Expression of alfalfa mosaic virus and tobacco rattle virus coat protein genes in transgenic tobacco plants

Whole-Genome Characterization of Alfalfa Mosaic Virus Obtained from Metagenomic Analysis of Vinca minor and Wisteria sinensis in Iran: with Implications for the Genetic Structure of the Virus

Alfalfa mosaic virus (AMV), an economically important pathogen, is present worldwide with a very wide host range. This work reports for the first time the infection of Vinca minor and Wisteria sinensis with AMV using RNA sequencing and reverse transcription polymerase chain reaction confirmation. De novo assembly and annotating of contigs revealed that RNA1, RNA2, and RNA3 genomic fragments consist of 3,690, 2,636, and 2,057 nucleotides (nt) for IR-VM and 3,690, 2,594, and 2,057 nt for IR-WS. RNA1 and RNA3 segments of IR-VM and IR-WS closely resembled those of the Chinese isolate HZ, with 99.23-99.26% and 98.04-98.09% nt identity, respectively. Their RNA2 resembled that of Canadian isolate CaM and American isolate OH-2-2017, with 97.96-98.07% nt identity. The P2 gene revealed more nucleotide diversity compared with other genes. Genes in the AMV genome were under dominant negative selection during evolution, and the P1 and coat protein (CP) proteins were subject to the strongest and weakest purifying selection, respectively. In the population genetic analysis based on the CP gene sequences, all 107 AMV isolates fell into two main clades (A, B) and isolates of clade A were further divided into three groups with significant subpopulation differentiation. The results indicated moderate genetic variation within and no clear geographic or genetic structure between the studied populations, implying moderate gene flow can play an important role in differentiation and distribution of genetic diversity among populations. Several factors have shaped the genetic structure and diversity of AMV: selection, recombination/reassortment, gene flow, and random processes such as founder effects.

Development and Adoption of Genetically Engineered Plants for Virus Resistance: Advances, Opportunities and Challenges

Plant viruses cause yield losses to crops of agronomic and economic significance and are a challenge to the achievement of global food security. Although conventional plant breeding has played an important role in managing plant viral diseases, it will unlikely meet the challenges posed by the frequent emergence of novel and more virulent viral species or viral strains. Hence there is an urgent need to seek alternative strategies of virus control that can be more readily deployed to contain viral diseases. The discovery in the late 1980s that viral genes can be introduced into plants to engineer resistance to the cognate virus provided a new avenue for virus disease control. Subsequent advances in genomics and biotechnology have led to the refinement and expansion of genetic engineering (GE) strategies in crop improvement. Importantly, many of the drawbacks of conventional breeding, such as long lead times, inability or difficulty to cross fertilize, loss of desirable plant traits, are overcome by GE. Unfortunately, public skepticism towards genetically modified (GM) crops and other factors have dampened the early promise of GE efforts. These concerns are principally about the possible negative effects of transgenes to humans and animals, as well as to the environment. However, with regards to engineering for virus resistance, these risks are overstated given that most virus resistance engineering strategies involve transfer of viral genes or genomic segments to plants. These viral genomes are found in infected plant cells and have not been associated with any adverse effects in humans or animals. Thus, integrating antiviral genes of virus origin into plant genomes is hardly unnatural as suggested by GM crop skeptics. Moreover, advances in deep sequencing have resulted in the sequencing of large numbers of plant genomes and the revelation of widespread endogenization of viral genomes into plant genomes. This has raised the possibility that viral genome endogenization is part of an antiviral defense mechanism deployed by the plant during its evolutionary past. Thus, GM crops engineered for viral resistance would likely be acceptable to the public if regulatory policies were product-based (the North America regulatory model), as opposed to process-based. This review discusses some of the benefits to be gained from adopting GE for virus resistance, as well as the challenges that must be overcome to leverage this technology. Furthermore, regulatory policies impacting virus-resistant GM crops and some success cases of virus-resistant GM crops approved so far for cultivation are discussed.

Transgenic resistance

Transgenic resistance to plant viruses is an important technology for control of plant virus infection, which has been demonstrated for many model systems, as well as for the most important plant viruses, in terms of the costs of crop losses to disease, and also for many other plant viruses infecting various fruits and vegetables. Different approaches have been used over the last 28 years to confer resistance, to ascertain whether particular genes or RNAs are more efficient at generating resistance, and to take advantage of advances in the biology of RNA interference to generate more efficient and environmentally safer, novel "resistance genes." The approaches used have been based on expression of various viral proteins (mostly capsid protein but also replicase proteins, movement proteins, and to a much lesser extent, other viral proteins), RNAs [sense RNAs (translatable or not), antisense RNAs, satellite RNAs, defective-interfering RNAs, hairpin RNAs, and artificial microRNAs], nonviral genes (nucleases, antiviral inhibitors, and plantibodies), and host-derived resistance genes (dominant resistance genes and recessive resistance genes), and various factors involved in host defense responses. This review examines the above range of approaches used, the viruses that were tested, and the host species that have been examined for resistance, in many cases describing differences in results that were obtained for various systems developed in the last 20 years. We hope this compilation of experiences will aid those who are seeking to use this technology to provide resistance in yet other crops, where nature has not provided such.

