Insertion sequence IS1141: discovery, characterization, and association with Mycobacterium intracellulare colonial variation

Via, Laura Ellen Akers

20 October 2005

Mycobacterium avium and Mycobacterium intracellulare, (M. avium complex, MAC) are human pathogens causing disease in individuals with acquired immunodeficiency syndrome (AIDS) or with thoracic abnormalities. MAC bacteria are difficult to kill because of the resistance of the pathogens to chemotherapeutic agents. One factor affecting treatment of MAC disease is the presence of interconvertible colonial variants. Transparent (T) variants have greater resistance to antibiotics and higher pathogenicity; opaque (O) variants are more susceptible to antibiotics and less pathogenic. The overall goal of this study was to investigate the mechanism for colonial variation. Based on an observation that T variants of M. intracellulare strain Va14 contained a plasmid which was 6 kb smaller than the 68 kb plasmid in O variants, it had been suggested that a transposable element might be responsible for colonial variation. The first objective was to clone the unique DNA fragment present in the 68 kb plasmid but absent from the 62 kb plasmid. The second and third objectives were to determine if the unique fragment contained a transposable element and to analyze the role of that element in the mechanism of colonial variation in M. intracellulare strain Va14. The fourth objective was to determine the distribution of IS1141 in MAC isolates. Fragments containing copies of the putative element were sequenced and a region 1596 basepairs in length with 23 basepair imperfect inverted repeats was designated as insertion sequence IS1141. IS1141 is the first insertion sequence identified in M. intracellulare. Data base searches using open reading frames (ORF) of IS1141, identified ORFb as significantly similar to the transposases of the IS3 family. The presence or absence of IS1141 in strain Va14 plasmids appeared unrelated to colonial variation, but IS1141 was present in another plasmid and the chromosome of the Va14 variants. Hybridization studies with IS1141 identified three chromosomal copies in O variants and two chromosomal copies in T variants. Va14 T variants each had a common IS1141 restriction fragment length polymorphism (RFLP) pattern which was different than the single RFLP pattern found in opaque variants. Based on these differences, it appears that IS1141 may integrate into the gene(s) responsible for the T phenotype preventing their expression. A survey of 64 James River basin non-AIDS, clinical and James River environmental MAC isolates identified 4 of 24 (17%) M. intracellulare isolates as containing IS1141. IS1141 has not been detected in any clinical or environmental M. avium or Mycobacterium species X isolates and may be limited to M. intracellulare. / Ph. D.

LD5655.V856 1993.V53

AIDS (Disease)

HIV (Viruses)

Mycobacterium avium

Mycobacterium intracellulare

Investigating the localisation of the ESX-3 secretion system in Mycobacterium smegmatis

Steyn, Natassja Lise

12 1900

Thesis (MScMedSc)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: Mycobacterium tuberculosis is a pathogenic organism that infects a third of the world’s population and causes approximately 2 million deaths per year. Extensive research has been done on this pathogen, however our knowledge of the mechanisms of pathogenicity remain limited. The M. tuberculosis genome contains five ESAT-6 gene cluster regions, ESX-1 to 5, which encode specialized type VII secretion systems. These secretion systems are known to secrete members of the ESAT-6/CFP-10 and PE/PPE protein families, some of which contribute to the pathogenicity and phagosomal escape of the pathogen. ESX-3 has been shown to be essential for in vitro growth and survival of M. tuberculosis. The expression of ESX-3 in M. tuberculosis is regulated by IdeR and Zur, in response to intracellular iron and zinc concentrations, respectively. Interestingly, ESX-3 is not essential for the growth and survival of the saprophytic organism M. smegmatis. In this study, we aimed to identify the subcellular localisation of the individual components of the ESX-3 secretion system in the non-pathogenic, fast-growing organism M. smegmatis. The esx conserved component (ecc) genes from ESX-3 were expressed from the episomal expression vector pDMNI as fusion proteins with green fluorescent protein (GFP). MSMEG_0615 (eccA3), MSMEG_0616 (eccB3), MSMEG_0623 (eccD3) and MSMEG_0626 (eccE3) were successfully cloned into pDMNI and expression of fusion proteins was confirmed by Western blotting for MSMEG_0615-GFP, MSMEG_0616-GFP and MSMEG_0626-GFP in M. smegmatis. In the M. smegmatis ESX-3 knock-out (with MSMEG_0615 to MSMEG_0626 deleted) expression was confirmed for MSMEG_0615-GFP and MSMEG0626-GFP. Fluorescent microscopy determined that MSMEG_0615-GFP localised to a single mycobacterial pole in both strains. MSMEG_0616-GFP and MSMEG_0626-GFP were found to be membrane associated in M. smegmatis, while MSMEG_0626-GFP was found to be membrane associated in the M. smegmatis ESX-3 knock-out. The unipolar localisation of MSMEG_0615-GFP suggests that the assembled ESX-3 secretion system apparatus is situated at a single pole in M. smegmatis. Therefore, we hypothesize that MSMEG_0615 might act as a recruiter protein that is involved in the assembly of ESX-3 at the mycobacterial pole. / AFRIKAANSE OPSOMMING: Mycobacterium tuberculosis is ‘n patogene organisme wat ‘n derde van die wêreld se bevolking infekteer en eis jaarliks 2 miljoen lewens deur tuberkulose. Ten spyte van uitgebreide navorsing, is daar min kennis oor die meganismes van patogenisiteit van hierdie organisme. Die M. tuberculosis genoom bevat vyf duplikasies van die ESAT-6 geen groep gebiede, ESX-1 tot 5, wat kodeer vir gespesialiseerde Tipe VII sekresie sisteme. Hierdie sekresie sisteme is bekend vir die sekresie van lede van die ESAT-6/CFP-10 en PE/PPE proteïen families, waarvan sommige bydra tot die patogenisieit en fagosomale ontsnapping van hierdie organisme. ESX-3 is noodsaaklik vir die in vitro groei en oorlewing van M. tuberculosis. Die uitdrukking van ESX-3 in M. tuberculosis word gereguleer deur IdeR en Zur in reaksie op intrasellulêre yster en sink konsentrasies, onderskeidelik. ESX-3 word nie benodig vir die groei en oorlewing van die saprofitiese organisme M. smegmatis nie. Hierdie studie was gemik om die sub-sellulêre lokalisering van ESX-3 te identifiseer in die niepatogeniese en vinnig-groeiende organisme, M. smegmatis. Die “esx conserved component” (ecc) gene van ESX-3 is uitgedruk vanaf die episomale uitdrukkingsvektor pDMNI as gekombineerde proteïene met die groen fluoreserende proteïen (GFP). MSMEG_0615 (eccA3), MSMEG_0616 (eccB3), MSMEG_0623 (eccD3) en MSMEG_0626 (eccE3) is suksesvol gekloneer en die uitdrukking van die gekombineerde proteïene is bevestig deur Western oordrag vir MSMEG_0615-GFP, MSMEG_0616-GFP en MSMEG_0626-GFP in M. smegmatis. In die M. smegmatis ESX-3 uitklopmutant (met MSMEG_0615 tot MSMEG_0626 uitgeslaan) is uitdrukking bevestig vir MSMEG_0615-GFP en MSMEG0626-GFP. Fluoresensie mikroskopie het bepaal dat MSMEG_0615-GFP gelokaliseer is by ‘n enkele mikobakteriese pool in beide stamme. MSMEG_0616-GFP en MSMEG_0626-GFP was membraan-geassosieerd in M. smegmatis, terwyl en MSMEG_0626-GFP geassosieer het met die membraan in die M. smegmatis uitklopmutant. MSMEG_0615 het gelokaliseer by ‘n enkele pool in M. smegmatis en dit dui aan dat die saamgestelde ESX-3 sekresie sisteem apparaat slegs by ‘n enkele pool voorkom in M. smegmatis. Ons hipotiseer dat MSMEG_0615 dalk mag optree as ‘n werwer proteïen wat betrokke is by die samestelling van die ESX-3 sekresie sisteem by die mikrobakteriese pool. / Stellenbosch University

Mycobacterium tuberculosis

Pathogenic organisms

ESX-3

Mycobacterium smegmatis

ESX-3 secretion system

Theses -- Medicine

Dissertations -- Medicine

Mycobacterium smegmatis

Processing Of DNA Recombination And Replication Intermediates By Mycobacterium Tuberculosis RuvA And RuvB Proteins

