Lip Y, The PE Family Triacylglycerol Hydrolase From Mycobacterium Tuberculosis : Functional Role Of The PE Domain And Immunogenicity

Mishra, Kanhu Charan

03 1900

More human lives have been lost to tuberculosis than to any other disease and despite the availability of effective short course chemotherapy (DOTS) as well as the Bacilli Calmette Guerin (BCG) vaccine, tuberculosis continues to claim more than a million lives annually. Mycobacterium tuberculosis (M. tuberculosis), the causative agent of tuberculosis, is one of the most successful and scientifically challenging pathogens of all time. However in the last two decades, the ability to perform molecular genetic analysis of M. tuberculosis has resulted in powerful new research tools, while the availability of the complete genome sequence has provided us with a wealth of new information and understanding of the biology of this major pathogen. One of the major challenges, however, is to analyze the properties and functions of those genes that are unique to M. tuberculosis genome. The identification and characterization of such genes which impart various survival strategies employed by M. tuberculosis for successful infection will be of particular significance. One of the important outcomes from the complete genome sequence of M. tuberculosis is the discovery of two multigene families designated PE (99 members) and PPE (69 members) named respectively for the Pro-Glu (PE) and Pro-Pro-Glu (PPE) motifs near the N-terminus of their gene products. In addition to these motifs, proteins of the PE family possess highly homologous N-terminal domains of approximately 100 amino acids (PE domain), whereas the PPE proteins possess a highly homologous N-terminal domain of about 180 amino acids (PPE domain). Although the PE and PPE families of mycobacterial proteins are the focus of intense research, no precise function has so far been unraveled for any member of these families. The current study focuses on Rv3097c gene of M. tuberculosis, a PE family gene that was bioinformatically predicted to be a triacylglycerol hydrolase (lipase). In order to decipher the role of the PE domain, we have carried out functional characterization of the Rv3097c gene (also named lipY) as it was, initially, the only known PE protein for which an enzymatic function (i.e. lipase activity) had been predicted. Further, to understand the function of PE family proteins, an important question that needs to be answered is; whether the PE domain of different PE family proteins has similar or different functions? In this context, our studies were focused on studying the functional role of the PE domain in LipY, as outlined below. In general, the in vivo function and subcellular localization of any protein are integrally connected. PE domain has been reported to be essential for cell wall localization of PE_PGRS33, another PE family protein. Therefore we investigated the subcellular localization of LipY and the influence of the PE domain on subcellular localization of LipY. LipY and a truncated form of LipY lacking the PE domain [LipY(ΔPE)] were expressed in mycobacteria(M. smegmatis and M. bovis BCG). Subcellular fractionation and western blot demonstrated that both LipY and LipY(ΔPE) were predominantly detected in the cell wall fraction, indicating that LipY is localized to the cell wall and the PE domain of LipY was not required for translocation of LipY to cell wall. This result is in contrast to the findings for PE_PGRS33, where the absence of the PE domain caused the cell wall associated protein to localize to the cytosol. Furthermore, immuno-electron microscopy of M. bovis BCG expressing LipY(ΔPE) clearly showed a cell surface localization of LipY(ΔPE). These results signify that the function of the PE domain might not always be similar amongst different PE family proteins. In order to further investigate the role of the PE domain in LipY, we studied the lipase activity of LipY and the influence of the PE domain on lipase activity. Bioinformatic analysis confirmed the presence of a lipase domain containing a GDSAG active site motif characteristic of lipases. Overexpression of LipY in mycobacteria (M. smegmatis and M. bovis BCG) resulted in a significant reduction in the pool of triacylglycerols (TAG), consistent with the lipase activity of this enzyme. Interestingly, this reduction was more pronounced in mycobacteria overexpressing LipY(ΔPE), suggesting that the presence of the PE domain diminishes the lipase activity of LipY. In vitro lipase assays also confirmed LipY(ΔPE) as a more efficient lipase compared to the wild-type LipY. Together these results suggest that the PE domain of LipY might be involved in the modulation of lipase activity. Surprisingly, M. marinum, another pathogenic mycobacteria, possesses a protein homologous to LipY, termed LipYmar, in which the PE domain is substituted by a PPE domain. The overexpression of LipYmar in M. smegmatis significantly reduced the TAG pool suggesting that it is a triacylglycerol hydrolase/lipase. Interestingly, similar to the removal of the PE domain of LipY, this reduction in the TAG pool was further pronounced when the PPE domain of LipYmar was removed. This suggests that PE and PPE domains might share similar functional roles in modulating the enzymatic activities of these lipase homologs. In order to assess the in vivo relevance of LipY expression during M. tuberculosis infection, we examined the humoral immune responses against LipY in sera derived from various clinical categories of tuberculosis patients. The presence of specific antibodies against any protein is suggestive of expression of the protein during infection and could potentially be used to differentiate between healthy individuals and infected patients (serodiagnosis of tuberculosis). The cell wall localization suggested that LipY may be accessible for interaction with the host immune system during infection. Moreover, humoral responses were observed against LipY in mice immunized with DNA constructs expressing LipY, indicating that LipY could be an effective B-cell antigen. Accordingly, a strong humoral response against LipY and LipY(ΔPE) was observed in tuberculosis patients compared to healthy individuals, suggesting that LipY is expressed during infection by clinical strains of M. tuberculosis and might represent an immunodominant antigen of M. tuberculosis with potential use in serodiagnosis of tuberculosis.

