Understanding the evolution and function of the mycobacterial Type VII ESX secretion systems (T7SSs) and their substrates

Newton-Foot, Mae

03 1900

Thesis (PhD)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: Mycobacterium tuberculosis, the causative agent of tuberculosis disease, contains five copies of the ESAT-6 gene cluster, each encoding a dedicated ESX protein secretion system which has been defined as a novel Type-VII secretion system. The ESX have been implicated in virulence and survival of M. tuberculosis, and as such present a promising target for novel treatment interventions. This study has investigated the evolution, regulation, functions and substrates of the ESX secretion systems. The evolutionary history of the ESX secretion systems was established using in silico and phylogenetic analyses of the sequenced mycobacteria, closely related actinomycetes and WXG-FtsK clusters from other bacteria. The ESX-4 gene cluster appears to have evolved with the start of the evolution of the mycomembrane, followed by the duplication of ESX-3, which marks the evolution of the genus Mycobacterium. The ESX-1 duplication occurred next, followed by ESX-2 and ESX-5 which occur only in the slow growing mycobacteria. Five additional ESX gene clusters were newly identified and named ESX-P1 to - P5. These additional ESX clusters occur, or are predicted to occur, on plasmid DNA, and appear to be progenitors of the genomic ESX-1 to -5 gene clusters, possibly indicating a plasmid-mediated mechanism of ESX duplication and evolution. The promoters expressing the M. tuberculosis ESX-1 to ESX-5 secretion systems were investigated using a promoter probe assay, and characterised using in silico analyses. Promoters were identified for ESX-1, -2, -3 and -5. The functions of the mycobacterial ESX secretion systems were investigated using whole proteomic, secretomic and metabolomic analyses of the fast growing, non-pathogenic M. smegmatis, which contains three of the ESX secretion systems, ESX-1, 3, and 4. ESX knockout strains of M. smegmatis were generated and used in comparative analyses with wild-type M. smegmatis. ESX-1 was highly expressed in wild-type M. smegmatis, however no specific pathways showed considerable variation when ESX-1 was deleted. Deletion of ESX-3 resulted in substantial variation to multiple cellular pathways, including amino acid, carbohydrate and fatty acid metabolism and oxidative stress. These and other differences indicate possible perturbed polyamine metabolism in the absence of ESX-3. Although no ESX-4 protein components were detected in wild type M. smegmatis, the ESX-4 knockout displayed substantial proteomic variation. Reduced levels of ESX-3 component proteins in the ESX-4 knockout suggest that ESX-4 influences ESX-3 expression. Other variation linked ESX-4 to cell division and molybdenum metabolism. Secretomic analyses of wild-type and ESX knockout M. smegmatis strains were used to search for novel substrates of the M. smegmatis ESX secretion systems. No prototype ESX substrates were identified in the culture filtrates, however 10 possible substrates of the ESX-1, -3 and -4 secretion systems, containing the general ESX secretion signal, YxxxD/E, were identified. The functions of some of these proteins correlate with the ESX functions identified in the proteomic and metabolomic analyses. This study sets the groundwork for future work in understanding the functional roles and expression patterns of these ESX secretion systems and in using global proteomic and metabolomic analyses to understand cellular changes in response to specific signals or genomic changes. / AFRIKAANSE OPSOMMING: Mycobacterium tuberculosis, die veroorsakende