de l'hélicase cellulaire DDX3 dans l'initiation de la traduction de la polyprotéine Gag du VIH-1. La première partie de ma thèse est consacrée à l'étude de l'interaction entre la sous unité ribosomale 40S et l'IRES gag du VIH-1. Par l'utilisation d'approches complémentaires, nous avons pu démontrer la présence de deux sites distincts de liaison au ribosome qui sont présents à proximité des deux codons d'initiation. Nous avons ensuite évalué à la fois in vitro et in cellulo (en collaboration avec l'équipe de T. Ohlmann, CIRI-ENS-Lyon) l'effet de la délétion de chacun des sites de liaison au 40S sur l'efficacité de traduction de la polyprotéine Gag. Nos résultats valident l'importance fonctionnelle des sites de liaison au ribosome pour une production optimale des deux isoformes de la polyprotéine Gag. La seconde partie de mon travail a consisté à définir le rôle de DDX3 dans l'initiation « coiffe-dépendante » de la traduction de la polyprotéine Gag. DDX3 est une hélicase à ARN à boîte DEAD impliquée dans de nombreux processus cellulaires tels que la régulation du cycle cellulaire et la réponse immunitaire innée mais également dans tous les aspects du métabolisme de l'ARN comme la transcription, l'épissage, l'export nucléaire ou encore la traduction. Plus récemment, il a été montré que DDX3 est nécessaire à la traduction de l'ARN génomique du VIH-1, cependant son rôle exact n'a pas encore été défini. Nous avons purifié une forme recombinante de la protéine en fusion avec la MBP (Maltose Binding Protein) et effectué des cinétiques enzymatiques afin de caractériser ses propriétés biochimiques. Contrairement à ce qui a été précédemment décrit, nos résultats montrent que DDX3 possède une activité ATPase strictement ARN-dépendante avec des constantes cinétiques similaires à celles de son homologue chez la levure, Ded1p. Nous avons également évalué l'activité hélicase de la protéine en présence de substrats de longueur et de nature variables (duplex ARN/ARN ou des hétéroduplex ADN/ARN). D'un point de vue fonctionnel, nous avons réalisé une première série d'expériences qui confirme la stimulation exercée par DDX3 sur la traduction de Gag in vitro. Ces résultats permettent d'envisager la caractérisation biochimique fine des interactions DDX3-ARN viral ainsi que de disséquer le rôle de DDX3 dans l'expression du génome viral. / The Human Immunodeficiency Virus (HIV) genomic RNA is multifunctional. It acts both as a genome that is packaged within virions and as messenger RNA translated to yield the Gag and Gag-Pol polyproteins. The translation of these proteins relies exclusively on the cellular translation machinery and is initiated through two mechanisms: the canonical cap-dependent initiation pathway and the use of internal ribosome entry sites (IRESes). HIV-1 has two IRESes, one located within the 5' UTR (5' UnTranslated Region) that is stimulated during the G2/M phase of the cell cycle, and the other embedded within the Gag polyprotein coding region. The later drives translation initiation from two AUG in frame and results in the production of the full-length Gag protein but also of an additional N-terminally truncated Gag isoform. Few things are known about this isoform, but the mutation of the second AUG causes a significant decrease in the rate of viral replication. The structural and functional conservation of Gag IRES among lentiviruses suggests an important role of this isoform and thus of the IRES in the viral cycle. Our work aims to understand at a molecular level the host-pathogen relationships in the translation of the viral messenger RNA. My work focused on the roles of the 40S ribosomal subunit and of the cellular helicase DDX3 in the translation initiation of Gag. During the first part of my Phd, I studied the interaction between the 40S ribosomal subunit and HIV-1Gag IRES. Following complementary approaches, we evidenced two distinct ribosome binding sites present close to the two the initiation sites of Gag. Then, we