Functions of the tobacco etch virus RNA polymerase (NIb): subcellular transport and protein-protein interaction with VPg/proteinase (NIa).

The NIb protein of tobacco etch potyvirus (TEV) possesses several functions, including RNA-dependent RNA polymerase and nuclear translocation activities. Using a reporter protein fusion strategy, NIb was shown to contain two independent nuclear localization signals (NLS I and NLS II). NLS I was mapped to a sequence within amino acid residues 1 to 17, and NLS II was identified between residues 292 and 316. Clustered point mutations resulting in substitutions of basic residues within the NLSs were shown previously to disrupt nuclear translocation activity. These mutations also abolished TEV RNA amplification when introduced into the viral genome. The amplification defects caused by each NLS mutation were complemented in trans within transgenic cells expressing functional NIb, although the level of complementation detected for each mutant differed significantly. Combined with previous results (X. H. Li and J. C. Carrington, Proc. Natl. Acad. Sci. USA 92:457-461, 1995), these data suggest that the NLSs overlap with essential regions necessary for NIb trans-active function(s). The fact that NIb functions in trans implies that it must interact with one or more other components of the genome replication apparatus. A yeast two-hybrid system was used to investigate physical interactions between NIb and several other TEV replication proteins, including the multifunctional VPg/proteinase NIa and the RNA helicase CI. A specific interaction was detected between NIa and NIb. Deletion of any of five regions spanning the NIb sequence resulted in NIb variants that were unable to interact with NIa. Clustered point mutations affecting the conserved GDD motif or NLS II within the central region of NIb, but not mutations affecting NLS I near the N terminus, reduced or eliminated the interaction. The C-terminal proteinase (Pro) domain of NIa, but not the N-terminal VPg domain, interacted with NIb. The effects of NIb mutations within NLS I, NLS II, and the GDD motif on the interaction between the Pro domain and NIb were identical to the effects of these mutations on the interaction between full-length NIa and NIb. These data are compatible with a model in which NIb is directed to replication complexes through an interaction with the Pro domain of NIa.     

High resistance to plum pox virus (PPV) in transgenic plants containing modified and truncated forms of PPV coat protein gene

Two modified plum pox virus (PPV) coat protein (CP) gene constructs, designed to reduce putative biological risks associated with heteroen capsidation, were integrated into Nicotiana benthamiana plants. The first one contained a deletion of the nucleotides encoding for the DAG amino acid triplet involved in virus aphid-transmission. In the second one, the first 420 nucleotides of the PPV CP gene were removed. We present here the analysis and the selection throughout the generations of PPV-resistant transgenic lines containing these constructs. In most of the lines, a recovery phenotype was observed and was associated with a down-regulation of the transgene products (RNA or protein). We also describe two lines that were highly resistant to PPV. This immunity was correlated with a high number of transgene copies (at least three) and with low or undetectable transgene RNA levels. No heterologous protection was observed against other potyviruses. These characteristics indicate that the described resistance against PPV was RNA-mediated and can be classified as a 'sense suppression' or homology-dependent resistance. Moreover, the production of a highly resistant line containing the PPV CP gene with one third of its 5 end deleted indicated that this region is not necessary to trigger the plant resistance mechanism(s)     

Functional Analysis of the Interaction between VPg-Proteinase (NIa) and RNA Polymerase (NIb) of Tobacco Etch Potyvirus, Using Conditional and Suppressor Mutants

The tobacco etch potyvirus (TEV) RNA-dependent RNA polymerase (NIb) has been shown to interact with the proteinase domain of the VPg-proteinase (NIa). To investigate the significance of this interaction, a Saccharomyces cerevisiae two-hybrid assay was used to isolate conditional NIa mutant proteins with temperature-sensitive (ts) defects in interacting with NIb. Thirty-six unique tsNIa mutants with substitutions affecting the proteinase domain were recovered. Most of the mutants coded for proteins with little or no proteolytic activity at permissive and nonpermissive temperatures. However, three mutant proteins retained proteolytic activity at both temperatures and, in two cases (tsNIa-Q384P and tsNIa-N393D), the mutations responsible for the ts interaction phenotype could be mapped to single positions. One of the mutations (N393D) conferred a ts-genome-amplification phenotype when it was placed in a recombinant TEV strain. Suppressor NIb mutants that restored interaction with the tsNIa-N393D protein at the restrictive temperature were recovered by a two-hybrid selection system. Although most of the suppressor mutants failed to stimulate amplification of genomes encoding the tsNIa-N393D protein, two suppressors (NIb-I94T and NIb-C380R) stimulated amplification of virus containing the N393D substitution by approximately sevenfold. These results support the hypothesis that interaction between NIa and NIb is important during TEV genome replication.     

