Genotypic characterization and fungicide resistance monitoring for Virginia populations of Parastagonospora nodorum in wheat

Kaur, Navjot

28 June 2021

Stagonospora nodorum blotch (SNB), is a major foliar disease of wheat in the mid-Atlantic U.S., is caused by the necrotrophic fungus Parastagonospora nodorum. SNB is managed using cultural practices, resistant varieties, and foliar fungicides. There are increasing trends of severity and incidence of SNB in Virginia and the surrounding mid-Atlantic region, but it is not known if changes in the pathogen population are contributing to this trend. The overall goal of this research was to 1) determine the occurrence of quinone outside inhibitor (QoI) resistance in Virginia populations of P. nodorum infecting wheat, 2) quantify the distribution of G143A mutations conferring fungicide resistance in Virginia populations of P. nodorum, and 3) characterize genetic diversity of P. nodorum populations in Virginia and assess influences of cultivars and environments on population structure and SNB severity. For Objective 1, QoI resistant isolates of P. nodorum were identified from Virginia wheat fields, and this was the first report of QoI resistant P. nodorum in the United States. The G143A substitution in the cytochrome b gene of P. nodorum was associated with reduced QoI sensitivity, and in Objective 2, a state-wide, two-year survey of P. nodorum populations in Virginia determined that the G143A mutation was widespread in the state and among sampled fields the frequency ranged from 5-32% (mean = 19%). For Objective 3, P. nodorum was isolated from five different wheat cultivars across seven locations over two years in Virginia. SNB severity varied by cultivar but greater differences in disease severity were observed among locations and years suggesting environment plays an important role in SNB development. Among the necrotrophic effector (NE) genes examined, SnTox1 was predominant followed by SnTox3, and frequencies of NE genes did not vary by cultivar or location. P. nodorum populations in Virginia had high genetic diversity, but there was no genetic subdivision among locations or wheat cultivars from which individuals were isolated. Results also indicated that the P. nodorum population in Virginia undergoes a mixed mode of reproduction, but sexual reproduction made the greatest contribution to population structure. Overall, this work provides insights into the population biology of P. nodorum in Virginia and information on variability in fungicide sensitivity and cultivar susceptibility to SNB that has implications for the current and future efficacy of fungicides and host resistance for management of SNB. / Doctor of Philosophy / Wheat (Triticum aestivum L.) is one of the major cereal crops grown worldwide for food, feed, and other products. However, yields of this crop are often limited by fungal diseases including Stagonospora nodorum blotch (SNB) caused by Parastagonospora nodorum. Increasing trends of severity and incidence of SNB may be due to reduced sensitivity of P. nodorum to fungicides or increased virulence of P. nodorum populations on commonly grown cultivars. Fungicides such as quinone outside inhibitors (QoIs) are one of the major classes of fungicides used for disease control and G143A substitution is the most common point mutation associated with complete resistance to QoIs. Therefore, the overall goal of this research was to better understand genotypic and phenotypic variation in Virginia populations of P. nodorum in the context of fungicide sensitivity and susceptibility of wheat cultivars to SNB. The specific objectives were to 1) determine the occurrence of quinone outside inhibitor (QoI) fungicide resistance in Virginia populations of P. nodorum infecting wheat, 2) quantify the distribution of G143A mutations conferring QoI fungicide resistance in Virginia populations of P. nodorum, and 3) characterize genetic diversity of P. nodorum populations in Virginia and assess influences of cultivars and environments on population structure and SNB severity. Results from this research indicate that QoI fungicide resistance occurs in Virginia populations of P. nodorum due to a target site mutation (G143A substitution in the cytochrome b gene), and this mutation is widespread and relatively common in Virginia wheat fields. Based on a multi-year multilocation study, P. nodorum populations were genetically diverse, but there was no genetic subdivision among locations or wheat cultivars. SNB severity varied by location and cultivar, but disease severity was greatest at site-years with moderate springtime temperatures and high rainfall. Overall, this work contributes to a better understanding of P. nodorum populations including the current efficacy of fungicides and host resistance for management of SNB in the region.

Stagonospora nodorum blotch

Parastagonospora nodorum

Triticum aestivum

genetic diversity

population structure

necrotrophic effector genes

mating type

Functional analysis of candidate effector proteins during Sporisorium scitamineum x sugarcane interaction / Análise funcional de proteínas candidatas a efetores durante a interação Sporisorium scitamineum x cana

