Rôle des topoisomérases de type IA dans la ségrégation des chromosomes chez Escherichia coli

Tanguay, Cynthia

12 1900

Les topoisomérases I (topA) et III (topB) sont les deux topoisomérases (topos) de type IA d’Escherichia coli. La fonction principale de la topo I est la relaxation de l’excès de surenroulement négatif, tandis que peu d’information est disponible sur le rôle de la topo III. Les cellules pour lesquelles les deux topoisomérases de type IA sont manquantes souffrent d’une croissance difficile ainsi que de défauts de ségrégation sévères. Nous démontrons que ces problèmes sont majoritairement attribuables à des mutations dans la gyrase qui empêchent l’accumulation d’excès de surenroulement négatif chez les mutants sans topA. L’augmentation de l’activité de la gyrase réalisée par le remplacement de l’allèle gyrB(Ts) par le gène de type sauvage ou par l’exposition des souches gyrB(Ts) à une température permissive, permet la correction significative de la croissance et de la ségrégation des cellules topos de type IA. Nous démontrons également que les mutants topB sont hypersensibles à l’inhibition de la gyrase par la novobiocine. La réplication non-régulée en l’absence de topA et de rnhA (RNase HI) augmente la nécessité de l’activité de la topoisomérase III. De plus, en l’absence de topA et de rnhA, la surproduction de la topoisomérase III permet de réduire la dégradation importante d’ADN qui est observée en l’absence de recA (RecA). Nous proposons un rôle pour la topoisomérase III dans la ségrégation des chromosomes lorsque l’activité de la gyrase n’est pas optimale, par la réduction des collisions fourches de réplication s’observant particulièrement en l’absence de la topo I et de la RNase HI. / E. coli possesses two type IA topoisomerases (topos), namely topo I (topA) and topo III (topB). The major function of topo I is the relaxation of excess negative supercoiling. Much less is known about the function of topo III. Cells lacking both type IA topos suffer from severe chromosome segregation and growth defects. We show that these defects are mostly related to the presence of gyrase mutations that prevent excess negative supercoiling in topA null mutants. Indeed, increasing gyrase activity by spontaneous mutations, by substituting a gyrB(Ts) allele for a wild-type one or by exposing cells carrying the gyrB(Ts) allele to permissive temperatures, significantly corrected the growth and segregation defects of cells lacking type IA topo activity. We also found that topB mutants are hypersensitive to novobiocin due to gyrase inhibition. Our data also suggest that unregulated replication occurring in the absence of topA and rnhA (RNase HI) exacerbates the need for topo III activity. Moreover, when topA and rnhA were absent, we found that topo III overproduction reduced the extensive DNA degradation that took place in the absence of recA (RecA). All together, our results lead us to propose a role for topo III in chromosome segregation when gyrase activity is suboptimal, thus reducing replication forks collapse, especially when replication is unregulated due to the absence of topo I and RNase HI.

Topoisomérase de type IA

Gyrase

RNase HI

Ségrégation des chromosomes

Réplication

Décaténation

Division cellulaire

Précaténane

Surenroulement de l’ADN

Escherichia coli

Type IA topoisomerase

Chromosome segregation

Replication

Decatenation

Cell division

Precatenane

DNA supercoiling

Les R-loops et leurs conséquences sur l'expression génique chez Escherichia coli.