agent van tuberkulose, bevat vyf kopieë van die ESAT-6 geengroep, wat elk 'n toegewyde ESX proteïen sekresiesisteem, omskryf as 'n nuwe Tipe-VII sekresiestelsel, kodeer. Die ESX sekresiesisteme is betrokke by virulensie en oorlewing van M. tuberculosis, en is dus belowende teikens vir nuwe behandelings. Hierdie studie het die evolusie, regulasie, funksies en substrate van die ESX sekresiesisteme ondersoek. Die evolusionêre geskiedenis van die ESX sekresiesisteme is bepaal met behulp van in silico en filogenetiese analises van die volgordebepaalde mikobakterieë, nouverwante actinomisete en WXG-FtsK groepe van ander bakterieë. Die ESX-4 geengroep het saam met die evolusie van die mikomembraan ontwikkel, gevolg deur die duplisering van ESX-3, wat die evolusie van die genus Mycobacterium merk. Die ESX-1 duplisering het volgende plaasgevind, gevolg deur ESX-2 en ESX-5, wat slegs in die stadiggroeiende mikobakterieë voorkom. Vyf addisionele ESX geengroepe is nuut geïdentifiseer in hierdie studie en is ESX-P1 tot -P5 genoem. Hierdie addisionale ESX groepe is op, of word voorspel om op, plasmied DNS voor te kom, en mag voorlopers van die genomiese ESX-1 tot -5 geengroepe wees, wat moontlik dui op 'n plasmied-gemedieërde meganisme van ESX duplisering en evolusie. Die promoters wat verantwoordelik is vir die uitdrukking van die M. tuberculosis ESX-1 tot ESX-5 sekresiesisteme is ondersoek deur middel van 'n promoter aktiwiteitstoets, en gekarakteriseer deur in silico analises. Promoters is geidentifiseer vir ESX-1, -2, -3 en -5. Die funksies van die mikobakteriële ESX sekresiesisteme is ondersoek deur proteomiese, sekretomiese en metabolomiese analises van die vinnig-groeiende, nie-patogeniese mikobakterium M. smegmatis, wat ESX- 1, -3 en -4 sekresiesisteme besit. ESX uitslaanmutante van M. smegmatis is gegenereer en gebruik in die vergelykende analises met die wilde-tipe M. smegmatis. ESX-1 is hoogs uitgedruk in wilde-tipe M. smegmatis, maar geen spesifieke metabolise weë het aansienlike variasie getoon wanneer ESX-1 verwyder is. Delesie van ESX-3 het gelei tot aansienlike variasie in verskeie sellulêre weë, insluitend aminosuur-, koolhidraat- en vetsuur-metabolisme en oksidatiewe stres. Hierdie en ander verskille dui op moontlike versteurde poli-amien metabolisme in die afwesigheid van ESX-3. Hoewel geen ESX-4 proteïenkomponente opgespoor is in wilde-tipe M. smegmatis nie, vertoon die ESX-4 uitslaanmutant aansienlike proteomiese variasie. Laer vlakke van ESX-3 proteïne dui daarop dat ESX-4 die uitdrukking van ESX-3 beinvloed. Baie van die proteomiese variasie kan geassosieer word met verlaagde ESX-3 uitdrukking, maar ander variasie mag ESX-4 koppel met seldeling en molibdeen metabolisme. Sekretomiese analises van wilde-tipe en ESX uitslaanmutant M. smegmatis stamme is gebruik om nuwe substrate van die M. smegmatis ESX sekresiesisteme te identifiseer. Geen prototipe ESX substrate is geïdentifiseer in die kultuurfiltraat, maar 10 moontlike substrate van die ESX-1, -3 en -4 sekresiesisteme, met die algemene ESX sekresiesein, YxxxD/E, is geïdentifiseer. Die funksies van sommige van hierdie proteïene korreleer met die funksies geïdentifiseer in die proteomiese en metabolomiese analises. Hierdie studie stel die grondslag vir toekomstige werk in die begrip van die funksionele rol en uitdrukkingspatrone van die ESX sekresiesisteme en in die gebruik van globale proteomiese en metabolomiese analises om sellulêre veranderinge in reaksie op spesifieke seine of genomiese veranderinge te verstaan. / The National Research Foundation / German Academic Exchange Service (DAAD), / The Harry Crossley Foundation / The Ernst and Ethel Erikson Trust / Stellenbosch University

