Cucumber mosaic virus contains a functionally divided genome

A Simplified Multiplex PCR Assay for Simultaneous Detection of Six Viruses Infecting Diverse Chilli Species in India and Its Application in Field Diagnosis

Chilli is infected by at least 65 viruses globally, with a mixed infection of multiple viruses leading to severe losses being a common occurrence. A simple diagnostic procedure that can identify multiple viruses at once is required to track their spread, initiate management measures and manage them using virus-free planting supplies. The present study, for the first time, reports a simplified and robust multiplex PCR (mPCR) assay for the simultaneous detection of five RNA viruses, capsicum chlorosis orthotospovirus (CaCV), chilli veinal mottle virus (ChiVMV), large cardamom chirke virus (LCCV), cucumber mosaic virus (CMV), and pepper mild mottle virus (PMMoV), and a DNA virus, chilli leaf curl virus (ChiLCV) infecting chilli. The developed mPCR employed six pairs of primer from the conserved coat protein (CP) region of the respective viruses. Different parameters viz., primer concentration (150-450 nM) and annealing temperature (50 °C), were optimized in order to achieve specific and sensitive amplification of the target viruses in a single reaction tube. The detection limit of the mPCR assay was 5.00 pg/µL to simultaneously detect all the target viruses in a single reaction, indicating a sufficient sensitivity of the developed assay. The developed assay showed high specificity and showed no cross-amplification. The multiplex PCR assay was validated using field samples collected across Northeast India. Interestingly, out of 61 samples collected across the northeastern states, only 22 samples (36%) were positive for single virus infection while 33 samples (54%) were positive for three or more viruses tested in mPCR, showing the widespread occurrence of mixed infection under field conditions. To the best of our knowledge, this is the first report on the development and field validation of the mPCR assay for six chilli viruses and will have application in routine virus indexing and virus management.

A Sensitized Genetic Screen to Identify Novel Components and Regulators of the Host Antiviral RNA Interference Pathway

RNA interference (RNAi) acts as a natural defense mechanism against virus infection in plants and animals. Much is known about the antiviral function of the core RNAi pathway components identified mostly by genetic screens based on specific RNAi of cellular mRNAs. Here we describe a sensitized genetic screening system for the identification of novel components and regulators in the antiviral RNAi pathway established in the model plant species Arabidopsis thaliana. Our genetic screen identifies antiviral RNAi (avi)-defective Arabidopsis mutants that develop visible disease symptoms after infection with CMV-∆2b, a Cucumber mosaic virus mutant deficient in the expression of its viral suppressor of RNAi. Loss of RNAi suppression renders CMV-∆2b highly susceptible to antiviral RNAi so that it replicates to high levels and induces disease development only in avi mutants. This chapter provides the methods for the propagation of CMV-∆2b, preparation of the mutant plants for virus inoculation, identification and characterization of avi mutants, and cloning of the genes responsible for the mutant phenotype by either the genetic linkage to T-DNA insertion or a mapping-by-sequencing approach.

Development of a molecular assay for the detection of Cucumber mosaic virus and the discrimination of its subgroups I and II

A nucleic acid based test for the detection of the economically important plant virus Cucumber mosaic virus (CMV) based on the Luminex xTAG technology was developed. This technology has the advantage of allowing the simultaneous detection of various targets. Applying this method, we prove the presence of CMV in general and differentiate between its two subgroups I and II for which significant differences concerning severity of symptoms and virulence have been reported. For the development of the test procedure the coat protein gene sequences of 29 CMV isolates were cloned, sequenced and classified into subgroups. Sequences from GenBank were used to design primers. Additionally, a subgroup specific ELISA was conducted for comparison. This work is part of a project which aims to develop a test for the simultaneous detection of various plant pathogens (viral, bacterial and fungal) in plant material.

Genetic structure and molecular variability of Cucumber mosaic virus isolates in the United States

Cucumber mosaic virus (CMV) has a worldwide distribution and the widest host range of any known plant virus. From 2000 to 2012, epidemics of CMV severely affected the production of snap bean (Phaseulos vulgaris L.) in the Midwest and Northeastern United States. Virus diversity leading to emergence of new strains is often considered a significant factor in virus epidemics. In addition to epidemics, new disease phenotypes arising from genetic exchanges or mutation can compromise effectiveness of plant disease management strategies. Here, we captured a snapshot of genetic variation of 32 CMV isolates collected from different regions of the U.S including new field as well as historic isolates. Nucleotide diversity (π) was low for U.S. CMV isolates. Sequence and phylogenetic analyses revealed that CMV subgroup I is predominant in the US and further showed that the CMV population is a mixture of subgroups IA and IB. Furthermore, phylogenetic analysis suggests likely reassortment between subgroups IA and IB within five CMV isolates. Based on phylogenetic and computational analysis, recombination between subgroups I and II as well as IA and IB in RNA 3 was detected. This is the first report of recombination between CMV subgroups I and II. Neutrality tests illustrated that negative selection was the major force operating upon the CMV genome, although some positively selected sites were detected for all encoded proteins. Together, these data suggest that different regions of the CMV genome are under different evolutionary constraints. These results also delineate composition of the CMV population in the US, and further suggest that recombination and reassortment among strain subgroups does occur but at a low frequency, and point towards CMV genomic regions that differ in types of selection pressure.

Cucumber mosaic virus as drug delivery vehicle for doxorubicin

Taking advantage of the unique structure feature of cucumber mosaic virus (CMV), we have anchored folic acid (FA) as targeting moiety on the rigid CMV capsid and loaded significant amount of doxorubicin (Dox) into the interior cavity of CMV through the formation of Dox-RNA conjugate to provide a nanosized control delivery system for cancer therapy. The FA-CMV-Dox assemblies were characterized using transmission electron microscopy and size exclusion chromatography, which disclose that they have comparable size and morphology to the native CMV particles. The Dox-loaded viral particles exhibit sustained in vitro Dox release profile over 5 days at physiological pH but can be liberated from the conjugates with the presence of elevated level of RNase. The in vitro effects of folate receptor (FR)-targeted CMV-Dox nanoconjugates on cellular internalization and cell proliferation were evaluated by live-cell imaging, MTT and TUNEL assay, respectively, in mouse cardiomyocytes and FR over expression OVCAR-3 tumor cells. The in vivo efficacy was also investigated in the OVCAR-3 BALB/c nude mouse xenograft model through histological alterations and TUNEL assessment. The FA-CMV-Dox particles significantly decrease the accumulation of Dox in the nuclei of mouse myocardial cells and improve the uptake of Dox in the ovarian cancer, leading to less cardiotoxicity and enhanced antitumor effect. We believe that CMV offers a new way to fabricate nanosized drug delivery vehicles.

