Defective Retroviral Endogenous RNA Is Efficiently Transmitted by Infectious Particles Produced on an Avian Retroviral Vector Packaging Cell Line

AbstractThis report describes the contamination of "helper-free" stocks of defective retroviral vector with particles bearing retroviral endogenous RNA. An avian leukosis virus-based packaging cell line was developed from LMH cells that bear the ev1, ev3, and ev6 retroviral endogenous loci. The results show that an endogenous retroviral transcript (ev3) was packaged into virions produced by this packaging cell line and was efficiently transferred along with the vector to target cells. The titer of the ev contaminant particles was estimated at 50 - 100 CA-p27gag-expressing units/ml of supernatant

Special Issue “Viral and Host Factors Driving the Emergence and the Evolution of the SARS-CoV-2 and Other Coronaviruses”

Two and half years ago, humanity was facing the emergence of the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), the causal agent of the COVID-19 pandemics that significantly impact public health, society and the global economy [...

La leucose aviaire

National audienc

Quantification of HIV-based lentiviral vectors: influence of several cell type parameters on vector infectivity

International audienceA human immunodeficiency virus type (HIV-1)-based lentiviral vector pseudotyped with the vesicular stomatitis virus envelope glycoprotein and encoding the GFP reporter gene was used to evaluate different methods of lentiviral vector titration. GFP expression, viral DNA quantification and the efficiency of vector DNA integration were assayed after infection of conventional HIV-1-permissive cell lines and human primary adult fibroblasts with the vector. We found that vector titers based on GFP expression determined by flow cytometry may vary by more than 50-fold depending on the cell type and the promoter-cell combination used. Interestingly, we observed that the viral integration process in primary HDFa cells was significantly more efficient compared to that in SupT1 or 293T cells. We propose that determination of the amount of integrated viral DNA by quantitative PCR be used in combination with the reporter gene expression assay

Etude structure-fonction de l’intégrase des rétrovirus de la famille des ALSV (Avian Leukemia and Sarcoma Viruses)

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Mutations in the C-terminal domain of ALSV (Avian Leukemia and Sarcoma Viruses) integrase alter the concerted DNA integration process in vitro

International audienceIntegrase (IN) is the retroviral enzyme responsible for the integration of the DNA copy of the retroviral genome into the host cell DNA. The C-terminal domain of IN is involved in DNA binding and enzyme multimerization. We previously performed single amino acid substitutions in the C-terminal domain of the avian leukemia and sarcoma viruses (ALSV) IN [Moreau et al. (2002). Arch. Virol.147, 1761-1778]. Here, we modelled these IN mutants and analysed their ability to mediate concerted DNA integration (in an in vitro assay) as well as to form dimers (by size exclusion chromatography and protein-protein cross-linking). Mutations of residues located at the dimer interface (V239, L240, Y246, V257 and K266) have the greatest effects on the activity of the IN. Among them: (a) the L240A mutation resulted in a decrease of integration efficiency that was concomitant with a decrease of IN dimerization; (b) the V239A, V249A and K266A mutants preferentially mediated non-concerted DNA integration rather than concerted DNA integration although they were found as dimers. Other mutations (V260E and Y246W/DeltaC25) highlight the role of the C-terminal domain in the general folding of the enzyme and, hence, on its activity. This study points to the important role of residues at the IN C-terminal domain in the folding and dimerization of the enzyme as well as in the concerted DNA integration of viral DNA ends

Mutational analyses of the core domain of Avian Leukemia and Sarcoma Viruses integrase : critical residues for concerted integration and multimerization

Referred to by: Erratum to "Mutational analyses of the core domain of Avian Leukemia and Sarcoma Viruses integrase: critical residues for concerted integration and multimerization" [Virology 318 (2004) 566–581] Virology, Volume 328, Issue 1, 15 October 2004, Pages 159-159, Karen Moreau, Claudine Faure, Sébastien Violot, Patrice Gouet, Gérard Verdier, Corinne RonfortInternational audienceDuring replicative cycle of retroviruses, the reverse-transcribed viral DNA is integrated into the cell DNA by the viral integrase (IN) enzyme. The central core domain of IN contains the catalytic site of the enzyme and is involved in binding viral ends and cell DNA as well as dimerization. We previously performed single amino acid substitutions in the core domain of an Avian Leukemia and Sarcoma Virus (ALSV) IN [Arch. Virol. 147 (2002) 176 1]. Here, we modeled the resulting IN mutants and analyzed the ability of these mutants to mediate concerted DNA integration in an in vitro assay, and to form dimers by protein-protein cross-linking and size exclusion chromatography. The N197C mutation resulted in the inability of the mutant to perform concerted integration that was concomitant with a loss of IN dimerization. Surprisingly, mutations Q102G and A106V at the dimer interface resulted in mutants with higher efficiencies than the wild-type IN in performing two-ended concerted integration of viral DNA ends. The G139D and A195V mutants had a trend to perform one-ended DNA integration of viral ends instead of two-ended integration. More drastically, the 188L and L135G mutants preferentially mediated nonconcerted DNA integration although the proteins form dimers. Therefore, these mutations may alter the formation of IN complexes of higher molecular size than a dimer that would be required for concerted integration. This study points to the important role of core domain residues in the concerted integration of viral DNA ends as well as in the oligomerization of the enzyme

Etude structurale de mutants d’integrases rétrovirales

National audienc

In vitro functional analyses of the human immunodeficiency virus type 1 (HIV-1) integrase mutants give new insights into the intasome assembly

International audienceA functional study of mutants of the human immunodeficiency virus type 1 (HIV-1) integrase (IN) was conducted with the support of a recently proposed HIV-1 intasome model. Firstly, we investigated the predicted position of the C-terminal domain (CTD) and the flexibility of the alpha-6 helix by mutating the residue Ile-203. This had no impact on the 3 '-processing reaction but reduced the strand transfer reaction and the formation of tetramers. Secondly, the residues Ile-141 of the catalytic loop and Glu-246 of the CTD are predicted to bind the Td-3 base of the viral DNA maintaining it in a "flipped out" position and stabilizing the catalytic core domain (CCD)-CTD interface. Our data showed that the Ile-141/Td-3 interaction was important for the strand transfer activity and the oligomerization of IN. Interestingly, mutating the Glu-246 residue by an alanine enhanced half- and full-site integrations, suggesting that this residue may not be optimized for integration. (C) 2013 Elsevier Inc. All rights reserved

Characterization of two distinct RNA domains that regulate translation of the Drosophila gypsy retroelement

The genomic RNA of the gypsy retroelement from Drosophila melanogaster exhibits features similar to other retroviral RNAs because its 5′ untranslated (5′ UTR) region is unusually long (846 nucleotides) and potentially highly structured. Our initial aim was to search for an internal ribosome entry site (IRES) element in the 5′ UTR of the gypsy genomic RNA by using various monocistronic and bicistronic RNAs in the rabbit reticulocyte lysate (RRL) system and in cultured cells. Results reported here show that two functionally distinct and independent RNA domains control the production of gypsy encoded proteins. The first domain corresponds to the 5′ UTR of the env subgenomic RNA and exhibits features of an efficient IRES (IRES(E)) both in the reticulocyte lysate and in cells. The second RNA domain that encompasses the gypsy insulator can function as an IRES in the rabbit reticulocyte lysate but strongly represses translation in cultured cells. Taken together, these results suggest that expression of the gypsy encoded proteins from the genomic and subgenomic RNAs can be regulated at the level of translation