Silva, Natália de Sousa Teixeira e

04 February 2019

Sugarcane smut is a worldwide distributed disease important to agribusiness, since it can affect sugarcane yield drastically. The disease is caused by the Basidiomycete Sporisorium scitamineum, a biotrophic fungus that colonizes mainly sugarcane. Sugarcane-smut interaction has been extensively studied by this research group for the past few years in their various aspects, considering both the pathogen attack and plant defenses. This work aimed to functionally address fungal candidate effector proteins associated with this pathosystem. Effectors are essential to modulate host metabolism to allow pathogen colonization. The identification of such proteins may assist in recognition of resistance genes relevant to genetic breeding programs. Based on the complete genome sequence of S. scitamineum and the dual transcriptomic data candidate genes were selected in silico. Selection strategies were based on the predicted secretome and differential expression levels of the genes in planta. Candidate effectors were analyzed regarding their expression pattern, subcellular location and influence over basal plant defenses and plant immunity. The results showed that the S. scitamineum candidate effector genes are expressed under the influence of the host genotype. It was observed various expression patterns in the set of selected genes and differential subcellular localization patterns. These results will enable future researches considering virulence level of different isolates and also help decision making in plant breeding programs. / O carvão da cana-de-açúcar é uma doença cosmopolita de grande importância para o agronegócio, uma vez que pode afetar a produtividade da cultura. A doença é causada pelo basidiomiceto Sporisorium scitamineum, fungo biotrófico que coloniza exclusivamente a cana-de-açúcar. A interação cana-carvão vem sendo extensivamente estudada por este grupo de pesquisa nos últimos anos em seus vários aspectos, considerando as atividades de ataque e defesa do patógeno e da planta, respectivamente. Este trabalho teve como finalidade o estudo funcional de proteínas candidatas a efetores neste patossistema. Efetores são moléculas essenciais na manipulação do metabolismo e fisiologia do hospedeiro de forma a permitir sua colonização. A identificação de tais proteínas auxilia no reconhecimento de genes de resistência podendo gerar informações relevantes a programas de melhoramento genético na produção de variedades resistentes. A estratégia de seleção utilizada se baseia em características do secretoma predito e da expressão diferencial de genes do patógeno in planta. Os candidatos foram analisados quanto ao padrão de expressão gênica, à localização sub celular e sua influência sobre a defesa basal e imunidade em plantas. Os resultados demonstraram que a expressão dos genes que codificam para as proteínas efetoras de S. scitamineum e é influenciada pelo genótipo das plantas infectadas. Foram observadas variações no padrão de expressão entre o conjunto de efetores selecionados, bem como padrões diferenciais de localização sub celular e influência sobre a imunidade em plantas. Os resultados gerados por este trabalho servirão de subsídio para estudos futuros sobre os níveis de virulência dos diferentes isolados do patógeno bem como para auxiliar a tomada de decisão em programas de melhoramento genético de variedades resistentes ao carvão da cana.

Biologia de efetores

Carvão da cana-de-açúcar

Effector biology

Expression profile

Functional genomics

Genômica funcional

Interação planta-patógeno

Localização sub celular

Perfil de expressão gênica

Plant-pathogen interaction

Subcellular location

Sugarcane smut

Caracterização de dois pares efetor/inibidor associados ao sistema de secreção tipo IV de Xanthomonas citri / Characterization of the two effector/inhibitor pair associated with the type IV secretion system of Xanthomonas citri

