The Eukaryotic Translation Initiation Factor 4E Controls Lettuce Susceptibility to the Potyvirus<i>Lettuce mosaic virus</i>

Nicaise, Valérie; German-Retana, Sylvie; Sanjuan, R. Arranz; Dubrana, Marie-Pierre; Mazier, Marianne; Maisonneuve, Brigitte; Candresse, Thierry; Caranta, Carole; Gall, Olivier Le

doi:10.1104/pp.102.017855

Cited by 251 publications

(217 citation statements)

References 54 publications

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“…Requirement for eIF4E/4G or eIF(iso)4E/4G isomers depends on the virus being studied, as A. thaliana knockout plants for eIF(iso)4E or eIF(iso)4G1/2 genes are resistant to TuMV, lettuce mosaic virus and plum pox virus infection, while disruption of eIF4E1 or eIF4G results in resistance to clover yellow vein virus (Decroocq et al, 2006; Duprat et al, 2002;Lellis et al, 2002;Nicaise et al, 2007;Sato et al, 2005). These results were also confirmed in multiple plant species with the identification of eIF4E and eIF4G isoforms as recessive resistance gene products against potyviruses (Gao et al, 2004;Kang et al, 2005;Nicaise et al, 2003; Ruffel et al, 2002Ruffel et al, , 2005. Together, these results are indicative of an essential link between potyvirus replication and components of the translation initiation complex.…”

Section: Introductionsupporting

confidence: 64%

Arabidopsis thaliana class II poly(A)-binding proteins are required for efficient multiplication of turnip mosaic virus

Dufresne

Ubalijoro

Fortin

et al. 2008

Journal of General Virology

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The poly(A)-binding protein (PABP) is an important translation initiation factor that binds to the polyadenylated 39 end of mRNA. We have previously shown that PABP2 interacts with the RNAdependent RNA polymerase (RdRp) and VPg-Pro of turnip mosaic virus (TuMV) within virusinduced vesicles. At least eight PABP isoforms are produced in Arabidopsis thaliana, three of which (PABP2, PABP4 and PABP8) are highly and broadly expressed and probably constitute the bulk of PABP required for cellular functions. Upon TuMV infection, an increase in protein and mRNA expression from PAB2, PAB4 and PAB8 genes was recorded. In vitro binding assays revealed that RdRp and the viral genome-linked protein (VPg-Pro) interact preferentially with PABP2 but are also capable of interaction with one or both of the other class II PABPs (i.e. PABP4 and PABP8). To assess whether PABP is required for potyvirus replication, A. thaliana single and double pab knockouts were isolated and inoculated with TuMV. All lines showed susceptibility to TuMV. However, when precise monitoring of viral RNA accumulation was performed, it was found to be reduced by 2.2-and 3.5-fold in pab2 pab4 and pab2 pab8 mutants, respectively, when compared with wild-type plants. PABP levels were most significantly reduced in the membrane-associated fraction in both of these mutants. TuMV mRNA levels thus correlated with cellular PABP concentrations in these A. thaliana knockout lines. These data provide further support for a role of PABP in potyvirus replication. INTRODUCTIONThe poly(A)-binding protein (PABP) is an abundant translation initiation factor in the cell that binds to the polyadenylated 39 end of mRNA. Its interaction with the eukaryotic translation initiation factor 4F complex (composed of the eIF4E, eIF4A and eIF4G proteins), which is bound to the 59 cap structure of the mRNA, results in the formation of a protein bridge that brings the 59 and 39 termini of the mRNA into proximity. This leads to a synergistic enhancement of translation (Sachs, 2000;Wells et al., 1998). PABP is also important for stability (BehmAnsmant et al., 2007;Parker & Song, 2004), biogenesis (Amrani et al., 1997;Brown & Sachs, 1998) and nuclear export of cellular mRNAs (Brune et al., 2005).Multiple PABP isoforms are normally found in animals and plants (Mangus et al., 2003). Eight PABP genes have been identified in Arabidopsis thaliana (Belostotsky, 2003).The corresponding proteins are divided into four classes based on gene expression and similarity. Class II genes (PAB2, PAB4 and PAB8) are highly and broadly expressed and probably encode the bulk of PABP required for cellular functions (Belostotsky, 2003).In animal cells, PABP is cleaved by proteinases of picornaviruses (Joachims et al., 1999;Kerekatte et al., 1999;Kuyumcu-Martinez et al., 2002, 2004bRodriguez Pulido et al., 2007;Zhang et al., 2007), caliciviruses (Kuyumcu-Martinez et al., 2004a) and retroviruses (Alvarez et al., 2006). The resultant cleavage leads to host translational shutdown (Joachims et al., 1999; KuyumcuMartinez ...

