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Interactions of the Treponema pallidum adhesin Tp0751 with the human vascular endotheliumLithgow, Karen V 30 July 2019 (has links)
Treponema pallidum ssp. pallidum is the causative agent of syphilis, a sexually transmitted infection characterized by multi-stage disease and diverse clinical manifestations. Treponema pallidum undergoes rapid vascular dissemination to penetrate tissue, placental, and blood-brain barriers and gain access to distant tissue and organ sites. The rapidity and extent of T. pallidum dissemination is well documented, but the molecular mechanisms that underlie this process have yet to be fully elucidated. Tp0751 is a T. pallidum adhesin that interacts with vascular factors and mediates adherence to endothelial cells under shear flow. This dissertation explores the molecular interactions and functional outcomes of Tp0751-mediated vascular endothelium adhesion.
The findings presented herein demonstrate that recombinant Tp0751 adheres to human macrovascular and microvascular endothelial cells, including cerebral brain endothelial cells. This interaction is confirmed using live T. pallidum, where spirochete- endothelial cells interactions are disrupted with Tp0751-specific antiserum. Further, the 67 kDa laminin receptor (LamR) is identified as an endothelial receptor using affinity chromatography coupled with mass spectrometry to isolate and identify Tp0751-interacting proteins from endothelial cells membrane extracts. Notably, LamR is a brain endothelial cell receptor for other neurotropic invasive pathogens. Evaluation of endothelial intercellular junctions reveals that recombinant Tp0751 and live T. pallidum disrupt junctional architecture. However, transwell solute flux assays reveal that Tp0751 and T. pallidum do not alter endothelial barrier integrity. The transendothelial migration of T. pallidum can be partially abrogated with an endocytosis inhibitor, implying a transcellular route for barrier traversal. However, a subpopulation of T. pallidum localizes to intercellular junctions, indicating paracellular traversal may also be employed. These findings enhance our understanding of the mechanics of T. pallidum attachment to endothelial cells and suggest that T. pallidum may use both paracellular and transcellular mechanisms to traverse the vascular endothelium without altering barrier permeability. A more complete understanding of this process will facilitate vaccine development for syphilis. / Graduate / 2020-06-18
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Identificação de adesinas de Leptospira interrogans por shotgun phage display / Identification of Leptospira interrogans adhesins by shotgun phage displayLima, Swiany Silveira 06 February 2013 (has links)
Em Leptospira interrogans algumas proteínas com capacidade de ligação aos componentes de matriz extracelular foram identificadas e, em sua maioria, são fatores de virulência. Phage display é considerada uma técnica poderosa na identificação de novos ligantes, inclusive de moléculas adesinas, importantes no primeiro estágio de infecção do hospedeiro. A técnica de shotgun phage display foi utilizada visando à obtenção de ligantes à células de mamíferos. Quatro bibliotecas, por inserção de fragmentos aleatórios obtidos por sonicação do DNA de L. interrogans nos fagomídeos pG8SAET (BBT1 e BBT2) e pG3DSS (BBT5 e BBT6), foram construídas. As bibliotecas BBT1 e BBT5 contém insertos maiores e as BBT2 e BBT6 contém insertos menores, com tamanhos médios de 1500 pb e 350 pb, respectivamente. Após ensaio de panning da BBT5 contra células de mamíferos e soro fetal bovino, as sequências de clones selecionados foram analisadas quanto a orientação correta e se a fusão estava em fase com a proteína pIII. As proteínas codificadas pelos genes LIC11719, LIC10769, LIC13143 e LIC12976 foram selecionadas com estas características. Os genes que codificam a LIC12976, LIC10768, LIC10769 e LIC13418, tiveram sua conservação avaliada em diferentes sorovares da espécie patogênica L. interrogans e no sorovar Patoc da espécie de vida livre L. biflexa. As proteínas LIC12976 (selecionada pela técnica de phage display) e