Infectious and Inflammatory Diseases of Salivary Glands

Al-Abbadi, Mousa A., Zakaria, Wael N., Eltoum, Isam A.

09 March 2011

No description available.

acute bacterial parotitis

an infrequent illness - in the elderly

in dehydrated

malnourished and intubated patients

an uncommon cause of parotitis

MULTISCALE SPATIOTEMPORAL MODELING FOR HUMAN DISEASE: AGENT BASED MODELS FOR NONTUBERCULOUS MYCOBACTERIUM INFECTIONS AND ALZHEIMER’S DISEASE

Catherine Weathered (13924857)

10 October 2022

<p>Human disease and the corresponding immune response occur in three-dimensional space and time. Many diseases are difficult to study, either <em>in vivo</em> or <em>in vitro</em>, due to the complexity of the system. Despite computational models that can address complexity, many do not capture the spatial  aspects  of  disease.  Agent-based  models  are  mechanistic,  spatiotemporal  computational models that can be integrated with other mathematical models to create multiscale models. Here I detail two models to examine spatiotemporal progression and possible treatment strategies for two diseases  with  low  treatment  success: <em>Mycobacterium  avium complex</em>  (MAC)  and  Alzheimer’s Disease.</p> <p>MAC  are  biofilm-forming  environmental  microbes  capable  of  residing  in  human  lung nodules,  causing  MAC  pulmonary  disease  (MAC-PD).  Clinical  drug  susceptibility  tests  and treatment  outcomes  are  poorly  correlated,  and  nodules  are  complex  and  difficult  to  monitor, leading to low MAC cure rates (45-65%)². I have developed an informative model of the initial infection  events  in  MAC-PD. This  model  has  been  used  to  probe  many  different  scenarios  of infection and to predict the effect of potential interventions.</p> <p>Alzheimer’s  Disease  (AD)  is  the  leading  cause  of  dementia,  with  no  disease-altering pharmacological  intervention.  Microglia  are  phagocytotic  neuroimmune  cells,  known  to  form barriers around plaques. There has been increased interest in leveraging microglia to slow the progression of neurodegeneration by manipulating these barriers. I present an agent-based model of microglia barriers at the single plaque level and use knock-out experiments to probe possible targets for immunotherapy and quantify their effects on plaque progression.</p>

agent-based modeling

spatial models

Mycobacterium avium complexes

alzheimer-disease

Structural Studies on Mycobacterium Tuberculosis Peptidyl-tRNA Hydrolase and Ribosome Recycling Factor, Two Proteins Involved in Translation

Selvaraj, M

January 2013

Protein synthesis is a process by which organisms manufacture their proteins that perform various cellular activities either alone or in combination with other similar or different molecules. In eubacteria, protein synthesis proceeds at a rate of around 15 amino acids per second. The ribosomes, charged tRNAs and mRNAs can be considered as the core components of protein synthesis system which, in addition, involves a panel of non-ribosomal proteins that regulate the speed, specificity and accuracy of the process. Peptidyl-tRNA hydrolase (Pth) and ribosome recycling factor (RRF) are two such non-ribosomal proteins involved in protein synthesis. These two proteins are essential for eubacterial survival and the work reported in this thesis involves structural characterization of these two proteins from the bacterial pathogen, Mycobacterium tuberculosis. The protein structures were solved using established techniques of protein crystallography. Hanging drop vapour diffusion method and crystallization under oil using microbatch plates were the methods employed for protein crystallization. X-ray intensity data were collected on a MAR Research imaging plate mounted on a Rigaku RU200 X-ray generator in all the cases. The data were processed using DENZO and MOSFLM. The structures were solved by molecular replacement method using the program PHASER. Structure refinements were carried out using programs CNS and REFMAC. Model building was carried out using COOT. PROCHECK, ALIGN, CHIMERA, and PYMOL were used for structure validation and analysis of the refined structures. Peptidyl-tRNA hydrolase cleaves the ester bond between tRNA and the attached peptide in peptidyl-tRNA that has dropped off from ribosome before reaching the stop codon, in order to avoid the toxicity resulting from peptidyl-tRNA accumulation and to free the tRNA to make it available for further rounds in protein synthesis. To begin with, the structure of the enzyme from M. tuberculosis (MtPth) was determined in three crystal forms. This structure and the structure of the same enzyme from Escherichia coli (EcPth) in its crystal differ substantially on account of the binding of the C-terminus of the E.coli enzyme to the peptide binding site of a neighboring molecule in the crystal. A detailed examination of this difference led to an elucidation of the plasticity of the binding site of the enzyme. The peptide-binding site of the enzyme is a cleft between the body of the molecule and a polypeptide stretch involving a loop and a helix. This stretch is in open conformation when the enzyme is in the free state as in the crystals of MtPth. Furthermore, there is no physical continuity between the tRNA and the peptide-binding sites. The molecule in the EcPth crystal mimics the peptide-bound conformation of the enzyme. The peptide stretch involving a loop and a helix, referred to earlier, now closes on the bound peptide. Concurrently, a gate connecting the tRNA and the peptide-binding site opens primarily through the concerted movement of the two residues. Thus, the crystal structure of MtPth when compared with that of EcPth, leads to a model of structural changes associated with enzyme action on the basis of the plasticity of the molecule. A discrepancy between the X-ray results and NMR results, which subsequently became available, led to X-ray studies on new crystal forms of the enzyme. The results of these studies and those of the enzyme from different sources that became available, confirmed the connection deduced previously between the closure of the lid at the peptide-binding site and the opening of the gate that separates the peptide-binding site and tRNA binding site. The plasticity of the molecule indicated by X-ray structures is in general agreement with that deduced from the available solution NMR results. The correlation between the lid and the gate movement is not, however, observed in the NMR structure of MtPth. The discrepancy between the X-ray and NMR structures of MtPth in relation to the functionally important plasticity of the molecule, referred to earlier, also led to molecular dynamics simulations. The X-ray and the NMR studies along with the simulations indicated an inverse correlation between crowding and molecular volume. A detailed comparison of proteins for which X-ray and the NMR structures are available appears to confirm this correlation. In consonance with the reported results of the investigation in cellular components and aqueous solutions, the comparison indicates that the crowding results in compaction of the molecule as well as change in its shape, which could specifically involve regions of the molecule important for function. Crowding could thus influence the action of proteins through modulation of the functionally important plasticity of the molecule. After termination of protein synthesis at the stop codon, the ribosome remains as a post-termination complex (PoTC), consisting of the 30S and the 50S subunits, mRNA and a deacylated tRNA. This complex has to be disassembled so that the ribosome is available for the next round of translation initiation. Ribosome recycling factor (RRF) binds to ribosome and in concert with elongation factor G (EF.G), performs the recycling of ribosome that results in disassembly of PoTC. The structure of this L-shaped protein with two domains connected by a hinge, from Mycobacterium tuberculosis (MtRRF) was solved previously in our laboratory. The relative movement of domains lies at the heart of RRF function. Three salt bridges were hypothesized to reduce the flexibility of MtRRF when compared to the protein from E.coli (EcRRF), which has only one such salt bridge. Out of these three bridges, two are between domain 1 and domain 2, whereas the third is between the hinge region and the C-terminus of the molecule. These salt bridges were disrupted with appropriate mutations and the structure and activity of the mutants and their ability to complement EcRRF were explored. An inactive C-terminal deletion mutant of MtRRF was also studied. Major, but different, structural changes were observed in the C-terminal deletion mutant and the mutant involving the hinge region. Unlike the wild type protein and the other mutants, the hinge mutant complements EcRRF. This appears to result from the increased mobility of the domains in the mutant, as evidenced by the results of librational analysis. In addition to the work on PTH and RRF, the author was involved during the period of studentship in carrying out X-ray studies of crystalline complexes involving amino acids and carboxylic acids, which is described in the Appendix of the thesis. The complexes studied are that of tartaric acid with arginine and lysine.