Analysis of the VPg-proteinase (NIa) encoded by tobacco etch potyvirus: effects of mutations on subcellular transport, proteolytic processing, and genome amplification.

A mutational analysis was conducted to investigate the functions of the tobacco etch potyvirus VPg-proteinase (NIa) protein in vivo. The NIa N-terminal domain contains the VPg attachment site, whereas the C-terminal domain contains a picornavirus 3C-like proteinase. Cleavage at an internal site separating the two domains occurs in a subset of NIa molecules. The majority of NIa molecules in TEV-infected cells accumulate within the nucleus. By using a reporter fusion strategy, the NIa nuclear localization signal was mapped to a sequence within amino acid residues 40 to 49 in the VPg domain. Mutations resulting in debilitation of NIa nuclear translocation also debilitated genome amplification, suggesting that the NLS overlaps a region critical for RNA replication. The internal cleavage site was shown to be a poor substrate for NIa proteolysis because of a suboptimal sequence context around the scissile bond. Mutants that encoded NIa variants with accelerated internal proteolysis exhibited genome amplification defects, supporting the hypothesis that slow internal processing provides a regulatory function. Mutations affecting the VPg attachment site and proteinase active-site residues resulted in amplification-defective viruses. A transgenic complementation assay was used to test whether NIa supplied in trans could rescue amplification-defective viral genomes encoding altered NIa proteins. Neither cells expressing NIa alone nor cells expressing a series of NIa-containing polyproteins supported increased levels of amplification of the mutants. The lack of complementation of NIa-defective mutants is in contrast to previous results obtained with RNA polymerase (NIb)-defective mutants, which were relatively efficiently rescued in the transgenic complementation assay. It is suggested that, unlike NIb polymerase, NIa provides replicative functions that are cis preferential.     

Transgenes in plants: protection against viruses and insects

Protective transgenes introduced into plants can be classified as directed against insects, fungi, bacteria or viruses. Mechanisms by which they protect plants in some cases are relatively simple and understood while in most cases they present only the field of rapidly progressing investigations. A brief review of the recent concepts of the resistance induced in plants against viruses by virus-derived transgenes is presented with emphasising the RNA mediated resistance. The RNA mediated resistance seems to operate in Nicotiana benthamiana plants transformed in our laboratory with cDNA of the PPV CP gene: both translatable and untranslatable versions of the cDNA made the transformed plants resistant against PPV. The resistant plants contained more than one copy of the transgene. To protect against insects plants were in our laboratory transformed with potato proteinase inhibitor II gene (PPI-II). The PPI-II gene expressed in model plants inhibited trypsin activity to an expected level.     

Expression of Multiple Virus-derived Resistance Determinants in Transgenic Plants Does Not Lead to Additive Resistance Properties

Plants can be protected against infection by potyviruses by expressing different portions of potyviral genomes as transgenes. This strategy has proven effective with several potyvirus genes, including the Nla, Nlb, and coat protein coding regions. Given the effectiveness of separate potyvirus coding regions as determinants of resistance, we tested the hypothesis that combinations of potyvirus coding regions would provide additively greater protection of plants against potyviruses. For this, we compared transgenic plant lines that expressed either the coat protein (CP) or the Nla+Nlb+coat protein (NNC) coding regions from tobacco vein mottling virus (TVMV). We found that plants that carry the NNC gene combination were invariably less resistant to TVMV than were lines that contain a CP gene alone. Additionally, we found that NNC lines displayed virtually no resistance to tobacco etch virus (TEV), in contrast to the CP lines. We conclude that combining more than one virus-derived resistance determinant in a single construct is detrimental to the production of virus-resistant plants.     

Characterization of the recombinant forms arising from a Potato virus X chimeric virus infection under RNA silencing pressure

Recombination is a frequent phenomenon in RNA viruses whose net result is largely influenced by selective pressures. RNA silencing in plants acts as a defense mechanism against viruses and can be used to engineer virus resistance. Here, we have investigated the influence of RNA silencing as a selective pressure to favor recombinants of PVX-HCT, a chimeric Potato virus X (PVX) vector carrying the helper-component proteinase (HC-Pro) gene from Plum pox virus (PPV). All the plants from two lines expressing a silenced HC-Pro transgene were completely resistant to PPV. However a significant proportion became infected with PVX-HCT. Analysis of viral RNAs accumulating in silenced plants revealed that PVX-HCT escaped silencing-based resistance by removal of the HC-Pro sequences that represented preferential targets for transgene-promoted silencing. The virus vector also tended to lose the HC-Pro insert when infecting transgenic plants containing a nonsilenced HC-Pro transgene or wild-type (wt) Nicotiana benthamiana plants. Nevertheless, loss of HC-Pro sequences was faster in nonsilenced transgenic plants than in wt plants, suggesting the transgene plays a role in promoting a higher selective pressure in favor of recombinant virus versions. These results indicate that the outcome of recombination processes depends on the strength of selection pressures applied to the virus.     