A cucumber mosaic virus based expression system for the production of porcine circovirus specific vaccines

Potential porcine circovirus type 2 (PCV2) capsid protein epitopes, suitable for expression on the surface of cucumber mosaic virus (CMV) particles were determined by a thorough analysis of the predicted PCV capsid protein structure. The ab initio protein structure prediction was carried out with fold recognition and threading methods. The putative PCV epitopes were selected on the basis of PCV virion models and integrated into the plant virus coat protein, after amino acid position 131. The recombinants were tested for infectivity and stability on different Nicotiana species and stable recombinant virus particles were purified. The particles were tested for their ability to bind to PCV induced porcine antibodies and used for specific antibody induction in mice and pigs. The results showed that PCV epitopes expressed on the CMV surface were recognized by the porcine antibodies and they were also able to induce PCV specific antibody response. Challenge experiment with PCV2 carried out in immunized pigs showed partial protection against the infection. Based on these results it was concluded that specific antiviral vaccine production for the given pathogen was feasible, offering an inexpensive way for the mass production of such vaccines.

Untranslated regions of diverse plant viral RNAs vary greatly in translation enhancement efficiency

BACKGROUND

Whole plants or plant cell cultures can serve as low cost bioreactors to produce massive amounts of a specific protein for pharmacological or industrial use. To maximize protein expression, translation of mRNA must be optimized. Many plant viral RNAs harbor extremely efficient translation enhancers. However, few of these different translation elements have been compared side-by-side. Thus, it is unclear which are the most efficient translation enhancers. Here, we compare the effects of untranslated regions (UTRs) containing translation elements from six plant viruses on translation in wheat germ extract and in monocotyledenous and dicotyledenous plant cells.

RESULTS

The highest expressing uncapped mRNAs contained viral UTRs harboring Barley yellow dwarf virus (BYDV)-like cap-independent translation elements (BTEs). The BYDV BTE conferred the most efficient translation of a luciferase reporter in wheat germ extract and oat protoplasts, while uncapped mRNA containing the BTE from Tobacco necrosis virus-D translated most efficiently in tobacco cells. Capped mRNA containing the Tobacco mosaic virus omega sequence was the most efficient mRNA in tobacco cells. UTRs from Satellite tobacco necrosis virus, Tomato bushy stunt virus, and Crucifer-infecting tobamovirus (crTMV) did not stimulate translation efficiently. mRNA with the crTMV 5' UTR was unstable in tobacco protoplasts.

CONCLUSIONS

BTEs confer the highest levels of translation of uncapped mRNAs in vitro and in vivo, while the capped omega sequence is most efficient in tobacco cells. These results provide a basis for understanding mechanisms of translation enhancement, and for maximizing protein synthesis in cell-free systems, transgenic plants, or in viral expression vectors.

Virus diseases in lettuce in the Mediterranean basin

Lettuce is frequently attacked by several viruses causing disease epidemics and considerable yield losses along the Mediterranean basin. Aphids are key pests and the major vectors of plant viruses in lettuce fields. Lettuce mosaic virus (LMV) is probably the most important because it is seed-transmitted in addition to be transmissible by many aphid species that alight on the crop. Tomato spotted wilt virus (TSWV) is another virus that causes severe damage since the introduction of its major vector, the thrips Frankliniella occidentalis. In regions with heavy and humid soils, Lettuce Mirafiori big-vein virus (LMBVV) can also produce major yield losses.

Virus diseases of peas, beans, and faba bean in the Mediterranean region

In the Mediterranean region, pea, bean, and faba bean production is affected by around 17 major viruses. These viruses do not have the same ecology and consequently require a variety of different preventive measures to control them. Some of these viruses have a narrow host range, such as Faba bean necrotic yellows virus (FBNYV), and others, such as Alfalfa mosaic virus (AMV) and Cucumber mosaic virus (CMV), a very wide host range. Such features are important when identifying sources of virus inoculum in a region, and the vectors can transmit viruses from natural reservoirs to the crop plants. Some of these viruses are seed borne and, consequently, can be disseminated long distances through infected seeds. Crop losses caused by these viruses are variable, depending on the sensitivity and susceptibility of the crop to infection. Host resistance genes have been identified for some of these viruses, but in others, such as FBNYV, no resistance genes in faba bean have been identified yet. Significant progress was made in developing precise methods for the identification of these viruses, and new virus problems are being identified every year. This chapter is not intended to be a review for pea, bean, and faba bean viruses, but rather focuses on the major viruses which affect these crops in the Mediterranean basin with focus on the progress made over the past two decades.

Characterisation of a satellite RNA of Cucumber mosaic virus that induces chlorosis in Capsicum annuum

The presence of Cucumber mosaic virus (CMV) satellite RNA dramatically changes symptoms on some hosts. A satellite RNA present in a strain of CMV (PepY-CMV) that induced chlorosis in pepper (Capsicum annuum) was shown to induce chlorosis in pepper in combination with another strain (Fny-CMV) that by itself induced a green mosaic symptom. The location of sequences within the PepY satellite RNA (PepY-satRNA) of CMV that conferred the ability to induce chlorosis on pepper plants were analyzed by exchanging sequence domains between cDNA clones of PepY-satRNA and an attenuated mosaic satellite RNA (Paf-satRNA), as well as site-directed mutagenesis of various clusters of the 22-nt sequence differences between the two satellite RNAs in the delimited central domain. The symptoms induced by site-directed mutants of PepY-satRNA and Paf-satRNA in the presence of Fny-CMV demonstrated an insertion within PepY-satRNA of 11 nt at positions 86-96 relative to Paf-satRNA determined the chlorosis-inducing phenotype. Within the chlorosis-inducing domain, deletion of nucleotides did not affect the satRNA replication but abolished the ability of PepY-satRNA to elicit chlorosis symptom. Conversely, a mutant satellite RNA derived from Paf-satRNA in which eleven nucleotides were inserted indicated that sequences of 11 nucleotides were found to be sufficient for chlorosis induction in pepper.

Satellite tobacco ringspot virus RNA: A subset of the RNA sequence is sufficient for autolytic processing

The satellite RNA of tobacco ringspot virus depends upon tobacco ringspot virus for its replication and source of coat protein. The satellite RNA reduces virus accumulation and the severity of virus-induced symptoms. Repetitive sequence, dimeric, and higher forms of the satellite RNA are known to autolytically process to form biologically active monomeric RNA of 359 nucleotide residues [Prody, G. A., Bakos, J. T., Buzayan, J. M., Schneider, I. R. & Bruening, G. (1986) Science 231, 1577-1580], with a 5'-hydroxyl and a 2',3'-cyclic phosphodiester as the new terminal groups. We show here that transcripts of full-length and truncated DNA clones of the satellite RNA sequence also process in a nonenzymic reaction. One such transcript was an RNA that has about one-fourth of the satellite RNA sequence, representing the 3'-terminal and 5'-terminal portions of monomeric RNA joined in the junction that is cleaved in dimeric RNA. This RNA autolytically processed more efficiently than molecules with a larger proportion of the satellite RNA nucleotide sequence.