Mycobacterium tuberculosis

Peptidyl-transfer RNA Hydrolase

Eubacteria - Translation

Ribosome Recycling Factor (RRF)

Peptidyl-transfer RNA

Mycobacterial Protein Synthesis

Non-Ribosomal Proteins

Mycobacterial Proteins

Peptidyl-tRNA Hydrolase

Molecular Biology

Investigating the Human-M. tuberculosis interactome to identify the host targets of ESAT-6 and other mycobacterial antigens

Bruiners, Natalie

12 1900

Thesis (PhD)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: The causative agent of human tuberculosis, Mycobacterium tuberculosis, is an intracellular pathogen that secretes virulence factors, namely ESAT-6 and CFP-10, as substrates of the ESX-1 secretion system. It is hypothesised that these substrates interact with host proteins in a targeted manner in order to elicit a required immune response, and they have been shown to be involved in processes related to pro-inflammatory responses, necrosis, apoptosis, membrane lysis and cytolysis. However, the biological function of ESX-1 substrates during host-pathogen interactions remains poorly and incompletely understood. Therefore, the present study was designed to gain insight into the role of the ESX-1 secretion system substrates in host-pathogen interactions and to identify how M. tuberculosis mediates the response of the human host. In this study, a cDNA yeast two-hybrid library was constructed from human lung mRNA, to identify mycobacterial-host protein-protein interactions that occur within the lung alveoli. The ESX-1 secretion system substrates, ESAT-6 and CFP-10, were cloned in-frame into the pGBKT7 vector, which was used in the yeast two-hybrid system to screen the lung cDNA library in Saccharomyces cerevisiae. The ESAT-6 and CFP-10 screens identified 79 and 19 positive colonies, respectively. Of the total number of clones characterised, only two in-frame inserts were identified with the ESAT-6 screen, corresponding to the human proteins filamin A and complement component 1, q subcomponent, A chain (C1QA). In addition, the screen with CFP-10 also identified C1QA as binding partner. Subsequent in vitro and in vivo experiments were unable to confirm the putative interactions of C1QA with ESAT-6 and CFP-10. However, the interaction between filamin A and ESAT-6 was demonstrated and confirmed by both in vivo co-localisation and co-immunoprecipitation. Furthermore, the degradation of filamin A in the presence of ESAT-6 was shown to be reflective of cytoskeleton remodelling and the induction of cell death. The work presented here suggests that as ESAT-6 gains access to the cytosol, it initiates cell death by inducing destabilisation of the cytoskeleton cell structure. This may possibly be driven by the interaction of ESAT-6 and filamin A. Finally, we also initiated an investigation of the identified putative binding partners (filamin A and C1QA) as possible genetic markers for genetic susceptibility studies to tuberculosis. A case-control analysis was performed involving 604 cases, of which 109 were Tuberculous Meningitis (TBM), and 486 were controls from the South African Coloured (SAC) population within the Ravensmead-Uitsig catchment area. The results of this analysis demonstrated a novel association of a regulatory variant (rs587585) located upstream of the C1QA gene and demonstrated an increasing trend towards increased values in tuberculosis patients with the associated genotype. This study has contributed significantly to our understanding of human-mycobacterial hostpathogen protein-protein interactions and has opened the way for future studies further exploring the consequences and function of the identified ESAT-6-filamin A interaction. It has also led to the identification of a novel genetic association with tuberculosis. Finally, it demonstrates the usefulness of the yeast two-hybrid system to identify potential proteinprotein (host-pathogen) interactions that can lead to additional important and exciting research. / AFRIKAANSE OPSOMMING: Die organisme wat tuberkulose veroorsaak, Mycobacterium tuberculosis, is `n intrasellulȇre patogeen wat virulensie faktore afskei, naamlik ESAT-6 en CFP-10, as substrate van die ESX-1 sekresiesisteem. Daar word vermoed dat hierdie substrate met gasheerproteïene in „n teiken wyse interaksie het om `n vereiste immuunreaksie voort te bring. Hierdie substrate is betrokke by prosesse soos pro-inflammatoriese reaksies, nekrose, apoptose, membraanlise en sitolise. Die biologiese funksie van die ESX-1 substrate tydens gasheer-patogeen interaksies word egter tans swak en onvolledig verstaan. Daarom was die huidige studie ontwerp om insig te bekom oor die rol hiervan in gasheer-patogeen interaksies en om te identifiseer hoe M. tuberculosis die reaksie teenoor die gasheer bemiddel. In hierdie studie was `n komplementȇre deoksiribonukleïensuur (kDNS) gis twee-hibried biblioteek gemaak vanaf long boodskapper ribonukleïensuur (bRNS) om proteïen-proteïen interaksies wat in die long plaasvind, te identifiseer. Die substrate van die ESX-1 sekresiesisteem, ESAT-6 en CFP-10, is in volgorde gekloneer in die pGBKT7 vektor en is gebruik om die long kDNS biblioteek in Saccharomyces cerevisiae te ondersoek. In die soeke na interaksies met ESAT-6 and CFP-10, was 79 en 19 positiewe kolonies onderskeidelik geïdentifiseer. Van die aantal klone, was slegs twee volgordes in-leesraam geïdentifiseer met ESAT-6. Hierdie proteïene het ooreengestem met filamin A en “complement component 1, q subcomponent, A chain” (C1QA). Bykomend hiertoe, is C1QA ook geïdentifiseer as „n bindende vennoot met CFP-10. Daaropvolgende in vitro and in vivo eksperimente kon nie die vermeende interaksie van C1QA met ESAT-6 en CFP-10 bevestig nie. Maar die interaksie tussen filamin A en ESAT-6 kon wel gedemonstreer word deur die gebruik van mede-lokalisering en medeimunopresipitasie. Die afbreek van filamin A in die teenwoordigheid van ESAT-6 is ook aangetoon en blyk „n weerspieëling te wees van sitoskelet hermodellering en die induksie van seldood. Die werk wat hier aangebied word, dui daarop dat soos ESAT-6 toegang kry tot die sitosol, inisieër dit seldood deur die destabilisaisie van die sitoskelet selstruktuur. Dit word moontlik aangedryf deur die interaksie van ESAT-6 met filamin A. Laastens het ons `n ondersoek van die geïdentifiseerde bindingsvennote (filamin A and C1QA) as moontlike genetiese merkers vir genetiese vatbaarheidsstudies vir tuberkulose uitgevoer. `n Pasiënt-kontrole studie is gedoen waarby 604 individue ingesluit is, waarvan 109 gediagnoseer is met Tuberculosis Meningitis (TBM), en die ander 486 kontrole individue was van die Suid Afrikaanse Kleurling (SAC) bevolking binne die Ravenmead-Uitsig opvanggebied. Die resultate het „n nuwe assosiasie van „n regulerende variant (rs587585) wat stroomop van die C1QA geen gelokaliseer is, getoon. Hierdie variant het `n verhoogde neiging in tuberkulose pasiënte met die geassosieërde genotipe getoon. Hierdie studie het `n beduidende bydrae gemaak tot ons begrip van menslike-mikobakteriese gasheer-patogeen proteïen-proteïen interaksies. Hierdie resultate het die weg oopgemaak om die gevolge en funksie van die geïdentifiseerde ESAT-6-filamin A interaksie verder te ondersoek. Dit het ook aanleiding gegee tot die identifikasie van `n genetiese assosiasie met tuberkulose. Om saam te vat, hierdie werk bewys die bruikbaarheid van die gis twee-hibriede sisteem, om potensiële proteïen-proteïen interaksies te ontdek wat die moontlikheid het om aanleiding te gee tot addisionele navorsingsvrae. / The National Research Foundation, / Harry Crossley Foundation / Medical Research Council of South Africa / Stellenbosch University Postgraduate bursary / Prof. Paul van Helden

