Newer Insights On Structure, Function And Regulation Of Dps Protein From Mycobacterium smegmatis

Chowdhury, Rakhi Pait

06 1900

The first chapter will provide an introduction to the physiology, pathogenesis and biology of mycobacteria. Host-pathogen interactions, different modes of resistance of the bacteria, adaptations for survival under nutrient and oxygen depleted conditions has been discussed. This is followed by a general discussion on gene expression and regulation in the microbe. The physiology of bacteria under stresses from the view of the transcriptional regulation of specific genes has also been discussed. The scope and objective of the present study in M. smegmatis covered in the thesis has been considered at the end. The next chapter discusses the characterization of msdps promoter in vivo with the help of reporter gene assay technologies. With the advent of promoterless E. coli-mycobacterium shuttle vectors, activity assays can be easily performed to characterize unknown upstream putative promoter sequences of genes. Both the 1 kb upstream as well as a 200bp upstream region of msdps gene has been characterized by. Primer extension analysis and subsequent site directed mutagenesis studies reveal +1 transcription start site and the promoter consensus sequence for the msdps gene respectively. Next chapter comprises of the method of constructing heterologous in vitro transcription machinery in mycobacteria. It is followed by characterization of transcription initiation at two dps promoters of M. smegmatis. A novel pull-down assay has been designed which enabled us to identify the sigma factors in the reconstituted RNA polymerases to be associated with the respective dps promoters and to compare the regulation of the two genes at transcription level. Further characterization through single round in vitro transcription at mycobacterial promoters has been attempted. The following two chapters provide some newer insights into the structure-function relationship of the first Dps molecule, MsDps (MsDps1) with respect to its DNA binding activity. The DNA binding activity is associated with the higher oligomeric form only. With the help of time resolved anisotropy and Förster Resonance Energy Transfer (FRET) experiments, we have monitored the nature of Dps dodecamer-DNA complex and mapped the distance between the N and C169 position in the absence and the presence of DNA. A new computational programme, Maximum Entropy Method (MEM) has been applied successfully to analyze data obtained from phase-modulation (Phi-M) lifetime experiments in order to get distribution of lifetime. In the last chapter a new method is adopted to predict amino acids important for stabilizing the interface in a trimeric structure. Subsequently, single and double amino acid mutants of the native MsDps protein has been constructed through site directed mutagenesis and are scored for the ability of the mutants to oligomerize under conditions similar to that of the native protein. This helped us to propose a hypothetical model of the overall mechanism of the protein oligomerization process in solution.

Dps Proteins

Mycobacterium smegmatis

Bacterial DNA

Mycobacteria - Gene Expression

Mycobacteria - Gene Regulation

DPs Proteins - Oligomerization

Mycobacteria - Transcriptome Analysis

Mycobacterium-Host Interactions

DNA Binding

msdps Promoter

Mycobacterial MsDps2 Protein

Interface Cluster

M. smegmatis

Molecular Biology

Avaliação do potencial das formigas como vetores mecâncios de micobactérias em hospital especializado na assistência de pacientes de tuberculose no Estado de São Paulo / Evaluation of ants as potential mechanical vectors of mycobacteria in a hospital specializing in assistance to TB patients, the state of São Paulo

Couceiro, Ana Paula Macedo Ruggiero

02 April 2012

Introdução - A urbanização desencadeia inúmeros transtornos, como a disseminação de artrópodes e, conseqüentemente, de doenças veiculadas pelos mesmos. As formigas são muito adaptáveis e se beneficiam com a convivência humana. Nos hospitais, elas podem ser vetores mecânicos de inúmeras bactérias, e a diversidade de espécies encontradas nestes ambientes, causam preocupação pelo risco potencial à saúde pública. O aumento das infecções hospitalares envolvendo micobactérias ambientais, com surtos no Brasil entre 1998 a 2009 em 23 estados alarmou os órgãos e profissionais de saúde pública. Objetivos - Avaliar o potencial de formigas como vetores de micobactérias em um hospital especializado no atendimento de doentes com tuberculose. Métodos - Foram realizadas seis coletas de formigas em diferentes áreas do hospital no período de 2009 a 2010, que foram semeadas em meios de cultura de Löwenstein-Jensen e de Stonebrink para isolamento de micobactérias. As culturas sugestivas foram submetidas à coloração de Ziehl-Neelsen para bacilos álcool-ácido resistentes e identificação por métodos moleculares (PRA para o gene hsp65 com o par de primers TB11 e TB12 gênero-específico e sequenciamento genético do DNA). Resultados - Do total de 247 amostras de formigas coletadas e semeadas, 70 por cento das formigas pertenciam à espécie Tapinoma melanocephalum, 25 por cento a espécie Dorymyrmex sp., 3 por cento a espécie Camponotus sp. e 2 por cento a espécie Pheidole sp., dados similares foram observados anteriormente em pesquisas realizadas em hospitais. Quinze amostras apresentaram bacilos álcool-ácido resistentes de crescimento rápido. Nos métodos moleculares, doze pertenciam ao Gênero Mycobacterium. No PRA-hsp 65, e no sequenciamento genético do DNA, quatro amostras foram identificadas quanto à espécie (duas Mycobacterium chelonae, uma Mycobacterium parafortuitum e uma Mycobacterium murale), quatro micobactérias com resultados idênticos no PRA e não identificadas no sequenciamento foram sugestivas de uma nova espécie, e duas amostras não foram identificadas. Mycobacterium chelonae isolada nesta pesquisa foi previamente descrita como agente causador de abscessos em humanos. Conclusão - Estes dados confirmam a presença de micobactérias veiculadas por formigas no ambiente hospitalar, representando um potencial vetor mecânico destas para pacientes e profissionais de saúde, principalmente em infecções nosocomiais / Introduction- Urbanization triggers numerous disorders, such as the dissemination of arthropods and, consequently, dissemination of diseases transmitted by them. Some ant species are very adaptable to the human environment. At hospitals, once they are mechanical vectors of bacteria, and the diversity of species found in these environments, they can represent a potential risk to public health. The increase of nosocomial infections involving environmental mycobacteria, with outbreaks in Brazil from 1998 to 2009 in 23 states called the interest of health professionals and health agencies. Purpose - Evaluate the potential of ants as vectors of mycobacteria in a hospital specialized in the care of patients with tuberculosis. Methods Samples of ants were collected from different areas of the hospital from 2009 to 2010, and workers were inoculated in Löwenstein-Jensen and Stonebrink media for mycobacteria isolation. The suggestive cultures were subjected to Ziehl-Neelsen stain for acid-fast bacilli and identification were performed by molecular methods (PRA for the hsp65 gene with the pair of primers TB11 - TB12 and genetic sequencing). Results - The total of 247 samples of ants collected and sown, 70 per cent belonged to species of ants Tapinoma melanochepalum, 25 per cent Dorymyrmex sp.,3 per cent Camponotus sp. and 2 per cent Pheidole sp., data similar with previous studies conducted in hospitals. Fifteen fast-growing mycobacteria were isolated. In molecular methods, twelve belonged to the genus Mycobacterium. In PRA-hsp65, and the genome sequencing of DNA, four samples were identified at species level (two Mycobacterium chelonae, one Mycobacterium parafortuitum and one Mycobacterium murale), four mycobacteria with similar results in the PRA and not identified in the sequencing, suggestive of a new species and two unidentified samples. M. chelonae was previously reported as causative agent of abscess in humans. Conclusions - These results confirm the presence of mycobacteria carried by ants in the hospital, representing a potential mechanical vector for these patients and healthcare professionals, particularly in nosocomial infections

Ambiente Hospitalar

Ants

Fast-Growing Mycobacteria

Formigas

Hospital

Hospital

Infecção Nosocomial

Mechanical Vector

Micobactérias

Micobactérias de Crescimento Rápido

Mycobacteria

Nosocomial Infection

Vetor Mecânico

Mycobacterium Smegmatis RecA And SSB : Structure-Function Relationships, Interaction With Cofactors And Accessory Proteins

