Global ETD Search

41	The Role of NS3 Helicase Domain in Hepatitis C Virus Particle Assembly Bouter, Caroline 27 November 2012 (has links) No description available. 610 Hepatitis C non-structural protein 3 NS3 virus particle assembly helicase domain Hepatitis C non-structural protein 3 NS3 virus particle assembly helicase domain Medizin (PPN619874732)
42	Helicases and DNA dependent ATPases of Sulfolobus solfataricus Richards, Jodi D. January 2008 (has links) DNA is susceptible to various types of damage as a result of normal cellular metabolism or from environmental sources. In order to maintain genome stability a number of different, partially overlapping DNA repair pathways have evolved to tackle specific lesions or distortions in the DNA. Nucleotide excision repair (NER) is highly conserved throughout eukarya, bacteria and archaea and predominantly targets lesions that result from exposure to UV light, for example cyclobutane pyrimidine dimers and 6-4 photoproducts. The majority of archaea possess homologous of the eukaryotic repair genes and this thesis describes the isolation and the characterization of two XPB homologues identified in the crenarchaeon Sulfolobus solfataricus, SsoXPB1 and SsoXPB2. Human XPB is one of 10 proteins that make up the TFIIH transcription complex. The activity of XPB is tightly controlled by protein interactions, in particular with p52, which stimulates the ATPase activity of XPB. Rather than a conventional helicase, human XPB is thought to act as an ATP dependent conformational switch. Consistent with human XPB, however, the S. solfataricus proteins were unable to catalyse strand separation and the identification of an archaeal protein partner, Bax1, for SsoXPB2 was one of the focuses of this project. In order to maintain genome stability, the DNA must be replicated accurately with each cell cycle. When the advancing replication fork stalls at a lesion or a DNA break, it is crucial that the fork is reset and that replication continues to completion. The helicase Hel308 is thought to clear the lagging strand template of a stalled replication fork in order for replication restart to proceed via homologous recombination (HR). Although the specific function of Hel308 is not well understood, the possibilities are described in this thesis. Strand exchange proceeds to form a D-loop, followed by branch migration to increase regions of heterology during the synapsis stage of HR. No motors for branch migration have previously been recognised in archaea, although the identification of a possible candidate was investigated during this project. 572.8
43	Splitting, joining and cutting : mechanistic studies of enzymes that manipulate DNA McRobbie, Anne-Marie M. January 2010 (has links) DNA is a reactive and dynamic molecule that is continually damaged by both exogenous and endogenous agents. Various DNA repair pathways have evolved to ensure the faithful replication of the genome. One such pathway, nucleotide excision repair (NER), involves the concerted action of several proteins to repair helix-distorting lesions that arise following exposure to UV light. Mutation of NER proteins is associated with several genetic diseases, including xeroderma pigmentosum that can arise upon mutation of the DNA helicase, XPD. The consequences of introducing human mutations into the gene encoding XPD from Sulfolobus acidocaldarius (SacXPD) were investigated to shed light on the molecular basis of XPD-related diseases. XPD is a 5’-3’ DNA helicase that requires an iron-sulphur (FeS) cluster for activity (Rudolf et al., 2006). Several proteins related to SacXPD, including human XPD, human FancJ and E. coli DinG, also rely on an FeS cluster for DNA unwinding (Rudolf et al., 2006; Pugh et al., 2008; Ren et al., 2009). Sequence analysis of the homologous protein, DinG, from Staphylococcus aureus (SarDinG) suggests that this protein does not encode a FeS cluster. In addition, SarDinG comprises an N-terminal extension with homology to the epsilon domain of polymerase III from E. coli. This thesis describes the purification and characterisation of SarDinG. During replication, DNA lesions or other ‘roadblocks’, such as DNA-bound proteins, can lead to replication fork stalling or collapse. To maintain genomic integrity, the fork must be restored and replication restarted. In archaea, the DNA helicase Hel308 is thought to play a role in this process by removing the lagging strands of stalled forks, thereby promoting fork repair by homologous recombination. Potential roles of Hel308 during replication fork repair are discussed in this thesis. The mechanism by which Hel308 moves along and unwinds DNA was also investigated using a combined structural and biophysical approach. The exchange of DNA between homologous strands, catalysed by a RecA family protein (RecA in bacteria, RAD51 in eukaryotes, and RadA in archaea), defines homologous recombination. While bacteria encode a single RecA protein, both eukaryotes and archaea encode multiple paralogues that have implications in the regulation of RAD51 and RadA activity, respectively. This thesis describes the purification and characterisation of one of the RadA paralogues (Sso2452) in archaea. 572.85
