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Analysis of the Nucleioprotein Complexes Essential for P1 Plasmid PartitionVecchiarelli, Anthony 01 September 2010 (has links)
For all organisms, segregation and proper intracellular localization of DNA are essential processes in ensuring faithful inheritance of genetic material. In prokaryotes, several different mechanisms have developed for efficiently moving chromosomal DNA to proper cellular locations prior to cell division, and the same holds true for bacterial plasmids. Low-copy-number plasmids and bacterial chromosomes encode active partition systems to ensure their inheritance within a bacterial cell population. One of the well-studied models of partition is that of the P1 plasmid in E. coli. The partition system encoded by the P1 plasmid is known as parABS - ParA is the partition ATPase, ParB is the partition site binding protein and parS is the partition site. The goal of this thesis was to investigate the nucleoprotein complexes essential in the P1 plasmid partition reaction. First, I examined how a single ParB dimer can bind its complicated arrangement of recognition motifs in parS to initiate the partition reaction. I then characterized a novel ParA interaction with the host nucleoid that is critical for proper P1 plasmid dynamics in vivo. Finally, I demonstrate how ParA can act as an adaptor between the nucleoid and the partition complex; effectively allowing the plasmid to use the nucleoid as a track for its intracellular movement and localization. My thesis work provides evidence towards a model that explains the P1 plasmid partition mechanism.
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Analysis of the Nucleioprotein Complexes Essential for P1 Plasmid PartitionVecchiarelli, Anthony 01 September 2010 (has links)
For all organisms, segregation and proper intracellular localization of DNA are essential processes in ensuring faithful inheritance of genetic material. In prokaryotes, several different mechanisms have developed for efficiently moving chromosomal DNA to proper cellular locations prior to cell division, and the same holds true for bacterial plasmids. Low-copy-number plasmids and bacterial chromosomes encode active partition systems to ensure their inheritance within a bacterial cell population. One of the well-studied models of partition is that of the P1 plasmid in E. coli. The partition system encoded by the P1 plasmid is known as parABS - ParA is the partition ATPase, ParB is the partition site binding protein and parS is the partition site. The goal of this thesis was to investigate the nucleoprotein complexes essential in the P1 plasmid partition reaction. First, I examined how a single ParB dimer can bind its complicated arrangement of recognition motifs in parS to initiate the partition reaction. I then characterized a novel ParA interaction with the host nucleoid that is critical for proper P1 plasmid dynamics in vivo. Finally, I demonstrate how ParA can act as an adaptor between the nucleoid and the partition complex; effectively allowing the plasmid to use the nucleoid as a track for its intracellular movement and localization. My thesis work provides evidence towards a model that explains the P1 plasmid partition mechanism.
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Chorégraphie de ségrégation des deux chromosomes de Vibrio cholerae / Segregation choreography of the two chromosomes of Vibrio choleraeDavid, Ariane 05 December 2013 (has links)
L’objectif de cette thèse est de définir la chorégraphie de ségrégation des deux chromosomes circulaires de Vibrio cholerae, c’est à dire le positionnement de l’information génétique au cours de la croissance de la cellule, ainsi que les mécanismes dirigeant ces ségrégations. Il a longtemps été supposé que les bactéries étaient trop petites pour avoir une organisation intra-cellulaire, et le manque de techniques appropriées ne permettait pas d’infirmer cette hypothèse. Or la taille des chromosomes comparée à celle de la bactérie impose une compaction et aujourd’hui, de nouvelles techniques de microscopie et d’analyse génétique permettent d’affirmer que les chromosomes bactériens étudiés jusqu’à maintenant ont tous une organisation et une chorégraphie de ségrégation précises et différentes selon les espèces. Toutes les espèces étudiées à ce jour ont un chromosome circulaire unique : la réplication du chromosome commence à une origine unique bidirectionnelle, les deux fourches de réplication se déplacent le long des deux bras de réplication (ou réplichores) et finissent la réplication au terminus, diamétralement à l’opposée de l’origine de réplication sur la carte du chromosome. Peu d’espèces ont été étudiées, et Vibrio cholerae émerge progressivement comme un nouveau modèle : son génome est réparti sur deux chromosomes, et la chorégraphie de plusieurs chromosomes dans une cellule n’a jamais été décrite. De plus, cette espèce semble être au croisement évolutif entre Caulobacter crescentus et Escherichia coli : Vibrio cholerae a d’une part une morphologie en croissant, des systèmes de partition aux origines et un positionnement