Manjunath, G P

10 1900

Homologous genetic recombination, because of its fundamental roles in the maintenance of genome stability and evolution, is an essential cellular function common to all organisms. This process also plays important roles in the repair of damaged DNA molecules, generation of genetic diversity and proper segregation of chromosomes. The genetic exchange is a highly orchestrated process that entails a plethora of control mechanisms and a large number of proteins, of which RecA and SSB are two proteins that have been chosen for further investigation(s) in the present study. In addition, we have also investigated the interaction between SSB and UvrD1, which plays an important role in DNA repair pathways, especially nucleotide excision repair (NER) and mismatch repair as well as DNA replication and recombination. Chapter 1 reviews the literature regarding various aspects of homologous recombination, with an emphasis on the biochemical and the biophysical aspects of RecA and SSB proteins. In addition, it provides an overview of the study of DNA repair and recombination in mycobacteria. RecA protein is ubiquitous and well conserved among bacterial species. Many archaeal species possess two RecA homologues (RadA and RadB) and eukarya possess multiple homologues of RecA including, Rad51, Rad51B, Rad51C, Rad51D, DMC1, XRCC2, or XRCC3. RecA or its homologues function as polymers, consisting of hundreds of monomers that cooperatively polymerize on single-stranded DNA to form a nucleoprotein filament. E. coli RecA protein participates in Trans Lesion Synthesis (TLS) of DNA and forms the minimal mutasome in association with DNA polymerase V (UmuD’2C). The fundamental mechanism underlying HR, i.e. DNA strand exchange, is one of the most fascinating examples of molecular recognition and exchange between biological macromolecules. Since the isolation of E. coli recA gene and the subsequent purification of its gene product and also from other organisms, RecA protein has been studied extensively for more than three decades. E. coli RecA protein has pivotal roles in DNA recombination and repair, and binding to DNA in the presence of ATP, is a fundamental property of RecA protein resulting in the formation of a nucleoprotein filament. This is the slow step of the HR process, and is considerably faster on ssDNA than on duplex DNA. Binding of RecA to dsDNA is slower at physiological pH, is accelerated at acidic pH, and the lag in binding at the higher pH values is due to slow nucleation. The ATP and the DNA binding functions of RecA display allosteric interaction such that ATP- binding leads to an increase in affinity to ssDNA-binding and vice-versa. X-ray structures of E. coli RecA complexed with nucleotide cofactors have implicated a highly conserved Gln196 in Mycobacterium smegmatis RecA in the coupling of ATP and the DNA binding domains. The carboxyamide group of Gln196 makes an H-bond with the γ-phosphate group of ATP and the side chain of this residue is observed to move by approximately 2Å towards the ATP, relative to the other residues involved in ATP binding. In addition, a highly conserved Arg198 has also been postulated to interact with the γ-phosphate group of bound ATP and position it for a nucleophilic attack by a conserved residue-Glu96 leading to ATP hydrolyses. To elucidate the role of Gln196 and Arg198 in the allosteric modulation of RecA functions, we generated MsRecA variant proteins, where in Gln196 was substituted with alanine, asparagine or glutamate; Arg198 was mutated to a lysine. The biochemical characterization of MsRecA and its variant proteins with the objective of defining the allosteric interaction between the ATP- and the DNA-binding sites has been described with in Chapter 2. We observed that while the mutant MsRecA proteins were proficient in ATP-binding they were deficient in ATP hydrolyses. We assayed for the ability of these proteins to bind ssDNA using either nitrocellulose filter binding or Surface Plasmon Resonance (SPR). While we did not detect any ssDNA-binding by the mutant MsRecA proteins in the filter binding assay, we observed only ten-fold reduction in the affinity for ssDNA as compared to wild type MsRecA protein in MsRecAQ196A, Q196N and R198K in the SPR assay. MsRecA Q196E did not show any binding to ssDNA, in both nitrocellulose filter-binding as well as SPR assays. We assayed for the ability of the mutant RecA proteins for their ability to promote DNA-pairing as well as DNA strand exchange. While we observed limited pairing promoted by the mutant proteins relative to the wild-type MsRecA, we observed a complete abrogation of strand exchange in the case of mutant proteins. In addition, we assayed for the co-protease function of MsRecA, by monitoring the cleavage of MtLexA. We observed that only the wild-type MsRecA protein was able to cleave MtLexA, while none of the mutant RecA proteins were able to do so. In order to understand the differences observed between the wild -type and the mutant MsRecA proteins, we analyzed the conformational state of MsRecA and its variant proteins by circular dichroism spectroscopy upon ATP-binding. We observed that while MsRecA and MsRecAQ196N displayed a reduction in the absorbance at 220 nm upon ATP binding, we did not observe any such structural transitions in the other mutant MsRecA proteins that we tested. Based on our observations and the crystal structure of E. coli RecA bound to ssDNA, in Chapter 2, we propose a dual role for the Gln196 and Arg198 in modulating RecA activities. In the presynaptic filament Gln196 and Arg198 sense the presence of the nucleotide in the nucleotide binding pocket and initiate a series of conformation changes that culminate in the transition to an active RecA nucleoprotein filament. In the active RecA nucleoprotein filament these residues are repositioned such that they now form a part of the protomer-protomer interface. As such they perform two vital functions; they stabilize the protomer-protomer interface by participating in the formation of hydrogen bonds that span the interface as well transmit the wave of ATP hydrolysis across the interface leading to a coordinated hydrolyses of ATP essential for the heteroduplex extension phase of strand exchange reaction. The members of the super family of single stranded DNA binding proteins (SSB) play an important role in all aspects of DNA metabolism including DNA replication, repair, transcription and recombination. Prokaryotic SSBs bind ssDNA with high affinity and generally with positive cooperativity. Several lines of evidence suggest that prokaryotic SSBs are modularly organized into three distinct domains: the N-terminal DNA binding domain and acidic C-terminal domain are linked by a flexible spacer. Studies from our laboratory have revealed that M. smegmatis SSB plays a concerted role in recombination-like activities promoted by the cognate RecA. The C- terminal of SSB is known to be involved in its ability to interact with other proteins. We have previously reported that the C-terminal domain of M. smegmatis SSB, which is not essential for interaction with DNA, is the site for the binding of cognate RecA. The data in Chapter 3 describes the characterization of the SSB C-terminus with the objective of delineating the elements responsible for mediating protein-protein interaction, as well as to define the mechanism by which SSB is able to modulate the activities of RecA. To map the RecA interaction domain of SSB we created deletion mutants in MsSSB lacking 5, 10, 15 or 20 residues from the C-terminal. The truncated SSB proteins were expressed with a His- tag at the N- terminus and purified to homogeneity using a Ni-NTA affinity matrix. We observed unlike MsSSB, MsSSB∆C5 and MsSSB∆C10, MsSSB∆C15 and MsSSB∆C20 were unable to support three-strand exchange catalyzed by MsRecA. Based on the observation that interaction with SSB is essential for MsRecA to catalyze the strand Exchange reaction, we postulate that the RecA interacting domain of SSB is situated between the 15th and the 20th residue from the C-terminal. Further, the C-terminal of MsSSB modulates the transitions between DNA binding modes. Unlike the case with EcSSB where deletion of the last 8 residues from the C-terminal stabilizes the (SSB)35 mode of ssDNA binding, we observe that in case of MsSSB the deletion of C-terminal seems to destabilize the (SSB)35. In addition, the transition from the low density binding mode to a high density mode involves the formation of several intermediates when the C-terminal residues are deleted. With the objective of understanding the functions to the C-terminal of SSB independent of its DNA-binding domain in modulating RecA functions, we employed a peptide corresponding to the 35 residues from the C-terminal of the MsSSB. We observed that the C-terminal region alone is capable of interacting with RecA. In addition we also observed that the C-terminal domain of SSB stimulates RecA functions independent of its DNA binding domain. To address the question, whether the stimulatory effect of the C-terminal domain of SSB in the absence of its DNA-binding domain is restricted to RecA or is a generalized phenomenon associated with all SSB interacting proteins; we tested the effect of C-terminal domain of SSB on UvrD which is known to interact with SSB. UvrD participates in several pathways of DNA metabolism, which include the nucleotide excision repair (NER) and mismatch repair pathway, replication and recombination. Genetic evidence suggests that UvrD and SSB interact in vivo. We tested the effect of mycobacterial SSB on M. tuberculosis UvrD1 (MtUvrD1) functions in vitro. We observe that MtUvrd1 physically interacts with SSB. Further, presence of SSB has an inhibitory effect on the helicase activity of MtUvrD1 and that this effect is dependent on the C-terminal region as the deletion of residues from the C-terminal of SSB abrogates the inhibitory effect of SSB. However, unlike RecA, the C-terminal region of SSB alone had no effect on the helicase activity of UvrD1. We also observed that MsSSB has opposing effects on the ATPase activity of MtUvrD1. In the presence of low concentrations of SSB the ATPase activity is enhanced, while we observed an inhibition when the concentration of MsSSB is high. The precise mechanistic details of how SSB is able to act as an accessory protein to RecA, in context of homologous recombination and stimulates its biochemical activities have been a subject of debate. Whereas research from some groups has shown that the stimulatory effect SSB is mediated through its ability to melt DNA secondary structure, thereby allowing RecA to overcome the kinetic barrier imposed by the presence of secondary structure in ssDNA, others postulate that SSB plays a direct role in the stabilization of RecA nucleoprotein filament and prevents its dissociation. Chapter 3 discusses the experimental evidence in favor of the aforesaid models and based on the results of our experiments; we propose that the accessory functions of SSB may be mediated by a mechanism that involves elements of both models. While interaction with SSB can bring about a conformational change in RecA that is reflected in the enhanced levels of strand exchange and co-protease activity, the helix destabilizing function of SSB is essential during heteroduplex extension and to sequester the displaced strand such that it does not participate in any further pairing reactions. The novel finding that we present in Chapter 3 is that the interaction of SSB C-terminal alone has a stimulatory effect upon RecA activities. Furthermore, we observed that M. tuberculosis UvrD1 is a weak interaction partner of SSB. The physical and functional interactions between MsSSB with RecA on the one hand, and MsSSB and UvrD1 on the other highlight different types of cross-talk between the components of HR and DNA repair pathways. In contrast to the results of earlier studies, our results indicate that protein-protein interactions alone between SSB and RecA may modulate the RecA mediated processes of presynapsis, homologous pairing and strand exchange between homologous DNA molecules as well as modulate its co-protease activity. In addition, our studies indicate that a direct protein-protein interaction is responsible for the modulation of UvrD1 activities by SSB.