Resistance to wheat streak mosaic virus in transgenic wheat expressing the viral replicase (NIb) gene

Wheat (Triticum aestivum L. cv. Hi-Line) immature embryos were transformed with the replicase gene (NIb) of wheat streak mosaic virus (WSMV) by the biolistic method. Six independent transgenic plant lines were analyzed for transgene expression and for resistance to mechanical inoculation of WSMV at R3 or R4 generation. Four out of the six lines showed various degree of resistance to WSMV. These lines had initially milder symptoms than controls, and the new growth ranged from milder symptoms, a substantial delay in symptom development, or asymptomatic. Two lines displayed higher resistance with very mild virus symptoms after inoculation and the new growth of 72% and 32% plants from these lines were asymptomatic and had no detectable virus through the plant life cycle. Interestingly, five out of the six transgenic lines had no detectable transgene mRNA expression by RNA gel blot hybridization. The only line that had detectable transgene mRNA did not show delay in the symptom development but had overall milder symptom to the virus.     

Identification of Plum pox virus pathogenicity determinants in herbaceous and woody hosts

Plum pox virus (PPV) is a member of the genus Potyvirus that is able to infect a large variety of plant species, including trees of the genus Prunus, its natural host. When some PPV isolates are propagated for an extended time in herbaceous plants, their ability to infect trees is reduced. The molecular basis of this change in host infectivity is poorly understood. We report the construction of hybrid viruses from cDNA clones of two D-strain isolates of PPV, PPV-D and PPV-R, which differ in their host range. PPV-D can infect GF305 peach seedlings efficiently, however, it is unable to infect Nicotiana clevelandii plants. Conversely, PPV-R infects N. clevelandii, but not GF305 peach seedlings. The analyses of the hybrid viruses showed that, although determinants of PPV pathogenicity are extensively spread throughout the PPV genome, the 3' terminal region of the PPV-R genome, including the 3' noncoding region and the coding regions for the coat protein (CP), NIb, and part of NIa protein, is sufficient to confer infectivity of N. clevelandii in a PPV-D background. Our data demonstrate a high concentration of amino acid substitutions in the CP and a host-specific effect of a deletion at the N terminus of this protein in PPV pathogenicity in peach and N. clevelandii infectivity experiments. These results suggest that relevant host specificity determinants are located in the N-terminal region of the CP. The analyses of the PPV-R and PPV-D chimeras also showed that key host-specific pathogenicity determinants lie in the 5' terminal third of the PPV genome, a region that spans proteins P1, HCPro, and P3. The selection of mutations in only a few specific residues in proteins P1, P3, and 6K1 after partial adaptation of a chimeric virus (BD-GFP) to N. clevelandii further suggests a relevant role for these proteins in host adaptation.     

Extreme resistance to potato virus X infection in plants expressing a modified component of the putative viral replicase.

Three types of mutation were introduced into the sequence encoding the GDD motif of the putative replicase component of potato virus X (PVX). All three mutations rendered the viral genome completely noninfectious when inoculated into Nicotiana clevelandii or into protoplasts of Nicotiana tabacum (cv. Samsun NN). In order to test whether these negative mutations could inactivate the viral genome in trans, the mutant genes were expressed in transformed N.tabacum (cv. Samsun NN) under control of the 35S RNA promoter of cauliflower mosaic virus and the transformed lines were inoculated with PVX. In 10 lines tested in which the GDD motif was expressed as GAD or GED there was no effect on susceptibility to PVX. In two of four lines transformed to express the ADD form of the conserved motif, the F1 and F2 progeny plants were highly resistant to infection by PVX, although only to strains closely related to the source of the transgene. The resistance was associated with suppression of PVX accumulation in the inoculated and systemic leaves and in protoplasts of the transformed plants, although some low level viral RNA production was observed in the inoculated but not the systemic leaves when the inoculum was as high as 100 or 250 micrograms/ml PVX RNA. These results suggest for a plant virus, as reported previously for Q beta phage, that virus resistance may be engineered by expression of dominant negative mutant forms of viral genes in transformed cells.     

