Global ETD Search

51	Computational mining for terminator-like genes in soybean Mahmood, Hamida January 1900 (has links) Master of Science / Genetics Interdepartmental Program - Plant Pathology / Frank F. White / Sanzhen Liu / Plants and bacterial pathogens are in constant co-evolution to survive and sustain the next generation. Plants have two well-characterized levels of active defense -pathogens-associated molecular patterns (PAMPs)-triggered immunity (PTI) and effectors-triggered immunity (ETI). Some plants that are hosts for bacterial pathogens employing type three secretion system transcription activator-like (TAL) effectors have evolved a unique form of ETI, namely TAL effector-mediated ETI. TAL effectors induce expression of specific disease susceptibility (S) genes. Rice and pepper have evolved resistance genes termed terminator (T) genes, which have promoters that bind TAL effectors and, upon expression of the T gene, elicit a hypersensitive reaction (HR) and cell death. Only five T genes have been cloned, and the origin of most T genes is unknown. To determine the presence of candidate T genes in other plants species, a bioinformatics-based mining was designed. The basic approach utilized three structural features common to four terminator genes: a short trans-membrane domain, a secretion signal domain, and a length of <200 amino acid residues. Soybean was chosen as the test plant species, and 161 genes were retrieved that fulfilled the three parameters using R and Perl software programs. Further, functional annotation of candidate genes was conducted by comparisons to genes in public databases. Major classes of proteins found included unique and hypothetical, defense/stress/oxidative stress associated, DNA-binding, kinases, transferases, hydrolases, effector-related tRNA splicing, and F- box domain proteins. The potential T genes will serve as candidates for experimental validation and new resources for durable resistance strategies in crop species. Terminator gene TAL effector Computational mining Bioinformatics Disease resistance Hypersensitive reaction
52	Novel Role of the Agrobacterium Virulence Effector Protein VirE2 in Modulating Plant Gene Expression Rachelle Amanda Lapham (6838424) 14 August 2019 (has links) <p><i>Agrobacterium tumefaciens </i>transfers virulence effector proteins to infected host plants to facilitate the transfer and trafficking of a piece of its tumor inducing (Ti) plasmid, (T-[transfer] DNA), into and through plant cells.<sup> </sup>T-DNA integrates into the host genome where it uses the host’s gene expression machinery to express transgenes. Scientists have used this process to insert beneficial genes into plants by replacing native T-DNA in the bacteria with engineered T-DNA, making <i>Agrobacterium</i>-mediated transformation the preferred method for crop genetic engineering. In spite of its wide-spread use in research and agriculture, we still do not have a complete understanding of the transformation process. Consequently, many important crop species remain highly resistant to transformation. One of my lab’s major goals is to define the molecular interactions between <i>Agrobacterium</i> and its host plants which mediate transformation. I study the role of the <i>Agrobacterium</i> effector protein, VirE2, which is important for plant transformation. VirE2 likely coats the transferred DNA (T-DNA) after it enters the plant cell and protects it from degradation. VIP1 is a host transcription factor that interacts with VirE2 and is involved in activating plant defense responses. VIP1 localizes to both the cytoplasm and the nucleus.<sup> </sup>Under stress, VIP1 localizes to the nucleus where it activates expression of defense response genes.<sup> </sup>This observation led to the model that T-DNA-bound VirE2 binds VIP1 and uses VIP1 nuclear localization to deliver T-DNA into the nucleus (the “Trojan Horse” model). In contrast to this model, our lab has obtained data showing that VirE2 holds at least a portion of the VIP1 pool outside the nucleus. We also showed that VIP1 and its homologs are not necessary for transformation. VirE2 interacts with several host proteins in addition to VIP1, and these interactions could lead to changes in host gene expression and protein levels, possibly facilitating transformation. We investigated this model by placing VirE2 under the control of an inducible promoter in <i>Arabidopsis</i> and performing RNA-seq and proteomics under non-induced and induced conditions, and in the presence of <i>Agrobacterium</i> to determine its individual effect on plant RNA and protein levels during infection. Some genes differentially expressed after VirE2 induction are known to be important for transformation. Knockout mutant lines of some VirE2 differentially expressed genes showed altered transformation phenotypes. Protein levels of genes known to be important for transformation were also increased in response to VirE2 induction, and overexpression of some of these genes resulted in increased transformation susceptibility. We therefore conclude that VirE2 modulates both plant RNA and protein levels to facilitate transformation.</p> Microbiology Molecular Biology Biotechnology Plant Cell and Molecular Biology Agrobacterium tumefaciens effector proteins VirE2 Plant gene expression