Bueno, Natalia Fernanda

15 June 2018

O sistema de secreção tipo IV (T4SS) da família de bactérias Xanthomonadaceae transfere efetores (X-Tfes) com a capacidade de matar outras bactérias, conferindo uma vantagem em comunidades bacterianas mistas para colonizar diferentes nichos como o solo ou as superfícies das plantas. Os X-Tfes possuem diferentes domínios putativos com atividades hidrolíticas contra componentes do envelope celular bacteriano do tipo: glicohidrolases, transglicosilases, amidases e lipases. Os X-Tfes por sua atividade biológica inata podem ocasionar dano intracelular para a bactéria que os produz. Para se proteger contra estas atividades, também são produzidas lipoproteínas com função inibitoria (X-Tfis) localizadas no periplasma. Os genes que codificam os X-Tfes e os X-Tfis estão organizados em operons, o que permite gerar os pares efetor/inibidor simultaneamente. Entre os potenciais X-Tfes do fitopatógeno Xanthomonas citri estão Xac1918 e Xac0574. Xac1918 é uma proteína com um domínio da superfamília da lisozima e um domínio conhecido como RTX (Repeats in Toxin) de ligação ao cálcio, enquanto Xac0574 tem um domínio da superfamília da lipase 3. Os seus possíveis inibidores, Xac1917 e Xac0573 respectivamente, apresentam um peptídeo sinal no N-terminal contendo o lipobox representativo das lipoproteínas. As proteínas Xac0574 e Xac0573 são monômeros em solução que formam um complexo estável 1:1, favorecido termodinamicamente (ΔG°= -12 Kcal/mol) com uma constante de dissociação de 2,45 nM, garantindo que a bactéria fique protegida contra os efeitos nocivos de Xac0574 quando é produzida intracelularmente. Xac0574 é uma fosfolipase A1, sem atividade lisofosfolipase, com a capacidade de hidrolisar os três fosfolipídios majoritários que compõem a membrana celular bacteriana, fosfatidilglicerol (PG), cardiolipina e fosfatidiletanolamina (PE), mostrando uma aparente preferência pelo último. A atividade enzimática de Xac0574 explica a forte inibição do crescimento celular em E. coli após da sua indução heteróloga, já que gera uma diminuição de quase 10 vezes da população celular comparada com a cultura não induzida com a mesma construção. Poroutro lado, Xac0573 inibe efetivamente a atividade enzimática de Xac0574 ao formar o complexo, além de não ter atividade fosfolipase nem lisofosfolipase. Foram produzidos cristais da Xac1918 e Xac0573 que difrataram com uma resolução de 3,0 e 2,5 Å, respectivamente. Porém, só foi gerado um modelo de Xac0573. Xac0573 está composta por duas folhas β antiparalelas com uma topologia característica de β sanduíche Com uma pequena hélice e duas voltas. Um alinhamento de homólogos de Xac0573 identificou nas extremidades da proteína as regiões conservadas, constituindo duas possíveis interfaces de interação que podem ser as responsáveis por bloquear o acesso dos fosfolipídios ao sítio catalítico ou impedir os rearranjos estruturais de Xac0574 que são necessários para a sua atividade enzimática. Adicionalmente, a topologia da Xac0573 é semelhante do domínio C2, conhecido em eucariotos como domínio de ligação ao lipídio e ao cálcio, e está envolvido em processos de sinalização de segundos mensageiros lipídicos, proteínas de trafego de membranas e mecanismos de fusão de membranas. Nossos resultados apontam para uma nova função biológica do domínio C2 como um inibidor enzimático intracelular em bactérias. / The type IV secretion system (T4SS) of the bacteria family Xanthomonadaceae transfers effectors (X-Tfes) with that can kill other bacterial cells, conferring an advantage to the bacterial community during colonization of different niches in the soil or on the plant surface. The X-Tfes possess different putative domains with hydrolytic activity against components of the bacterial cellular envelope, including glycohydrolase, transglycolase, amidase and lipase domain. The innate biological activity of X-Tfes can cause intracellular damage. Therefore, the bacteria that produce them also produce lipoproteins with inhibitor function (X-Tfis) located in the periplasm for their protection. The genes that code for X-Tfes and X-Tfis are organized in operons that allow for their simultaneous expression. Among the X-Tfes of the phytopathogen Xanthomonas citri are Xac1918 and Xac0574. Xac1918 is carries a lysozyme superfamily domain, as well as a domain known as RTX (Repeats in Toxic) predict to bind calcium, while, Xac0574 has a domain belonging to the lipase 3 superfamily. Their possible inhibitors, Xac1917 e Xac0573 respectively, carry an N-terminal signal peptide containing a lipobox found in bacterial lipoproteins. The Xac0574 and Xac0573 proteins are both monomers in solution, They can form a stable 1:1 complex, that is thermodynamically favored (ΔG°= -12 Kcal/mol) with a dissociation constant of 2,45 nM. This affinity ensure that the bacterium is protected against the harmful effects of Xac0574 when it is produced intracellularly. We show that Xac0574 is a phospholipase A1, without lisophospholipase activity, and is able to hydrolyze the three most common phospholipids found in the membranes of Gram negative bacteria, namely phosphatidylglycerol (PG), cardiolipin and phosphatidylethanolamine (PE), presenting an apparent preference for PE. The enzymatic activity of Xac0574 explains the strong inhibition of growth of E. coli cells after its heterologous induction: a nearly 10-fold decrease in the cell population is observed when compared to the non-induced culture with the same construct. On the other hand, Xac0573 effectively inhibits the enzymatic activity of Xac0574. Furthermore, Xac0573 does not possess when forming the complex, besides not having phospholipase nor lysophospholipase activity.Crystals of Xac1918 and Xac0573 were produced which diffracted with to resolution of 3.0 and 2.5 Å, respectively. However, we were able to resolve the structure of only Xac0573. Xac0573 is composed of two anti-parallel sheet that form a β-sandwich with three small helices. An alignment to Xac0573 homologs identified conserved regions at the ends of the protein that constitute two possible interfaces of interaction that may be responsible for blocking the access of the phospholipids to the catalytic site or impede the structural rearrangements of Xac0574 that are necessary for its enzymatic activity. Additionally, the topology of Xac0573 is similar to that to C2 domains, known in eukaryotes to bind lipids and calcium and to be involved in signaling processes mediated by lipid second messengers, membrane trafficking and membrane fusion mechanisms. Our results point to a new biological function of the C2 domain as an intracellular enzyme inhibitor in bacteria.