Bacteria - Proteins

Mycobacterium Smegmatis

Homologous Genetic Recombination

Recombinase A Protein

DNA Repair

Mycobacteria - DNA Repair

Mycobacteria - DNA Recombination

DNA Replication

Recombinant DNA

RecA Protein

SSB Protein

Biochemistry

Stringent Response In Mycobacteria: Molecular Dissection Of Rel

Jain, Vikas

07 1900

Adaptation to any undesirable change in the environment dictates the survivability of many microorganisms. Such changes generate a quick and suitable response, which guides the physiology of bacteria. Stringent response is one of the mechanisms that can be called a survival strategy under nutritional starvation in bacteria and was first observed in E. coli upon amino acid starvation, when bacteria demonstrated an immediate downshift in the rRNA and tRNA levels (Stent and Brenner 1961). Mutations that rendered bacteria insensitive to amino acid levels were mapped to an ‘RC gene locus’, later termed relA because of the relAxed behavior of the bacteria (Alfoldi et al. 1962). Later on, Cashel and Gallant, showed that two “magic spots” (MSI and MSII) were specifically observed in starved cells when a labeled nucleotide extract of these cells was separated by thin layer chromatography (Cashel and Gallant 1969). These molecules were found to be polyphosphate derivatives of guanosine, ppGpp and pppGpp (Cashel and Kalbacher 1970; Sy and Lipmann 1973), and were shown to be involved in regulating the gene expression in the bacterial cell, demonstrating a global response, thus fine-tuning the physiology of the bacterium. Two proteins in E. coli, RelA and SpoT, carry out the synthesis and hydrolysis of these molecules, respectively, and maintain their levels in the cell (Cashel et al. 1996; Chatterji and Ojha 2001). On the other hand, Gram-positive organisms have only one protein Rel carrying out the functions of both RelA and SpoT (Mechold et al. 1996; Martinez-Costa et al. 1998; Avarbock et al. 1999). Although Rel or RelA/SpoT has been studied from several systems in detail pertaining to the physiological adaptation, less information is available on the egulation of the protein activity under different conditions. Our studies show that the RelMsm is composed of several domains (HD, RSD, TGS and ACT) with distinct function. HD and RSD domains, present in the N-terminal half of the protein, harbor catalytic sites for the hydrolysis and the synthesis of (p)ppGpp, respectively. TGS and ACT domains, on the other hand, are present at the C-erminal half of the protein and have regulatory function. It, therefore, appears that a communication exists between these domains, to regulate protein activity. It was shown earlier, while studying Rel from S.equisimilis, that there exists an interaction between the C-terminal and the N- terminal of the protein which determines the kind of activity (synthesis/hydrolysis), the protein should demonstrate (Mechold et al. 2002). Later, the N-terminal half crystal structure of the same protein suggested an inter-domain “cross-talk” between the HD and the RSD domain that controls the synthesis/hydrolysis switch depending on cellular conditions (Hogg et al. 2004). In the present work, studies have been carried out to understand a Gram- positive Rel in greater detail and to find out how the opposing activities of Rel are regulated so that a futile cycle of synthesis and hydrolysis of (p)ppGpp, at the expense of ATP, can be avoided. The work has been divided into several chapters describing studies on various aspects of the protein. Chapter 1 outlines the history of the stringent response and summarizes the information available about the stringent response in various systems including plants. Several roles that (p)ppGpp plays in different bacteria have been examined. A special mention on the crystal structure of RelSeq has been made with respect to the regulation of activity. Also, the information available regarding the effects of (p)ppGpp on RNA polymerase has been documented. Role of ppGpp in plants has been discussed in great detail with special emphasis on abiotic stresses. Since different functional domains have been identified in RelMsm, the protein has been divided into two halves and they have been discussed separately in the form of two chapters. Chapter 2 describes the N-terminal half of the Rel protein of M. smegmatis in greater detail. Out of the several domains identified, the role of the two domains present in the N-terminal half of the protein has been studied. The N-terminal half shows both synthesis and hydrolysis activities. Importantly, we find that the protein is active even in the absence of accessory factors such as ribosome and uncharged tRNA, unlike RelA of E. coli. Moreover, deletion of the C-terminal half of the protein leads to a much higher synthetic activity, clearly indicating that the C-terminus is involved in regulating the activity of the protein. Both TGS and ACT domains (the two domains found in the C-terminal half of the protein) have been found to play a regulatory role. The results also indicate that all the deleted constructs are active both in vitro and in vivo. Chapter 3 discusses the C-terminal half of the protein and its role in the multimerization observed in RelMsm. We show that multimerization of Rel protein is due to the inter-molecular disulfide cross-linking. Furthermore, we find that the monomer is the active species in vivo. One of the fascinating points about the C- terminal half is that it is largely unstructured. Additionally, the C-terminal half cannot complement the N-terminal part of the protein when provided in trans, demonstrating further, the requirement of an intact protein for bringing about regulation of Rel activity. This requirement in cis suggests the presence of an intra-molecular communication between the N- and the C-termini, as a mediator of protein regulation. Further, presence of uncharged tRNA increases pppGpp synthesis and down-regulates its hydrolysis in the wildtype protein. However, the uncharged tRNA-mediated regulation is absent in the deleted construct with only the N-terminus half, indicating that uncharged tRNA binds to the C-terminal half of the protein. Several cysteine mutants have been constructed to understand their role in the regulation of Rel activity. The results suggest that one cysteine, present at the C-terminus, is required for intra-molecular cross-talk and the uncharged tRNA-mediated regulation. A detailed characterization of the communication between the two halves of the protein has been attempted in Chapter 4. Surface plasmon resonance experiments carried out on the different cysteine mutants discussed in Chapter 3, for uncharged tRNA binding indicate that all the mutants bind to uncharged tRNA with near-equal affinities as the wildtype protein. This study suggests that the non-responsiveness for tRNA seen in one of the cysteine mutants is due to the loss of inter-domain interaction, while the binding of protein to accessory factors is unaffected. Fluorescence resonance energy transfer has been carried out to observe domain movement in the presence of accessory factors. Distances between the different domains scattered in this ~90 kDa protein, measured by FRET technique, are suggestive of an inter-domain cross-talk, specifically between C338 and C692, thereby regulating the activity of this enzyme. We show, for the first time, that the product of this protein, (p)ppGpp can bind to the C-terminal half making it unstructured, and can, therefore, regulate the protein activity. Chapter 5 is an effort to characterize the promoter of rel from M. tuberculosis. This study was undertaken in order to develop an expression system in mycobacteria. The +1 transcription and the translation start sites have been identified. The –10 hexamer for the RNA polymerase binding has also been mapped using site-directed mutagenesis and is found to be TATCCT. This promoter is also unusually close to the +1 transcription start site. The promoter is specific for mycobacteria and does not function in E. coli. Additionally, the promoter is found to be constitutive in M. smegmatis; however, the possibility of it being regulated in M. tuberculosis cannot be ruled out. Appendix section discusses, in short, the phylogenetic analysis of the mycobacterial Rel sequences. Diagrams of the plasmids used in this study have been provided. Mass spectra recorded for the in vitro synthesized and purified pppGpp and the trypsin digest of the full-length Rel protein have also been given. O O O O