Mycobacterium tuberculosis

Tuberculosis -- Genetic aspects

ESAT-6

CFP-10

ESX-1 secretion system substrate

Theses -- Medicine

Dissertations -- Medicine

Theses -- Molecular biology

Dissertations -- Molecular biology

Theses -- Human genetics

Dissertations -- Human genetics

Biomedical Sciences

Studies On DNA Gyrase From Mycobacteria : Insights Into Its Mechanism Of Action And Elucidation Of Its Interaction With The Transcription Machinery

Gupta, Richa

05 1900

Packaging of genomic DNA by proteins and super coiling into chromatin and chromatin-like structures (in bacteria) influences nearly all nuclear process such as replication, transcription, repair, and recombination. A ubiquitous class of enzymes termed “DNA topoisomerases” pay key roles during these process. The reactions catalyzed by the members of the DNA topoisomerases family share a common chemistry, which involves phosphodiester bond breakage and re-joining, to bring about a change in the linking number of DNA. Nevertheless, the underlying mechanisms used by these enzymes differ significantly from another. Consequently, DNA topoisomerases are divided into type I and type II enzymes. The mechanism(s) by which DNA topoisomerases perform their functions, and act as targets for anti-bacterial and anti-neoplastic drugs, has attracted considerable interest. Based on these and other finding, I have chosen DNA gyrase from mycobacteria as the subject of my Ph.D. theses investigation. The prokaryotic enzyme, DNA gyrase, is unique amongst all topoisomerases being the only enzyme capable of introducing negative super coils in to duplex DNA. Since no equivalent enzymatic activity has been reported in humans, this essential enzyme has been exploited as a during target against many microbial infections including tuberculosis.DNA gyrase is a tetrameric protein, comprised of two pairs of subunits, encoded by gyrA and gyrB. Inhibitors of DNA gyrase know till date target either of the two subunits and are categorized broadly in to two class, viz. coumarins and quinolones. With the emergence of multiple-drug resistant strains of pathogenic bacteria such as Mycobacterium tuberculosis, which is a leading cause of death world-wide, there is a need to develops new lead molecules with novel mechanisms of inhibition. Towards this end, a new approach to inhibit the mycobacterial DNA gyrase using single-chain antibody has been explore in the present study. In addition to this, the differences in the catalytic properties of the subunits and assembly of the Mycobacterium smegmatis enzyme vis-à-vis Escherichia coli DNA gyrase have been examined. Further, the in vivo relationship of DNA gyrase with the transcription machinery of the cell has also been investigated, with an emphasis on the biology of mycobacteria.

