Mycobacterium tuberculosis : genetic and phenotypic comparison

dc.contributor.advisorWarren, R. M.
dc.contributor.advisorVan Helden, P. D.
dc.contributor.authorSampson, Samantha Leigh
dc.contributor.otherStellenbosch University. Faculty of Medicine and Health Sciences. Dept. of Medicine.en_ZA
dc.date.accessioned2012-08-27T11:35:13Z
dc.date.available2012-08-27T11:35:13Z
dc.date.issued2002-03
dc.descriptionThesis (PhD)--University of Stellenbosch, 2002.en_ZA
dc.description.abstractENGLISH ABSTRACT: This study exploits the Mycobacterium tuberculosis H37Rv genome sequence data in the context of M. tuberculosis clinical isolates, to elucidate genetic variation, and examine the phenotypic and molecular epidemiological implications thereof. The study was initiated by investigation of the insertion sequence IS6110, the primary DNA fingerprinting probe for the molecular epidemiology of tuberculosis. The transposable element is present in variable copy number and chromosomal location in clinical isolates of M. tuberculosis strains, giving rise to extensive genetic diversity. At the inception of this study, little was known about this element in terms of the genetic identity of its surrounding regions, its chromosomal distribution, and the mechanisms contributing to genetic diversity. These shortcomings were therefore addressed by a number of approaches. Firstly, to establish their genetic identity and chromosomal distribution, IS6110 insertion sites from clinical isolates of M. tuberculosis were cloned and sequenced. This data was examined in conjunction with available genome sequence data. The results demonstrated that the majority of insertions occurred within coding regions. Furthermore, the element was shown to have a non-random chromosomal distribution, and a number of preferential integration sites were identified. Secondly, the stability of chromosomal domains flanking IS611 0 elements was investigated by utilizing the insertion site clones as hybridization probes against clinical isolates. This allowed the identification of extensive genetic variation associated with these chromosomal domains, arising from IS6110 transpositions, deletions and point mutations. These events were expressed in terms of a phylogenetic tree which demonstrated ongoing genome evolution associated with IS6110. Thirdly, to investigate the hypothesis that IS6110-mediated deletions occur via homologous recombination between adjacent elements, deletion junctions were mapped and sequenced in clinical isolates representing predecessor and descendant strains. While these results support the involvement of IS6110 as a mediator of genetic deletion, they suggest either alternative mechanisms or the existence of unidentified intermediates. The investigation of IS6110 flanking regions identified the disruption of a number of members of the PPE gene family, leading to the second main area of investigation. The PPE gene family was newly identified as a result of the M. tuberculosis genome sequencing project, and its products are speculated to be of antigenic importance. However, at the commencement of this study very little data was available regarding the biological role of PPE proteins. Therefore, to explore the phenotypic implications of PPE gene disruption, various aspects of the gene family were investigated. Firstly, phylogenetic relationships between members of the PPE family were elucidated, which suggested an evolutionary progression, and highlighted the possibility that there may be functional subdivisions within the gene family. Secondly, the extent and mechanisms of PPE gene variation were analyzed by a combination of hybridization, peR and sequence analysis. This approach revealed extensive variation associated the gene family, although different members of the family exhibit different levels of variation. Of special interest was the discovery that long tandem repeat regions (~69 bp) found within 3 members of the gene family demonstrate variation in the numbers of these tandem repeats. A third avenue of investigation focused on in vitro and in vivo PPE gene expression profiles. RT- , peR was utilized to demonstrate in vitro expression of PPE genes, while RNA:RNA in situ hybridization demonstrated the expression of PPE genes in human tissue samples. Intriguingly, in situ hybridization suggests that there is variable PPE gene expression within the human granuloma. The final approach reported here focused on the subcellular localization of one member of the PPE family, Rv1917c. A combination of cell fractionation and whole-cell antibody binding experiments suggest that the Rv 1917c protein is a cell wallassociated, surface exposed molecule. In summary, the results obtained have potential implications for the interpretation of molecular epidemiological data, support the role of IS6110 as an agent of genome evolution, and emphasize the potential for IS6110 to impact on strain phenotype. Investigation of the PPE family demonstrated that this gene family contributes to genetic variation, is expressed in vitro and in vivo and that at least one protein encoded by the gene family is cell wall associated. Together, the results obtained support the hypothesis that selected members of the PPE gene family may encode products involved in antigenic variation.en_ZA