Plant genetic engineering for crop improvement

Plant genetic engineering has long since left its experimental stage: transgenic plants with resistance to viruses, bacteria, fungi, various pests and abiotic stresses have already been released in their hundreds. Transgenic plants can produce better fruits and food of higher quality than wild-types, and can be used as bioreactors for the synthesis of pharmaceutically important compounds. This review portrays some of the achievements in this field of plant molecular biology.

Genetically engineering plants for crop improvement

Dramatic progress has been made in the development of gene transfer systems for higher plants. The ability to introduce foreign genes into plant cells and tissues and to regenerate viable, fertile plants has allowed for explosive expansion of our understanding of plant biology and has provided an unparalleled opportunity to modify and improve crop plants. Genetic engineering of plants offers significant potential for seed, agrichemical, food processing, specialty chemical, and pharmaceutical industries to develop new products and manufacturing processes. The extent to which genetically engineered plants will have an impact on key industries will be determined both by continued technical progress and by issues such as regulatory approval, proprietary protection, and public perception.

Generation of transgenic oriental melon resistant to Zucchini yellow mosaic virus by an improved cotyledon-cutting method

Production of melon (Cucumis melo L.) worldwide is often limited by the potyvirus, Zucchini yellow mosaic virus (ZYMV). In order to engineer melon lines resistant to ZYMV, a construct containing the translatable coat protein (CP) sequence coupled with the 3' non-translatable region of the virus was generated and used to transform an elite cultivar of oriental melon (Silver light) mediated by Agrobacterium using an improved cotyledon-cutting method. Removal of 1-mm portion from the proximal end of cotyledons greatly increased the frequency of transgenic regenerants by significantly decreasing the incidence of false positive and aberrant transformants. Results of greenhouse evaluation of transgenic lines by mechanical challenge with ZYMV identified transgenic lines exhibiting different levels of resistance or complete immunity to ZYMV. Southern hybridization of transgenic lines revealed random insertion of the transgene in host genome, with insert numbers differing among transformants. Northern hybridization revealed great variations in the levels of accumulation of the transgene transcripts among transgenic lines, and evidenced an inverse correlation of the levels of accumulation of transgene transcript to the degrees of virus resistance, indicating post-transcriptional gene silencing (PTGS)-mediated transgenic resistance. These transgenic melon lines with high degrees of resistance to ZYMV have great potential for the control of ZYMV in East Asia.

Tobacco mosaic virus 126-kDa protein increases the susceptibility of Nicotiana tabacum to other viruses and its dosage affects virus-induced gene silencing

The Tobacco mosaic virus (TMV) 126-kDa protein is a suppressor of RNA silencing previously shown to delay the silencing of transgenes in Nicotiana tabacum and N. benthamiana. Here, we demonstrate that expression of a 126-kDa protein-green fluorescent protein (GFP) fusion (126-GFP) in N. tabacum increases susceptibility to a broad assortment of viruses, including Alfalfa mosaic virus, Brome mosaic virus, Tobacco rattle virus (TRV), and Potato virus X. Given its ability to enhance TRV infection in tobacco, we tested the effect of 126-GFP expression on TRV-mediated virus-induced gene silencing (VIGS) and demonstrate that this protein can enhance silencing phenotypes. To explain these results, we examined the poorly understood effect of suppressor dosage on the VIGS response and demonstrated that enhanced VIGS corresponds to the presence of low levels of suppressor protein. A mutant version of the 126-kDa protein, inhibited in its ability to suppress silencing, had a minimal effect on VIGS, suggesting that the suppressor activity of the 126-kDa protein is indeed responsible for the observed dosage effects. These findings illustrate the sensitivity of host plants to relatively small changes in suppressor dosage and have implications for those interested in enhancing silencing phenotypes in tobacco and other species through VIGS.