Khanduja, Jasbeer Singh

02 1900

Homologous recombination (HR) is a highly conserved cellular process involved in the maintenance of chromosomal integrity and generation of genetic diversity. Biochemical and genetic studies have suggested that HR is crucial for repair of damaged DNA arising from various endogenous or exogenous assaults on the genome of any organism. Further, HR is vital to repair fatal DNA damage during DNA replication. An instructive example of cross-talk between the processes of DNA recombination and replication can be construed in the processing of replication/recombination/repair intermediates. The impediment(s) to the progression of DNA replication fork is one of the underlying causes for increased genome instability and consequently this might compromise the survival of organism. Various processes manifest at stalled replication forks before they can be rendered competent for the replication-restart. One of the mechanisms of replication-restart involves replication fork reversal (RFR), which envisage unwinding of the blocked forks with simultaneous annealing of the parental and daughter strands o generate a Holliday junction intermediate adjacent to DNA double strand end. Genetic evidence shows that in E. coli dnaEts mutant, holD mutant and in helicase defective rep mutant, RFR is catalyzed by RuvAB complex. Classically, HJ intermediates are generated during the terminal stages of the HR pathway. In E. coli, branch migration and resolution of HJ intermediates is promoted by RuvA, RuvB and RuvC proteins, which participate at the late stages of HR. Structural, biochemical and mutational analysis suggest that E. coli RuvA binds Holliday junction DNA with high affinity and specificity. RuvB, a member of the AAA+ (ATPase associated with various cellular activities) family, is recruited to the RuvA-Holliday junction complex and functions as a motor protein. Together, RuvA and RuvB catalyze ATP dependent branch migration of HJ. The resolution of HJ is catalyzed by the RuvC endonuclease, which introduces coordinated cuts at two symmetrical sites across the junction. RuvAB complex, the Holliday junction branch migration apparatus, is ubiquitous in bacteria. Genetic, biochemical and structural studies have not only established the in vivo role of E. coli RuvAB, in context of HR pathway, but have also provided valuable insights into the mechanism of HJ processing by RuvAB complex. However, the paucity of extensive studies examining the biochemical properties of each member of the RuvABC protein complex restricts models in deciphering the functions of the individual components of this tripartite protein complex. Our current understanding of the biochemical function of E. coli RuvA is within the context of its interacting cellular partner, RuvB. Consequently, the inherent activities of RuvA in the context of DNA repair and HR are poorly understood. Moreover, it remains to be ascertained if RuvABC protein complex, its different sub-complexes, or the individual subunits can function differently in the processing of HJ intermediates generated during DNA repair and HR. The information from these studies would be helpful in understanding the mechanistic details of HR pathway in mycobacteria. Additionally, a number of important questions regarding the molecular basis of RuvAB catalyzed fork reversal remain unanswered. Therefore, exploration of biochemical details of the RuvAB mediated RFR would provide mechanistic insights into the dynamics of fork reversal process. Moreover, analysis of RuvAB catalyzed RFR might be helpful in validating the different assumptions of the RFR model that has been proposed on the basis of genetic analysis of certain E. coli replication mutants. Another interesting question that remains to be answered is, how under in vivo conditions, RuvABC protein complex or its individual subunits are regulated to function differently in the context of HR and DNA repair? Mycobacterium tuberculosis is an important intracellular pathogen which is likely to experience substantial DNA damage inside the host and thus may require an efficient DNA recombination and repair machinery for its survival. Our knowledge about the mechanistic aspects of genetic exchange in mycobacteria is rather limited. Therefore, understanding of the processes catalyzed by the components of HR pathway may help in molecular genetic analysis of mycobacteria. Sequence analysis of M. tuberculosis genome, followed by various comparative genomic studies, has revealed the presence of putative homologs of E. coli rec genes but it is not known whether these gene products are able to catalyze the reactions similar to their E. coli counterparts. In M. tuberculosis, the genes encoding for the enzymatic machinery required for branch migration and resolution of HJ intermediates are present. The ruvA, ruvB and ruvC genes form an operon, and are probably translationally coupled. Further, these ruv genes are DNA damage inducible. The transcript level of ruvC is regulated by both RecA dependent and independent mechanisms whereas ruvA and ruvB are induced only through RecA dependent SOS response. During M. tuberculosis infection of host cells, expression of ruvA and ruvB genes is upregulated. We therefore surmise that their gene product might be required for DNA replication, recombination or repair, and would be physiologically relevant under in vivo conditions. However, the details of reactions involved in the processing of HR intermediates and rescue of stalled replication forks in M. tuberculosis remains unknown. In the initial part of this study, we have investigated the function of M. tuberculosis RuvA protein using Holliday junctions containing either homologous or heterologous core. In the later part, we have explored the ability of M. tuberculosis RuvA and RuvB proteins to catalyze in vitro replication fork reversal. M. tuberculosis ruvA gene was isolated by PCR amplification and cloned in an expression vector to generate the pMTRA construct. Genetic complementation assays, using the pMTRA construct transformed into E. coli ΔruvA mutant, indicated that M. tuberculosis ruvA is functional in E. coli and suggested that it can substitute for E. coli RuvA in conferring resistance to MMS and survival following UV irradiation. Having established the functionality of M.tuberculosis ruvA, a method was developed for heterologous over-expression and purification of M. tuberculosis RuvA protein (MtRuvA). MtRuvA was purified to homogeneity and the identity of purified protein was verified using western blot analysis using the anti-MtRuvA antibodies. Purified MtRuvA was free of any contaminating endo- or exo-nuclease activity. Biochemical functions of MtRuvA were defined by performing detailed investigations of DNA-binding and Holliday junction processing activities. Substrate specificity of purified MtRuvA was examined,through DNA binding assays, by using oligonucleotide substrates mimicking differentintermediates involved in the pathway of recombinational DNA repair. Purified M. tuberculosis RuvA exhibited high affinity for HJ substrate but also formed stable complex with replication fork and flap substrate. DNase I footprinting of MtRuvA-homologous Holliday junction complex confirmed that MtRuvA bound at the junction center. The DNase I protection conferred by MtRuvA, on homologous HJ, was two-fold symmetric; the continuous footprint was 10 bp longon one pair of symmetrical arms and 7 bp on the opposite pair of arms. In parallel, DNase footprinting of MtRuvA-heterologous Holliday junction complex generated a footprint that encompassed 16 nucleotide residues on each strand of the Holliday junction. Different crystallographic studies have envisaged an important role for RuvA in base pair rearrangement atthe center of the junction. Also, in crystal structure of tetramer of EcRuvA-HJ complex twobases at the junction center were unpaired. To explore if RuvA binding leads to helical distortionof Holliday junction, MtRuvA-HJ complexes were subjected to chemical probing with KMnO4.In case of heterologous HJ, binding of MtRuvA resulted in appearance of sensitive T residues at the junction crossover. By contrast, binding of MtRuvA to homologous HJ rendered the T residues at the junction center and within the homologous core sensitive to oxidation by KMnO4.Taken together, these observations suggested that binding of MtRuvA distorts two base pairs at the junction crossover in heterologous HJ, whereas in case of homologous HJ base pairs distortion extends into the arms of the junction. These observations with KMnO4 probing were independently validated, in real time, by using sensitive to 2-aminopurine fluorescence spectroscopy measurements of MtRuvA-HJ complexes. To follow structural distortions upon interaction with MtRuvA, HJ variants carrying 2-AP substitution were generated for both homologous and heterologous HJ substrate. In each junction species, the 2-AP residue was uniquely present either at the junction center, adjacent to the center or away from the center. Incase of heterologous HJ, binding of MtRuvA resulted in increase of fluorescence emission of2-AP residues located at the junction crossover but not those of 2-AP residues that were present1-2 base pairs away from the junction center. Binding of MtRuvA to homologous HJ resulted in increase of fluorescence emission of 2-AP residues located at the junction crossover. Further, increase in fluorescence emission was also observed for 2-AP residues present within the homologous core or adjacent to the homologous core in a pair of symmetrically related arms. Thus, 2-AP fluorescence results suggested that binding of MtRuvA to homologous HJ causes base pair distortion within and adjacent to the homologous core whereas in case of heterologous HJ the base pair distortion is restricted to the junction center. Together, these results suggest thatMtRuvA causes two distinct types of base pair distortions between homologous and heterologous HJ substrates. To explore the relationship between binding of MtRuvA and alterations in global structure of the junction DNA, we employed the established technique of comparative gel electrophoresis. Analysis of data from comparative gel electrophoresis revealed that MtRuvA, upon binding to the Holliday junctions, converts the stacked-X structure of HJ to square-planar form and stabilizes the same for loading of RuvB rings and subsequent branch migration by RuvAB complex. Our results underline the possible existence of distinct pathways for RuvA function, which presumably depend on the structure and the nature of the DNA repair or HR intermediates. In summary, our results show that binding of MtRuvA to the HJ induced changes in the local conformation of junction, which might augment RuvB catalyzed branch migration. An unexpected finding is the observation that MtRuvA causes two distinct types of structural distortions, depending on whether the Holliday junction contains homologous or heterologous core. These observations support models wherein RuvA facilitates, in a manner independent of RuvB, base pair rearrangements at the crossover point of both homologous and heterologous Holliday junctions. Although the genetic basis of ruvA ruvB catalyzed RFR in E. coli has been understood in some detail but less is known about the genetic and molecular mechanism of fork reversal in mycobacteria or other organisms. Specifically, to examine if the E. coli paradigm can be generalized to other RuvAB orthologs, we explored the RFR activity of M. tuberculosis RuvAB using a series of oligonucleotides and plasmid-based substrates that mimic stalled replication fork intermediates. This approach might be useful in genetic analysis of factors involved in processing of stalled forks in M. tuberculosis wherein technical difficulties associated with the isolation and characterization of appropriate mutants have limited our understanding of DNA metabolism. Importantly, we have asked the questions as to how the structure at fork junction, extent of reversal and presence of sequence heterology might determine the outcome of RuvAB mediated RFR. The results from this study will be helpful in consolidating the proposed in vivo role for RuvAB complex in fork reversal. The open reading frame corresponding to M. tuberculosis ruvB gene was PCR amplified and cloned in an expression vector to generate the pMTRB construct. Genetic complementation assays were performed to assess the functionality of M. tuberculosis ruvB in E. coli ΔruvB mutant. The data from these assays suggested that M. tuberculosis ruvB is active in E. coli and it is able to make functional contacts with E. coli RuvA. Moreover, the efficient alleviation of MMS toxicity in E. coli ΔruvB mutant suggested that M. tuberculosis ruvB might have a role in relieving replication stress generated under specific in vivo conditions. For biochemical analysis, M. tuberculosis RuvB protein (MtRuvB) was over-expressed in a heterologous system and purified to homogeneity. The identity of purified MtRuvB was verified using western blot analysis using the anti-MtRuvB antibodies. Purified MtRuvB was free of any contaminating endo- or exo- nuclease activity. The DNA-binding properties of MtRuvB were analyzed, in conjunction with its cognate RuvA, by using different substrates that are most likely to occur as intermediates during the processes of DNA replication and/or recombination. MtRuvAB bound HJ, three-way junction and heterologous replication fork with high affinity but with relatively weaker affinity to flap and flayed duplex substrates. MtRuvB displayed very weak affinity for linear duplex and failed to bind linear single-stranded DNA. The high affinity of MtRuvB for HJ substrate, in presence of its cognate RuvA, is indicative of direct and functional interaction between RuvA and RuvB. To further test this idea, the catalytic activity of MtRuvB was assayed in the in vitro HJ branch migration assay. In this assay,MtRuvB, in association with its cognate RuvA, promoted efficient branch migration of homologous HJ over heterologous HJ. To decipher the role of MtRuvAB in processing of stalled replication fork we performed in vitro replication fork reversal (RFR) assay using both oligonucleotide and plasmid based model replication fork substrates. Initially, binding of MtRuvAB to different homologous fork (HomFork) substrates was analyzed using the electrophoretic mobility shift assays. MtRuvAB exhibited similar binding affinity towards different HomFork substrates bearing different spatial orientation of nascent leading and lagging strands. To gain insight into the role of MtRuvAB in processing of replication forks, in vitro RFR reactions were carried out using an array of synthetic homologous fork substrates. In all these reactions, MtRuvAB catalyzed efficient fork reversal leading to generation of both parental duplex and daughter duplex. In the kinetics of fork reversal reaction, for all the fork substrates,the accumulation of daughter duplex increased with time whereas the increase in parental or nascent strand DNA was negligible. Taken together, our results suggest that MtRuvAB can efficiently catalyze in vitro replication fork reversal reaction to generate a Holliday junction intermediate thus implicating that RuvAB mediated fork reversal involves concerted unwinding and annealing of nascent leading and lagging strands. Equally important, we demonstrate the reversal of forks carrying hemi-replicated DNA, thus indicating that MtRuvAB mediated fork reversal is independent of symmetry at the fork junction. For understanding the role of RuvAB mediated processing of stalled forks at chromosome level, the fork reversal assays were performed using plasmid derived model “RF” substrate. Fork reversal was monitored by restriction enzyme digestion mediated release of 5’ end labeled fragments of specific size from the fourth arm extruded at the branch point of fork junction. In these reactions MtRuvAB complex was proficient at generating the reversed arm de novo from the RF substrate. Further, MtRuvAB complex catalyzed extensive fork reversal as analyzed by release of linear duplex of2.9 kb from a JM substrate. Use of non hydrolysable analogs of ATP and analysis of restriction digestion mediated release of duplex fragments from the reversed arm suggested that MtRuvAB catalyzed RFR reaction is ATP hydrolysis dependent progressive and processive reaction. MtRuvAB complex catalyzed fork reversal on plasmid substrate that had been linearized thus indicating that MtRuvAB mediated RFR is uncoupled from DNA supercoils in the substrate. Notably, MtRuvAB promoted reversal of forks in a substrate containing short stretch of heterologous sequences, indicating that sequence heterology failed to impede fork reversal activity of MtRuvAB complex. These results are discussed in the context of recognition and processing of varied types of replication fork structures by RuvAB enzyme complex.

