Analysis of the relative frequencies of the multipartite BNYVV genomic RNAs in different plants and tissues

Multipartite virus genomes are composed of two or more segments, each packaged into an independent viral particle. A potential advantage of multipartitism is the regulation of gene expression through changes in the segment copy number. Soil-borne beet necrotic yellow vein virus (BNYVV) is a typical example of multipartism, given its high number of genomic positive-sense RNAs (up to five). Here we analyse the relative frequencies of the four genomic RNAs of BNYVV type B during infection of different host plants (Chenopodium quinoa, Beta macrocarpa and Spinacia oleracea) and organs (leaves and roots). By successfully validating a two-step reverse-transcriptase digital droplet PCR protocol, we show that RNA1 and -2 genomic segments always replicate at low and comparable relative frequencies. In contrast, RNA3 and -4 accumulate with variable relative frequencies, resulting in distinct RNA1 : RNA2 : RNA3 : RNA4 ratios, depending on the infected host species and organ.

Rhizomania: Hide and Seek of Polymyxa betae and the Beet Necrotic Yellow Vein Virus with Beta vulgaris

The molecular interactions between Polymyxa betae, the protist vector of sugar beet viruses, beet necrotic yellow vein virus (BNYVV), the causal agent of rhizomania, and Beta vulgaris have not been extensively studied. Here, the transmission of BNYVV to sugar beet by P. betae zoospores was optimized using genetically characterized organisms. Molecular interactions of aviruliferous and viruliferous protist infection on sugar beet were highlighted by transcriptomic analysis. P. betae alone induced limited gene expression changes in sugar beet, as a biotrophic asymptomatic parasite. Most differentially expressed plant genes were down-regulated and included resistance gene analogs and cell wall peroxidases. Several enzymes involved in stress regulation, such as the glutathione-S-transferases, were significantly induced. With BNYVV, the first stages of the P. betae life cycle on sugar beet were accelerated with a faster increase of relative protist DNA level and an earlier appearance of sporangia and sporosori in plants roots. A clear activation of plant defenses and the modulation of genes involved in plant cell wall metabolism were observed. The P. betae transcriptome in the presence of BNYVV revealed induction of genes possibly involved in the switch to the survival stage. The interactions were different depending on the presence or absence of the virus. P. betae alone alleviates plant defense response, playing hide-and-seek with sugar beet and allowing for their mutual development. Conversely, BNYVV manipulates plant defense and promotes the rapid invasion of plant roots by P. betae. This accelerated colonization is accompanied by the development of thick-walled resting spores, supporting the virus survival. [Formula: see text] Copyright © 2022 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Agroinoculation of a full-length cDNA clone of cotton leafroll dwarf virus (CLRDV) results in systemic infection in cotton and the model plant Nicotiana benthamiana

Cotton blue disease is the most important viral disease of cotton in the southern part of South America. Its etiological agent, cotton leafroll dwarf virus (CLRDV), is specifically transmitted to host plants by the aphid vector (Aphis gossypii) and any attempt to perform mechanical inoculations of this virus into its host has failed. This limitation has held back the study of this virus and the disease it causes. In this study, a full-length cDNA of CLRDV was constructed and expressed in vivo under the control of cauliflower mosaic virus 35S promoter. An agrobacterium-mediated inoculation system for the cloned cDNA construct of CLRDV was developed. Northern and immunoblot analyses showed that after several weeks the replicon of CLRDV delivered by Agrobacterium tumefaciens in Gossypium hirsutum plants gave rise to a systemic infection and typical blue disease symptoms correlated to the presence of viral RNA and P3 capsid protein. We also demonstrated that the virus that accumulated in the agroinfected plants was transmissible by the vector A. gossypii. This result confirms the production of biologically active transmissible virions. In addition, the clone was infectious in Nicotiana benthamiana plants which developed interveinal chlorosis three weeks postinoculation and CLRDV was detected both in the inoculated and systemic leaves. Attempts to agroinfect Arabidopsis thaliana plants were irregularly successful. Although no symptoms were observed, the P3 capsid protein as well as the genomic and subgenomic RNAs were irregularly detected in systemic leaves of some agroinfiltrated plants. The inefficient infection rate infers that A. thaliana is a poor host for CLRDV. This is the first report on the construction of a biologically-active infectious full-length clone of a cotton RNA virus showing successful agroinfection of host and non-host plants. The system herein developed will be useful to study CLRDV viral functions and plant-virus interactions using a reverse genetic approach.