Mycobacteria - DNA

DNA Gyrase

DNA Transcription

DNA Topoisomerases

Mycobacteria - RNA Polymerase

Mycobacterial DNA Gyrase

Mycobacterium Smegmatis DNA Gyrase

RNA Polymerase-DNA Gyrase Interaction

DNA Topology

DNA Transctions

Cell Biology

Starvation Response In Mycobacterium Smegmatis : A Tale Of Two Proteins

Saraswathi, Ramachandran

02 1900

The Dps (DNA-Binding Protein from Starved Cells) proteins are a class of stress-specific proteins with a major role in protecting DNA during the stationary phase of bacterial growth, through direct physical binding as well as ferroxidation. These proteins are characteristically dodecameric in nature. Mycobacterium smegmatis, which is the model organism used in this study has two Dps homologues- MsDps1 and MsDps2. MsDps1, that has previously been studied, is exceptional in having trimeric as well as dodecameric states in vitro. This work focuses on the functional domains of MsDps1, with respect to its oligomerisation and DNA binding property, the identification of a new Dps homologue MsDps2, the in vitro characterization of MsDps2 and elucidation of a possible function of the protein in the physiology of Mycobacterium smegmatis. The Thesis is organized as shown below: Chapter 1: The literature on the bacterial stationary phase physiology and the role of Dps has been reviewed in this chapter. It gives a brief introduction of the background of the present study including the stationary phase response of bacteria and the significance of studying bacteria under stress as apart from ideal conditions of growth, which has been the conventional approach until recently. The advantages of using Mycobacterium smegmatis as a model system, and its starvation-induced stationary phase are also discussed. An introduction to the Dps proteins as a family of proteins branched off from ferritins and nucleoid proteins is explained. A brief summary of the ferritin and nucleoid proteins is given. Similarities connecting Dps to both these protein families is described. The review of earlier work done in our laboratory on the mycobacterial MsDps1 protein is also presented. Chapter 2: involves the study of the solution properties of the protein including its ability to oligomerize in vitro. The MsDps1 protein exists in two forms, a trimer and a dodecamer. The trimer form is a unique feature of the M.smegmatis homologue. Dps proteins from other sources are characteristically dodecameric. Earlier studies have shown that the trimeric form of the protein can perform ferroxidation while the dodecamer can bind to DNA. The dodecamer can also perform ferroxidation and accumulate the oxidized iron in its negatively charged core. In this chapter, we show that the trimeric form is extremely stable, under various conditions of pHs. The protein, when over expressed in M.smegmatis, also shows the presence of the trimer, thus ruling out the effect of heterologous expression of the protein in E.coli. We further report here, the ideal conditions for dodecamerisation of the protein from trimer to dodecamer, which binds to DNA. The dodecamer once formed is also highly stable and does not revert back to the trimeric form. The structural stability of the dodecamer is expected, as it is the fully functional form of the protein that physically protects the DNA from stress. However, the high stability of the trimeric form and its precise conversion into a stable dodecamer is intriguing. It is interesting to study the functional significance in vivo of the oligomerisation process in MsDps1. In addition, we looked at the effect of over expression of the protein on the overall phenotype of Mycobacterium smegmatis, as evidenced by the colony morphology and find no visible alteration, when compared with the wild type. Chapter 3: deals with a more detailed structural analysis of the MsDps1 protein. The role of N and C termini of the protein in maintaining a stable oligomeric structure is studied by making an N-terminal deletion mutant of the protein which is found to be unable to form a dodecamer in solution. On the other hand, MsDps1 with a 16 amino acid C-terminal deletion, MsDpsΔC16, is able to form stable oligomeric structures, when the N-terminal is intact. A previous deletion reported from our laboratory with 26 amino acids deleted from the C-terminal tail, called MsDpsΔC26 showed inability to form stable oligomeric structures in vitro. Putting together all the above results, a model for the interaction of the N and C-terminal tails of the protein in maintaining a stable dodecamer is presented. A demarcation of the C-terminal tail of MsDps1 into regions determining the oligomeric stability and DNA binding was also inferred. The MsDpsΔC16 protein, does not bind to DNA although it forms a stable dodecamer. A further deletion of 10 amino acids, as seen in a previously made construct, MsDpsΔC26 disrupts both the DNA binding as well as the oligomeric stability of the protein. Chapter 4: describes the discovery of a new homolog of the Dps protein in M.smegmatis. It was named as MsDps2. Bio-informatics analysis carried out on the complete genome data of Mycobacterium smegmatis yielded a second homologue of Dps in addition to the one already present and characterized. Interestingly, out of the 300 homogues of Dps found in bacteria, only 195 are present as single copies in a bacterium. The rest exist as more than one homologue in the same bacterial genome. The basic characterization of this new Dps homologue and its confirmation as a Dps family member is the focus of this chapter. Chapter 5: deals with the possible functions of the new protein MsDps2. Electron micrography shows that the purified protein forms stable nucleoprotein-like complexes. Over expression of the MsDps2 proteins presents no difference in the colony morphology when compared with the wild-type. Western analysis shows that the MsDps2 protein is not expressed under normal conditions tested for growth. MsDps1, on the other hand shows expression under conditions of starvation and osmotic stress, as has been established previously in the laboratory. Hence, it can be inferred that the new protein MsDps2 does not perform the same function as MsDps1. However, the in vivo function of this protein remains an important question to be addressed. The appearance of in vitro nucleoid structures involving this protein under the electron microscope, suggests a possible role for this protein in the formation and stabilization of the mycobacterial nucleoid. Indeed extensive evidence for the same exists for the E.coli protein. Chapter 6: describes the results obtained from the sequence comparison of MsDps2 with other Dps proteins listed in the TIGR database. ClustalW sequence analysis, followed by the construction of a phylogenetic tree using the MEGA software, suggests that the mycobacterial Dps proteins fall into two separate groups, represented by the MsDps1 and MsDps2 homologues from Mycobacterium smegmatis. Chapter 7 Summary and Conclusions: A summary of the work presented in the thesis is given followed by the appendix sections. Appendix 1 includes list and maps of plasmids used. Appendix 2 details the theoretical DNA and protein sequences of the recombinant clones generated in the study and theoretical physical and chemical properties of the proteins studied, as calculated with the Expasy Protparam software. Appendix 3 includes raw data obtained from the bio-informatic analysis of MsDps2, obtained using ClustalW analysis.