Biological activity of T7 transcripts of a prototype clone and a sequence variant clone of a satellite RNA of cucumber mosaic virus

Molecular cloning of the (D)CARNA 5 (previously known as n-CARNA 5) necrosis-inducing satellite RNA of cucumber mosaic virus produced a prototype clone (pDsat4) and a sequence variant clone (pDsat1). pDsat1 contained 10 nucleotide changes between positions 70 and 160 which rendered that region identical to the corresponding region of a satellite RNA which does not induce necrosis. T7 RNA polymerase transcripts of each clone replicated in both tobacco and tomato, and the progeny satellite RNAs did not retain the 57-nucleotide non-satellite sequence at the 5' ends of the T7 transcripts. RNase T1 fingerprint analysis of both T7 transcripts and progeny satellite RNAs proved that the satellite sequence portion of each transcript was faithfully replicated in tobacco, and the variations in pDsat1 relative to pDsat4 were maintained. Replication of transcripts of either pDsat4 or pDsat1 in tomato resulted in lethal necrosis, suggesting that the determinant of necrosis induction lies outside the region between nucleotides 70 and 160.

Nucleotide sequence of satellite tobacco ringspot virus RNA and its relationship to multimeric forms

Tobacco ringspot virus, a member of the nepovirus group, supports the increase and encapsidation of coinoculated satellite tobacco ringspot virus RNA (STobRV RNA). The nucleotide sequence of the unit length STobRV RNA, found here to be 359 nucleotide residues for the budblight strain, occurs also in multimeric, repetitive sequence forms. These are able to undergo an autolytic processing reaction to generate biologically active, unit length STobRV RNA (G. A. Prody, J. T. Bakos, J. M. Buzayan, I. R. Schneider, and G. Bruening,1984, In "Abstracts of the 3rd Cold Spring Harbor RNA Processing Meeting, May 16-20,1 984," p. 8). We determined the nucleotide sequence of the monomeric STobRV RNA by combining results from partial enzymatic digestions of the RNA, partial chemical cleavage of cDNA transcribed from the RNA, and analyses of cDNA clones. Other analyses gave the terminal residues of monomeric STobRV RNA: a cytosine-2':3'-cyclic phosphodiester and a 5' terminal adenosine. The terminal residues of monomeric RNA and their adjacent nucleotide sequences are consistent with the sequence in the junction region of dimeric RNA, derived from transcripts and cDNA clones, and with the formation of two monomeric STobRV RNAs upon autolysis of dimer, without the gain or loss of a nucleotide residue.

Viral RNA synthesis by a particulate fraction from cucumber seedlings infected with cucumber mosaic virus

Particulate preparations from cucumber mosaic virus (CMV)-infected cucumber cotyledons incorporated [alpha-32P]GTP into products which, after phenol extraction, appeared to be double-stranded forms of the four CMV RNAs. In preparations isolated 3 to 5 days after inoculation, the label was incorporated mostly into plus RNA as shown by dot-blot hybridization using single-strand recombinant DNA clones of CMV RNA. After a short pulse the labeled material consisted mostly of small heterogeneous products, but part of the label could be chased into full-length RNAs, demonstrating that the synthetic process was continuous strand elongation rather than terminal addition. CMV RNAs added to the particulate fraction did not give rise to high molecular weight transcripts. In addition to the high molecular weight defined products which remained in the particulate fraction, small heterogeneous products, complementary to plant RNA and to viral RNA of both plus and minus polarity, were released into the incubation medium. They appeared to be products of the virus-induced Mr 100,000 (100K) protein which is solubilized from the particulate fraction during incubation. However, when the particulate fraction was first subjected to an extensive solubilization and washing treatment in order to remove the M(r) 100K protein [D. S. Gill, R. Kumarasamy, and R. H. Symons (1981) Virology 113, 1-8], and then used for product synthesis, a large amount of the product was still of small size, suggesting that the synthesis of high and low molecular weight RNA was intrinsically connected, and that the M(r) 100K protein was not merely contaminating the particulate fraction.

Subgenomic RNAs with nucleotide sequences derived from RNAs 1 and 2 of cucumber mosaic virus can act as messenger RNAs in vitro

Encapsidated RNAs of cucumber mosaic virus (CMV) were analyzed by hybridization to specific probes after gel electrophoresis. [32P]-complementary DNA (cDNA) probes were prepared by transcription of genomic RNA 1 and RNA 2 nucleotide sequences that had been cloned in a bacteriophage M13 vector. Probes that correspond to unique sequences near the 3' ends of RNA 1 and RNA 2 revealed over 20 smaller RNAs. The subgenomic RNAs derived from each genomic RNA were analyzed more definitively by hybrid selection from total encapsidated RNA, using minus DNA clones derived from sequences in either RNA 1 or RNA 2, and a cDNA probe for the 3' sequence conserved among all the genomic RNAs. Different patterns of over 20 minor RNA species, which were 3'-coterminal with RNAs 1 and 2, were detected, and they were reproducible irrespective of the host, cucumber or Nicotiana clevelandii, from which the virus was isolated. The same RNA patterns were found in RNA extracted from the particulate fraction of CMV-infected cucumber orN. clevelandii. In order to determine whether the subgenomic RNAs could function as messenger RNAs, hybrid-selected RNAs were tested by in vitro translation, using the rabbit reticulocyte lysate. The subgenomic RNAs from RNA 1 produced over 10 major polypeptides from Mr 27,000 to Mr 90,000 all of which could be translated from a few RNA species over about 2,300 nucleotides long. The 3'-coterminal subgenomic RNAs derived from RNA 2 gave less than 10 products from Mr, 17,000 toM(r) 85,000. The smallest product (Mr 17,000) was produced by an RNA about 880 nucleotides long, whereas longer RNAs from 1400 to 2500 nucleotides were efficient mRNAs for polypeptides from Mr 30,000 up to the largest translation products consistent with the size of the RNA.