LIC13418 (selecionada por ferramentas de bioinformática) tiveram suas sequências amplificadas por PCR, clonadas em pGEM T easy, subclonadas em vetor de expressão pAE e expressas na fração celular correspondente ao corpúsculo de inclusão em E. coli BL21 (DE3) Star pLysS e E. coli BL21 SI, respectivamente. Após renaturação e purificação destas proteínas por cromatografia de afinidade a metal bivalente, um grupo de cinco animais BALB/c fêmeas foi imunizado. Ambas as proteínas se mostraram imunogênicas com títulos dos soros policlonais 1:256000 e 1:512000, respectivamente. Em ensaio de Western Blot os soros foram específicos no reconhecimento das proteínas recombinantes e as proteínas nativas foram verificadas em extratos de sorovares patogênicos de L. interrogans. Em ensaios de adesão, as proteínas recombinantes aderiram às células A31, LLC-PK1 e Vero e especificamente à laminina. Em ensaios de interferência em células usando laminina houve um aumento da adesão das proteínas recombinantes, o que pode ser explicado pela ligação da laminina às células e uma maior ligação das LICs estudadas. Em ensaio de localização celular usando imunofluorescência e microscopia eletrônica, foi observado que ambas as proteínas se encontram na superfície da L. interrogans. No experimento de desafio animal, a LIC12976 e a LIC13418 não se mostraram protetoras. Este trabalho contribuiu para a identificação das novas adesinas LIC13418 e LIC12976 que podem participar da virulência de leptospiras patogênicas envolvendo a primeira etapa da infecção na interação patógeno-hospedeiro / In Leptospira interrogans, proteins capable to bind to extracellular matrix components have been identified and most of them are important virulence factors. Phage display is a powerful technique to identify new ligands, including adhesin molecules that are important in the first stage of host infection. A shotgun phage display technique was used in order to obtain cell ligands. Four libraries were constructed by inserting random fragments obtained by sonication of L. interrogans DNA into phagemids pG8SAET (BBT1 and BBT2) and pG3DSS (BBT5 and BBT6). The libraries BBT1 and BBT5 contain larger inserts and BBT2 and BBT6 contain smaller inserts, with 1500 bp and 350 bp average sizes, respectively. After panning of BBT5 against mammalian cells and bovine fetal serum, the sequences of selected clones were analyzed for correct orientation and fusion with pIII protein. The proteins encoded by genes LIC11719, LIC10769, LIC13143 and LIC12976 were selected. The genes LIC12976, LIC10768, LIC10769 and LIC13418 were evaluated for their conservation in different pathogenic serovars of L. interrogans and free-living L. biflexa serovar Patoc. Proteins LIC12976 (selected by phage display technique) and also LIC13418 that was selected by bioinformatic tools, were amplified by PCR, cloned into pGEM T easy, subcloned into expression vector pAE and expressed in cellular fraction corresponding to the inclusion body in E. coli BL21 (DE3) Star pLysS and E. coli BL21 SI, respectively. After protein renaturation protocol and purification by affinity chromatography, a group of five BALB/c mice was immunized with the purified proteins. Both proteins were shown to be immunogenic with 1:256000 and 1:512000 polyclonal sera titers, respectively. In Western blot the sera were specific to recognize recombinant proteins and native proteins were detected in pathogenic L. interrogans serovars extracts. In binding assays, recombinant proteins bind to A31, LLC-PK1 and Vero cells and specifically to laminin. In interference cell assay using laminin there was an increase of recombinant protein bindings, which can be explained by the laminin binding to cells and further binding of the recombinant LICs. In cellular localization assay using immunofluorescence and electron microscopy, it was observed that both are surface proteins of L. interrogans. In the animal challenge, the LIC12976 and LIC13418 were not protective. As a whole, this work contributed to the identification of LIC12976 and LIC13418 as new adhesins and they can participate in the virulence of pathogenic Leptospira in the first stage of host pathogen interaction.