Bacterial membrane

Efetor (X-Tfe)

Effector (X-Tfe)

Fosfolipase A1

Inhibitor (X-Tfi)

Inibidor (X-Tfi)

Membrana bacteriana

Phospholipase A1

Sistema de Secreção Tipo IV (T4SS)

The type IV secretion system (T4SS)

Xanthomonas

Xanthomonas

Analysis of Type Three System transport mechanism in gram-negative bacteria

Dohlich, Kim-Stephanie

24 February 2014

Das Typ III Sekretionssystem (T3SS) ist ein Proteinkomplex den Gramnegative Bakterien nutzen um in einem Schritt Effektorproteine (Effektoren) aus dem Zytosol über die Doppelmembran zu sekretieren. Für viele Bakterien ist das T3SS ein essenzieller Virulenzfaktor, der es ihnen erlaubt mit ihrem Wirt zu interagieren und diesen zu manipulieren. Charakteristisch für das T3SS ist die strukturelle Komponente, der Nadelkomplex. Dieser ähnelt strukturell einer Spritze, deren Basalkörper die bakteriellen Membranen und das Periplasma durchspannt und einer Nadel, die vom Basalkörper aus dem Bakterium ragt. Basierend auf dem Modell einer Spritze wird angenommen, dass Effektoren entfaltet und anschließend durch Basalkörper und Nadelkanal sekretiert werden. Trotz der kontinuierlichen Forschung an T3SS entbehrt dieses Modell einer experimentellen Grundlage und der Mechanismus ist nicht vollständig erklärt. Ziel der Arbeit war es, eine experimentelle Basis für den Sekretionsmechanismus des T3SS zu schaffen. Um zu verstehen, wie das T3SS Effektoren sekretiert, wurden zunächst Fusionsproteine konstruiert, welche aus einem Effektor und einem stabil gefalteten Knotenprotein bestehen. Aufgrund des Knotens in der Fusion ist davon auszugehen, dass dieser während der Sekretion nicht entfalten kann. Die Effektordomäne wird sekretiert während der Knoten im Kanal verbleibt und diesen verstopft. Nach unseremWissen ist diese Arbeit die erste Visualisierung von Effektorfusionen an isolierten Nadelkomplexen. Die Effektorfusion wird N-terminal voran durch den Kanal sekretiert, wobei der Kanal das Substrat umschließt und gegen Proteasen und chemische Modifikationen abschirmt. Die Ergebnisse dieser Arbeit untermauern eine Grundidee der Funktionsweise des T3SS und liefern eine vielversprechende Strategie für in situ-Strukturanalysen. Dieser Ansatz lässt sich auch auf andere Proteinsekretionssysteme übertragen, bei welchen Substrate vor dem Transport entfaltet werden müssen. / The Type III Secretion System (T3SS) is a complex used by Gram-negative bacteria to secrete effector proteins from the cytoplasm across the bacterial envelope in a single step. For many pathogens, the T3SS is an essential virulence factor that enables the bacteria to interact with and manipulate their respective host. A characteristic structural feature of the T3SS is the needle complex (NC). The NC resembles a syringe with a basal body spanning both bacterial membranes and a long needle-like structure that protrudes from the bacterium. Based on the paradigm of a syringe-like mechanism, it is generally assumed that effectors are unfolded and secreted from the bacterial cytoplasm through the basal body and needle channel. Despite extensive research on T3SS, this hypothesis lacks experimental evidence and the mechanism of secretion is not fully understood. This work aimed to provide an experimental basis for the model of the T3SS mechanism. In order to elucidate details of the effector secretion mechanism, fusion proteins consisting of an effector and a bulky protein containing a knotted motif were generated. It is assumed that the knot cannot be unfolded during secretion of the chimera. Consequently, these fusions are accepted as T3SS substrates but remain inside the NC channel and obstruct the T3SS. This is, to our best knowledge, the first time effector fusions have been visualized together with isolated NCs and it demonstrates that effector proteins are secreted directly through the channel with their N-terminus first. The channel encloses the substrate and shields it from a protease and chemical modifications. These results corroborate an elementary understanding of how the T3SS works and provide a powerful tool for in situ-structural investigations. This approach might also be applicable to other protein secretion systems that require unfolding of their substrates prior to secretion.

