57 research outputs found

    Aux origines de Loft Story

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    Clonage et caractérisation de deux gènes codant des enzymes lipolytiques de la microalgue Isochrysis galbana

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    Lipolytic enzymes present in all known species play a key role in lipid metabolism and are involved in several industrial processes. They catalyse lipid hydrolysis and synthesis. Actually and particularly in microalgae, isolation and characterization of this type of enzyme remains an unexplored research area.The potential of the lipidic content of microalgae in food industry or energy field requires specific lipolytic enzymes. Docosahexaenoic acid (DHA), an 3 poly insaturated fatty acid (3 PUFA) is well known for its beneficial effects on human health. Among many species, Isochrysis galbana, a unicellular marine microalga belonging to the Prymnesiophyceae class, is considered as a potential alternative source of DHA.Lipid analysis of I. galbana shows free fatty acids and suggests the presence of lipolytic enzymes with potential interesting selectivities and substrate specificities. Analysis of incomplete expressed sequence tag (EST) listed in the EST bank of Isochrysis galbana, identified incomplete genes that encode lipolytic enzymes. Messenger RNAs were extracted, characterized and cloned.This work describes the analysis and cloning of two genes encoding a putative ester hydrolase and a putative thioesterase in marine microalgae Isochrysis galbana. Sequences encode two proteins with predicted molecular weights of approximately 35,41 kDa and 42,31 kDa. Slight similarity and identity (from 30 to 40 %) were observed between the gene sequence and various fold hydrolase found in diverse phyla (including carboxylesterase).Sequences also included the consensus Gly-X-Ser-X-Gly and the catalytic triad Ser/Asp/His. To characterize the predicted enzymatic functions, an experimental procedure was introduced: coding sequences were cloned into expression vectors and expressed in Saccharomyces cerevisiae and in Escherichia coli.Western blot identification of recombinant enzyme shows a convenient protein production in bacteria. Furthermore, the expression of the protein in E. coli shifted the fatty acid composition predominantly towards C16:1 and C18:1 fatty acids. The enzyme called IgTeCe showed a thioesterase activity.Les enzymes lipolytiques sont des ester hydrolases impliquées dans le métabolisme lipidique. Leurs caractéristiques se sont révélées être des atouts dans de nombreuses applications industrielles. Chez les microalgues, l’isolement et la caractérisation de ces enzymes d’un point de vue structural et fonctionnel restent des domaines de recherche peu explorés à ce jour.Certaines espèces bénéficient pourtant de contenus en lipides intéressants, source de matière première pour les industries de l’agroalimentaire ou de l’énergie. Par exemple, l’acide docosahexaénoique (DHA), un acide gras polyinsaturé de la série des omégas 3, est reconnu pour ses propriétés en santé humaine. Parmi de nombreuses espèces, Isochrysis galbana, une microalgue unicellulaire appartenant à la classe des Prymnesiophycées est considérée comme une source possible de DHA. La présence d’acides gras libres a été montrée par l’analyse des lipides, suggérant la présence d’enzymes lipolytiques potentiellement intéressantes pour leur sélectivité et leur spécificité de substrat.L’analyse d’une banque de marqueurs de séquences exprimées a permis l’identification de séquences susceptibles de coder des enzymes lipolytiques. Les ARN messagers ont été extraits et les ADN complémentaires ont été clonés.Ce travail de thèse présente l’analyse et le clonage de deux gènes codant une ester hydrolase putative et une thioestérase putative, issues de la microalgue Isochrysis galbana.Les deux séquences codent des protéines de poids moléculaires de 35,41 kDa et de 42,31 kDa. Elles montrent 30 à 40 % d’identité et de similarité avec des hydrolases notamment des carboxylestérasesde différents organismes. Les séquences protéiques ont permis l’identification du pentapeptide consensus Gly-X-Ser-X-Gly caractéristique des enzymes lipolytiques et les acides aminés Ser/Asp/His de la triade catalytique.Les deux séquences codantes ont été clonées et exprimées dans la levure Saccharomyces cerevisiae et la bactérie Escherichia coli. Le clonage dans E. coli a permis d’identifier à la taille attendue une protéine par Western blot. En présence de cette protéine, la composition en acides gras des lipides de la bactérie a été modifiée. L’analyse CPG a notamment montré une augmentation des proportions en acides gras C16 :1 et C18 :1 par rapport au témoin. Ce résultat permet de caractériser l’activité thioestérase pour IgTeCe

    Differential Localization of Structural and Non-Structural Proteins during the Bluetongue Virus Replication Cycle.