Proteins

Mycobacterium Smegmatis

DNA-Binding Proteins From Starved Cells

Dps Proteins - Structural Analysis

Mycobactertial DPS Proteins

Proteins - Oligomerisation

Ferritin Protein

Nucleoid Protein

Mycobactertial MsDps1

Mycobacterial MsDps2

Dps-DNA Binding Protein

Dps

Biochemistry

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

Chowdhury, Rakhi Pait

06 1900

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

Dps Proteins

Mycobacterium smegmatis

Bacterial DNA

Mycobacteria - Gene Expression

Mycobacteria - Gene Regulation

DPs Proteins - Oligomerization

Mycobacteria - Transcriptome Analysis

Mycobacterium-Host Interactions

DNA Binding

msdps Promoter

Mycobacterial MsDps2 Protein

Interface Cluster

M. smegmatis

Molecular Biology

Response of Mycobacterium Tuberculosis to Rifampicin - A Cellular, Molecular, and Ultrastructural Study

Sebastian, Jees

January 2016

Tee PhD thesis presents the study of the response of Mycobacterium tuberculosis, the causative agent of tuberculosis, upon prolonged exposure to lethal concentrations of the first line anti-tuberculosis drug, rifampicin. The study shows that prolonged exposure to lethal concentration of rifampicin causes cell death initially by several log orders of cells, followed by a persistence phase, from where rifampicin resisters emerge carrying mutation in the RRDR locus of the rpoB gene. This phenomenon was found to occur even when the drug concentration is well above MBC levels. Luria-Delbruck experiment, in a modified format, showed that the resisters emerged as fresh mutants, and not due to the growth of pre-existing natural resisters to rifampicin. The per sister cells, which showed high levels of hydroxyl radical generation, were found to have thickened outer layer, unlike the mid-log phase cells, which restricts the permeability of a fluorescent-conjugate of rifampicin, 5-FAM-rifampicin, 10-fold less in per sister cells, as compared to mid-log phase cells. The thickened outer layer has high negative surface charge and is hydrophilic in nature. It is proposed that the hydrophilic-natured thickened outer layer might have restricted the permeability of lethal concentrations of hydrophobic-natured rifampicin. This, in turn, might have ensured the presence of sub-lethal concentration rifampicin inside the per sisters, which in turn might have generated the hydroxyl radical that caused mutagenesis to generate rifampicin resisters. The Chapter 1 is the Introduction to the thesis presented in 4 parts – Part 1.1, 1.2, 1.3 and 1.4, introducing briefly the history of antibiotics, antibiotic resistance, antibiotic persistence and a brief history of tuberculosis respectively. It is concluded with a rationale behind the present study. The Chapter 2 presents the entire Materials and Methods used in the experiments described in the thesis. The Chapter 3 presents the data on the response of M. tuberculosis to rifampicin upon extended exposure. Rifampicin exposure of susceptible M. tuberculosis H37Ra cells showed a decrease in their CFU/ml followed by a persistence phase wherein the CFU/ml remained constant. However, prolonged exposure of rifampicin even at higher concentrations showed regrowth in the culture, which was found to be due to the emergence of rifampicin-resistant bacteria. Screening of rifampicin-resistant mutants showed point mutations in the rifampicin resistance determining region (RRDR) of the rpoB gene in all the mutants. In parallel, using trans formants of M. tuberculosis expressing unstable GFP under the respective native ribosomal RNA promoter, the metabolic status of the per sister cells was determined. When actively growing highly fluorescing cells were exposed to lethal concentration of rifampicin, their metabolism diminished, as illustrated by the decrease in their fluorescence during persistence phase, followed by the emergence of a sub-population of bacteria which were again metabolically active. In order to verify whether the rifampicin resisters are freshly formed mutants or have come from the naturally existing resisters, Luria-Delbruck fluctuation test was performed in a modified manner. The number of rifampicin resisters that emerged from the persistent phase was found to vary amongst different cultures from different days and different times of exposure, showing fluctuation. However, the addition of theorem before persistence phase almost abolished the generation of the rifampicin-resistant bacilli, indicating the role of hydroxyl radical in the emergence of rifampicin resisters. The generation of hydroxyl radical in mycobacteria exposed to rifampicin was confirmed using electron para-magnetic resonance spectrometry (EPR), with the spin trap agent, 5,5- Dimethyl-1-pyrroline N-oxide (DMPO) specific for hydroxyl radical. An increase in the formation DMPO-OH adduct in the persistence phase cells was observed, in comparison to mid-log phase cells. Exposure to theorem significantly diminished the adduct formation. The persistence phase cells also showed significantly high levels of signal specific to the hydroxyl-specific fluorescent dye, hydroxyphenyl fluorescein (HPF), as compared to the mid-log phase cells. In addition we have determined the oxidative stress in the bacilli upon rifampicin exposure using a redox biosensor (Mrx1-roGFP) which also showed high oxidative stress in the persistent phase. These observations confirmed the presence of high levels of oxidative stress and hydroxyl radical in the rifampicin persistent cells, in comparison with mid-log phase cells. Whole genome sequencing of the four independently isolated rifampicin resistant M. tuberculosis showed genome wide mutations having less common mutations with respect to the wild type genome, indicative of the occurrence of random mutagenesis. In addition mutation frequencies were comparable between the samples with respect to the wild type sample. About 69% of the mutations were A-C or T-G, followed by A-T or T-A, which is known to be due to oxidative stress in the cells. Variations in the colony morphology were also observed on the persistent phase cells, indicating the occurrence of mutagenesis in the bacterial genome during rifampicin treatment. The Chapter 4 is on the morphological and ultrastructural studies on rifampicin-exposed M. tuberculosis cells. Transmission electron micrographs of rifampicin per sisters showed significant thickening of the outermost capsular layer (OL), as compared to the mid-log phase cells. This observation was verified by staining the cells with ruthenium red, which specifically stains anionic polysaccharide of the OL. Zeta potential (ZP) measurement of the surface charge of the persistent cells showed high negative ZP, as compared to the mid-log phase cells. The negative ZP value was found to gradually increase during the course of rifampicin treatment and to decrease during the regrowth phase. Hexadecane assay showed larger proportion of per sister cells being retained in the aqueous phase, as compared to the mid-log phase cells. This indicated the higher hydrophilicity of the per sister cells, which was in agreement with the higher surface negative charge of the cells. The permeability of rifampicin per sister cells to 5-FAM-rifampicin (rifampicin conjugated to 5-carboxy fluorescein, which is as hydrophobic as rifampicin) was found to be 10-fold less than that of the mid-log phase cells. However, removal of the thick OL by bead beating (BB) with 4 mm glass beads significantly improved the permeability of per sister cells to 5-FAM-rifampicin. On the contrary, no difference in the 5-FAM-rifampicin uptake was observed in mid-log phase cells, with or without BB. These observations implied that the thick hydrophilic-natured OL with high negative surface charge may be playing a significant role in limiting the permeability of hydrophobic-natured rifampicin entry into the persisted cells. This in turn may ensure the presence of sub-lethal concentration of rifampicin inside the persisted cells that are exposed to lethal concentration of the antibiotic. Exposure of bacteria to sub-lethal concentration of antibiotics has been reported to generate oxidative stress in the bacteria, leading to mutagenesis. A model has been proposed based on these observations in which the persistent mycobacteria are protected from lethal concentrations of the rifampicin by the thick OL which in turn ensures sub-lethal intracellular antibiotic concentration, leading to the generation of hydroxyl radical mediated mutagenesis and thereby emergence of rifampicin resisters. This thesis is concluded with the list of salient findings, publications and references.