DNA Recombination

Mycobacterium Tuberculosis

Homologous Recombination (HR)

Mycobacterium Tuberculosis RuvA Protein

Mycobacterium Tuberculosis RuvB Protein

DNA Replication

Holliday Junctions

M. tuberculosis

Biochemical Genetics

Detection and transmission of Mycobacterium marinum and Mycobacterium chelonae in zebrafish (Danio rerio)

Peterson, Tracy Shawn

02 April 2015

Mycobacteriosis is a common disease of laboratory zebrafish (Danio rerio). Different infection patterns occur in zebrafish depending on mycobacterial species. Mycobacterium marinum and M. haemophilum produce virulent infections associated with high mortality, whereas M. chelonae is more wide spread and not associated with high mortality. Identification of mycobacterial infections to the species level provides important information for making management decisions. Observation of acid-fast bacilli in histological sections or tissue imprints is the most common diagnostic method for mycobacteriosis in fish, but only allows for diagnosis to the genus level. Mycobacterial culture, followed by molecular or biochemical identification is the traditional approach for species identification, but recently it has been shown that DNA of diagnostic value can be retrieved from paraffin blocks. Type of fixative, time in fixative before processing, species of mycobacteria, and severity of infection were investigated as parameters to determine if the hsp gene PCR assay (primer set HS5F/hsp667R) could detect and amplify mycobacterial DNA from paraffin-embedded zebrafish. Whole zebrafish were experimentally infected with either M. chelonae or M. marinum, and then preserved in 10% neutral buffered formalin or Dietrich's fixative for 3, 7, 21 and 45 days. Subsequently, fish were evaluated by H&E and Fite's acid-fast stains to detect mycobacteria within granulomatous lesions. The PCR assay was quite effective, and obtained PCR product from 75% and 88% of the M. chelonae and M. marinum infected fish, respectively. Fixative type, time in fixative, and mycobacterial species showed no statistical relationship with the efficacy of the PCR test. Regarding natural transmission, zebrafish are capable of contracting mycobacterial infections by feeding on infected fish tissue, but other natural routes have not been clearly elucidated. Free living amoebae have been shown to be vectors for mycobacteria and their virulence is enhanced when residing in these protozoans. Paramecium caudatum are commonly used as a first food for zebrafish, and I investigated this ciliate's potential to serve as a vector of Mycobacterium marinum and M. chelonae. The ability of live P. caudatum to transmit these mycobacteria to larval, juvenile and adult zebrafish was evaluated. Infections were defined by histologic observation of granulomas containing acid-fast bacteria in extraintestinal locations. In both experiments, fish fed paramecia containing mycobacteria became infected at a higher incidence than controls. Larvae (exposed at 4 days post hatch) fed paramecia with M. marinum exhibited an incidence of 30% (24/80) and juveniles (exposed at 21 days post hatch) showed 31% incidence (14/45). Adult fish fed gelatin diets containing bacteria within paramecia or mycobacteria alone for 2 wk resulted in infections when examined 8 wk after exposure: M. marinum OSU 214; in paramecia 47% (21/45; 3.5 x 10⁵ dose/fish/day), M. marinum CH in paramecia 47% (9/19; 3.6 x 10⁵ dose/fish/day), M. chelonae in paramecia 38% (5/13; 3.5 x 10⁵ dose/fish/day). I investigated the ability of mycobacteria to persist within paramecia, as this has previously been demonstrated in amoebae. Gram negative bacteria ingested by paramecia were processed within an hour. In contrast, I determined using GFP-labeled Mycobacterium marinum that mycobacteria can persist within paramecia digestive vacuoles. The concentration of M. marinum at 1 hour was similar to that at the time of ingestion. Twenty-four hours post-ingestion and later there was significant decline in M. marinum concentrations compared to time of ingestion, but M. marinum continued to persist inside digestive vacuoles for up to one week. My results demonstrate for the first time that Paramecium caudatum can act as a vector for mycobacteria. This provides a useful animal model for evaluation of natural mycobacterial infections and demonstrates the possibility of mycobacterial transmission in zebrafish facilities via contaminated paramecia cultures. / Graduation date: 2013 / Access restricted to the OSU Community at author's request from April 2, 2013 - April 2, 2015