Tuberculosis - Immunogenicity

Triacylglycerol Hydrolase

Mycobacterium Tuberculosis

Tuberculosis - Pathogenesis

Proline-Glutamate Motif(PE)Genes

LiPY - PE Domains/Proteins

PE Antigens

LipY

M. tuberculosis

Microbiology

Structural And Biophysical Analysis Of The Regulatory Mechanism Of Mycobacterium Tuberculosis Sigma Factors

Gopal, Krishan

08 1900

Mycobacterium tuberculosis has one ribosomal RNA operon. The survival of this bacillus thus depends on a transcription mechanism that can effectively couple gene expression to changes in the environment. σ factors are transcription proteins that bind to the RNA polymerase (RNAP) and dictate gene expression. Extra Cytoplasmic Function σ factors (ECF) are a subset of σ factors that coordinate environment-induced changes in transcription. The environment specific binding of ECF σ factors to the RNAP presents an effective mechanism for the bacillus to modulate gene expression. ECF σ factors, in turn, are regulated by their interaction with an anti-σ factor. The active σ factor is released from this complex upon specific cellular or environmental stimuli. The aim of this study was to understand the structural and mechanistic aspects of σ factor activation. Towards this goal, two ECF σ factors, σC and σL, were examined. Structural and biophysical studies on M. tuberculosis σC provided a novel insight into ECF σ factor regulation. Inter-domain interactions in σC were sufficient to occlude the DNA recognition regions even in the absence of an interacting protein. The structure of M. tuberculosis σL in complex with the anti-σ factor RslA provides a structural basis to rationalize the release of active σL under oxidative stress. The other chapters of this thesis include a description of the structure and biochemical features of a hypothetical protein Rv2704 that is co-transcribed with the primary σ factor σA. In an effort to understand the collaboration-competition-redundancy model of prokaryotic σ factors, we performed a computational analysis of this system compiling experimental data from the E. coli and B. subtilis model systems. These results are also presented in this thesis. Put together, the structural and biochemical characteristics of the σ factors presented in this thesis suggest substantial variations in the regulatory mechanisms of the M. tuberculosis σ factors when compared to the canonical E. coli or B. subtilis model systems. This thesis is organized as follows: Chapter 1: The introductory chapter of this thesis is organized to frame the pertinent mechanistic issues involved in the σ factor-regulatory protein interactions in the context of the underlying biology of M. tuberculosis. The first part of this chapter provides an overview of σ factors and a summary of the classification of these proteins and their roles in different prokaryotes. The latter part of this chapter is a summary of the pathogen M. tuberculosis in terms of its genetic composition, gene expression as well as aspects of virulence and pathogenecity. Chapter 2: This chapter describes the characterization of the ECF σ factor, σC. Here we report the structure of an ECF σ factor σC from M. tuberculosis. σC is essential for the lethality of M. tuberculosis in a mouse model of infection. Our studies suggest that M. tuberculosis σC differs from the canonical ECF σ factors as it has an N-terminal domain comprising of 126 amino acids that precedes the σC2 and σC4 domains. In an effort to understand the regulatory mechanism of this protein, the crystal structures of the σC2 and C4 domains of σC were determined. These promoter recognition domains are structurally similar to the corresponding domains of E. coli σA despite the low sequence similarity. Fluorescence experiments using the intrinsic tryptophan residues of σC2 as well as surface plasmon resonance measurements reveal that the σC2 and σC4 domains interact with each other. Mutational analysis suggests that the Pribnow box-binding region of σC2 is involved in this inter-domain interaction. Interactions between the promoter recognition domains in M. tuberculosis σC are thus likely to regulate the activity of this protein even in the absence of an anti-σ factor. Chapter 3 provides an account of the regulatory features of the ECF σ factor, σL. ECF σ factors are often regulated by their interactions with an anti-σ factor that can sense diverse environmental stimuli. Transcriptional responses to changes