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Diversidade molecular dos genes codificadores das proteínas não-estruturais Nsp2 e protease Papaína-like e da proteína estrutural S1 de amostras brasileiras do Coronavírus aviário / Molecular diversity of Nsp2 and Papain-like protease and S1 structural protein coding genes in Brazilian isolates of Avian coronavirusRossa, Giselle Ayres Razera 14 November 2014 (has links)
Coronavírus, incluindo-se o Coronavírus aviário (ACoV), possuem o maior genoma composto por RNA conhecido entre os vírus. Aproximadamente dois terços desse genoma codificam proteínas não estruturais (Nsps), cujas funções parecem estar associadas à replicação e patogênese viral. Até o momento, esses alvos têm sido pouco explorados quanto a sua diversidade em diferentes linhagens de ACoV. O presente estudo teve como objetivo investigar a diversidade dos genes codificadores das proteínas não estruturais Nsp2 e protease Papaína-like (Plpro), utilizando-se linhagens brasileiras de ACoV. Para tanto, 10 linhagens de ACoV, isoladas em ovos embrionados, foram submetidas à RT-PCR direcionada aos genes codificadores de Plpro e Nsp2, seguindo-se o sequenciamento de DNA e a análise filogenética, juntamente com sequências homólogas obtidas no GenBank. Além disso, realizou-se a genotipagem por meio do sequenciamento parcial do gene codificador da proteína de espícula (região S1). Três das amostras virais obtidas e investigadas no presente trabalho apresentaram padrão de segregação discordante para os genes estudados. O isolado CRG I22 agrupou-se com linhagens virais pertencentes ao genótipo Massachusetts para S1 e com o grupamento de ACoVs brasileiros os genes da Nsp2 e Plpro. O isolado CRG I33 agrupou-se com linhagens virais pertencentes ao genótipo brasileiro para s1 e plpro e de maneira divergente para o gene da Nsp2. Para o isolado CRG I38, não foi obtida a genotipagem por s1, entretanto, similarmente ao observado para o isolado CRG I33, esse isolado agrupo-se com linhagens virais brasileiras para o gene plro e de maneira independente para o gene nsp2. As demais linhagens estudadas resultaram na formação de um grupamento especificamente brasileiro de ACoV, para os três genes estudados. Esses achados sugerem a ocorrência de recombinação nessas amostras discrepantes. Quanto às identidades médias entre as sequencias nucleotídicas analisadas, a região de s1 analisada apresentou as menores identidades (73,75% ±16,78), seguido pelo gene plpro (88,06% ±5,7) e do gene nsp2 (92,28% ±4,37), em acordo com a literatura. Assim sendo, os alvos investigados podem constituir ferramentas úteis na epidemiologia molecular do ACoV e na investigação de linhagens recombinantes do vírus. O presente estudo é o primeiro a investigar a diversidade genética de genes codificadores de proteínas não-estruturais em linhagens brasileiras de ACoV. Os resultados aqui apresentados reforçam a existência de um genótipo brasileiro de ACoV, para os 3 genes estudados. Entretanto, discrepâncias pontuais encontradas no padrão genotípico para s1, nsp2 e nsp3 permitem inferir uma diversidade genética maior do que a conhecida até o momento, possivelmente resultante de eventos de recombinação entre ACoVs brasileiros, ACoVs vacinais e outros ainda desconhecidos. Os resultados obtidos auxiliam na compreensão dos padrões e evolução dos ACoVs / Coronaviruses, including Avian coronavirus (ACoV), have the largest known RNA genome. Nearly two thirds of its genome codes for non-structural proteins (Nsps), whose functions appear to be linked to viral replication and pathogenesis. Hitherto these targets have been poorly explored regarding the ACoV lineages diversity. The present study aimed to assess the diversity of non-structural protein 2 (nsp2), papain-like protease (plpro) and spike protein (S1 subunit) coding genes, in Brazilian ACoV strains. To this end, 10 ACoV strains, isolated in embryonated eggs, had its 3rd and 5th passages submitted to RT-PCR targeting nsp2, plpro and s1, followed by DNA sequencing and phylogenetic analysis, herewith homologous sequences obtained from GenBank. Three of the ACoV strains sequenced showed a discordant segregation pattern for target genes. CRG I22 strain clustered with Massachusetts genotipe strains for S1, and with Brazilian cluster for nsp3 and plpro genes. CRG I33 strain, clustered with Brazilian strains for S1 and plpro genes, and was divergent for nsp2 gene. For CRG I38 strain, the S1 sequence was not obtained, however, similarly to what was observed for CRG I33, this strain grouped with the Brazilian lineage for plpro gene and was divergent for nsp2 gene. All the other ACoV here sequenced resulted in a specific Brazilian cluster for the three studied genes. Regarding the