Baaklini, Imad

02 1900

Des variations importantes du surenroulement de l’ADN peuvent être générées durant la phase d’élongation de la transcription selon le modèle du « twin supercoiled domain ». Selon ce modèle, le déplacement du complexe de transcription génère du surenroulement positif à l’avant, et du surenroulement négatif à l’arrière de l’ARN polymérase. Le rôle essentiel de la topoisomérase I chez Escherichia coli est de prévenir l’accumulation de ce surenroulement négatif générée durant la transcription. En absence de topoisomérase I, l’accumulation de ce surenroulement négatif favorise la formation de R-loops qui ont pour conséquence d’inhiber la croissance bactérienne. Les R-loops sont des hybrides ARN-ADN qui se forment entre l’ARN nouvellement synthétisé et le simple brin d’ADN complémentaire. Dans les cellules déficientes en topoisomérase I, des mutations compensatoires s’accumulent dans les gènes qui codent pour la gyrase, réduisant le niveau de surenroulement négatif du chromosome et favorisant la croissance. Une des ces mutations est une gyrase thermosensible qui s’exprime à 37 °C. La RNase HI, une enzyme qui dégrade la partie ARN d’un R-loop, peut aussi restaurer la croissance en absence de topoisomérase I lorsqu’elle est produite en très grande quantité par rapport à sa concentration physiologique. En présence de topoisomérase I, des R-loops peuvent aussi se former lorsque la RNase HI est inactive. Dans ces souches mutantes, les R-loops induisent la réponse SOS et la réplication constitutive de l’ADN (cSDR). Dans notre étude, nous montrons comment les R-loops formés en absence de topoisomérase I ou RNase HI peuvent affecter négativement la croissance des cellules. Lorsque la topoisomérase I est inactivée, l’accumulation d’hypersurenroulement négatif conduit à la formation de nombreux R-loops, ce qui déclenche la dégradation de l’ARN synthétisé. Issus de la dégradation de l’ARNm de pleine longueur, des ARNm incomplets et traductibles s’accumulent et causent l’inhibition de la synthèse protéique et de la croissance. Le processus par lequel l’ARN est dégradé n’est pas encore complètement élucidé, mais nos résultats soutiennent fortement que la RNase HI présente en concentration physiologique est responsable de ce phénotype. Chose importante, la RNase E qui est l’endoribonuclease majeure de la cellule n’est pas impliquée dans ce processus, et la dégradation de l’ARN survient avant son action. Nous montrons aussi qu’une corrélation parfaite existe entre la concentration de RNase HI, l’accumulation d’hypersurenroulement négatif et l’inhibition de la croissance bactérienne. Lorsque la RNase HI est en excès, l’accumulation de surenroulement négatif est inhibée et la croissance n’est pas affectée. L’inverse se produit Lorsque la RNase HI est en concentration physiologique. En limitant l’accumulation d’hypersurenroulement négatif, la surproduction de la RNase HI prévient alors la dégradation de l’ARN et permet la croissance. Quand la RNase HI est inactivée en présence de topoisomérase I, les R-loops réduisent le niveau d’expression de nombreux gènes, incluant des gènes de résistance aux stress comme rpoH et grpE. Cette inhibition de l’expression génique n’est pas accompagnée de la dégradation de l’ARN contrairement à ce qui se produit en absence de topoisomérase I. Dans le mutant déficient en RNase HI, la diminution de l’expression génique réduit la concentration cellulaire de différentes protéines, ce qui altère négativement le taux de croissance et affecte dramatiquement la survie des cellules exposées aux stress de hautes températures et oxydatifs. Une inactivation de RecA, le facteur essentiel qui déclenche la réponse SOS et le cSDR, ne restaure pas l’expression génique. Ceci démontre que la réponse SOS et le cSDR ne sont pas impliqués dans l’inhibition de l’expression génique en absence de RNase HI. La croissance bactérienne qui est inhibée en absence de topoisomérase I, reprend lorsque l’excès de surenroulement négatif est éliminé. En absence de RNase HI et de topoisomérase I, le surenroulement négatif est très relaxé. Il semble que la réponse cellulaire suite à la formation de R-loops, soit la relaxation du surenroulement négatif. Selon le même principe, des mutations compensatoires dans la gyrase apparaissent en absence de topoisomérase I et réduisent l’accumulation de surenroulement négatif. Ceci supporte fortement l’idée que le surenroulement négatif joue un rôle primordial dans la formation de R-loop. La régulation du surenroulement négatif de l’ADN est donc une tâche essentielle pour la cellule. Elle favorise notamment l’expression génique optimale durant la croissance et l’exposition aux stress, en limitant la formation de R-loops. La topoisomérase I et la RNase HI jouent un rôle important et complémentaire dans ce processus. / Important fluctuations of DNA supercoiling occur during transcription in the frame of the “twin supercoiled domain” model. In this model, transcription elongation generates negative and positive supercoiling respectively, upstream and downstream of the moving RNA polymerase. The major role of bacterial topoisomerase I is to prevent the accumulation of transcription-induced negative supercoiling. In its absence, the accumulation of negative supercoiling triggers R-loop formation which inhibits bacterial growth. R-loops are DNA/RNA hybrids formed during transcription when the nascent RNA hybridizes with the template strand thus, leaving the non-template strand single stranded. In cells lacking DNA topoisomerase I, a constant and selective pressure for the acquisition of compensatory mutations in gyrase genes reduces the negative supercoiling level of the chromosome and allows growth. One of these mutations is a thermosensitive gyrase expressed at 37 °C. The overexpression of RNase HI, an enzyme that degrades the RNA moiety of an R-loop, is also able to correct growth inhibition in absence of topoisomerase I. In the presence of topoisomerase I, R-loops can also form when RNase HI is lacking. In these mutants, R-loop formation induces SOS and constitutive stable DNA replication (cSDR). In our study, we show how R-loops formed in cells lacking topoisomerase I or RNase HI can affect bacterial growth. When topoisomerase I is inactivated, the accumulation of hypernegative supercoiling inhibits growth by causing extensive R-loop formation which, in turn, can lead to RNA degradation. As a result of RNA degradation, the accumulation of truncated and functional mRNA instead of full length ones, is responsible for protein synthesis inhibition that alters bacterial growth. The mechanism by which RNA is degraded is not completely clear but our results strongly suggest that RNase HI is involved in this process. More importantly, the major endoribonuclease, RNase E, is not involved in RNA degradation because RNA is degraded before its action. We show also that there is a perfect correlation between RNase HI concentration, the accumulation of hypernegative supercoiling and bacterial growth inhibition. When RNase HI is in excess, no accumulation of hypernegative supercoiling and growth inhibition are observed. The opposite is true when RNase HI is at its wild type level. By preventing the accumulation of hypernegative supercoiling, the overproduction of RNase HI inhibits extensive R-loop formation and RNA degradation, thus, allowing growth. In absence of RNase HI (rnhA) and in presence of topoisomerase I, R-loops are also responsible for an inhibition in gene expression, including stress genes such as rpoH and grpE. The inhibition of gene expression is not related to RNA degradation as seen in absence of topoisomerase I but it is rather related to a reduction in gene expression. In absence of RNase HI, the diminution of genes expression is responsible for a reduction in the cellular level of proteins, which negatively affects bacterial growth and bacterial survival to heat shock and oxydative stress. Additional mutations in RecA, the protein that activates SOS and cSDR after R-loop formation in rnhA, do not correct this phenotype in rnhA. Thus, SOS and cSDR are not directly involved in the inhibition of gene expression in the absence of RNase HI. In absence of topoisomerase I, growth inhibition resumes when hypernegative supercoiling is reduced. When compared to wild type strains, DNA is very relaxed in absence of RNase HI and topoisomerase I. It seems that R-loop formation induces the relaxation of negatively supercoiled DNA. All this strongly supports the idea that negative supercoiling plays an important role in R-loop formation. Finally, our work shows how essential negative supercoiling regulation is for cell physiology. By preventing R-loop formation, regulation of negative supercoiling allows optimal gene expression, which is crucial for cellular growth and for stress survival. Both topoisomerase I and RNase HI play an important and complementary role in this process.