53	Regulation of Kinesin-1 activity by Salmonella effectors PipB2 and SifA / Régulation de l'activité de la kinésine-1 par les effecteurs de Salmonella PipB2 et SifA Alberdi, Maria Lucrecia 02 November 2018 (has links) Salmonella est un pathogène intracellulaire qui établit une niche de réplication (SCV) grâce à l’activité des toxines que la bactérie injecte dans le cytosol des cellules infectées. La Kinésine-1, une protéine moteur des microtubules, est la cible de certaines de ces toxines. Ce travail démontre le rôle critique de la kinésine-1 pour la formation de tubules membranaires induits par Salmonella et qui émanent des SCVs. Des travaux antérieurs avaient montré que la toxine PipB2 lie la kinésine-1 à la SCV. Nos résultats écartent une interaction potentielle de PipB2 avec d’autres protéines moteur et renforcent l’idée d’une activité spécifique du couple PipB2/kinésine-1. Grâce à l’utilisation de systèmes in vitro, nous avons montré que: 1) l’activité du complexe PipB2/Kinésine-1 est suffisante pour permettre la formation de tubules membranaires à partir de vésicules artificielles; 2) PipB2 lie et active le moteur moléculaire qui s’engage alors sur les microtubules. Il a été suggéré que la protéine de l’hôte SKIP activait la kinésine-1 en se liant à la toxine SifA. Ce travail met en lumière un mécanisme plus précis grâce à un partenariat entre PipB2 et SifA. / Salmonella is an intracellular pathogen that establishes a replication niche (SCV) through the activity of toxins that the bacterium injects into the cytosol of infected cells. Kinesin-1, a microtubule motor protein, is the target of some of these toxins. This work demonstrates the critical role of kinesin-1 in the formation of Salmonella-induced membrane tubules emanating from the SCVs. Previous work has shown that PipB2 toxin binds kinesin-1 to the SCVs. Our results rule out a potential interaction of PipB2 with other motor proteins and reinforce the idea of a specific activity of the PipB2/kinesin-1 pair. Through the use of in vitro systems, we have shown that: 1) the activity of the PipB2/Kinesin-1 complex is sufficient to pull membrane tubules from artificial vesicles; 2) PipB2 binds and activates the molecular motor which then engages on the microtubules. It has been suggested that the host protein SKIP activates kinesin-1 by binding to the SifA toxin. This work highlights a more precise mechanism thanks to a partnership between PipB2 and SifA. Salmonella Effecteurs In vitro Kinésine-1 Salmonella Effector In vitro Kinesin-1 570
54	Estudos funcionais e bioquímicos sobre o reconhecimento e inibição de efetores de um sistema de secreção tipo IV de Xanthomonas citri subsp. citri. / Functional and biochemical son the recognition and Inhibition of effectors of a Type IV secretion System of Xanthomonas citri subsp. citri Oka, Gabriel Umaji 03 October 2017 (has links) Sistemas de Secreção Tipo IV (T4SSs), normalmente compostos por 12 proteínas (VirB1-VirB11 e VirD4) são tipicamente associados às funções de conjugação bacteriana e transferência de fatores de patogenicidade para células hospedeiras. Mas também, muitas espécies da ordem Xanthomonadales possuem um T4SS associado a matar bactérias. O modelo atual de morte de uma célula-alvo mediada pelo T4SS é baseado na secreção de toxinas denominadas XVIPs (\"Xanthomonas VirD4 interacting proteins\") ou X-Tfe (Xanthomonadaceae-T4SS effector) no qual cada XVIP/X-Tfe apresenta uma proteína de imunidade cognata denominada X-Tfi (Xanthomonadaceae-T4SS immunity protein). Demonstramos que um XVIP, XAC2609, é secretado através do T4SS de modo que depende de contato célula-célula e do seu domínio XVIPCD (\"XVIP conserved domains\"). A porção N-terminal de XAC2609 codifica um domínio GH19 que cliva a peptideoglicana de E. coli, mas perde a sua atividade na presença do seu inibidor cognato, o X-Tfi XAC2610. Portanto, XAC2609/XAC2610 formam um par de proteínas efetora/imunidade associado ao T4SS de X. citri. Através de diferentes técnicas de microscopias utilizando a cepa Δxac2610, foi observado que XAC2610 protege o envelope celular de X. citri contra efeitos de autólise celular promovidos pela atividade de XAC2609. Ensaios funcionais baseados nas observações de fenótipos de colônias e de formação de biofilme mostraram que XAC2610 confere imunidade para X. citri contra uma atividade 7 intrínseca de XAC2609. A proteína com o papel de reconhecer os substratos através da interação com os sinais de secreção do T4SS é VirD4. No T4SS de X. citri, existe a hipótese de que o domínio XVIPCD seja o sinal de secreção presente nas XVIPs. Logo, os aspectos bioquímicos e biofísicos da interação VirD4-XVIPCD foram investigados através de experimentos de co-purificação por cromatografia