Mycobacteria - Genes

Rel

Mycobacteria

Mycobacterial Rel

Guanosine 3,5(bis) Pyrophosphate

ppGpp

Mycobacterium Smegmatis

Bacteria - Physiology

Stringent Response

Mycobacterium Tuberculosis

RelA/SpoT

Bacteriology

Avaliação do potencial das formigas como vetores mecâncios de micobactérias em hospital especializado na assistência de pacientes de tuberculose no Estado de São Paulo / Evaluation of ants as potential mechanical vectors of mycobacteria in a hospital specializing in assistance to TB patients, the state of São Paulo

Ana Paula Macedo Ruggiero Couceiro

02 April 2012

Introdução - A urbanização desencadeia inúmeros transtornos, como a disseminação de artrópodes e, conseqüentemente, de doenças veiculadas pelos mesmos. As formigas são muito adaptáveis e se beneficiam com a convivência humana. Nos hospitais, elas podem ser vetores mecânicos de inúmeras bactérias, e a diversidade de espécies encontradas nestes ambientes, causam preocupação pelo risco potencial à saúde pública. O aumento das infecções hospitalares envolvendo micobactérias ambientais, com surtos no Brasil entre 1998 a 2009 em 23 estados alarmou os órgãos e profissionais de saúde pública. Objetivos - Avaliar o potencial de formigas como vetores de micobactérias em um hospital especializado no atendimento de doentes com tuberculose. Métodos - Foram realizadas seis coletas de formigas em diferentes áreas do hospital no período de 2009 a 2010, que foram semeadas em meios de cultura de Löwenstein-Jensen e de Stonebrink para isolamento de micobactérias. As culturas sugestivas foram submetidas à coloração de Ziehl-Neelsen para bacilos álcool-ácido resistentes e identificação por métodos moleculares (PRA para o gene hsp65 com o par de primers TB11 e TB12 gênero-específico e sequenciamento genético do DNA). Resultados - Do total de 247 amostras de formigas coletadas e semeadas, 70 por cento das formigas pertenciam à espécie Tapinoma melanocephalum, 25 por cento a espécie Dorymyrmex sp., 3 por cento a espécie Camponotus sp. e 2 por cento a espécie Pheidole sp., dados similares foram observados anteriormente em pesquisas realizadas em hospitais. Quinze amostras apresentaram bacilos álcool-ácido resistentes de crescimento rápido. Nos métodos moleculares, doze pertenciam ao Gênero Mycobacterium. No PRA-hsp 65, e no sequenciamento genético do DNA, quatro amostras foram identificadas quanto à espécie (duas Mycobacterium chelonae, uma Mycobacterium parafortuitum e uma Mycobacterium murale), quatro micobactérias com resultados idênticos no PRA e não identificadas no sequenciamento foram sugestivas de uma nova espécie, e duas amostras não foram identificadas. Mycobacterium chelonae isolada nesta pesquisa foi previamente descrita como agente causador de abscessos em humanos. Conclusão - Estes dados confirmam a presença de micobactérias veiculadas por formigas no ambiente hospitalar, representando um potencial vetor mecânico destas para pacientes e profissionais de saúde, principalmente em infecções nosocomiais / Introduction- Urbanization triggers numerous disorders, such as the dissemination of arthropods and, consequently, dissemination of diseases transmitted by them. Some ant species are very adaptable to the human environment. At hospitals, once they are mechanical vectors of bacteria, and the diversity of species found in these environments, they can represent a potential risk to public health. The increase of nosocomial infections involving environmental mycobacteria, with outbreaks in Brazil from 1998 to 2009 in 23 states called the interest of health professionals and health agencies. Purpose - Evaluate the potential of ants as vectors of mycobacteria in a hospital specialized in the care of patients with tuberculosis. Methods Samples of ants were collected from different areas of the hospital from 2009 to 2010, and workers were inoculated in Löwenstein-Jensen and Stonebrink media for mycobacteria isolation. The suggestive cultures were subjected to Ziehl-Neelsen stain for acid-fast bacilli and identification were performed by molecular methods (PRA for the hsp65 gene with the pair of primers TB11 - TB12 and genetic sequencing). Results - The total of 247 samples of ants collected and sown, 70 per cent belonged to species of ants Tapinoma melanochepalum, 25 per cent Dorymyrmex sp.,3 per cent Camponotus sp. and 2 per cent Pheidole sp., data similar with previous studies conducted in hospitals. Fifteen fast-growing mycobacteria were isolated. In molecular methods, twelve belonged to the genus Mycobacterium. In PRA-hsp65, and the genome sequencing of DNA, four samples were identified at species level (two Mycobacterium chelonae, one Mycobacterium parafortuitum and one Mycobacterium murale), four mycobacteria with similar results in the PRA and not identified in the sequencing, suggestive of a new species and two unidentified samples. M. chelonae was previously reported as causative agent of abscess in humans. Conclusions - These results confirm the presence of mycobacteria carried by ants in the hospital, representing a potential mechanical vector for these patients and healthcare professionals, particularly in nosocomial infections

Ambiente Hospitalar

Formigas

Hospital

Infecção Nosocomial

Micobactérias

Micobactérias de Crescimento Rápido

Vetor Mecânico

Ants

Fast-Growing Mycobacteria

Hospital

Mechanical Vector

Mycobacteria

Nosocomial Infection

Nucleic Acid-binding Adenylyl Cyclases in Mycobacteria : Studies on Evolutionary & Biochemical Aspects