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    Members of the Reoviridae family assemble virus factories within the cytoplasm of infected cells to replicate and assemble virus particles. Bluetongue virus (BTV) forms virus inclusion bodies (VIBs) that are aggregates of viral RNA, certain viral proteins, and host factors, and have been shown to be sites of the initial assembly of transcriptionally active virus-like particles. This study sought to characterize the formation, composition, and ultrastructure of VIBs, particularly in relation to virus replication. In this study we have utilized various microscopic techniques, including structured illumination microscopy, and virological assays to show for the first time that the outer capsid protein VP5, which is essential for virus maturation, is also associated with VIBs. The addition of VP5 to assembled virus cores exiting VIBs is required to arrest transcriptionally active core particles, facilitating virus maturation. Furthermore, we observed a time-dependent association of the glycosylated non-structural protein 3 (NS3) with VIBs, and report on the importance of the two polybasic motifs within NS3 that facilitate virus trafficking and egress from infected cells at the plasma membrane. Thus, the presence of VP5 and the dynamic nature of NS3 association with VIBs that we report here provide novel insight into these previously less well-characterized processes

    A Calcium Sensor Discovered in Bluetongue Virus Nonstructural Protein 2 Is Critical for Virus Replication.

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    Many viruses use specific viral proteins to bind calcium ions (Ca2+) for stability or to modify host cell pathways; however, to date, no Ca2+ binding protein has been reported in bluetongue virus (BTV), the causative agent of bluetongue disease in livestock. Here, using a comprehensive bioinformatics screening, we identified a putative EF-hand-like Ca2+ binding motif in the carboxyl terminal region of BTV nonstructural phosphoprotein 2 (NS2). Subsequently, using a recombinant NS2, we demonstrated that NS2 binds Ca2+ efficiently and that Ca2+ binding was perturbed when the Asp and Glu residues in the motif were substituted by alanine. Using circular dichroism analysis, we found that Ca2+ binding by NS2 triggered a helix-to-coil secondary structure transition. Further, cryo-electron microscopy in the presence of Ca2+ revealed that NS2 forms helical oligomers which, when aligned with the N-terminal domain crystal structure, suggest an N-terminal domain that wraps around the C-terminal domain in the oligomer. Further, an in vitro kinase assay demonstrated that Ca2+ enhanced the phosphorylation of NS2 significantly. Importantly, mutations introduced at the Ca2+ binding site in the viral genome by reverse genetics failed to allow recovery of viable virus, and the NS2 phosphorylation level and assembly of viral inclusion bodies (VIBs) were reduced. Together, our data suggest that NS2 is a dedicated Ca2+ binding protein and that calcium sensing acts as a trigger for VIB assembly, which in turn facilitates virus replication and assembly.IMPORTANCE After entering the host cells, viruses use cellular host factors to ensure a successful virus replication process. For replication in infected cells, members of the Reoviridae family form inclusion body-like structures known as viral inclusion bodies (VIB) or viral factories. Bluetongue virus (BTV) forms VIBs in infected cells through nonstructural protein 2 (NS2), a phosphoprotein. An important regulatory factor critical for VIB formation is phosphorylation of NS2. In our study, we discovered a characteristic calcium-binding EF-hand-like motif in NS2 and found that the calcium binding preferentially affects phosphorylation level of the NS2 and has a role in regulating VIB assembly

    Protective efficacy of multivalent replication-abortive vaccine strains in horses against African horse sickness virus challenge.