de afinidade e exclusão molecular, RMN e SAXS. Demonstramos que o domínio AAD de VirD4 (VirD4AAD) está associado a interagir especificamente com o domínio XVIPCD de XAC2609 (XAC2609XVIPCD), formando um heterodímero em solução. VirD4AAD é um domínio globular e monomérico e XAC2609XVIPCD é desenovelado mas se enovela concomitante à interação com VirD4AAD. Construções de XAC2609 contendo mutações pontuais no domínio XVIPCD foram utilizadas em ensaios in vivo de secreção pela X. citri e ensaios in vitro de interação com VirD4AAD por titulação monitorada por calorimetria isotérmica (ITC). Através desses experimentos, observamos que uma forte interação entre VirD4AAD-XAC2609XVIPCD é essencial para secreção de XAC2609 via o T4SS. Esses resultados permitem concluir que o domínio XVIPCD é o sinal de secreção dos substratos do T4SS de X. citri e que o AAD confere especificidade à VirD4 por interagir com o XVIPCD. Finalmente, através de ensaios de competições bacterianas entre E. coli e X. citri, foram observados diferentes fenótipos associados à função do T4SS: i) nocautes gênicos das subunidades estruturais VirB5, VirB11 abolem a função do T4SS em X. citri.; ii) nocautes de xac2611, apresentaram uma maior vantagem adaptativa do que a cepa selvagem de X. citri em competições e a expressão epissomal de XAC2611 inibe fortemente a função do T4SS e iii) a atividade ATPásica de VirD4 é essencial para a função do sistema e a expressão de mutantes 8 de VirD4 exerce um fenótipo de dominância negativa sobre a função do T4SS em X. citri. / The Type IV secretion System (T4SS) is typically associated with the function of bacterial conjugation and as a pathogenicity factor. T4SSs are normally composed of 12 proteins, VirB1-VirB11 and VirD4. Many species of the order Xanthomonadales possess a T4SS associated with killing bacteria. The current model of the T4SS killing is based on the secretion of toxins denominated XVIPs/X-Tfes (Xanthomonas VirD4 interacting proteins) /(Xanthomonadaceae-T4SS effector) in which each XVIP/X-Tfe has a cognate immunity protein denominated X-Tfi (Xanthomonadaceae-T4SS immunity protein). We demonstrate that an XVIP, XAC2609, is secreted through the T4SS so that it depends on cell-cell contact and its XVIPCD domain (\"XVIP conserved domains\"). The N-terminal portion of XAC2609 encodes a GH19 domain which cleaves the E. coli peptidoglycan but loses its activity in the presence of its cognate inhibitor, X-Tfi XAC2610. Therefore, XAC2609 /XAC2610 form a pair of effector/immunity proteins associated with X. citri T4SS. By using the X. citri Δxac2610 strain, has been shown through different microscopic techniques that XAC2610 protects the cell envelope of X. citri against the effects of cellular autolysis promoted by XAC2609 activity. Functional assays based on observations of colony phenotypes and biofilm formation has shown that XAC2610 confers immunity to X. citri against an intrinsic activity of XAC2609. VirD4 is the protein that recognizes the substrates through the interaction with the T4SS secretion signals. In the T4SS of X. citri, is hypothesized that the XVIPCD domain is the secretion signal present in the XVIPs. Here, the biochemical and biophysical aspects of the VirD4-XVIPCD interaction were investigated through Pull- Down, Molecular Exclusion Chromatography, NMR and SAXS assays. It has been shown the AAD domain of VirD4 (VirD4AAD) is associated with specifically interacting with the XAC2609XVIPCD domain (XAC2609XVIPCD), forming a heterodimer in solution. VirD4AAD is a globular and monomeric domain while XAC2609XVIPCD is elongated, but upon interaction with VirD4AAD goes through structural compaction process. Constructs of XAC2609 containing point mutations in the XVIPCD domain were used to perform secretion experiments in X. citri and Isothermal titration calorimetry against VirD4AAD. Through these assays, it has been characterized that a strong interaction between VirD4AAD-XAC2609XVIPCD is essential for secretion of XAC2609 via T4SS. Consequently, these results allow concluding that the XVIPCD domain is the secretion signal of X. citri T4SS substrate and the AAD confer specificity to VirD4 by interact with the XVIPCD domains. Finally, bacterial competitions between E. coli and X. citri showed different phenotypes associated with T4SS function: i) virB5, virB11 knockouts abolish the function of T4SS in X. citri.; ii) knockouts of xac2611 exhibited a higher adaptive efficiency than the wild-type X. citri strain in competitions, but the expression of XAC2611 abolishes the function of T4SS in the wild strain of X. citri; iii) The ATPase activity of VirD4 is essential and exerts a negative dominance over the T4SS function in X.citri. Efetor-Imunidade Effector-Immunity Secreção Secretion T4SS T4SS VirD4 VirD4 Xanthomonas Xanthomonas XVIPCD XVIPCD