in the oxidation state are particularly important for M. tuberculosis as it adapts to the environment of the host alveoli and macrophages. Here we demonstrate that the protein RslA binds Zinc and can sequester σL in a reducing environment. Our data suggests that the cytosolic domain at the N-terminus of RslA alone is involved in binding σL. Under oxidizing conditions, the σL/RslA complex undergoes substantial conformational rearrangements that coincide with the release of the Zinc cofactor. In the absence of Zinc, the affinity of RslA for σL reduces by ca 8 fold compared to the holo form. The CXXC motif of RslA acts as a redox sensor. In response to oxidative stimuli, the proximal cysteines in this motif can form a disulfide bond with the release of the bound Zn2+ ion. This observation could be rationalized based on the crystal structure of the σL4/RslA complex. Put together, RslA is a distinct variant of the Zinc binding anti-σ factor (ZAS) family. The structural and biophysical parameters that control σL/RslA interactions demonstrate how variations in the rate of Zinc release and associated conformational changes in RslA could regulate the release of free σL in a measured response to oxidative stress. Chapter 4 is based on the biochemical and structural characterization of a hypothetical protein Rv2704. The gene for M. tuberculosis Rv2704 is located in the same operon as the principal σ factor σA. The biochemical and structural features of Rv2704 were thus examined to identify its role, if any, in the regulation of σA. This protein is a trimer in solution and adopts a chorismate mutase-like fold. The crystal structure reveals that Rv2704 is a member of the functionally diverse YjgF family of proteins. The important structural differences between Rv2704 and other YjgF proteins lie in the arrangement of secondary structural elements and the putative functional clefts between the subunit interface. Although Rv2704 does not interact with σA in vitro, the structural similarities to the YjgF family suggests that this protein could interact with a variety of metabolites, potentially influencing its function. Chapter 5 of this thesis is based on a computational analysis of σ factors. Four conformational segments of σ factors, referred to as σ1, σ2, σ3 and σ4 interact with specific regions of promoter DNA. ECF σ factors are a subset of σ factors that coordinate environment-induced transcription. ECF σ factors are minimalist σ factors with two DNA binding domains viz., σ2 and σ4 that recognize the –10 and –35 promoter elements and are unable to interact with either upstream-activating regions or the extended –10 element of the promoter. There are several ECF σ factors in a typical bacterium often characterized by substantial overlap in function. Here we present an analysis of B. subtilis ECF σ factors and their cognate promoters to understand functional overlap and redundancy in this class of proteins. As expected, conserved bases in the –10 element appear more critical for promoter selectivity than the –35 element. However, we note distinct conformational features in the –35 promoter interaction with the helix-turn-helix (HTH) motif when compared to a data-set of known HTH-DNA complexes. Furthermore, we note differences in –35 element interaction between σ factors that act alone and those that overlap in function. The σ factor promoter interactions were then examined vis-à-vis the estimated cellular concentration of these proteins and their affinity to bind the core RNAP. Put together, this analysis suggests that while the cellular protein concentration dictates the choice of an ECF σ factor to form a complex with the RNAP, conformational features of the –35 element serve to select potential collaborative members, a subset of which eventually initiate transcription. Collaborative arrangements and functional redundancy in ECF σ factors are thus possible within the limits placed by these two parameters. Chapter 6 is a summary of the work reported in this thesis and the conclusions that can be drawn based on these studies. The appendix section of this thesis comprises of technical details that were not included in the main text of this thesis. Appendix I describes the initial characterization of the M. tuberculosis σD/anti-σD complex. Appendix II provides the experimental protocols as well as some of the supplementary data to the work reported in Chapters 2-5 of this thesis.