Posttranscriptional Gene Silencing Does Not Play a Significant Role in Potato virus X Coat Protein-Mediated Resistance

ABSTRACT The expression of a gene that encodes coat protein (CP) of Potato virus X (PVX) in transgenic tobacco plants confers a high level of CP-mediated rresistance (CP-MR) against PVX infection. To determine if posttranscriptional gene silencing (PTGS) plays a role in resistance, transgenic plants expressing PVX CP were challenged against PVX under conditions in which PTGS was suppressed by low temperatures or using viruses carrying PTGS suppressors. The data demonstrate that PTGS does not play a significant role in PVX CP-MR.

Tobacco mosaic virus (TMV) and potato virus X (PVX) coat proteins confer heterologous interference to PVX and TMV infection, respectively

Replication of Potato virus X (PVX) was reduced in transgenic protoplasts that accumulated wild-type coat protein (CPWT) of Tobacco mosaic virus (TMV) or a mutant CP, CP(T42W), that produced highly ordered states of aggregation, including pseudovirions. This reaction is referred to as heterologous CP-mediated resistance. However, protoplasts expressing a CP mutant that abolished aggregation and did not produce pseudovirions, CPT28W, did not reduce PVX replication. Similarly, in transgenic tobacco plants producing TMV CPWT or CP(T42W), there was a delay in local cell-to-cell spread of PVX infection that was not observed in CP(T28W) plants or in non-transgenic plants. The results suggest that the quaternary structure of the TMV CP regulates the mechanism(s) of heterologous CP-mediated resistance. Similarly, transgenic protoplasts that produced PVX CP conferred transient protection against infection by TMV RNA. Transgenic plants that accumulated PVX CP reduced the cell-to-cell spread of infection and resulted in a delay in systemic infection following inoculation with TMV or TMV RNA. Heterologous CP-mediated resistance was characterized by a brief delay in systemic infection, whilst homologous CP-mediated resistance conferred reduced or no systemic infection.

Temporal and Spatial Spread of Soybean mosaic virus (SMV) in Soybeans Transformed with the Coat Protein Gene of SMV

ABSTRACT Soybean lines transformed with the coat protein (CP) gene of Soybean mosaic virus (SMV) were evaluated for SMV resistance by quantifying the temporal and spatial spread of SMV strain AL-5 released from a point source in the field. The temporal spread of SMV within field plots during 1999 and 2000 was quantified by enzyme-linked immunosorbent assay. The Gompertz model most appropriately described temporal spread. Two SMV CP transformed lines (genotypes) had significantly lower infection rates and significantly lower final SMV incidence values (P </= 0.05) compared with controls that did not contain the CP gene. Ordinary runs analysis revealed that the spatial pattern of SMV-infected quadrats was more clustered in plots with higher SMV infection rates. Soybean lines with the lowest infection rates had significantly higher yields in 2000 and significantly less seed coat mottling compared with the controls. To our knowledge, this is the first field study demonstrating the effectiveness of pathogen-derived resistance on the temporal and spatial dynamics of pathogen spread in soybean.

The multifunctional capsid proteins of plant RNA viruses

This article summarizes studies of viral coat (capsid) proteins (CPs) of RNA plant viruses. In addition, we discuss and seek to interpret the knowledge accumulated to data. CPs are named for their primary function; to encapsidate viral genomic nucleic acids. However, encapsidation is only one feature of an extremely diverse array of structural, functional, and ecological roles played during viral infection and spread. Herein, we consider the evolution of viral CPs and their multitude of interactions with factors encoded by the virus, host plant, or viral vector (biological transmission agent) that influence the infection and epidemiological facets of plant disease. In addition, applications of today's understanding of CPs in the protection of crops from viral infection and use in the manufacture of valuable compounds are considered.

Viruses and gene silencing in plants

Genetic engineering of virus resistance in plants may be conferred by transgenes based on sequences from the viral genome. In many instances the underlying mechanism involves the transgenically expressed proteins. However there are other examples in which the mechanism is based on RNA. It appears that this mechanism is related to post transcriptional gene silencing in transgenic plants. This gene silencing is likely to involve antisense RNA produced by the action of a host-encoded RNA dependent RNA polymerase. The natural role of this mechanism is as a genetic immune system conferring protection against viruses. There may also be a genomic role of the process reflected in RNA directed methylation of transgenes. Further understanding of this mechanism has obvious implications for virus resistance in plants. In addition the gene silencing can be used as a component of a new technology with application in functional genomics.