55	Papel da proteína EspFU em Escherichia coli enteropatogênica atípica. / Role of EspFU protein in atypical enteropathogenic Escherichia coli. Martins, Fernando Henrique 14 December 2017 (has links) Escherichia coli enteropatogênica atípica (aEPEC) é considerada um dos principais agentes etiológicos da diarreia em várias regiões do mundo. O mecanismo central da patogenicidade de aEPEC é a capacidade de causar lesões attaching-effacing (A/E) no epitélio intestinal, uma propriedade desencadeada por proteínas codificadas pelo locus of enterocyte effacement (LEE). Enquanto algumas aEPEC utilizam a via de fosforilação de Tir (Y-P) para induzir a formação de pedestais, outras cepas podem empregar a proteína efetora EspFU (TccP/TccP2) para uma eficiente polimerização de actina. Neste estudo foi avaliada a prevalência e produção de EspFU, como também o papel desempenhado por esta proteína na interação com células epiteliais e colonização intestinal, aspectos essenciais da patogênese de aEPEC. O gene espFU foi detectado em 46% das cepas de aEPEC, com uma predominância do alelo tccP2. A maioria das cepas apresentou o tir fosforilado (Y-P), sugerindo que possam utilizar diferentes mecanismos redundantes para a polimerização de actina. As cepas positivas para tccP e tccP2 foram significativamente associadas com os filogrupos E, e B1, respectivamente. A produção de EspFU (TccP/TccP2) variou de cepa-a-cepa, independentemente dos genótipos e filogrupos. A deleção do gene espFU em uma cepa de aEPEC O55:H7 (BA320) resultou em menor aderência bacteriana e comprometeu a capacidade de induzir polimerização de actina em células HeLa após 6 h de infecção. Adicionalmente, o mutante em espFU apresentou uma menor eficiência na colonização intestinal em um modelo murino de infecção. A análise da cinética da formação de pedestais por aEPEC mostrou que, de modo geral, cepas expressando EspFU foram mais aderentes e induziram polimerização de actina mais rapidamente em comparação à via de TirY-P. A adesão bacteriana e formação de pedestais mediada por EspFU regulou negativamente a expressão de LEE, além de modular a resposta transcricional epitelial por meio da ativação de genes pró-inflamatórios, como NF-kB, IL-6, IL-8, entre outros. Em suma, a proteína EspFU é ampla e filogeneticamente distribuída em cepas de aEPEC, desempenha um importante papel na adesão bacteriana e colonização intestinal, e pode contribuir direta ou indiretamente para a indução de resposta inflamatória. / Atypical enteropathogenic Escherichia coli (aEPEC) is one of the most important pathogen causing diarrhea disease worldwide. The hallmark of aEPEC pathogenesis is the ability to cause attaching and effacing (A/E) lesions on intestinal epithelium, a property triggered by proteins encoded on a pathogenicity island called locus of enterocyte effacement (LEE). While some aEPEC require tyrosine phosphorylation (Y-P) of Tir to trigger actin assembling, certain strains whose Tir is not tyrosine phosphorylated utilize the T3SS effector Tir-cytoskeleton coupling protein (TccP/TccP2) for efficient actin polymerization. In the present study, we evaluated the prevalence, production, and functions played by the EspFU protein on important aspects of aEPEC pathogenesis, such as interaction with epithelial cells and intestinal colonization. The tccP and/or tccP2 genes were detected in 45.8% of the aEPEC strains, with a predominance of tccP2 allele. Most of these strains carried tirY-P, suggesting that can trigger actin polymerization using both Tir tyrosine phosphorylation and TccP/TccP2 pathways. aEPEC strains carrying tccP or tccP2 were significantly associated to phylogroups E and B1, respectively. We also observed a differential production of TccP/TccP2 among the strains, regardless genotypes and phylogeny. Deletion of espFU from aEPEC BA320 (serotype O55:H7) significantly decreased bacterial adherence and impaired the ability to induce actin rearrangement in HeLa cells after 6 h of infection. Also, the espFU mutant showed lower colonization levels compared to the wild-type strain in a murine infection model. Analysis of the kinetics of pedestal formation showed EspFU-expressing strains were more adherent and induced actin rearrangement more rapidly than Tir-phosphorylated (TirY-P) producing aEPEC. Importantly, bacterial adherence and pedestal formation driven by EspFU downregulated the LEE expression, and also induced changes in the epithelial transcriptional response, specifically by activating pro-inflammatory genes such as NKFB, IL6 and IL8. In summary, our data suggest that EspFU protein is widely and phylogenetically distributed among aEPEC strains, and play an important role on bacterial attachment and intestinal colonization. Moreover, aEPEC could induce inflammation in a EspFU-dependent manner. Escherichia coli Escherichia coli Effector protein Inflamação Inflammation Pathogenesis Patogenicidade Proteína efetora Transcriptoma Transcriptome