mean nucleotide identities measured, s1 gene showed the lowest identity (73.75% ±16.78), followed by plpro gene (88.06% ±5.7) and nsp2 gene (92.28% ±4.37), in accordance with previous reported data. Therefore, the targets of the present study are useful tools for ACoV molecular epidemiology studies and for the survey of recombinant ACoV strains. The presented study is the first one investigating the molecular diversity of non-structural proteins coding genes in Brazilian strains of ACoV. Results achieved herein reinforce the data over the circulation of ACoV Brazilian strains in this country, for the three investigated genes. However, divergences found between S1, nsp2 and plpro genetic patters allow inferring a higher molecular diversity than previously known. It is possible that this divergence is due to recombination events between ACoV from vaccines, Brazilian field strains and others still unknown. These results contribute on the comprehension over genetic patters and evolution of ACoV
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Diversidade molecular dos genes codificadores das proteínas não-estruturais Nsp2 e protease Papaína-like e da proteína estrutural S1 de amostras brasileiras do Coronavírus aviário / Molecular diversity of Nsp2 and Papain-like protease and S1 structural protein coding genes in Brazilian isolates of Avian coronavirusGiselle Ayres Razera Rossa 14 November 2014 (has links)
Coronavírus, incluindo-se o Coronavírus aviário (ACoV), possuem o maior genoma composto por RNA conhecido entre os vírus. Aproximadamente dois terços desse genoma codificam proteínas não estruturais (Nsps), cujas funções parecem estar associadas à replicação e patogênese viral. Até o momento, esses alvos têm sido pouco explorados quanto a sua diversidade em diferentes linhagens de ACoV. O presente estudo teve como objetivo investigar a diversidade dos genes codificadores das proteínas não estruturais Nsp2 e protease Papaína-like (Plpro), utilizando-se linhagens brasileiras de ACoV. Para tanto, 10 linhagens de ACoV, isoladas em ovos embrionados, foram submetidas à RT-PCR direcionada aos genes codificadores de Plpro e Nsp2, seguindo-se o sequenciamento de DNA e a análise filogenética, juntamente com sequências homólogas obtidas no GenBank. Além disso, realizou-se a genotipagem por meio do sequenciamento parcial do gene codificador da proteína de espícula (região S1). Três das amostras virais obtidas e investigadas no presente trabalho apresentaram padrão de segregação discordante para os genes estudados. O isolado CRG I22 agrupou-se com linhagens virais pertencentes ao genótipo Massachusetts para S1 e com o grupamento de ACoVs brasileiros os genes da Nsp2 e Plpro. O isolado CRG I33 agrupou-se com linhagens virais pertencentes ao genótipo brasileiro para s1 e plpro e de maneira divergente para o gene da Nsp2. Para o isolado CRG I38, não foi obtida a genotipagem por s1, entretanto, similarmente ao observado para o isolado CRG I33, esse isolado agrupo-se com linhagens virais brasileiras para o gene plro e de maneira independente para o gene nsp2. As demais linhagens estudadas resultaram na formação de um grupamento especificamente brasileiro de ACoV, para os três genes estudados. Esses achados sugerem a ocorrência de recombinação nessas amostras discrepantes. Quanto às identidades médias entre as sequencias nucleotídicas analisadas, a região de s1 analisada apresentou as menores identidades (73,75% ±16,78), seguido pelo gene plpro (88,06% ±5,7) e do gene nsp2 (92,28% ±4,37), em acordo com a literatura. Assim sendo, os alvos investigados podem constituir ferramentas úteis na epidemiologia molecular do ACoV e na investigação de linhagens recombinantes do vírus. O presente estudo é o primeiro a investigar a diversidade genética de genes codificadores de proteínas não-estruturais em linhagens brasileiras de ACoV. Os resultados aqui apresentados reforçam a existência de um genótipo brasileiro de ACoV, para os 3 genes estudados. Entretanto, discrepâncias pontuais encontradas no padrão genotípico para s1, nsp2 e nsp3 permitem inferir uma diversidade genética maior do que a conhecida até o momento, possivelmente resultante de eventos de recombinação entre ACoVs brasileiros, ACoVs vacinais e outros ainda desconhecidos. Os resultados obtidos auxiliam na compreensão dos padrões e evolução dos ACoVs / Coronaviruses, including Avian coronavirus (ACoV), have the largest known RNA genome. Nearly two thirds of its genome codes for non-structural proteins (Nsps), whose functions appear to be linked to viral replication and pathogenesis. Hitherto these targets have been poorly explored regarding the ACoV lineages diversity. The present study aimed to assess the diversity of non-structural