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The Anaplasma phagocytophilum adhesin Asp14 directs PDI-mediated disulfide reduction to promote infectionGreen, Ryan S 01 January 2019 (has links)
Obligate intracellular pathogens must invade host cells to survive and pose a global health risk. As such, internalization is a critical life stage and represents an excellent therapeutic target. Oxidoreductase exploitation is a thematic invasion strategy among obligate intracellular pathogens. Delineating the mechanisms and proteins mediating this exploitation could identify novel therapeutic targets for many important pathogens. Anaplasma phagocytophilum infects neutrophils by an incompletely defined mechanism, resulting in the emerging potentially fatal disease, human granulocytic anaplasmosis. The bacterial adhesin, Asp14, contributes to invasion by virtue of its C-terminus engaging an unknown receptor. Yeast two-hybrid analysis identified protein disulfide isomerase (PDI) as a putative Asp14 binding partner. Co-immunoprecipitation confirmed this interaction and identified the Asp14 C-terminus as critical to it. PDI reductase activity inhibition impaired bacterial infection of, but not binding to, host cells. A. phagocytophilum failed to productively infect myeloid-specific PDI conditional knock-out mice. This is the first demonstration of microbial PDI exploitation in vivo. Infection of PDI inhibited cells was rescued when bacterial, but not host surfaces were reduced with the reducing agent tris(2-carboxyethyl)phosphine (TCEP). Furthermore, TCEP restored bacterial infectivity after Asp14 inhibition using an antibody that reduces infection. Mutational analyses identified Asp14 residues critical for binding PDI. These data demonstrate that Asp14 binds and brings PDI to disulfide bonds within A. phagocytophilum surface protein(s) that it reduces, enabling infection. Targeting the Asp14 C-terminus could benefit approaches to prevent/treat granulocytic anaplasmosis. A similar approach would identify proteins from other obligate intracellular pathogens that could prove to be protective targets.
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Characterization of mechanisms involved in rickettsia pathogenicityVellaiswamy, Manohari 23 November 2011 (has links) (PDF)
Les rickettsies sont de petites bactéries à Gram-négatif associées à différentes espèces d'arthropodes. Leur nature intracellulaire stricte a longtemps été un obstacle à la compréhension des mécanismes moléculaires responsables de leur pathogénicité qui restent mal connus. L'adhésion bactérienne, qui est une étape clef de l'invasion des tissus de l'hôte, met en jeu les protéines rOmpA et rOmpB (rickettsial outer membrane proteins), identifiées depuis longtemps comme des antigènes de surface majeurs des rickettsies. L'objectif de cette thèse a été de caractériser une autre adhésine potentielle de Rickettsia prowazekii récemment identifiée, soit Adr2. La stratégie mise en œuvre a été basée sur la production d'anticorps monoclonaux spécifiques de cette protéine, dont une forme recombinante a été exprimée. Cet outil a permis, non seulement de localiser Adr2 à la surface des rickettsies, mais aussi d'apporter la preuve de son rôle dans le phénomène invasif puisque les anticorps anti-Adr2 diminuent significativement la cytotoxicité des rickettsies sur les cellules épithéliales. Un autre aspect de la pathogénicité que nous avons abordé concerne la mobilité des rickettsies du groupe boutonneux, fonction attribuée à la protéine RickA lorsque ce travail a été initié. La résolution des images obtenues par immunofluorescence, ou par microscopie électronique après marquage immunogold, montrent que l'expression de RickA est non-polarisée et répartie sur la surface entière de Rickettsia conorii. Enfin, plusieurs protéines recombinantes ont été utilisées dans des tests de screening sérologiques avec des sérums de patients infectés par diverses rickettsies, avec des résultats encourageants. L'ensemble de ces résultats contribue à une meilleure connaissance de la pathogénicité des bactéries du genre Rickettsia.