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Section: Introductionsupporting

confidence: 64%

Arabidopsis thaliana class II poly(A)-binding proteins are required for efficient multiplication of turnip mosaic virus

Dufresne

Ubalijoro

Fortin

et al. 2008

Journal of General Virology

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“…In plants, a number of alleles at the eIF4E locus conferring resistance against multiple viruses in the family Potyviridae and at least one virus in the family Tombusviridae have been discovered recently. These include pvr1 in pepper (Ruffel et al, 2002;Kang et al, 2005a), mo1 in lettuce (Nicaise et al, 2003), sbm1 in pea (Gao et al, 2004), pot-1 in tomato (Ruffel et al, 2005), rym4/5 in barley (Stein et al, 2005), and nsv in melon (Nieto et al, 2006). It is striking to note that the critical amino acid substitution in eIF4E-pvr1, G107R, also exists at the homologous sites in several other recessive resistance genes: mo1 and sbm1 in lettuce and pea, respectively.…”

Section: The G107r Change Conferring Potyvirus Resistance Has Evolvedmentioning

confidence: 99%

“…The efficacy of this resistance, which typically manifests as recessive inheritence, is evidenced by the prominence of recessive resistance to plant viruses relative to that of other pathogen classes (Provvidenti and Hampton, 1992;Keller et al, 1998;Robaglia and Caranta, 2006). This defense strategy appears to be particularly widely observed at the eIF4E locus where resistance to multiple RNA phytopathogenic viruses occurs in numerous plant families, including pvr1 in Capsicum (Ruffel et al, 2002;Kang et al, 2005a), mo1 in lettuce (Lactuca sativa; Nicaise et al, 2003), sbm1 in pea (Pisum sativum; Gao et al, 2004), pot-1 in tomato (Solanum lycopersicum; Ruffel et al, 2005), rym4/5 in barley (Hordeum vulgare; Stein et al, 2005), and nsv in melon (Cucumis melo; Nieto et al, 2006). In addition to these naturally existing genes, lsp1 and cum1 resistance alleles created via mutagenesis in Arabidopsis thaliana also encode eIF4E (Lellis et al, 2002;Yoshii et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

Functional Dissection of Naturally Occurring Amino Acid Substitutions in eIF4E That Confers Recessive Potyvirus Resistance in Plants

et al. 2007

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Naturally existing variation in the eukaryotic translation initiation factor 4E (eIF4E) homolog encoded at the pvr1 locus in Capsicum results in recessively inherited resistance against several potyviruses. Previously reported data indicate that the physical interaction between Capsicum-eIF4E and the viral genome-linked protein (VPg) is required for the viral infection in the Capsicum-Tobacco etch virus (TEV) pathosystem. In this study, the potential structural role(s) of natural variation in the eIF4E protein encoded by recessive resistance alleles and their biological consequences have been assessed. Using highresolution three-dimensional structural models based on the available crystallographic structures of eIF4E, we show that the amino acid substitution G107R, found in many recessive plant virus resistance genes encoding eIF4E, is predicted to result in a substantial modification in the protein binding pocket. The G107R change was shown to not only be responsible for the interruption of VPg binding in planta but also for the loss of cap binding ability in vitro, the principal function of eIF4E in the host. Overexpression of the Capsicum-eIF4E protein containing the G107R amino acid substitution in Solanum lycopersicum indicated that this polymorphism alone is sufficient for the acquisition of resistance against several TEV strains.