Mycobacterium Tuberculosis

Rifampicin

Antibiotic Persistence

Antibiotic Resistance

Mycobacterial Genome

Antibiotic Persistent Bacteria

Rifampicin Resistant

Rifampicin Persistence Phase Cells

Antituberculosis Drug

Mycobacterium tuberculosis - RIF

Rifampicin - Anti-tuberculosis Drug

Rifampicin - M. tuberculosis Cells

Microbiology and Cell Biology

Structural and Related Studies on Mycobacterial Lectins

Patra, Dhabaleswar

January 2014

This thesis is concerned with the first ever X-ray crystallographic and complimentary solution studies on mycobacterial lectins. Lectins, described as multivalent carbohydrate binding proteins of non-immune origin, are found in all kingdoms of life. As explained in the introductory chapter, those from plants and animals are the best characterized in terms of structure and function. Although not that extensive, important studies have been carried out on viral, fungal and parasite lectins as well. Bacterial lectins studied so far can be classified in to fimbrial, surface and secretory (or toxic). Applications of lectins include blood typing, cell separation and purification of glycoconjugates, mitogenic stimulation of lymphocytes, mapping of neuronal pathways and drug targeting and delivery. The work reported in the thesis lies at the intersection of two major long range programs in this laboratory, one on lectins and the other on mycobacterial proteins. Three putative lectins Rv1419 and Rv2813 from M. tuberculosis and MSMEG_3662 from M. smegmatis were chosen for exploratory studies on the basis of preliminary genomic searches. Exploratory studies on Rv1419, Rv2813 and MSMEG_3662 are described in the second chapter. MSMEG_3662 contains two domains, a LysM domain and a lectin domain (MSL) connected by a long polypeptide chain. The two M. tuberculosis proteins, full length MSMEG_3662 and MSL were cloned, expressed, purified and characterized. Rv2813 did not show any appreciable agglutination activity. It showed ATPase activity. Clearly the protein was not a lectin. Rv1419, full length MSMEG_3662 and MSL exhibited lectin characteristics. Among them, Rv1419 and MSL could be crystallized. Preliminary X-ray diffraction studies on them were carried out. Rv1419 could be successfully expressed only once. However, that was enough for the determination of crystal structure and the glycan array analysis of the lectin (Chapter 3). The monomeric lectin has a β-trefoil fold. It has high affinity for LacNAc and its Neu5Ac derivatives. Modeling studies using complexes of homologous structures, led to the identification of two carbohydrate binding sites on the lectins. Sequence comparisons of Rv1419 with homologous proteins with known structures and phylogenetic analysis involving them provide interesting insights into the relationship among trefoil lectins from different sources. X-ray crystal structure analysis of MSL and its complexes with mannose and methyl-α-mannose, the first comprehensive effort of its kind on a mycobacterial lectin, reveals a structure very similar to β-prism II fold lectins from plant sources, but with extensive unprecedented domain swapping in dimer formation (Chapter 4). The two subunits in a dimer often show small differences in structure, but the two domains, not always related by 2-fold symmetry, have the same structure. Each domain carries three sugar-binding sites, similar to those in plant lectins, one on each Greek key motif. The occurrence of β-prism II fold lectins in bacteria, with characteristics similar to those from plants, indicates that this family of lectins is of ancient origin and had evolved into a mature system before bacteria and plants diverged. In plants, the number of binding sites per domain varies between one and three, whereas the number is two in the recently reported lectin domains from Pseudomonas putida and Pseudomonas aeruginosa. An analysis of the sequences of the lectins and the lectin domains shows that the level of sequence similarity among the three Greek keys in each domain has a correlation with the number of binding sites in it. Furthermore, sequence conservation among the lectins from different species is the highest for that Greek key which carries a binding site in all of them. Thus, it would appear that carbohydrate binding influences the course of the evolution of the lectin. LysM domains have been recognized in bacteria and eukaryotes as carbohydrate-binding protein modules, but the mechanism of their binding to chitooligosaccharides is underexplored. Binding of a full length MSMEG_3662 containing LysM and lectin (MSL) domains to chitooligosaccharides has been studied using isothermal titration calorimetry and fluorescence titration (Chapter 5). This investigation demonstrates the presence of two binding sites of non-identical affinities per dimeric MSL-LysM molecule. Affinity of the molecule for chitooligosaccharides correlates with the length of the carbohydrate chain. Its binding to chitooligosaccharides is characterized by negative cooperativity in the interactions of the two domains. Apparently, the flexibility of the long linker that connects the LysM and MSL domains plays a facilitating role in this recognition. The LysM domain in MSL-LysM, like other bacterial domains but unlike plant LysM domains, recognizes equally well peptidoglycan fragments as well as chitin polymers. Interestingly, in the present case two LysM domains are enough for binding to peptidoglycan in contrast to the three reportedly required by the LysM domains of Bacillus subtilis and Lactococcus lactis. Also, the affinity of MSL-LysM for chitooligosaccharides is higher than that of LysM-chitooligosaccharide interactions reported so far. A part of the work presented in this thesis has been reported in the following publications: • Patra D, Mishra P, Surolia A, Vijayan M. 2014. Structure, interactions and evolutionary implications of a domain-swapped lectin dimer from Mycobacterium smegmatis. Glycobiology, 24:956-965. • Patra D, Sharma A, Chandran D, Vijayan M. 2011. Cloning, expression, purification, crystallization and preliminary X-ray studies of the mannose-binding lectin domain of MSMEG_3662 from Mycobacterium smegmatis. Acta Crystallogr Sect F Struct Biol Cryst Commun, 67:596-599. • Patra D, Srikalaivani R, Misra A, Singh DD, Selvaraj M, Vijayan M. 2010. Cloning, expression, purification, crystallization and preliminary X-ray studies of a secreted lectin (Rv1419) from Mycobacterium tuberculosis. Acta Crystallogr Sect F Struct Biol Cryst Commun, 66:1662-1665.

