Peanut yellow spot virus: A distinct tospovirus species based on serology and nucleic acid hybridisation

Nucleocapsids of peanut yellow spot virus (PYSV), purified from peanut (= groundnut) plant tissue, contained a protein with a molecular mass of 29 kDa. In ELISA and immuno-blot analysis the virus did not react with tomato spotted wilt virus (TSWV), Impatiens necrotic spot virus (INSV) and peanut bud necrosis virus (PBNV) antisera. PYSV contained three RNA species, a large (L) RNA (c.8900 nucleotides), a medium (M) RNA (c.4800 nucleotides) and a small (S) RNA (c.3000 nucleotides), similar to other tospoviruses. In addition, a fourth RNA species of approximately 1800 nucleotides was also present in purified preparations. Hybridisation analysis under high stringency conditions revealed no hybridisation between PYSV RNAs and cDNA probes representing the nucleocapsid (N) gene, the glycoprotein (GP) gene and the 3' half of the RNA polymerase gene of PBNV. PYSV genomic RNAs also failed to hybridise with cDNA probes from the GP genes of TSWV and INSV. In reciprocal tests, the cDNA clones of PYSV S and M RNAs did not hybridise with any of the PBNV RNAs. Based on the absence of serological relationships between PYSV and PBNV, TSWV and INSV and lack of nucleotide homology based on hybridisation studies between the PYSV RNAs and cDNA clones from PBNV, TSWV and INSV, PYSV should be considered as a distinct species of the genus Tospovirus under a new serogroup, putatively designated ‘V’.     

Serological relationships and purification of bud necrosis virus,a tospovirus occurring in peanut (Arachis hypogaea L.) in India*

A procedure for the purification of a tospovirus which causes bud necrosis disease (BND) of peanut in India is described. The virus contained three polypeptides of 78 kDa, 54 kDa and 31 kDa. In two ELISA procedures the virus failed to react with antisera to tomato spotted wilt virus (TSWV) obtained from different sources and with an antiserum to impatiens necrotic spot virus (INSV). Additionally, in reciprocal tests TSWV and INSV antigens failed to react with antiserum to the virus infecting peanut in India. In electro-blot immunoassay 54 kDa and 31 kDa polypeptides of the virus reacted with the homologous antiserum. None of the heterologous antisera reacted with any of the three viral polypeptides. On the basis of serological differences the virus that causes BND in India is distinct and therefore has been named bud necrosis virus (BNV). This serotype appears to be restricted to Asia.     

Tomato spotted wilt virus (TSWV) in Greece: its incidence following the expansion of Frankliniella occidentalis, and characterisation of isolates collected from various hosts

Leaf samples were collected from plants with tospovirus‐like symptoms from various hosts in different regions of Greece where Thrips tabaci, Frankliniella occidentalis or both vectors occur. The viruses infecting these plants were identified with polyclonal antibodies raised against the N proteins of Tomato spotted wilt virus (TSWV) and Impatiens necrotic spot virus (INSV) by ELISA. All samples tested positive for TSWV, but not for INSV. ELISA of thirty three isolates, using monoclonal antibodies against the N protein of TSWV, revealed the existence of five epitopes on the N protein. RT‐PCR tests on a few randomly‐selected isolates, using a pair of universal primers, a pair of primers specific for the L gene and a pair of primers specific for the N gene, as well as sequence analysis of a part of the S gene of one isolate, confirmed the authenticity of the virus isolated as TSWV. Host range studies showed differences in susceptibility, especially among species belonging to the Leguminosae and Cucurbitaceae. The species Beloporone guttata and Coleus sp. are reported for the first time as hosts of the virus, whereas Solanum melongena, Celosia cristata, Dianthus chinensis, Stephanotis floribunda and Catharanthus roseus were identified as new hosts of TSWV in Greece.     

Monoclonal Antibodies against the Recombinant Nucleocapsid Protein of Tomato spotted wilt virus and its Application in Virus Detection

Tomato spotted wilt virus (TSWV) is the type member of the tospovirus genus and causes significant losses in a wide range of economically important ornamental and vegetable crops worldwide. The nucleocapsid gene, located on the ambisense S RNA segment of TSWV was expressed in Escherichia coli using pET-32a as vector and correct expression of recombinant protein was confirmed by Western blot using an anti-TSWV monoclonal antibody (MAb). The recombinant protein was purified using Ni-NTA agarose and the purified protein was used for the production of MAbs. Three murine MAbs against the recombinant nucleocapsid protein were produced. Triple antibody sandwich enzyme-linked immunosorbent assay and immunocapture RT-PCR methods were then established for reliable and efficient detection of TSWV using the produced MAbs.     

