Expression of alfalfa mosaic virus RNA 4 in transgenic plants confers virus resistance

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.

Phosphorylation of alfalfa mosaic virus movement protein in vivo

The 32-kDa movement protein, P3, of alfalfa mosaic virus (AMV) is essential for cell-to-cell spread of the virus in plants. P3 shares many properties with other virus movement proteins (MPs); however, it is not known if P3 is posttranslationally modified by phosphorylation, which is important for the function of other MPs. When expressed in Nicotiana tabacum, P3 accumulated primarily in the cell walls of older leaves or in the cytosol of younger leaves. When expressed in Pischia pastoris, P3 accumulated primarily in a soluble form. Metabolic labeling indicated that a portion of P3 was phosphorylated in both tobacco and yeast, suggesting that phosphorylation regulates the function of this protein as it does for other virus MPs.

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.

Control of virus diseases in soybeans

Soybean, one of the world's most important sources of animal feed and vegetable oil, can be infected by numerous viruses. However, only a small number of the viruses that can potentially infect soybean are considered as major economic problems to soybean production. Therefore, we consider management options available to control diseases caused by eight viruses that cause, or have the potential to cause, significant economic loss to producers. We summarize management tactics in use and suggest direction for the future. Clearly, the most important tactic is disease resistance. Several resistance genes are available for three of the eight viruses discussed. Other options include use of virus-free seed and avoidance of alternative virus hosts when planting. Attempts at arthropod vector control have generally not provided consistent disease management. In the future, disease management will be considerably enhanced by knowledge of the interaction between soybean and viral proteins. Identification of genes required for soybean defense may represent key regulatory hubs that will enhance or broaden the spectrum of basal resistance to viruses. It may be possible to create new recessive or dominant negative alleles of host proteins that do not support viral functions but perform normal cellular function. The future approach to virus control based on gene editing or exploiting allelic diversity points to necessary research into soybean-virus interactions. This will help to generate the knowledge needed for rational design of durable resistance that will maximize global production.

Transgenic resistance to Bamboo mosaic virus by expression of interfering satellite RNA

Plant genetic engineering has broadened the options for plant virus resistance and is mostly based on pathogen-derived resistance. Previously, we have shown that interfering satellite RNA (satRNA) of Bamboo mosaic virus (satBaMV) greatly reduces Bamboo mosaic virus (BaMV) accumulation and BaMV-induced symptoms in co-inoculated plants. Here, we generated a nonviral source of virus-resistant transgenic Nicotiana benthamiana and Arabidopsis thaliana by introducing interfering satBaMV. Asymptomatic transgenic N. benthamiana lines were highly resistant to BaMV virion and viral RNA infection, and the expression of the transgene BSL6 was higher in asymptomatic than mildly symptomatic lines. In addition, BaMV- and satBaMV-specific small RNAs were detectable only after BaMV challenge, and their levels were associated with genomic viral RNA or satRNA levels. By transcriptomic analysis, the salicylic acid (SA) signalling pathway was not induced in satBaMV transgenic A. thaliana in mock conditions, suggesting that two major antiviral mechanisms, RNA silencing and SA-mediated resistance, are not involved directly in transgenic satBaMV-mediated BaMV interference. In contrast, resistance is associated with the level of the interfering satBaMV transgene. We propose satBaMV-mediated BaMV interference in transgenic plants by competition for replicase with BaMV.

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.

Coat protein gene sequence analysis of potato virus X and potato virus Y: conserved regions to design gene silencing cassette

Potato virus X(PVX) and Potato virus Y(PVY) are two of the three most prevalent viruses that cause significant yield declines in potato. Twenty-seven PVX and thirty-seven PVY accessions were analyzed for nucleotide sequence variation of the coat protein gene. The average and variance of genetic distance for PVX were estimated at 0.118 and 0.004 and 0.118 and 0.005 for PVY using the neighbour joining method. Results of phylogenetic trees and their certification via stepwise discriminant analysis led us to classify of PVX sequences in four groups and PVY sequences in three groups. One purpose of this project was to determine suitable conserved regions to make of gene silencing constructs. Length of identified conserved regions were enough to silence of the virus coat protein genes on infected plants, many of which were located consequently with short gap spacers. In this term, some of groups were divided into subgroups to obtain conserved regions under minimum length of25 nt, enough length to design specific diagnostic-primers.

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.