de l’origine du chromosome I, semblables à C. crescentus, et d’autre part un système de compaction du terminus et un set de gènes impliqués dans la maintenance du chromosome ayant co-évolué, qu’on ne retrouve que dans peu d’espèces proches d’E. coli. Une autre caractéristique intéressante de V. cholerae est que le chromosome II semble avoir été acquis récemment et n’est donc peut être pas gouverné par les mêmes mécanismes que le chromosome I, comme en témoignent le positionnement de son origine et son terminus, inédits pour des chromosomes bactériens. Parmi les Vibrios (environ 60 espèces principalement retrouvées dans les environnements aquatiques), certaines espèces sont des pathogènes dévastateurs pour les poissons, le corail, les crustacés ou les fruits de mer. Mais la plus documentée est Vibrio cholerae, car elle provoque chez l’Humain une maladie provoquée par l’ingestion d’eau contaminée qui peut être mortelle si le patient n’est pas réhydraté à temps. Bien que facilement traitable, le choléra fait encore de nombreuses victimes dans les pays en développement où les structures de santé et les règles d’hygiène font parfois défaut. Ainsi l’étude de Vibrio cholerae présente un intérêt médical, mais également par extension aux autres Vibrios, un intérêt environnemental non négligeable. / The aim of this thesis is to define the segregation choreography of the two circular chromosomes of Vibrio cholerae, which is the positionning of the genetic information during cell growth, as well as the mecanisms directing those segregations. It was supposed for a long time that bacteria were too small to have a intra-cellular organization and the lack of appropriate tools could not prove this hypothesis wrong. The size of the chromosomes compared to the size of the cell means there has to be a compaction and today, new tools for microscopy and genetic analysis allow us to affirm that all bacterial chromosomes studied so far have an organization and a segregation choreography which are precise and different between specie. Most bacterial specie studied to this day have a unique circular chromosome : the replication of the chromosome starts at a unique and bidirectionnal origin, both replication forks move along the two replication arms (or replichores) and end the replication at the terminus which is diametrically to the opposite of the origin on the chromosome map. A few specie have been studied, and Vibrio cholerae progressively emerges as a new model : its genome is divided between two chromosomes, and the choreography of several chromosomes in a cell has never been described. Moreover, this species seems to be at the crossover between Caulobacter crescentus and Escherichia coli : Vibrio cholerae as on one hand, a crescent shape, partition systems positionned at both origins and a positionning of the chromosome I origin similar to C. crescentus, and on the other hand a compaction system of the terminus and a set of genes involved on the maintenance of chromosomes that one only finds in very few specie closely related to E. coli. An other interesting characteristic of V. cholerae is that the chromosome II seems to have been acquired recently and thus might not be governed by the same mecanisms as the chromosome I, as shown by the positionning of its origin and terminus which are completely new to bacterial chromosomes. Among Vibrios (about 60 species mostly found in aquatic environments), some species are devastating pathogens for fish, coral, crustacean and shellfish. But the most documented one is Vibrio cholerae, because it induces a disease in humans caused by the ingestion of contaminated water, which can be deadly if the patient is not rehydrated on time. Although easily treatable, cholera still makes a lot of victims in developing countries where health structures and basic hygiene sometimes lack dramatically. The study of Vibrio cholerae has a medical interest, but also by extention to other Vibrios, a non-negligible environmental interest.
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Interaction of P1 Plasmid Partition Components with the Bacterial ChromosomeYu, Analyn R. 29 July 2010 (has links)
P1 is a low copy number plasmid that uses a dedicated partition system that actively ensures each daughter cell inherits a copy of the plasmid. P1 plasmid partition is a positioning reaction, ensuring that each plasmid copy is correctly localized to the one-quarter and three-quarter position or midcell in an E. coli cell prior to partition. The factors involved in this positioning process are not well understood. I utilized cell biology techniques and E. coli mukB mutants that produce cells with chromosomal condensation defects to study the role of the bacterial chromosome and P1 ParA as possible localization signals. P1 plasmid prefers to localize to the bacterial nucleoid even when the chromosome is perturbed. ParA is necessary for plasmid localization to the chromosome. In this study, live cell microscopy analysis of ParA indicates that an interaction between P1 ParA and the E. coli nucleoid may underlie the localization mechanism of the plasmid partition system.