Complete Genome Sequence of Mulberry Vein Banding Associated Virus,a New Tospovirus Infecting Mulberry

Mulberry vein banding associated virus (MVBaV) that infects mulberry plants with typical vein banding symptoms had been identified as a tentative species of the genus Tospovirus based on the homology of N gene sequence to those of tospoviruses. In this study, the complete sequence of the tripartite RNA genome of MVBaV was determined and analyzed. The L RNA has 8905 nucleotides (nt) and encodes the putative RNA-dependent RNA polymerase (RdRp) of 2877 aa amino acids (aa) in the viral complementary (vc) strand. The RdRp of MVBaV shares the highest aa sequence identity (85.9%) with that of Watermelon silver mottle virus (WSMoV), and contains conserved motifs shared with those of the species of the genus Tospovirus. The M RNA contains 4731 nt and codes in ambisense arrangement for the NSm protein of 309 aa in the sense strand and the Gn/Gc glycoprotein precursor (GP) of 1,124 aa in the vc strand. The NSm and GP of MVBaV share the highest aa sequence identities with those of Capsicum chlorosis virus (CaCV) and Groundnut bud necrosis virus (GBNV) (83.2% and 84.3%, respectively). The S RNA is 3294 nt in length and contains two open reading frames (ORFs) in an ambisense coding strategy, encoding a 439-aa non-structural protein (NSs) and the 277-aa nucleocapsid protein (N), respectively. The NSs and N also share the highest aa sequence identity (71.1% and 74.4%, respectively) with those of CaCV. Phylogenetic analysis of the RdRp, NSm, GP, NSs, and N proteins showed that MVBaV is most closely related to CaCV and GBNV and that these proteins cluster with those of the WSMoV serogroup, and that MVBaV seems to be a species bridging the two subgroups within the WSMoV serogroup of tospoviruses in evolutionary aspect, suggesting that MVBaV represents a distinct tospovirus. Analysis of S RNA sequence uncovered the highly conserved 5’-/3’-ends and the coding regions, and the variable region of IGR with divergent patterns among MVBaV isolates.     

A UK Isolate of Impatiens Necrotic Spot Virus From Glasshouse-grown Cineraria

A tospovirus was detected by ELISA in a Cineraria sample from a commercial protected crop in the UK. Its seroiogical properties indicated it to be Impatiens necrotic spot virus (INSV), results confirmed by RT-PCR tests and nucleotide sequence data on the nucleoprotein-encoding region of the genome. This is the first report of the presence of INSV in a protected crop grown in the UK.     

Structural Characteristics and Nucleotide Sequence Analysis of Genomic RNA from RD-114 Virus and Feline RNA Tumor Viruses

The results of molecular hybridization experiments have demonstrated that the RNA genome of RD-114 virus has extensive nucleotide sequence homology with the RNA genome of Crandell virus, an endogenous type C virus of cats, but only limited homology with the RNA genomes of feline sarcoma virus and feline leukemia virus. The genomic RNAs of RD-114 virus and Crandell virus also had identical sedimentation coefficients of 50S. A structural rearrangement of genomic RNA did not exist within released RD-114 virions, whereas a structural rearrangement of genomic RNA did occur within feline sarcoma virions and feline leukemia virions after release from virus-producing cells.     

Uukuniemi virus S RNA segment: ambisense coding strategy, packaging of complementary strands into virions, and homology to members of the genus Phlebovirus.