ESX protein secretion systems

Mycobacterium tuberculosis

TB

Tuberculosis disease

Theses -- Medicine

Dissertations -- Medicine

Theses -- Molecular biology

Dissertations -- Molecular biology

Secretomics

Proteomics

Biomedical Sciences

Investigation of the ESX-4 secretion system interactome of Mycobacterium tuberculosis

Smit, Michelle

12 1900

Thesis (MScMedSc (Biomedical Sciences. Medical Biochemistry))--University of Stellenbosch, 2010. / Bibliography / ENGLISH ABSTRACT: The genome of the pathogen Mycobacterium tuberculosis contains five copies of the ESAT-6 (ESX) gene cluster region, which encodes for a novel type VII secretion system. These gene cluster regions, which are directly involved in pathogenicity and phagosomal escape, contain genes encoding exported T-cell antigens ESAT-6 and CFP-10. The mechanism of action of the ESX secretion system however, remains largely unknown. This study focused on ESX gene cluster region 4 (ESX-4), which has been shown to be the most ancestral region and is also present in other species of Mycobacteria and even in other high G+C Gram-positive bacteria, such as Corynebacterium diptheriae and Streptomyces coelicolor. This project aimed to investigate the protein-protein interactions of ESX-4 of M. tuberculosis in the model organism Mycobacterium smegmatis by means of Mycobacterial Protein Fragment Complementation (M-PFC). M-PFC is a two-hybrid technique which employs two cloning vectors, pUAB300 (conferring resistance to hygromycin B) and pUAB400 (conferring resistance to kanamycin). Genes of interest are cloned into these vectors and co-transformed into the model organism M. smegmatis after which it is expressed as fusion proteins. Interaction of the proteins allows selective growth on a medium containing the antibiotic trimethoprim. Various interactions were identified throughout this region, including selfinteractions as well as the expected interaction between the ESAT-6 and CFP-10 protein family members esxT and esxU. Since this region is ancestral, ESX-4 provides the basic model of the mechanism of secretion of the type VII secretion system. Many similarities were apparent when the interactions identified for ESX-4 were compared to the interactions previously identified in ESX-3. Interactions identified by means of M-PFC provide a basis for the further study of the structure of this secretion system, and should be confirmed by means of other techniques, such as co-immunoprecipitation. Despite the ability of M-PFC to identify protein-protein interactions in a mycobacterial system, and thus overcoming some of the limitations of the classical yeast two-hybrid model, it must still be regarded as a fishing experiment for potential interactions. A further aim of the project was to construct a knock-out of ESX-4 in the model organism M. smegmatis, which contains three ESX regions, namely ESX-1, -3 and -4. Homologous recombination proved to be an effective technique for the construction of the knock-out, also indicating that ESX-4 is not essential for in vitro growth of M. smegmatis. The knock-out strain showed no morphological differences to the wild type strain of M. smegmatis. The knock-out strain will in future be compared to the wild type strain in various functional studies in order to determine the function of the ancestral ESX region. / AFRIKAANSE OPSOMMING: Die genoom van die patogeen Mycobacterium tuberculosis bavat vyf kopieë van die ESAT-6 geen groep gebiede wat kodeer vir ‘n unieke tipe VII sekresie sisteem. Die geen groep gebiede, wat direk betrokke is by patogenisiteit en fagosomale ontsnapping, bevat gene wat kodeer vir die gesekreteerde T-sel antigene ESAT-6 en CFP-10. Die meganisme van die ESX sekresie sisteem is egter steeds tot ‘n groot mate onbekend. Hierdie studie het gefokus op die ESX geen groep gebied 4 (ESX-4), wat voorheen bepaal is om die vroegste kopie van die gebied te wees en wat ook in ander species van Mikobakterieë en hoë G+C Gram-positiewe bakterieë, soos Corynebacterium diptheriae en Streptomyces coelicolor, voorkom. Hierdie projek was daarop gemik om die proteïen-proteïen interaksies van ESX-4 van M. tuberculosis in die model organisme Mycobacterium smegmatis te ondersoek deur middel van Mikobakteriële Proteïen Fragment Komplementasie (M-PFK). M-PFK is ‘n twee-hibried tegniek wat van twee kloningsvektore, naamlik pUAB300 (wat weerstand teen hygromycin B bied) en pUAB400 (wat weerstand teen kanamycin bied) gebruik maak. Gene van belang word in die vektore ingekloneer en in die model organisme, M. smegmatis geko-transformeer, waarna dit as fusieproteïene uitgedruk word. Indien ‘n interaksie tussen die proteïene plaasvind, sal selektiewe groei op ‘n medium wat die antibiotikum trimethoprim bevat, waargeneem word. Verskeie interaksies is in hierdie gebied geïdentifiseer, insluitende self-interaksies, sowel as die verwagte interaksie tussen die ESAT-6 en CFP-10 proteïen familielede esxT en esxU. Aangesien hierdie gebied die vroegste kopie is, bied ESX-4 die basiese model vir die meganisme van sekresie van die tipe VII sekresie sisteem. Wanneer interaksies wat vir ESX-4 geïdentifiseer is met die wat voorheen vir ESX-3 geïdentifiseer is vergelyk word is daar heelwat ooreenkomste. Interaksies wat deur middel van M-PFK geïdentifiseer is, verskaf ‘n basis vir die vêrdere studie van interaksies van hierdie gebied, en sal bevestig moet word deur gebruik te maak van aanvullende tegnieke, soos ko-immunopresipitasie. Ten spyte van die vermoë van M-PFK om proteïen-proteïen interaksies in ‘n mikobakteriële sisteem, wat dus sommige van die beperkings van die klassieke gis twee-hibriedmodel oorkom, te bestudeer, behoort dit steeds as ‘n voorlopige metode van identifikasie beskou te word. ‘n Vêrdere doel van die projek was om ‘n uitslaanmutant van ESX-4 in die model organisme M. smegmatis, wat drie van die ESX gebiede, naamlik ESX-1, -3 en -4 bevat, te skep. Homoloë rekombinasie is bewys om ‘n effektiewe tegniek te wees vir die skep van ‘n uitslaanmuntant en het daarop gedui dat ESX-4 nie essensieel is vir die in vitro groei van M. smegmatis nie. Die uitslaanstam het ook geen morfologiese verskille getoon teenoor die oorspronklike stam nie. Die uitslaanmutant sal in die toekoms gebruik word in ‘n verskeidenheid funksionele studies waar dit vergelyk sal word met die oorspronklike stam, ten einde die funksie van die vroegste ESX-gebied te bepaal. / Medical Research Council of South Africa / National Research Foundation of South Africa / Ernst and Ethel Eriksen Trust