Satellite RNAs of cucumber mosaic virus: characterization of two new satellites

Two new satellite RNAs of cucumber mosaic virus (CMV) which did not induce necrosis on tomato in the presence of CMV, B-sat RNA, and WL-sat RNA, were shown to be related by sequence to two well-characterized satellite RNAs of CMV: G-sat RNA (non-necrotic on tomato) and n-CARNA 5 (necrotic on tomato). Using the techniques of molecular hybridization analysis, RNA fingerprinting and partial RNA sequencing, B-sat RNA and WL-sat RNA were shown to be more closely related to each other (probably differing by only a small number of nucleotides) than to the other two satellite RNAs. Furthermore, B-sat RNA and WL-sat RNA showed greater sequence homology with G-sat RNA than with n-CARNA 5. WL-sat RNA, which induces a "white-leaf" disease on tomato in the presence of CMV [Gonsalves et al. (1982)., exhibited heterogeneity of sequence in at least one nucleotide position.

Sequence of the 3' untranslated region of brome mosaic virus coat protein messenger RNA

The 3' terminal 337 bases of BMV (brome mosaic virus) coat protein mRNA (BMV RNA4) are presented. This sequence includes the terminal portion of the coat protein cistron and the complete 300-base 3' noncoding sequence. The 3' noncoding sequence displays significant complementarity to the 5' terminal sequence of BMV RNA3 but not to the 5' terminal sequence of BMV RNA4.

The bipartite genome of red clover necrotic mosaic virus

Purified preparations of red clover necrotic mosaic virus isolated in Australia have been shown to contain three RNA components whose electrophoretic mobilities in polyacrylamide gel electrophoresis indicate molecular weights of 1.5 x 106 (RNA 1), 0.5 x 10(6) (RNA 2), and 0.14 x 10(6) (RNA 3). Comparisons of the RNAs by hybridization analysis with 3H-labeled complementary DNAs synthesized in vitro have established that RNAs 1 and 2 are unique RNA molecular species with little or no sequence homology between them. However, RNA 3 appears to be a complex mixture of breakdown fragments of both RNA 1 and RNA 2. Infectivity experiments with highly purified preparations of RNAs 1 and 2 have demonstrated that both molecules are essential for infectivity.

Studies on encapsidated viroid-like RNA I. Characterization of velvet tobacco mottle virus

Velvet tobacco mottle virus (VTMoV) isolated from Nicotiana velutina growing wild in arid Central Australia was transmitted by inoculation to a limited number of plant species of which N. clevelandii was the most convenient experimental host. The virus was also transmitted from field-grown plants toN. velutina and N. clevelandii by the mirid Cyropeltis nicotianae. VTMoV preparations purified by clarification with organic solvents and differential centrifugation contained polyhedral particles about 30 nm in diameter sedimenting as a single component at about 115 S. The particles were shown to be located in the nucleus, cytoplasm, and vacuoles of infected plant cells. Virus dissociated in the presence of mercaptoethanol and sodium dodecyl sulfate (SDS) separated into one major and two minor polypeptides with estimated molecular weights of 33,000, 36,000 and 31,000, respectively. Single-stranded RNA isolated from VTMoV by extraction with phenol was separated into five components with apparent molecular weights of 1.5 x 10(6), 0.63 x 10(6), 0.25 x 10(6), 0.16 x 10(6), and 0.12 x 10(6) referred to as RNAs 1, 1a, 1b, 2, and 3, respectively. It appears that RNAs 1a and 1b are breakdown products of RNA 1, as shown elsewhere, and electron microscopic examination of the other species showed that whereas RNAs 1 and 3 are linear molecules, RNA 2 is circular. The similarity of RNAs 2 and 3 to the RNA of viroids is discussed. VTMoV has been compared with several RNA plant viruses with small polyhedral particles. Only solanum nodiflorum mottle virus appears to share some of its unique features and the two have been shown to be antigenically related.

The RNAs of cucumoviruses: 3'-terminal sequence analysis of two strains of tomato aspermy virus

The sequences of 189 residues from the 3' terminus of three RNAs of one strain and two RNAs of another strain of tomato aspermy virus have been determined; there was almost complete sequence homology between the RNAs. A base-paired transfer RNA-like structure is proposed for tomato aspermy virus RNAs which is similar in many aspects to the structure proposed for the 3'-terminal 172 residues of RNA 4 of the Q-strain of cucumber mosaic virus (R. H. Symons, Nucleic Acids Res.7, 825-837, 1979). These 172 residues of cucumber mosaic virus RNA 4 can be aligned to show 73% sequence homology with the 3'-terminal 189 residues of the tomato aspermy virus RNAs.

Comparative studies on two satellite RNAs of cucumber mosaic virus

Cucumber mosaic virus (CMV) satellite RNA (Sat-RNA, D. W. Mossop and R. I. B. Francki, 1978, Virology86, 562-566) is similar in many of its physical and biological properties to CMV associated RNA 5 (CARNA 5) described by Kaper and Tousignant (1977, Virology85, 323-327). However, CARNA 5, unlike Sat-RNA, causes a serious necrotic disease of tomato. Sat-RNA when inoculated together with various CMV or tomato aspermy virus strains not only failed to increase the severity of symptoms in infected tomato plants, but ameliorated them in some instances. Comparisons of the two RNAs by hybridization analysis using 32P-labelled complementary DNA probes, indicate that they have partial nucleotide sequence homology. It is suggested that the difference in their primary structure is reflected in their biological properties.

The stability of satellite viral RNAs in vivo and in vitro

Like the satellite RNA (Sat-RNA) of cucumber mosaic virus (CMV), the RNA of satellite tobacco necrosis virus (STNV-RNA) was shown to be capable of surviving in vivo without replication for at least 10 days in the absence of its helper tobacco necrosis virus (TNV). However, under similar conditions, the genomic RNA 3 of CMV failed to survive for 48 hr. It has been demonstrated that both STNV-RNA and Sat-RNA are significantly more resistant to inactivation in vitro than the RNAs of their helper viruses. The thermal denaturation kinetics of STNV-RNA and Sat-RNA, unlike those of TNV-RNA and CMV-RNA, are more like those of transfer RNA (tRNA) indicating that a high proportion of their nucleotides are involved in base pairing. STNV-RNA, Sat-RNA, and tRNA also show similar degrees of resistance to degradation by the single strand-specific S(1) nuclease. It is suggested that both STNV-RNA and Sat-RNA may owe their in vitro stability to features of their molecular structure which may also account for their ability to survive in vivo for prolonged periods without replication. Similarities and differences between satellites and viroids are discussed and it is concluded that these two classes of RNAs are unlikely to be related. The possible evolutionary origins of the satellites are also considered.