Biophysics

Sigma Factor

Mycobacterium Tuberculosis

Extra Cytoplasmic Function Sigma Factors

Gene Expression

Gene Transcription-Regulation

Protein-RNA Binding

Transcription Proteins

Sigma Factors - Regulation

Sigma Factors - Computational Analysis

M. tuberculosis RslA

σ Factors

Bacteriology

Functional Characterization Of Rv0754(PE_PGRS11) : A Multifunctional PE_PGRS Protein From Mycobacterium Tuberculosis

Chaturvedi, Rashmi

07 1900

Mycobacterium tuberculosis, the causative agent of pulmonary tuberculosis, infects one-third of the world’s human population. Despite the multiplicity of antimicrobial mechanisms mounted by its host, M. tuberculosis shows a remarkable ability to survive either by evoking survival strategies or by interference with critical macrophage functions that are required to successfully respond to the infection. It has been postulated that the outcome of exposure to M. tuberculosis (in terms of disease symptoms) largely depends upon the selective gene expression of tuberculosis bacilli along with activation of specific signaling pathways in the infected host cells during different phases of infection. In this perspective, determination of the complete genome sequence of Mycobacterium tuberculosis has provided crucial information with respect to the physiology of this bacterium and the pathogenesis of tuberculosis. However, putative functional annotation to all hypothetical proteins coded by M. tuberculosis genome remains complex. One important outcome of the genome-sequencing project was the discovery of two new multigene families designated PE and PPE. About 10% of the M. tuberculosis coding capacity is devoted to the PE and PPE genes, named for the Pro-Glu (PE) and Pro-Pro-Glu (PPE) motifs near the N terminus of their gene products. In addition to these motifs, proteins of PE family share N-terminal domains of approximately 100 amino acids, whereas the PPE proteins possess an N-terminal domain of about 180 amino acids. Many PE and PPE proteins are composed only of these N-terminal homologous domains. However, other members possess an additional C-terminal segment of variable length, often composed of multiple copies of polymorphic GC rich sequences (PGRS). The uniqueness of the PE genes is further illustrated by the fact that these genes are restricted to mycobacteria. However, despite their abundance in mycobacteria, very little is known regarding the expression or the functions of PE family genes. Although the PE and PPE families of mycobacterial proteins are the focus of intense research, no precise function has so far been unraveled for any member of these families. In perspective of above-mentioned observations, we have chosen Rv0754 as a representative PE family gene. Rv0754 was shown to be upregulated in tubercle bacilli upon infection of bone marrow derived macrophages as well as in M. tuberculosis isolated from alveolar macrophages of infected mice. In the current investigation, we demonstrate that Rv0754 is hypoxia responsive gene based on promoter or transcript expression analysis. Further, extensive bioinformatics analysis predicated that Rv0754 posses possible Phosphoglycerate Mutase domain, an enzyme known for its significant role not only in the glycolytic pathway of the carbohydrate metabolism, but also for the crucial cell fate decision during conditions like oxidative stress as well as infection. Experimental data clearly suggests that hypoxic environment dependent expression of Rv0754 imparts resistance to macrophages from oxidative stress. These findings could be attributed to the presence of catalytically active Phosphoglycerate Mutase domain of Rv0754. More often, sophisticated regulation/modulation of key signaling events regulate the critical cell fate decisions during oxidative stress. In this context, TLR2 dependent triggering of PI3K-ERK1/2- NF-κB signaling axis by Rv0754 may be operative in imparting resistance to oxidative stress. Further, Rv0754 triggers COX-2 expression by activating PI3K-ERK1/2-NF-κB cascade in mouse macrophages. These observations are of relevance as Rv0754 is associated with cell wall and is exposed outside the surface of the bacterium suggesting the possible access to intracellular compartments of the infected macrophages. Additionally, Rv0754 elicited humoral antibody reactivities in a panel of human sera or in cerebrospinal fluid samples obtained from different clinical categories of tuberculosis patients. DNA immunizations experiments in mice clearly suggested that Rv0754 is an immunodominant antigen demonstrating significant T cell and humoral reactivity. These observations clearly advocate that Rv0754 protein is expressed in vivo during active infection with M. tuberculosis and that the Rv0754 is immunogenic. Taken together, our findings suggest that Rv0754 is a novel PE_PGRS protein with unique features which could generate conditions that favor survival of the mycobacteria.

PE-PGRS Protein

Mycobacterium Tuberculosis

Multifunctional Protein

Rv0754 Protein

Oxidative Stress

P13 Kinase

Mycobacteria

Rv1818c

Phosphoglycerate Mutase (PGM)

Microbiology

Targeting Infectious Disease : Structural and functional studies of proteins from two RNA viruses and Mycobacterium tuberculosis

Jansson, Anna M.

January 2013

The recent emergence of a number of new viral diseases as well as the re-emergence of tuberculosis (TB), indicate an urgent need for new drugs against viral and bacterial infections. Coronavirus nsp1 has been shown to induce suppression of host gene expression and interfere with host immune response. However, the mechanism behind this is currently unknown. Here we present the first nsp1 structure from an alphacoronavirus, Transmissible gastroenteritis virus (TGEV) nsp1. Contrary to previous speculation, the TGEV nsp1 structure clearly shows that alpha- and betacoronavirus nsp1s have a common evolutionary origin. However, differences in conservation, shape and surface electrostatics indicate that the mechanism for nsp1-induced suppression of host mRNA translation is likely to be different in the alpha- and betacoronavirus genera. The Modoc virus is a neuroinvasive rodent virus with similar pathology as flavivirus encephalitis in humans. The flaviviral methyltransferase catalyses the two methylations required to complete 5´ mRNA capping, essential for mRNA stability and translation. The structure of the Modoc NS5 methyltransferase domain was determined in complex with its cofactor S-adenosyl-L-methionine. The observed methyltransferase conservation between Modoc and other flaviviral branches, indicates that it may be possible to identify drugs that target a range of flaviviruses and supports the use of Modoc virus as a model for general flaviviral studies. 1-deoxy-D-xylulose 5-phosphate reductoisomerase (DXR) is part of the methylerythritol phosphate (MEP) pathway that produces essential precursors for isoprenoid biosynthesis. This pathway is used by a number of pathogens, including Mycobacterium tuberculosis and Plasmodium falciparum, but it is not present in humans. Using a structure-based approach, we designed a number of MtDXR inhibitors, including a novel fosmidomycin-analogue that exhibited improved activity against P.falciparum in an in vitro blood cell growth assay. The approach also allowed the first design of an inhibitor that bridge both DXR substrate and co-factor binding sites, providing a stepping-stone for further optimization.