evaluated the effect of each 40S binding site deletion on Gag translation efficiency, both in vitro and in cellulo (in collaboration with the team of T. Ohlmann, CIRI-ENS-Lyon). Taken together, our results confirm the functional relevance of the two ribosomal binding sites to ensure optimal production of the two Gag isoforms. The second part of my Phd project aims to define the role of DDX3 in the translation initiation of Gag. DDX3 is a RNA DEAD-box helicase involved in many cellular processes such as cell cycle regulation and the innate immune response but also in all aspects of RNA metabolism such as transcription, splicing, mRNA nuclear export and translation. Recently DDX3 has been shown to favor HIV-1 Gag translation. To define its role, we first purified a recombinant form of the protein and performed kinetic experiments to analyze its biochemical properties. Contrary to what has been previously described, MBP-DDX3 displays a strictly RNA-dependent ATPase activity with kinetic constants similar to those displayed by its yeast counterpart Ded1p. We next evaluated MBP-DDX3 helicase activity towards RNA duplexes or RNA/DNA hybrids, with different length and single strand overhangs. Our preliminary results indicate that DDX3 alone is sufficient to enhance Gag translation in our in vitro system which paves the way to fine biochemistry experiments such as reconstruction of functional initiation complexes assembled onto Gag RNA and evaluation of its role on Gag RNA structure. VIH-1 Traduction IRES Ribosomes 40S DEAD BOX Hélicases DDX3 Polyprotéine Gag HIV-1 Translation IRES Ribosomes 40S DEAD BOX Helicases DDX3 Gag polyprotein 572.8
76	The function of the germline rna helicase (GLH) genes in caenorhabditis elegans Kuznicki, Kathleen January 2000 (has links) Thesis (Ph. D.)--University of Missouri--Columbia, 2000. / Typescript. Vita. Includes bibliographical references (leaves 107-112). Also available on the Internet.
77	Étude biochimique et biophysique de l’ARN hélicase UPF1 : un moteur moléculaire hautement régulé / Biochemical and biophysical study of the RNA helicase UPF1 : a highly regulated molecular motor Kanaan, Joanne 09 July 2018 (has links) UPF1 (Up-Frameshift 1) est une hélicase multifonctionnelle conservée chez tous les eucaryotes. Elle est essentielle à la voie de surveillance du NMD (Nonsense Mediated mRNA Decay), qui dégrade des ARNm portant un codon stop prématuré. UPF1 est l’archétype d’une famille d’hélicases qui partagent des corps similaires mais sont impliquées dans des voies cellulaires variées. Cependant, les relations structure-fonction et les caractéristiques biophysiques intrinsèques de ces moteurs moléculaires restent à ce jour peu connues. In vitro, le coeur hélicase d’UPF1 est hautement processif, il traverse des milliers de bases sur l’ARN ou l’ADN et déroule des doubles brins. Dans ce travail, nous avons cherché les facteurs clés régissant cette remarquable processivité en combinant des techniques de biochimie et de biophysique. En particulier, nous avons utilisé des pinces magnétiques pour étudier en temps réel des hélicases à l’échelle de la molécule unique. Contrairement à UPF1, l’hélicase IGHMBP2 de la famille UPF1-like n’est pas processive ; la processivité n’est donc pas un trait conservé au sein de la famille. Grâce à une étude fine de la structure 3D des deux hélicases, nous avons conçu divers mutants que nous avons utilisés pour identifier les éléments structuraux qui modulent la processivité. Notre approche révèle qu’UPF1 a une prise très ferme sur les acides nucléiques, garantissant de longs temps de résidence et d’action qui dictent sa haute processivité. Grâce à la variété de comportements des mutants, nous avons construit un modèle mécanistique expliquant le lien entre énergie d’interaction et processivité. Nous démontrons aussi que la processivité d’UPF1 est requise pour un processus de NMD efficace in vivo. Nous avons utilisé les mêmes outils biochimiques et