Agroinoculation of Beet necrotic yellow vein virus cDNA clones results in plant systemic infection and efficient Polymyxa betae transmission

Agroinoculation is a quick and easy method for the infection of plants with viruses. This method involves the infiltration of tissue with a suspension of Agrobacterium tumefaciens carrying binary plasmids harbouring full-length cDNA copies of viral genome components. When transferred into host cells, transcription of the cDNA produces RNA copies of the viral genome that initiate infection. We produced full-length cDNA corresponding to Beet necrotic yellow vein virus (BNYVV) RNAs and derived replicon vectors expressing viral and fluorescent proteins in pJL89 binary plasmid under the control of the Cauliflower mosaic virus 35S promoter. We infected Nicotiana benthamiana and Beta macrocarpa plants with BNYVV by leaf agroinfiltration of combinations of agrobacteria carrying full-length cDNA clones of BNYVV RNAs. We validated the ability of agroclones to reproduce a complete viral cycle, from replication to cell-to-cell and systemic movement and, finally, plant-to-plant transmission by its plasmodiophorid vector. We also showed successful root agroinfection of B. vulgaris, a new tool for the assay of resistance to rhizomania, the sugar beet disease caused by BNYVV.

Sufficient length of a poly(A) tail for the formation of a potential pseudoknot is required for efficient replication of bamboo mosaic potexvirus RNA

RNAs transcribed from a full-length infectious cDNA clone of the bamboo mosaic potexvirus (strain O) genome, pBaMV-O, were infectious to Nicotiana benthamiana plants. Mutant genomes in which the poly(A) tail is absent or replaced by a 3' tRNA-like structure from turnip yellow mosaic virus RNA failed to amplify detectably in N. benthamiana protoplasts. No amplification was detected in protoplasts inoculated with transcripts containing 4, 7, or 10 adenylate residues at the 3' end, whereas transcript inocula with 15 adenylate residues resulted in coat protein accumulation to a level 26% of that resulting from inoculation with transcripts with 25 adenylate residues (designated as wild type). Coat protein accumulation levels of 69 and 98% relative to wild type were observed after inoculation of protoplasts with transcripts bearing poly(A) tails 18 and 22 nucleotides long, respectively. The presence of a putative 3' pseudoknot structure including at least 13 adenylate residues of the 3'-terminal poly(A) tail was supported by enzymatic and chemical structural analysis. The functional relevance of this putative pseudoknot was tested by mutations that affected basepairing within the pseudoknot. These results support the existence of functional 3' pseudoknot that includes part of the 3' poly(A) tail.

Artificial defective interfering RNAs derived from RNA 2 of beet necrotic yellow vein virus

Long internal deletions were introduced into cloned cDNA of beet necrotic yellow vein virus RNAs 1-4 and transcripts containing the deletions were tested for their ability to inhibit replication of viral RNA in Chenopodium quinoa protoplasts and plants. No inhibition was observed with the deletion mutants based on RNAs 1, 3 and 4 but the RNA 2 deletion mutants all provoked a dramatic inhibition of synthesis of viral RNAs 1 and 2.