RNA virus

coronavirus

alphacoronavirus

nsp1

TGEV

flavivirus

Modoc virus

NS5

methyltransferase

mRNA capping

Mycobacterium tuberculosis

tuberculosis

DXR

fosmidomycin analogues

MEP pathway

drug development

xray-crystallography

T Cell Epitopes Of PE And PPE Family Of Proteins Of Mycobacterium Tuberculosis And Analysis Of Their Vaccine Potential

Chaitra, M G

04 1900

One-third of the world’s population is latently infected with Mycobacterium tuberculosis, which causes over 2 million deaths every year. The current live attenuated vaccine, Bacille Calmette-Guerin (BCG), protects against miliary tuberculosis in children, but fails to consistently protect against pulmonary tuberculosis in adults. The global resurgence of tuberculosis, together with the HIV pandemic and emerging multi-drug resistance, has heightened the need for an effective vaccine. Completion of the M. tuberculosis genome sequence paved way for identification of many new candidate antigens for protective vaccine against tuberculosis. This includes the discovery of two multigene families of proteins PE and PPE which constitute 10% of the coding capacity of the M. tuberculosis genome. Members of the PE and PPE protein families are characterized by highly conserved N-terminal domains and the C-terminus, however, exhibit considerable variation in the number of residues as well as in the sequence. Till date, little is known about the functional role of the proteins of PPE or PE family in the biology of M.tuberculosis. Some of the PE_PGRS proteins have been found to be associated with the cell wall and influence interactions with other cells. PE and PPE family of proteins are of potential interest from the point of view of immune response, since they show antigenic variation which may play a role in immune evasion. Very little is known about the immunogenecity of these two classes of proteins and only few proteins have been shown to be potent B or T cell antigens, like Rv3873, Mtb39 and Rv0915c. Two proteins from PE_PGRS subfamily, Rv1759c and Rv3367 are expressed during infection and show antibody response in humans and rabbits, respectively. Rv1196 and Rv0915c from PPE family have been shown to be good T cell antigens. Another study has shown that the PE domain of PE_PGRS protein Rv1818c upon immunization into mice induces good cell mediated immune response in mice, whereas the PGRS domain is responsible for good humoral response. In humans there is increasing evidence to suggest that CD8+ T cells are elicited in response to infection with mycobacteria. CD8+ CTL may play an important role through several mechanisms. They produce potent anti-bacterial cytokines such as IFN-γ and TNF-α in response to antigenic stimulation and IFN-γ is critical for immunity to TB. Thus, identification of antigens and peptides that induce T cell responses could be useful for designing new vaccines to protect against TB. Relatively few epitopes in mycobacterial antigens have so far been identified for human CD8 T cells. In this regard, release of genome sequences of M. tuberculosis has provided an opportunity to identify proteins with vaccine potential that could give immune protection in individuals with different HLA backgrounds. Objectives and scope of the present work 1. Prediction of putative T cell antigens in PE and PPE family of proteins of Mycobacterium tuberculosis through immuno-informatics approach 2. Evaluation of immune response to three of the PE and PPE proteins in mouse model. 3. Evaluation of immune response against chosen PE and PPE proteins of Mycobacterium tuberculosis with Human Peripheral Blood Mononuclear Cells (PBMCs) from PPD positive healthy donors and TB patients. 4. Immune response to multi-epitope DNA vaccine construct for Mycobacterium tuberculosis. Prediction of MHC class I peptides from PE and PPE proteins. In an effort to identify potential T cell antigens from PE and PPE family of proteins, we have carried out a systematic in silico analysis of the 167 different PE and PPE proteins. Employing immuno-informatics approach, a set of HLA class I binding peptides have been identified from these proteins. Further, their binding abilities have been ascertained using independent methods such as molecular modeling and structural analysis methods. The nonameric sequences from PE and PPE families of proteins were predicted to contain high percentage of binding peptides to human class I HLA, whereas PE_PGRS proteins show relatively low level of binding. This difference is seen in spite of PE and PE_PGRS being Sub-families of the same family, PE. Seventy-one high- as well as low-affinity peptides from both PE and PPE proteins have been analyzed for structural compatibility with crystal structures of HLA in terms of intermolecular energies and were found to correlate well with the corresponding affinities predicted by the BIMAS algorithm. Most of the peptides binding to HLA are specific with very few promiscuous binders. Identification of T cell epitopes from three of the PE/PPE proteins using DNA immunization This work describes the evaluation of immune responses to three of the PE and PPE proteins in mouse model. Three of PE and PPE proteins, coded by Rv1818c, Rv3812 and Rv3018c genes were chosen based on immuno-informatics approach. They were cloned, expressed in prokaryotic and mammalian expression vectors and recombinant protein expressing stable cell lines were made. T lymphocytes from DNA immunized mice recognize synthetic peptides from chosen proteins in vitro, indicating that these peptides are being processed and presented by MHC molecules to T cells. By MHC stabilization assay, 5 of the synthetic peptides were found to stabilize the MHC class I molecules on the cell surface for more than 6 hrs, validating the computational prediction. Recognition of T cell epitopes derived from PE/PPE proteins by human PBMCs This work describes the evaluation of immune response against three of PE and PPE proteins of Mycobacterium tuberculosis with Human Peripheral Blood Mononuclear Cells (PBMCs) from PPD positive Healthy donors and TB patients. Proliferation response of PBMCs from ten PPD positive healthy donors as well as from ten TB patients, indicated that the peptides from PE and PPE proteins of Mtb can sensitize naive T cells and induce peptide specific IFN-γ and also the T cell response to the chosen peptides was both HLA class I restricted and CD8 mediated. After the peptide specific expansion, significant percentage of CD8+ T cells were shown to secrete IFN-γ and stained positive for perforin. Antigen specific CD8+ T cells were found to have cytolytic potential in addition to their cytokine function. Immune response to a multiepitope DNA vaccine in mouse model Minigene poly-epitope vaccine constructs coding for nine peptides derived from identified T cell antigens of PE and PPE proteins and three of the experimentally mapped epitopes from M tuberculosis was designed and constructed. The minigene was used to immunize mice and the immune response was tested. The DNA primed splenocytes recognized the full length poly-epitope protein as well as the individual peptides. T cell response to epitopes was enhanced by mere presence in multi-epitope construct compared to full length antigens. Human PBMCs derived from both PPD+ve and TB patients also recognized the peptides in vitro. It is thus obvious that a large cocktail of proteins are required to achieve reasonable population coverage. Besides, this work suggests the feasibility of designing haplotype specific subunit vaccine, which can be given to individuals with known HLA haplotype. The haplotype specific vaccines can be combined to target a population where the distribution of HLA alleles is known. This work also indicates that use of single or limited number of genes in a DNA vaccine may not be suitable to cover a given population.