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Adaptation of Helicobacter pylori Adherence Properties in Promotion of Host Tropism and Inflammatory DiseaseAspholm, Marina January 2004 (has links)
Being among the most prevalent of persistent infectious agents in humans worldwide, Helicobacter pylori induces chronic inflammation (gastritis), which may progress to peptic ulceration and stomach cancer. The ability to adhere to the gastric mucosa is considered to be both a colonization and virulence property of H. pylori. For adherence, H. pylori expresses surface-located attachment proteins (adhesins) that bind to specific receptors in the gastric mucosa. The best characterized H. pylori adhesin-receptor interaction is that between the blood group antigen binding adhesin (BabA) and the fucosylated blood group antigens, which are glycans highly expressed in the gastric mucosa. Our recent results have changed the view of the blood group antigen-specific binding mode of H. pylori. We have tested clinical isolates of H. pylori from human populations worldwide for their ability to bind to ABO blood group antigens. The results revealed that more than 95% of isolates from Sweden, Germany, Spain, Japan and Alaska that bind fucosylated blood group antigens, bind both the Lewis b antigen (Leb) (of blood group O) and the blood group A-related antigen A-Lewis b, i.e. they exhibit a generalist type of binding mode. In contrast, the majority of strains (62%) from South American Amerindians bound best to Leb, i.e. they exhibit a specialist blood group “O antigen” binding mode. This specialization in binding coincides with the unique predominance of blood group O in the South American Amerindian populations. Furthermore, we also showed that H. pylori could switch from specialist to generalist binding modes by chromosomal integration of foreign babA gene fragments. A mutant strain lacking the babA gene turned out to adhere to inflamed gastric epithelium, despite the fact that it did not bind Leb. We identified the receptor to which the mutant binds to as the sialyl-dimeric-Lewis x antigen (sdiLex) and found its expression to be associated with persistent H. pylori infection and chronic inflammation, both in humans and Rhesus monkeys. The cognate sialic acid binding adhesin (SabA) was identified by our ReTagging technique. Deletion of sabA caused loss of H. pylori binding to sialylated glycans, and screening of single colony isolates revealed a high frequency of spontaneous on⇒off phase variation in sLex binding. Using erythrocytes as a model for sialyl dependent cell adhesion, we could show that SabA is the sought-after H. pylori sialyl-dependent hemagglutinin. Swedish clinical H. pylori isolates were analyzed for sialyl-dependent hemagglutination (sia-HA), and the sia-HA titers were found to be highly correlated to the levels of sLex binding. Clinical isolates were shown to exhibit several distinct binding modes for sialylated glycans, which suggest that SabA exhibit polymorphism in binding. We also found that SabA binds to sialylated glycans on neutrophil surfaces by mechanisms involving “selectin mimicry”, and that SabA plays an important role in nonopsonic activation of neutrophils. In the human stomach, H. pylori is exposed to selective pressures such as immune and inflammatory responses, and this is reflected by changes in mucosal glycosylation patterns. The high mutation and recombination rates of H. pylori in combination with bio selection will continuously generate clones that are adapted to changes in individual gastric mucosa. Such adaptive selection contributes to the remarkable diversity in binding modes and to the extraordinary chronicity of H. pylori infections worldwide.
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Structural studies of the surface adhesin SspB from Streptococcus gordoniiForsgren, Nina January 2010 (has links)
Surface proteins on microorganisms that build up the oral biofilm are key players in the formation of the biofilm. Antigen I/II proteins are surface adhesins found on virtually all oral streptococci and share a conserved multi-domain architecture. These adhesins bind surface components on other bacteria and on host cells. Thus, they are crucial for the development of the biofilm. The objective of this thesis work is the structural characterization of the large multi-domain Antigen I/II protein SspB from the primary colonizing commensal bacterium Streptococcus gordonii. The crystal structure of the variable domain of SspB was determined to 2.3 Å resolution. The domain comprises a β-supersandwich and a putative binding cleft stabilized by a calcium ion. Despite high similarity in the overall structure, the cleft within SspB is significantly smaller than the cleft within the homologous protein from Streptococcus mutans, indicating that different substrates may bind in the clefts. A screen for carbohydrate binding resulted in no hits for interaction with the SspB variable domain suggesting that the cleft may not be suitable for binding sugars. This thesis also presents the high resolution 1.5 Å structure of a truncated C-terminal domain of SspB, the first of an Antigen I/II C-domain. The structure contains two structurally related domains, each containing one calcium ion and one intramolecular isopeptide bond. The SspB protein shares the feature of intramoleular isopeptide bonds with other surface proteins from Gram positive bacteria, such as pili from Streptococcus pyogenes and Corynebacterium diphtheriae. Intramolecular isopeptide bonds are suggested to be a common feature for retaining stability in a harsh environment. The SspB adherence region, shown to be the recognition motif for Porphyromonas gingivalis attachment to S. gordonii, protrudes from the core protein as a handle available for recognition. In conclusion, this thesis work has provided new knowledge about the SspB protein and increased the understanding of the common structure of AgI/II proteins.