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    African horse sickness virus (AHSV) is an orbivirus, a member of the Reoviridae family. Nine different serotypes have been described so far. AHSV is vectored by Culicoides spp. to equids, causing high mortality, particularly in horses, with considerable economic impacts. For development of a safe attenuated vaccine, we previously established an efficient reverse genetics (RG) system to generate Entry Competent Replication-Abortive (ECRA) virus strains, for all nine serotypes and demonstrated the vaccine potential of these strains in type I interferon receptor (IFNAR)-knockout mice. Here, we evaluated the protective efficacies of these ECRA viruses in AHSV natural hosts. One monoserotype (ECRA.A4) vaccine and one multivalent cocktail (ECRA.A1/4/6/8) vaccine were tested in ponies and subsequently challenged with a virulent AHSV4. In contrast to control animals, all vaccinated ponies were protected and did not develop severe clinical symptoms of AHS. Furthermore, the multivalent cocktail vaccinated ponies produced neutralizing antibodies against all serotypes present in the cocktail, and a foal born during the trial was healthy and had no viremia. These results validate the suitability of these ECRA strains as a new generation of vaccines for AHSV

    Mapping the pH Sensors Critical for Host Cell Entry by a Complex Nonenveloped Virus.

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    Bluetongue virus (BTV), in the family Reoviridae, is an insect-borne, double-capsid virus causing hemorrhagic disease in livestock around the world. Here, we elucidate how outer capsid proteins VP2 and VP5 coordinate cell entry of BTV. To identify key functional residues, we used atomic-level structural data to guide mutagenesis of VP2 and VP5 and a series of biological and biochemical approaches, including site-directed mutagenesis, reverse genetics-based virus recovery, expression and characterization of individual recombinant mutant proteins, and various in vitro and in vivo assays. We demonstrate the dynamic nature of the conformational change process, revealing that a unique zinc finger (CCCH) in VP2 acts as the major low pH sensor, coordinating VP2 detachment, subsequently allowing VP5 to sense low pH via specific histidine residues at key positions. We show that single substitution of only certain histidine residues has a lethal effect, indicating that the location of histidine in VP5 is critical to inducing changes in VP5 conformation that facilitates membrane penetration. Further, we show that the VP5 anchoring domain alone recapitulates sensing of low pH. Our data reveal a novel, multiconformational process that overcomes entry barriers faced by this multicapsid nonenveloped virus.IMPORTANCE Virus entry into a susceptible cell is the first step of infection and a significant point at which infection can be prevented. To enter effectively, viruses must sense the cellular environment and, when appropriate, initiate a series of changes that eventually jettison the protective shell and deposit virus genes into the cytoplasm. Many viruses sense pH, but how this happens and the events that follow are often poorly understood. Here, we address this question for a large multilayered bluetongue virus. We show key residues in outer capsid proteins, a pH-sensing histidine of a zinc finger within the receptor-binding VP2 protein, and certain histidine residues in the membrane-penetrating VP5 protein that detect cellular pH, leading to irreversible changes and propel the virus through the cell membrane. Our data reveal a novel mechanism of cell entry for a nonenveloped virus and highlight mechanisms which may also be used by other viruses

    Atomic structure of the translation regulatory protein NS1 of bluetongue virus

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    Bluetongue virus (BTV) non-structural protein 1 (NS1) regulates viral protein synthesis and exists as tubular and non-tubular forms in infected cells, but how tubules assemble and how protein synthesis is regulated are unknown. Here, we report near-atomic resolution structures of two NS1 tubular forms determined by cryo-electron microscopy. The two tubular forms are different helical assemblies of the same NS1 monomer, consisting of an amino-terminal foot, a head and body domains connected to an extended carboxy-terminal arm, which wraps atop the head domain of another NS1 subunit through hydrophobic interactions. Deletion of the C terminus prevents tubule formation but not viral replication, suggesting an active non-tubular form. Two zinc-finger-like motifs are present in each NS1 monomer, and tubules are disrupted by divalent cation chelation and restored by cation addition, including Zn2+, suggesting a regulatory role of divalent cations in tubule formation. In vitro luciferase assays show that the NS1 non-tubular form upregulates BTV mRNA translation, whereas zinc-finger disruption decreases viral mRNA translation, tubule formation and virus replication, confirming a functional role for the zinc-fingers. Thus, the non-tubular form of NS1 is sufficient for viral protein synthesis and infectious virus replication, and the regulatory mechanism involved operates through divalent cation-dependent conversion between the non-tubular and tubular forms