T Cellls

Human Immunology

Proteins

Vaccines

Anti-Microbial Effect

Mycobacterium Tuberculosis

Proline-Glutamic Acid Motif Proteins

Pro-Pro-Glu Motif Proteins

T Cell Epitopes

PE Family

PPE Family

Multiepitope DNA Vaccine

Pathology

Evaluation of molecular methods used for the rapid detection of multi-drug resistant Mycobacterium tuberculosis

Hansen, Tarrant William

January 2008

Tuberculosis remains a major public health issue globally, with an estimated 9.2 million new cases in 2006. A new threat to TB control is the emergence of drug resistant strains. These strains are harder to cure as standard anti-tuberculosis first line treatments are ineffective. Multi Drug Resistant Tuberculosis (MDR-TB) is defined as Mycobacterium tuberculosis that has developed resistance to at least rifampicin and isoniazid, and these strains now account for greater than 5% of worldwide cases. Mutations within the Rifampicin Resistance Determining Region (RRDR) of the rpoB gene are present in greater than 95% of strains that show rifampicin resistance by conventional drug susceptibility testing. As rifampicin mono resistance is extremely rare, and rifampicin resistance is usually associated with isoniaizd resistance, the RRDR region of the rpoB gene is a very useful surrogate marker for MDR-TB. Many molecular assays have been attempted based on this theory and have had varied levels of success. The three methods evaluated in this study are DNA sequencing of the rpoB, katG and inhA genes, the Genotype MTBDRplus line probe assay (Hain Lifesciences) and a novel method incorporating Real-Time PCR with High Resolution Melt analysis targeted at the RRDR using the Rotorgene 6000 (Corbett Lifesciences). The sensitivity for the detection of rifampicin resistance was far better using DNA sequencing or the commercially available line probe assay than detection by the Real-Time PCR method developed in this study.

Metallic nanoparticles with polymeric shell: A multifunctional platform for application to biosensor

Ngema, Xolani Terrance

January 2018

Philosophiae Doctor - PhD (Chemistry) / Tuberculosis (TB) is an airborne disease caused by Mycobacterium tuberculosis (MTB) that usually affects the lungs leading to severe coughing, fever and chest pains. It was estimated that over 9.6 million people worldwide developed TB and 1.5 million died from the infectious disease of which 12 % were co-infected with human immunodeficiency virus (HIV) in the year 2015. In 2016 the statistics increased to a total of 1.7 million people reportedly died from TB with an estimated 10.4 million new cases of TB diagnosed worldwide. The development of the efficient point-of-care systems that are ultra-sensitive, cheap and readily available is essential in order to address and control the spread of the tuberculosis (TB) disease and multidrugresistant tuberculosis.

Molecular characterization of the Mycobacterium tuberculosis complex (MTC) of raw milk from selected dairy farms in the Eastern Cape