Zaveri, Anisha

January 2016

Mycobacterium tuberculosis is one of the most successful human pathogens, estimated to have infected close to one-third of the global human population. In order to survive within its host, M. tuberculosis utilises multiple signalling strategies, one of them being synthesis and secretion of universal second messenger cAMP. This process is enabled by the presence of sixteen predicted adenylyl cyclases in the genome of M. tuberculosis H37Rv, ten of which have been characterised in vitro. The synthesized cAMP is recognised by ten putative cAMP-binding proteins in which the cyclic AMP-binding domain is associated with a variety of enzymatic domains. The cAMP signal can be extinguished by degradation by phosphodiesterase’s, secretion into the extracellular milieu or via sequestration of the nucleotide by upregulation of a high-affinity cAMP-binding protein. Of the sixteen adenylyl cyclases (ACs) encoded by M. tuberculosis H37Rv, a subset of multidomain adenylyl cyclases remain poorly characterised, primarily due to challenges associated with studying these in vitro. The adenylyl cyclase domain in these proteins is associated with an NB-ARC domain (nucleotide binding domain common to APAF-1, plant R proteins and CED-4), a TPR domain (tetratricopeptide repeat) and an LuxR-type HTH motif (helix-turn-helix). This architecture places these multidomain mycobacterial ACs within a larger group of STAND (Signal transduction ATPase’s with numerous domains) proteins, and hence they will be referred to as STAND ACs. The STAND proteins are a recently recognised class of multidomain ATPases which integrate a variety of signals prior to activation. Activation is accompanied by formation of large oligomeric signalling hubs which facilitate downstream signalling events. While most STAND proteins have a single effector domain followed by an NB-ARC domain and a scaffolding domain, the STAND ACs distinguish themselves by retaining two effector domains, the AC domain and the HTH domain, at the N- and C- termini respectively. The cyclase, NB-ARC, TPR and HTH domains have widely divergent taxonomic distributions making the presence of these four domains in a single polypeptide rare. In fact, proteins with cyclase-NB-ARC-TPR-HTH (C-A-T-H) domain organisation were found to be encoded almost exclusively by slow growing mycobacterial species, a clade that harbours most mycobacterial pathogens, such as M. tuberculosis and M. leprae. Notably, one of the STAND ACs, Rv0386, is the only mycobacterial AC shown till date to be required for virulence of M. tuberculosis in mice. Using phylogenetic, the evolutionary underpinnings of this domain architecture were examined. The STAND ACs appear to have most likely evolved via a domain gain event from a cyclase-ATPase-TPR progenitor encoded by a strain ancestral to M. marina. Subsequently, the genes duplicated and diverged, sometimes leading to frameshift mutations splitting the cyclase domain from the C-terminal domains. Consequently, M. tuberculosis encodes for three ‘full-length’ STAND ACs, namely, Rv0386, Rv1358 and Rv2488c and one split STAND AC. The split STAND AC is made up of Rv0891c, containing the AC domain, and Rv0890c, containing the NB-ARC, TPR and HTH domains. rv0891c and rv0890c were found to be expressed as an operatic transcript, though they were translationally uncoupled. Pertinently, M. Canetti, an early-branching species of the M. tuberculosis complex, contains an orthologue of Rv0891c and Rv0890c where all four domains are present in a single polypeptide. Sequence analysis of the four STAND ACs in M. tuberculosis allowed predictions of significant divergence in function. These proteins showed high sequence conservation in their HTH domains, with substantial sequence divergence in their TPR, NB-ARC and AC domains. Biochemical analysis on the AC domains revealed that Rv0891c and Rv2488c possessed poor or no AC activity, respectively. On the other hand, the cyclase domain of Rv0386 could catalyse cAMP synthesis. Moreover, for both Rv0891c and Rv0386, presence of the C-terminal domains potentiated adenylyl cyclase activity, suggestive of allosteric regulation within the STAND AC module. Studies on Rv0891c also revealed that the protein could inhibit the adenylyl cyclase activity of Rv0386 in trans. This result thus provided a novel mechanism by which proteins harbouring poorly active/inactive adenylyl cyclase domains could contribute to cAMP levels, by acting as inhibitors of other adenylyl cyclases. The STAND ACs were found to be inactive ATPases. Additionally, incubation with nucleotides did not stimulate oligomerisation of these proteins, unlike what has been shown for several other STAND proteins. However, mutations in the NB-ARC domain perturbed the basal oligomeric state of these proteins, indicating that the NB-ARC domain can influence self- association. A subset of NB-ARC domain mutants also showed increased adenylyl cyclase activity, reiterating the inter-domain cross-talk in the STAND ACs. Since the AC activity of these proteins was meagre, the properties of the HTH domain were examined, as an alternative effector domain. Genomic SELEX was performed using the TPR-HTH domains of Rv0890c, and revealed a set of sequences that bound to this protein, though they lacked common sequence features. Further analysis revealed that Rv0890c bound to DNA in a sequence-independent manner, through the HTH domain. This binding was cooperative with multiple protein units engaging in DNA-binding. Due to the cooperative nature of binding and the lack of sequence preference, Rv0890c appeared coat the DNA molecule. This was further proved by the ability of Rv0890c to protect DNA from DNaseI-mediated degradation, and the requirement for long DNA sequences to form stable DNA-protein complexes. Studies also revealed that Rv0890c interacted with RNA and ssDNA. In fact, the protein as purified from heterologously expressing E. coli cells was bound to RNA. RNA-binding by a LuxR-type HTH has not been reported previously, providing a new function for this class of HTHs. Interestingly, nucleic acid-binding by a fusion Rv0891c-Rv0890c protein, similar to the one encoded in M. canetti, was shown to stimulate adenylyl cyclase activity. This was likely due to a relief of inhibitory interactions between the TPR-HTH and the AC domains, on DNA-binding. Given the high sequence similarity between the HTH domains of the STAND ACs, they were expected to bind to DNA in an identical manner. Indeed, the HTH domains of Rv0386 and Rv1358 engaged with DNA with an identical affinity as Rv0890c. Sequence comparisons in the HTH domain enabled identification of conserved basic residues, of which one, R850 was essential for nucleic acid-binding. Surprisingly however, Rv0386 and Rv1358 did not exhibit RNA-binding, pointing towards functional divergence of Rv0890c from its paralogues. Since the HTH domains of the STAND ACs were highly conserved, it was possible that the ability to bind to RNA was instead dictated by the adjacent TPR modules. To examine this possibility, TPR domains were swapped between Rv0890c and Rv0386. Interestingly, both the chimeric proteins showed a reduced ability to bind to DNA, while showing a complete absence of RNA- binding. These results suggested that the TPR domains were critical in modulating nucleic acid-binding. Moreover, the effect of the TPR domain was context-dependent, since the presence of non-cognate TPR domains hampered nucleic acid-binding. However, the ability to bind to RNA was not solely governed by the TPR domain since the Rv0890cTPR-Rv0386HTH chimeric protein did not show RNA-binding, in spite of containing a permissive TPR domain. To further dissect the molecular requirements for RNA-binding, the conservation of basic residues between the HTH domains of Rv0890c versus Rv1358 and Rv0386 was examined. Interestingly the HTH domain Rv0890c contained two additional positively charged residues over Rv1358 and Rv0386. Mutations of these abolished RNA-binding by Rv0890c. Thus the evolution of two basic residues permit Rv0890c to diverge in its nucleic acid-binding properties, a possible example of defunctionalisation following gene duplication. In summary, this thesis attempts to understand the evolution and functions of the STAND ACs, a group of pathogenically relevant and uniquely mycobacterial multidomain proteins. Phylogenetic analysis revealed an expansion of this gene family in slow growing mycobacteria. Biochemical characterisation showed that following gene duplication, the resulting proteins diverge both in their ability to synthesize cAMP and in their association with nucleic acids. Studies on these proteins also revealed novel mechanisms of regulation of mycobacterial cAMP levels. Additionally, these proteins exhibited indiscriminate binding to DNA/nucleic acids indicating that they may be responsible for global functions in the cell which extend beyond cAMP synthesis.