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Cha-Cha-Cha: Variable Adhesive Activity of the <italic>Haemophilus</Italic> Cryptic Genospecies Trimeric Autotransporter ChaSheets, Amanda Joan January 2009 (has links)
<p>Disease caused by the Gram-negative <italic>Haemophilus</italic> cryptic genospecies begins with colonization of the maternal genital or neonatal respiratory tract. The primary goal of this work was to identify and characterize the molecular determinant(s) of <italic>Haemophilus<i/talic> cryptic genospecies adherence as a means to better understand the specific adaptation of this species to the urogenital tract and neonatal respiratory tract. Using transposon mutagenesis of prototype strain 1595, we identified a locus that is essential for <italic>Haemophilus</italic> cryptic genospecies adherence to a variety of epithelial cell lines of both genital and respiratory origin. This locus encodes a protein called Cha that shares homology with trimeric autotransporters. Trimeric autotransporters are composed of an N-terminal signal peptide, an internal passenger domain that harbors adhesive activity, and a short C-terminal membrane anchor domain and are classically characterized by head-stalk-anchor domain architecture. By generating chimeric proteins, we demonstrated that the C-terminus of Cha trimerizes in the bacterial outer membrane and is capable presenting a heterologous passenger domain (Hia) in a functional form, thus confirming that Cha is a trimeric autotransporter. Southern analysis revealed that <italic>cha</italic> is unique to the <italic>Haemophilus</italic> cryptic genospecies and is ubiquitous among these strains. </p><p>Similar to a number of trimeric autotransporters, the passenger domain of Cha contains scattered clusters of YadA-like head domains associated with head-to-stalk neck adaptor motifs, predicted coiled-coil stalks and a series of identical tandem coding repeats which are not required for adherence. By evaluating the adherence capacity of <italic>H. influenzae</italic> expressing Cha deletion derivatives, we established that the N-terminal 473 residues of Cha harbor the binding domains responsible for Cha-mediated adherence to epithelial cells. In additional studies, we demonstrated that this same N-terminal region mediates bacterial aggregation through inter-bacterial Cha-Cha binding. </p><p>Further analysis revealed that variable Cha-mediated adherence is linked to spontaneous changes in the number of identical tandem repeats predicted to comprise a coiled-coil stalk domain. Variation in repeat copy number has a direct effect on Cha adhesive and aggregative activity, independent of an impact on transcription of the <italic>cha</italic> locus or surface localization of Cha protein. Moreover, length of Cha surface fibers correlates with repeat copy number expansion. We propose two hypotheses to explain how repeat expansion inhibits bacterial aggregation and host cell binding: 1) Variation in the number of 28-amino acid repeats may influence the conformation of Cha, thus changing the surface accessibility of the Cha binding pocket. 2) Repeat expansion results in the formation of long, flexible Cha fibers on the bacterial cell surface that may have a greater propensity to interact with neighboring Cha trimers at the N-terminus, thereby precluding adherence to other bacteria or host epithelial cells. </p><p>In additional studies screening adherent cryptic genospecies isolates for expression of Cha protein, we identified an additional, antigenically-divergent Cha variant that we refer to as Cha2. Amino acid sequence and domain comparison of Cha2 with Cha (now Cha1) revealed that the structurally undefined N-terminal sequences (encompassing the Cha1 adhesive and aggregative domain) are strikingly divergent. Inspite of this, Cha2 mediates efficient adherence to human epithelial cells, similar to Cha1.