The cucumovirus 2b gene drives selection of inter-viral recombinants affecting the crossover site, the acceptor RNA and the rate of selection

RNA–RNA recombination is an important pathway in virus evolution and has been described for many viruses. However, the factors driving recombination or promoting the selection of recombinants are still unclear. Here, we show that the small movement protein (2b) was able to promote selection of RNA 1/2–RNA 3 recombinants within a chimeric virus having RNAs 1 and 2 from cucumber mosaic virus, and RNA 3 from the related tomato aspermy virus, along with heterologous 2b genes. The source of the 2b also determined the selection of the acceptor RNA and the crossover site, as well as affecting the rate of selection of the recombinant RNAs. The nature of the RNA 3 also influenced the selection of the recombinant RNAs. A 163-nt tandem repeat in RNA 3 significantly affected the rate of selection of the recombinant RNA, while a single nucleotide within the repeat affected the crossover site. The recombination occurred in a non-random manner, involved no intermediates and probably was generated via a copy-choice mechanism during (+) strand RNA synthesis.

Molecular Characterization of Naturally Occurring RNA1 Recombinants of the Comovirus Bean pod mottle virus

ABSTRACT The Bean pod mottle virus, a member of the genus Comovirus, has a bipartite genome consisting of RNA1 and RNA2. We previously reported the occurrence in nature of two distinct subgroups of BPMV strains (subgroups I and II), as well as reassortants between the two subgroups. Here, we report on the isolation and molecular characterization of RNA1 recombinants from soybean plants infected with the partial diploid reassortant strain IL-Cb1, which induces very severe symptoms on soybean. cDNA cloning and sequencing of RNA1 from strain IL-Cb1 revealed the presence of chimeric and mosaic recombinant RNA1s. The full-length mosaic and chimeric recombinant RNA1s were infectious and induced mild symptoms on soybean. Although the recombinant RNA1 accumulated to high levels in the absence of wild-type RNA1, its accumulation level was low in mixed infections with wild-type RNA1. Recombinant RNA1 molecules with similar structures to the naturally occurring recombinant RNA1s were generated in soybean after four passages following inoculation with RNA1 transcripts derived from cDNAs of two distinct strains. This suggests that recombination events are frequent and that a recombination hot spot exists. Sequence analysis of the recombination region showed that it has AU-rich sequences characteristic of recombination hot spots.

Suppression of antiviral silencing by cucumber mosaic virus 2b protein in Arabidopsis is associated with drastically reduced accumulation of three classes of viral small interfering RNAs

We investigated the genetic pathway in Arabidopsis thaliana targeted during infection by cucumber mosaic virus (CMV) 2b protein, known to suppress non-cell-autonomous transgene silencing and salicylic acid (SA)-mediated virus resistance. We show that 2b expressed from the CMV genome drastically reduced the accumulation of 21-, 22-, and 24-nucleotide classes of viral small interfering RNAs (siRNAs) produced by Dicer-like4 (DCL4), DCL2, and DCL3, respectively. The defect of a CMV 2b-deletion mutant (CMV-Delta2b) in plant infection was efficiently rescued in Arabidopsis mutants producing neither 21- nor 22-nucleotide viral siRNAs. Since genetic analysis further identifies a unique antiviral role for DCL3 upstream of DCL4, our data indicate that inhibition of the accumulation of distinct viral siRNAs plays a key role in 2b suppression of antiviral silencing. Strikingly, disease symptoms caused by CMV-Delta2b in Arabidopsis mutants defective in antiviral silencing were as severe as those caused by CMV, demonstrating an indirect role for the silencing suppressor activity in virus virulence. We found that production of CMV siRNAs without 2b interference depended largely on RNA-dependent RNA polymerase 1 (RDR1) inducible by SA. Given the known role of RDR6-dependent transgene siRNAs in non-cell-autonomous silencing, our results suggest a model in which 2b inhibits the production of RDR1-dependent viral siRNAs that confer SA-dependent virus resistance by directing non-cell-autonomous antiviral silencing.

Unit-length, single-stranded circular DNAs of both polarity of begomoviruses are generated in Escherichia coli harboring phage M13-cloned begomovirus genome with single copy of replication origin

Replication of genomic DNAs of plant-pathogenic begomoviruses has been demonstrated in prokaryotes, which supported the possibility of analyzing DNA replication process of begomoviruses in bacteria. However, previous studies indicated that the replication of begomovirus DNAs in prokaryotes requires tandem constructs of viral genomes with at least two copies of the origin of replication (ori). In this study, phage M13 vector harboring the unit-length genome with only a single copy of ori of a mono-partite begomovirus, Ageratum yellow vein virus PD isolate (AYVV-[PD]), was constructed and used to investigate the replication of AYVV-[PD] DNAs in Escherichia coli. The generation of single-stranded, circular DNAs (sscDNAs) corresponding to the unit-length AYVV-[PD] genome of both polarity was observed and verified. Replication-associated (Rep) protein of AYVV-[PD] was detected only in bacteria generating the corresponding sscDNAs, whereas disruption of the Rep gene abolished the phenomenon. The results suggested that a single copy of ori is sufficient for the prokaryotes to support the generation of unit-length, genomic sscDNAs of begomoviruses, which requires the presence of functional Rep protein.

Development of Bean pod mottle virus-based vectors for stable protein expression and sequence-specific virus-induced gene silencing in soybean

Plant virus-based vectors provide valuable tools for expression of foreign proteins in plants and for gene function studies. None of the presently available virus vectors is suitable for use in soybean. In the present study, we produced Bean pod mottle virus (BPMV)-based vectors that are appropriate for gene expression and virus-induced gene silencing (VIGS) in soybean. The genes of interest were inserted into the RNA2-encoded polyprotein open reading frame between the movement protein (MP) and the large coat protein (L-CP) coding regions. Additional proteinase cleavage sites were created to flank the foreign protein by duplicating the MP/L-CP cleavage site. To minimize the chances of homologous recombination and thus insert instability, we took advantage of the genetic code degeneracy and altered the nucleotide sequence of the duplicated regions without affecting amino acid sequences. The recombinant BPMV constructs were stable following several serial passages in soybean and relatively high levels of protein expression were attained. Successful expression of several proteins with different biological activities was demonstrated from the BPMV vector. These included the reporter proteins GFP and DsRed, phosphinothricin acetyltransferase (encoded by the herbicide resistance bar gene), and the RNA silencing suppressors encoded by Tomato bushy stunt virus, Turnip crinkle virus, Tobacco etch virus, and Soybean mosaic virus. The possible use of BPMV as a VIGS vector to study gene function in soybean was also demonstrated with the phytoene desaturase gene. Our results suggest that the BPMV-based vectors are suitable for expression of foreign proteins in soybean and for functional genomics applications.