44	Mécanismes d’adaptation aux basses températures de croissance de la bactérie pathogène B. cereus : rôle des hélicases à ARN / Involvement of RNA helicases in the cold adaptation of the foodborne pathogenic bacteria Bacillus cereus Pandiani, Franck 16 December 2010 (has links) Bacillus cereus est une bactérie largement disséminée dans la nature, contaminant ainsi les aliments en contact avec le sol. En France, cette bactérie est considérée comme le quatrième agent de toxi infection alimentaire collective. Pour être pathogène, B. cereus doit être capable de se multiplier lors des différentes étapes de transformation et notamment au cours de la réfrigération. Le but de cette étude a été d'étudier les mécanismes moléculaires de la réponse adaptative au froid et en particulier le rôle des hélicases à ARN de B. cereus ATCC 14579. Le gène cshA, codant pour une hélicase à ARN putative, a été identifié par une approche de mutagénèse aléatoire, comme jouant un important dans l’adaptation au froid de B. cereus. La souche ATCC 14579 possède 5 gènes codant pour des hélicases à ARN, cshA à cshE qui sont tous fortement surexprimés à 10°C par rapport à 37°C et quel que soit le stade de croissance considéré. La délétion simple des gènes cshA, cshB et cshC conduit à l’apparition de phénotypes cryosensibles, se traduisant par une incapacité d'adaptation au froid par rapport à la souche sauvage, associée à une modification de la morphologie cellulaire. De plus, CshA, CshB et CshC possèdent chacune un domaine de température où leur action est prépondérante. Elles semblent également être impliquées dans l’adaptation au stress oxydant et au stress basique, alors que CshD et E n’ont pas de rôle dans l’adaptation aux stress testés. Nous avons montré que CshA est indispensable à basse température, pour permettre le maintien de la stabilité des ribosomes avec lesquels elle interagit directement, mais aussi pour réguler la dégradation des ARNr. L’identification des partenaires protéiques interagissant avec CshA suggérent qu'elle puisse être également impliquée dans un complexe de dégradation des ARN / Bacillus cereus is a widespread bacteria, thus contaminating all raw materials in contact with soil. In France, B. cereus is considered as the fourth causative agent of foodborne illness. To be pathogenic, B. cereus should multiply during the various stages of food processing and particularly during preservation at low temperature. The aim of this study was to study molecular mechanisms of the adaptive response at low temperature and more precisely the involvement of the B. cereus ATCC 14579 RNA helicases. The cshA gene encoding a putative RNA helicase was identified by a random mutagenesis approach, as playing a major role in cold adaptation of B. cereus. The ATCC 14579 strain possesses 5 genes encoding putative RNA helicases, cshA to cshE, which were all strongly overexpressed at 10°C versus 37°C, whatever the growth stage. The simple deletion of cshA, cshB, and cshC lead to a cold-sensitive phenotype, resulting in an inability to adapt at 10 °C compared to the wild type strain, associated to a huge modification of cell morphology. In addition, CshA, CshB and CshC have a temperature range where their action is decisive. The role of these three RNA helicases also appears to be important in adaptation to oxidative and basic stresses while CshD and E did not appear to be involved in the adaptation to the tested stresses. The RNA helicase CshA has the most important role in adaptation to cold. We demonstrated that CshA is essential at low temperature to allow the maintenance of ribosome stability. CshA interacts directly with ribosomes, and also regulate rRNA degradation. The identification of protein partners that interact with CshA suggests that it could be involve in a complex of RNA decay Bacillus cereus Hélicase à ARN Froid Stress Adaptation Bacillus cereus RNA helicase Cold Stress Adaptation