Complementation and disruption of viral processes in transgenic plants

RNAs 1 and 2 of alfalfa mosaic virus (AIMV) encode the replicase genes P1 and P2, respectively, whereas RNA 3 encodes the movem ent protein and the viral coat protein (CP). To investigate the mechanism of cross-protection, tobacco plants were transformed with wild-type and mutant DNA copies of the AIMV CP gene and the two replicase genes P1 and P2. Expression of wild-type CP at relatively low levels resulted in a resistance against infection with AIMV virus particles whereas at higher expression levels CP protected against infection with either AIMV particles or RNAs. Plants transformed with a mutant AIMV CP gene were not resistant to the wild-type virus but were resistant to AIMV with the same mutation in the CP gene. Transformation of plants with the wild-type P1 gene (P1 plants), P2 gene (P2 plants) or both these genes (P12 plants) did not result in resistance to AIMV. Instead, these plants could be infected with an inoculum lacking the gene(s) that was (were) integrated in the plant genome. Infection of non-transgenic plants, P1 plants or P2 plants with a mixture of AIMV genomic RNAs requires the presence of CP in the inoculum but P12 plants could be infected with RNA3 without any requirement for CP in the inoculum. Infection conditions in which 355 promoter/AlMV cDNA fusions were present in the inoculum instead of in the plant genome were used to shed light on the early function of CP. Finally, plants were transformed with P2 genes with mutations in the GDD-motif. A number of these transgenic lines showed a high level of resistance to AIMV.

Sugar-binding activity of pea (Pisum sativum) lectin is essential for heterologous infection of transgenic white clover hairy roots by Rhizobium leguminosarum biovar viciae

Legume lectin stimulates infection of roots in the symbiosis between leguminous plants and bacteria of the genus Rhizobium. Introduction of the Pisum sativum lectin gene (psl) into white clover hairy roots enables heterologous infection and nodulation by the pea symbiont R. leguminosarum biovar viciae (R.l. viciae). Legume lectins contain a specific sugar-binding site. Here, we show that inoculation of white clover hairy roots co-transformed with a psl mutant encoding a non-sugar-binding lectin (PSL N125D) with R.l. viciae yielded only background pseudo-nodule formation, in contrast to the situation after transformation with wild type psl or with a psl mutant encoding sugar-binding PSL (PSL A126V). For every construct tested, nodulation by the homologous symbiont R.l. trifolii was normal. These results strongly suggest that (1) sugar-binding activity of PSL is necessary for infection of white clover hairy roots by R.l. viciae, and (2) the rhizobial ligand of host lectin is a sugar residue rather than a lipid.

Coat protein-mediated resistance in transgenic plants

This review describes the proposed mechanism(s) of classical virus cross-protection in plants, followed by those suggested for coat protein-mediated resistance (CP-mediated resistance). Although both have common features, cross-protection is thought to be a complex response caused by the replication and expression of the entire viral genome, whereas the resistance conferred by the expression of a virus coat protein gene is more limited. The term genetically engineered cross-protection is frequently used because in many cases the phenotype of resistance mimics that of cross-protection. However, CP-mediated resistance, although a narrow term, more accurately describes the resistance that results from the expression of a virus CP gene in transgenic plants.

Increased Resistance to Potato Virus X and Preservation of Cultivar Properties in Transgenic Potato Under Field Conditions

During the last three years we performed field trials to assess levels of resistance against potato virus X (PVX) and changes in intrinsic properties of the potato cultivars Bintje and Escort upon the introduction of the PVX coat protein (CP) gene. Analysis of leaf and tuber samples collected in the field at two week intervals revealed a stable expression of the PVX CP gene throughout the growing season. This resulted in a large decrease in PVX incidence among clonal progeny obtained from previously infected Bintje and Escort clones. Based on evaluation of 50 defined morphological characteristics, tuber yield and grading, 81.8% of the Escort and 17.9% of the Bintje derived transgenic clones proved to be true to type. Overall lightsprout morphology was a useful criterion for the early detection of deviant transgenic clones. Using the polymerase chain reaction (PCR) with convergent primers spanning transgenic sequences, true to type clones could be distinguished unambiguously from the corresponding untransformed cultivars. Clear distinctions between independent transgenic clones could be made by inverted PCR (IPCR) diagnosis revealing integration-specific border fragments. These results demonstrate the commercial feasibility of improving potato cultivars by selectively adding new traits while preserving intrinsic properties, and the possibility of unambiguously identifying independent transgenic cultivars.

Characterization of cymbidium mosaic virus coat protein gene and its expression in transgenic tobacco plants

Cymbidium mosaic virus (CyMV) is the most prevalent virus infecting orchids. Here, we report the isolation of partial cDNA clones encoding the genomic RNA of CyMV. Like most of the polyadenylated monopartite positive-strand RNA viruses, the open reading frame (ORF) coding for the viral coat protein (CP) is located at the 3' end. The ORF predicts a polypeptide chain of 220 amino acids with a molecular weight of 23,600. Sequence comparison of this ORF to the CP sequences of potato virus X(PVX) and white clover mosaic virus (WClMV) revealed a strong amino acid homology in the mid-portion of the CP, but the overall homology was low. The CyMV CP gene was placed downstream of a cauliflower mosaic virus 35S promoter and the chimaeric gene was transferred into Nicotiana benthamiana. Transgenic plants expressing the CyMV CP were protected against CyMV infection.