Mycobacterial Lectins

Fimbrial Lectins

X-ray Crystallography

Bacterial Surface Lectins

Secreted Toxic Lectins

Lectins

Mycobacterium Smegmatis Proteins

Mycobacterium Tuberculosis Proteins

Putative Lectins

Carbohydrate-Binding Proteins

Bacterial Proteins

Rv1419

MSMEG_3662

Molecular Biophysics

A Multiscale Modeling Study of Iron Homeostasis in Mycrobacterium Tuberculosis

Ghosh, Soma

January 2014

Mycobacterium tuberculosis (M.tb), the causative agent of tuberculosis (TB), has remained the largest killer among infectious diseases for over a century. The increasing emergence of drug resistant varieties such as the multidrug resistant (MDR) and extremely drug resistant (XDR) strains are only increasing the global burden of the disease. Available statistics indicate that nearly one-third of the world’s population is infected, where the bacteria remains in the latent state but can reactivate into an actively growing stage to cause disease when the individual is immunocompromised. It is thus immensely important to rethink newer strategies for containing and combating the spread of this disease. Extraction of iron from the host cell is one of the many factors that enable the bacterium to survive in the harsh environments of the host macrophages and promote tuberculosis. Host–pathogen interactions can be interpreted as the battle of two systems, each aiming to overcome the other. From the host’s perspective, iron is essential for diverse processes such as oxygen transport, repression, detoxification and DNA synthesis. Infact, during infection, both the host and the pathogen are known to fight for the available iron, thereby influencing the outcome of the infection. It is of no surprise therefore, that many studies have investigated several components of the iron regulatory machinery of M.tb and the host. However, very few attempts have been made to study the interactions between these components and how such interactions lead to a better adapted phenotype. Such studies require exploration at multiple levels of structural and functional complexity, thereby necessitating the use of a multiscale approach. Systems biology adopts an integrated approach to study and understand the function of biological systems. It involves building large scale models based on individual biochemical interactions, followed by model validation and predictions of the system’s response to perturbations, such as a gene knock-out or exposure to drug. In multiscale modeling, an approach employed in this thesis, a particular biological phenomenon is studied at different spatiotemporal levels. Studying responses at multiple scales provides a broader picture of the communications that occur between a host and pathogen. Moreover, such an analysis also provides valuable insights into how perturbation at a particular level can elicit responses at another level and help in the identification of crucial inter-level communications that can possibly be hindered or activated for a desired physiological outcome. The broad objectives of this thesis was to obtain a comprehensive in silico understanding of mycobacterial iron homeostasis and metabolism, the influence of iron on host-pathogen interactions, identification of key players that mediate such interactions, determination of the molecular consequences of inhibiting the key players and finally the global response of M.tb to altered iron concentration. Perturbation of iron homeostasis holds a strong therapeutic potential, given its essentiality in both the host and the pathogen. Understanding the workings of iron metabolism and regulation in M.tb has been a main objective, so as to ultimately obtain insights about specific therapeutic strategies that capitalize on the criticality of iron concentration. An in-depth study of iron metabolism and regulation is performed at different levels of temporal and spatial scales using diverse methods, each appropriate to investigate biological events associated with the different scales. The specific investigations carried out in the thesis are as follows, a) Reconstruction of a host-pathogen interaction (HPI) model, with focus on iron homeostasis. This study represented the inter-cellular level analysis and was crucial for the identification of key players that mediate communication between the host and pathogen. Additionally, the model also provided a mathematical framework to study the effect of perturbations and gene knock-outs. b) Understanding the influence of iron on IdeR, an iron-responsive transcription factor, also identified as a key player in the HPI model. The study was carried out at the molecular level to identify atomistic details of how IdeR senses iron and the resulting structural modifications, which finally enables IdeR-DNA interaction. The study enabled identification of residues for the functioning of IdeR. c) Genome scale identification of genes that are regulated by IdeR to obtain an overview of the various biological processes affected by changing iron concentrations and IdeR mutation in M.tb. d) To understand the direct and indirect influences of iron and IdeR on the M.tb proteome using large scale protein-protein interaction network. The study enabled identification of highest differentially regulated genes and altered activity of the different biological processes under differing iron concentrations and regulation. e) Systems level analysis of the M.tb metabolome to investigate the metabolic re-adjustments undertaken by M.tb to adapt to altered iron concentration and regulation. The conceptual details and the background of each of the methods used to study the specific aims are provided in the Methodology chapter (Chapter 2). Construction of the host-pathogen interaction (HPI) model and the insights obtained from this study are presented in Chapter 3. A rule based HPI model was built with a focus on the iron regulatory mechanisms in both the host and pathogen. The model consisted of 194 rules, of which 4 rules represented interactions between the host and pathogen. The model not only represented an overview of iron metabolism but also allowed prediction of critical interaction that had the potential to form bottleneck in the system so as to control bacterial proliferation. Infact, model simulation led to the identification of 5 bottlenecks or chokepoints in the system, which if perturbed, could successfully interfere with the host-pathogen dynamics in favour of the host. The model also provided a framework to test perturbation strategies based on the bottlenecks. The study also established the importance of an iron responsive transcription factor, IdeR for regulating iron concentration in the pathogen and mediating host-pathogen interactions. Additionally, the importance of mycobactin and transferrin as key molecular players, involved in host-pathogen dynamics was also determined. The model provided a mathematical framework to test TB pathogenesis and provided significant insights about key molecular players and perturbation strategies that can be used to enhance therapeutic strategies. Given the importance of IdeR in HPI, its molecular mechanism of activation and dimerization was explored in Chapter 4. The main objective of the study was to explore the structural details of IdeR and its iron sensing capacity at the molecular level. A combination of molecular dynamics and protein structure network (PSN) were used to analyse IdeR monomers and dimers in the presence and absence of iron. PSNs used in this thesis are based on non-covalent interactions between sidechain atoms and are quite efficient