Adenylyl Cyclases

Mycobacteria

Cyclic AMP in Mycobacteria

STAND Proteins

TPR Domain

HTH Domain

Nucleoid Associated Proteins

Mycobacterium tuberculosis

M. tuberculosis

H37Rv

Biochemistry

DNA Repair Proteins in Mycobacteria and their Physiological Importance

Sang, Pau Biak

January 2014

DNA repair proteins in mycobacteria and their physiological importance Mycobacterium tuberculosis, the causative organism of tuberculosis, resides in the host macrophages where it is subjected to a plethora of stresses like reactive oxygen species (ROS) and reactive nitrogen intermediate(RNI) which are generated as a part of the host’s primary immune response. These stresses can damage the cellular components of the pathogen including DNA and its precursors. Two common damages to DNA and its precursors caused by ROS and RNI are oxidation of guanine to 8-oxo-guanine and deamination of cytosine to uracil. Mycobacteria, which are known to have high G+C content, must be more susceptible to such damages, and are thus equipped with the mechanisms to counteract these damages. One such mechanism is to hydrolyse the 8-oxo-dGTP into 8-oxo-dGMP to avoid its incorporation in the DNA during its synthesis. This job is done by a protein called MutT.In mycobacteria four homologs of MutT, namely MutT1, MutT2, MutT3 and MutT4 have been annotated. The second mechanism deals with the repair of uracil residues present in DNA which are generated by deamination of cytosines or incorporation of dUTP during DNA synthesis. This is taken care of by a protein called uracil DNA glycosylase (UDG) which excises uracil by cleaving the N-C1’ glycosidic bond between the uracil and the deoxyribose sugar in a DNA repair pathway called the base excision repair (BER). In this study, the biochemical properties and physiological role of mycobacterial MutT2 and, MSMEG_0265 (MsmUdgX), a novel uracil DNA glycosylase superfamily protein, have been investigated. I.Biochemical characterization of MutT2 from mycobacteria and its antimutator role. Nucleotide pool, the substrate for DNA synthesis is one of the targets of ROS which is generated in the macrophage upon Mycobacterium tuberculosis infection. Thus, the pathogen is at increased risk of accumulating oxidised guanine nucleotides such as 8-oxo-dGTP and 8-oxo-GTP. By hydrolysing the damaged guanine nucleotides before their incorporation into nucleic acids, MutT proteins play a critical role inallowing organisms to avoid their deleterious effects. Mycobacteria possess several MutT proteins. Here, we have purified recombinantM. tuberculosisMutT2 (MtuMutT2) andM. smegmatisMutT2 (MsmMutT2) proteins as representative of slow and fast growing mycobacteria, for the purpose of biochemical characterization. UnlikeEscherichia coliMutT, which hydrolyzes 8-oxo-dGTP and 8-oxo-GTP, the mycobacterial proteins hydrolyze not only 8-oxo-dGTP and 8-oxo-GTP but also dCTP and 5-methyl-dCTP. Determination of kinetic parameters (KmandVmax) revealed thatwhileMtuMutT2 hydrolyzes dCTP nearly four times better than it does 8-oxo-dGTP,MsmMutT2 hydrolyzes them almost equally well. Also,MsmMutT2 is about 14 times more efficient thanMtuMutT2 in its catalytic activity of hydrolyzing 8-oxo-dGTP.Consistent with these observations,MsmMutT2 but notMtuMutT2 rescuesE. colifor MutT deficiency by decreasing both themutation frequency and A to C mutations (a hallmark of MutT deficiency). We discuss these findings in the context of the physiological significance of MutT proteins. II.Understanding the biochemical properties of MSMEG_0265 (MsmUdgX), a novel uracil DNA glycosylase superfamily protein Uracil DNA glycosylases (UDGs) are base excision repair enzymes which excise uracil from DNA by cleaving the N-glycosidic bond. UDGs are classified into 6 different families based on their two functional motifs, i. e.,motif A and motif B. In mycobacteria, there are two uracil DNA glycosylases, Ung and UdgB which belong to Family 1 and Family 5, respectively. In this study, based on the presence of the two functional motifs, we have discovered yet another uracil DNA glycosylase in M. smegmatis, which we have called MsmUdgX.The motif A and motif B of this protein indicate that it does not belong to any of the UDG families already classified but has highest similarity with Family 4 UDGs. Homologs of this protein are also present in several other organisms like M. avium, Streptomyces ceolicolor, Rhodococcus etc., but absent in M. tuberculosis, archaea and eukaryotes. Activity assays of this protein show that unlike other UDGs, MsmUdgX does not excise uracil, but forms a tight complex with uracil containing single stranded (ss) and double stranded (ds) DNAs, as observed by a shifted band in 8M urea-PAGE as well as SDS-PAGE. It also does not recognize other modified nucleotides that we investigated, in DNA. The protein binds to uracil-DNA in a wide range of pH and the minimum substrate required for its binding is pNUNN. Like Family 4 UDG, the protein has Fe-S cluster but it is not as thermostable as the Family 4 UDGs. Addition of different metal ions does not affect its binding property, and even the presence of M. smegmatis cell free extract does not diminish its binding activity. Since this protein binds specifically to uracil in DNA, an application of the protein for detection of uracil in the genomic DNA is proposed. III. Elucidation of the role of KRRIH loop in MsmUdgX by mutational analysis MsmUdgX is a novel uracil DNA glycosylase superfamily protein which has the highest homology to Family 4 UDGs. However, alignment of MsmUdgX amino acid sequence with that of Family 4 UDGs shows that there is an extra stretch of amino acids which is unique to this group of proteins. This stretch, defined by AGGKRRIH is absent in all Family 4 UDGs and the region KRRIH of the strtch is quite conserved amongst all UdgX proteins. Homology modelling of MsmUdgX, using a Family 4 UDG (TthUdgA) shows that this extra stretch of amino acids forms an outloop near the enzyme active site. Another unique difference between MsmUdgX and Family 4 UDGs is in the motif A where MsmUdgX has GEQPG and the Family 4 UDGs haveGE(A/G)PG. Our work on MsmUdgX has shown that, unlike other UDGs, this protein does not excise uracils, but forms a tight complex with the uracil containing DNA. This unique tight uracil binding property as well as KRRIH amino acid stretch has not been observed for any uracil DNA glycosylase superfamily proteins. So, to gain insight into the role of KRRIH and glutamine (Q) of motif A in MsmUdgX family of proteins, site directed mutagenesis was done in this region and we observed that mutation of His109 of the KRRIH loop to serine (S) leads to a gain of uracil excision activity, whereas changing the R107 to S, ‘RRIH’ to ‘SSAS’ or deleting the loop altogether leads to loss of its complex formation activity. Further, mutation of H109 to other amino acids like G, Q and A also shows uracil excision activity. Mutation of the glutamine in the motif A to alanine so that it is exactly similar to that of Family 4 UDGs, does not affect its uracil binding activity. This observation indicates that the KRRIH loop has an important role in the tight binding and/or uracil excision activity of MsmUdgX. Crystal structure of MsmUdgX in complex with uracil-DNA oligo and MsmUdgX H109S mutants are being studied.IV. Physiological importance of MsmUdgX in M. smegmatis MsmUdgX is a uracil DNA glycosylase superfamily protein which binds tightly to uracil (in DNA) without excising it. To elucidate its role in M. smegmatis, knockout of udgX was generated. Growth comparison of the wild type and the ΔudgX strains does not show any growth differences under the conditions tested. However, overexpression of MsmUdgX in recA deficient strains of E. coli as well as M. smegmatis leads to their retarded growth. Retarded grown is also observed in strains deficient in other DNA repair proteins that work in conjunction with RecA. These observations indicate that repair/release of MsmUdgX-uracil DNA complex might be a RecA dependent process.

Mycobacteria

Mycobacterial DNA Repair Proteins

Mycobacteria

MSMEG

MutT2

Bacterial Proteins

Site Directed Mutagenesis

DNA Binding Proteins

DNA Repair Enzymes

Uracil DNA Glycosylase

MsmUdgX

MutT4

MutT2

MutY

Microbiology

Insights Into Transcription-Repair Coupling Factor From Mycobacterium Tuberculosis