Komani, Nosiphiwo

January 2013

Tuberculosis (TB) is an ancient infectious disease that has been infecting different populations around the globe and it has also been considered as one of the most successful human and animal disease. TB found in animals such as cattle and other known bovids is known as bovine tuberculosis. Bovine tuberculosis (BTB) is an infectious disease found in cattle mainly caused by Mycobacterium bovis. M. bovis is a member of the Mycobacterium tuberculosis complex (MTC) together with M. tuberculosis, M. africanum, and M. canetti where the natural host is humans; whereas M. caprae, M. microti and M. pinnipedii usually have animals as their natural host. In this study the molecular characterization of the MTC from cow milk in the Eastern Cape was investigated. One hundred and twenty samples (40 ml each) were collected from three dairy farms in the Eastern Cape, South Africa. These samples were processed using a modified Petroff decontamination method. Sample processing was followed by DNA isolation using a Zymo Bacterial/Fungal DNA Kit and the amplification and detection of the MTC was done using the Seeplex MTB Nested ACE assay. The drug susceptibility tests were done using GenoTypeMTBDRplus assay which detects mutations and resistance to INH (isoniazid) and RMP (rifampicin). The milk isolates were further analyzed using a spoligotyping method which is based on the PCR amplification of a highly polymorphic direct repeat locus in the M. tuberculosis genome which detects and types the MTC. A percentage of 20.8 % samples were found to be positive for MTC using the Seeplex MTB Nested ACE assay. There were 42.1 % samples that were resistant to both INH and RMP with the rest sensitive to either INH or RMP. The spoligotyping method showed that 78.3 % samples resembled Family 33 strains and the rest (21.7 %) resembled a spoligotyping signature known to be that of M.africanum. Both these strains belong to the Ancestral lineage with Indo-Oceanic and West Africa 2 lineage. The outcomes of our study showed that molecular methods for detection of MTC can be applied directly on milk samples without the need for culturing.

Milk -- South Africa -- Eastern Cape

Major spoligotype families of Mycobacterium tuberculosis strains isolated from tuberculosis patients in Port Elizabeth, Eastern Cape, South Africa

Nqini, Babalwa J

January 2012

South Africa is burdened with tuberculosis (TB) which is aggravated by the concurrent epidemic of HIV as well as the emergence of drug resistance. In most developed countries molecular techniques have been used to look at the dynamics of the TB epidemic however, despite the prevalence that is high in sub-Saharan Africa, there is little data on strain types that are available in Port Elizabeth. This study aims to find the major clades of M. tuberculosis that are circulating in Port Elizabeth. Two hundred MDR-TB DNA samples were obtained from the National Health Laboratory Services TB laboratory in Port Elizabeth. Spoligotyping and MIRU-VNTR were used to genotype the strains. Two hundred strains were sent to the University of Stellenbosch for spoligotyping and 179 of those were typed. Spoligotype defined families were further typed by MIRU-VNTR typing, so as to further differentiate and assess clonal diversity within the spoligotype families. The Beijing family was the dominant family and the MANU family being the least dominant, with percentages of 71 percent and 0.5 percent respectively. A comparison of spoligotyping results with the international spoligotyping database (SITVIT2) showed a total of 15 shared international types. Forty four percent (44 percent) of the isolates that were typed by MIRU-VNTR showed similarities, suggesting epidemiological relatedness. Thirty eight percent of isolates from spoligotyping were from the same family, the Beijing family, with the same shared international type STI1, but when typed by 12 MIRU-VNTR they showed no epidemiological relatedness and 18 percent of the isolates showed no relatedness when typed by 12 MIRU-VNTR but spoligotyping showed that they were from the LAM family. Results from our study illustrate the effectiveness of MIRU-VNTR typing together with spoligotyping in epidemiological studies in the region of Port Elizabeth.

Drug resistance

Genotipagem de isolados de Mycobacterium tuberculosis do Paraguai, da Argentina e da Venezuela