Expression of the gene encoding the coat protein of cucumber mosaic virus (CMV) strain WL appears to provide protection to tobacco plants against infection by several different CMV strains

The gene (cp) encoding the coat protein (CP) of cucumber mosaic virus (CMV) strain WL (CMV-WL, which belongs to CMV subgroup II) was custom polymerase chain reaction (CPCR)-engineered for expression as described by Slightom [Gene 100 (1991) 251-255]. CPCR amplification was used to add 5'- and 3'-flanking NcoI sites to the CMV-WL cp gene, and cp was cloned into the expression vector, pUC18cpexp. This CMV-WL cp expression cassette was transferred into the genome of tobacco (Nicotiana tabacum cv. Havana 423) via the Agrobacterium T-DNA transfer mechanism. R0 plants that express the CMV-WL cp gene were subcloned, propagated, and challenge-inoculated with CMV-WL. Several R0 plant lines showed excellent protection against CMV-WL infection; however, plants found to accumulate the highest CP levels did not show the highest degree of protection. Thus in our case, CP levels appear not to be a useful predictor of the degree of protection. Plants from the best protected CMV-WL cp gene-expressing R0 tobacco lines were also inoculated with CMV strains belonging to the other major CMV subgroup (subgroup I), CMV-C and CMV-Chi, and compared in a parallel experiment with a transgenic tobacco plant line that expresses the CMV-C cp gene. Plants expressing the CMV-WL cp gene appeared to show a broader spectrum of protection against infection by the various CMV strains than plants expressing the CMV-C cp gene.

Complementation and recombination between alfalfa mosaic virus RNA3 mutants in tobacco plants

Deletions were made in an infectious cDNA clone of alfalfa mosaic virus (AIMV) RNA3 and the replication of RNA transcripts of these cDNAs was studied in tobacco plants transformed with AIMV replicase genes (P12 plants). Previously, we found that deletions in the P3 gene did not affect accumulation of RNA3 in P12 protoplasts whereas deletions in the coat protein (CP) gene reduced accumulation 100-fold (A. C. van der Kuyl, L. Neeleman, and J. F. Bol, 1991, Virology 183, 687-694). In P12 plants deletions in the P3 gene reduced accumulation by about 200-fold and accumulation of CP deletion mutants was not detectable. When P12 plants were inoculated with a mixture of P3- and CP-deletion mutants, both mutants replicated efficiently and various amounts of full-length RNA3 molecules were formed by recombination. The observation that some P3 and CP mutants did not recombine at a detectable level after several passages in P12 plants demonstrated that mutations in the AIMV P3 and CP genes can be complemented in trans.

Protection against detrimental effects of potyvirus infection in transgenic tobacco plants expressing the papaya ringspot virus coat protein gene

We obtained transgenic tobacco plants expressing the papaya ringspot virus (PRV) coat protein (CP) gene by transformation via Agrobacterium tumefaciens. Expression was effectively monitored by enzyme-linked immunosorbent assays (ELISA) of crude tissue extracts. Subcloned plants derived from eight original Ro transformants were inoculated with potyviruses: tobacco etch (TEV), potato virus Y (PVY), and pepper mottle (PeMV). Plants that accumulated detectable levels of the PRV CP showed significant delay in symptom development and the symptoms were attenuated. Similar results were obtained with inoculated R1 plants. We conclude that the expression of the PRV CP-gene imparts protection against infection by a broad spectrum of potyviruses.

The development of virus-resistant alfalfa, Medicago sativa L

We have generated more than 100 transgenic alfalfa plants, via Agrobacterium-mediated gene transfer, from genotypes selected from five alfalfa cultivars. These plants express the genes for kanamycin resistance and for the coat protein of alfalfa mosaic virus (AMV). The strongest expressers accumulated nearly 500 ng coat protein per mg soluble leaf protein. AMV inoculation of protoplasts from these strong expressers indicated that they were resistant to infection by AMV, while protoplasts from plants containing about a hundred-fold less coat protein and from control untransformed plants were not. Transgenic alfalfa plants containing large amounts of coat protein were, likewise, resistant to AMV. These plants did not develop systemic infections following inoculation with up to 50 micrograms/ml AMV, while inoculated control plants developed systemic infections following inoculation with as little as 10 micrograms/ml AMV. These results demonstrate that expression of the AMV coat protein gene confers resistance to AMV infection in transgenic alfalfa plants.