Shigella flexneri

Virulenzfaktor

Typ III Sekretionssystem

T3SS

Proteintransport

Effektor

bakterielle Sekretion

Shigella flexneri

virulence factor

Type Three Secretion System

T3SS

protein transport

effector

bacterial secretion

570 Biowissenschaften, Biologie

32 Biologie

WF 5700

ddc:570

Caracterização de dois pares efetor/inibidor associados ao sistema de secreção tipo IV de Xanthomonas citri / Characterization of the two effector/inhibitor pair associated with the type IV secretion system of Xanthomonas citri

Natalia Fernanda Bueno

15 June 2018

O sistema de secreção tipo IV (T4SS) da família de bactérias Xanthomonadaceae transfere efetores (X-Tfes) com a capacidade de matar outras bactérias, conferindo uma vantagem em comunidades bacterianas mistas para colonizar diferentes nichos como o solo ou as superfícies das plantas. Os X-Tfes possuem diferentes domínios putativos com atividades hidrolíticas contra componentes do envelope celular bacteriano do tipo: glicohidrolases, transglicosilases, amidases e lipases. Os X-Tfes por sua atividade biológica inata podem ocasionar dano intracelular para a bactéria que os produz. Para se proteger contra estas atividades, também são produzidas lipoproteínas com função inibitoria (X-Tfis) localizadas no periplasma. Os genes que codificam os X-Tfes e os X-Tfis estão organizados em operons, o que permite gerar os pares efetor/inibidor simultaneamente. Entre os potenciais X-Tfes do fitopatógeno Xanthomonas citri estão Xac1918 e Xac0574. Xac1918 é uma proteína com um domínio da superfamília da lisozima e um domínio conhecido como RTX (Repeats in Toxin) de ligação ao cálcio, enquanto Xac0574 tem um domínio da superfamília da lipase 3. Os seus possíveis inibidores, Xac1917 e Xac0573 respectivamente, apresentam um peptídeo sinal no N-terminal contendo o lipobox representativo das lipoproteínas. As proteínas Xac0574 e Xac0573 são monômeros em solução que formam um complexo estável 1:1, favorecido termodinamicamente (ΔG°= -12 Kcal/mol) com uma constante de dissociação de 2,45 nM, garantindo que a bactéria fique protegida contra os efeitos nocivos de Xac0574 quando é produzida intracelularmente. Xac0574 é uma fosfolipase A1, sem atividade lisofosfolipase, com a capacidade de hidrolisar os três fosfolipídios majoritários que compõem a membrana celular bacteriana, fosfatidilglicerol (PG), cardiolipina e fosfatidiletanolamina (PE), mostrando uma aparente preferência pelo último. A atividade enzimática de Xac0574 explica a forte inibição do crescimento celular em E. coli após da sua indução heteróloga, já que gera uma diminuição de quase 10 vezes da população celular comparada com a cultura não induzida com a mesma construção. Poroutro lado, Xac0573 inibe efetivamente a atividade enzimática de Xac0574 ao formar o complexo, além de não ter atividade fosfolipase nem lisofosfolipase. Foram produzidos cristais da Xac1918 e Xac0573 que difrataram com uma resolução de 3,0 e 2,5 Å, respectivamente. Porém, só foi gerado um modelo de Xac0573. Xac0573 está composta por duas folhas β antiparalelas com uma topologia característica de β sanduíche Com uma pequena hélice e duas voltas. Um alinhamento de homólogos de Xac0573 identificou nas extremidades da proteína as regiões conservadas, constituindo duas possíveis interfaces de interação que podem ser as responsáveis por bloquear o acesso dos fosfolipídios ao sítio catalítico ou impedir os rearranjos estruturais de Xac0574 que são necessários para a sua atividade enzimática. Adicionalmente, a topologia da Xac0573 é semelhante do domínio C2, conhecido em eucariotos como domínio de ligação ao lipídio e ao cálcio, e está envolvido em processos de sinalização de segundos mensageiros lipídicos, proteínas de trafego de membranas e mecanismos de fusão de membranas. Nossos resultados apontam para uma nova função biológica do domínio C2 como um inibidor enzimático intracelular em bactérias. / The type IV secretion system (T4SS) of the bacteria family Xanthomonadaceae transfers effectors (X-Tfes) with that can kill other bacterial cells, conferring an advantage to the bacterial community during colonization of different niches in the soil or on the plant surface. The X-Tfes possess different putative domains with hydrolytic activity against components of the bacterial cellular envelope, including glycohydrolase, transglycolase, amidase and lipase domain. The innate biological activity of X-Tfes can cause intracellular damage. Therefore, the bacteria that produce them also produce lipoproteins with inhibitor function (X-Tfis) located in the periplasm for their protection. The genes that code for X-Tfes and X-Tfis are organized in operons that allow for their simultaneous expression. Among the X-Tfes of the phytopathogen Xanthomonas citri are Xac1918 and Xac0574. Xac1918 is carries a lysozyme superfamily domain, as well as a domain known as RTX (Repeats in Toxic) predict to bind calcium, while, Xac0574 has a domain belonging to the lipase 3 superfamily. Their possible inhibitors, Xac1917 e Xac0573 respectively, carry an N-terminal signal peptide containing a lipobox found in bacterial lipoproteins. The Xac0574 and Xac0573 proteins are both monomers in solution, They can form a stable 1:1 complex, that is thermodynamically favored (ΔG°= -12 Kcal/mol) with a dissociation constant of 2,45 nM. This affinity ensure that the bacterium is protected against the harmful effects of Xac0574 when it is produced intracellularly. We show that Xac0574 is a phospholipase A1, without lisophospholipase activity, and is able to hydrolyze the three most common phospholipids found in the membranes of Gram negative bacteria, namely phosphatidylglycerol (PG), cardiolipin and phosphatidylethanolamine (PE), presenting an apparent preference for PE. The enzymatic activity of Xac0574 explains the strong inhibition of growth of E. coli cells after its heterologous induction: a nearly 10-fold decrease in the cell population is observed when compared to the non-induced culture with the same construct. On the other hand, Xac0573 effectively inhibits the enzymatic activity of Xac0574. Furthermore, Xac0573 does not possess when forming the complex, besides not having phospholipase nor lysophospholipase activity.Crystals of Xac1918 and Xac0573 were produced which diffracted with to resolution of 3.0 and 2.5 Å, respectively. However, we were able to resolve the structure of only Xac0573. Xac0573 is composed of two anti-parallel sheet that form a β-sandwich with three small helices. An alignment to Xac0573 homologs identified conserved regions at the ends of the protein that constitute two possible interfaces of interaction that may be responsible for blocking the access of the phospholipids to the catalytic site or impede the structural rearrangements of Xac0574 that are necessary for its enzymatic activity. Additionally, the topology of Xac0573 is similar to that to C2 domains, known in eukaryotes to bind lipids and calcium and to be involved in signaling processes mediated by lipid second messengers, membrane trafficking and membrane fusion mechanisms. Our results point to a new biological function of the C2 domain as an intracellular enzyme inhibitor in bacteria.