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Interaction of P1 Plasmid Partition Components with the Bacterial ChromosomeYu, Analyn R. 29 July 2010 (has links)
P1 is a low copy number plasmid that uses a dedicated partition system that actively ensures each daughter cell inherits a copy of the plasmid. P1 plasmid partition is a positioning reaction, ensuring that each plasmid copy is correctly localized to the one-quarter and three-quarter position or midcell in an E. coli cell prior to partition. The factors involved in this positioning process are not well understood. I utilized cell biology techniques and E. coli mukB mutants that produce cells with chromosomal condensation defects to study the role of the bacterial chromosome and P1 ParA as possible localization signals. P1 plasmid prefers to localize to the bacterial nucleoid even when the chromosome is perturbed. ParA is necessary for plasmid localization to the chromosome. In this study, live cell microscopy analysis of ParA indicates that an interaction between P1 ParA and the E. coli nucleoid may underlie the localization mechanism of the plasmid partition system.
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Biochemical and Functional Characterization of Mycobacterium Tuberculosis Nucleoid-Associated Proteins H-NS and mIHFHarshavardhana, Y January 2015 (has links) (PDF)
Bacteria lack nucleus and any other membrane-bound organelles. Hence all the cellular components, including proteins, DNA, RNA and other components are located within the cytoplasm. The region of the cell which encompasses the bacterial genomic DNA is termed ‘Nucleoid’. The nucleoid is composed largely of DNA and small amounts of proteins and RNA. The genomic DNA is organized in ways that are compatible with all the major DNA-related processes like replication, transcription and chromosome segregation. Proteins that play important role(s) in the structuring of DNA and having the potential to influence gene expression have been explored in all kingdoms of life. The organization of bacterial chromosome is influenced by several important factors. These factors include molecular crowding, negative supercoiling of DNA and NAPs (nucleoid-associated proteins) and transcription.
Nucleoid-associated proteins are abundant and relatively low-molecular mass proteins which can bind DNA and function as architectural constituents in the nucleoid. Additionally, NAPs are involved in all the major cellular processes like replication, repair and gene transcription. At least a dozen distinct NAPs are known to be present in E. coli. HU, IHF (integration host factor), H-NS (histone-like nucleoid-structuring), Fis (Factor for inversion stimulation), Dps (DNA protection from starvation) are some of the abundant NAPs in E. coli. Most of these proteins bind DNA and show either DNA bending, bridging or wrapping which are directly relevant to their physiological role(s). As most of these proteins are involved in the regulation of transcription of many genes, they act as factors unifying gene regulation with nucleoid architecture and environment. Pathogenic bacteria have the ability to grow and colonize different environments and thus need to adapt to constantly changing conditions within the host. H-NS and IHF, being able to link environmental cues to the regulation of gene expression, play an important role in the bacterial pathogenesis.
H-NS is one of the well studied NAPs in enterobacteria, and is known as a global gene silencer. It is also an important DNA structuring protein, involved in chromosome packaging. H-NS protein is a small (~15 kDa) protein, which is present at approximately 20000 copies/ cell. The most striking feature of H-NS is that although it binds DNA in a relatively sequence-independent fashion but is known to preferentially recognize and bind intrinsically curved DNA. It also constrains DNA supercoils in vitro, thereby affects DNA topology. H-NS also influences replication, recombination and genomic stability. In addition, it functions as a global regulator by regulating the expression of various genes which are linked to environmental adaptation. Various studies have shown the association of H-NS to AT-rich regions of the genome. About 5% of E. coli genes are regulated by H-NS, bulk of which are (~80%) negatively regulated. H-NS is involved in the silencing of horizontally-acquired genes, many of which are involved in pathogenesis, in a process known as xenogeneic silencing. H-NS is known to regulate the expression of various virulence factors like cytotoxins, fimbriae and siderophores in several pathogenic bacteria. Several studies have revealed that hns mutants show increased frequency of illegitimate recombination and reduction in intra-chromosomal recombination, indicating the involvement of H-NS in DNA repair/recombination. H-NS is known to act in several transposition systems, which it does so due to its ability to interact with other proteins involved and due to its DNA structure-specific binding activity.