Swayam Prabha, *

02 1900

Introduction Nucleotide excision repair (NER) is a highly conserved pathway involved in repair of a wide variety of structurally unrelated DNA lesions. One of the well characterized NER systems is from E. coli which involves UvrABC nucleases. NER consists of two related sub-pathways: global genomic repair (GGR), which removes lesions from the overall genome, and transcription coupled repair (TCR), which removes lesions from the transcribed strand of active genes. Bulky DNA lesions such as cyclobutane pyrimidine photodimers (CPD) induced by UV irradiation block RNA polymerase (RNAP) during transcription. In bacteria, a gene product of mfd called transcription repair coupling factor (TRCF) or Mfd is required for TCR. Bacterial Mfd interacts with the stalled RNAP, displaces it from the DNA and recruits NER proteins at the site of damage. Mfd, thus contributes to the faster repair of the transcribed strand compared to the non-transcribed strand for similar kind of lesions. Intracellular pathogens like M. tuberculosis are constantly exposed to a variety of stress conditions inside the host, mainly due to host defense systems and antibiotic treatments. It is therefore, extremely important for bacteria to have DNA damage repair and reversal mechanisms that can efficiently counteract these effects. However, very little is known about DNA repair systems in M. tuberculosis compared to other bacteria. Sequencing of M. tuberculosis genome revealed the presence of NER associated genes including a putative mfd. Additionally, due to the high GC content of genome as well as the DNA damage prone host environment, the transcription in M. tuberculosis may encounter the problems, which are not apparent in other bacteria. Therefore, the gene like mfd may play very important role in physiology of M. tuberculosis. In the present study, we describe the biochemical and functional characterization of Mfd from M. tuberculosis (MtbMfd) and discuss its unusual properties. Biochemical characterization of MtbMfd Genome analysis of M. tuberculosis as well as the sequence alignment studies revealed that MtbMfd is 1234 amino acids long multifunctional protein having various domains specialized for different functions. Cloning of Mtbmfd was carried out by reconstructing the full length gene from three PCR amplified fragments using genomic DNA as a template. Complementation study using Mtbmfd suggested that the gene of interest complements E. coli counterpart and increases survival of UV irradiated cells. To further characterize the function of Mtbmfd, a road block reporter assay was performed, which indicates that the MtbMfd interacts with stalled E. coli RNAP and displaces it from the site of transcription resulting in low reporter gene activity. The MtbMfd protein was expressed and purified by using various chromatographic techniques, and confirmed by mass spectrometry. In addition to full length protein, a number of truncated MtbMfd constructs were generated and purified to homogeneity. Mfd is a motor protein and requires ATP hydrolysis in order to translocate along DNA. The signature motifs of superfamily 2 helicases / ATPases are present at the C-terminal of Mfd along with translocase motif which is highly homologous to motif present in RecG helicase. To analyze the kinetics of ATP hydrolysis of MtbMfd and its truncated proteins, ATPase reactions were carried out using γ32P-ATP as a tracer. Wild-type MtbMfd exhibited ATPase activity, which was stimulated ~1.5 fold in presence of dsDNA. The mutant MtbMfd (D778A), which harbors mutation in one of the key residues of Walker B motif of the ATPase domain showed negligible ATPase activity indicating the importance of residue D778 for ATP hydrolysis. While the C-terminal domain (CTD) comprising amino acids 600 to 1234 showed elevated ATPase activity, the N-terminal domain (NTD) containing the first 500 amino acid residues was able to bind ATP but deficient in hydrolysis. Deletion of 184 amino acids from the C-terminal end of MtbMfd (MfdΔC) increased the ATPase activity by ~10-fold compared to full-length MtbMfd. The translocase activity of MtbMfd was measured by an oligonucleotide displacement assay and it was found that full length MtbMfd and CTD have a very weak translocase activity whereas, MfdΔC exhibited efficient translocation along DNA in ATP dependent manner. These results provide a direct correlation between translocase and ATPase activity of MtbMfd, and suggest possibly an auto-regulatory function for the extreme C-terminus of MtbMfd. Oligomeric status of MtbMfd was determined using various techniques including gel filtration chromatography and it was found that MtbMfd exists as monomer and hexamer in solution. The monomer showed increased ATPase activity and susceptibility to proteases compared to the hexameric form. MfdΔC, on the other hand, was predominantly monomer in solution implicating importance of the extreme C-terminal region in oligomerization of protein. Taken together, the biochemical evidence suggests that monomeric MtbMfd is an active form and oligomerization provides stability to the protein. One important finding of the present study is the binding of ATP to NTD of MtbMfd. All Mfd NTDs resemble UvrB and possesses the degenerate ATPase motifs. Indeed, on the basis of sequence and structural similarities, it has been suggested that Mfds have evolved from UvrB incorporating an additional translocase activity. UvrB has a cryptic ATPase activity while the NTD of Mfd may have lost the activity as it possesses degenerate Walker motifs. In contrast, NTD of MtbMfd binds ATP but is hydrolysis deficient. A closer comparison of the amino acid sequences in the Walker A motif reveal that conserved K 45 of UvrB has been replaced by R in case of NTD of MtbMfd. It has been shown previously that mutation of K 45 to A, D and R led to a loss of ATPase activity of UvrB. Thus, MtbMfd seems to be a natural mutant of UvrB. Since NTD harbors an intact UvrA interacting domain, when it is expressed it may sequester the cellular pool of UvrA leading to dominant negative phenotype. When UV survival assays were carried out, cells expressing NTD showed hyper-sensitivity to UV light – a typical characteristic of NER deficiency. In addition, in vitro NER assay clearly suggested that NTD sequesters pool of UvrA inside the cell and blocks both GGR and TCR which further affects the mutation frequency of bacterial cells. Influence of MtbMfd on elongation state of RNAP The movement of RNAP along the template during transcription elongation is not uniform and is interrupted due to various factors. To overcome transcription elongation interruptions, a number of proteins viz. Mfd, Gre and Nus act on RNAP and modify its activity. RNAP displacement and transcript release experiments showed that MtbMfd influenced the elongating RNAP by more than one way. MtbMfd displaced stalled RNAP, which was blocked by NTP starvation on T7A1 promoter based template in a concentration and time-dependent manner. RNAP displacement activity of MtbMfd was shown to depend on ATP or dATP hydrolysis. On the other hand nucleotides like ADP, GTP, CTP and ATPγS did not support the RNAP displacement activity. However, in presence of ATPγS, MtbMfd was able to bind stalled complex but unable to displace RNAP suggesting that ATP or dATP hydrolysis is important for MtbMfd function. On the other hand, MtbMfd did not affect initiating RNAP when σ factor was still bound suggesting that upstream DNA is necessary for Mfd function. To assay RNA or transcript release activity of MtbMfd after transcription complex disruption, immobilized transcription complex assay was carried out. Immobilized stalled complex was generated by UTP and CTP starvation on biotinylated T7A1 promoter based template which can be affixed to temporary pellet in presence of streptavidin beads. It was found that MtbMfd released RNA into a supernatant fraction in a concentration-dependent manner suggesting that MtbMfd releases transcript after ternary complex disruption. MtbMfd released transcript in an energy-dependent manner and both ATP and dATP supported the activity, which allows the complete separation of RNA release from RNA synthesis inside the cell. An ATPase mutant of MtbMfd (MfdD778A) failed to release transcript, which further supported that ATP hydrolysis is important for MtbMfd function. Since both Mfds and RNAPs are evolutionary conserved proteins, to analyze the effect of MtbMfd on other bacterial RNAPs, displacement and release assays were carried out. Stalled complexes were generated using EcoRNAP (E. coli), MsRNAP (M. smegmatis) and MtbRNAP (M. tuberculosis) on T7A1 promoter based template. It was observed that MtbMfd was able to displace all the three RNAPs from stalled elongation complex as well as released transcript with varying efficiency. MtbMfd showed optimal displacement and release activity in presence of mycobacterial RNAPs. Transcription elongation complexes adopt various conformations and exist as different isomerized states during elongation. In an active elongation complex the 3'-OH polymerizing end of transcript aligns with an active centre of the RNAP. However, one of the most common and intrinsic properties of RNAP is backtracking or reverse translocation, which leads to misalignment of 3'-OH polymerizing end from an active centre of the polymerase. It is of interest to know if backtracking affects MtbMfd function. It is likely that complexes blocked by lesions inside the cell might tend to backtrack, and different translocational isomers possibly have different sensitivities to MtbMfd action which may illuminate the overall mechanism of MtbMfd. Backtracking of RNAP was induced on +20 and +39 stalled complexes and the effect of MtbMfd was analyzed in presence of NTPs in the reaction. It was found that arrested or backtracked complexes were restored to the forward position by the activity of MtbMfd in presence of NTP resulting into productive elongation. These results suggest that arrested RNAP again resumes transcription if conditions are favorable; otherwise, MtbMfd further assists RNAP to dissociate which leads to release of transcript. Anti-backtracking activity of MtbMfd might have important function in cellular metabolism and it has been speculated that Mfd could play more general role during transcription apart from repair. To explore the role of MtbMfd as a transcription factor and effect of MtbMtb on transcription processes in the mycobacteria, a variety of T7A1 promoter based templates were generated. These templates were derived from genes of M. tuberculosis and E. coli having varying GC content (39-81 %). The rationale behind this experiment is that the high GC content of mycobacteria and the template derived from mycobacterial genes may pose as sequence dependent structural constraints and hence block the RNAP during transcription. By anti-backtracking activity of MtbMfd these paused complexes may get relieved, leading to efficient transcription by RNAP which may lead to the formation of more full length transcript. To analyze the effect of MtbMfd, purified templates of different GC content were incubated with RNAP and MtbMfd to carry out in vitro transcription. Although, in case of multiple rounds of transcription, multiple pauses were observed even in presence of MtbMfd. However, in presence MtbMfd around 1.5 - 2 fold increased full-length transcripts were observed suggesting that MtbMfd assisted RNAP during elongation to overcome sequence dependent pause. To avoid multiple pauses that are likely to occur due to the initiation of multiple round of transcription, and trailing effect of RNAP itself, single round of transcriptions were carried out in presence of heparin. Sequence specific pauses were observed with increasing GC percentage in template suggesting that indeed high GC content contributes to transcription pause. At the same time, MtbMfd in the reaction increased the amount of full length transcript by 1.5 - 2.0 fold probably by pushing paused RNAP forward to resume elongation. Taken together, this study investigates the biochemical properties of MtbMfd and its mechanism of action. In addition, it explores the importance of the coupling of transcription to repair in M. tuberculosis as well as the overall proof reading mechanism of transcription elongation in the GC rich genome of mycobacteria.