Efetor (X-Tfe)

Fosfolipase A1

Inibidor (X-Tfi)

Membrana bacteriana

Sistema de Secreção Tipo IV (T4SS)

Xanthomonas

Bacterial membrane

Effector (X-Tfe)

Inhibitor (X-Tfi)

Phospholipase A1

The type IV secretion system (T4SS)

Xanthomonas

Estudo do efeito imunomodulador do derivado 3-fenilcumarínico 6,7-diidroxi-3-[3',4'-metilenodioxifenil]-cumarina em neutrófilos humanos estimulados e em modelo animal de inflamação induzida por zimosan / Study of the immunomodulator effect of the 3-phenylcoumarin derivative 6,7-dihydroxy-3-[3\',4\'-methylenedioxyphenyl]-coumarin in stimulated human neutrophils and in an animal model of zymosan-induced inflammation

Andrade, Micássio Fernandes de

29 September 2016

Os neutrófilos são os leucócitos circulantes mais abundantes. Apesar de serem importantes no combate às infecções, o intenso recrutamento e a consequente ativação dessas células levam à liberação de mediadores inflamatórios que estão relacionados com o agravamento do quadro clínico de inúmeras doenças. Dessa forma, nos últimos anos tem-se intensificado a procura por substâncias terapêuticas que minimizem os danos teciduais ocasionados pela infiltração neutrofílica. Estudos prévios do grupo de pesquisa mostraram que as 3-fenilcumarinas, que constituem uma classe de produtos naturais de origem vegetal, são substâncias promissoras como moduladores do metabolismo oxidativo de neutrófilos. Em continuidade a essas investigações, o derivado sintético 3-fenilcumarínico 6,7-diidroxi-3-[3\',4\'- metilenodioxifenil]-cumarina (C13) foi selecionado, por apresentar o grupo substituinte ortodiidroxi nas posições C-6 e C-7 do esqueleto cumarínico e a metilenodioxila ligada ao anel fenílico, no intuito de avaliar o seu efeito nas demais funções efetoras dos neutrófilos, como também em um modelo animal de inflamação articular. Foi avaliado o efeito modulatório in vitro da C13 sobre a quimiotaxia, a produção de ERO e interação com o sítio ativo da mieloperoxidase (MPO), a fagocitose de imunocomplexos (IC), a desgranulação da enzima elastase, a atividade microbicida sobre Candida albicans, a mobilização e o influxo de cálcio, a polimerização do citoesqueleto, e a formação e liberação das NETs em neutrófilos humanos. A C13 inibiu, de forma dependente da concentração, o metabolismo oxidativo de neutrófilos estimulados via receptores de IgG (Fc?R) e/ou de complemento (CR), utilizando-se diferentes tipos de IC e foi capaz de interagir com o sítio ativo da MPO. Nas concentrações próximas da necessária para inibir 50% do metabolismo oxidativo (~ 2µmol/L), a C13 não interferiu nas demais funções efetoras dos neutrófilos avaliadas. No entanto, na maior concentração avaliada (20 µmol/L), a C13 inibiu cerca de: 30% da capacidade das células de migrar a favor dos agentes quimiotáticos n-formil-metionil-leucil-fenilalanina (fMLP) e leucotrieno B4; 70% da fagocitose de IC mediada por CR; 40% e 80% da desgranulação estimulada por fMLP e IC imobilizados, respectivamente; 50% do processo de formação e liberação das NETs. Esta concentração de C13 também interferiu na polimerização do citoesqueleto de actina, mas não inibiu: a quimiotaxia de neutrófilos frente à interleucina (IL) 8; a capacidade fagocítica de IC estimulada via Fc?R e Fc?R+CR; e a atividade microbicida sobre C. albicans. Na segunda parte deste trabalho, foi avaliada a toxicidade da C13 sobre neutrófilos mantidos em condições de cultura celular por 6 e 12 h. Nos períodos avaliados, essa substância não alterou a viabilidade dos neutrófilos. Por último, a C13 foi incorporada em vesículas lipossomais e sua atividade biológica foi avaliada em ratos Wistar com inflamação articular induzida por zimosan. O tratamento dos animais com a C13 lipossomal (1mg/Kg) reduziu a formação do edema e a