Characterization of resistance mechanism in transgenic Nicotiana benthamiana containing Turnip crinkle virus coat protein

Two transgenic lines, of Nicotiana benthamiana expressing Turnip crinkle virus (TCV)-coat protein (CP) gene with contrasting phenotype, the highest (#3) and the lowest (#18) CP expressers, were selected and challenged with the homologous TCV. The former, the highest expresser, showed nearly five times more CP expression than the latter. Progenies of #3 and #18 lines showed 30 and 100% infection rates, respectively. The infected progenies of #3 line showed mild and delayed symptom with TCV. This is a coat protein-mediated resistance (CP-MR), and its resistance level is directly proportional to CP transgene expression. However, CP-MR of the transgenic plants was specific only for TCV but not for heterologous viruses. Newly growing leaves of those infected progenies of #3 line did not show any visible symptoms at 4-week post-inoculation (wpi) with TCV, suggesting a reversal from infection. This was confirmed by RT-PCR analysis with the disappearance of the target at 4 wpi. This is a case of RNA-mediated resistance, and a threshold level of transgene expression may be needed to achieve the silent state. To confirm the RNA silencing, we infiltrated Agrobacterium carrying TCV-CP into leaves of progenies of #3 and performed RT-PCR analysis. The results indicate that TCV-CP's suppressor activity against RNA silencing itself can be silenced by the homologous expression of TCV-CP in the transgenic plants. The transgenic plants containing TCV-CP seem to be a model system to study viral protection mediated by a combination of protein and RNA silencing.

Coat protein-mediated resistance against an Indian isolate of the Cucumber mosaic virus subgroup IB in Nicotiana benthamiana

Coat protein (CP) -mediated resistance against an Indian isolate of the Cucumber mosaic virus (CMV) subgroup IB was demonstrated in transgenic lines of Nicotiana benthamiana through Agrobacterium tumefaciens-mediated transformation. Out of the fourteen independently transformed lines developed, two lines were tested for resistance against CMV by challenge inoculations. The transgenic lines exhibiting complete resistance remained symptomless throughout life and showed reduced or no virus accumulation in their systemic leaves after virus challenge. These lines also showed virus resistance against two closely related strains of CMV. This is the first report of CP-mediated transgenic resistance against a CMV subgroup IB member isolated from India.

Molecular analysis of Korean isolate of barley yellow mosaic virus

The complete sequences of both RNAs of an isolate of barley yellow mosaic virus (BaYMV) from Haenam, Korea, were determined. RNA1 is 7639 nucleotides long [excluding the 3'-poly(A)], and codes for a 270 kDa polyprotein of 2411 amino acids which contains the capsid protein (CP) at the C terminus and seven putative non-structural proteins. RNA2 is 3582 nucleotides long and codes for a polyprotein of 890 amino acids, which contains a 28 kDa putative proteinase (P1) and a 73 kDa polypeptide (P2). The whole sequences of Korean isolate (BaYMV-K) closely resembled those of an isolate from Japan (BaYMV-J) (99.6 identical nucleotides for RNA1; 99.4 for RNA2) and china (BaYMV-C) (96.7 and 96.2%, respectively) than from Germany (BaYMV-G) (93.6 and 90.4%, respectively). The greatest differences between the BaYMV-K and BaYMV-J isolates were in the 3'-NCRs of RNA1 and 5' NCRs of RNA2 and there were also some other regions of difference in Nib Pro (RNA1) and P1 (RNA2). Further, the phylogenetic analysis of CP region showed that Asian and European isolates formed distinct clusters. However, molecular variations between isolates could not be linked to earlier results showing differences in cultivar response.

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.

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.

Tobacco plants transformed with a modified coat protein of tomato mottle begomovirus show resistance to virus infection

ABSTRACT Tobacco plants (Nicotiana tabacum 'Xanthi') were transformed with a binary vector containing the coat protein gene of tomato mottle begomo-virus (ToMoV) modified by the deletion of 30 nucleotides in the 5' end. The R(1) generation was screened for resistance to ToMoV by inoculation with viruliferous whiteflies. Fifteen days after inoculation, symptom development was recorded weekly for up to 120 days using a visual scale, and ToMoV infection was confirmed by polymerase chain reaction and enzyme-linked immunosorbent assay. The response to high inoculation levels of ToMoV varied and ranged from susceptibility to immunity. The transgene transcript was detected by northern blot analysis; however, the transgene product could not be detected by protein blot analysis using antisera reactive with ToMoV coat protein. The lack of detection of the transgene product in resistant plants suggests that it is not involved in eliciting the resistance response and that resistance may be mediated by the transgene transcript.

Functional significance of three basic N-terminal amino acids of alfalfa mosaic virus coat protein

Infection of tobacco protoplasts with mutant alfalfa mosaic virus (AMV) RNAs indicated that three basic amino acids in the N-terminus of AMV coat protein are important for the biological activity of the coat protein in the beginning of infection. Substitution of alanines for lysines at position 14 or 17 in the coat protein resulted in a 5- or 10-fold reduction in the activity of the protein, respectively. However, substitution of alanine for arginine at position 18 entirely abolished activity. Arginine 18 was also required for the coat protein to bind to the 3' noncoding region of the virus RNA in vitro, whereas lysine 14 or 17 was not required. Thus, these results indicate that arginine 18 is essential for the activity of the coat protein in early infection and that binding of the coat protein to AMV RNA correlates with activity.