Díaz Acosta, Chyntia Carolina

January 2010

Submitted by Anderson Silva (avargas@icict.fiocruz.br) on 2012-10-24T13:20:12Z No. of bitstreams: 1 chyntia_c_d_acosta_ioc_bcm_0014_2010.pdf: 6762215 bytes, checksum: eeda2289ddbc51f6797d64ab1bcdbead (MD5) / Made available in DSpace on 2012-10-24T13:20:12Z (GMT). No. of bitstreams: 1 chyntia_c_d_acosta_ioc_bcm_0014_2010.pdf: 6762215 bytes, checksum: eeda2289ddbc51f6797d64ab1bcdbead (MD5) Previous issue date: 2010 / CNPq Instituto de Investigaciones en Ciencias de la Salud-Universidad Nacional de Asunción (IICS-UNA) / Fundação Oswaldo Cruz.Instituto Oswaldo Cruz. Rio de Janeiro, RJ, Brasil / A tuberculose (TB) é uma importante causa de mortalidade, sendo Mycobacterium tuberculosis (Mtb) o agente etiológico. Globalmente a família “Latin American- Mediterranean” (LAM) é responsável por aproximadamente 15% dos casos de TB. Dentro desta família, recentemente foi descrito um novo polimorfismo caracterizado por uma deleção de 26,3 kb e designado como LSP RDRio. Esta linhagem é freqüente (30%) no Rio de Janeiro e dados preliminares sugerem que cepas pertencentes a este genótipo apresentam maior virulência. Neste contexto, é de grande importância avaliar a distribuição e transmissibilidade deste genótipo em nível regional e global. O presente estudo descritivo teve como objetivo, primeiramente, estudar a variabilidade genética entre isolados de Mtb do Paraguai, da Argentina e da Venezuela pelas técnicas de Spoligotyping e MIRU-VNTR 12loci, países onde existe pouca informação sobre a presença e natureza de genótipos de Mtb. Outro foco abordado foi o estudo da família LAM, que alberga genótipos de grande importância em nível regional. Para detectar esta família recentemente foi descrito um novo marcador genético que implica o estudo da presença do SNP Ag85C (G103A) por PCR-RFLP. Este marcador pode servir como complemento ao método de Spoligotyping, para ajudar a classificar certos spoligotypes mal definidos ou convergentes. O mesmo pode também constituir uma alternativa rápida e simples para detectar isolados LAM, o que pode ser de grande importância para países de menos recursos. Finalmente, estudamos a freqüência da linhagem RDRio ao analisarmos além da presença do LSP RDRio, outros marcadores para esta linhagem como a deleção de RD174, a presença de 2 cópias alélicas no MIRU 2 e 1 cópia no MIRU 40 e genótipo LAM. Quanto ao primeiro objetivo, foi observada uma distribuição ampla diferença nas famílias de spoligotyping, de acordo com a região estudada. A maior taxa de agrupamentos de isolados observou-se na população de isolados venezuelanos, sugerindo um processo de transmissão contínua ou introdução de algumas linhagens muito tempo atrás. Quanto ao segundo objetivo, foi observado um comportamento variado do SNP Ag85C em referência ao seu papel como marcador da família LAM. Nos isolados paraguaios e venezuelanos houve um grau significativo de concordância com os resultados de spoligotyping enquanto nos pacientes argentinos houve baixa concordância. A relação entre a presença do SNP Ag85C (G103A) e o genótipo LAM, entretanto deve ser melhor estudada. Finalmente, foi observada a presença da linhagem RDRio nos três países, com maior frequência na Venezuela. A baixa freqüência no Paraguai chama a atenção e deve ser mais bem estudada. As características genéticas da linhagem RDRio, salvo poucas exceções, estiveram presentes nos isolados dos três países estudados. Após construção de árvores tipo MST com base nos spoligotypes, observamos, como previsto, a família LAM9 como nodo central que contem a linhagem RDRio e do qual derivam os outros subtipos da família LAM. No entanto, os agrupamentos dos isolados RDRio nos MST de MIRU-VNTR devem ser melhor estudados. Concluindo, no presente estudo descrevemos os genótipos circulantes de Mtb nos três países estudados. Os resultados geraram perguntas interessantes que devem ser abordados no futuro. / Tuberculosis (TB) still remains an important cause of death and its etiological agent is Mycobacterium tuberculosis (Mtb). Globally the “Latin American-Mediterranean” (LAM) accounts for 15% of the TB cases. Within this family, recently a new Long Sequence Polymorphism has been described, characterized by a 26,3kb deletion and assigned as RDRio-LSP. Currently this lineage constitutes the predominant clade (30%) of TB cases in Rio de Janeiro, and preliminary studies suggest that strains belonging to this genotype present enhanced virulence. Consequently it is of considerable importance to evaluate the distribution and the transmissibility of this genotype regionally as well as globally. The present descriptive study had three main objectives, starting with the study of the genetic variability of the Mtb strains of three Latin-American countries, Paraguay, Argentina, and Venezuela, with little information about the presence and nature of Mtb genotypes; by using spoligotyping and MIRU-VNTR 12 loci. The other focus was on the LAM family, which regionally is of extreme importance. To detect this family recently a new genetic marker has been described, which involves the detection of the SNP Ag85C (G103A) by PCR-RFLP. This marker allows classifying ill defined spoligopatterns or convergent spoligopatterns and it constitutes a simple and fast method, thus an important alternative in low resource countries. Finally our third goal was to study the prevalence of the RDRio lineage by analyzing the RDRio-LSP as well as other markers like the deletion of RD174, 2 allelic copies in MIRU 2 and 1 in MIRU 40, as well as LAM genotype. Regarding the first objective, the population structure obtained by spoligotyping varied considerably according to the geographical location.The highest clustering rate was detected within strains from Venezuela. As for the second objective, we observed a variable behavior of the SNP Ag85C as a marker for the LAM family. Both in strains from Paraguay and Venezuela, the marker had a significant concordance when compared with spoligotyping results. Nevertheless within Argentinean strains, the opposite was observed. Thus, the relationship between the presence of the Ag85C (G103A) SNP and the LAM genotype must be further studied. As for the third objective, we observed the presence of the RDRio lineage within the three countries, but with the highest prevalence in Venezuela. The low prevalence observed within Paraguayan strains deserves more studies. The genetic characteristics of the RDRio lineage were present within the RDRio strains of the three countries, with some few exceptions. Expectedly the construction of MST trees allowed us to observe a central node of the LAM9 family that contained the RDRio lineage and of which other sub-types of the LAM family derived. The nodes observed within the MST based on MIRU, must be further analyzed. In conclusion, we managed to describe the genotypes circulating within the three studied countries. From the results obtained, interesting questions were posed that should be analyzed in the future.

RDRio

Tuberculose/etiologia

Mycobacterium tuberculosis /genética

Genótipo

Separação Celular /utilização

Repetições Mini-Satélites/genética

Argentina/epidemiologia

Paraguai /epidemiologia

Venezuela /epidemiologia