infiltração de leucócitos e neutrófilos na sinóvia inflamada, mas não alterou a concentração sinovial das citocinas inflamatórias fator de necrose tumoral ?, IL-1? e IL-6. Portanto, o derivado 3-fenilcumarínico C13 pode servir de protótipo para o desenvolvimento de novos agentes terapêuticos com aplicação no tratamento de doenças onde há intensa participação dos neutrófilos. / Neutrophils are the most abundant circulating leukocytes. Although neutrophils are important to fight against infections, the massive recruitment and consequent activation of these cells result in the release of inflammatory mediators that are associated with worsening of the clinical condition in many diseases. In this sense, the search for new therapeutic compounds that minimize tissue damage caused by neutrophil infiltration has been intensified in the past few years. Previous studies have demonstrated that 3-phenylcoumarins, a class of plantderived natural compounds, are promising modulators of neutrophil oxidative metabolism. To continue these investigations, we selected the 3-phenylcoumarin derivative 6,7-dihydroxy-3- [3?,4?-methylenedioxyphenyl]-coumarin (C13), bearing the 6,7-dihydroxyl and the 3?,4?- methylenedioxyl groups, to further assess its effects on the other effector functions of neutrophils, as well as on in an animal model of articular inflammation. We examined the in vitro modulator effect of C13 on the human neutrophil chemotaxis, production of ROS and interaction with active site of myeloperoxidase (MPO), phagocytosis of immune complexes (IC), degranulation, killing of Candida albicans, calcium mobilization and influx, cytoskeleton polymerization, and the formation and release of NETs. C13 inhibited, in a concentration-dependent manner, the neutrophil ROS generation elicited via IgG (Fc?R) and/ or complement (CR) receptors using different types of IC and it interacted with active site of MPO. At concentrations near to that required to suppress the ROS production by 50% (~ 2µmol/L), C13 did not modulate the other neutrophil effector functions assessed. However, at the highest concentration tested (20 µmol/L), C13 inhibited nearly: 30% of the cell ability to migrate towards n-formyl-methionyl-leucyl-phenylalanine (fMLP) and leukotriene B4; 70% of CR-mediated phagocytosis of IC; 40% and 80% of cell degranulation triggered by fMLP and immobilized IC, respectively; and 50% of the NETs formation and release process. Such C13 concentration also interfered in the actin cytoskeleton polymerization, but it did not suppress the neutrophil: chemotaxis towards interleukin (IL) 8; capacity to phagocytose IC elicited via Fc?R and Fc?R+CR; and killing of C. albicans. In the second part of this study, we examined whether C13 was toxic towards neutrophils maintained in culture for 6 and 12 h. At the time points assessed, this compound did not change the viability of neutrophils. Finally, we incorporated C13 into liposomes and examined its biological activity in Wistar rats of zymosan-induced articular inflammation. Treatment of animals with liposomal C13 reduced edema formation, and leukocyte and neutrophil infiltration in the inflamed synovia, but it did not change the synovial concentration of the inflammatory cytokines tumor necrosis factor ?, IL-1?, and IL-6. Therefore, the 3-phenylcoumarin derivative C13 can be a prototype for the development of novel therapeutic agents to be used in the treatment of diseases where neutrophils have intense participation.

Anti-inflammatory activity

Arthritis

Artrite

Atividade anti-inflamatória

Effector function

Função efetora

Liposome

Lipossoma

Neutrófilo

Neutrophil

phenylcoumarin

Identification and characterization of type III effector proteins in plant-associated bacteria

Thomas, William J.