Surenroulement de l'ADN

DNA supercoiling

Hypersurenroulement négatif

Hypernegative supercoiling

Topoisomérase I bactérienne

Bacterial topoisomerase I

Transcription

Transcription

R-loop

R-loop

RNase HI

RNase HI

Expression génique

Gene expression

Rôle des topoisomérases de type IA dans la ségrégation des chromosomes chez Escherichia coli

Tanguay, Cynthia

12 1900

Les topoisomérases I (topA) et III (topB) sont les deux topoisomérases (topos) de type IA d’Escherichia coli. La fonction principale de la topo I est la relaxation de l’excès de surenroulement négatif, tandis que peu d’information est disponible sur le rôle de la topo III. Les cellules pour lesquelles les deux topoisomérases de type IA sont manquantes souffrent d’une croissance difficile ainsi que de défauts de ségrégation sévères. Nous démontrons que ces problèmes sont majoritairement attribuables à des mutations dans la gyrase qui empêchent l’accumulation d’excès de surenroulement négatif chez les mutants sans topA. L’augmentation de l’activité de la gyrase réalisée par le remplacement de l’allèle gyrB(Ts) par le gène de type sauvage ou par l’exposition des souches gyrB(Ts) à une température permissive, permet la correction significative de la croissance et de la ségrégation des cellules topos de type IA. Nous démontrons également que les mutants topB sont hypersensibles à l’inhibition de la gyrase par la novobiocine. La réplication non-régulée en l’absence de topA et de rnhA (RNase HI) augmente la nécessité de l’activité de la topoisomérase III. De plus, en l’absence de topA et de rnhA, la surproduction de la topoisomérase III permet de réduire la dégradation importante d’ADN qui est observée en l’absence de recA (RecA). Nous proposons un rôle pour la topoisomérase III dans la ségrégation des chromosomes lorsque l’activité de la gyrase n’est pas optimale, par la réduction des collisions fourches de réplication s’observant particulièrement en l’absence de la topo I et de la RNase HI. / E. coli possesses two type IA topoisomerases (topos), namely topo I (topA) and topo III (topB). The major function of topo I is the relaxation of excess negative supercoiling. Much less is known about the function of topo III. Cells lacking both type IA topos suffer from severe chromosome segregation and growth defects. We show that these defects are mostly related to the presence of gyrase mutations that prevent excess negative supercoiling in topA null mutants. Indeed, increasing gyrase activity by spontaneous mutations, by substituting a gyrB(Ts) allele for a wild-type one or by exposing cells carrying the gyrB(Ts) allele to permissive temperatures, significantly corrected the growth and segregation defects of cells lacking type IA topo activity. We also found that topB mutants are hypersensitive to novobiocin due to gyrase inhibition. Our data also suggest that unregulated replication occurring in the absence of topA and rnhA (RNase HI) exacerbates the need for topo III activity. Moreover, when topA and rnhA were absent, we found that topo III overproduction reduced the extensive DNA degradation that took place in the absence of recA (RecA). All together, our results lead us to propose a role for topo III in chromosome segregation when gyrase activity is suboptimal, thus reducing replication forks collapse, especially when replication is unregulated due to the absence of topo I and RNase HI.