Genetic modification of proteins in food

Plant breeders have been extremely successful in improving the quality and yield of the major crops, while maintaining the safety of the food supply. This success has been achieved with very little understanding of the biochemical mechanisms that determine the selected traits. Each time a cross is made, tens of thousands of genes are mixed and reassorted, largely at random. The skill of the breeder lies in selecting the lines to be crossed and recognizing the preferred progeny, discarding those that lack the desirable trait or exhibit undesirable properties. With the advent of recombinant DNA technology, breeders have not only extended the range of biological materials from which genes can be accessed, but have also gained new insights into genome organization and gene structure as well as the nature and function of the proteins that those genes encode. Such knowledge affords exquisite specificity in altering the genetic makeup of new crop varieties. For example, resistance to insect pests can now be achieved through the addition of a single well-characterized gene, instead of introducing thousands of unwanted genes from a wild relative that code for uncharacterized and possibly toxic proteins that must be eliminated by generations of backcrossing and screening to recover a commercially acceptable insect-resistant line. The technology also affords unique opportunities to identify the individual components of foods that may cause allergies, and to remove them from food, or change them, so that the food can be consumed safely. A number of commercial products derived through genetic engineering have been approved through regulatory processes that address environmental and food safety concerns. These products are available, or will shortly be available, to growers, producers, and consumers. They will provide foods and feeds that are produced with fewer chemical inputs and have improved nutritional composition and quality.

CMV protecton in transgenic cucumber plants with an introduced CMV-O cp gene

We introduced the CMV-O coat-protein gene into cucumber plants, using a Ti-Agrobacterium-mediated transformation system, with the aim of producing cucumber plants with CMV resistance. The RNA transcripts from the CaMV 35s-cp gene could be detected in the leaves of the R0 transgenic cucumber plants, as well as in the epicotyls containing two cotyledons of transgenic progeny plants, by Northern-blot analysis; but the presence of coat protein originating from the CaMV 35s-cp gene could not be detected in the cotyledons or leaves of R0 and transgenic progeny plants by Westernblot analysis. The progenies of a cross between cv "Sharp 1" and transgenic plants (pure line "1021") possessing the cp gene displayed strong resistance to inoculation of the CMV-Y strain, although both the control cv "Sharp 1" and segregated cp (-) plants displayed many spotted disease symptons on their leaves 5-6 days after CMV-Y inoculation on the cotyledons. The control "1021" had a slight tolerance toward CMV-Y inoculation. The transgenic cucumber plants displayed the absence of resistance to ZYMV. However, transgenic plants showed a reduced degree of disease symptom development following a double inoculation of CMV and ZYMV. The CMV resistance of the present transgenic cucumber plants seems to be due to the synergism of the slight CMV tolerance in the pure line "1021" and the protection against CMV afforded by the introduction of the CMV cp gene. This leads to the possibility of producing cucumber plants with the agronomic characteristics of very strong CMV resistance by the combination of genotypes of cucumbers and the CMV cp gene. The transgenic plants possessing the cp gene should thus be useful as a genetic source for producing cucumber plants with the agronomic characteristic of CMV resistance.

Small-scale field tests with transgenic potato, cv. Bintje, to test resistance to primary and secondary infections with potato virus y

The coat protein (CP) gene of the potato virus Y (PVY) strain N605 has been cloned into a plant binary expression vector and introduced into the potato variety Bintje. The transformed lines, Bt6, that contained two copies of the CP gene showed complete resistance to the homologous strain PVY-N605 and a good resistance to the related strain PVY-O803 in the greenhouse. The good resistance of Bt6 to primary and secondary infections by PVY was confirmed in two successive field tests where the virus was transmitted by its natural aphid vector.

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.

Alphavirus expression systems: Applications to mosquito vector studies

In this review, Steve Higgs, Ann Powers and Ken Olson describe how alphavirus expression systems, based on infectious cDNA clones of Sindbis virus, constitute a novel RNA virus delivery system suitable for the efficient expression of heterologous gene products or RNA sequences in mosquito cells or adult mosquitoes. The technique permits ready assessment of molecular genetic-based methods of intracellular interference to infection and provides a powerful new tool for molecular biological studies in arthropods.