04 May 2012

Symbioses between microbes and multicellular eukaryotes are found in all biomes, and encompass a spectrum of symbiotic lifestyles that includes parasitism and disease, commensalism, and mutually beneficial interdependent host-microbe relationships. Regardless of outcome, these symbiotic lifestyles are governed by a complex molecular "courtship" between microbe and potential host. This courtship is the primary determinant of the host range of a given microsymbiont. Host immunity poses a formidable barrier to the establishment of host-microbe relationships, and the majority of microbial suitors will be thwarted by it. Only by successfully "wooing" the host cell's immune defenses with the appropriate molecular signals can a microsymbiont successfully colonize its host. A strategy common to microsymbionts across the spectrum of symbiotic lifestyles and host organisms is the delivery of microbial-encoded effector proteins into the cytoplasm of host cells to manipulate the host cell's molecular machinery for the purposes of subverting host immunity. Bacteria, in particular, have adapted a number of secretion systems for this purpose. The most well-characterized of these is the type III secretion system (T3SS), a molecular apparatus that specializes in injecting type III effector (T3Es) proteins directly into host cells. The work in this thesis focuses on T3Es of plant-associated bacteria, with particular emphasis on mutualistic bacteria. We present evidence that collections of T3Es from Sinorhizobium fredii and Bradyrhizobium japonicum are, in stark contrast to those of phytopathogenic bacteria, in a co-evolutionary equilibrium with their hosts. This equilibrium is characterized by highly conserved T3E collections consisting of many "core" T3Es with little variation in nucleotide sequence. The T3Es of Mesorhizobium loti MAFF303099 suggest a completely different picture of the evolution of T3Es. MAFF303099 recently acquired its T3SS locus, and the work in this thesis provides an evolutionary snapshot of a mutualist that is innovating a T3E collection primarily through horizontal gene transfer. Collectively, this work represents the first comprehensive catalog of T3Es of rhizobia and, in the case of Sinorhizobium and Bradyrhizobium, the first evidence of purifying selection for T3Es. / Graduation date: 2012

Type III effector proteins

T3E proteins

Host-microbe relationships

Type III secretion system

T3SS

Plant-associated bacteria

Mutualistic bacteria

Rhizobia

Nitrifying bacteria

Mutualism (Biology)

Host-bacteria relationships

Plant growth-promoting rhizobacteria

Bacterial proteins

Modelling the Dynamics of Mass Capture

Lahey, Timothy John

January 2013

This thesis presents an approach to modelling dynamic mass capture which is applied to a number of system models. The models range from a simple 2D Euler-Bernoulli beam with point masses for the end-effector and target to a 3D Timoshenko beam model (including torsion) with rigid bodies for the end-effector and target. In addition, new models for torsion, as well as software to derive the finite element equations from first principles were developed to support the modelling. Results of the models are compared to a simple experiment as done by Ben Rhody. Investigations of offset capture are done by simulation to show why one would consider using a 3D model that includes torsion. These problems have relevance to both terrestrial robots and to space based robotic systems such as the manipulators on the International Space Station capturing payloads such as the SpaceX Dragon capsule. One could increase production in an industrial environment if industrial robots could pick up items without having to establish a zero relative velocity between the end effector and the item. To have a robot acquire its payload in this way would introduce system dynamics that could lead to the necessity of modelling a previously ‘rigid’ robot as flexible.

Mass Capture

End-effector

Torsion

Structural Dynamics

Payload

Symbolic

Finite Element Analysis

Finite Element Method

FEA

FEM

Reissner

Warping

Timoshenko Beam

Euler-Bernoulli Beam

Vibration

Damping

Jourdain

Variational

Offset Capture

System Design Engineering

Untersuchungen zum putativen Effektorprotein CPn0809 des Typ-III-Sekretionssystems von <i>Chlamydophila pneumoniae</i> / Studies on the putative effector protein CPn0809 of the type III secretion system of <i>Chlamydophila pneumoniae</i>

Kuhns, Martin

27 April 2006

No description available.

610 Medizin, Gesundheit

Medicine

Chlamydophila pneumoniae

Typ-III-Sekretion

Effektor

Pathogen-Wirt-Interaktion

Chlamydophila pneumoniae

Type III Secretion

Effector

Pathogen-Host-Interaction

44.43

Kristallstrukturuntersuchungen zum Katalyse- und Regulationsmechanismus der Tyrosin-regulierten 3-Deoxy-D-arabino-Heptulosonat-7-Phosphat-Synthase aus Saccharomyces cerevisiae / Crystal structure analysis on the tyrosine-regulated 3-Deoxy-D-arabino-heptulosonate-7-phosphate synthase from Saccharomyces cerevisiae

König, Verena

31 October 2002

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Röntgenstrukturanalyse

Enzym-Substrat-Komplexe

Effektor

negative Rückkopplung

Metalloenzym

TIM-Barrel

X-ray crystal structure analysis

enzyme-substrate-complexes

effector

negative feedback regulation

metalloenzymes

TIM barrel

35.25

35.70

SP 000: Strukturchemie