biophysiques pour étudier une isoforme naturelle d’UPF1 humaine se déplaçant plus vite que l’isoforme majeure, et pour comparer la régulation d’UPF1 humaine et de levure par leurs domaines flanquants. Nous avons également caractérisé l'interaction d’UPF1 de levure avec de nouveaux partenaires. Nos travaux montrent comment la combinaison d'outils biochimiques, biophysiques, structuraux etin vivo offre des aperçus inattendus quant au mode de fonctionnement des moteurs moléculaires. / UPF1 (Up-Frameshift 1) is a multifunctional helicase that unwinds nucleic acids and is conserved throughout the eukaryote kingdom. UPF1 is required for the Nonsense Mediated mRNA Decay (NMD) surveillance pathway, which degrades mRNAs carrying premature termination codons, among other substrates. UPF1 is the archetype of a family of 11 helicases sharing similar cores but involved in various cellular pathways. However, the structure-function relationship and intrinsic biophysical properties of these molecular engines remain poorly described. In vitro, the UPF1 helicase core is highly processive, it travels along thousands of RNA or DNA bases and unwinds double-strands. In this work, we looked for key factors governing this remarkable processivity. We combined biochemical and biophysical techniques. In particular, we used magnetic tweezers to study helicases in real time at a single molecule scale. In contrast to UPF1, the related IGHMBP2 is not processive, thus processivity is not a shared family trait. Based on the 3D structures of both proteins, we designed various mutants and used them to identify structural elements that modulate processivity. Our approach reveals that UPF1 has a very firm grip on nucleic acids, guaranteeing long binding lifetimes and action times that dictate its high processivity. Thanks to the variety in mutant behaviors, we built a novel mechanistic model linking binding energy to processivity. Furthermore, we show that UPF1 processivity is required for an efficient NMD in vivo. In addition, we used the same biochemical and biophysical tools to investigate a natural human UPF1 isoform moving faster than the major isoform, and to compare the regulation of human andyeast UPF1 by their flanking domains. We also characterized the interaction of yeast UPF1 with new NMD partners. Our work shows how a combination of biochemical, biophysical, structural and in vivo tools can offer unexpected insights into the operating mode of molecular motors. Upf1 Hélicases Processivité Régulation Acides nucléiques NMD Interactions Biochimie Biophysique Molécule unique Upf1 Helicases Processivity Regulation Nucleic acids NMD Interactions Biochemistry Biophysics Single molecule 572.8
78	Interdoménové a intradoménové interakce u motorové podjednotky EcoR124I: Výpočetní studie SINHA, Dhiraj January 2016 (has links) EcoR124I is a Type I restrictionmodification (RM) enzyme and as such forms multifunctional pentameric complexes with DNA cleavage and ATP-dependent DNA translocation activities located on the motor subunit HsdR. When non-methylated invading DNA is recognized by the complex, two HsdR endonuclease/motor subunits start to translocate dsDNA without strand separation activity up to thousands base pairs towards the stationary enzyme while consuming ~1 molecule of ATP per base pair advanced. Whenever translocation is stalled the HsdR subunits cleave the dsDNA nonspecifically far from recognition site. The X-ray crystal structure of HsdR of EcoR124I bound to ATP gave a first insight of structural/functional correlation in the HsdR subunit. The four domains within the subunit were found to be in a square planer arrangement. Computational modeling including molecular dynamics in combination with crystallography, point mutations, in vivo and in vitro assays reveals how interactions between these four domains contribute to ATP-dependent DNA translocation, DNA cleavage or inter-domain communication between the translocase and endonuclease activities.