Efficient pathogen-derived resistance induced by integrated potato virus Y coat protein gene in tobacco

The coat protein (CP) gene from potato virus Y (Hungarian isolate, PVY-H) was engineered into Agrobacterium tumefaciens binary vector for expression in different tobacco lines. Three different Nicotiana tabacum breeding lines were transformed and the integration of the CP gene was confirmed by PCR technique using genomic DNA preparations. The transcription and expression of the integrated CP gene was detected by Northern and Western blots. Pathogen-derived resistance was demonstrated by inoculation of the R1 progeny of the transformed lines with purified PVY-H. The efficiency of protection varied between different transgenic plants ranging from almost complete to no protection. Five CP expressing tobacco lines were resistant to challenge infection with PVY-H as indicated by attenuation or absence of symptom development associated with reduction or lack of detectable virus accumulation. Data from Western blots showed that there is no correlation between the level of the expressed CP and the extent of protection. This suggests that the mechanism of the observed resistance is independent of the level of CP accumulation in the transgenic tobacco plants.

The coat protein of white clover mosaic potexvirus has a role in facilitating cell-to-cell transport in plants

Functions of the coat protein of white clover mosaic potexvirus (WCIMV) were investigated using C-terminal deletion mutants. Whereas plants inoculated with RNA transcripts of a full-length wild-type clone of WCIMV produced typical infections, plants inoculated with transcripts of each mutant did not produce symptoms, and viral RNA species were not detected by Northern analysis. The mutants were able to replicate in protoplasts, although, relative to the wild-type RNA profile, the level of genomic RNA, but not subgenomic RNA, was reduced. These results indicate a role for the coat protein in efficient cell-to-cell transport in plants. Virus-like particles were detected in protoplast extracts inoculated with transcripts of a mutant in which the coat protein was truncated by 31 amino acids. This result suggests that the lack of detectable transport in plants was not due solely to a failure of the mutants to form virus particles. Possible roles for the coat protein in transport and replication are discussed. A 6-kDa open reading frame, internal to the coat protein gene, was shown by mutational analysis not to be essential for replication or transport.

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.

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.

Coat protein and protease activity as in vitro translation products of potato carlavirus M RNA

Genomic-size RNA isolated from purified potato carlavirus M (PVM) was translated in both the reticulocyte and the wheat germ cell-free, messenger-dependent systems. The PVM RNA translated the same set of major products in both in vitro systems. The Mr values of the most prominent polypeptides observed consistently were 185,000 (P185), 147,000 (P147), 94,000 (P94), 87,000 (P87), 72,000 (P72), 67,000 (P67), 52,000 (P52), 46,000 (P46), 35,000 (P35) and 25,000 (P25). Relatively low amounts of a translation product of Mr 200,000 (P200) were often detectable in both systems. The P35 polypeptide displayed the same molecular weight and one-dimensional peptide map as the virus coat protein (CP), and was precipitated by antibodies raised against PVM and PVM CP. The kinetics of appearance of the in vitro synthesized polypeptides suggested that primary translation products of high molecular weight undergo post-translational proteolytic cleavage.

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.

Cloning of the coat protein gene from beet necrotic yellow vein virus and its expression in sugar beet hairy roots

Expression of the beet necrotic yellow vein virus (BNYVV) coat protein (CP) gene in transgenic sugar beet hairy roots was accomplished as a step towards CP-mediated virus resistance. A cDNA for the CP gene and its 5' terminal untranslated leader sequence was prepared from BNYVV RNA, using two oligodeoxynucleotides to prime the synthesis of both strands. Second-strand synthesis and amplification of the cDNA were done by Taq DNA polymerase chain reactions. Run-off transcripts of the cloned cDNA sequence were obtained and translated in vitro, yielding immunoreactive CP. A binary vector construction containing the CP gene under the control of the 35S promoter of cauliflower mosaic virus was prepared and used for Agrobacterium rhizogenes-mediated transformation of sugar beet tissue. Stable integration and expression of the CP gene in sugar beet hairy roots was demonstrated by Southern, Northern, and Western blot analysis, respectively.

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.

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.

Local and systemic spread of tobacco mosaic virus in transgenic tobacco

Expression of a chimeric gene encoding the coat protein (CP) of tobacco mosaic virus (TMV) in transgenic tobacco plants confers resistance to infection by TMV. We investigated the spread of TMV within the inoculated leaf and throughout the plant following inoculation. Plants that expressed the CP gene [CP(+)] and those that did not [CP(-)] accumulated equivalent amounts of virus in the inoculated leaves after inoculation with TMV-RNA, but the CP(+) plants showed a delay in the development of systemic symptoms and reduced virus accumulation in the upper leaves. Tissue printing experiments demonstrated that if TMV infection became systemic, spread of virus occurred in the CP(+) plants essentially as it occurred in the CP(-) plants although at a reduced rate. Through a series of grafting experiments, we showed that stem tissue with a leaf attached taken from CP(+) plants prevented the systemic spread of virus. Stem tissue without a leaf had no effect on TMV spread. All of these findings indicate that protection against systemic spread in CP(+) plants is caused by one or more mechanisms that, in correlation with the protection against initial infection upon inoculation, result in a phenotype of resistance to TMV.

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.