</p><p>Identification of Cha offers insight into the apparent tissue tropism associated with the <italic>Haemophilus</italic> cryptic genospecies. We speculate that the unique regulation of Cha adhesive activity enhances the adaptive capability of this pathogenic organism in the human host.</p> / Dissertation
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Identification and Characterisation of Novel Autotransporters of Enterohaemorrhagic Escherichia coli O157:H7Timothy Wells Unknown Date (has links)
Enterohemorrhagic Escherichia coli (EHEC) are a subgroup of Shiga toxin producing E. coli that cause gastrointestinal disease with the potential for life-threatening sequelae. Cattle serve as the natural reservoir for EHEC and outbreaks occur sporadically as a result of contaminated beef products and other farming products. E. coli O157:H7 was the first EHEC strain described and has been responsible for hundreds of outbreaks in Canada, Europe, Japan and the U.S.A. since 1982. While certain EHEC virulence mechanisms have been extensively studied, the factors that mediate host colonisation are poorly defined. Autotransporter (AT) proteins have been identified in many Gram-negative pathogens and are unique in that their primary sequence is sufficient to direct their transport across the bacterial membrane system. Many characterised members are associated with virulence. Using conserved AT motifs as a search tool five putative AT proteins were identified in the EHEC O157:H7 EDL933 genome. The genes encoding these proteins (z0402/ehaA, z0469/ehaB, z3487/ehaC, z3948/ehaD and z5029/ehaG) were PCR amplified, cloned and expressed in an E. coli K-12 MG1655flu background. Characterisation revealed that ehaA, ehaB, ehaD and ehaG encode proteins associated with an increase in biofilm formation. EhaA, EhaB and EhaG were found to mediate biofilm formation under continuous flow conditions when expressed in E. coli K-12. Over-expression of either EhaA or EhaG in E. coli K-12 resulted in the formation of large cell aggregates. Three of the AT proteins were found to mediate adhesion when over-expressed in E. coli K-12. The EhaA AT protein mediated binding to primary epithelial cells of the bovine terminal rectum. EhaB promoted adhesion to the extracellular matrix (ECM) proteins laminin and collagen I and was recognised by IgA serum taken from calves challenged with E. coli O157:H7. EhaG is a member of the trimeric autotransporter adhesin (TAA) sub-group of AT proteins and mediated adhesion to colorectal adenocacinoma (Caco-2) epithelial cells. Our results suggest that EhaA, EhaB, EhaD and EhaG may contribute to adhesion, colonisation and biofilm formation by E. coli O157:H7. This study also used a bioinformatic approach to identify AT encoding genes in available E. coli genomes. We identified 156 AT encoding genes in 18 E. coli genomes queried. Alignment and analysis of these proteins identified three broad groups, the serine protease autotransporters of enterobacteriacae (SPATEs), the trimeric autotransporter adhesins (TAAs) and AIDA-I type AT vii proteins. The latter group consisted of a further ten sub-groups. The results demonstrated that E. coli strains encode multiple AT proteins, many of which may have some degree of functional redundancy.