Mapping the promoter for subgenomic RNA synthesis on beet necrotic yellow vein virus RNA 3

During infection of Tetragonia expansa leaves, RNA 3 of the quadripartite genome of beet necrotic yellow vein virus directs synthesis of a subgenomic RNA (RNA 3sub) which corresponds to the 3'-terminal 600 residues of the RNA 3 molecule. Biologically active run-off transcripts have been prepared from full-length cDNA of RNA 3 cloned behind a bacteriophage T7-RNA polymerase promoter. RNA 3 transcripts carrying deletions in the vicinity of the RNA 3sub initiation site were produced by site-directed mutagenesis at the cDNA level and then tested for their capacity to direct RNA 3sub synthesis in infected leaves. The cis-acting domain essential for normal levels of RNA 3sub production in planta (the 'core' promoter) did not extend in the 5'-direction beyond position -16 relative to the RNA 3sub transcription initiation site. The 3'-boundary of the core promoter domain was located somewhere between positions +100 and +208. Displacement of the promoter domain to an upstream site in RNA 3 produced a new subgenomic RNA starting at or near the predicted upstream site.

Cloned DNA copies of cowpea severe mosaic virus genomic RNAs: infectious transcripts and complete nucleotide sequence of RNA 1

Cowpea severe mosaic virus (CPSMV) is a member of the comovirus group of messenger-sense RNA viruses with bipartite genomes, of which cowpea mosaic virus (CPMV) is the type member. Full-length copies of CPSMV RNA 1 were cloned in plasmids bearing a bacteriophage T7 promoter. Previously, similar clones of CPSMV RNA 2 had been obtained. A 5'-rUAUUAAAAUUUU sequence is common to RNA 1 and RNA 2. From two RNA 1 clones and four RNA 2 clones we excised non-CPSMV sequences so as to provide templates for in vitro transcripts that have only a single guanylate preceding CPSMV RNA sequences. Transcripts from the most active RNA 1 and RNA 2 clones, when mixed, showed about 5% of the infectivity of unfractionated CPSMV RNAs from virions. The longest, 1858 codon open reading frame of the 5957 nt CPSMV RNA 1 extends from an AUG at nt 257 to a UGA termination codon at nt 5831. The calculated molecular weight of the polyprotein is 208,000. Comparisons with the available amino acid residue (aa) sequence information from the complete CPMV RNA 1 sequence and the partial sequence of red clover mottle virus RNA 1 suggest that CPSMV RNA 1 specifies the expected set of five mature proteins: 32K proteinase cofactor, 58K presumed helicase, VPg 5'-linked protein of the genomic RNAs, 24K proteinase, and 87K presumed polymerase, separated by four cleavage sites. Of the determined and deduced cleavage sites of the three RNA 1 polyproteins, only that at the 24K/87K junction has a distinct aa pair in the CPSMV polyprotein. Of the five proteins, VPg and 87K show the greatest similarity between CPSMV and CPMV, with identities of 68 and 55%, respectively. Published mutational analysis of the CPMV 24K proteinase and alignment of aa sequences from three comoviruses suggest that cysteine-168, histidine-40 and glutamic acid-77 form the catalytic triad of the CPSMV 24K proteinase. Results are discussed in the context of the resistance that some cowpea (Vigna unguiculata) lines exhibit against CPMV but not against CPSMV.

cis-active sequences near the 5'-termini of beet necrotic yellow vein virus RNAs 3 and 4

RNAs 3 and 4 of the multicomponent genome of beet necrotic yellow vein virus are dispensable for infection of Chenopodium quinoa leaves. We have used mutagenesis of biologically active RNA 3 transcripts to identify 5'-proximal sequences essential in cis for RNA 3 amplification. One such element, Box I, (nucleotides 283-292) was complementary to the first 10 residues (Box I') following the 5'-terminal cap. A second cis-active element (Box II) was identified between nucleotides 237-244 and was complementary to nucleotides 16-23 (Box II'). Other cis-active sequences exist between Box II' and II but have not been mapped to fine scale. Most sequence substitutions in Boxes I and II or in the 5'-proximal complementary sequences were lethal but compensatory mutations designed to restore Box I/I' or Box II/II' base pairing restored viability, suggesting that secondary structure involving these elements rather than their exact sequence is the critical feature. Transcripts bearing short deletions near residue 200 were replicated but did not assemble into virions, indicating that this region contains or contributes to a cis-active encapsidation signal. Similar experiments with RNA 4 transcript have shown that 5'-proximal cis-essential elements are limited to the first 400 residues of this RNA. Essential subdomains within this region have not been mapped but there are no structures obviously homologous to Boxes I/I' and II/II' of RNA 3.