Type VII secretion

Targeted genetic knock-outs

Mycobacterial two-hybrid techniques

Model of ESX-4 secretion

Theses -- Medical biochemistry

Dissertations -- Medical biochemistry

Theses -- Medicine

Dissertations -- Medicine

Biomedical Sciences

Interplay of human macrophages and Mycobacterium tuberculosis phenotypes

Raffetseder, Johanna

January 2016

Mycobacterium tuberculosis (Mtb) is the pathogen causing tuberculosis (TB), a disease most often affecting the lung. 1.5 million people die annually due to TB, mainly in low-income countries. Usually considered a disease of the poor, also developed nations recently put TB back on their agenda, fueled by the HIV epidemic and the global emergence of drug-resistant Mtb strains. HIV-coinfection is a predisposing factor for TB, and infection with multi-drug resistant and extremely drug resistant strains significantly impedes and lengthens antibiotic treatment, and increases fatality. Mtb is transmitted from a sick individual via coughing, and resident macrophages are the first cells to encounter the bacterium upon inhalation. These cells phagocytose intruders and subject them to a range of destructive mechanisms, aiming at killing pathogens and protecting the host. Mtb, however, has evolved to cope with host pressures, and has developed mechanisms to submerge macrophage defenses. Among these, inhibition of phagosomal maturation and adaptation to the intracellular environment are important features. Mtb profoundly alters its phenotype inside host cells, characterized by altered metabolism and slower growth. These adaptations contribute to the ability of Mtb to remain dormant inside a host during latent TB infection, a state that can last for decades. According to recent estimates, one third of the world’s population is latently infected with Mtb, which represents a huge reservoir for active TB disease. Mtb is also intrinsically tolerant to many antibiotics, and adaptation to host pressures enhances tolerance to first-line TB drugs. Therefore, TB antibiotic therapy takes 6 to 9 months, and current treatment regimens involve a combination of several antibiotics. Patient noncompliance due to therapeutic side effects as well as insufficient penetration of drugs into TB lesions are reasons for treatment failure and can lead to the rise of drug-resistant populations. In view of the global spread of drug-resistant strains, new antibiotics and treatment strategies are urgently needed. In this thesis, we studied the interplay of the primary host cell of Mtb, human macrophages, and different Mtb phenotypes. A low-burden infection resulted in restriction of Mtb replication via phagolysosomal effectors and the maintenance of an inactive Mtb phenotype reminiscent of dormant bacteria. Macrophages remained viable for up to 14 days, and profiling of secreted cytokines mirrored a silent infection. On the contrary, higher bacterial numbers inside macrophages could not be controlled by phagolysosomal functions, and intracellular Mtb shifted their phenotype towards active replication. Although slowed mycobacterial replication is believed to render Mtb tolerant to antibiotics, we did not observe such an effect. Mtb-induced macrophage cell death is dependent on ESAT6, a small mycobacterial virulence factor involved in host cell necrosis and the spread of the pathogen. Although well-studied, the fate of ESAT6 inside infected macrophages has been enigmatic. Cultivation of Mtb is commonly carried out in broth containing detergent to avoid aggregation of bacilli due to their waxy cell wall. Altering cultivation conditions revealed the presence of a mycobacterial capsule, and ESAT6 situated on the mycobacterial surface. Infection of macrophages with this encapsulated Mtb phenotype resulted in rapid ESAT6-dependent host cell death, and ESAT6 staining was lost as bacilli were ingested by macrophages. These observations could reflect the earlier reported integration of ESAT6 into membranes followed by membrane rupture and host cell death. In conclusion, the work presented in this thesis shows that the phenotype of Mtb has a significant impact on the struggle between the pathogen and human macrophages. Taking the bacterial phenotype into account can lead to the development of drugs active against altered bacterial populations that are not targeted by conventional antibiotics. Furthermore, deeper knowledge on Mtb virulence factors can inform the development of virulence blockers, a new class of antibiotics with great therapeutic potential.