Topoisomérase de type IA

Gyrase

RNase HI

Ségrégation des chromosomes

Réplication

Décaténation

Division cellulaire

Précaténane

Surenroulement de l’ADN

Escherichia coli

Type IA topoisomerase

Chromosome segregation

Replication

Decatenation

Cell division

Precatenane

DNA supercoiling

Les R-loops et leurs conséquences sur l'expression génique chez Escherichia coli

Baaklini, Imad

02 1900

No description available.

Surenroulement de l'ADN

DNA supercoiling

Hypersurenroulement négatif

Hypernegative supercoiling

Topoisomérase I bactérienne

Bacterial topoisomerase I

Transcription

Transcription

R-loop

R-loop

RNase HI

RNase HI

Expression génique

Gene expression

Topoisomerases from Mycobacteria : Insights into the Mechanism, Regulation and Global Modulatory Functions

Ahmed, Wareed

January 2014

The eubacterial genome is maintained in a negatively supercoiled state which facilitates its compaction and storage in a small cellular space. Genome supercoiling can potentially influence various DNA transaction processes such as DNA replication, transcription, recombination, chromosome segregation and gene expression. Alterations in the genome supercoiling have global impact on the gene expression and cell growth. Inside the cell, the genome supercoiling is maintained judiciously by DNA topoisomerases to optimize DNA transaction processes. These enzymes solve the problems associated with the DNA topology by cutting and rejoining the DNA. Due to their essential cellular functions and global regulatory roles, DNA topoisomerases are fascinating candidates for the study of the effect of topology perturbation on a global scale. Genus Mycobacterium includes a large number of species including the well-studied Mycobacterium smegmatis (Msm) as well as various pathogens–Mycobacterium leprae, Mycobacterium abscessus and Mycobacterium tuberculosis (Mtb), the last one being the causative agent of the deadly disease Tuberculosis (TB), which claims millions of lives worldwide annually. The organism combats various stresses and alterations in its environment during the pathogenesis and virulence. During such adaptation, various metabolic pathways and transcriptional networks are reconfigured. Considering their global regulatory role, DNA topoisomerases and genome supercoiling may have an influence on the mycobacterial survival and adaptation. Biochemical studies from our laboratory have revealed several distinctive characteristics of mycobacterial DNA gyrase and topoisomerase I. DNA gyrase has been shown to be a strong decatenase apart from its characteristic supercoiling activity. Similarly, the mycobacterial topoisomerase I exhibits several distinct features such as the ability to bind both single- as well as double-stranded DNA, site specific DNA binding and absence of Zn2+ fingers required for DNA relaxation activity in other Type I enzymes. Although, efforts have been made to understand the biochemistry and mechanism of mycobacterial topoisomerases, in vivo significance and regulatory roles remain to be explored. The present study is aimed at understanding the mechanism, in vivo functions, regulation and genome wide distribution of mycobacterial topoisomerases. Chapter 1 of the thesis provides introduction on DNA topology, genome supercoiling and DNA topoisomerases. The importance of genome supercoiling and its regulatory roles has been discussed. Further, the regulation of topoisomerase activity and the role in the virulence gene regulation is described. Finally, a brief overview of Mtb genome, disease epidemiology, and pathogenesis is presented along with the description of the work on mycobacterial topoisomerases. In Chapter 2, the studies are directed to understand the DNA relaxation mechanism of mycobacterial Type IA topoisomerase which lack Zn2+ fingers. The N-terminal domain (NTD) of the Type IA topoisomerases harbor DNA cleavage and religation activities, but the carboxyl terminal domain (CTD) is highly diverse. Most of these enzymes contain a varied number of Zn2+ finger motifs in the CTD. The Zn2+ finger motifs were found to be essential in Escherichia coli TopoI but dispensable in the Thermotoga maritima enzyme. Although, the CTD of mycobacterial TopoI lacks Zn2+ fingers, it is indispensable for the DNA relaxation activity of the enzyme. The divergent CTD harbors three stretches of basic amino acids needed for the strand passage step of the reaction as demonstrated by a new assay. It is elucidated that the basic amino acids constitute an independent DNA-binding site apart from the NTD and assist the simultaneous binding of two molecules of DNA to the enzyme, as required during the strand passage step of the catalysis. It is hypothesized that the loss of Zn2+ fingers from the mycobacterial TopoI could be associated with Zn2+ export and homeostasis. In Chapter 3, the studies have been carried out to understand the regulation of mycobacterial TopoI. Identification of Transcription Start Site (TSS) suggested the presence of multiple promoters which were found to be sensitive to genome supercoiling. The promoter activity was found to be specific to mycobacteria as the promoter(s) did not show activity in E. coli. Analysis of the putative promoter elements suggested the non-optimal spacing of the putative -35 and -10 