Cucumber mosaic virus 2a polymerase and 3a movement proteins independently affect both virus movement and the timing of symptom development in zucchini squash

The basis for differences in the timing of systemic symptom elicitation in zucchini squash between a pepper strain of Cucumber mosaic virus (Pf-CMV) and a cucurbit strain (Fny-CMV) was analysed. The difference in timing of appearance of systemic symptoms was shown to map to both RNA 2 and RNA 3 of Pf-CMV, with pseudorecombinant viruses containing either RNA 2 or RNA 3 from Pf-CMV showing an intermediate rate of systemic symptom development compared with those containing both or neither Pf-CMV RNAs. Symptom phenotype was shown to map to two single-nucleotide changes, both in codons for Ile at aa 267 and 168 (in Fny-CMV RNAs 2 and 3, respectively) to Thr (in Pf-CMV RNAs 2 and 3). The differential rate of symptom development was shown to be due to differences in the rates of cell-to-cell movement in the inoculated cotyledons, as well as differences in the rate of egress of the virus from the inoculated leaves. These data indicate that both the CMV 3a movement protein and the CMV 2a polymerase protein affect the rate of movement of CMV in zucchini squash and that these two proteins function independently of each other in their interactions with the host, facilitating virus movement.

The Bean pod mottle virus proteinase cofactor and putative helicase are symptom severity determinants

Full-length infectious cDNA clones were constructed from the genomic RNAs of three distinct strains (K-G7, K-Ha1 and K-Ho1) of the comovirus Bean pod mottle virus (BPMV). Whereas K-G7, a subgroup I strain, and K-Ha1, a subgroup II strain produce mild mottling, the reassortant strain K-Ho1 (RNA1(I) + RNA2(II)) induces necrotic primary lesions on inoculated leaves of soybean and severe systemic leaf mottling and blistering. Pseudorecombinants of all possible combinations of transcripts were generated and tested for symptom production. Only soybean plants inoculated with combinations having RNA1 derived from the severe strain K-Ho1, regardless of the origin of RNA2, induced severe symptoms, indicating that symptom severity maps to RNA1. Experiments with chimeric RNA1 constructs indicated that the coding regions of the protease co-factor (Co-pro) and the C-terminal half of the putative helicase (Hel) are determinants of symptom severity. Symptom severity correlated well with higher accumulation of viral RNA, but neither the Co-pro nor Hel protein could be demonstrated as a suppressor of RNA silencing.

Virion stability and aphid vector transmissibility of Cucumber mosaic virus mutants

The physical stability of virions of Cucumber mosaic virus (CMV) mutants was investigated to determine if relative stability correlated with efficiency of aphid transmission. Virion stability was evaluated by a urea disruption assay and by testing the infectivity of virus following purifications. All viruses were infectious when purified using a low salt buffer without organic solvent, whereas two of seven viruses were less stable and inactivated following purification with a high salt buffer and chloroform. These two viruses were both reassortants derived from the spontaneous transmission-defective mutant CMV-M (F1F2M3 and F1F2M3-L129P). F1F2M3 was relatively unstable, being disrupted between 0 and 1 M urea versus the wild-type CMV-Fny (F1F2M3) that was destabilized at 3-4 M urea. Modifications of F1F2M3 at three amino acid positions (129, 162, 168), singly or in combination, increased the relative stability of virions. A second class of transmission-defective CMVs with engineered mutations in the betaH-betaI surface loop of the CMV-Fny capsid protein (CP) exhibited near wild-type levels of stability. Lastly, a single Pro to Leu substitution at CP position 129 of CMV-Fny (F1F2M3-P129L) conferred the induction of necrosis in tobacco plants and reduced aphid transmissibility, but did not markedly alter the physical stability of virions. Thus, only among CMV-M derivatives harboring the CP mutation of Thr to Ala at position 162 were increases in stability correlated with restoration of transmissibility by the aphid Aphis gossypii.

A Short Insert in the Leader Sequence of RNA 3L, A Long Variant of Alfalfa mosaic virus RNA3, Introduces Two Unidentified Reading Frames

N20-RNA 3L, a large form of RNA 3 associated with Alfalfa mosaic virus (AMV) strain N20 comprises 2281 nt and has approximately 97% overall sequence similarity to the longest previously described RNA 3 of AMV strain YSMV (YSMV-RNA 3; 2188 nt). Compared with YSMV-RNA 3, N20-RNA 3L contains an additional 97 nt in the 5' leader upstream of the open reading frames for movement protein (MP) and coat protein (CP). Two overlapping unidentified reading frames (URF1 and URF2) result from this modification, each of which code for putative translation products of 21 amino acids. The URF1 putative peptide has a hydrophilic N-terminus and a hydrophobic C-terminus, indicating a possible association with both host cell membrane and cytosol whereas the putative URF2 product is predominantly hydrophobic. A further structural modification found in N20-RNA 3L is a new tandem repeat of 243 nts which overlaps with the MP open reading frame.

Stable and unstable mutations in the 5' non-translated regions of tomato aspermy virus RNAs 1 and 2 generated de novo from infectious cDNA clones containing a cauliflower mosaic virus 35S promoter

Tomato aspermy virus RNAs derived from infectious cDNA clones exhibited a number of sequence alterations in the 5' non-translated region (NTR). These included a deletion of the first four residues in both RNAs 1 and 2, transversion of residue 5 from a G to a U in RNA 1, and transversion of A to C at position of 50 of RNA 1. These alterations were not stable in the infected plants while the insertion of a U residue between nucleotides 1 and 5 of RNA 1 was stable in the infected plants. Generation of these sequence alternations was not dependent upon either the host species or the concentration of the inoculum. The sequence alterations also did not occur on passage of wildtype virus. Rather, the sequence alterations related to transcription from the cauliflower mosaic virus 35S RNA promoter-driving infectious cDNAs. The alternations observed had no impact on symptoms or infectivity, but did affect the accumulation of specific viral RNAs. The data also demonstrated the existence of some plasticity in the sequence of the 5' NTR.

Cucumoviruses

Research on the molecular biology of cucumoviruses and their plant-virus interactions has been very extensive in the last decade. Cucumovirus genome structures have been analyzed, giving new insights into their genetic variability, evolution, and taxonomy. A new viral gene has been discovered, and its role in promoting virus infection has been delineated. The localization and various functions of each viral-encoded gene product have been established. The particle structures of Cucumber mosaic virus (CMV) and Tomato aspermy virus have been determined. Pathogenicity domains have been mapped, and barriers to virus infection have been localized. The movement pathways of the viruses in some hosts have been discerned, and viral mutants affecting the movement processes have been identified. Host responses to viral infection have been characterized, both temporally and spatially. Progress has been made in determining the mechanisms of replication, gene expression, and transmission of CMV. The pathogenicity determinants of various satellite RNAs have been characterized, and the importance of secondary structure in satellite RNA-mediated interactions has been recognized. Novel plant genes specifying resistance to infection by CMV have been identified. In some cases, these genes have been mapped, and one resistance gene to CMV has been isolated and characterized. Pathogen-derived resistance has been demonstrated against CMV using various segments of the CMV genome, and the mechanisms of some of these forms of resistances have been analyzed. Finally, the nature of synergistic interactions between CMV and other viruses has been characterized. This review highlights these various achievements in the context of the previous work on the biology of cucumoviruses and their interactions with plants.