Efficient cell-to-cell movement of beet necrotic yellow vein virus requires 3' proximal genes located on RNA 2

RNA 2 of beet necrotic yellow vein virus (BNYVV) carries six open reading frames. The four 3' proximal frames encode the proteins P42, P13, P15, and P14. The first three species present homologies to proteins encoded by three overlapping open reading frames (the triple gene block) in potexviruses, carlaviruses, and barley stripe mosaic virus. P14 does not display homology with other known plant viral proteins. The functions of P42, P13, P15, and P14 were investigated by site-directed mutagenesis. Full-length transcripts of wild-type BNYVV RNAs 1 and 2 were infectious when coinoculated to protoplasts or leaves of Chenopodium quinoa. RNA 2 transcripts in which P42, P13, and P15 were prematurely terminated by frameshift mutations replicated in protoplasts (when inoculated with wild-type RNA 1) but were not infectious to leaves, indicating that the triple gene block proteins of BNYVV are essential for viral cell-to-cell spread. Mutations in P14 were not lethal in leaf infections but smaller local lesions and lesser amounts of viral RNA were produced. RNA 2-related subgenomic RNA species of 2.6, 1.4, and 0.7 kb were detected; they presumably direct synthesis of P42, P13, and P14. No species of the length predicted for a P15-specific subgenomic RNA was detected.

Synthesis of full-length transcripts of beet western yellows virus RNA: messenger properties and biological activity in protoplasts

Full-length cDNA of beet western yellows virus genomic RNA has been cloned behind the bacteriophage T7 RNA polymerase promoter of the transcription vector BS(-). The in vitro run-off transcription product obtained in the presence of T7 RNA polymerase and m7GpppG cap has the same messenger properties as natural viral RNA in in vitro translation systems. The full-length transcript was also able to infect Chenopodium quinoa protoplasts inoculated by electroporation. Infection could be followed by the appearance of viral coat protein in the inoculated protoplasts and the de novo synthesis of viral RNA. Site-directed mutagenesis experiments revealed that expression of beet western yellows virus open reading frame 1 and the C-terminal portion of open reading frame 6 were not required for infection of protoplasts. Additional experiments with these mutants and mutants in the other viral open reading frames should provide information concerning the requirements for beet western yellows virus replication and, ultimately, the role of virus genes in other important steps in the virus infection cycle, such as aphid transmission.

cDNAs of beet necrotic yellow vein virus RNAs 3 and 4 are rendered biologically active in a plasmid containing the cauliflower mosaic virus 35S promoter

cDNAs of beet necrotic yellow vein virus RNAs 3 and 4 could be rendered biologically active when they were placed under the control of the cauliflower mosaic virus 35S promoter and polyadenylation signal. Although the 35S in vivo transcripts should have contained up to forty 5' and several hundred 3' nonviral nucleotides, the progeny viral RNAs had the same sizes as in naturally infected sugarbeets. The progeny RNAs did not hybridize with the nonviral sequences indicating that they were apparently not replicated. Deletion and insertion mutants of RNA 3 cDNA clones were also biologically active in plants but a plasmid which contained the cDNA of RNA 3 in antisense orientation was not. The biological activity of plasmid DNAs compared with the corresponding synthetic transcripts is discussed.