protein 2 (nsp2), papain-like protease (plpro) and spike protein (S1 subunit) coding genes, in Brazilian ACoV strains. To this end, 10 ACoV strains, isolated in embryonated eggs, had its 3rd and 5th passages submitted to RT-PCR targeting nsp2, plpro and s1, followed by DNA sequencing and phylogenetic analysis, herewith homologous sequences obtained from GenBank. Three of the ACoV strains sequenced showed a discordant segregation pattern for target genes. CRG I22 strain clustered with Massachusetts genotipe strains for S1, and with Brazilian cluster for nsp3 and plpro genes. CRG I33 strain, clustered with Brazilian strains for S1 and plpro genes, and was divergent for nsp2 gene. For CRG I38 strain, the S1 sequence was not obtained, however, similarly to what was observed for CRG I33, this strain grouped with the Brazilian lineage for plpro gene and was divergent for nsp2 gene. All the other ACoV here sequenced resulted in a specific Brazilian cluster for the three studied genes. Regarding the mean nucleotide identities measured, s1 gene showed the lowest identity (73.75% ±16.78), followed by plpro gene (88.06% ±5.7) and nsp2 gene (92.28% ±4.37), in accordance with previous reported data. Therefore, the targets of the present study are useful tools for ACoV molecular epidemiology studies and for the survey of recombinant ACoV strains. The presented study is the first one investigating the molecular diversity of non-structural proteins coding genes in Brazilian strains of ACoV. Results achieved herein reinforce the data over the circulation of ACoV Brazilian strains in this country, for the three investigated genes. However, divergences found between S1, nsp2 and plpro genetic patters allow inferring a higher molecular diversity than previously known. It is possible that this divergence is due to recombination events between ACoV from vaccines, Brazilian field strains and others still unknown. These results contribute on the comprehension over genetic patters and evolution of ACoV
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Spatiotemporal regulation of the arbuscular mycorrhiza symbiosis establishment / Régulation spatiotemporelle de l'établissement de la symbiose mycorhizienne à arbusculeGuillotin, Bruno 30 September 2016 (has links)
La symbiose mycorhizienne à arbuscule est une interaction bénéfique entre les champignons du phylum Glomeromycota et près de 80% des espèces de plantes terrestres. Elle est caractérisée par un échange réciproque de nutriments dans lequel le champignon fournit des sels minéraux à la plante en échange de sucres issus de la photosynthèse. Cependant, cette "alimentation" du champignon au cours de la symbiose représente un coût carbone important pour la plante. Ainsi, les plantes doivent strictement maitriser le développement des champignons symbiotiques dans les racines. Ce contrôle est appelé autorégulation. Plusieurs protéines ont été démontrées comme étant importantes pour la régulation des différentes étapes de la colonisation : la stimulation de la croissance fongique dans la rhizosphère par les strigolactones, l'entrée dans les racines, la prolifération des hyphes au sein des racines et la formation des arbuscules. Dans ce travail, nous avons examiné plus en détail le rôle de deux de ces protéines connues pour être impliquées dans le processus de mycorhization, les facteurs de transcription NSP1 et NSP2 (Nodulation Signaling Pathway). Nous avons d'abord pu confirmer dans les racines de M. truncatula en conditions non-symbiotiques, l'implication directe de NSP1 dans la régulation de deux gènes de biosynthèse des strigolactones, DWARF27 (D27) et MORE AXILLARY GROWTH (MAX1). Ensuite, nous avons montré que NSP1, contrairement à NSP2, favorise l'entrée du champignon dans la racine, sans doute due à l'induction de la synthèse des strigolactones stimulant le champignon, via l'activation de D27 et de MAX1. Ensuite, au cours des étapes ultérieures de la mycorhization, nous avons montré que dans les tissus colonisés, NSP1 est absent et que l'induction de D27 et de MAX1 n'était plus NSP1 dépendante. À cette étape, l'expression de la protéine NSP1 est localisée dans les cellules justes en amont du front de colonisation fongique. Là, elle contrôle négativement la propagation des hyphes dans la racine et positivement la formation des arbuscules. En revanche, NSP2 est présente dans le tissu colonisé où elle favorise la propagation des hyphes et le développement des arbuscules, peut-être en interaction avec d'autres facteurs. Nous avons également montré chez M. truncatula que si les protéines NSP1 sont absentes des tissus colonisés, les transcrits de NSP1 sont présents. De façon inattendue, nous avons mis en évidence que l'ARN messager de NSP1 