Involvement of RNA2 for systemic infection of Cucumber mosaic virus isolated from lily on zucchini squash

A lily strain of Cucumber mosaic virus (LK-CMV) was not able to systemically infect zucchini squash (Cucurbita pepo), while Fny strain of CMV (Fny-CMV) caused systemic mosaic and stunting symptom at 4 days post-inoculation on the same host species. The pathogenicity of LK-CMV in zucchini squash was investigated by reassortments of genomic RNAs of LK-CMV and Fny-CMV for infection, as well as by pseudorecombinants generated from biologically active transcripts of cDNA clones of LK-CMV and Fny-CMV, respectively. The assessments of pathogenicity for LK-CMV indicated that RNA2 of LK-CMV was responsible for systemic infection in zucchini squash. In the protoplast of zucchini squash, the RNA accumulations of all constructed pseudorecombinants were indistinguishable and LK-CMV replication was slightly lower than that of Fny-CMV, suggesting that the inability of LK-CMV to infect squash plants was responsible for the poor efficiency of virus movement, rather than the reduction of replication function.

Differential virulence by strains of Cucumber mosaic virus is mediated by the 2b gene

The approximately 12-kDa 2b protein, encoded by all cucumoviruses, had been shown to play an important role in viral long-distance movement, hypervirulence, and suppression of post-transcriptional gene silencing. The role of the 2b gene in the hypervirulence of Cucumber mosaic virus (CMV) and whether hypervirulence was linked to movement were analyzed using a hybrid virus (CMV-qw), generated by replacing the 2b gene in a subgroup II strain, Q-CMV, with the 2b gene from a subgroup IA strain, WAII-CMV. CMV-qw was more virulent than Q-CMV or WAII-CMV on most of the host plant species tested. Northern blot and nucleotide sequence analyses demonstrated that CMV-qw was stably maintained during the course of infection and upon passage. Kinetic studies revealed that the hypervirulence induced by the hybrid virus was associated with neither increased viral RNA accumulation nor more rapid viral movement per se, suggesting that other functions of the 2b protein are important in determining the hypervirulence.

Virulence and differential local and systemic spread of cucumber mosaic virus in tobacco are affected by the CMV 2b protein

A mutant of the Cucumber mosaic virus subgroup IA strain Fny (Fny-CMV) lacking the gene encoding the 2b protein (Fny-CMVdelta2b) induced a symptomless systemic infection in tobacco. Both the accumulation of Fny-CMVdelta2b in inoculated tissue and the systemic movement of the virus appeared to proceed more slowly than for wild-type Fny-CMV. The influence of the 2b protein on virus movement in the inoculated leaf was examined using viral constructs derived from Fny-CMV and Fny-CMVdelta2b expressing the green fluorescent protein. Laser scanning confocal microscopy was used to visualize the movement of these viruses. Whereas the wild-type virus spread between the epidermal cells as well as the mesophyll cells, the mutant virus spread less efficiently through the epidermal layer and moved preferentially through the mesophyll. Thus, the 2b protein of Fny-CMV influences the dynamics of movement of the virus both within the inoculated leaf and through the whole plant. We propose that this altered movement profile of Fny-CMVdelta2b results in the absence of disease symptoms in tobacco.

Diversity Among Isolates of Bean pod mottle virus

ABSTRACT Isolates of Bean pod mottle virus (BPMV), a member of the genus Comovirus, collected from soybean fields in Kentucky, Virginia, Arkansas, and Iowa were classified into two distinct subgroups, I and II, based on nucleic acid hybridization analysis using cloned cDNA probes to RNA-1 from BPMV strains K-G7 and K-Ha1. Slot blot hybridization analysis using cloned cDNA probes to RNA-2 from the same two strains (K-G7 and K-Ha1), however, revealed that some of the isolates, initially classified as belonging to subgroup I after analysis with RNA-1 probes, are in fact natural reassortants between the two strain subgroups. This was corroborated by nucleotide sequence analysis of full-length cDNA clones of both RNA-1 and RNA-2 from a putative reassortant strain (K-Ho1). These results indicate that BPMV strain diversity is more complex than initially anticipated, and that the use of cloned probes to both genomic RNAs during nucleic acid hybridization analysis is required to unravel the extent of such diversity. In a field plot experiment, BPMV isolates that belong to distinct strain subgroups induced symptoms that varied in severity and in the level of yield losses. In this regard, the reassortant strain K-Ho1 caused the most serious damage compared with four other BPMV isolates tested. Furthermore, the soybean alleles Rsv(1) and Rsv(4), known to confer resistance against Soybean mosaic virus, a member of the genus Potyvirus, did not provide any protection against BPMV. Additionally, we developed a reverse transcription-polymerase chain reaction procedure based on the sequence of a highly conserved region in the capsid polyprotein coding sequence that provides efficient and highly sensitive detection of all BPMV isolates tested, regardless of their strain classification.

Core promoter for initiation of Cucumber mosaic virus subgenomic RNA4A

summary The core subgenomic promoter for the initiation of Cucumber mosaic virus (CMV) RNA4A was characterized in vitro using a template-dependent RNA synthesis assay and variants of the core promoter RNAs. The minimal sequence required for specific initiation from the cytidylate (T1) used in vivo consists of 31-nucleotides (nt) 3' of T1 and a 13 nt template sequence. This 44 nt RNA was found to provide three elements that contribute to efficient initiation of RNA4A synthesis by the CMV replicase: a stem-loop secondary structure 3' of T1, a template sequence that is rich in adenylates and uridylates, and T1 in an unbase-paired sequence.

