Synthesis of (−)-strand RNA from the 3′ untranslated region of plant viral genomes expressed in transgenic plants upon infection with related viruses

Teycheney, Pierre‐Yves; Aaziz, Rachid; Dinant, Sylvie; Salánki, Katalin; Tourneur, Colette; Balázs, Ervin; Jacquemond, Mireille; Tepfer, Mark

doi:10.1099/0022-1317-81-4-1121

Cited by 18 publications

(14 citation statements)

References 27 publications

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“…The 3¢ UTR is highly conserved among all of these full genome sequences (usually more so than even the CP coding region) suggesting that potent purifying selection may preserve secondary structures and/or sequence motifs involved in RdRp complex formation [34,35]. Unlike the 3¢ UTR, the 5¢ UTR was the most divergent genome region.…”

Section: Recombination Analysismentioning

confidence: 99%

Genome analysis of a severe and a mild isolate of Papaya ringspot virus-type W found in Brazil

et al. 2006

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Papaya ringspot virus-type W (PRSV-W) is one of the most economically threatening viruses of cucurbits in Brazil. Premunization is one of the most effective PRSV control measures currently applied in squash and zucchini crops. PRSV-W-1, a mild and premunizing strain of PRSV has been successfully used to protect cucurbits against both the severe PRSV-W-C strain and other Brazilian PRSVs. To aid in understanding the mechanism by which PRSV-W-1 premunization operates, the complete genome sequences of PRSV-W-1 and PRSV-W-C were determined. PRSV-W-1 had a genome size of 10,332 nucleotides, whereas indels within the coat protein encoding gene meant that the genome size of PRSV-W-C was six nucleotides shorter than that of the mild strain. The genomes of the two strains shared 94.63% nucleotide sequence identity, with the 5' UTR and P1 being the most variable regions, and the coat protein and 3' UTR being the most conserved. Rigorous recombination analysis revealed that neither PRSV-W-1 nor PRSV-W-C was obviously recombinant, there was significant evidence that many other fully sequenced PRSV genomes were recombinant.

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Section: Recombination Analysismentioning

confidence: 99%

Genome analysis of a severe and a mild isolate of Papaya ringspot virus-type W found in Brazil

et al. 2006

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“…It should be noted, however, that a cellular exclusion phenomenon limits the number of cells in which both subgroups are present (Takeshita et al ., ). By contrast, as the plants expressing the CP+3′UTR of R‐CMV (subgroup II) are fully susceptible to I17F‐CMV (subgroup I), the transgene mRNA and viral RNA will both be present in all infected cells (Jacquemond et al ., ). Template switching by the viral replicase between the transgene mRNA and the RNA of the non‐target viral genome occurs, creating messenger/viral RNA recombinants One of the first pieces of evidence that this could occur was the demonstration that, when transgene mRNA contains the CMV 3′UTR, the 3′UTR promoter can be recognized by the viral replicase to synthesize complementary RNA (Teycheney et al ., ). Several papers have demonstrated that recombination does indeed occur in transgenic plants expressing CMV CP genes on infection with a divergent strain of CMV (Turturo et al ., ; Morroni et al ., , ). The population of messenger/viral RNA recombinants includes variants not produced by the equivalent virus/virus recombination If recombination occurs in VRTPs, the recombinant viruses could lead to a novel disease only if they were different from those occurring in non‐transgenic plants.…”

Section: Evaluation Of Whether Recombination In Plants Expressing a Cmentioning

confidence: 97%

A critical evaluation of whether recombination in virus‐resistant transgenic plants will lead to the emergence of novel viral diseases

2015

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Summary In the evaluation of the potential impacts of first‐generation genetically modified (GM) crops, one of the most complex issues has been whether the expression of viral sequences would lead to the emergence of novel viruses, which could occur through recombination between transgene mRNA and that of an infecting non‐target virus. Here, we examine this issue, focusing on Cucumber mosaic virus (CMV), which is a particularly pertinent choice, as it is both a major plant pathogen and also the virus with which this question has been studied in the most detail. Using recent results on recombination in CMV, we employ a novel framework giving particular prominence to the formulation of the risk hypothesis and to hypothesis testing via examination of the potential pathway to harm. This allows us to conclude with greater certainty that the likelihood of this potential harm, the emergence of novel viruses, is low.

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“…In a recent study, Turturo et al (2008) were the first to succeed, using transgenic plants expressing the coat protein (CP) and the 39-non-coding region (39-NCR) of RNA3 of a subgroup II strain of cucumber mosaic virus (R-CMV). The 39-NCR can serve as an initiation site for the viral replicase (Teycheney et al, 2000), thus making it possible for full-length recombinant RNA3 that can potentially be replicated to be produced by a single crossover. Turturo et al (2008) showed clearly that the populations of recombinant viral RNAs were similar in the transgenic plant system when infected with a subgroup I CMV (I17F-CMV) and in the non-transgenic plants infected simultaneously with both CMV strains.…”

Section: Introductionmentioning

confidence: 99%

Analysis of recombination between viral RNAs and transgene mRNA under conditions of high selection pressure in favour of recombinants

Morroni

Thompson

Tepfer

2009

Journal of General Virology

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One possible environmental risk related to the utilization of virus-resistant transgenic plants expressing viral sequences is the emergence of new viruses generated by recombination between the viral transgene mRNA and the RNA of an infecting virus. This hypothesis has been tested recently for cucumber mosaic virus (CMV) by comparing the recombinant populations in transgenic and non-transgenic plants under conditions of minimal selection pressure in favour of the recombinants. Equivalent populations were observed in transgenic and non-transgenic plants but, in both, there was a strongly dominant hotspot recombinant which was shown recently to be nonviable alone in planta, suggesting that its predominance could be reduced by applying an increased selection pressure in favour of viable recombinants. Partially disabled I17F-CMV mutants were created by engineering 6 nt deletions in five sites in the RNA3 39-non-coding region (39-NCR). One mutant was used to inoculate transgenic tobacco plants expressing the coat protein and 39-NCR of R-CMV. A total of 22 different recombinant types were identified, of which 12 were, as expected, between the transgene mRNA and the mutated I17F-CMV RNA3, while 10 resulted from recombination between the mutated RNA3 and I17F-CMV RNA1. Twenty recombinants were of the aberrant type, while two, including the dominant one detected previously under conditions of minimal selection pressure, were homologous recombinants. All recombinants detected were very similar to ones observed in nature, suggesting that the deployment of transgenic lines similar to the one studied here would not lead to the emergence of new viruses.

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Synthesis of (−)-strand RNA from the 3′ untranslated region of plant viral genomes expressed in transgenic plants upon infection with related viruses

Cited by 18 publications

References 27 publications

Genome analysis of a severe and a mild isolate of Papaya ringspot virus-type W found in Brazil

Genome analysis of a severe and a mild isolate of Papaya ringspot virus-type W found in Brazil

A critical evaluation of whether recombination in virus‐resistant transgenic plants will lead to the emergence of novel viral diseases

Analysis of recombination between viral RNAs and transgene mRNA under conditions of high selection pressure in favour of recombinants

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