Strategies for expression of foreign genes in plants. Potential use of engineered viruses

Advances in gene transfer techniques for higher plants have already permitted important achievements towards crop protection and improvement using recombinant DNA technology. Besides plant genetic engineering, the possible use of plant viruses to express foreign genes could be of considerable interest to plant biotechnology. However, insuring containment of engineered viruses for environmental use is an important safety issue that must be addressed.

Replication of an incomplete alfalfa mosaic virus genome in plants transformed with viral replicase genes

RNAs 1 and 2 of alfalfa mosaic virus (AIMV) encode proteins P1 and P2, respectively, both of which have a putative role in viral RNA replication. Tobacco plants were transformed with DNA copies of RNA1 (P1-plants), RNA2 (P2-plants) or a combination of these two cDNAs (P12-plants). All transgenic plants were susceptible to infection with the complete AIMV genome (RNAs 1, 2, and 3). Inoculation with incomplete mixtures of AIMV RNAs showed that the P1-plants were able to replicate RNAs 2 and 3, that the P2-plants were able to replicate RNAs 1 and 3, and that the P12-plants were able to replicate RNA3. Initiation of infection of nontransgenic plants, P1-plants, or P2-plants requires the presence of AIMV coat protein in the inoculum, but no coat protein was required to initiate infection of P12-plants with RNA3. Results obtained with P12-protoplasts supported the conclusion that coat protein plays an essential role in the replication cycle of AIMV RNAs 1 and 2.

Role of alfalfa mosaic virus coat protein gene in symptom formation

On Samsun NN tobacco plants strains 425 and YSMV of alfalfa mosaic virus (AIMV) cause mild chlorosis and local necrotic lesions, respectively. DNA copies of RNA3 of both strains were transcribed in vitro into infectious RNA molecules. When the 425 and YSMV transcripts were inoculated to tobacco plants transformed with DNA copies of AIMV RNAs 1 and 2, they induced symptoms indistinguishable from those of the corresponding parent strains. Exchange of restriction fragments between the infectious clones showed that symptom expression was determined by the coat protein gene in RNA3. The sequence of YSMV RNA3 was determined and compared with the known sequence of 425 RNA3. When the codon for Gln-29 in the coat protein of strain 425 was mutated into the Arg codon present at this position in strain YSMV, the symptoms induced by the transcript on inoculated leaves changed from chlorosis to necrosis. Genetic determinants for the systemic response were more complex.

Tissue-specific expression of the TMV coat protein in transgenic tobacco plants affects the level of coat protein-mediated virus protection

Transgenic tobacco plants were produced that express a chimeric gene encoding the coat protein (CP) of tobacco mosaic virus (TMV) under the control of the promoter from a ribulose bisphosphate carboxylase small subunit (rbcS) gene. Plant lines expressing comparable levels of CP from the rbcS and cauliflower mosaic virus 35S promoters were compared for resistance to TMV. In whole plant assays the 35S:CP constructs gave higher resistance than the rbcS:CP constructs. On the other hand, leaf mesophyll protoplasts isolated from both plant lines were equally resistant to infection by TMV. This indicated that the difference in resistance between the lines in the whole plant assay reflects differences at the level of short- and/or long-distance spread of TMV. Therefore, we propose that the difference in tissue-specific expression between the 35S and rbcS promoters accounts for greater resistance in the plant lines that express the 35S:CP chimeric genes.

Susceptibility to virus infection of transgenic tobacco plants expressing structural and nonstructural genes of tobacco rattle virus

Tobacco plants were transformed with the coat protein (CP) genes and several nonstructural genes of tobacco rattle virus (TRV) strains PLB and TCM. Accumulation of RNA transcripts from the integrated viral genes was detectable in all types of transformants. Plants expressing CP were resistant to infection with virions of the homologous strain but susceptible to infection with RNA of the homologous strain or nucleoprotein of the heterologous strain. No resistance was detectable in plants transformed with the nonstructural 13K and 16K genes of strain PLB, or with the 29K gene that is unique to RNA-2 of strain TCM. When protoplasts from plants expressing TCM-CP were inoculated with TCM virions, there was a normal production of genomic RNAs and CP but the synthesis of mRNA and protein corresponding to the 16K gene was selectively defective. Because this defect was not observed when protoplasts from plants expressing PLB-CP were inoculated with PLB virions, it probably plays no role in the coat protein-mediated protection observed in transgenic plants.