promoter elements indicating the involvement of supercoiling for the optimal alignment during the transcription. Moreover, upon genome relaxation, the occupancy of RNA polymerase was decreased on the promoter region of topoI gene implicating the role of DNA topology in the Supercoiling Sensitive Transcription (SST) of TopoI gene from mycobacteria. The involvement of intrinsic promoter elements in such regulation has been proposed. In Chapter 4, the importance of TopoI for the Mtb growth and survival has been validated. Mtb contains only one Type IA topoisomerase (Rv3646c), a sole DNA relaxase in the cell, and hence a candidate drug target. To validate the essentiality of Mtb topoisomerase I for bacterial growth and survival, conditionally regulated strain of topoI in Mtb was generated. The conditional knockdown mutant exhibited delayed growth on agar plate and in liquid culture the growth was drastically impaired when TopoI expression was suppressed. Additionally, novobiocin and isoniazid showed enhanced inhibitory potential against the conditional mutant. Analysis of the nucleoid revealed its altered architecture upon TopoI depletion. These studies establish the essentiality of TopoI for the Mtb growth and open up new avenues for targeting the enzyme. In Chapter 5, the influence of perturbation of TopoI activity on the Msm growth and physiology has been studied. Notably, Msm contains an additional DNA relaxation enzyme– an atypical Type II topoisomerase TopoNM. The TopoI depleted strain exhibited slow growth and drastic change in phenotypic characters. Moreover, the genome architecture was disturbed upon depletion of TopoI. Further, the proteomic and transcript analysis indicated the altered expression of the genes involved in central metabolic pathways and core DNA transaction processes in the mutant. The study suggests the importance of TopoI in the maintenance of cellular phenotype and growth characteristics of fast growing mycobacteria having additional topoisomerases. In Chapter 6, the ChIP-Seq method is used to decipher the genome wide distribution of the DNA gyrase, topoisomerase I (TopoI) and RNA polymerase (RNAP). Analysis of the ChIP-Seq data revealed the genome wide distribution of topoisomerases along with RNAP. Importantly, the signals of topoisomerases and RNAP was found to be co-localized on the genome suggesting their functional association in the twin supercoiled domain model, originally proposed by J. C. Wang. Closer inspection of the occupancy profile of topoisomerases and RNAP on transcription units (TUs) revealed their co-existence validating the topoisomerases occupancy within the twin supercoiled domains. On the genomic scale, the distribution of topoisomerases was found to be more at the ori domains compared to the ter domain which appeared to be an attribute of higher torsional stress at ori. The reappearance of gyrase binding at the ter domain (and the lack of it in the ter domain of E. coli) suggests a role for Mtb gyrase in the decatenation of the daughter chromosomes at the end of replication. The eubacterial genome is maintained in a negatively supercoiled state which facilitates its compaction and storage in a small cellular space. Genome supercoiling can potentially influence various DNA transaction processes such as DNA replication, transcription, recombination, chromosome segregation and gene expression. Alterations in the genome supercoiling have global impact on the gene expression and cell growth. Inside the cell, the genome supercoiling is maintained judiciously by DNA topoisomerases to optimize DNA transaction processes. These enzymes solve the problems associated with the DNA topology by cutting and rejoining the DNA. Due to their essential cellular functions and global regulatory roles, DNA topoisomerases are fascinating candidates for the study of the effect of topology perturbation on a global scale. Genus Mycobacterium includes a large number of species including the well-studied Mycobacterium smegmatis (Msm) as well as various pathogens–Mycobacterium leprae, Mycobacterium abscessus and Mycobacterium tuberculosis (Mtb), the last one being the causative agent of the deadly disease Tuberculosis (TB), which claims millions of lives worldwide annually. The organism combats various stresses and alterations in its environment during the pathogenesis and virulence. During such adaptation, various metabolic pathways and transcriptional networks are reconfigured. Considering their global regulatory role, DNA topoisomerases and genome supercoiling may have an influence on the mycobacterial survival and adaptation. Biochemical studies from our laboratory have revealed several distinctive characteristics of mycobacterial DNA gyrase and topoisomerase I. DNA gyrase has been shown to be a strong decatenase apart from its characteristic supercoiling activity. Similarly, the mycobacterial topoisomerase I exhibits several distinct features such as the ability to bind both single- as well as double-stranded DNA, site specific DNA binding and absence of Zn2+ fingers required for DNA relaxation activity in other Type I enzymes. Although, efforts have been made to understand the biochemistry and mechanism of mycobacterial topoisomerases, in vivo significance and regulatory roles remain to be explored. The