79	Étude structurale et fonctionnelle de la régulation de l’hélicase Prp43 / Structural and functional study of the regulation of the helicase Prp43 Robert-Paganin, Julien 02 October 2014 (has links) Les hélicases à ARN de la famille DEAH/RHA sont impliquées dans la plupart des processus essentiels à la vie tels que l'épissage, la biogenèse des ribosomes, la réplication, la transcription ou encore la détection d’ARN viraux. Ces enzymes sont capables de catalyser la dissociation de duplexes d'ARN, la réorganisation de structures secondaires ou de remodeler des complexes ARN-protéines. L'hélicase DEAH/RHA Prp43 présente la particularité d'être bifonctionnelle. Prp43 est impliquée dans l'épissage des Pré-ARNm, où elle assure le recyclage du spliceosome et du lasso, mais aussi dans la biogenèse des ribosomes où elle est impliquée dans la maturation des deux sous-unités. Prp43 est activée et régulée par cinq partenaires protéiques : Ntr1, Gno1, Pfa1, RBM5 et GPATCH2. Ces partenaires protéiques présentent tous un domaine G-patch et sont capables de stimuler les activités hélicase et ATPase de Prp43. La structure cristallographique de Prp43 en complexe avec l'ADP a été résolue au laboratoire. Cette structure a mis en évidence un mode de fixation du nucléotide inédit chez les autres hélicases, notamment au niveau de la base qui s'empile entre la phénylalanine 357 (F357) du domaine RecA2 et l'arginine 159 (R159) du domaine RecA1. Les déterminants de l'activation de Prp43 par les protéines à domaine G-patch demeurent méconnus. Dans ce travail, nous avons cherché à déterminer quel était le rôle de l’empilement de la base dans l’activation de Prp43. Nous présentons ici plusieurs structures cristallographiques de Prp43 en complexe avec tous les nucléotides diphosphates(NDP) et les désoxynucléotides triphosphates (dNDP). Ces structures ont permis de conclure qu'il y avait des différences dans l’empilement de la base selon le (d)NDP considéré. Des dosages d'activité NTPase de Prp43 avec et sans son partenaire protéique Pfa1 montrent que lorsque la base ne s'empile pas avec la F357 et la R159, l'activité de l'enzyme n'est pas correctement régulée par son partenaire protéique. Les dosages d’activité enzymatique sur les mutants ponctuels F357A et R159A révèlent que le résidu F357 permet de moduler l’activité de Prp43. Tous ces résultats nous ont permis de mettre en évidence un modèle de la régulation de Prp43 par les protéines à domaines G-patch et d'expliquer l'importance du mode de fixation de la base à l'enzyme dans cette régulation. / RNA helicases from the DEAH/RHA family are involved in most of essential processes of life such as pre-mRNA splicing, ribosome biogenesis, replication, transcription or viral RNA sensing. These enzymes are able to catalyze RNA unwinding, secondary structures reorganization or RNA-protein complexes remodeling. The DEAH/RHA helicase Prp43 is remarkable because it is bifunctional, as it is involved both in pre-mRNA splicing, where it is responsible of spliceosome and lariat recycling and in the biogenesis of the two ribosomal subunits. Prp43 is activated by five protein partners: Ntr1, Gno1, Pfa1, RBM5 and GPATCH2. These protein partners all possess a G-patch domain and are able to stimulate helicase and ATPase activity of Prp43. The structure of Prp43 in complex with ADP has been solved by X-ray crystallography. The structure reveals that the nucleotide is bound to the enzyme in a novel mode that has never been observed in other known helicase structures. The specific feature of this binding mode is the base, stacked between phenylalanine (F357) from RecA2 domain and an arginine (R159) from RecA1 domain. Features of the activation of Prp43 by G-patch proteins are unclear. In this work, we investigated the role of base stacking in the activation of Prp43. We present several structures of Prp43 bound to all the nucleotide diphosphates (NDP) and deoxynucleotide diphosphates (dNTP). These results indicate that there are differences in stacking according to the (d)NDP bound to the enzyme. NTPase activity assays revealed that when stacking is weakened, Prp43 activity cannot be properly regulated by its protein partner Pfa1. Moreover, point mutations F357A and R159A show that stacking of F357 permits to modulate Prp43 activity. All these results allow us to propose a model of NTPase activity activation of Prp43 by G-patch proteins and to highlight the importance of base stacking in this regulation. Hélicases à ARN Interactions protéine-protéine Domaine G-patch Biologie structurale Cristallographie aux rayons X. RNA helicases Protein-protein interactions G-patch domain Structural biology X-ray crystallography 572.79