Functional analysis of deletion mutants of cucumber mosaic virus RNA3 using an in vitro transcription system

Full-length DNA copies of RNAs 1, 2, and 3 of CMV Y strain (CMV-Y) were cloned downstream of modified phage T7 promoter sequences to obtain infectious RNA transcripts. The small number of extra nonviral nucleotides at the 5' ends considerably decreased the specific infectivity of the transcripts of RNAs 1 and 2 but did not affect that of the RNA3 transcripts. Using the most infective transcripts, up to 45% of tobacco protoplasts could be infected. Various cDNA mutants were constructed from the full-length RNA3 cDNA to give RNA transcripts having deletions in the coding region of the 3a protein or the coat protein. These mutants replicated in tobacco protoplasts but did not produce systemic symptoms on tobacco when inoculated together with transcripts of RNAs 1 and 2. One of the mutants having a small in-frame deletion near the N-terminal region of the coat protein produced local lesions on cowpea and local chlorotic spots on the inoculated leaves of tobacco. These results suggest that both the 3a protein and the coat protein are involved in virus transport, and that viral assembly is associated with long-distance movement of CMV.

Construction and analysis of infectious transcripts synthesized from full-length cDNA clones of both genomic RNAs of pea early browning virus

Full-length cDNA clones of both RNAs of pea early browning virus have been constructed. Synthetic transcripts derived in vitro from these clones are infectious when inoculated onto plants. Electron microscopy revealed the presence of virions in transcript-inoculated plants, and both purified RNA and virions isolated from such plants could be used to infect other plants. Transcripts of RNA1 alone were able to replicate and spread systemically which is a characteristic of members of the tobravirus group of plant viruses.

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.

Techniques in plant molecular biology--progress and problems

Progress in plant molecular biology has been dependent on efficient methods of introducing foreign DNA into plant cells. Gene transfer into plant cells can be achieved by either direct uptake of DNA or the natural process of gene transfer carried out by the soil bacterium Agrobacterium. Versatile gene-transfer vectors have been developed for use with Agrobacterium and more recently vectors based on the genomes of plant viruses have become available. Using this technology the expression of foreign DNA, the functional analysis of plant DNA sequences, the investigation of the mechanism of viral DNA replication and cell to cell spread, as well as the study of transposition, can be carried out. In addition, the versatility of the gene-transfer vectors is such that they may be used to isolate genes not amenable to isolation using conventional protocols. This review concentrates on these aspects of plant molecular biology and discusses the limitations of the experimental systems that are currently available.

Multiplication of beet necrotic yellow vein virus RNA 3 lacking a 3' poly(A) tail is accompanied by reappearance of the poly(A) tail and a novel short U-rich tract preceding it

Beet necrotic yellow vein virus RNAs 1 and 2 but not RNAs 3 and 4 are required for viral multiplication in Chenopodium quinoa leaves. Elimination of the 3' poly(A) tail from RNA 3 transcripts markedly attenuated their ability to be amplified when co-inoculated with RNAs 1 and 2 to this host. Successful multiplication of the tailless RNA 3 was accompanied by the reappearance of new 3' poly(A) tails on the progeny. The evidence suggests that the newly acquired poly(A) sequence results from the action of a poly(A) polymerase rather than recombination with the homologous 3' terminal domains of RNAs 1 or 2. An unexpected feature of these progeny RNA 3 molecules was the presence of a novel short heterogenous U-rich tract separating the poly(A) tail from the 3' end of the heteropolymeric RNA 3 sequence proper.

