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Estudo de transportador de poliaminas, PotD, e seus híbridos como antígenos vacinais contra Streptococcus pneumoniae. / The study of the polyamine transporter, PotD, and it hybrids as vaccine antigens against Streptococcus pneumoniae.Converso, Thiago Rojas 10 February 2017 (has links)
A Proteína Transportadora de Poliaminas (PotD) é um antígeno importante para a virulência de Streptococcus pneumoniae in vivo, capaz de proteger camundongos imunizados contra infecção sistêmica, além de reduzir a colonização da nasofaringe dos animais. Porém, visando ampliar a cobertura vacinal, a combinação com outros antígenos da bactéria se faz necessária. Este trabalho teve como objetivo aprofundar o estudo sobre a resposta imune gerada contra a proteína PotD, sozinha ou em fusão com duas outras proteínas pneumocócicas: o derivado de Pneumolisina, PdT, e a proteína de superfície de pneumococo A (PspA). Para tanto, os genes potD, pdT e pspA foram clonados e expressos, sozinhos ou fusionados, gerando as proteínas híbridas rPotD-PdT e rPspA-PotD. As proteínas recombinantes e os híbridos foram utilizados na imunização subcutânea de camundongos BALB/c, gerando elevados níveis de anticorpos. O soro dos animais imunizados foi capaz de reconhecer e se ligar à superfície de diferentes isolados de pneumococos, e de ampliar a fagocitose da bactéria por células peritoneais murinas in vitro. Em todos os ensaios, os híbridos se mostraram mais eficazes do que as proteínas isoladas, induzindo anticorpos capazes de potencializar a fagocitose dos pneumococos. A resposta imune celular foi caracterizada pela produção de INF-γ, IL-2 e IL-17 pelos esplenócitos, e um aumento na produção de NO pelos fagócitos peritoneais dos animais imunizados. Apesar dos resultados promissores in vitro, a proteína rPotD-PdT não foi capaz de induzir proteção em nenhum dos modelos avaliados; em contraste, a fusão rPspAPotD foi capaz de proteger os camundongos contra sepse por dois isolados virulentos de pneumococo, além de reduzir a colonização na nasofaringe. Por fim, demonstramos que a adição das poliaminas transportadas por PotD, espermidina e putrescina, à cultura de pneumococos interfere na formação de biofilme in vitro. Cnsiderando o importante papel da formação de biofilmes na colonização, este resultado sugere um possível mecanismo de ação da PotD durante a colonização por pneumococo. Em conjunto, os resultados deste estudo sugerem que a utilização de uma formulação híbrida, rPspA-PotD, compreende uma estratégia vacinal promissora, capaz de proteger contra colonização e sepse pneumocócica, pela produção de anticorpos opsonizantes e ativação de citocinas protetoras, como IL-17. / Polyamine Transporter D (PotD) is an important antigen for Streptococcus pneumoniae virulence in vivo, protecting immunized mice against systemic infection and reducing the bacterial load in the nasopharynx of immunized animals. However, in order to extend vaccine coverage, the combination of PotD with other antigens of the bacterium is required. The present study aimed at expanding the investigation of the immune response generated against PotD alone or fused with two other pneumococcal proteins: the Pneumolysin derivative, PdT and Pneumococcal Surface Protein A (PspA). Therefore, the potD, pdt and pspA genes were cloned and expressed, either alone or in fusion, generating the hybrid proteins rPotD-PdT and rPspA-PotD. The recombinant proteins and hybrids were used for subcutaneous immunization of BALB/c mice, generating high levels of antibodies. Sera from immunized animals were able to recognize and bind onto the surface of different pneumococcal strains, and to enhance phagocytosis of the bacterium in vitro. In all tests, the hybrids were more effective than the isolated proteins. The cellular immune response was characterized by the production of INF-γ, IL-2 and IL-17 by splenocytes and increased production of NO by peritoneal cells of the immunized animals. Despite promising results in vitro, rPotD-PdT protein was not able to induce protection in any of the tested challenge models. In contrast, rPspA-PotD fusion was able to protect mice against sepsis with two virulent isolates of pneumococcus and led to reduction in bacterial loads in the nasopharynx of challenged animals. Finally, we demonstrate that the addition of exogenous polyamines, spermidine, and putrescine, in the pneumococcal culture interfered with biofilm formation in vitro. Considering the important role of biofilm formation for successful colonization, this result suggests a possible mechanism of action of PotD during colonization by pneumococcus. Taken together, the results suggest that the use of the hybrid rPspA-PotD comprises a promising vaccine strategy, able to protect against colonization and pneumococcal sepsis, through the production of opsonizing antibodies and activation of protective cytokines, such as IL-17.
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Pact of impaired polyamine synthesis and transport on pneumococcal transcriptome, proteome, metabolome, and stress responsesNakamya, Mary Frances 06 August 2021 (has links) (PDF)
This dissertation is a compilation of published work and a manuscript that seeks to understand the role of polyamine metabolism in the regulation of pneumococcal physiology. Streptococcus pneumoniae (pneumococcus) is the major cause of community-acquired pneumonia, and otitis media worldwide. Genetic diversity and serotype replacement, and antibiotics resistance to confound existing therapeutic strategies and limit the effectiveness of the available capsule polysaccharide (CPS) based vaccines. Polyamines such as putrescine, spermidine and cadaverine are ubiquitous polycationic hydrocarbons that interact with negatively charged molecules and modulate important cellular processes. Intracellular polyamine concentrations are regulated by biosynthesis, degradation, and transport. This work investigated the impact of the deletion of polyamine biosynthesis gene, SP_0916 (cadA, lysine/arginine decarboxylase covered in the second, third and fourth chapters), on growth, Gram staining characteristics, capsule production, proteome and stress responses of virulent pneumococcal serotype 4 (TIGR4). We identified loss of capsular polysaccharide (CPS) in DELTA SP_0916 strain. Our proteome results showed a shift in metabolism towards the pentose phosphate pathway (PPP) that could reduce the availability of precursors for CPS and could explain the un-encapsulated phenotype of DELTA SP_0916. Since a shift towards the PPP is usually in response to stress, we compared the stress responses of DELTA SP_0916 to that of TIGR4. Our results show that the mutant was more susceptible to oxidative, nitrosative, and acid stress compared to the wild type. In the fifth chapter we compared the transcriptome, metabolome, stress responses and stress susceptibility of the polyamine transport deficient strain (DELTA potABCD) and S. pneumoniae TIGR4. Results in this chapter show that polyamine transport is essential for pneumococcal stress responses, and capsule biosynthesis. The impact of impaired polyamine synthesis (DELTA SP_0916), and transport (DELTA potABCD) on pneumococcal capsule is due to altered expression of Leloir pathway, reduced glycolysis, and increased PPP, possibly in response to impaired stress responses. These results demonstrate that alteration of polyamine pathways affects pneumococcal stress responses which in turn could limit the availability of precursors for capsule synthesis, and thus have an impact on virulence. Thus, polyamine metabolism is an attractive avenue for developing novel interventions for limiting the spread of S. pneumoniae, a versatile human pathogen.
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