80	Role of Mycobacterium Tuberculosis RecG Helicase in DNA Repair, Recombination and in Remodelling of Stalled Replication Forks Thakur, Roshan Singh January 2015 (has links) (PDF) Tuberculosis, caused by the infection with Mycobacterium tuberculosis remained as a major global health challenge with one third of world population being infected by this pathogen. M. tuberculosis can persist for decades in infected individuals in the latent state as an asymptomatic disease and can emerge to cause active disease at a later stage. Thus, pathways and the mechanisms that are involved in the maintenance of genome integrity appear to be important for M. tuberculosis survival, persistence and pathogenesis. Helicases are ubiquitous enzymes known to play a key role in DNA replication, repair and recombination. However, role of helicases in providing selective advantage for M. tuberculosis survival and genome maintenance is obscure. Therefore, understanding the role of various helicases could provide insights into the M. tuberculosis survival, persistence and pathogenesis in humans. This information could be useful in considering helicases as a novel therapeutic target as well as developing effective vaccines. The research focus of my thesis has been to understand the role of helicases in safeguarding the M. tuberculosis genome from various genotoxic stresses. The major focus of the current study has been addressed towards understanding the role of M. tuberculosis RecG (MtRecG) helicase in recombinational repair and in remodeling stalled replication forks. This study highlights the importance of RecG helicase in the maintenance of genome integrity via DNA repair, recombination and in remodeling the stalled replication forks in M. tuberculosis. The thesis has been divided into following sections as follows: Chapter I: General introduction that describes the causes and consequences of replication stress and DNA repair pathways in M. tuberculosis The genome is susceptible to various types of damage induced by exogenous as well as endogenous DNA damaging agents. Unrepaired or misrepaired DNA lesions can lead to gross chromosomal rearrangements and ultimately cell death. Thus, organisms have evolved with efficient DNA damage response machinery to cope up with deleterious effects of genotoxic agents. Accurate transmission of genetic information requires error-free duplication of chromosomal DNA during every round of cell division. Defects associated with replication are considered as a major source of genome instability in all organisms. Normal DNA replication is hampered when the fork encounters road blocks that have the potential to stall or collapse a replication fork. The types of lesions that potentially block replication fork include lesions on the template DNA, various secondary structures, R-loops, or DNA bound proteins. To understand the DNA damage induced replication stress and the role of fork remodeling enzymes in the repair of stalled replication forks and its restart, chapter I of the thesis has been distributed into multiple sections as follows: Briefly, initial portion of the chapter describes overall replication process in prokaryotes highlighting the importance of coordinated replisome assembly and disassembly during initiation and termination. Later section discusses about various types of exogenous and endogenous DNA damages leading to replication fork stalling. Subsequent section of chapter I provide detailed description and mechanism of various repair pathways cell operates to repair such damages. Chapter I further summarizes causes of stalled replication forks majorly including template lesions, natural impediments like DNA secondary structures and DNA-protein cross links. Subsequent section discusses various pathways of replication restart that include essential role of primosomal proteins in reloading replisome machinery at stalled replication forks. Subsequent section of chapter I provide a comprehensive description of replication fork reversal (RFR) and mechanism of replication restart. RFR involves unwinding of blocked forks via simultaneous unwinding and annealing of parental and daughter strands to generate Holliday junction (HJ) intermediate. Genetic and biochemical studies highlighted the importance of RecG, RuvAB and RecA proteins in driving RFR reaction in E. coli. Hence, in the subsequent chapter, the functional role of RecG, RuvAB and RecA in replication-recombination processes has been discussed. Last section of the chapter devotes completely to M. tuberculosis, its genome dynamics and the various pathways of mycobacterial DNA repair. M. tuberculosis experiences substantial DNA damage inside host macrophages owing to the acidic environment, reactive oxygen species (ROS) and reactive nitrogen intermediates (RNI) which are sufficient enough to cause replication stress. To gain insights into the role of M. tuberculosis RecG helicase in DNA repair, recombination and in remodeling the stalled replication forks the following objectives were laid for my PhD thesis: 1 To understand the functional role of M. tuberculosis RecG (MtRecG) in DNA repair and recombination. 