45	The DEAD-Box Helicase Family Member Ded1 Plays a Role in the Cellular Stress Response Rodela, Emily Cristina, Rodela, Emily Cristina January 2016 (has links) The DEAD-Box RNA helicase family is a conserved group of enzymes that function in gene expression through ATP-dependent RNA unwinding and ribonucleoprotein (RNP) remodeling. DEAD-Box helicases function in multiple cellular processes, including pre-mRNA processing, translation, mRNA export, and mRNA decay. Although DEAD-Box proteins are critical for gene expression, much of their mechanistic activities are poorly understood. DEAD-Box proteins have increasingly been linked to tumorigenesis in humans, and better defining their activity at the mechanistic level will aid in understanding the underlying disease pathology. In this study, we used the model organism Saccharomyces cerevisiae to study the human DEAD-Box protein DDX3 orthologue, Ded1, and its role in translation initiation during cellular stress. Recently, we have found that Ded1 is an important mediator of the cellular stress response in a TOR-dependent manner. TOR regulates protein synthesis dependent on energy availability in the cell by regulating the assembly of the eukaryotic translation initiation complex. Human DDX3 has been found to interact with translation initiation complex subunit eIF4E and Ded1 has been found to interact with the translation initiation complex subunit eIF4G. In this study, we examined the purported interaction region between Ded1 and eIF4G on the C-terminus of Ded1 and found that ded1 Δ591-604 prevents eIF4G degradation under rapamycin treatment and confers resistance to rapamycin-induced growth inhibition. We also examined putative regulatory phosphorylation sites in the purported Ded1 eIF4G binding region. We propose that the Ded1/eIF4G interaction is critical for the repression of translation by Ded1 and that eIF4G degradation may be regulated by Ded1 under stress conditions. Ded1 eIF4G RNA helicase Translation Initiation Cellular and Molecular Medicine DEAD-Box proteins
46	Structure-function studies of the bacterial dsDNA translocase FtsK Graham, James Edward January 2010 (has links) DNA translocases are molecular motors that use energy from nucleotide triphosphate (NTP) hydrolysis to move along, pump, remodel or clear DNA. Unlike helicases, double-stranded DNA (dsDNA) translocases do not unwind DNA; their action has no net product apart from inducing supercoils as a result of groove-tracking, which has hampered their characterisation. Many dsDNA translocases appear to have biased directionality. However, the inherent symmetry of dsDNA requires that translocase activity is regulated by specific sequences or through modulation by interaction partners. FtsK is a highly conserved bacterial cell-division protein, localised to the dividing septum, that coordinates chromosome segregation with cytokinesis. It is responsible for the resolution of chromosome dimers by activating the tyrosine recombinases XerCD bound to the 28bp chromosomal site dif. The C-terminal domain of FtsK (FtsKC) is a dsDNA translocase (speed ~5 kb/s, stall force ~60 pN) most closely related to superfamily 4 helicases and is active as a hexameric ring. A winged-helix subdomain at the C-terminus of FtsKC, FtsKgamma, binds to specific 8 bp sequences, KOPS, that are polarised in the bacterial chromosome from the origin to towards dif. FtsKgamma also interacts with XerD, activating it for catalysis. Studies of FtsK translocation have differed over whether KOPS act as a loading or a reversal sequence for FtsK. In Chapter 2, I use a continuous ensemble assay for dsDNA translocation to show that FtsK initiates rapidly at KOPS, with loading dependent on FtsKgamma. Translocation requires moderately cooperative ATP binding, while ATP hydrolysis has a more relaxed cooperativity. I have determined the ATP coupling efficiency of translocation to be ~1.6 bp/ATP, in line with theoretical estimates. Though FtsK probably strips most proteins from DNA, I show in Chapter 3 that FtsK stops translocating when it encounters XerCD bound to dif. The interaction is most likely a specific down-regulation, but surprisingly does not depend on FtsKgamma or on the catalytic or synaptic activity of XerCD. In Chapter 4, I show some preliminary structural data of FtsKC bound to dsDNA, with the aim of determining the first high resolution structure of a ring dsDNA translocase bound to nucleic acid. 572.85
47	Helicase-SSB Interactions In Recombination-Dependent DNA Repair and Replication Jordan, Christian 01 January 2014 (has links) Dda, one of three helicases encoded by bacteriophage T4, has been well- characterized biochemically but its biological role remains unclear. It is thought to be involved in origin-dependent replication, recombination-dependent replication, anti- recombination, recombination repair, as well as in replication fork progression past template-bound nucleosomes and RNA polymerase. One of the proteins that most strongly interacts with Dda, Gp32, is the only single-stranded DNA binding protein (SSB) encoded by T4, is essential for DNA replication, recombination, and repair. Previous studies have shown that Gp32 is