Immunodetection in vivo of beet necrotic yellow vein virus-encoded proteins

Open reading frames identified on the four genomic RNAs of beet necrotic yellow vein virus were cloned into bacterial expression vectors and resulting cl-fusion proteins expressed in Escherichia coli were used to raise polyclonal antibodies. This set of antisera was used to show the presence of 7 of 9 predicted viral proteins in mechanically inoculated Chenopodium quinoa leaves by the Western blot technique. Viral coat protein (p22) and its readthrough protein p85 encoded by RNA-2 could be detected in all subcellular fractions. Two other RNA-2-encoded proteins, p42 and p13, are predominantly associated with membranous structures. Another RNA-2-encoded protein, p14, as well as the two polypeptides p25 and p31, encoded by RNA-3 and -4, respectively, are soluble proteins. The viral proteins could first be detected about the time lesions became visible and increased thereafter except for p85, in which case the amount of the soluble form decreased with time. No protein could be detected corresponding to the RNA-1-encoded p237 protein or to the p15 species encoded by open reading frame V of RNA-2.

Mapping sequences required for productive replication of beet necrotic yellow vein virus RNA 3

Of the four genome components of beet necrotic yellow vein virus only RNAs 1 and 2 are essential for viral replication in leaves. We have mapped cis-regulatory elements on RNA 3 by introducing deletions into expressible cDNA clones and inoculating leaves with the altered transcripts along with RNAs 1 and 2. Transcripts carrying internal deletions extending to within 69 residues of the 3' poly(A) tail or to within about 300 residues of the 5' terminus were efficiently amplified and encapsidated in vivo. The 3' terminal cis-essential domain can be folded into a secondary structure which is conserved among all four genomic RNAs and which probably contains the minus-strand promoter. RNA 3 transcripts with 75% of the central core of the sequence deleted or replaced by the beta-glucuronidase (GUS) gene were also viable. GUS activity was detected in infected tissue in the latter case.

Construction of full-length cDNA clones of cucumber mosaic virus RNAs 1, 2 and 3: generation of infectious RNA transcripts

Full-length cDNA copies of cucumber mosaic virus (CMV) RNAs 1 and 2 of the Fny strain were constructed from partial cDNA clones and were cloned downstream of bacteriophage T7 promoters. In one pair of clones, transcription proceeded from an unaltered T7 promoter such that in vitro transcripts representing RNAs 1 and 2 contained an additional 17 nucleotides at their 5' termini. In a second pair of clones, the T7 promoter/cDNA junction was altered by oligonucleotide-directed mutagenesis such that the in vitro transcripts contained only an additional G residue at their 5' ends. In addition, a full-length cDNA copy of Fny-CMV RNA 3 was constructed from two overlapping cDNA clones and was cloned downstream of an altered T7 promoter such that the resultant in vitro transcripts also contained only an additional G residue at their 5' ends. In vitro transcripts derived from all clones contained an additional C residue at their 3' ends. In vitro transcripts representing RNAs 1, 2 and 3 which contained an additional residue at each terminus were shown to be infectious together in several hosts of CMV.

Biologically active transcripts of alfalfa mosaic virus RNA3

Transcripts of the bicistronic RNA3 of alfalfa mosaic virus were synthesized using the in vitro T7 run-off transcription system. Synthetic RNA3 containing one additional G nucleotide at the 5' end were found to be infectious when coinoculated with RNA1 and RNA2 and coat protein.

Improvements of the infectivity of in vitro transcripts from cloned cowpea mosaic virus cDNA: impact of terminal nucleotide sequences

Full-length DNA copies of both B- and M-RNA of cowpea mosaic virus (CPMV) were constructed downstream from a T7 promoter. By removal of nucleotides from the promoter sequence, B- and M-RNA-like transcripts with varying numbers of additional nonviral sequences at the 5' end were obtained upon transcription with T7 RNA polymerase. The infectivity of the transcripts in cowpea protoplasts was greatly affected by only a few extra nonviral nucleotides at the 5' end. The addition of about 400 nonviral nucleotides at the 3' end did not have any effect. Using the most infectious transcripts, in 40% of the cowpea protoplasts replication and expression of B-RNA like transcripts were observed and in 10% of the protoplasts both B- and M-RNA-like transcripts multiplied. Moreover, cowpea plants could also be infected with these transcripts. Sequence analysis showed that the 5' terminus of the M-RNA transcripts and the 3' terminus of the B-RNA transcripts were completely restored during replication in plants, including a poly(A) tail of variable length. Swapping experiments have been used to identify an influential point mutation in the coding region for the viral polymerase of a noninfectious B transcript. This experiment demonstrates the potential of the optimized infection system for future analysis of virus-encoded functions.