2 To investigate the distinct role(s) of MtRecG, MtRuvAB and MtRecA in remodeling the stalled replication forks. Chapter II: Evidence for the role of Mycobacterium tuberculosis RecG helicase in DNA repair and recombination In order to survive and replicate in a variety of stressful conditions during its life cycle, M. tuberculosis must possess mechanisms to safeguard the integrity of the genome. Although DNA repair and recombination related genes are thought to play key roles in the repair of damaged DNA in all organisms, so far only a few of them have been functionally characterized in the tubercle bacillus. Helicases are one such ubiquitous enzyme involved in all DNA metabolic transaction pathways for maintenance of genome stability. To understand the role of M. tuberculosis RecG (MtRecG) helicase in recombination and repair, we carried out functional and biochemical studies. In our study, we show that M. tuberculosis RecG expression was induced in response to different genotoxic agents. Strikingly, expression of M. tuberculosis RecG in Escherichia coli ∆recG mutant strain provided protection against MMC, MMS and UV-induced cell death. Purified M. tuberculosis RecG exhibited higher binding affinity for the Holliday junction (HJ) as compared to a number of canonical recombinational DNA repair intermediates. Notably, although MtRecG binds at the core of the mobile and immobile HJs, and with higher binding affinity for the immobile junction, branch migration and resolution was evident only in the case of the mobile junction. Furthermore, immobile HJs stimulate MtRecG ATPase activity less efficiently as compared to the mobile HJs. In addition to HJ substrates, MtRecG exhibited binding affinity for a variety of branched DNA structures including three-way junctions, replication forks, flap structures, forked duplex and a D-loop structures, but demonstrated strong unwinding activity on replication fork and flap DNA structures. Altogether, these results support that MtRecG plays an important role in processes related to DNA metabolism under normal as well as in stress conditions. Chapter III: Mycobacterium tuberculosis RecG but not RuvAB or RecA is efficient at remodeling the stalled replication forks: Implications for multiple mechanisms of replication restart in mycobacteria Aberrant DNA replication, defects in the protection and restart of stalled replication forks are a major cause of genome instability in all organisms. Replication fork reversal is emerging as an evolutionarily conserved physiological response for restart of stalled forks. Escherichia coli RecG, RuvAB and RecA proteins have been shown to reverse the model replication fork structures in vitro. However, the pathways and the mechanisms by which Mycobacterium tuberculosis, a slow growing human pathogen responds to different types of replication stress and DNA damage is unclear. In our study, we show that M. tuberculosis RecG rescues E. coli ∆recG cells from replicative stress. The purified M. tuberculosis RecG (MtRecG) and RuvAB (MtRuvAB) proteins catalyze fork reversal of model replication fork structures with and without leading strand ssDNA gap. Interestingly, SSB suppresses the MtRecG and MtRuvAB mediated fork reversal with substrates that contain lagging strand gap. Notably, our comparative studies with fork structures containing template damage and template switching mechanism of lesion bypass reveal that MtRecG but not MtRuvAB or MtRecA is proficient in driving the fork reversal. Finally, unlike MtRuvAB, we find that MtRecG drives efficient reversal of forks when fork structures are tightly bound by protein. These results provide direct evidence and valuable insights into the underlying mechanism of MtRecG catalyzed replication fork remodeling and restart pathways in vivo. Mycobacterium Tuberculosis DNA Replication DNA Repair DNA Helicases DNA Damage Genomic Instability Mycobacterium Tuberculosis RecG Helicase DNA Recombination M. tuberculosis Genome Mycobacterium tuberculosis RecG G4 DNA Biochemistry

Search results