56	Identificação e análise funcional de interações proteína-proteína do sistema de secreção do tipo III do Xanthomonas axonopodis pv. citri<I/> / Identification and functional analysis of protein-protein interactions of type III secretion system of Xanthomonas axonopodis pv. citri<I/> Cappelletti, Paola Alejandra 28 July 2010 (has links) O cancro cítrico é considerado na atualidade uma das doenças mais perigosas e prejudiciais à citricultura brasileira e mundial, devido aos danos causados na produção e qualidade dos frutos, sendo a Xanthomonas axonopodis pv. citri (Xac) a bactéria fitopatogênica responsável por tais prejuízos. Nosso laboratório iniciou estudos de identificação e análise funcional das interações proteína-proteína de Xac envolvendo sistemas importantes para sua patogenicidade (Alegria et. al., 2004). Nosso objetivo principal foi o estudo funcional e fisiológico de interações já identificadas entre proteínas do sistema de secreção do tipo III (T3SS) da Xac. O foco de nossa pesquisa foi tentar desvendar a importância biológica, na patogenicidade de Xac, das interações proteína-proteína: HrpB2-HrcU; HpaA-HpaB-HrcV; HrpD6-HrpB1- HrpW. Com este intuito clonamos, expressamos e purificamos as proteínas recombinantes. Produzimos soros policlonais específicos contra cada uma das proteínas citadas acima. Estudamos a interação entre as proteínas in vitro por meio de técnicas como Far-Western Blot, Pull Down, fluorescência e dicroísmo circular. Outro enfoque do nosso trabalho foi monitorar a contribuição individual destas proteínas no desenvolvimento da doença in planta. Para isso produzimos cepas de Xac mutantes para os genes hrpB2, hrcU, hpaA, hpaB, hrpB1 e hrpG. Os nocautes não polares foram infiltrados em plantas de laranja pêra, assim como também as cepas de complementação correspondentes, e assim foi testada a habilidade de desenvolver o cancro cítrico e/ou reverter os sintomas da doença. Também foi monitorada a capacidade de multiplicação e sobrevida in planta das cepas Xac ΔhrpB2, ΔhrcU e ΔhpaB, assim como a secreção das proteínas HrpB2 e HpaA pelo T3SS de Xac. Estudamos com mais detalhe a possível função de HrpB2 no T3SS de Xac, desenvolvendo experimentos para determinar a região da proteína imprescindível para sua função permanecer inalterada. Realizamos mutações sítio dirigidas, a fim de introduzir códons de terminação em diferentes regiões da proteína e testar a habilidade desses fragmentos de reverter os sintomas da doença na planta. Monitoramos a capacidade de proteínas mutantes de reverter fenótipos de patogenicidade em citrus, ausentes na cepa Xac ΔhrpB2 e revertidos na cepa de complementação Xac ΔhrpB2+pUFR047_hrpB2. Desta maneira, determinamos que os últimos seis aminoácidos de HrpB2 estão envolvidos no desenvolvimento da/s função/ões em Xac. / Citrus canker, caused by the bacterial pathogen Xanthomonas axonopodis pv citri (Xac), is a disease with significant economic consequences for the Brazilian and global citrus industry due to reductions in production and fruit quality. Our laboratory has initiated studies for the identification and functional analysis of protein-protein interactions involving Xac systems involved in pathogenicity (Alegria et. al., 2004). One objective has been to study functional and physiological interactions between proteins that make up the Xac Type III secretion system (T3SS). The focus of the present study is to unravel the biological significance in Xac pathogenicity of the following previously identified protein-protein interactions: HrpB2-HrcU; HpaA-HpaBHrcV; HrpD6-HrpB1-HrpW. With therefore cloned, expressed and purified the above-mentioned recombinant proteins. Specific polyclonal serum were produced and interactions between the proteins were studied in vitro using a variety of methods, including Far-Western Blot, Pull Down, fluorescence and circular dichroism. To monitor the individual contribution of these proteins in disease development in planta, we produced mutant Xac strains in which the hrpB2, hrcU, hpaA, hpaB, hrpB1 and hrpG genes were disrupted. The nonpolar knockouts as well as the corresponding complementation strains were infiltrated into Citrus sensensis plants and the development of citrus canker symtoms and bacterial proliferation in planta was evaluated. We also evaluated the T3SS-dependent secretion of proteins HpaA and HrpB2 by these Xac mutant strains. Structure-function relationships of the HrpB2 protein were studied in more detail. We developed experiments to determine the region of the protein essential for its function. We produced a series of hrpB2 mutants which were used to complement the hrpB2 knockout strain and evaluated their abilities to reverse the symptoms of the disease in the plant. The results demonstrate that the last six amino acids HrpB2 are important for its function in the development of disease symptoms by Xac. Citricultura Citrus industty Effector Proteins Pathogenicity Patogenicidade Pilus Pilus Proteínas efetoras T3SS T3SS Xanthomonas Xanthomonas