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“…One such example is the eIF4E gene that has been found to be associated with virus resistance in many plant species (Nicaise et al 2003;Gao et al 2004;Yoshii et al 2004;Kang et al 2005;Kanyuka et al 2005;Stein et al 2005;Nieto et al 2006Nieto et al , 2007Ibiza et al 2010;Naderpour et al 2010;Piron et al 2010), including resistance to potato virus Y in potato, tomato, and pepper (Ruffel et al 2002(Ruffel et al , 2005Cavatorta et al 2011;Duan et al 2012). Variants of eIF4E confer resistance to PVY in the potato wild species relatives S. chacoense, S. demissum, and S. etuberosum , permitting the eventual use of this gene in future biotech potato varieties.…”

Section: Resistance To Biotic and Abiotic Stressesmentioning

confidence: 99%

Biotech Potatoes in the 21st Century: 20 Years Since the First Biotech Potato

et al. 2015

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Potato is the world's most important vegetable crop, with nearly 400 million tons produced worldwide every year, lending to stability in food supply and socioeconomic impact. In general, potato is an intensively managed crop, requiring irrigation, fertilization, and frequent pesticide applications in order to obtain the highest yields possible. Important traits are easy to find in wild relatives of potato, but their introduction using traditional breeding can take 15-20 years. This is due to sexual incompatibility between some wild and cultivated species, a desire to remove undesirable wild species traits from adapted germplasm, and difficulty in identifying broadly applicable molecular markers. Fortunately, potato is amenable to propagation via tissue culture and it is relatively easy to introduce new traits using currently available biotech transformation techniques. For these reasons, potato is arguably the crop that can benefit most by modern biotechnology. The benefits of biotech potato, such as limited gene flow to conventionally grown crops and weedy relatives, the opportunity for significant productivity and nutritional quality gains, and reductions in production cost and environmental impact, have the potential to influence the marketability of newly developed varieties. In this review we will discuss current and past efforts to develop biotech potato varieties, traits that could be impacted, and the potential effects that biotech potato could have on the industry.Resumen La papa es el cultivo hortícola más importante en el mundo, con cerca de 400 millones de toneladas producidas a nivel mundial anualmente, acreditando la estabilidad en el suministro de alimentos e impacto socioeconómico. En general, la papa es un cultivo manejado intensivamente, que requiere riego, fertilización y aplicaciones frecuentes de plaguicidas para obtener los más altos rendimientos posibles. Los caracteres importantes son fáciles de encontrar en parientes silvestres de la papa, pero su introducción usando el mejoramiento tradicional puede llevar de 15 a 20 años. Esto es debido a la incompatibilidad sexual entre algunas especies silvestres y cultivadas, el deseo para eliminar características indeseables de las especies silvestres del germoplasma adaptado, y la dificultad en la identificación de marcadores moleculares aplicables ampliamente. Afortunadamente, la papa es receptiva a la propagación por cultivo de tejidos y es relativamente fácil la introducción de nuevos caracteres usando técnicas biotecnológicas de transformación actualmente disponibles. Por estas razones, la papa es probablemente el cultivo que se puede beneficiar mayormente por la biotecnología moderna. Los beneficios de la papa biotecnológica, como el flujo genético limitado a cultivos que se siembran convencionalmente y a los parientes como malezas, la oportunidad para productividad significativa y logros en calidad nutricional, y las reducciones en los costos de producción e impacto ambiental, tienen el potencial para influenciar la comercialización...

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The Eukaryotic Translation Initiation Factor 4E Controls Lettuce Susceptibility to the PotyvirusLettuce mosaic virus

Cited by 251 publications

References 54 publications

Arabidopsis thaliana class II poly(A)-binding proteins are required for efficient multiplication of turnip mosaic virus

Arabidopsis thaliana class II poly(A)-binding proteins are required for efficient multiplication of turnip mosaic virus

Functional Dissection of Naturally Occurring Amino Acid Substitutions in eIF4E That Confers Recessive Potyvirus Resistance in Plants

Biotech Potatoes in the 21st Century: 20 Years Since the First Biotech Potato

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