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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Molecular Characterization c-di-GMP Signalling In Mycobacterium Smegmatis

Bharati, Binod Kumar 07 1900 (has links) (PDF)
Bacterial stationary phase is an interesting biological system to study, as the organism undergoes several metabolic changes during this period and new molecules are generated to support its survival. The stationary phase of mycobacteria has been extensively studied since the discovery of Mycobacterium tuberculosis, the causative agent of tuberculosis. The stationary phase of mycobacteria adds further complication as many antibacterial drugs become less effective. The M. tuberculosis infects the alveolar macrophages and dendritic cells or monocytes recruited from peripheral blood. Macrophages are supposed to provide an initial barrier against the bacterial infection, but fails. Mycobacteria have evolved several strategies to survive and set up an initial residence within these cells and grow actively inside the host. The host immune system tries to limit the bacterial growth and confines the organism to a latent state in which the organism can persist indefinitely, known as granuloma stage. During latency or granuloma stage mycobacteria can retain the ability to resume the growth in the future. Mycobacteria must adapt to a highly dynamic and challenging environment because the interior environment of granuloma is devoid of or in low level of oxygen, depleted nutrient, high carbon dioxide, and possess increased levels of aliphatic organic acids and hydrolytic enzymes. The survival of a bacterium in less nutrient supply or in depleted oxygen is important for its long-¬term persistence inside the host under harsh environmental conditions. Mycobacterium smegmatis is the closest non-¬pathogenic homologue of M. tuberculosis, and has been used widely as a model system to study gene regulation under such conditions. In these harsh environmental conditions bacteria need to sense the external environment to modulate their gene expression. More importantly, each individual cell should communicate with its neighbours, and the response takes place in a concerted manner, which is termed as quorum sensing. Thus, the quorum sensing is a cell-¬cell signaling process that allow the bacteria to monitor the presence of other bacteria in their surroundings by producing and responding to small signaling molecules, which are known as autoinducers. It is a density dependent phenomenon and regulates the expression of the genes in response to fluctuation in cell¬-population density. A minimum threshold level of autoinducers is necessary to detect the signal and respond to it. Quorum sensing enables bacteria to behave like multicellular organisms and controls group activities like biofilm formation, sporulation, bioluminescence, virulence, and pigment production, etc (Bassler, 1999; Camilli & Bassler, 2006; Fuqua et al., 1996; Miller & Bassler, 2001). In Gram-¬negative bacteria, small-¬molecules, which are known as autoinducers are produced. They are acyl homoserine lactones (AHLs), which are derived from S¬adenosyl methionine (SAM) and particular fatty acyl carrier protein by LuxI¬type AHL synthases (Fuqua et al., 1996). In Gram-¬positive bacteria small peptides autoinducers, 5¬12 amino acids long, play an active role in communication. These oligopeptides are post--translationally modified by the incorporation of lactone and thiolactone rings, lanthionines and isoprenyl groups. These oligopeptide autoinducers are detected by membrane-¬bound two-¬component signaling proteins, and signal transduction occurs by a phosphorylation cascade (Camilli & Bassler, 2006; More et al., 1996; Novick, 2003; Zhang et al., 2002). In bacteria, the cyclic adenosine monophosphate (cAMP), and guanosine pentaphosphate and/or tetraphosphate ((p)ppGpp) are well known second messengers, which play important role in relaying extracellular information, but recently cyclic diguanosine monophosphate (c-¬di¬-GMP) is being studied most comprehensively as a nucleotide-¬based second messenger. C-¬di¬-GMP was first discovered in Gluconacetobacter xylinus as a positive allosteric regulator of cellulose synthase (Ross et al., 1987; Tal et al., 1998; Weinhouse et al., 1997). The in vivo level of c-¬di-¬GMP in bacterial cell is maintained by the balance between diguanylate cyclase and phosphodiesterase activities. The GGDEF and EAL amino acids sequence are the signature motif for GGDEF and EAL domain protein within its active site, respectively. The GGDEF domain protein is involved in synthesis of c-¬di-¬GMP and the EAL domain protein is involved in the hydrolysis of c-¬di-¬GMP, and the majority of these proteins contain additional signal input domains (Paul et al., 2004; Ross et al., 1987; Ryjenkov et al., 2005; Tal et al., 1998). M. smegmatis has a single bi-¬functional protein having both the domains, GGDEF and EAL, for the diguanylate cyclase (DGC) and phosphodiesterase (PDE¬A) activities. In addition to GGDEF and EAL domain, one sensory domain, GAF, is also there at the N-terminal of MSMEG_2196 in M. smegmatis. In the present investigation, studies have been carried out to understand the regulation of c-¬di-¬GMP in M. smegmatis at protein and gene level. The entire study on mycobacterial MSMEG_2196 (msdgc¬1) can be broadly divided into five parts; the first part will cover the identification and biochemical characterization of MSDGC¬1 protein, responsible for the regulation of in vivo c-¬di-¬GMP concentration in M. smegmatis, and the presence of GGDEF¬EAL domain containing proteins in various mycobacterial species. The second part will cover the structure function relationship as a function of substrate, GTP and product, c-¬di-GMP, molecule using fluorescence spectroscopy as a tool, and the mutational and structural studies, which leads to the identification of a novel structural motif. The third part will cover the characterization of msdgc¬1 gene knockout and complementation studies in great detail. The fourth part will comprise in vivo and in vitro promoter characterization and regulation of the msdgc¬1 gene under nutritional starvation. The