present study is aimed at understanding the mechanism, in vivo functions, regulation and genome wide distribution of mycobacterial topoisomerases. Chapter 1 of the thesis provides introduction on DNA topology, genome supercoiling and DNA topoisomerases. The importance of genome supercoiling and its regulatory roles has been discussed. Further, the regulation of topoisomerase activity and the role in the virulence gene regulation is described. Finally, a brief overview of Mtb genome, disease epidemiology, and pathogenesis is presented along with the description of the work on mycobacterial topoisomerases. In Chapter 2, the studies are directed to understand the DNA relaxation mechanism of mycobacterial Type IA topoisomerase which lack Zn2+ fingers. The N-terminal domain (NTD) of the Type IA topoisomerases harbor DNA cleavage and religation activities, but the carboxyl terminal domain (CTD) is highly diverse. Most of these enzymes contain a varied number of Zn2+ finger motifs in the CTD. The Zn2+ finger motifs were found to be essential in Escherichia coli TopoI but dispensable in the Thermotoga maritima enzyme. Although, the CTD of mycobacterial TopoI lacks Zn2+ fingers, it is indispensable for the DNA relaxation activity of the enzyme. The divergent CTD harbors three stretches of basic amino acids needed for the strand passage step of the reaction as demonstrated by a new assay. It is elucidated that the basic amino acids constitute an independent DNA-binding site apart from the NTD and assist the simultaneous binding of two molecules of DNA to the enzyme, as required during the strand passage step of the catalysis. It is hypothesized that the loss of Zn2+ fingers from the mycobacterial TopoI could be associated with Zn2+ export and homeostasis. In Chapter 3, the studies have been carried out to understand the regulation of mycobacterial TopoI. Identification of Transcription Start Site (TSS) suggested the presence of multiple promoters which were found to be sensitive to genome supercoiling. The promoter activity was found to be specific to mycobacteria as the promoter(s) did not show activity in E. coli. Analysis of the putative promoter elements suggested the non-optimal spacing of the putative -35 and -10 promoter elements indicating the involvement of supercoiling for the optimal alignment during the transcription. Moreover, upon genome relaxation, the occupancy of RNA polymerase was decreased on the promoter region of topoI gene implicating the role of DNA topology in the Supercoiling Sensitive Transcription (SST) of TopoI gene from mycobacteria. The involvement of intrinsic promoter elements in such regulation has been proposed. In Chapter 4, the importance of TopoI for the Mtb growth and survival has been validated. Mtb contains only one Type IA topoisomerase (Rv3646c), a sole DNA relaxase in the cell, and hence a candidate drug target. To validate the essentiality of Mtb topoisomerase I for bacterial growth and survival, conditionally regulated strain of topoI in Mtb was generated. The conditional knockdown mutant exhibited delayed growth on agar plate and in liquid culture the growth was drastically impaired when TopoI expression was suppressed. Additionally, novobiocin and isoniazid showed enhanced inhibitory potential against the conditional mutant. Analysis of the nucleoid revealed its altered architecture upon TopoI depletion. These studies establish the essentiality of TopoI for the Mtb growth and open up new avenues for targeting the enzyme. In Chapter 5, the influence of perturbation of TopoI activity on the Msm growth and physiology has been studied. Notably, Msm contains an additional DNA relaxation enzyme– an atypical Type II topoisomerase TopoNM. The TopoI depleted strain exhibited slow growth and drastic change in phenotypic characters. Moreover, the genome architecture was disturbed upon depletion of TopoI. Further, the proteomic and transcript analysis indicated the altered expression of the genes involved in central metabolic pathways and core DNA transaction processes in the mutant. The study suggests the importance of TopoI in the maintenance of cellular phenotype and growth characteristics of fast growing mycobacteria having additional topoisomerases. In Chapter 6, the ChIP-Seq method is used to decipher the genome wide distribution of the DNA gyrase, topoisomerase I (TopoI) and RNA polymerase (RNAP). Analysis of the ChIP-Seq data revealed the genome wide distribution of topoisomerases along with RNAP. Importantly, the signals of topoisomerases and RNAP was found to be co-localized on the genome suggesting their functional association in the twin supercoiled domain model, originally proposed by J. C. Wang. Closer inspection of the occupancy profile of topoisomerases and RNAP on transcription units (TUs) revealed their co-existence validating the topoisomerases occupancy within the twin supercoiled domains. On the genomic scale, the distribution of topoisomerases was found to be more at the ori domains compared to the ter domain which appeared to be an attribute of higher torsional stress at ori. The reappearance of gyrase binding at the ter domain (and the lack of it in the ter domain of E. coli) suggests a role for Mtb gyrase in the decatenation of the daughter chromosomes at the end of replication.