    The Interaction of Bluetongue Virus VP6 and Genomic RNA Is Essential for Genome Packaging.

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    The genomes of the Reoviridae, including the animal pathogen bluetongue virus (BTV), are multisegmented double-stranded RNA (dsRNA). During replication, single-stranded (ss) positive-sense RNA segments are packaged into the assembling virus capsid, triggering genomic dsRNA synthesis. However, exactly how this packaging event occurs is not clear. A minor capsid protein, VP6, unique for the orbiviruses, has been proposed to be involved in the RNA-packaging process. In this study, we sought to characterize the RNA binding activity of VP6 and its functional relevance. A novel proteomic approach was utilized to map the ssRNA/dsRNA binding sites of a purified recombinant protein and the genomic dsRNA binding sites of the capsid-associated VP6. The data revealed that each VP6 protein has multiple distinct RNA-binding regions and that only one region is shared between recombinant and capsid-associated VP6. A combination of targeted mutagenesis and reverse genetics identified the RNA-binding region that is essential for virus replication. Using an in vitro RNA-binding competition assay, a unique cell-free assembly assay, and an in vivo single-cycle replication assay, it was possible to identify a motif within the shared binding region that binds BTV ssRNA preferentially in a manner consistent with specific RNA recruitment during capsid assembly. These data highlight the critical roles that this unique protein plays in orbivirus genome packaging and replication.IMPORTANCE Genome packaging is a critical stage during virus replication. For viruses with segmented genomes, the genome segments need to be correctly packaged into a newly formed capsid. However, the detailed mechanism of this packaging is unclear. Here we focus on VP6, a minor viral protein of bluetongue virus, which is critical for genome packaging. We used multiple approaches, including a robust RNA-protein fingerprinting assay, to map the ssRNA binding sites of recombinant VP6 and the genomic dsRNA binding sites of capsid-associated VP6. By these means, together with virological and biochemical methods, we identify the viral RNA-packaging motif of a segmented dsRNA virus for the first time

    Entry-competent-replication-abortive African horse sickness virus strains elicit robust immunity in ponies against all serotypes

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    African horse sickness virus (AHSV) is an Orbivirus within the Reoviridae family, spread by Culicoides species of midges, which infects equids with high mortality, particularly in horses and has a considerable impact on the equine industry. In order to control the disease, we previously described Entry Competent Replication Abortive (ECRA) virus strains for each of the nine distinct AHSV serotypes and demonstrated their potential as vaccines, first in type I interferon receptor (IFNAR-/-) knockout mice, and then in ponies. In this report we have investigated whether or not a combination ECRA vaccine comprising nine vaccine strains as two different cocktails is as efficient in ponies and the duration of the immunity triggered by ECRA vaccines. In one study, a group of ponies were vaccinated with a cocktail of 4 vaccine strains, followed by a vaccination of the remaining 5 vaccine strains, mimicking the current live attenuated vaccine regimen. In the second study, ponies were vaccinated with a single ECRA-AHSV strain and monitored for 6 months. The first group of ponies developed neutralising antibody responses against all 9 serotypes, indicating that no cross-serotype interference occurred, while the second group developed robust neutralising antibody responses against the single serotype that were sustained at the same level throughout a 6-month study. The results support our previous data and further validate ECRA vaccines as a safe and efficacious replacement of current live vaccines
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