dc.description.abstractAFRIKAANSE OPSOMMING: Dié studie maak gebruik van die Mycobacterium tuberculosis H37Rv genoom volgorde data in die konteks van M. tuberculosis kliniese isolate, om genetiese variasie toe te lig en die fenotipiese en molekulêre epidemiologiese implikasies daarvan te ondersoek. Die studie het 'n aanvang geneem deur die ondersoek van die inset-volgorde /S6110, wat die primêre DNS vingerafdruk pylfragment vir die molekulêre epidemiologie van tuberkulose is. Hierdie transponerende element is in wisselende kopiegetal en chromosomale posisies teenwoordig in kliniese isolate van M. tuberculosis stamme, en gee so oorsprong aan omvangryke genetiese afwisseling. Met die aanvang van hierdie studie was min bekend omtrent hierdie element betreffende die genetiese identiteit van die areas wat die insetsels omring, die chromosomale distribusie van insetsels, asook die meganismes wat bydra tot genetiese afwisseling. Hierdie gebreke is dus deur 'n aantal benaderings aangespreek. Eerstens is IS6110 insettingsetels van kliniese M. tuberculosis isolate gekloneer en hul nukleotiedvolgorde bepaal om sodoende hul genetiese identiteit en chromosomale verspreiding vas te stel. Hierdie data is in oorleg met beskikbare genomiese volgorde data geanaliseer. Die resultate het gewys dat die meerderheid van insetsels binne koderende gebiede plaasgevind het. Verder is gewys dat hierdie element nie na willekeur deur die chromosoom versprei is nie, en 'n aantal gebiede waar insetting by voorkeur plaasvind, is geïdentifiseer. Tweedens is die stabiliteit van die chromosomale gebiede wat IS6110 elemente flankeer ondersoek deur die insettingsetel klone as pylfragmente te gebruik in hibridisasie van kliniese isolate. Dit het die identifisering van omvangryke genetiese afwisseling binne hierdie chromosomale gebiede, wat ontstaan deur IS611 0 transposisies, delesies en puntmutasies, tot gevolg gehad. Hierdie afwisselings is uitgedruk as 'n filogenetiese boom waarin die voortdurende genomiese evolusie wat geassosieer word met IS6110 gewys word. Derdens, om die teorie dat IS6110-gedrewe delesies deur middel van homoloë rekombinasie tussen naasliggende elemente plaasvind te ondersoek, is die grense van delesies gekarteer en die nukleotiedvolgorde daarvan bepaal in kliniese isolate wat voorganger- en afstammelingstamme verteenwoordig. Alhoewel die resultate die betrokkenheid van IS6110 as 'n bemiddelaar van genetiese delesie ondersteun, stel dit ook die bestaan van of alternatiewe meganismes of van onbekende intermediêre vorme voor. Ondersoek van die IS6110-flankerende gebiede het gelei tot die ontdekking van ontwrigting van 'n aantal gene wat behoort tot die PPE geenfamilie, en het so gelei tot die tweede hoof ondersoek tema. Die PPE geenfamilie is ontdek as gevolg van die M. tuberculosis genoomprojek, en dit word gespekuleer dat die produkte van hierdie gene van antigeniese belang mag wees. Daar was egter met die aanvang van hierdie studie baie min data beskikbaar omtrent die biologiese rol van die PPE proteïene. Om die fenotipiese implikasies van ontwrigting van PPE gene te ondersoek is daar dus ondersoek ingestel na verskeie aspekte van hierdie geenfamilie. Eerstens is filogenetiese verwantskappe tussen lede van die PPE familie bepaal, wat gedui het op 'n evolusionêre progressie en wat ook aangedui het dat daar moontlik funksionele onderverdelings binne hierdie geenfamilie mag bestaan. Tweedens is die omvang en meganismes van PPE geenvariasie geanaliseer deur 'n kombinasie van hibridisasie, PKR en nukleotiedvolgorde analise. Hierdie benadering het omvangryke afwisseling binne hierdie geenfamilie getoon, alhoewel verskillende lede van die familie verskillende vlakke van afwisseling demonstreer. Wat veral interessant was, was die ontdekking dat lang tandem herhalingsvolgordes (~69 bp) wat in 3 lede van hierdie geenfamilie voorkom, variasie toon in die getalle van hierdie tandem herhalingsvolgordes. 'n Derde been van ondersoek het gefokus op in vitro en in vivo PPE geen uitdrukkingsprofiele. RT-PKR is gebruik om te toon dat PPE gene in vitro uitgedruk word, terwyl RNA:RNA in situ hibridisasie getoon het dat PPE gene ook in menslike weefsel uitgedruk word. Interessant genoeg dui in situ hibridisasie daarop dat daar wisselende PPE geen uitdrukking binne die menslike granuloom voorkom. Die laaste benadering wat hier gerapporteer word fokus op die sub-sellulêre lokalisering van een lid van die PPE familie, Rv1917c. 'n Kombinasie van selfraksionering en heel-sel antiliggaam-bindingseksperimente dui daarop dat Rv1917c 'n selwand-geassosieerde molekuul is wat aan die oppervlak blootgestel word. Ter opsomming het die resultate wat bereik IS potensiële implikasies vir die interpretasie van molekulêr-epidemiologiese data, dit ondersteun die rol van IS6110 as 'n bemiddelaar van genoom evolusie en beklemtoon die potensiaal vir IS6110 om 'n invloed te hê op die fenotipe van die stam. Ondersoek van die PPE familie het getoon dat hierdie geenfamilie bydra tot genetiese afwisseling, dat dit uitgedruk word beide in vitro en in vivo en dat ten minste een lid van hierdie geenfamilie geassossieer word met die selwand. Tesame ondersteun hierdie resultate die teorie dat geselekteerde lede van die PPE geenfamilie wel produkte enkodeer wat betrokke is by antigeniese variasie.af_ZA
dc.format.extent252 p. : ill.
dc.identifier.urihttp://hdl.handle.net/10019.1/52948
dc.language.isoen_ZAen_ZA
dc.publisherStellenbosch : Stellenbosch Universityen_ZA
dc.rights.holderStellenbosch Universityen_ZA
dc.subjectMycobacterium tuberculosisen_ZA
dc.subjectMycobacterium tuberculosis -- Genetic aspectsen_ZA
dc.subjectDissertations -- Medicineen_ZA
dc.subjectTheses -- Medicineen_ZA
dc.titleMycobacterium tuberculosis : genetic and phenotypic comparisonen_ZA
dc.typeThesisen_ZA
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