Zebrafish

Mycobacteria

PCR

Paraffin-embedded

Paramecia

Mycobacterium chelonae

Zebra danio -- Diseases -- Diagnosis

Zebra danio -- Diseases -- Transmission

Mycobacterial diseases -- Diagnosis

Mycobacterial diseases -- Transmission

Mycobacterium

Mycobacterium marinum

Structural Studies On Mycobacterium Smegmatis Dps Molecules

Roy, Siddhartha

09 1900

Oxidative stress is a universal phenomenon experienced by both aerobic and anaerobic organisms. Reactive oxygen species (ROS) are generated during the stress, which can damage most cellular components including proteins, lipids and DNA. Naturally, organisms have evolved defence mechanisms to prevent oxidative damage. In prokaryotic systems, Dps (DNA binding protein from stationary phase cells) forms an important component of the mechanisms. Dps is known to be produced maximally during the stationary phase of bacterial growth. They exhibit ferroxidase activity as well. Dps homologs have been identified in a variety of distantly related bacteria, thus implying that this protein has a crucial function. The crystal structures of these proteins from a few bacteria are available. The work reported here is concerned with structural studies on Dps molecules from Mycobacterium smegmatis. Well-established X-ray crystallographic techniques were used to study the structures reported here. Hanging drop vapour diffusion and microbatch methods were used for crystallization. X-ray intensity data were collected on MAR Research imaging plates mounted on Rigaku X-ray generators. The data were processed using the HKL program suite. All the structures were solved by the molecular replacement method using the programs AMoRe and PHASER. Structure refinements were carried out using the programs CNS and REFMAC. Model building was carried out using FRODO and COOT. PROCHECK, ALIGN, INSIGHT, NACCESS, HBPLUS, CONTACT and ESCET were used for validation and analysis of the refined structures. Figures were prepared using MOLSCRIPT, BOBSCRIPT, RASTER3D and PYMOL. The structure of the first Dps identified in M. smegmatis has been determined in three crystal forms and has been compared with those of similar proteins from other sources. The dodecameric molecule can be described as a distorted icosahedron. The interfaces among subunits are such that the dodecameric molecule appears to have been made up of stable trimers. The situation is similar in the proteins from Escherichia coli and Agrobacterium tumefaciens, which are closer to the M. smegmatis protein in sequence and structure than those from other sources, which appear to form a dimer first. Trimerisation is aided in the three proteins by the additional N-terminal stretches they possess. The M. smegmatis protein has an additional C-terminal stretch compared to other related proteins. The stretch, known to be involved in DNA binding, is situated on the surface of the molecule. A comparison of the available structures permits a delineation of the rigid and flexible regions in the molecule. The subunit interfaces around the molecular dyads, where the ferroxidation centres are located, are relatively rigid. Regions in the vicinity of the acidic holes centred around molecular threefold axes, are relatively flexible. So are the DNA binding regions. The crystal structures of the protein from M. smegmatis confirm that DNA molecules can occupy spaces within the crystal without disturbing the arrangement of the protein molecules. However, contrary to earlier suggestions, the spaces need not to be between layers of the protein molecules. The cubic form provides an arrangement in which grooves, which could hold DNA molecules, criss-cross the crystal. M. smegmatis Dps is characterised by a 26 residue C-terminal tail which has been shown to be involved in DNA binding. The protein spontaneously degrades into a species in which 16 C-terminal residues are cleaved away. This species does not bind DNA, but forms dodecamers. A second species in which all the 26 residues constituting the tail were deleted not only does not bind to DNA, but also fails to assemble into dodecamers, indicating a role in assembly also for the C terminal tail. Therefore, the crystal structure of the species without the entire C-terminal tail was carried out. The molecule of the C-terminal mutant has an unusual open decameric structure, resulting from the removal of two adjacent subunits from the original dodecameric structure of the native form. It has been earlier shown that a Dps dodecamer could assemble with a dimer or one of two trimers (Trimer-A and Trimer-B) as intermediate and that Trimer-A is the intermediate species in the M. smegmatis protein. Estimation of surface area buried on trimerisation indicates that association within Trimer-B is weak. It further weakens when the C-terminal tail is removed, leading to the disruption of the dodecameric structure. Thus, the C-terminal tail has a dual role, one in DNA binding and the other in the assembly of the dodecamer. M. smegmatis Dps also has a short N-terminal tail of 9 residues. A species with this tail deleted, forms trimers in solution, but not dodecamers unlike wild type M. smegmatis Dps, under the same conditions. The crystal structure of this N-terminal mutant was also determined. Unlike in solution, the N-terminal mutant forms dodecamers in the crystal. In native Dps, the N-terminal stretch of one subunit and the C-terminal stretch of a neighbouring subunit lock each other into ordered positions. The deletion of one stretch results in the disorder of the other. This disorder appears to result in the formation of a trimeric species of the N-terminal deletion mutant contrary to the indication provided by the native structure. The ferroxidation site is intact in the mutants. A second DNA binding protein from stationary phase cells of M. smegmatis (MsDps2) has been identified from the bacterial genome and its crystal structure determined. The core dodecameric structure of MsDps2 is the same as that of the Dps from the organism described earlier (MsDps1). However, MsDps2 possesses a long N-terminal tail instead of the C-terminal tail in MsDps1. This tail appears to be involved in DNA binding. It is also intimately involved in stabilizing the dodecamer. Partly on account of this factor, MsDps2 assembles straightway into the dodecamer while MsDps1 does so on incubation after going through an intermediate trimeric stage. The ferroxidation centre is similar in the two proteins while the pores leading to it exhibit some difference. The mode of sequestration of DNA in the crystalline array of molecules, as evidenced by the crystal structures, appears to be different in MsDps1 and MsDps2, highlighting the variability in the mode of Dps-DNA complexation. A sequence search led to the identification of 300 Dps molecules in bacteria with known genome sequences. 50 bacteria contain 2 or more types of Dps molecules each, while 195 contain only one type. Some bacteria, notably some pathogenic ones, do not contain Dps. A sequence signature for Dps could also be derived from the analysis In addition to the work on Dps molecules, the author was also involved in studies on the crystal structures of the adipic acid complexes of L- and DL-arginine and supramolecular association in arginine-dicarboxylic acid complexes. This investigation, carried out primarily to obtain a good grounding in crystallography, is presented in an appendix.

Mycobacterium Smegmatis

Molecular Biology

DNA Binding Proteins

DNA Binding

Oxidative Stress

Dps

MsDps1

MsDps2

Structural Biology

Structure-Function Correlative Studies On The Biochemical Properties (Polymerisation, GTP binding, GTPase) Of Mycobacterial Cytokinetic Protein FtsZ In Vitro