Recognition of the core RNA promoter for minus-strand RNA synthesis by the replicases of Brome mosaic virus and Cucumber mosaic virus

Replication of viral RNA genomes requires the specific interaction between the replicase and the RNA template. Members of the Bromovirus and Cucumovirus genera have a tRNA-like structure at the 3' end of their genomic RNAs that interacts with the replicase and is required for minus-strand synthesis. In Brome mosaic virus (BMV), a stem-loop structure named C (SLC) is present within the tRNA-like region and is required for replicase binding and initiation of RNA synthesis in vitro. We have prepared an enriched replicase fraction from tobacco plants infected with the Fny isolate of Cucumber mosaic virus (Fny-CMV) that will direct synthesis from exogenously added templates. Using this replicase, we demonstrate that the SLC-like structure in Fny-CMV plays a role similar to that of BMV SLC in interacting with the CMV replicase. While the majority of CMV isolates have SLC-like elements similar to that of Fny-CMV, a second group displays sequence or structural features that are distinct but nonetheless recognized by Fny-CMV replicase for RNA synthesis. Both motifs have a 5'CA3' dinucleotide that is invariant in the CMV isolates examined, and mutational analysis indicates that these are critical for interaction with the replicase. In the context of the entire tRNA-like element, both CMV SLC-like motifs are recognized by the BMV replicase. However, neither motif can direct synthesis by the BMV replicase in the absence of other tRNA-like elements, indicating that other features of the CMV tRNA can induce promoter recognition by a heterologous replicase.

Cucumber mosaic virus mutants with altered physical properties and defective in aphid vector transmission

Two mutant strains of cucumber mosaic virus (CMV) were investigated with respect to virion stability and molecular determinants of aphid vector transmission. The mutant 2A1-MT-60x, derived from the mechanically passaged wild type 2A1-AT, is poorly transmissible by the aphid Aphis gossypii and not transmissible by the aphid Myzus persicae, whereas the wild type virus is transmissible by both aphid species. The mutant phenotype was shown to be conferred by a single encoded amino acid change of alanine to threonine at position 162 of the coat protein (CP). Modifying the mutant CP gene to encode the wild type sequence (alanine) at position 162 restored aphid transmission. To test for a correspondence between changes in the physical stability of virions and defects in aphid transmission, a urea disruption assay was developed. Virions of aphid-transmissible strains 2A1-AT and CMV-Fny were stable with treatments of up to between 3 and 4 M urea. In this assay mutant viruses 2A1-MT-60x and CMV-M were less stable, as they were completely disrupted at urea concentrations of 2 and 1 M urea, respectively. The mutant 2A1-MT-60x also accumulated at a reduced level in infected squash relative to the wild type virus. These studies suggest that a primary factor in the loss of aphid transmissibility of some strains of CMV is a reduction in virion stability.

Subcellular distribution analysis of the cucumber mosaic virus 2b protein

The cucumoviral 2b protein is a viral counterdefence factor that interferes with the establishment of virus-induced gene silencing in plants. Synthetic peptides were used to generate an antibody to the 2b protein encoded by the Fny strain of cucumber mosaic virus (Fny-CMV). This polyclonal antibody was able to recognize the Fny-CMV 2b protein in a 10000 g pellet fraction of infected tobacco. No protein of equivalent size was detected in mock-inoculated or tobacco mosaic virus-infected samples. This represents the first demonstration of 2b protein expression by a subgroup I strain of CMV. Subcellular fractionation experiments on CMV-infected tobacco leaf tissue showed that the Fny-CMV 2b protein accumulated within a fraction that sedimented at forces of less than 5000 g and that the 2b protein was solubilized only by treatment with urea or SDS. These results suggested that the 2b protein associates either with the nucleus or cytoskeleton of the host cell. Further analysis showed that the 2b protein was enriched in a fraction that sedimented through a 2.2 M sucrose cushion. This fraction was also enriched in histones, suggesting that the CMV 2b protein associates preferentially with the host cell nucleus.

The plant defense response to cucumber mosaic virus in cowpea is elicited by the viral polymerase gene and affects virus accumulation in single cells

Resistance to infection in cowpea by strains of cucumber mosaic virus (CMV) involves a local, hypersensitive response (HR) and a localization of infection. These responses can be separated by mutation at two sites (nucleotides 1978 and 2007, in codons 631 and 641) in the CMV 2a polymerase gene. Changes to both sites of a restricted strain allow systemic infection without an HR and increase the accumulation of both the 2a protein and viral RNA in protoplasts, while changing position 1978 alone results in a systemic infection, a systemic HR, and an increase in viral RNA accumulation in protoplasts. It is suggested that the inhibition response observed in protoplasts, where an HR does not occur, leads to localization of infection in whole plants and that different plant genes are involved in eliciting the HR and the localization response.

Biological properties of pseudorecombinant and recombinant strains created with cucumber mosaic virus and tomato aspermy virus

Cucumber mosaic virus (CMV) and tomato aspermy virus (TAV) are closely related cucumoviruses. We have made pseudorecombinant viruses in which the RNAs 3 of these two viruses have been exchanged and recombinant viruses containing chimeric RNA 3 molecules, in which the coat proteins and the 3'-end regions of CMV and TAV have been exchanged, giving rise to recombinants designated RT3 and TR3. The replication properties and the cell-to-cell and long-distance movement patterns of these pseudorecombinant and recombinant viruses were examined in different hosts. All the viruses were able to replicate and accumulate RNA 4 in protoplasts. The pseudorecombinants and the R1R2RT3 recombinant infected tobacco systemically, but the R1R2TR3 recombinant was not detectable, even in the inoculated leaves. Comparison of the abilities of the viruses to replicate in protoplasts and intact cucumber plants suggests that cell-to-cell movement factors are also encoded by RNAs 1 and/or 2. Major determinants of symptom severity in Nicotiana glutinosa are localized on the 3' part of RNA 3, and in Nicotiana benthamiana, more severe symptoms were observed with the T1T2R3 strain than with the others tested.

Characterization of cucumber mosaic virus. III. Localization of sequences in the movement protein controlling systemic infection in cucurbits

Cucumber mosaic virus (CMV), generated from biologically active cDNA clones of Fny-CMV RNA 1 plus 2 and Sny-CMV RNA 3, derived from the Fny- and Sny-strains of CMV, was able to infect tobacco but not squash plants systemically. In squash, viral RNA, movement protein, and coat protein all accumulated in the inoculated cotyledons. The lack of systemic infection was associated with a reduced rate of cell-to-cell movement within the cotyledons. The restricted movement mapped to two sequence changes in the codons of amino acids 51 and 240 of the Sny-CMV 3a gene. These same sequence changes previously were shown to be associated with high levels of 3a protein accumulation and chronic vs acute, cyclic infection typical of Sny-CMV vs Fny-CMV [Gal-on et al. (1996). Virology 226, 354-361]. Fny-CMV, mutated in the codons of 3a gene amino acids 51 and 240, was still able to infect several solanaceous hosts (tobacco, tomato, and pepper) systemically, but did not elicit a typical CMV systemic infection on any of several cucurbit hosts (cucumber, melon, or squash). The significance of the location of amino acid positions 51 and 240 in the 3a movement protein is discussed.