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Caracterização da enolase de Paracoccidioides brasiliensis e identificação proteômica de novas moléculas /Marcos, Caroline Maria. January 2011 (has links)
Resumo: Paracoccidioides brasiliensis é um importante patógeno humano que causa a paracoccidioidomicose (PCM), uma micose sistêmica com ampla distribuição na América Latina. A adesão e invasão de células são eventos cruciais envolvidos na infecção e disseminação do patógeno. Além disso, patógenos utilizam suas moléculas de superfície para se ligar aos componentes da matriz extracelular para estabelecer a infecção. Uma proteína antigênica de P. brasiliensis foi isolada de géis de eletroforese bidimensional do cell-free do fungo e caracterizada. Peptídeos foram obtidos da proteína de 54 kDa e pI 5,6 e mostraram homologia com enolase de Paracoccidioides brasiliensis e outros fungos. A proteína foi purificada através de eletroeluição e utilizada para a produção de anticorpo policlonal em coelho. Por microscopia de fluorescência não foi possível observar a localização exata desta proteína, apenas que se encontra aparentemente distribuídapor todo o fungo, foi possível verificar alterações no citoesqueleto de pneumócitos durante a infecção por P. brasiliensis. A localização foi confirmada por microscopia imunoeletrônica a presença de enolase foi detectada principalmente na parede celular de leveduras de P. brasiliensis e também no citoplasma, ela se demonstrou mais expressa quando este fungo foi cultivado em meio onde houve acréscimo de sangue de carneiro e durante a situação de infecção a pneumócitos. A enolase purificada foi capaz de se ligar a fibronectina, fibrinogênio, laminina, plasminogênio, colágenos tipo I e IV. Foi confirmado que a ligação desta proteína à pneumócitos é influenciada pela sequência de aminoácidos Arg-Gly-Asp contida provavelmente nos receptores da matriz extracelular presentes na célula do hospedeiro. Essas informações indicam que a enolase possivelmente contribui para a adesão do microrganismo aos tecidos do ... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Paracoccidioides brasiliensis is an important human pathogen that causes paracoccidioidomycosis (PCM), a systemic mycosis with a wide distribution in Latin America. The ability of P. brasiliensis to cause not only human diseases but also mycoses with a variety of clinical manifestations from localized forms to the disseminated disease progressing to lethality, probably depends on the relationship between the virulence of the fungus, its ability to interact with and to invade the surface structures of the host and the immune response of the host. The adhesion of the pathogen leads to the recognition of carbohydrate and protein ligands on the surface of the host cell or proteins of the extracellular matrix (ECM). The large number of tissue types that fungi can colonize and infect suggests that they use a variety of surface molecules for adhesion.Understanding the interactions between P. brasiliensis and the host tissue depends on the study of the different steps of the process of colonization, especially adhesion, in which the pathogen recognizes ligands on the surface of host cells. This study aimed to verify the role of enolase in the host cell-fungus interaction and the ability of enolase to bind to extracellular matrix components, to determine its subcellular localization. The data revealed that fibronectin is the major ligand of enolase. Evaluation of the location of enolase at an ultrastructural level revealed that it is distributed in various cellular compartments, but at a high level in the cell wall. This suggests that enolase performs additional functions related to the glycolytic pathway and also plays a role of adhesion in P. brasiliensis. Therefore, this study increases the knowledge about the characteristics of enolase and its influence on the binding process of P. brasiliensis / Orientador: Ana Marisa Fusco Almeida / Coorientador: Maria José Soares Mendes Giannini / Banca: Márcia Aparecida Silva Graminha / Banca: Eduardo Bagagli / Mestre
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Identificação de adesinas de Leptospira interrogans por shotgun phage display / Identification of Leptospira interrogans adhesins by shotgun phage displaySwiany Silveira Lima 06 February 2013 (has links)