Gupta, Prabuddha

02 1900

FtsZ, the principal cell-division protein, polymerizes in GTP-dependent manner in vitro (Bramhill and Thompson, 1994; Mukherjee and Lutkenhaus, 1994; Rivas et al., 2000). FtsZ polymerization at the mid-cell site of bacterium leads to formation of a guiding scaffold, the Z-ring, for bacterial cytokinesis (Bi and Lutkenhaus, 1991; Sun and Margolin, 1998). GTP-induced polymerization process of FtsZ can be monitored in vitro Using 90º light scattering (Mukherjee and Lutkenhaus, 1999) and polymers formed can be visualized using transmission electron microscopy (Lu and Erickson, 1998) or quntitated in terms of the amount of FtsZ polymer pelleted during ultracentrifugation (Mukherjee and Lutkenhaus, 1998). The research work presented in this thesis focused on structure-function correlative analysis of Mycobacterium tuberculosis FtsZ(MtFtsZ0 and FtsZ proteins of Mycobacterium leprae (M1FtsZ), Mycobacterium smegmatis(MsFtsZ), and Streptomyces coelicolor (ScFtsZ) (as it is from Actinomycetes family to which mycobacteria belong) in vitro. It was initiated with investigation on the biochemical properties of Mycobacterium leprae FtsZ (M1FtsZ) in vitro. In comparison with those of MtFtsZ. Subsequently, the role of C-terminal stretch of amino acid residues of MtFtsZ in polymerization was investigated. Finally, a comparative analysis of the biochemical properties of MtFtsZ, MsFtsZ, and ScFtsZ was carried out in order to find out whether a correlation exists between the time taken by the FtsZ of a bacterium to polymerise and the generation time of the organism. The thesis is presented in five chapters. First Chapter gives an exhaustive introduction on the structure-function aspects of FtsZ. Second Chapter deals with materials used in this research work and details of various experimental methods [cloning and expression of FtsZ (White et. Al., 2000), decision and point mutagenesis, preparation of His-tag free MtFtsZ and M1FtsZ by thrombin cleavage method, 90º light scattering (Mukherjee and Lutkenhaus, 1999), White, et al., 2000), transmission electron microscopy (Lu and Erickson, 1998), pelleting assay for polymeric FtsZ (Mukherjee and Lutkenhaus, 1998), GTP-binding by UV-crosslinking (RayChaudhuri and Park, 1992; de Boer et al.,) GTPase assay(RayChaudhuri and Park, 1992); de Boer et al., 1992), Circular Dichroism (Saxena and Wetlaufer, 1971) and ANS fluorescence emission spectroscopy (Semisotnov, et al., 1991)]. The Chapters three to five contain all the data related to the research work, the outlines of which are given below. Chapter 3. Biochemical Characterisation of FtsZ Protein of Mycobacterium leprae In Comparison with the Biochemical Properties of FtsZ Protein of Mycobacteriulm tulberculosis In Vitro The major finding in this part of thesis work is on the demonstration that single reciprocal point mutation partially revives polymerization-inactive M1FtsZ and Inactivates polymerization-active MtFtsZ in vitro. In brief, soluble, recombinant M1FtsZ did not show detectable polymerization in vitro, in contrast to MtFtsZ, which showed appreciable polymerization, under standard conditions, when monitored using 90º light scattering assay and transmission electron microscopy. This was a surprising result, as M1FtsZ and MtFtsZ has 96% protein sequence identity. Mutation f T172 in the N-terminal domain of M1FtsZ to A172, as it exists in MtFtsZ, showed dramatic levels of polymerization in vitro. Reciprocal mutation of A172 in MtFtsZ to T172, as it exists in M1FtsZ, abolished polymerization in vitro. Further, M1FtsZ showed weak GTPase activity, in contrast to MtFtsZ, which showed appreciable GTPase activity. While T172A mutation enhanced GTPase activity of MtFtsZ in vitro. Circular dichroism spectroscopy and ANS fluorescence emission spectroscopy showed that there were no major secondary or tertiary structural changes in these point mutants. These observations demonstrate that the residue at position 172 plays a critical role in the polymerization of M1FtsZ and MtFtsZ, without appreciably affecting their respective GTpPase activity. Further, this result might have implications on evolution of a slow polymerizing FtsZ in slow growing bacteria. Further details of evolution related questions are addressed in Chapter 5. Chapter 4. Role of Carboxy Terminal Residues in the Biochemical Properties of FtsZ Protein of Mycobacterium tuberculosis In Vitro The major finding in this part of thesis work is the demonstration that the C-terminal end residues are critically required for polymerization of MtFtsZ in vitro, which is in direct contrast to the dispensability of C-terminal residues of Escherichia coli FtsZ(EcFtsZ), Bacillus subtilis FtsZ (BsFtsZ), and Pseudomonas aeruginosa (PaFtsZ) for polymerization. FtsZ protein from several bacterial species namely, Methanococcus jannaschii (MjFtsZ), Bacillus subtillis(BsFtsZ), Pseudomonas aeruginosa (PaFtsZ), and Aquifex aeolicus (AaFtsZ) (Lowe and Amos, 1998; Oliva et al., 2007), and Mycobacterium tuberculosis H37Rv (mtFtsZl Leung et al., 2004), whose crystal structures have been solved so far, were found to possess an N-terminal domain and a C-terminal domain that were connected to each other through a helix. The extreme C-terminal portion of all these FtsZ proteins is constituted by an unstructured tail (Lowe and Amos, 1998; Oliva et al., 2007l Leung et al., 2004), which is not found in the respective crystal structure of the protein. We examined whether C-terminal residues of soluble recombinant FtsZ of Mycobacterium tuberculosis (mtFtsZ) have any role in MtFtsZ polymerization in vitro. Deletion of C-terminal 66 residues (313-379) was found to abolish polymerization. Replacement of the C-terminal 66 residues with the extreme C-terminal 13-residue stretch (DDDDVDVPPFMRR) did not restore polymerization. Although the terminal R in DDDDVDVPPFMRR is dispensable for full-length MtFtsZ polymerization, the terminal R in DDDDVDVPPFMR is indispensable for polymerization. Neither replacement of this R, in the terminal R deletion mutant DDDDVDVPPFMR, with K/H/D/A residues enabled polymerization. GTP binding and GTPase activities of the mutants were partially affected. The indispensable nature of C-terminal residues for MtFtsZ polymerization in vitro is contrary to the dispensability of the equivalent extreme C-terminal residues of Escherichi coli, Pseudomonas aeruginosa, and Bacillus subtilis FtsZ (Wang et. Al., 1997; Cordell et al., 2003; Singh et al., 2007) for in vitro polymerization. The essentiality of C-terminal extreme residues of BtFtsZ for polymerization offers direction to design anti MtFtsZ polymerization agents. Chapter 5. An attempt to find correlation between Biochemical properties of FtsZ and Generation Time of the Bacterium The clue that there might be a correlation between FtsZ polymeristion and generation time of the bacterium came from the observation mentioned in chapter 3. The presence of polymerization-aversive T172 in the FtsZ of extremely slow-growing M. leprae 913.5 days generation time, Levy, 1970) and polymerization-favouring A172 in the FtsZ of M. tuberculosis(18hrs generation time, Patterson and Youmans, 1970). For a bacterium, which has short generation time, it might be conducive to have an FtsZ that will also polymerise fast. Conversely, for a bacterium, which has long generation, it might be conducive to have an FtsZ molecule that will polymerise slow. In this respect, a preliminary comparative study was carried out between the generation time of bacterial species, E. coli, Mycobacterium smegmatis, Streptomyces coelicolor, M leprae, and M. tuhberculosis and their respective FtsZ (EcFtsZ, MsFtsZ, M1FtsZ and MtFtsZ). Detailed biochemical characterization of EcFtsZ and MtFtsZ has already been reported in the literature. In this thesis work, biochemical characterisation of M1FtsZ(Chapter 3), ScFtsZ and MsFtsZ (in this Chapter) were carried out. E. coli, which has a generation time of 18-55 min(labrum, 1953), possesses FtsZ (EcFtsZ) that reaches steady state of polymerization in about 10 sec under standard conditions in vitro (Beamhill and Thompson, 1994), using 90º light scattering assay (Mukherjee and Lukenhaus, 1999). On the other hand, M. tuberculosis, which has a generation time of 18hrs in vivo (Patterson and Youmans, 1970) and 24 hrs in vitro (Hiriyanna and Ramakrishnan, 1986) possesses FtsZ (MtFtsZ) that reaches steady state of polymerization in about 6 min post-addiction of GTP in vitro (White et al., 2000). Further, M. leprae, which takes 13.5 days tp divide once in vivo (levy, 1970), possesses an FtsZ (M1FtsZ) that does not even show polymerization under standard conditions in vitro (Chapter 3 of this thesis). The organisms Mycobacterium smegmatis and Streptomyces coelicolor have generation times that fall in between those of the other three organisms mentioned above. While M. smegmatis divides once in 2-3 hrs (Husson, 1998), S. coelicolor has a variable generation time depending on growth condition, which can be as fast as once in 2.31 hours, depending upon growth conditions (Cox, 2004). We found ScFtsZ and MsFtsZ takes around 4 min to reach polymerization saturation after addition of GTP, EcFtsZ( 10 sec), MtFtsZ (10 min) and M1FtsZ (dose not polymerise in vitro) seem to indicate that there exists a correlation between polymerization saturation after addition of GTP, EcFtsZ (10sec), MtFtsZ (10 min) and M1FtsZ (does not polymerise in vitro) seem to indicate that there exists a correlation between polymerization saturation time and the generation time of the respective bacterium. But when we compared polymerization time of ScFtsZ and MsFtsZ (4 min both case) with MtFtsZ ( 6 min), we found that there is no linear correlation with generation time of these bacteria and the time taken by their FtsZ to reach steady state of polymerization. Many more bacterial FtsZ proteins need to be characterized to conclusively state wthether there exist a correlation between generation time of bacteria and the time taken for their FtsZ to reach steady state of polymeristion. Such correlation would simply reveal the fact that the primary structure of an FtsZ protein might have evolved to suit the generation time of the bacterium.

Protein

Polymerisation

GTP Binding

GT Pase

FtsZ Protein - Biochemical Properties

Mycobacterium Leprae FtsZ

Mycobacterium Tuberculosis FtsZ

FtsZ-Mycobacterial Cytokinetic Protein

Biochemistry

Role of Mycobacterium Tuberculosis RecG Helicase in DNA Repair, Recombination and in Remodelling of Stalled Replication Forks