转不可翻译PVY^N CP基因烟草的抗病性分析

我们曾报道表达不可翻译PVY^N CP基因的转基因烟草抗病性是由RNA介导的,其抗病性类似于转录后的基因沉默(PTGS)。本研究以这类不同抗性的T0代转基因烟草植株为材料,对自交后的T1代转基因植株的遗传和抗病性进行了分析,并选取部分T1代抗病株系自交留种。对T2代RNA介导抗病性转基因植株进行了分子分析和一系列抗病性研究。结果表明,含1—2个转基因拷贝的T0代感病植株,在T1代中的Km抗性分离符合单位点插入的3：1的遗传规律;含3个或3个以上转基因拷贝的T0代中抗或高抗植株,在T1代中的Km抗性分离符合多位点插入的15：1或63：1的遗传规律。大多数T1、T2代转基因植株的抗病性与转基因拷贝数成正相关,转基因在T1、T2代植株中能够转录表达,且转基因植株之间转基因mRNA在细胞质中的积累水平与转基因植株的抗病性成负相关。转基因植株的抗病性能够在T1、T2代中遗传,且T2代转基因植株的抗病性具有以下特征：1)既抗病毒粒体又抗病毒RNA的侵染,且这种抗病性不受接种物剂量的影响;2)抗病谱较窄,只对PVY的某些株系具有高度抗病性;3)与传毒方式无关,既抗摩擦接种又抗带毒蚜虫接种;4)与植株的发育阶段没有关系。     

转不可翻译PVYN CP基因烟草的抗病性分析

我们曾报道表达不可翻译PVY~N CP基因的转基因烟草抗病性是由RNA介导的,其抗病性类似于转录后的基因沉默(PTGS)。本研究以这类不同抗性的Tn代转基因烟草植株为材料,对自交后的T1代转基因植株的遗传和抗病性进行了分析,并选取部分T_1代抗病株系自交留种。对T_2代RNA介导抗病性转基因植株进行了分子分析和一系列抗病性研究。结果表明,含1-2个转基因拷贝的T_0代感病植株,在T_1代中的Km抗性分离符合单位点插入的3∶1的遗传规律;含3个或3个以上转基因拷贝的T_0代中抗或高抗植株,在T_1代中的Km抗性分离符合多位点插入的15∶1或63∶1的遗传规律。大多数T_1、T_2代转基因植株的抗病性与转基因拷贝数成正相关,转基因在T_1、T_2代植株中能够转录表达,且转基因植株之间转基因mRNA在细胞质中的积累水平与转基因植株的抗病性成负相关。转基因植株的抗病性能够在T_1、T_2代中遗传,且T_2代转基因植株的抗病性具有以下特征:1)既抗病毒粒体又抗病毒RNA的侵染,且这种抗病性不受接种物剂量的影响;2)抗病谱较窄,只对PVY的某些株系具有高度抗病性;3)与传毒方式无关,既抗摩擦接种又抗带毒蚜虫接种;4)与植株的发育阶段没有关系。     

The tobacco etch potyvirus 6-kilodalton protein is membrane associated and involved in viral replication.

The tobacco etch potyvirus (TEV) genome encodes a polyprotein that is processed by three virus-encoded proteinases. Although replication of TEV likely occurs in the cytoplasm, two replication-associated proteins, VPg-proteinase (nuclear inclusion protein a) (NIa) and RNA-dependent RNA polymerase (nuclear inclusion protein b) (NIb), accumulate in the nucleus of infected cells. The 6-kDa protein is located adjacent to the N terminus of NIa in the TEV polyprotein, and, in the context of a 6-kDa protein/NIa (6/NIa) polyprotein, impedes nuclear translocation of NIa (M. A. Restrepo-Hartwig and J. C. Carrington, J. Virol. 66:5662-5666, 1992). The 6-kDa protein and three polyproteins containing the 6-kDa protein were identified by affinity chromatography of extracts from infected plants. Two of the polyproteins contained NIa or the N-terminal VPg domain of NIa linked to the 6-kDa protein. To investigate the role of the 6-kDa protein in vivo, insertion and substitution mutagenesis was targeted to sequences coding for the 6-kDa protein and its N- and C-terminal cleavage sites. These mutations were introduced into a TEV genome engineered to express the reporter protein beta-glucuronidase (GUS), allowing quantitation of virus amplification by a fluorometric assay. Three-amino-acid insertions at each of three positions in the 6-kDa protein resulted in viruses that were nonviable in tobacco protoplasts. Disruption of the N-terminal cleavage site resulted in a virus that was approximately 10% as active as the parent, while disruption of the C-terminal processing site eliminated virus viability. The subcellular localization properties of the 6-kDa protein were investigated by fractionation and immunolocalization of 6-kDa protein/GUS (6/GUS) fusion proteins in transgenic plants. Nonfused GUS was associated with the cytosolic fraction (30,000 x g centrifugation supernatant), while 6/GUS and GUS/6 fusion proteins sedimented with the crude membrane fraction (30,000 x g centrifugation pellet). The GUS/6 fusion protein was localized to apparent membranous proliferations associated with the periphery of the nucleus. These data suggest that the 6-kDa protein is membrane associated and is necessary for virus replication.