Em Leptospira interrogans algumas proteínas com capacidade de ligação aos componentes de matriz extracelular foram identificadas e, em sua maioria, são fatores de virulência. Phage display é considerada uma técnica poderosa na identificação de novos ligantes, inclusive de moléculas adesinas, importantes no primeiro estágio de infecção do hospedeiro. A técnica de shotgun phage display foi utilizada visando à obtenção de ligantes à células de mamíferos. Quatro bibliotecas, por inserção de fragmentos aleatórios obtidos por sonicação do DNA de L. interrogans nos fagomídeos pG8SAET (BBT1 e BBT2) e pG3DSS (BBT5 e BBT6), foram construídas. As bibliotecas BBT1 e BBT5 contém insertos maiores e as BBT2 e BBT6 contém insertos menores, com tamanhos médios de 1500 pb e 350 pb, respectivamente. Após ensaio de panning da BBT5 contra células de mamíferos e soro fetal bovino, as sequências de clones selecionados foram analisadas quanto a orientação correta e se a fusão estava em fase com a proteína pIII. As proteínas codificadas pelos genes LIC11719, LIC10769, LIC13143 e LIC12976 foram selecionadas com estas características. Os genes que codificam a LIC12976, LIC10768, LIC10769 e LIC13418, tiveram sua conservação avaliada em diferentes sorovares da espécie patogênica L. interrogans e no sorovar Patoc da espécie de vida livre L. biflexa. As proteínas LIC12976 (selecionada pela técnica de phage display) e LIC13418 (selecionada por ferramentas de bioinformática) tiveram suas sequências amplificadas por PCR, clonadas em pGEM T easy, subclonadas em vetor de expressão pAE e expressas na fração celular correspondente ao corpúsculo de inclusão em E. coli BL21 (DE3) Star pLysS e E. coli BL21 SI, respectivamente. Após renaturação e purificação destas proteínas por cromatografia de afinidade a metal bivalente, um grupo de cinco animais BALB/c fêmeas foi imunizado. Ambas as proteínas se mostraram imunogênicas com títulos dos soros policlonais 1:256000 e 1:512000, respectivamente. Em ensaio de Western Blot os soros foram específicos no reconhecimento das proteínas recombinantes e as proteínas nativas foram verificadas em extratos de sorovares patogênicos de L. interrogans. Em ensaios de adesão, as proteínas recombinantes aderiram às células A31, LLC-PK1 e Vero e especificamente à laminina. Em ensaios de interferência em células usando laminina houve um aumento da adesão das proteínas recombinantes, o que pode ser explicado pela ligação da laminina às células e uma maior ligação das LICs estudadas. Em ensaio de localização celular usando imunofluorescência e microscopia eletrônica, foi observado que ambas as proteínas se encontram na superfície da L. interrogans. No experimento de desafio animal, a LIC12976 e a LIC13418 não se mostraram protetoras. Este trabalho contribuiu para a identificação das novas adesinas LIC13418 e LIC12976 que podem participar da virulência de leptospiras patogênicas envolvendo a primeira etapa da infecção na interação patógeno-hospedeiro / In Leptospira interrogans, proteins capable to bind to extracellular matrix components have been identified and most of them are important virulence factors. Phage display is a powerful technique to identify new ligands, including adhesin molecules that are important in the first stage of host infection. A shotgun phage display technique was used in order to obtain cell ligands. Four libraries were constructed by inserting random fragments obtained by sonication of L. interrogans DNA into phagemids pG8SAET (BBT1 and BBT2) and pG3DSS (BBT5 and BBT6). The libraries BBT1 and BBT5 contain larger inserts and BBT2 and BBT6 contain smaller inserts, with 1500 bp and 350 bp average sizes, respectively. After panning of BBT5 against mammalian cells and bovine fetal serum, the sequences of selected clones were analyzed for correct orientation and fusion with pIII protein. The proteins encoded by genes LIC11719, LIC10769, LIC13143 and LIC12976 were selected. The genes LIC12976, LIC10768, LIC10769 and LIC13418 were evaluated for their conservation in different pathogenic serovars of L. interrogans and free-living L. biflexa serovar Patoc. Proteins LIC12976 (selected by phage display technique) and also LIC13418 that was selected by bioinformatic tools, were amplified by PCR, cloned into pGEM T easy, subcloned into expression vector pAE and expressed in cellular fraction corresponding to the inclusion body in E. coli BL21 (DE3) Star pLysS and E. coli BL21 SI, respectively. After protein renaturation protocol and purification by affinity chromatography, a group of five BALB/c mice was immunized with the purified proteins. Both proteins were shown to be immunogenic with 1:256000 and 1:512000 polyclonal sera titers, respectively. In Western blot the sera were specific to recognize recombinant proteins and native proteins were detected in pathogenic L. interrogans serovars extracts. In binding assays, recombinant proteins bind to A31, LLC-PK1 and Vero cells and specifically to laminin. In interference cell assay using laminin there was an increase of recombinant protein bindings, which can be explained by the laminin binding to cells and further binding of the recombinant LICs. In cellular localization assay using immunofluorescence and electron microscopy, it was observed that both are surface proteins of L. interrogans. In the animal challenge, the LIC12976 and LIC13418 were not protective. As a whole, this work contributed to the identification of LIC12976 and LIC13418 as new adhesins and they can participate in the virulence of pathogenic Leptospira in the first stage of host pathogen interaction.
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