Thakur, Roshan Singh

January 2015

Tuberculosis, caused by the infection with Mycobacterium tuberculosis remained as a major global health challenge with one third of world population being infected by this pathogen. M. tuberculosis can persist for decades in infected individuals in the latent state as an asymptomatic disease and can emerge to cause active disease at a later stage. Thus, pathways and the mechanisms that are involved in the maintenance of genome integrity appear to be important for M. tuberculosis survival, persistence and pathogenesis. Helicases are ubiquitous enzymes known to play a key role in DNA replication, repair and recombination. However, role of helicases in providing selective advantage for M. tuberculosis survival and genome maintenance is obscure. Therefore, understanding the role of various helicases could provide insights into the M. tuberculosis survival, persistence and pathogenesis in humans. This information could be useful in considering helicases as a novel therapeutic target as well as developing effective vaccines. The research focus of my thesis has been to understand the role of helicases in safeguarding the M. tuberculosis genome from various genotoxic stresses. The major focus of the current study has been addressed towards understanding the role of M. tuberculosis RecG (MtRecG) helicase in recombinational repair and in remodeling stalled replication forks. This study highlights the importance of RecG helicase in the maintenance of genome integrity via DNA repair, recombination and in remodeling the stalled replication forks in M. tuberculosis. The thesis has been divided into following sections as follows: Chapter I: General introduction that describes the causes and consequences of replication stress and DNA repair pathways in M. tuberculosis The genome is susceptible to various types of damage induced by exogenous as well as endogenous DNA damaging agents. Unrepaired or misrepaired DNA lesions can lead to gross chromosomal rearrangements and ultimately cell death. Thus, organisms have evolved with efficient DNA damage response machinery to cope up with deleterious effects of genotoxic agents. Accurate transmission of genetic information requires error-free duplication of chromosomal DNA during every round of cell division. Defects associated with replication are considered as a major source of genome instability in all organisms. Normal DNA replication is hampered when the fork encounters road blocks that have the potential to stall or collapse a replication fork. The types of lesions that potentially block replication fork include lesions on the template DNA, various secondary structures, R-loops, or DNA bound proteins. To understand the DNA damage induced replication stress and the role of fork remodeling enzymes in the repair of stalled replication forks and its restart, chapter I of the thesis has been distributed into multiple sections as follows: Briefly, initial portion of the chapter describes overall replication process in prokaryotes highlighting the importance of coordinated replisome assembly and disassembly during initiation and termination. Later section discusses about various types of exogenous and endogenous DNA damages leading to replication fork stalling. Subsequent section of chapter I provide detailed description and mechanism of various repair pathways cell operates to repair such damages. Chapter I further summarizes causes of stalled replication forks majorly including template lesions, natural impediments like DNA secondary structures and DNA-protein cross links. Subsequent section discusses various pathways of replication restart that include essential role of primosomal proteins in reloading replisome machinery at stalled replication forks. Subsequent section of chapter I provide a comprehensive description of replication fork reversal (RFR) and mechanism of replication restart. RFR involves unwinding of blocked forks via simultaneous unwinding and annealing of parental and daughter strands to generate Holliday junction (HJ) intermediate. Genetic and biochemical studies highlighted the importance of RecG, RuvAB and RecA proteins in driving RFR reaction in E. coli. Hence, in the subsequent chapter, the functional role of RecG, RuvAB and RecA in replication-recombination processes has been discussed. Last section of the chapter devotes completely to M. tuberculosis, its genome dynamics and the various pathways of mycobacterial DNA repair. M. tuberculosis experiences substantial DNA damage inside host macrophages owing to the acidic environment, reactive oxygen species (ROS) and reactive nitrogen intermediates (RNI) which are sufficient enough to cause replication stress. To gain insights into the role of M. tuberculosis RecG helicase in DNA repair, recombination and in remodeling the stalled replication forks the following objectives were laid for my PhD thesis: 1 To understand the functional role of M. tuberculosis RecG (MtRecG) in DNA repair and recombination. 2 To investigate the distinct role(s) of MtRecG, MtRuvAB and MtRecA in remodeling the stalled replication forks. Chapter II: Evidence for the role of Mycobacterium tuberculosis RecG helicase in DNA repair and recombination In order to survive and replicate in a variety of stressful conditions during its life cycle, M. tuberculosis must possess mechanisms to safeguard the integrity of the genome. Although DNA repair and recombination related genes are thought to play key roles in the repair of damaged DNA in all organisms, so far only a few of them have been functionally characterized in the tubercle bacillus. Helicases are one such ubiquitous enzyme involved in all DNA metabolic transaction pathways for maintenance of genome stability. To understand the role of M. tuberculosis RecG (MtRecG) helicase in recombination and repair, we carried out functional and biochemical studies. In our study, we show that M. tuberculosis RecG expression was induced in response to different genotoxic agents. Strikingly, expression of M. tuberculosis RecG in Escherichia coli ∆recG mutant strain provided protection against MMC, MMS and UV-induced cell death. Purified M. tuberculosis RecG exhibited higher binding affinity for the Holliday junction (HJ) as compared to a number of canonical recombinational DNA repair intermediates. Notably, although MtRecG binds at the core of the mobile and immobile HJs, and with higher binding affinity for the immobile junction, branch migration and resolution was evident only in the case of the mobile junction. Furthermore, immobile HJs stimulate MtRecG ATPase activity less efficiently as compared to the mobile HJs. In addition to HJ substrates, MtRecG exhibited binding affinity for a variety of branched DNA structures including three-way junctions, replication forks, flap structures, forked duplex and a D-loop structures, but demonstrated strong unwinding activity on replication fork and flap DNA structures. Altogether, these results support that MtRecG plays an important role in processes related to DNA metabolism under normal as well as in stress conditions. Chapter III: Mycobacterium tuberculosis RecG but not RuvAB or RecA is efficient at remodeling the stalled replication forks: Implications for multiple mechanisms of replication restart in mycobacteria Aberrant DNA replication, defects in the protection and restart of stalled replication forks are a major cause of genome instability in all organisms. Replication fork reversal is emerging as an evolutionarily conserved physiological response for restart of stalled forks. Escherichia coli RecG, RuvAB and RecA proteins have been shown to reverse the model replication fork structures in vitro. However, the pathways and the mechanisms by which Mycobacterium tuberculosis, a slow growing human pathogen responds to different types of replication stress and DNA damage is unclear. In our study, we show that M. tuberculosis RecG rescues E. coli ∆recG cells from replicative stress. The purified M. tuberculosis RecG (MtRecG) and RuvAB (MtRuvAB) proteins catalyze fork reversal of model replication fork structures with and without leading strand ssDNA gap. Interestingly, SSB suppresses the MtRecG and MtRuvAB mediated fork reversal with substrates that contain lagging strand gap. Notably, our comparative studies with fork structures containing template damage and template switching mechanism of lesion bypass reveal that MtRecG but not MtRuvAB or MtRecA is proficient in driving the fork reversal. Finally, unlike MtRuvAB, we find that MtRecG drives efficient reversal of forks when fork structures are tightly bound by protein. These results provide direct evidence and valuable insights into the underlying mechanism of MtRecG catalyzed replication fork remodeling and restart pathways in vivo.

Mycobacterium Tuberculosis

DNA Replication

DNA Repair

DNA Helicases

DNA Damage

Genomic Instability

Mycobacterium Tuberculosis RecG Helicase

DNA Recombination

M. tuberculosis Genome

Mycobacterium tuberculosis RecG

G4 DNA

Biochemistry

Mechanistic And Functional Insights Into Mycobacterium Bovis BCG Induced Expression Of Cyclooxygenase-2 : Implications For Immune Evasion Strategies