avait la capacité de protéger l'ARN messager de NSP2 contre sa dégradation par le microARN (miR171h), par une action de piégeage du miR171h, appelé effet mimicry. Ceci est la première démonstration qu'une molécule d'ARN codante peut être la cible mimétique d'un microARN. Dans notre contexte d'étude cette constatation révèle que les transcrits de NSP1 permettent une régulation positive de l'expression de NSP2, et met en lumière un niveau de complexité supplémentaire dans le rôle de ces deux facteurs de transcription dans la symbiose mycorhizienne. Enfin, dans la tomate, nous avons montré que Sl-NSP1 pourrait être directement ou indirectement régulée par une protéine AUX / IAA impliquée dans la réponse précoce à l'auxine, Sl-IAA27. Ce lien avec l'auxine nous fait présumer que cette AUX/AAI est un nouveau composant de la voie de signalisation du contrôle de la colonisation fongique dans la tomate, et nous proposons qu'il puisse avoir un rôle dans le contrôle de la biosynthèse des strigolactones via la régulation de Sl-NSP1. L'ensemble de ce travail fournit de nouvelles pièces du puzzle constituant la symbiose mycorhizienne et montre l'importance de l'analyse des régulations spatiotemporelles pour une meilleure compréhension de ces processus biologiques extrêmement complexes. / The arbuscular mycorrhiza (AM), a symbiosis between fungi from the phylum Glomeromycota and nearly 80% of terrestrial plant species. It is characterized by a two-way exchange in which the fungus provides mineral nutrients to the plant in exchange for carbohydrates. However this "feeding" of the fungus during the symbiotic process represents a significant carbon cost for the plant. To maintain a mutualistic interaction the two symbiotic partners have to strictly control the extent of fungal development in the roots. This control is called autoregulation. Several proteins have been found to be important for the regulation of the different mycorrhizal steps: the stimulation of fungal growth in the rhizosphere by the strigolactones, the fungal entrance in the roots, the hyphal proliferation in the roots and the arbuscule formation. In this work we examine in more detail the role of two of these proteins known to be involved in the mycorrhization process, the transcriptional factors NSP1 and NSP2 (Nodulation Signaling Pathway). We first confirm in M. truncatula roots the direct implication of NSP1 in the regulation of two strigolactone biosynthesis genes, DWARF27 (D27) and MAX1, during the asymbiotic conditions. Then, we show that NSP1, unlike NSP2, is a factor that promotes the fungal entries in the root, presumably due to its activation of D27 and MAX1 resulting in a stimulation of strigolactone synthesis and presymbiotic fungal growth. Next, during the later stages of mycorrhization, we highlight that in the colonized tissues NSP1 is absent and the induction of both D27 and MAX1 is not anymore NSP1 dependent. NSP1 protein is then localized in cells which are not yet colonized but are close to a colonization zone. There, it controls negatively the hyphal propagation in the root and positively the formation of arbuscules. In contrast, NSP2 is present in the colonized tissue where it promotes hyphal propagation and arbuscule development, perhaps by interacting with other proteins. We also show that if NSP1 proteins are absent of the colonized tissues, NSP1 transcripts are present. Unexpectedly, we unveil that in those colonized cells, NSP1 mRNA can protect, by a micro RNA (miR171h) decoy action called target mimicry, NSP2 mRNA against miR171h-mediated degradation. This is the first demonstration that a coding RNA molecule can be a target mimic for a microRNA. In our context this finding reveals a positive regulation of NSP2 expression by NSP1 transcripts and brings to light an additional layer of complexity in the mycorrhizal dual role of these two transcription factors. Finally, in tomato, we highlight that SlNSP1 could be directly or indirectly regulated by the AUX/IAA protein, SlIAA27. As a link with auxin we presume that this AUX/IAA protein is a new component of the signaling pathway controlling AM fungal colonization in tomato, and we propose that it controls strigolactone biosynthesis via the regulation of SlNSP1. Overall our work provides new pieces of the mycorrhizal puzzle and shows how important it is to perform spatiotemporal investigations for a better understanding of highly integrated and complex biological processes.
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Alphavirus nsP2 interacts with Host Pathways for Viral Minus-Strand Synthesis and Replication Complex StabilityMai, Junbo January 2009 (has links)
No description available.
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