Genetic engineering of plants for virus resistance

Historically, control of plant virus disease has involved numerous strategies which have often been combined to provide effective durable resistance in the field. In recent years, the dramatic advances obtained in plant molecular virology have enhanced our understanding of viral genome organizations and gene functions. Moreover, genetic engineering of plants for virus resistance has recently provided promising additional strategies for control of virus disease. At present, the most promising of these has been the expression of coat-protein coding sequences in plants transformed with a coat protein gene. Other potential methods include the expression of anti-sense viral transcripts in transgenic plants, the application of artificial anti-sense mediated gene regulation to viral systems, and the expression of viral satellite RNAs, RNAs with endoribonuclease activity, antiviral antibody genes, or human interferon genes in plants.

Engineering Resistance to Mixed Virus Infection in a Commercial Potato Cultivar: Resistance to Potato Virus X and Potato Virus Y in Transgenic Russet Burbank

Potato virus X (PVX) and potato virus Y (PVY) infection in potato may result in the loss of certification of seed potatoes and affect quality and yield of potatoes in commercial production. We transformed a major commercial cultivar of potato, Russet Burbank, with the coat protein genes of PVX and PVY. Transgenic plants that expressed both CP genes were resistant to infection by PVX and PVY by mechanical inoculation. One line was also resistant when PVY was inoculated with viruliferous green peach aphids. These experiments demonstrate that CP protection is effective against mixed infection by two different viruses and against mechanical and aphid transmission of PVY.

Effect of protein aggregation state on coat protein-mediated protection against tobacco mosaic virus using a transient protoplast assay

To address the mechanism(s) of protection against tobacco mosaic virus (TMV) infection conferred by expression of the TMV capsid protein (CP) gene in transgenic tobacco plants, a transient protection assay has been developed. Introduction of either purified viral CP or virus inactivated by ultraviolet irradiation into tobacco protoplasts induced a transient protection to challenge virus introduced concomitantly or shortly thereafter. The transient protection was characterized and the effects of different aggregation states of TMV CP were tested in the transient assay system. Tobacco mosaic virus CP preparations composed largely of helical, virus-like, aggregates conferred a less transient protection against TMV and greater protection against a distantly related virus than did preparations composed primarily of smaller aggregates.

Decreased levels of TMV coat protein in transgenic tobacco plants at elevated temperatures reduce resistance to TMV infection

Transgenic tobacco plants that accumulate tobacco mosaic virus (TMV) coat protein (CP) are resistant to TMV infection under standard growth conditions. The amount of CP accumulated and the degree of resistance to TMV were found to be temperature dependent. Exposure to continuous high temperatures (30-35 degrees) results in a sharp decrease in the amount of CP within 6 hr with no further change for at least 6 days. Under these conditions the transgenic plants developed typical systemic disease symptoms when inoculated with TMV although disease development was delayed. Transgenic plants which were moved from 35 to 22 degrees accumulated the normal level of CP within several hours. Transgenic tobacco plants inoculated and held at 35/25 degrees day/night cycles retained resistance to TMV infection. The level of CP mRNA was constant at each temperature and was associated with polyribosomes. On the basis of these results we suggest that the low level of CP under elevated temperature is due to instability of the TMV CP. In contrast, TMV CP levels in transgenic tomato plants also dropped under elevated temperatures yet retained high resistance to TMV.

Evidence that nucleocapsid disassembly and a later step in virus replication are inhibited in transgenic tobacco protoplasts expressing TMV coat protein

Tobacco mosaic virus (TMV)-like pseudovirus particles containing mRNA for Escherichia coli beta-glucuronidase (GUS) were electroporated into mesophyll protoplasts from control or TMV coat protein (CP)-transgenic tobacco (Nicotiana tabacum cv. Xanthi). GUS-particles were expressed 100-fold less efficiently in CP-transformed than in control protoplasts whereas unencapsidated GUS mRNA was expressed only 2.8-fold less efficiently. Lower transient expression of packaged GUS mRNA is probably due to inhibited disassembly of nucleocapsids in CP-transgenic protoplasts. Control and U1 CP-transformed protoplasts are equally susceptible to infection by cowpea strain TMV (Cc), as well as unencapsidated Cc or U1 RNA. In contrast, native or in vitro reconstituted U1 TMV particles result in 5- to 6-fold fewer infected CP-transgenic than control protoplasts. When Cc RNA was transcapsidated in U1 CP in vitro, the hybrid virions were equally infectious in both classes of protoplasts. We conclude that although compatible U1 protein-protein interactions significantly inhibit (GUS) nucleocapsid disassembly in CP-transgenic protoplasts, the endogenous CP must also interfere with a later stage of infection involving the homologous viral RNA.