Bansal, Kushagra

07 1900

Mycobacteria are multifaceted pathogens capable of causing both acute disease as well as an asymptomatic latent infection. Protective immunity against pathogenic mycobacteria depends principally on cell-mediated immunity executed by efficient anti-infectious functions of type 1 T helper (Th1) subset of CD4+ T cells. The polarization of Th1 responses is orchestrated by IL-12 secreted by antigen presenting cells (APCs) such as macrophages and dendritic cells (DCs). A hallmark of Th1 type CD4+ T cells is the production of IFN-γ that activates plethora of innate cell-mediated immunity. It is well known that cytokines such as IFN-γ, IL-12 and TNF-α are required for control of mycobacterial infection in humans as well as in mice. However, it remains unclear that why the immune response controls mycobacteria, but does not eradicate infection suggesting critical roles for series of survival strategies employed by pathogenic mycobacteria. In general, these evasion strategies include blockade of phagosome-lysosome fusion, secretion of ROI antagonistic proteins like superoxide dismutase & catalase, inhibition of processing of its antigens for presentation to T cells, induced secretion of immunosuppressive cytokines like IL-10 and TGF-β etc. that ultimately suppress the secretion of IL-12 and IFN-γ from APCs and T cells respectively, culminating in a skewed Th1/Th2 balance towards unprotective Th2 responses. Th2 cells secrete IL-4, IL-5, IL-9, IL-10 and IL-13 but are deficient in clearing intracellular infections including pathogenic mycobacteria. This eventually leads to inhibition of host’s immuno-protective responses with concomitant increase in the vulnerability to chronic mycobacterial infection. In this intricate process, modulation of cyclooxygenase-2 (COX-2) levels, a key enzyme catalyzing the rate-limiting step in the inducible production of prostaglandin E2 (PGE2), by mycobacteria like Mycobacterium bovis BCG assumes critical importance in influencing the overall host immune response. PGE2, an immunosuppressive member of prostaglandin family, is known to restrain production of IL-12, as well as reactive oxygen intermediates. PGE2-mediated inhibition of IL-12R, diminishes IL-12 responsiveness of macrophages and dendritic cells. PGE2 also inhibits the secretion of IFN-γ, which is important in activating T cells and macrophages. In contrast, PGE2 promotes IL-10 production by macrophages, dendritic cells and Th1-to-Th2 shift of acquired immune responses by inhibiting IL-2 and enhancing IL-4 production. Albeit, mitogen-activated protein kinase (MAPK) and nuclear factor-kappa B (NF-κB) signaling pathways are generally believed to be involved, little is known about the signaling molecules playing significant roles upstream of MAPK and NF-κB pathways during mycobacteria triggered COX-2 expression. Further, information on early receptor proximal signaling mechanisms essential during mycobacteria mediated induction of COX-2 remains scanty. In this regard, signaling cascade triggered upon recognition of mycobacterial components by pattern recognition receptors (PRR) signify as critical event in overall regulation of cell fate decisions. PRR like Toll like receptor (TLR2) and nucleotide-binding oligomerization domain 2 (NOD2) are two nonredundant recognition mechanisms of pathogenic mycobacteria. Several components of mycobacteria have been identified as being responsible for TLR2-dependent activation including 19-kDa lipoprotein, lipomannan etc.; while NOD2 recognizes mycobacterial peptidoglycans through its interaction with muramyl dipeptide (MDP). Interestingly, although mycobacteria reside within phagolysosomes of the infected macrophages, many cell wall antigens like lipoarabinomannan (LAM), phosphatidyl-myo-inositol mannosides (PIM), trehalose 6,6′-dimycolate (TDM; cord factor), PE/PPE family proteins etc., are released and traffic out of the mycobacterial phagosome platform into endocytic compartments. Importantly, these antigens could gain access to the extracellular environment in the form of exocytosed vesicles. In this perspective, PIM represents a variety of phosphatidyl-myo-inositol mannosides (PIM) 1-6 containing molecules and are integral component of the mycobacterial envelope. Further, PIM2 is a known TLR2 agonist and reported to activate NF-κB, AP-1, and MAPK suggesting that mycobacterial envelope antigen PIM2 could modulate the inflammatory responses similar to mycobacteria bacilli. In this context, we explored the signaling events modulated by M. bovis BCG, and role for TLR2 and NOD2 in this intricate process, to trigger the expression of COX-2 in macrophages. Our studies demonstrated that M. bovis BCG triggered TLR2-dependent signaling leads to COX-2 expression and PGE2 secretion in vitro in macrophages and in vivo in mice. Further, the presence of PGE2 could be demonstrated in sera or CSF of tuberculosis patients. Similarly, mycobacterial TLR2 agonist PIM2 and NOD2 ligand MDP triggered COX-2 expression in macrophages. The induced COX-2 expression in macrophages either by M. bovis BCG or PIM2 or MDP was dependent on NF-κB activation, which was in turn mediated by iNOS/NO and Wnt-β-Catenin dependent participation of the members of Notch1-PI3K signaling cascade. Importantly, loss of iNOS activity either in iNOS null macrophages or by pharmacological intervention in wild type macrophages severely abrogated M. bovis BCG ability to trigger the generation of Notch1 intracellular domain (NICD) as well as activation of PI3K signaling cascade. On contrary, treatment of macrophages with SIN-1, an NO donor, resulted in a rapid increase in generation of NICD, activation of PI3K pathway as well as the expression of COX-2. Interestingly, pharmacological inhibition as well as siRNA mediated knockdown of Wnt-β-Catenin signaling compromised ability of M. bovis BCG to induce activation of Notch1-PI3K signaling and drive COX-2 expression. Concomitantly, activation of Wnt-β-Catenin signaling by LiCl triggered activation of Notch1 and PI3K pathway as well as COX-2 expression. Stable expression of NICD in RAW 264.7 macrophages resulted in augmented expression of COX-2. Further, signaling perturbation experiments suggested involvement of the cross-talk of Notch1 with PI3K signaling cascade. In this perspective, we propose TLR2 and NOD2 as two major receptors involved in mycobacteria mediated activation of Notch1PI3K signaling, and the activation of iNOS/NO and Wnt-β-Catenin signaling axis as obligatory early receptor proximal signaling events during mycobacteria induced COX-2 expression in macrophages. Functional characterization of mycobacterial antigens that are potent modulators of host immune responses to pathogens by virtue of induced expression of COX-2 assumes critical importance for deciphering pathogenesis of mycobacterial diseases as well as to identify novel therapeutic targets to combat the disease. In this context, a group of novel antigens carried by M. tuberculosis that are expressed upon infection of macrophages belong to PE and PPE family of proteins. Ten percent of the coding capacity of M. tuberculosis genome is devoted to the PE and PPE gene family members, exemplified by the presence of Pro-Glu (PE) and Pro-Pro-Glu (PPE) motifs near the N-terminus of their gene products. Many members of the PE family exhibit multiple copies of polymorphic guanine-cytosine– rich sequences (PGRS) at the C-terminal end, which are designated as the PE_PGRS family of proteins. A number of PE/PPE proteins associate with the cell wall and are known to induce strong T & B cell responses in humans. However information related to effects of PE/PPE antigens on the maturation and functions of human dendritic cells and eventual modulation of T cell responses as well as underlying signaling events remains obscure. Our results demonstrated that two cell wall associated/secretory PE_PGRS proteins PE_PGRS 17, PE_PGRS 11 and PPE family protein PPE 34 recognize TLR2, induce maturation and activation of human dendritic cells and enhance the ability of dendritic cells to stimulate CD4+ T cells. In addition, tuberculosis patients were found to have a high frequency of T cells specific to PE_PGRS and PPE antigens. We further found that PE/PPE proteins-mediated activation of dendritic cells involves participation of ERK1/2, p38 MAPK and NF-κB signaling pathways. While, PE_PGRS antigens-matured dendritic cells secreted high amounts of inflammatory cytokine IL-12, PPE 34 triggered maturation of dendritic cells was associated with secretion of high amounts of anti-inflammatory cytokine IL-10 but not the Th1-polarizing cytokine IL-12. Consistent with these results, PPE 34-matured dendritic cells favored secretion of IL-4, IL-5 and IL-10 from CD4+ T cells and contributed to Th2 skewed cytokine balance ex vivo in healthy individuals and in patients with pulmonary tuberculosis. Interestingly, PPE 34-skewed Th2 immune response involved induced expression of COX-2 in dendritic cells. Our results suggest that by inducing differential maturation and activation of human dendritic cells, PE/PPE proteins could potentially modulate the initiation of host immune responses against mycobacteria. Taken together, our observations clearly signify the potential role for TLR2 and NOD2 triggering by M. bovis BCG in activating receptor proximal Notch1-PI3K signaling during induced COX-2/PGE2 expression which represents a crucial immune subversion mechanism employed by mycobacteria in order to suppress or attenuate host immune responses. Further, differential maturation of human dendritic cells by PE_PGRS and PPE antigens as well as their ability to stimulate CD4+ T cells towards Th1 and Th2 phenotype respectively, improves our understanding about host-mycobacteria interactions and clearly paves a way towards the development of novel combinatorial therapeutics.

Mycobacteria Immunity

Cyclooxygenase-2

Mycobacterial Infections - Immunity

Pathogenic Mycobacteria

Mycobacterium Bovis BCG

Pathogenic Mycobacteria - Immune Evasion

Mycobacterium tuberculosis

Mycobacterium bovis

COX-2

Bacteriology

Defining mechanisms that determine the levels of drug resistance in Mycobacterium tuberculosis

Bester, Margaretha

12 1900

Thesis (MSc (Biomedical Sciences. Molecular Biology and Human Genetics))--University of Stellenbosch, 2009. / ENGLISH ABSTRACT: Varying levels of Rifampicin (RIF) resistance in closely related clinical Mycobacterium tuberculosis isolates and in vitro generated mutants question the dogma that non-synonymous single nucleotide polymorphisms in the rpoB gene are the only mechanism explaining RIF resistance. This study aimed to identify biological mechanisms that define the level of RIF resistance in two closely related clinical M. tuberculosis isolates using proteomic, transcriptomic and genomic approaches. Two dimensional electrophoresis revealed an increase in the abundance of numerous membrane proteins in response to RIF at the critical concentration of 2g/ml. Fourty-one of these proteins were identified by mass spectrometry and could be grouped according to their cellular function (Energy metabolism, degradation, biosynthesis of cofactors, metabolic groups and carriers, lipid biosynthesis, central intermediate metabolism, synthesis and modification of macromolecules, chaperone/heat shock proteins). The identification of proteins responsible for ATP synthesis (atpA and atpH) suggests an ATP requirement to combat the toxic effect of RIF. These proteins are components of the FoF1 ATP synthase an enzyme which is involved in the oxidative phosphorylation pathway that generates ATP in the cell. QRT-PCR confirmed the up regulation of the transcription of the atpA and atpH genes in response to RIF, while DNA sequencing failed to identify mutations that could define the rate of transcription. To explain our findings we proposed that RIF induces a toxic response leading to the up regulation of a number of genes. The induction of metabolic enzymes, such as the FoF1 ATP synthase provides energy to activate ATP dependant mechanisms, including membrane ABC transporters. These ABC transporters actively pump RIF out of the cell thereby lowering the intracellular concentration of RIF to below its binding concentration with the rpoB protein leading to RIF resistance. Inhibition of efflux by the efflux pump inhibitors reserpine and verapamil leads to an accumulation of RIF within the cell and concurrent binding of RIF to rpoB, leading to inhibition of transcription and cell death (ongoing research in our laboratory). Similarly, we propose that the recently identified diarylquinoline compound (TMC207) inhibit ATP synthesis, thereby depleting the energy source necessary for active efflux. This will lead to an accumulation of anti-TB drug within the cell and subsequent cell death. In summary, this study provides the first evidence to suggest that the evolution of RIF resistance is a dynamic process involving a cascade of adaptive events which leads to a bacterial growth state where hydrophobic compounds are actively extruded from the cell. This has important ramifications for the treatment of RIF resistant TB and supports the need for the development of anti-TB drugs that target both efflux and ATP synthesis to improve the treatment outcome of MDR-TB and XDR-TB. / AFRIKAANSE OPSOMMING: Verskillende vlakke van Rifampisien (RIF) weerstandigheid, in naby verwante Mycobacterium tuberculosis kliniese isolate en in vitro mutante, bevraagteken die dogma dat nie-sinonieme enkel nukleotied polimorfismes in die rpoB geen die enigste verklaarbare meganisme vir RIF weerstandigheid is. Die doel van hierdie studie was om deur 'n proteomiese, transkriptomiese en genomiese benadering, biologiese meganismes te identifiseer wat die vlakke van RIF weerstandigheid in twee naby verwante kliniese M. tuberculosis isolate bepaal. Twee dimensionele elektroferese het gevind dat daar 'n verhoging in die hoeveelheid van verskeie proteïne is wanneer die isolate aan RIF by die 'n kritiese konsentrasie van 2μg/ml blootgestel is. Massa spektrometrie het 41 van hierdie proteine geïdentifiseer en die proteïne kan gegroepeer word in verskeie sellulêre funksies (Energie metabolism, degradering, biosintese van kofaktore, metaboliese groepe en draers, lipied biosintese, sentrale intemediêre metabolisme, sintese en modifisering van makromolekules, en “chaperone/heat shock” proteine). Die identifisering van proteïne verantwoordlik vir ATP sintese (atpA en atpH) stel voor dat ATP belangrik is om die toksiese effek van RIF te ontwyk. Hierdie proteïne is komponente van die FoF1 ATP sintase ensiem wat betrokke is in die oksidatiewe fosforilerings pad en wat lei tot die generering van ATP in die sel. Kwantitatiewe QRT-PCR het bevestig dat hierdie gene, atpA en atpH, opgereguleer word nadat die bakterium aan RIF blootgestel is. In teen deel kon DNA volgorde bepaling nie mutasies identifiseer wat die verandering in geen transkripsie kon verklaar nie. Om ons bevindings te verduidelik, stel ons voor dat RIF 'n toksiese effek in die sel induseer wat lei tot die opregulering van verskeie gene. Die indusering van metaboliese ensieme, soos die FoF1 ATP sintase, voorsien energie om ATP afhanklike meganismes, insluitende membraan ABC transporters, te aktiveer. Hierdie ABC transporters pomp RIF aktief uit die sel, wat daarvolgens die intrasellulêre konsentrasie van RIF verlaag tot 'n konsentrasie laer as die bindings konsentrasie met die rpoB protein en gevolglik lei tot weerstandigheid. Die onderdrukking van membraan pompe wat RIF uit die sel pomp deur middels soos reserpine en verapamil sal aanleiding gee lei tot akkumulering van RIF in die sel. Die verhoogde RIF in die sel versoorsaak dat RIF aan die rpoB protein gebind bly sodat dit transkripsie inhibeer, wat dan aanleiding gee tot seldood. (voortgesette navorsing in ons laboratorium). Soortgelyk, stel ons voor dat die onlangs geïdentifiseerde dairylquinoline verbinding (TMC207) ATP sintese inhibeer en daarvolgens die energie bron uitput wat noodsaaklik is vir aktiewe uitpomp van RIF. Dit sal aanleiding gee tot die ophoping van RIF in die sel en gevolglik lei tot seldood. In opsomming, hierdie studie voorsien die eerste bewys wat voorstel dat die evolusie van RIF weerstandighied 'n dinamiese proses is. Dit sluit 'n kaskade van aanpasbare gebeurtenisse in wat lei tot 'n bakteriële groei fase waar hidrofobiese verbindings aktief uit die sel gedryf word. Dit het rampspoedige gevolge vir die behandeling van RIF weerstandige TB en ondersteun die noodsaaklikheid om teen-TB middels te ontwikkel wat beide effluks pompe en ATP sintese teiken om die uikoms van behandeling vir MDR-TB en XDR-TB te verbeter.