Biological activity of transcripts synthesized in vitro from full-length and mutated DNA copies of tobacco rattle virus RNA 2

Full-length cDNA clones of RNA 2 of tobacco rattle virus (TRV) strain PLB have been cloned into the transcription vector pPM1. Products of in vitro transcription by Escherichia coli RNA polymerase, either capped or uncapped, were as infectious as native RNA 2 when coinoculated with RNA 1 of TRV strain TCM. At least 70% of the internal sequence of the cDNA could be deleted without reduction of the replication efficiency of the transcripts. Sequences of 340 nucleotides at the 5' end and 405 nucleotides at the 3' end of PLB RNA 2 were found to be sufficient for replication. The encapsidation of deletion mutants of PLB RNA 2 was investigated after addition of native PLB RNA 1 and RNA 2. Accumulation of these mutants was distinguished from that of wild-type RNA 2 by insertion of nonviral sequences in the deleted parts. Three mutant forms of RNA 2 with extensive deletions in the coat protein (CP) gene were replicated but failed to encapsidate, while mutants with nonviral sequences inserted downstream from the CP gene showed a large reduction in replication efficiency.

In vitro synthesis of biologically active beet necrotic yellow vein virus RNA

Beet necrotic yellow vein virus (BNYVV) has a quadripartite plus-strand RNA genome in which the two smallest genome components, RNA 3 and 4, are not necessary for virus multiplication in leaves. Infectious transcripts of BNYVV RNA 3 and 4 have already been described (V. Ziegler-Graff, S. Bouzoubaa, I. Jupin, H. Guilley, G. Jonard, and K. Richards (1988) J. Gen. Virol. 69, 2347-2357). In this paper we describe synthesis of a full-length RNA-1 transcript by bacteriophage T7 RNA polymerase-directed run-off transcription of cloned viral cDNA. A recombinant plasmid containing a full-length cDNA insert of RNA 2 could not be maintained in Escherichia coli. Therefore full-length transcript of RNA 2 was produced by transcription of cDNA ligation products without amplification in bacteria. When inoculated together to leaves of Chenopodium quinoa or Tetragonia expansa the RNA 1 and 2 transcripts were infectious; they also supported multiplication of the BNYVV RNA 3 and 4 transcripts, providing a totally synthetic inoculum of the virus. In one recombinant clone of RNA 2 a point mutation causing an arginine to serine substitution at position 119 of the viral coat protein was discovered. The mutation was detected because the resulting coat protein had altered electrophoretic mobility. RNA 2 transcripts containing this mutation were infectious but viral RNA was not encapsidated. The mutation also interfered with long distance movement of the virus in spinach, presumably as a consequence of the packaging deficiency.

Comparison of enzyme-linked immunosorbent assay (ELISA) with dot hybridization using 32P- or 2-acetylaminofluorene (AAF)-labelled cDNA probes for the detection and characterization of beet necrotic yellow vein virus

Beet Necrotic Yellow Vein Virus (BNYVV) was detected by enzyme-linked immunosorbent assay (ELISA) and RNA/DNA dot hybridization using either radiolabelled or non-radioactive probes. Dot hybridization specifically distinguished isolates that could not be distinguished by ELISA. The detection thresholds for ELISA, hybridization with non-radioactive probes and hybridization with radiolabelled probes were 2 ng, 0.2 ng, 0.02 ng of purified virus, respectively. Dot hybridization with non-radioactive probes could be performed on crude infected beet root extracts, thus providing a useful tool for monitoring BNYVV infection and for routine testing in plant breeding programs.