last chapter will cover the characterization of novel synthetic glycolipids, which are working as a growth and biofilm inhibitors in mycobacteria, and can be used as a new drug candidates. Chapter 1 outlines the signal transduction and quorum sensing mechanism, and small molecule signaling modules in brief. The importance of the study started with a brief introduction about the historical aspect of tuberculosis, the current scenario of the treatment of tuberculosis. The urgent need for new drug targets and drugs will be discussed. The important role of the novel second messenger, c-¬di¬-GMP has been explained in greater details in both Gram-¬positive and Gram-¬negative bacteria, and the information available on the different cellular targets has been documented. Chapter 2 describes the identification and biochemical characterization of M. smegmatis MSMEG_2196 protein. The domain architecture and individual domain role have been studied. The MSMEG_2196 proteins consist of three domains, GAF, GGDEF and EAL in tandem, and individual role of each domain has been studied. The diguanylate cyclases containing GGDEF and phosphodiesterases containing EAL domains have been identified as the enzymes involved in the regulation of in vivo cellular concentration of c-¬di-¬GMP. GAF domain has been identified as a metal binding domain in other bacteria and may be playing a role in the regulation of synthesis and hydrolysis activities of c-¬di¬-GMP. The identification, cloning expression and purification of MSMEG_2196 and MSMEG_2774 have been discussed. We have reported that mycobacterial MSDGC¬1 protein has dual activity, which means that it can synthesize and hydrolyse c¬-di-¬GMP; and also full-¬length protein is necessary for its either of the activities. The synthesis and hydrolysis products, c-¬di-¬GMP and pGpG, of MSDGC¬1 protein have been identified and characterized using radiolabelled alpha [α¬32P]GTP and Matrix Assisted Laser Desorption/Ionization mass spectrometry (MALDI). The effects of temperature and pH on the activities of MSDGC¬1 have been studied. The circular dichroism studies show that the MSDGC¬1 protein is predominantly α¬helical in nature, and secondary structure does not alter upon GTP binding. The kinetic parameters for MSDGC¬1 protein have been calculated as a function of substrate, GTP. The protein, MSDGC¬1, exist as a monomer and a dimer in solution. The MSDGC¬1 protein has four cysteines, and we have shown here using mass spectrometric analysis that none of the cysteines is involved in the disulphide linkage. Chapter 3 deals with the structure-¬function relationship as a function of GTP and c¬-di-GMP molecules using fluorescence spectroscopy as a tool. In order to do so we have generated several cysteine mutants using site directed mutagenesis, and protein was labelled with thiol-¬specific fluorophores. The labelled protein was checked for its DGC and PDE¬A activities and specificity of labelling was confirmed using MALDI and radiometric analysis. The Fluorescence Resonance Energy Transfer (FRET) has been carried out to observe domain-¬domain interaction as a function of GTP and c¬-di-¬GMP. The bioinformatics, structural, and mutational analysis suggest that cysteine at 579 position is important for DGC and PDE¬A activities, and may be involved in the formation of a novel structural motif, GCXXXQGF, which is necessary for synthesis and degradation of c-¬di-¬GMP. Chapter 4 describes the construction of a deletion mutation of MSMEG_2196 gene in M. smegmatis. The strategy for the construction of the knockout strain has been shown and confirmation of the knockout event has been carried out using PCR and Southern hybridization. The effect of deletion of msdgc¬1 has been studied in great detail, and it was noticed that biofilm formation is not affected, but long-¬term survival is significantly compromised. It is hypothesized here that c-¬di¬-GMP is involved in the regulation of cell population density in mycobacteria. We have successfully detected the c-¬di¬-GMP in the total nucleotide extract using HLPC coupled with MALDI, and we have shown here that level of c-¬di-¬GMP increases many fold in the stationary phase of growth under nutritional starvation. Chapter 5 deals with the identification and characterization of the promoter element of msdgc¬1 in M. smegmatis. The study was undertaken to understand the mechanism of regulation at promoter level. We have observed here that msdgc¬1 promoter is starvation induced, and expression of msdgc¬1 increases many fold in the stationary phase under nutritional starvation. We have also tried to establish the link between the ppGpp and c-di¬-GMP signalling, and possible role of c-¬di-¬GMP in the regulation of cell population density have been discussed. Further, the +1 transcription start site has been identified using primer extension method. The putative ¬10 hexamer region for the RNA polymerase binding has been identified and confirmed using site-¬directed mutagenesis. It was found to be TCGATA, which is 14 bp upstream from the +1 transcription start site. The msdgc-1 promoter is specific for mycobacteria and does not function in E. coli. Moreover, we have identified the sigma factors, which regulate the msdgc¬1 promoter in growth phase dependent manner. Chapter 6 begins with the screening of synthetic glycolipids as a novel drug candidate. The different glycolipids have been tested for their effect on growth, biofilm formation, and sliding motility of M. smegmatis, and we have screened few of them, which were found to be effective in inhibiting the microbial growth, biofilm formation, and sliding motility. Chapter 7 summarizes the work presented in this thesis. Appendix: The protein sequences of MSDGC¬1 and MSDGC¬2, and the multiple sequence alignments of MSDGC¬1 protein have been documented. The FORTRAN program, which was used to calculate spectral overlap integral J, and the diagrams of the plasmids used in this study have been provided.
2

DNA Repair Proteins in Mycobacteria and their Physiological Importance

Sang, Pau Biak January 2014 (has links) (PDF)
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.

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