Mycobacterium tuberculosis

tuberculosis

macrophage

innate immunity

host-pathogen interaction

antibiotic tolerance

phagosomal maturation

bacterial phenotype

dormancy

persistence

virulence factor

ESAT-6

ESX-1

Structure et localisation du complexe ESX-3 dans les mycobactéries

Morneau, Isabelle

08 1900

Le système de sécrétion type VII (T7SS) présent chez les mycobactéries comporte cinq loci, nommés ESX-1 à ESX-5, chacun possédant leurs propres fonctions. Le système ESX-3, le plus conservé entre les espèces de mycobactéries, participe au transport du fer et à la sécrétion de protéines dont la protéine EsxH. EsxH interagit avec le système ESCRT dans le macrophage et contribue à la persistance de M. tuberculosis (Mtb) dans l’hôte. Afin de mieux comprendre le mécanisme du T7SS, nous avons surexprimé le locus ESX-3 de Mtb dans les organismes recombinants M. smegmatis et M. marinum. Nous avons purifié un coeur protéique partiel du complexe ESX-3 par chromatographie liquide de protéine rapide (FPLC) et déterminé différentes structures in vitro qui pourraient représenter son dynamisme par une analyse des particules individuelles. Nous avons localisé le complexe ESX-3 aux pôles chez M. marinum par microscopie de fluorescence (fLM) et microscopie super-résolution d’illumination de structure (SR-SIM). Finalement, nous avons reconstruit un modèle in vivo 3D de ce complexe en jumelant une technique de corrélation entre la microscopie par localisation photoactivée (PALM) et la tomographie électronique en conditions cryogéniques (cryo-ET). En jumelant nos structures in vitro et notre modèle in vivo, nous discutons d’un mécanisme possible du complexe ESX-3. Ces analyses pourront aussi supporter le criblage d’inhibiteurs potentiels pour traiter les infection mycobactériennes. / A novel, type VII secretion system (T7SS) was recently discovered in Mycobacteria. Five subsystems, called ESX-1 to ESX-5, have been identified, with the ESX-3 being the most conserved. The ESX-3 system is essential for growth and pathogenesis, and has been implicated in iron transport and secretion of effector proteins into the host. The secreted proteins are shown to prevent phagosome maturation by interacting with the ESCRT machinery of the macrophage. To characterize the structure and mechanism of secretion employed by the T7SS, we use the ESX-3 system from Mycobacterium tuberculosis (Mtb) and recombinantly express it in M. smegmatis and M. marinum cells. By combining Fast Protein Liquid Chromatography (FPLC) and Single Particle electron microscopy analysis, we have reconstructed several in vitro models that contain at least three of the ESX-3 cluster proteins and may represent the dynamic nature of the core complex. Using fluorescent light microscopy (fLM) and super-resolution structure illumination microscopy (SR-SIM), we localized the ESX-3 complex to the lateral pole in M. marinum cells. We also used super-resolution photoactivated localization microscopy (PALM) in correlation with cryo-electron tomography (cryo-ET) of whole M. marinum cells to localize and reconstruct an in vivo 3D model of the ESX-3 secretion system. By combining the single particle reconstructions and the cryotomography data, we discuss a possible mechanism of ESX-3 secretion. Such analysis may support future inhibitor screens to prevent mycobacterial infections.

T7SS

ESX-3

localisation

structure

modèle

Microscopie corrélative PALM-cryo-ET

dynamisme

Localization

Model

Correlative PALM-cryo-ET

Dynamism

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