The prototypical IHF (Integration Host Factor) was originally discovered in E. coli as an essential co-factor for the site-specific recombination of phage λ. E. coli IHF belongs to DNABII structural family, along with HU and other proteins and consists of two subunits, IHFα and IHFβ. Thesubunits are ~10 kDa each and are essential for full IHF activity. Apart from its role in bacteriophage integration/excision, IHF also has roles in various processes such as DNA replication, transcription and also in several site-specific recombination systems. In most of these processes, IHF acts as an architectural component by facilitating the formation of nucleoprotein complexes by bending DNA at specific sites. IHF acts as a transcriptional regulator, influencing the global gene expression in E. coli and S. Typhimurium. Gene regulation by IHF requires its DNA architectural role, facilitating interactions between RNA polymerase and regulatory protein. The high intracellular concentration of IHF indicates that it might associate with DNA in a non-specific manner and contribute to chromatin organization. The binding of E. coli IHF causes the DNA to adopt U-turn and brings the non-adjacent sequences into close juxtaposition.
IHF is also involved in gene regulation in several pathogenic organisms and is shown to regulate expression of many virulence factors.
Despite extensive literature on NAPs, very little is known about NAPs and nucleoid architecture in M. tuberculosis. In the light of significant physiological roles played by NAPs in adaptation to environmental changes and in growth and virulence of bacteria, elucidation of their roles in M. tuberculosis is of paramount importance for a better understanding of its pathogen city. M. tuberculosis Rv3852 (hns) gene is predicted to encode a 134 amino acid protein with a molecular mass of 13.8 kDa. The amino acid sequence alignment revealed that M. tuberculosis H-NS and E. coli H-NS showed very low degree of sequence identity (6%). To explore the biochemical properties of M. tuberculosis H-NS, the sequence corresponding to Rv3852 was amplified via PCR, cloned and plasmid expressing M. tuberculosis hns was constructed. M. tuberculosis H-NS was over expressed and purified to homogeneity. E. coli H-NS was also over expressed and purified. Comparison of experimentally determined secondary structure showed considerable differences between M. tuberculosis and E. coli H-NS proteins. Chemical cross linking suggested that M. tuberculosis H-NS protein exists in both monomeric and dimeric forms in solution, consistent with the diametric nature of E. coli H-NS protein. Our studies have revealed that M. tuberculosis H-NS binds in a more structure-specific manner to DNA replication and repair intermediates, but displays lower affinity for double stranded DNA with relatively higher GC content. It bound to the Holliday junction (HJ), the central recombination intermediate, with high affinity. Furthermore, similar to M. tuberculosis H-NS, E. coli H-NS was able to bind to replication and recombination intermediates, but at a lower affinity than M. tuberculosis H-NS. To gain insights into homologous recombination in the context of nucleoid, we investigated the ability of M. tuberculosis RecA to catalyze DNA strand exchange between single-strand DNA and linear duplex DNA in the presence of increasing amounts of H-NS. We found that M. tuberculosis H-NS inhibited strand exchange mediated by its cognate RecA in a concentration dependent manner. Similar effect was seen in the case of E. coli H-NS, where it was able to suppress DNA strand exchange promoted by E. coli RecA, but at relatively higher concentrations, suggesting that H-NS proteins act as ‘roadblocks’ to strand exchange promoted by their cognate RecA proteins.
H-NS and members of H-NS-family of NAPs are known to form rigid nucleoprotein filament structures on binding to DNA, which results in gene-silencing and is also implicated in chromosomal organization. Studies have also shown that H-NS mutants defective in gene silencing also lack the ability to form rigid nucleoprotein filament structure and that nucleoprotein filament structure is responsive to environmental factors. Our studies employing ligase-mediated DNA circularization assays reveal that both E. coli and M. tuberculosis H-NS proteins abrogate the circularization of linear DNA substrate by rigidifying the DNA backbone. These results suggest that M. tuberculosis H-NS could form nucleoprotein filament-like structures upon binding to DNA and these structures might be involved in transcriptional repression, chromosomal organization and protection of genomic DNA. In summary, these findings provide insights into the role of M. tuberculosis H-NS in homologous and/or homeologous recombination as well as transcriptional regulation and nucleoid organization.