Mycobacterium tuberculosis

Drug resistance

Rifampicin

Level of resistance

RIF

Investigation of Mycobacterium tuberculosis protein expression and analysis of humoral immune responses of TB patients

Pheiffer, Carmen

12 1900

Thesis (PhD)--Stellenbosch University, 2004. / ENGLISH ABSTRACT: New agents for the diagnosis, prevention and treatment of tuberculosis are urgently required. Yet, despite extensive tuberculosis research over recent years, no new drugs, vaccines or diagnostics have been identified to date. It is widely speculated that the major obstacle to the identification of new therapies is the lack of understanding of the hostpathogen interaction. This study has investigated whether patterns of antigen expression correlate with molecular epidemiological data and strain virulence through the analysis of protein expression and antigen recognition profiles of different M tuberculosis clinical isolates. Using polyacrylamide gel electrophoresis, enzyme-linked immunosorbent assay, and Western blotting, protein expression and antigen recognition by two genotypically different clinical strains that differed in their frequency in the study population have been compared. In addition to differences in protein expression and antigen recognition between the clinical strains and the reference strain H37Rv, protein expression differences between the clinical strains themselves were observed which may relate to strain frequency and virulence. Differential protein expression by M tuberculosis strains, may explain the heterogeneous host humoral immune response and why no fully effective serodiagnostic test has been developed to date. To explore this hypothesis, the potential of serodiagnosis in this community, where patients are infected with a wide variety of genotypically distinct strains, was investigated. IgG levels to three mycobacterial antigens showed that serodiagnosis of TB is possible in this community, despite infection by a wide variety of genotypically different M tuberculosis strains. Disease episode affected antibody levels, suggesting that care should be taken when evaluating serological diagnosis for repeat episode patients. This study has shown that M tuberculosis protein expression is dynamic and that the bacillus presents a hypervariabie array of antigens to the host immune system. It is likely that different antigens become immunodominant as antituberculosis chemotherapy progresses, and that these differentially expressed antigens may be tracked as predictors of treatment outcome. This hypothesis was tested by correlating Ag85-specific IgG with treatment response, as assessed by sputum smear conversion after two months of antimycobacterial chemotherapy. No significant correlation between antibody levels and treatment responses was observed, suggesting that antibodies may not be useful surrogate markers or that the incorrect antibody type or mycobacterial antigen were selected. Results were consistent with previous findings where patient-to-patient variation dictated the host humoral response. The results obtained in this study have demonstrated that although bacteriological factors may influence strain prevalence due to antigen variation and immune evasion, both bacteriological and host factors affect humoral immunity. Differential protein expression by M tuberculosis strains has potentially important implications for serodiagnosis and the development of subunit or DNA vaccines, by suggesting that multi-antigen cocktails should be used. Differential protein expression may also explain why patients do not develop adequate protective immunity and are susceptible to reinfection. / AFRIKAANSE OPSOMMING: Daar is 'n dringende behoefte vir nuwe middels vir die diagnosering, voorkoming en behandeling van tuberkulose. Ondanks intense tuberkulose navorsing gedurende die afgelope paar jaar, is daar geen nuwe tuberkulose medikasie, vaksines of diagnostiese metodes geïdentifiseer nie. Daar word gespekuleer dat die hoof struikelblok vir die identifisering van nuwe medikasie die onkunde oor die tuberkulose patogeen is. Deur die analise van proteien-uitdrukking en antigeen-erkenning profiele van verskillende M. tuberculosis kliniese isolate is daar tydens hierdie studie ondersoek ingestel of die patroon van antigeen uitdrukking korreleer met molekulêre epidemiologiese data and stam-virulensie. Proteien-uitdrukking en antigeen-erkenning deur twee genotipies verskillende kliniese stamme wat verskil in hul frekwensie in die bestudeerde populasie, is vergelyk deur middel van poli-akrielamied gel elektroforese, ensiem-gekoppelde immuunabsorberende analise en Westelike oordrag. Addisoneel tot die verskille in proteienuitdrukking en antigeen-ekenning tussen kliniese stamme en die verwysingstam H37Rv, is daar ook verskille aangedui tussen die kliniese stamme self wat kan dui op stam frekwensie en virulensie. Differensiële proteien-uitdrukking deur M. tuberculosis stamme, kan moontlik die heterogene gasheer se humorale immuunreaksie verduidelik en daarmee saam die rede waarom daar nie tot op hede 'n effektiewe sero-diagnostiese toets ontwikkel is nie. Daar is dus ondersoek ingestel na die potensiaal van sero-diagnose in 'n gemeenskap waar pasiënte geïnfekteer is met 'n wye verskeidenheid genotipiese stamme. Die IgG vlakke van drie mikobakteriële antigene het aangedui dat sero-diagnose van tuberkulose moontlik is in hierdie gemeenskap, ten spyte van infektering deur 'n wye verskeidenheid genotipies-verskillende M. tuberculosis stamme. Die tussenspel van die siekte het teenliggaampie-vlakke beïnvloed wat daarop dui dat daar versigtig moet gelet word tydens die evaluering van serologiese diagnose van geïnfekteerde pasiënte wat voorheen siek was. Hierdie studie toon dat M. tuberculosis proteïen-uitdrukking dinamies is en dat die bacillus 'n groot variëteit van antigene tot die immuun sisteem bied. Dit is moontlik dat verskillende antigene immuun dominant kan word soos wat antituberkulose chemoterapie toeneem, en dat hierdie verskillend-uitgedrukte antigene as 'n gevolg daarvan gebruik kan word as voorspellers vir behandeling. Hierdie hipotese is getoets deur die korrelering van Ag85-spesifieke IgG met die reaksie op behandeling soos geëvalueer deur speeksel-monster verandering na twee maande se anti-mikobakteriële chemoterapie. Daar was geen noemenswaardige korrelasie tussen teenliggaampie vlakke en die reaksie op behandeling nie, wat daarop dui dat die teenliggaampies nie toepaslike surrogaat merkers is nie of dat die verkeerde teenliggaampie-tipe of mikobakteriële antigeen geselekteer is. Hierdie resultate bevestig vorige bevindinge waar pasiënt-tot-pasiënt verskille die gasheer se humorale immuunreaksie gedikteer het. Die resultate wat uit hierdie studie volg dui dat alhoewel bakteriologiese faktore die stam-frekwensie kan beïnvloed as gevolg van antigeen-variasie en immuun-ontduiking, kan beide bakteriologiese en gasheer faktore die humorale immuunreaksie beïnvloed. Differensiële proteiën uitdrukking deur 'n verskeidenheid M. tuberculosis stamme het potensieël belangrike toepassings vir sero-diagnose en die ontwikkeling van subeenheid of DNS vaksines wat impliseer dat multi-antigeen mengsels gebruik moet word. Differensiële proteiën uitdrukking mag ook verduidelik waarom pasiënte nie 'n voldoende beskermende immuniteit opbou nie en sodoende ontvanklik is vir her-infeksie.

Mycobacterium tuberculosis

Immune response

Antigens

Proteins -- Synthesis

Dissertations -- Medicine