essential for Dda stimulation of replication fork progression. Our studies show that interactions between Dda and Gp32 play a critical role in regulating replication fork restart during recombination repair. When the leading strand polymerase stalls at a site of ssDNA damage and the lagging strand machinery continues, Gp32 binds the resulting ssDNA gap ahead of the stalled leading strand polymerase. We found that a Gp32 cluster on leading strand ssDNA blocks Dda loading on the lagging strand ssDNA, blocks stimulation of fork progression by Dda, and stimulates Dda to displace the stalled polymerase and the 3' end of the daughter strand. This unwinding generates conditions necessary for polymerase template switching in order to regress the DNA damage-stalled replication fork. Helicase trafficking by Gp32 could play a role in preventing premature fork progression until the events required for error-free translesion DNA synthesis have taken place. Interestingly, we found that Dda helicase activity is strongly stimulated by the N-terminal deletion mutant Gp32-B, suggesting the N-terminal truncation to generate Gp32-B reveals a cryptic helicase stimulatory activity of Gp32 that may be revealed in the context of a moving polymerase, or through direct interactions of Gp32 with other replisome components. Additionally, our findings support a role for Dda-Gp32 interactions in double strand break (DSB) repair by homology-directed repair (HDR), which relies on homologous recombination and the formation of a displacement loop (D-loop) that can initiate DNA synthesis. We examined the D-loop unwinding activity of Dda, Gp41, and UvsW, the D-loop strand extension activity of Gp43 polymerase, and the effect of the helicases and their modulators on D-loop extension. Dda and UvsW, but not Gp41, catalyze D-loop invading strand by DNA unwinding. The relationship between Dda and Gp43 was modulated by the presence of Gp32. Dda D-loop unwinding competes with D- loop extension by Gp43 only in the presence of Gp32, resulting in a decreased frequency of invading strand extension when all three proteins are present. These data suggest Dda functions as an antirecombinase and negatively regulates the replicative extension of D- loops. Invading strand extension is observed in the presence of Dda, indicating that invading strand extension and unwinding can occur in a coordinated manner. The result is a translocating D-loop, called bubble migration synthesis, a hallmark of break-induced repair (BIR) and synthesis dependent strand annealing (SDSA). Gp41 did not unwind D- loops studied and may serve as a secondary helicase loaded subsequent to D-loop processing by Dda. Dda is proposed to be a mixed function helicase that can work both as an antirecombinase and to promote recombination-dependent DNA synthesis, consistent with the notion that Dda stimulates branch migration. These results have implications on the repair of ssDNA damage, DSB repair, and replication fork regulation, which are highly conserved processes sustained in all organisms. DNA helicase recombination repair replication single-stranded DNA binding protein Biochemistry Molecular Biology
48	Molecular mechanisms of premature ageing in a worm model of human Werner syndrome Lees, Hayley Diane January 2014 (has links) Investigating the biological basis of ageing is both fascinating and medically relevant, as we strive to understand both how organisms age, and how our knowledge might be put to good use in an increasingly long-lived human population. Despite the complexity of ageing biology, it is very striking that longevity, in a wide variety of organisms, can be modified by manipulating single genes. In this thesis, I investigate phenotypes associated with mutations in C. elegans homologues of human WRN, the gene mutated in the progeroid Werner syndrome (WS). Mutant phenotypes in the worm recapitulate aspects of the pathophysiology observed in WS patients, including premature ageing, genomic instability, and sensitivity to DNA damaging agents. wrn-1 overexpression, on the other hand, appears to enhance longevity, suggesting that wrn-1 acts as a bona fide anti-gerontogene. The combination of wrn-1 mutations with mutation in the worm p53 homologue, cep-1, unexpectedly triggers a novel and very striking enhanced lifespan and healthspan phenotype, termed synthetic super-viability (SSV). The SSV phenotype is modulated by various environmental inputs such as temperature stress. The data presented here can be incorporated into a model in which stress sensing (involving p53) is the crucial determinant of longevity outcomes. Several theories of ageing incorporate the idea that 'that which does not kill us, makes us stronger' - encapsulated in a biological sense in the idea of hormesis, a physiological shift in response to stress. Here, this hypothesis is expanded to include the notion that intrinsic <strong>responses</strong> to stress may themselves act to limit lifespan - too much of a good thing can be bad. 612.6