Mycobacteria

Mycobacterial Topoisomerases

Mycobacterial Gyrase

DNA Supercoiling

DNA Topology

DNA Topoisomerase I

Mycobacterial Gene Regulation

Virulent Gene Expression

Mycobacterium Tuberculosis Topoisomerase

Mycobacterium Smegmatis Topoisomerase I

Bacterial Growth

RNA Polymerases

Bacterial DNA Topoisomerases

Topoisomerase I

Mycobacterial Topoisomerase I

Microbiology

Rôle de la topoisomérase I dans la stabilité du génome chez Escherichia coli

Ngningone, Christy M.

12 1900

Les topoisomérases (topos) de type IA jouent un rôle primordial dans le maintien et l’organisation du génome. Cependant, les mécanismes par lesquels elles contrôlent cette stabilité génomique sont encore à approfondir. Chez E. coli, les deux principales topoisomérases de type IA sont la topo I (codée par le gène topA) et la topo III (codée par le gène topB). Il a déjà été montré que les cellules dépourvues des topos I et III formaient de très longs filaments dans lesquels les chromosomes ne sont pas bien séparés. Comme ces défauts de ségrégation des chromosomes sont corrigés par l’inactivation de la protéine RecA qui est responsable de la recombinaison homologue, il a été émis comme hypothèse que les topoisomérases de type IA avaient un rôle dans la résolution des intermédiaires de recombinaison afin de permettre la séparation des chromosomes. D’autre part, des études réalisées dans notre laboratoire démontrent que le rôle majeur de la topoisomérase I est d’empêcher la formation des R-loops durant la transcription, surtout au niveau des opérons rrn. Ces R-loops on été récemment identifiés comme des obstacles majeurs à l’avancement des fourches de réplication, ce qui peut provoquer une instabilité génomique. Nous avons des évidences génétiques montrant qu’il en serait de même chez nos mutants topA. Tout récemment, des études ont montré le rôle majeur de certaines hélicases dans le soutien aux fourches de réplication bloquées, mais aussi une aide afin de supprimer les R-loops. Chez E. coli, ces hélicases ont été identifiées et sont DinG, Rep et UvrD. Ces hélicases jouent un rôle dans la suppression de certains obstacles à la réplication. Le but de ce projet était de vérifier l’implication de ces hélicases chez le mutant topA en utilisant une approche génétique. Étonnamment, nos résultats montrent que la délétion de certains de ces gènes d’hélicases a pour effet de corriger plutôt que d’exacerber des phénotypes du mutants topA qui sont liés à la croissance et à la morphologie des nucléoides et des cellules. Ces résultats sont interprétés à la lumière de nouvelles fonctions attribuées aux topoisomérases de types IA dans la stabilité du génome. / Type 1A topoisomerases (topos) play a vital role in the maintenance and organization of the genome. However, the mechanisms by which they control genome stability still remain to be explored. In E. coli, the two type IA topoisomerases are topo I (encoded by topA) and topo III (encoded by topB). It has been shown that cells lacking topo I and III form very long filaments in which the chromosomes are not well separated. As the chromosome segregation defects are corrected by inactivation of the RecA protein, that is responsible for homologous recombination, it has been hypothesized that type IA topoisomerases have a role in the resolution of recombination intermediates to allow chromosome segregation. On the other hand, studies in our laboratory have shown that the major role of topoisomerase I is to prevent the formation of R-loops during transcription, especially at the rrn operons. These R-loops have been recently identified as major roadblocks to the progression of replication forks, which can cause genomic instability. We have genetic evidence suggesting similar effects may occur in our topA mutants. More recently, studies have shown the important role of certain helicases in eliminating roadblocks for replication forks that could sometimes be R-loops. In E. coli, these helicases have been identified and they are DinG, Rep and UvrD. The purpose of this project was to study the roles of these helicases in our topA mutant, using a genetic approach. Surprisingly, our results show that deletions of some of these genes have the effect of correcting rather than exacerbating topA mutant phenotypes that are related to the growth and cell and nucleoid morphology. These results are interpreted in the light of new functions assigned to the type IA topoisomerases in genome stability.