57	Criblage de la diversité d'Oryza spp. pour l'identification de nouvelles sources de résistances dépendantes des effecteurs TAL à X. oryzae pv. oryzae, agent de la bactériose vasculaire du riz / Exploring Oryza spp. diversity to search for novel TAL effector-dependent sources of resistance against X. oryzae pv. oryzae, the causal agent of bacterial blight. Hutin, Mathilde 27 November 2015 (has links) Xanthomonas oryzae pv. oryzae (Xoo) est l’agent causal de la bactériose vasculaire du riz (BLB), une maladie dévastatrice dans de nombreux pays rizicoles. Chez cette bactérie, les effecteurs de type TAL (Transcription Activator-Like) jouent un rôle majeur dans le pouvoir pathogène. En effet ces effecteurs qui sont secrétés à l’intérieur des cellules eucaryotes hôtes par le système de sécrétion de type III de Xanthomonas agissent comme de véritables facteurs de transcription capables de manipuler le transcriptome de l’hôte via l’induction de gènes spécifiques. L’interaction entre les TALs et le promoteur hôte ciblé est régi selon un code, tel que la région centrale des répétitions des TALs s’associe spécifiquement à sa séquence cible à raison d’une répétition pour un nucléotide. Un TAL peut agir comme une protéine de virulence via l’induction de gènes dits de sensibilité (S) dont l’activation est nécessaire au développement de la maladie, et comme protéine d’avirulence via l’induction d’un gène dit exécuteur (E), dont l’activation promeut les réponses de défense de la plante. L’objectif de cette thèse était d’identifier et de caractériser de nouvelles sources de résistance dépendants des effecteurs de type TAL pour contrôler la BLB. Chez le riz, les gènes de sensibilité à Xoo les mieux caractérisés sont ceux du clade III de la famille SWEET des transporteurs de sucres. L’un d’entre eux, OsSWEET14, est particulièrement important puisqu’il est ciblé par 4 effecteurs TALs différents et issus de souches de Xoo appartenant à des lignées génétiques distinctes et d’origines géographiques différentes. Partant du constat de la convergence pour l’induction de ce gène S majeur, un crible moléculaire du promoteur de OsSWEET14 a été réalisé dans le but d’identifier du polymorphisme pouvant affecter la liaison TAL-ADN et en conséquence entrainer une perte de sensibilité. Ces travaux ont permis l’identification du gène xa41(t) qui confère une forme de résistance récessive et à large spectre contre Xoo. Dans une seconde partie, le criblage phénotypique d’une centaine de variétés de riz résistantes à la souche africaine de Xoo MAI1 a permis d’identifier cinq TALs agissant comme des protéines d’avirulence. C’est le cas des effecteurs Tal2 et Tal9 qui provoquent spécifiquement une réaction de résistance sur la variété de riz IR64 dont le génome a été séquencé. Des analyses de type RNAseq ont été réalisées et ont permis d’identifier une dizaine de gènes exécuteurs E candidats expliquant potentiellement la résistance de IR64 à la souche de Xoo MAI1. Finalement, une troisième stratégie a été menée dans le cadre d’un projet collaboratif, visant à démontrer que PiCO39 conférant la résistance du riz au champignon pathogène Magnaporthe oryzae pouvait aussi contrôler les bactérioses vasculaire et à stries foliaires. Pour ce faire, des TAL artificiels (dTALE) ont été dessinés pour induire spécifiquement l’expression de la construction de M. oryzae AVR1-CO39 dans des riz transgéniques résistant (PiCO39) et sensible (pico39). Nos données montrent que l’induction de AVR1-CO39 par Xoo ou Xoc conduit de manière PiCO39-dépendante à une réduction spectaculaire des symptômes. Ceci démontre que les réactions de défense induites par un gène de résistance à M. oryzae sont également fonctionnelles contre X. oryzae, ouvrant de nouvelles perspectives originales quant aux stratégies de contrôle des bactérioses dues à Xanthomonas. / Bacterial blight caused by Xanthomonas oryzae pv. oryzae (Xoo) is the most destructive bacterial disease of rice. Xoo pathogenicity critically depends on the TAL (Transcription Activator-Like) effectors. TALs are type three effectors secreted through a type three secretion system into the eukaryotic cell where they act as transcription factors able to manipulate the host transcriptome via the induction of specific genes. DNA-binding specificity involves a unique central repeated region in the TAL effector whereby each repeat directly binds to one single nucleotide. TALs can act as major virulence effector thtough the induction of so-called susceptibility (S) genes that are essential for disease development, or act as avirulence effector by inducing so-called executor (E) resistance genes that promote host defense responses. The goal of this PhD project was to identify and characterize novel TAL-dependent resistance sources to control BLB. In rice, the best characterized S genes are those of the clade III of the sugar transporters SWEET family. The most important is OsSWEET14 as this gene is targeted at unrelated DNA boxes by four TAL effectors, which belong to strains of different lineages and geographic origins. The evolutionary convergence for the induction of SWEET14 reflects its crucial role as major determinant of rice susceptibility to Xoo. A molecular screening of the OsSWEET14 promoter was performed using the natural diversity