The second part of the thesis concerns the characterization of M. tuberculosis integration host factor (mIHF). The annotation of whole-genome sequence of M. tuberculosis H37Rv showed the presence of Mtihf gene (Rv1388) which codes for a putative 20-kDa integration host factor (mIHF). Amino acid sequence alignment revealed very low degree of sequence identity between mIHF and E. coli IHFαβ subunits. Unlike E. coli IHF, mIHF is essential for the viability of M. tuberculosis. The three-dimensional molecular modeling of mIHF based upon co crystal structure of Streptomycin coelicolor IHF (sIHF) duplex DNA, showed the presence of conserved Arg170, Arg171, Arg173, which were predicted to be involved in DNA binding and a conserved Pro150, in the tight turn. The coding sequence corresponding to the M. tuberculosis H37Rv ihf gene (Rv1388) was amplified, cloned and plasmid over expressing M. tuberculosis ihf (pMtihf) was constructed. Using pMtihf as a template and using specific primers, mutant ihf encoding plasmids were constructed in which, the arginine at position 170, 171, or 173 was replaced with alanine or aspartate and proline at position 150 was substituted with alanine.
To explore the role of mIHF in cell viability, we investigated the ability of M. tuberculosis ihf to complement E. coli ΔihfA or ΔihfB strains against genotoxic stress. Despite low sequence identity between Mtihf and E. coli ihfA and ihfB, wild type Mtihf was able to rescue the UV and MMS sensitive phenotypes of E. coli ΔihfAand ΔihfBstrains, whereas Mtihf alleles bearing mutations in the DNA-binding residues failed to confer resistance against DNA-damaging agents. To further characterize the functions of mIHF, wild type and mutant versions of mIHF proteins were over expressed and purified to near homogeneity. Circular dichroism spectroscopy of wild type mIHF and mIHF mutant proteins revealed that they have similar secondary structures. By employing size-exclusion chromatography and blue-native PAGE, we determined that mIHF exists as a dimmer in solution. To understand the mechanistic basis of mIHF functions, we carried out electrophoretic mobility shift assays. In these assays, we found that wild-type mIHF showed high affinity and stable binding to DNA containing attB and attP sites and also to curved DNA, but not those mIHF mutants bearing mutations in DNA-binding residues. Because wild type mIHF was able to rescue the UV and MMS sensitive phenotypes of
E. coli ΔihfA and ΔihfB strains, we ascertained the effect of overexpression of mIHF proteins on the bacterial nucleoid. Our results revealed that wild type mIHF was also able to cause significant nucleoid compaction upon its overexpression, but mutant mIHF proteins were unable to cause compaction of E. coli nucleoid structure.
M. smegmatis IHF is known to stimulate L5 phage integrase mediated site-specific recombination, we investigated the ability of mIHF to promote site-specific recombination. In vitro recombination assays showed that M. tuberculosis IHF effectively stimulated the L5 integrase mediated site-specific recombination. Since DNA-bending activity of E. coli IHF is necessary for its functions in various processes like initiation of replication, site-specific recombination, transcriptional regulation and chromosomal organization, we asked whether mIHF possesses DNA bending activity. We employed ligase mediated DNA circularization assays, which revealed that like E. coli IHF, mIHF was able to bend DNA resulting in the covalent closure of DNA to yield circular DNA molecules. Interestingly mIHF also resulted in the formation of slower migrating linear DNA multimers, albeit to a lesser extent, which suggest that both E. coli IHF and mIHF show DNA-bending, but the mechanism is distinct. Further studies using atomic force microscopy showed that depending upon the placement of preferred binding site (curved-DNA sequence) mIHF promotes DNA compaction into nucleoid-like or higher order filamentous structures. Together, these findings provide insights into functions of mIHF in the organization of bacterial nucleoid and formation of higher-order nucleoprotein structures. Importantly, our studies revealed that the DNA-binding residues, the DNA bending mechanism and mechanism of action of mIHF during site-specific recombination were different from E. coli IHF protein. Together with extensive biochemical and in vitro data of bacterial growth, the findings presented in this thesis provide novel insights into the biological roles of H-NS and mIHF in M. tuberculosis.
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