Mycobacterium tuberculosis

Mycobacterium tuberculosis Mfd

DNA Damage

RNA Polymerase (RNAP)

DNA Repair

Mycobacteria - Transcirption Elongation

M. tuberculosis

MtbMfd

Endogenous DNA

Biochemical Genetics

T cell Differentiation and Cytokine Responses in Nontuberculous Mycobacterial Infection

Claeys, Tiffany Ann

January 2021

No description available.

Biomedical Research

Immunology

Microbiology

Biology

T cells

mycobacteria

nontuberculous mycobacteria

NTM

Mycobacterium avium

mycobacterium intracellulare

cytokine

T cell differentiation

Th1

Th17

Characterisation of a high copy number mutant pAL5000 origin of replication

Jansen, Yvette

12 1900

Thesis (MScMedSc)--Stellenbosch University, 2001. / ENGLISH ABSTRACT: The plasmid pAL5000 is a mycobacterial plasmid isolated from Mycobacterium fortuitum. It is a low copy number plasmid, which replicates in both fast growing (e.g. M. smegmatis) and slow growing (e.g. M. bovis BCG) mycobacteria. Most mycobacterial-E. coli shuttle vectors utilise the pAL5000 origin of replication. The minimum replicon consists of ORF1 (RepA), ORF2 (RepB) and the origin of replication. Dr W.R. Bourn created an E. coli-mycobacterial vector based on the pAL5000 origin of replication (pORI) and then subjected it to semi-random mutagenesis. A high copy number mutant was identified (pHIGH) and the causative mutation was tentatively identified as a 3bp deletion situated just upstream of repB. This work describes the further characterisation of the mutant plasmid. Firstly, it was shown by retransforming M. smegmatis with both the original and mutant plasmids (pORI and pHIGH), that the mutation causing the increased copy number was plasmid-encoded and not on the chromosome. Following this, it was demonstrated by simple subcloning of the region that carries the 3 bp deletion, that other pAL5000-based vectors could be converted to high copy number. In addition to this, the subcloned region was sequenced and the nature of the mutations was confirmed. The subcloning experiment confirmed that the 3bp deletion caused the high copy number phenotype. Following this, the exact copy number of pHIGH and the relative increase in copy number was determined. From this, the copy number of pORI could also be determined. The plasmid pHIGH has a copy number of approximately 54, compared to the 8 of pORI (a relative increase by a factor of 7). Because it is important for researchers to know the characteristics of the vectors that they use, especially the influence it will have on its host, stability tests and growth curves were also performed. It was seen that the higher copy number did not markedly increase the stability, however, this is because pORI is already extremely, and unexpectedly, stable in the host M. smegmatis. According to the growth curves, the increased copy number has little effect on the growth of the host M. smegmatis. Possible mechanisms for the increased copy number were then investigated. By using a promoter probe vector, the possible existence of a promoter situated between the two open reading frames of pAL5000 (repA and repB) was investigated. It was thought that the mutation might have created, or changed an existing promoter, situated between repA and repB. The results showed, however, that in both pORI and pHIGH there might be a very weak promoter upstream of repB, but the mutation did not cause any change that was measurable by the method that was used. A further possibility was that the mutation caused a change in the RNA secondary structure, which might then have an effect on the translational efficiency of RepB. It was found that the 3bp deletion in pHIGH causes a change in the local RNA secondary structure around the ribosomal binding site and the start codon, when compared to pORI (wild type). This change may cause the translation initiation rate of RepB to be different between pHIGH and pORI. Ultimately it would lead to a different ratio of RepA and RepB in the cell. / AFRIKAANSE OPSOMMING: Die plasmied pAL5000 is ‘n mikobakteriele plasmied wat vanuit Mycobacterium fortuitum gei'soleer is. Dit is ‘n lae kopie-getal plasmied wat in beide vinnig groeiende (bv. M. smegmatis) en stadig groeiende (bv. M. bovis BCG) mikobakteriee kan repliseer. Die meeste mikobakteriele-E. coli shuttle vektore gebruik die pAL5000 oorsprong van replisering. Die minimum replikon bestaan uit ORF1 (RepA), ORF2 (RepB) en die oorsprong van replisering. Dr. W.R. Bourn het ‘n E. coli-mikobakteriele vektor gemaak wat gebaseer is op die pAL5000 oorsprong van replisering (pORI), en dit onderwerp aan semi-random mutagenese. ‘n Hoë kopie-getal mutant is gei'dentifiseer (pHIGH) en die mutasie hiervoor verantwoordelik was tentatief gei'dentifiseer as ‘n 3bp delesie, net stroomop van repB. Die projek beskryf die verdere karakterisering van die mutante plasmied. Eerstens, deur M. smegmatis te hertransformeer met die plasmied DNA (pORI en pHIGH), is dit bewys dat dit mutasie wat die toename in kopie-getal veroorsaak, deur die plasmied gekodeer word, en dat dit nie ‘n mutasie op die chromosoom is nie. Hierna is dit deur eenvoudige subklonering bewys dat die gedeelte wat die 3bp delesie dra, ander pAL5000-gebaseerde vektore ook kan verander in ‘n hoër kopie-getal. Die sub-klonerings eksperiment het ook bewys dat die 3 bp delesie die oorsaak is vir die hoë kopie-getal fenotipe. Volgende is die presiese kopie-getal van pHIGH en die relatiewe toename in kopiegetal bepaal. Die kopie-getal van pORI kon vanaf hierdie data bepaal word. Die plasmied pHIGH het ‘n kopie-getal van ongeveer 54 in M. smegmatis, in vergelyking met die 8 van pORI (‘n relatiewe toename met ‘n faktor van 7). Aangesien dit vir navorsers belangrik is om die eienskappe van die vektore wat hulle gebruik, te ken, en veral die invloed wat dit op die gasheer sal hê, is stabiliteits toetse, en groeikurwes gedoen. Die hoër kopie-getal het nie die stabiliteit werklik verbeter nie, maar dit is omdat pORI alreeds uiters stabiel is in die gasheer M. smegmatis. Volgens die groeikurwes het die toename in kopie-getal ‘n minimale effek op die groei van die gasheer M. smegmatis. Moontlike meganismes vir die hoër kopie-getal is ook ondersoek. Die moontlike bestaan van ‘n promoter tussen die twee oop-leesrame van pAL5000 (repA en repB) is ondersoek deur gebruik te maak van ‘n “promoter probe” vektor. Die mutasie kon moontlik ‘n promoter geskep het, of ‘n bestaande een tussen repA en repB verander het. Die resultate het gewys dat daar in beide pORI en pHIGH moontlik ‘n baie swak promoter stroomop van repB is, maar die mutasie het nie enige veranderinge veroorsaak wat meetbaar was met die metode wat gebruik is nie. ‘n Verdere moontlikheid was dat die mutasie ‘n verandering in die RNA sekondere struktuur kon veroorsaak het, en dit mag ‘n effek hê op die translasie effektiwiteit van RepB. Daar is gevind dat, in vergelyking met pORI, het die 3bp delesie in pHIGH ‘n verandering in die lokale RNA sekondere struktuur rondom die ribosomale bindings posisie en die begin-kodon veroorsaak. Die verandering mag veroorsaak dat die translasie inisiasie tempo van RepB verskillend is vir pORI en pHIGH. Uiteindelik sal dit lei tot ‘n heeltemal ander verhouding van RepA en RepB in die sel.

Plasmids

Plasmids -- Genetics

Mycobacteria

Mycobacterial diseases

Mutant plasmids

Mycobacterial plasmids

Plasmid replication

Dissertations -- Medicine