of wild African rice in order to identify polymorphism that could affect the TAL/DNA binding and thus lead to loss of susceptibility. This work allowed the identification of xa41(t) that confers broad spectrum recessive resistance to Xoo. In a second part of my PhD project, a phenotypic screen for resistance against the Xoo African strain MAI1 of a hundred of rice accessions enabled to identify five TALs. Among them, Tal2 and Tal9 were shown to trigger resistance on the rice variety IR64 the genome of which is fully sequenced. RNAseq analysis identified a small set of resistance E gene candidates underlying potentially IR64 resistance against Xoo strain MAI1. Finally, as a third strategy we aimed within a collaborative project to investigate if PiCO39 that confers resistance of rice towards Magnaporthe oryzae could also control BLB and BLS (Bacterial leaf streak). To that end, Artificial TAL effectors (dTALe) were designed to induce specifically the M. oryzae AVR1-CO39 construct in resistant (PiCO39) and susceptible (piCO39) transgenic backgrounds. We show that the induction of AVR1-CO39 by Xoo or Xoc drastically impairs bacterial colonization in a PiCO39-dependent manner, highlighting the potential of exploiting rice blast or other resistance genes as novel strategies to control rice pathogenic Xanthomonas bacteria. Phytopathologie Xanthomonas Riz Resistance/sensibilité Tal Effecteur/cible Phytopathologu Xanthomonas Rice Resistance/succeptibility Tal Effector/target
58	In situ studies on Foxp3+ regulatory T cells in central nervous system autoimmune disease Zandee, Stephanie Elizabeth Johanna January 2016 (has links) In multiple sclerosis (MS), pathogenic T effector cells (Teff) are believed to orchestrate immune-mediated destruction of the central nervous system (CNS) myelin sheath. In experimental autoimmune encephalomyelitis (EAE), a mouse model of MS, CNS infiltration by regulatory T cells (Treg), producing the anti-inflammatory cytokine IL-10, promotes the resolution of disease. Currently, little is understood about how Treg function within the inflamed CNS and on which cells they exert their suppressive function. There is a debate as to whether Treg in MS patients are capable of infiltrating the CNS and if they do, it is unclear whether they are functional. Understanding Treg function in EAE and MS could open up new possibilities for treatment, as Treg could be modulated for immunosuppressive therapy. A key step in the development of EAE (and presumably MS) is the ability of Teff cells to cross the blood brain barrier (BBB) and enter the CNS parenchyma. The hypothesis of this work was that Treg facilitate resolution of the inflamed CNS by preventing entry of the pathogenic T cells into the CNS parenchyma, thus preventing further damage. As such, it is important to understand with which immune cells and CNS resident cells Treg communicate to achieve resolution of disease. The presence of Treg in MS lesions was investigated with double immunohistochemistry (IHC) in frozen post-mortem MS brain tissue. CD4+Foxp3+ Treg were present in a subset of patients and their presence was associated with perivascular retention of CD4+Foxp3- and CD8+Foxp3- T cells. Foxp3+ cells in MS lesions predominantly expressed IL-10, indicating regulatory activity, although low-level production of IL-17, TNF-α, IFN-γ and GM-CSF was observed as well. Generally, analysis of total cytokine expression identified distinct patterns of cytokine production between lesions. Nonetheless, these could not be used to discriminate individual patients. These studies were repeated in C57BL/6 mice in which the Treg population was depleted before onset of EAE to mimic lesions with and without Treg presence, as found in MS patients. An immunofluorescent technique to study up to 5 fluorochromes simultaneously was developed to study antigen presenting cell (APC), Teff and Treg location, spatial relationship and function (as measured by cytokine expression) in the CNS of EAE mice at different stages of disease. Using this technique it was found that CD4+Foxp3- Teff and CD4+Foxp3+ Treg were located within 50-100μm of CD11c+ APC in the CNS of EAE affected mice. CNS Teff and Treg predominantly produced IFN-γ or IL-10, although low levels of IL-17 were detected in Teff and Treg as well. IL-17+ Treg were close to IL-17+ Teff, IFN-γ+ Treg were close to IFN-γ+ Teff, but IL-10+ Treg were not in close proximity to IL-10+ T cells in the CNS during EAE. In conclusion, there is evidence for functional Treg in EAE and MS lesions, supporting the concept of enhancing Treg activity as a clinical intervention. Treg seem to be capable of retaining pathogenic T cells at the blood brain barrier in MS lesions. In addition, studies of cytokine expression in MS lesions indicated that there is no sound basis for patient stratification based on peripheral blood cytokine profile. This thesis advances our understanding of Treg location, function and spatial relationship with other immune cells within the inflamed CNS.