Plant viruses: a tool-box for genetic engineering and crop protection

Traditionally, plant viruses are viewed as harmful, undesirable pathogens. However, their genomes can provide several useful 'designer functions' or 'sequence modules' with which to tailor future gene vectors for plant or general biotechnology. The majority (77%) of known plant viruses have single-stranded RNA of the messenger (protein coding) sense as their genetic material. Over the past 4 years, improved in vitro transcription systems and the construction of partial or full-length DNA copies of several plant RNA viruses have enhanced our ability to manipulate and study their genomes, particularly in the context of their pathogenic interactions with host plants. Recently, two forms of genetically engineered protection against plant virus infections have been reported. In both, a virus-related 'interfering' molecule was stably introduced into plants via the DNA-transfer mechanism of Agrobacterium tumefaciens. To date, the choice of 'interfering' molecule has been guided by empirical field-observations and each is effective against only a narrow range of closely-related viruses. As yet, we do not fully understand the molecular mechanism(s) responsible for the observed protection. The ability to manipulate the plant-pathogen relationship is a powerful tool to increase our knowledge and improve future strategies for unconventional cropprotection by genetic engineering techniques.

Resistance to TMV in transgenic plants results from interference with an early event in infection

Constitutive expression of the tobacco mosaic virus (TMV) coat protein (CP) gene in transgenic tobacco plants results in inhibition of disease symptom development following inoculation with TMV. Evidence is presented here that this protection is also observed in leaf mesophyll protoplasts isolated from these plants. Protoplasts were resistant to infection by TMV at concentrations of 10 microgram/ml to 1 mg/ml when introduced by either electroporation or polyethylene glycol-mediated inoculation. There was little protection against infection by TMV RNA and the protection was lost as the concentration of TMV RNA in the inoculum increased. When virus was incubated briefly at pH 8.0 prior to inoculation, protection broke down in a manner similar to that observed following RNA inoculation. Analogous results were obtained in experiments with whole plants. Because virus treated in this manner has presumably lost little or no CP, these results suggest that expression of the TMV CP gene in transgenic plant cells prevents TMV from uncoating. A model is presented for the mechanism of this blockage which relates these results to early events in TMV infection.

Sequence and identification of the barley yellow dwarf virus coat protein gene

The nucleotide sequence of the coat protein gene of barley yellow dwarf virus (BYDV, PAV serotype) was determined, and the amino acid sequence was deduced. The open reading frame, encoding a protein of relative molecular mass (Mr) 22,047, was confirmed as the coat protein gene by comparison with amino acid sequences of tryptic peptides derived from dissociated virions. In addition, a fragment of this gene expressed in Escherichia coli produced a product which was recognized by antibodies prepared against purified BYDV virions. An overlapping reading frame encoding an Mr 17,147 protein is contained completely within the coat protein gene.

Transgenic tobacco expressing tobacco streak virus or mutated alfalfa mosaic virus coat protein does not cross-protect against alfalfa mosaic virus infection

Transgenic tobacco plants expressing the coat protein (CP) genes of tobacco streak virus (TSV) and alfalfa mosaic virus (AIMV) were used in studies on cross-protection and genome activation. Plants expressing the TSV CP gene were highly resistant to infection with TSV nucleoproteins but were susceptible to infection with AIMV nucleoproteins. Moreover, these plants could be infected with a mixture of AIMV RNAs 1, 2, and 3 in contrast to the nontransformed control plants. This demonstrates that the endogenously produced TSV CP is able to activate the AIMV genome but does not cross-protect against this virus. Conversely, it was shown that plants expressing the AIMV CP gene did not resist TSV infection. Transgenic tobacco plants transformed with an AIMV CP gene with a frame-shift mutation in the reading frame were found to accumulate viral transcripts to a level similar to that obtained in plants expressing a wild-type AIMV CP gene. However, these plants did not produce detectable amounts of viral protein and showed no resistance to infection with AIMV nucleoproteins in contrast to transgenic plants accumulating wild-type AIMV CP. This demonstrates that it is the CP that is responsible for cross-protection in transgenic plants and not the chimeric CP mRNA.

Nucleotide sequence of the capsid protein gene of potato virus Y (PVY)

The nucleotide sequence of the 3' terminal region of potato virus Y (PVY) was determined. Starting with a poly(A) tail of 18 residues a non-coding region of 335 nucleotides precedes the region encoding for the virus coat protein (cp) 801 nucleotides long ending with a TGA. This region was located by comparing the predicted amino acid sequence with the one determined for the PVY capsid protein by Shukla et al. (1). Both sequences contained 267 amino acids sharing about 94% homology. They differ, however, at several positions presumably due to base transitions within their respective nucleotide sequences. Restriction endonuclease sites in and around the cp coding region were identified.