in identifying iron induced subtle conformational variations. The study distinctly indicated the role of iron in IdeR stability. Further, it was observed that IdeR monomers can take up two major conformations, the ‘open’ and ‘close’ conformation with the iron bound structure preferring the ‘close’ conformation. Major structural changes, such as the N-terminal folding and increased propensity for dimerization were observed upon iron binding. Interestingly, careful analysis of structure suggests a role of these structural modifications towards DNA binding and has been tested in the next chapter. Overall, the results clearly highlight the influence of iron on IdeR activation and dimerization. The predisposition of IdeR to bind to DNA in the presence of metal is clearly visible even when the simulations are performed solely on protein molecules. However, to confirm the conjectures proposed in this chapter and to obtain the atomistic details of IdeR-DNA interactions, the IdeR-DNA complex was investigated. Chapter 5 focuses on the mechanistic details of IdeR-DNA interactions and the influence of iron on the same. IdeR is known to bind to a specific stretch of DNA, known as the ‘iron-box’ motif to form a dimer-of-dimer complex. Molecular dynamics followed by protein-DNA bipartite network analysis was performed on a set of four IdeR-DNA complexes to obtain a molecular level understanding of IdeR-DNA interactions. A striking observation was the dissociation of IdeR-DNA complex in the absence of iron, undoubtedly establishing the importance of iron for IdeR-DNA binding. At the residue level, hydrogen bond and non-covalent interactions clearly established the importance of N-terminal residues for DNA binding, thereby confirming the conjecture put forth in the previous chapter. An important aspect studied in this chapter is the allosteric nature of IdeR-DNA binding. Recent years have witnessed a paradigm shift in the understanding of allostery. Unlike the classical definition of allostery that was based on static structures, the newer definition is based on the conformational ensemble as represented by the shift in the energy landscape of the protein. The allosteric nature of IdeR-DNA complex was probed using simulated trajectories and indeed they suggest iron to be an allosteric regulator of the protein. Finally, based on the known experimental data and observations presented in Chapters 4 and 5, a multi-step model of IdeR activation and DNA binding has been proposed. In chapter 6, a global perspective of IdeR regulation in M.tb was obtained. This was important to gain insights about the influences of iron and its regulation at the M.tb cellular level. A genome scale identification of all possible IdeR targets based on the presence of ‘iron-box’ motif in the promoter region of the genes was carried out. An interesting aspect of this study was the use of energetic information from previous molecular dynamics study as an input for generation of the motif. A total of 255 such IdeR targets were identified and converted into an IdeR target network (IdeRnet). Along with IdeRnet, an unbiased systems level protein-protein interaction network was also generated. To study the response of the pathogen to external perturbations, iron-specific gene expression data was integrated into the network as node weights and edge weights. Analysis of IdeRnet provides interesting associations between fatty acid metabolism and IdeR regulations. Specific genes such as fadD32, DesA3 or lppW have been found to be affected by IdeR mutation. While IdeRnet discusses the direct associations, the global level responses are monitored by analysing pathways for the flow of information in the protein-protein interaction network (PPInet). Comparisons of the PPInets under conditions such as altering iron concentrations and lack of iron homeostasis led to the identification of the ‘top-most’ active paths under the different conditions. The study clearly suggests a halt in the protein synthesis machinery and decreased energy consumption under iron scarcity and an uninhibited consumption of energy when iron homeostasis is perturbed. In the final chapter (Chapter 7), flux balance analyses has been used to investigate the influence of iron on M.tb metabolism. The importance of iron for metabolic enzymes has already been established in the previous chapter. Additionally, M.tb is known to produce siderophores, an important metabolite that requires amino acids as its precursors, for iron extraction. All this, together highlighted the importance of iron and its regulation of M.tb metabolism. Flux balance analysis has been used previously to study the metabolic alterations that occur in an organism under different conditions. For this study, iron specific gene expression data was also incorporated into the model as reaction bounds and the flux values so obtained were compared in different environmental conditions. The study provided valuable insights into the metabolic adjustments taken up by M.tb under iron stress conditions and correlates well with the responses observed from the interactome as well as experimental observations. Most significantly, changes were observed in the energy preferences of the cell. For instance, it was noted that while the wild type strain of M.tb prefers synthesis of ATP via glycolysis, the IdeR mutant strain preferred oxidative phosphorylation. The picture becomes clearer when one accounts for the uncontrolled utilization of energy and rapid activation of protein synthesis machinery in the IdeR mutant strain. Biological systems are inherently multiscale in nature and therefore for a successful drug target regime, analysis of the genome to the phenome, which captures interactions at multiple levels, is essential. In this thesis, a detailed understanding of iron homeostasis and regulation in M.tb at multiple levels has been attempted. More importantly, insights obtained from one level, formed questions in the next level. The study was initiated at the inter-cellular level, where the influence of iron on HPI was modeled and analysed. From this study, IdeR, an iron-responsive transcription factor was identified as a key player that had the potential to alter host-pathogen interactions in the favour of the host. For a complete understanding of how IdeR regulates iron homeostasis, it was imperative to obtain a molecular level insight of its mechanism of action. Finally, the various aspects of IdeR regulation were investigated at the cellular level by analysing direct and indirect influences of IdeR on M.tb proteome and metabolome. The study suggests certain therapeutic interventions, such as 1) reduction in the concentration of free transferrin various, 2) mutations at the N-terminal sites of IdeR, 3) regulation of proteins involved in production of mycolic acids by iron and 4) perturbation of altering energy sources, which capitalize on iron and should be investigated in detail. In summary, the consequences of iron on TB infection were studied by threading different levels. This is based on the belief that most biological functions involve multiple spatio-temporal levels with frequent cross talks between the different levels, thereby making such multiscale approaches very useful.

Mycobacterium Tubercolosis

Mycobacterial Iron Homeostasis

Systems Biology

Host-Pathogen Interaction (HPI) Model

Protein Structure Network

Molecular Dynamics

Tuberculosis Infections

Protein Interaction Networks

Iron Dependant Repressor

IdeR-DNA Interactions

Tuberculosis - Iron Homeostasis

IdeR

Molecular Biophysics