59	Development of N-glycan Specific Plant Produced Antibody Therapeutics for a Fine-tuned Immune Response January 2019 (has links) abstract: Antibodies are naturally occurring proteins that protect a host during infection through direct neutralization and/or recruitment of the innate immune system. Unfortunately, in some infections, antibodies present unique hurdles that must be overcome for a safer and more efficacious antibody-based therapeutic (e.g., antibody dependent viral enhancement (ADE) and inflammatory pathology). This dissertation describes the utilization of plant expression systems to produce N-glycan specific antibody-based therapeutics for Dengue Virus (DENV) and Chikungunya Virus (CHIKV). The Fc region of an antibody interacts with Fcγ Receptors (FcγRs) on immune cells and components of the innate immune system. Each class of immune cells has a distinct action of neutralization (e.g., antibody dependent cell-mediated cytotoxicity (ADCC) and antibody dependent cell-mediated phagocytosis (ADCP)). Therefore, structural alteration of the Fc region results in novel immune pathways of protection. One approach is to modulate the N-glycosylation in the Fc region of the antibody. Of scientific significance, is the plant’s capacity to express human antibodies with homogenous plant and humanized N-glycosylation (WT and GnGn, respectively). This allows to study how specific glycovariants interact with other components of the immune system to clear an infection, producing a tailor-made antibody for distinct diseases. In the first section, plant-produced glycovariants were explored for reduced interactions with specific FcγRs for the overall reduction in ADE for DENV infections. The results demonstrate a reduction in ADE of our plant-produced monoclonal antibodies in in vitro experiments, which led to a greater survival in vivo of immunodeficient mice challenged with lethal doses of DENV and a sub-lethal dose of DENV in ADE conditions. In the second section, plant-produced glycovariants were explored for increased interaction with specific FcγRs to improve ADCC in the treatment of the highly inflammatory CHIKV. The results demonstrate an increase ADCC activity in in vitro experiments and a reduction in CHIKV-associated inflammation in in vivo mouse models. Overall, the significance of this dissertation is that it can provide a treatment for DENV and CHIKV; but equally importantly, give insight to the role of N-glycosylation in antibody effector functions, which has a broader implication for therapeutic development for other viral infections. / Dissertation/Thesis / Doctoral Dissertation Molecular and Cellular Biology 2019 Immunology Biomedical engineering Biology Antibody Dependent Enhancement Antibody Effector Function Chikungunya Virus Dengue Virus Glycoengineering Therapeutics
60	YopD translocator function in Yersinia pseudotuberculosis type III secretion Costa, Tiago R. D. January 2012 (has links) Type III secretion systems (T3SS) are a common feature of Gram-negative bacteria, allowing them to inject anti-host effectors into the interior of infected eukaryotic cells. By this mechanism, these virulence factors help the bacteria to modulate eukaryotic cell function in its favor and subvert host innate immunity. This promotes a less hostile environment in which infecting bacteria can colonize and cause disease. In pathogenic Yersinia, a crucial protein in this process is YopD. YopD is a T3S substrate that, together with YopB, forms a translocon pore in the host cell membrane through which the Yop effectors may gain access to the target-cell cytosol. The assembly of the translocator pore in plasma membranes is considered a fundamental feature of all T3SSs. How the pore is formed, what determines the correct size and ultimately the stoichiometry between YopD YopB, is still unknown. Portions of YopD are also observed inside HeLa cells. Moreover, YopD functions together with its T3S chaperone, LcrH, to control Yops synthesis in the bacterial cytoplasm. The multifunctional YopD may influence all these processes by compartmentalizing activities into discrete modular domains along the protein length. Therefore, understanding how particular domains and/or residues within these regions coordinate multiple functions of the protein will provide a platform to improve our knowledge of the molecular mechanisms behind translocation through T3SSs. Comprehensive site-directed mutagenesis of the YopD C-terminal amphipathic α-helix domain, pinpointed hydrophobic residues as important for YopD function. Some YopD variants were defective in self-assembly and in the ability to interact with the needle tip protein, LcrV, which were required to facilitate bacterial T3S activity. A similar mutagenesis approach was used to understand the role of the two predicted coiled-coils located at the N-terminal and C-terminal region of YopD. The predicted N-terminal element that occurs solely in the Yersinia YopD translocator family is essential for optimal T3SS and full disease progression. The predicted YopD C-terminal coiled-coil shapes a functional translocon inserted into host cell membranes. This translocon was seen to be a dynamic structure facilitating at least two roles during effectors delivery into cells; one to guarantee translocon pore insertion into target cell membranes and the other to promote targeted activity of internalized effector toxins. In Yersinia expression of yop genes and secretion of the corresponding polypeptides is tightly regulated at a transcriptional and post-transcriptional level. If T3S chaperones of the translocator class are known to influence transcriptional output of T3SS genes in other bacteria, we show that in Yersinia the class II T3S chaperone LcrH has no such effect on the LcrF transcriptional activator activity. We also demonstrate that there are possibly additional yop-regulatory roles for the LcrH chaperone besides forming a stable complex with YopD to impose post-transcriptional silencing on Yops synthesis. This mechanism that relies upon an active T3SS, might act independently of both YopD and the regulatory element LcrQ. In conclusion, this work has sought to delineate the encrypted functions of the YopD translocator that contribute to Yersinia T3SS-dependent pathogenesis. Contributions of the YopD cognate chaperone LcrH in yop regulatory control are also presented. Y. pseudotuberculosis T3SS translocon YopD coiled-coil effector delivery regulation virulence

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