Topoisomérases de type IA

R-loops

Réplication

Transcription

Surenroulement de l'ADN

Recombinaison homologue

Collisions réplication-transcription

Hélicases DinG, Rep et UvrD

Topoisomerases type IA

R-loops

Replication

Transcription

DNA supercoiling

Homologous recombination

Transcription-replication collision

DinG, Rep and UvrD helicases

Multimode Analysis of Nanoscale Biomolecular Interactions

Tiwari, Purushottam Babu

25 February 2015

Biomolecular interactions, including protein-protein, protein-DNA, and protein-ligand interactions, are of special importance in all biological systems. These interactions may occer during the loading of biomolecules to interfaces, the translocation of biomolecules through transmembrane protein pores, and the movement of biomolecules in a crowded intracellular environment. The molecular interaction of a protein with its binding partners is crucial in fundamental biological processes such as electron transfer, intracellular signal transmission and regulation, neuroprotective mechanisms, and regulation of DNA topology. In this dissertation, a customized surface plasmon resonance (SPR) has been optimized and new theoretical and label free experimental methods with related analytical calculations have been developed for the analysis of biomolecular interactions. Human neuroglobin (hNgb) and cytochrome c from equine heart (Cyt c) proteins have been used to optimize the customized SPR instrument. The obtained Kd value (~13 µM), from SPR results, for Cyt c-hNgb molecular interactions is in general agreement with a previously published result. The SPR results also confirmed no significant impact of the internal disulfide bridge between Cys 46 and Cys 55 on hNgb binding to Cyt c. Using SPR, E. coli topoisomerase I enzyme turnover during plasmid DNA relaxation was found to be enhanced in the presence of Mg2+. In addition, a new theoretical approach of analyzing biphasic SPR data has been introduced based on analytical solutions of the biphasic rate equations. In order to develop a new label free method to quantitatively study protein-protein interactions, quartz nanopipettes were chemically modified. The derived Kd (~20 µM) value for the Cyt c-hNgb complex formations matched very well with SPR measurements (Kd ~16 µM). The finite element numerical simulation results were similar to the nanopipette experimental results. These results demonstrate that nanopipettes can potentially be used as a new class of a label-free analytical method to quantitatively characterize protein-protein interactions in attoliter sensing volumes, based on a charge sensing mechanism. Moreover, the molecule-based selective nature of hydrophobic and nanometer sized carbon nanotube (CNT) pores was observed. This result might be helpful to understand the selective nature of cellular transport through transmembrane protein pores.

Biomolecular interactions

Heme proteins

DNA topoisomerases

DNA supercoiling

Surface plasmon resonance (SPR)

SPR data fitting

Quartz nanopipettes

label-free methods

Finite element simulations

Analytical Chemistry

Biochemistry

Biological and Chemical Physics

Biophysics

Biotechnology

Condensed Matter Physics

Molecular Biology

Physics