49	Rôles de l'endonucléase Sae2 et de l'helicase Sgs 1 dans le métabolisme des télomères chez la levure Saccharomyces cerevisiae . Hardy, Julien 09 November 2012 (has links) Les télomères sont des structures nucléo-protéiques présentes à l'extrémité des chromosomes. Ils sont un des facteurs garant de la stabilité génomique. Ils assurent la protection des extrémités des chromosomes et leur entière réplication. Les dysfonctionnements du télomère sont impliqués dans la tumorigénèse et le vieillissement.Un des rôles majeurs des télomères est d'éviter que les extrémités des chromosomes ne soient reconnues comme des cassures double brin de l'ADN et traitées comme telles par la machinerie de réparation. Cependant, de nombreuses protéines impliquées dans la reconnaissance et le métabolisme des cassures double brin, comme la protéine Tel1 et le complexe MRX par exemple, sont présentes au niveau des télomères et participent au maintien de leur taille par la télomérase. En s'appuyant sur cette analogie, j'ai étudié le rôle télomérique de l'endonucléase Sae2 et de l'hélicase Sgs1, impliquées dans l'étape de dégradation du brin 5' qui précède la réparation des cassures double brin de l'ADN par recombinaison.Les rôles des protéines Sae2 et Sgs1 ont été étudiés sur les télomères natifs et sur les télomères érodés lors de la sénescence réplicative. L'ensemble de mes résultats suggèrent que, bien que les télomères érodés en absence de télomérase soient reconnus comme une cassure double brin de l'ADN et traités comme tels par les nucléases et hélicases, le rôle majeur de Sae2 et Sgs1 au niveau des télomères natifs serait de les protéger contre des recombinaisons illégitimes au cours de leur réplication. / Telomeres are nucleoprotein complexes that protect the extremities of linear chromosomes, avoiding end-to-end fusions and nucleolytic degradation of chromosome ends. The failure of cells to properly maintain telomeres can be an important source of chromosome instability involved in cancer progression and aging.A major role of telomeres is to prevent chromosome ends from being recognized as damage-induced double-strand DNA breaks (DSBs). However, many proteins involved in recognition and processing of DSBs are also involved in telomeres maintenance, like Tel1 and MRX. Based on this analogy, I have studied the role at telomeres of the role of the endonuclease Sae2 and the helicase Sgs1, two proteins that have a key function in the processing of DSBs through nucleolytic degradation of their 5' end.The role of protein Sae2 and Sgs1 has been studied at native and eroded telomeres. My results showed that eroded telomeres, in telomerase deficient cells, are recognized and resected as a double-strand break DNA by a set of nucleases and helicases including Sae2 and sgs1. In contrast, the main role of Sae2 and Sgs1 at native telomeres would be to protect telomeres against illegitimate recombination during replication. Télomère Hélicase Nucléase Sénescence Réplication Recombinaison Telomere Helicase Nuclease Senescence Replication Recombination
50	Charakterizace proteinu HelD z Bacillus subtilis / Characterization of the HelD protein from Bacillus subtilis Sudzinová, Petra January 2013 (has links) BACKGROUND: Bacterial RNA polymerase (RNAP) is an extensively studied enzyme required for gene expression. In our Laboratory we found a new protein named HelD. HelD copurifies with B. subtilis RNAP. HelD is a ~90 kDa protein from the UvrD/Rep helicase family, which contains protein with the 3'-5' DNA unwinding activity. The molecular role(s) HelD in cell are still unknown and its potential role in transcription has not been studied so far. OBJECTIVE: The main aim of this Diploma project was to describe HelD. APPROACHES: The characterization was carried out on three levels: (i) bioinformatics analysis in silico was used to identify HelD homologs in other bacteria; (ii) growth tests in vivo were used to determine the phenotype(s) of the HelD-null mutant strain compared to wt; and (iii) biochemical experiments in vitro were utilized to describe the effects of HelD on transcription, and to test whether HelD has DNA binding and DNA unwinding activities. RESULTS: The in silico analysis revealed that HelD is present in Firmicutes, an industrially and medicinally important group of G+ bacteria. The phenotypic experiments showed that HelD is required for rapid adaptations to nutritional changes in the environment. The biochemical experiments showed that HelD stimulates transcription despite the fact that it...

Search results