We determined the complete nucleotide sequence of the small (S) RNA segment of Uukuniemi virus, the prototype of the Uukuvirus genus within the Bunyaviridae family. The RNA, which is 1,720 nucleotides long, contains two nonoverlapping open reading frames. The 5' end of one strand (complementary to the viral strand) encodes the nonstructural protein NSs (273 residues; molecular weight, 32,019), whereas the 5' end of the viral-sense strand encodes the nucleocapsid protein N (254 residues; molecular weight, 28,508). Thus, the S RNA uses an ambisense coding strategy previously described for the S segment of two phleboviruses and the arenaviruses. The localization of the N protein within the S RNA sequence was confirmed by amino-terminal sequence analysis of all five possible cyanogen bromide fragments obtained from purified N protein. Northern (RNA) blot analyses with strand-specific probes showed that the N and NSs proteins are translated from subgenomic mRNAs about 800 and 850 nucleotides long, respectively. These mRNAs are apparently transcribed from full-length S RNAs of opposite polarities. The two mRNA species were also detected in virus-infected cells. Interestingly, highly purified virions contained full-length S RNA copies of both polarities at a ratio of about 10:1. In contrast, virions contained exclusively negative-strand copies of the M RNA segment. The possible significance of these results for viral infection is discussed. The amino acid sequence of the N protein showed 35 and 32% homology (identity) with the N protein of Punta Toro and sandfly fever Sicilian viruses, two members of the Phlebovirus genus. The NSs proteins were much less related (about 15% identity). In addition, the extreme 5' and 3' ends of the S RNA, which are complementary to each other, also showed a high degree of conservation with the two phleboviruses. These results indicate that the uukuviruses and phleboviruses are evolutionarily related and suggest that the two genera could be merged into a single genus within the Bunyaviridae family.     

Влнянне характера эаселення ноля капустноii совкоii(Barathra brassicae L.) эффективноеть трихограммы (Trichogramma evanescens Westw.) (Lepidoptera,Noctuidae; Hymenoptera,Trichogrammatidae)

TSWV belongs to the genus Tospovirus which was established in the family Bunyaviridae, a family of animal viruses. Besides TSWV, Impatiens necrotic spot virus (INSV) and ground nut bud necrosis virus (GBNV) were established as different Tospovirus species. Tospoviruses have quasispherical particles of 85 nm diametre which are surrounded by a membrane and contain 3 RNA species and 4 structural proteins. In Tospovirus infected plant cells virions were detected in cavaties of the endoplasmatic reticulum and additionally amorphous electron dense material accumulates in infected cells. Defective forms of TSWV lack the ability to form complete virus particles. TSWV is the only plant pathogenic virus that is transmitted by thrips which transmit the virus with different efficiency. The virus has an extensive plant host range of more than 360 different species. The developing symptoms depend on the Tospovirus species, the virulence of the virus strains and the environmental conditions.

Based on the reaction of TSWV isolates with N‐specific polyclonal antisera, 3 serogroups were established. The most frequently used technique for serologically based diagnosis of Tospoviruses is DAS ELISA with N‐specific or preadsorbed antisera against complete virus. For TSWV epidemiology distinct weeds and cultural host plants play an important role for the survival of virus and vector. Breeding for resistance is the most important preventive measure of control.     

侵染花生的辣椒褪绿病毒SRNA全序列分析

番茄斑萎病毒属(Tospovirus)是布尼亚病毒科(Bunyaviridae)中植物病毒组成的一个属,病毒粒子为球状,直径80~110nm,粒体外层由一层脂质包裹。基因组属于负单链RNA,由三个片段组成,分别被称为L RNA、M RNA、和S RNA。L RNA为负链、含单个开放阅读框架(ORF),M RNA和S RNA均为双义R     

Occurrence of Different Tospoviruses in Vegetable Crops in Argentina

Significant damage on vegetable crops by tospoviruses had occurred sporadically in Argentina in the past but since 1994, severe outbreaks have been recorded every year. The crops that have been most affected, tomato, lettuce, and pepper, were surveyed in the provinces of Mendoza and Buenos Aires in 1994–95 and 1995–96. A few weeds and miscellaneous crops were also collected. A total of 543 samples showing symptoms typical for tospoviruses were analysed by double-antibody sandwich-enzyme-linked immunosorbent assay with polyclonal antibodies to groundnut ringspot tospovirus (GRSV), impatiens necrotic spot tospovirus (INSV) and tomato spotted wilt tospovirus (TSWV). The 339 samples collected in 1995–96 were also assayed for tomato chlorotic spot tospovirus (TCSV). In addition, the incidence of tospoviruses in tomato crops was assessed in 41 farms representing 310 ha and 10 cultivars. GRSV was identified in 222 samples (40.8%), TSWV in 194 samples (32.7%), TCSV in 50 samples (14.7%), INSV was not detected and 77 samples did not react with the antisera used. TSWV was found to prevail in Buenos Aires and GRSV in Mendoza. Mixed infections were not found in this survey. In tomato crops the mean incidence of tospoviruses was 33%. These results show that the disease formerly assigned to TSWV, is caused by at least three tospoviruses.     

Characterization of bean necrotic mosaic virus: a member of a novel evolutionary lineage within the Genus Tospovirus

BACKGROUND: Tospoviruses (Genus Tospovirus, Family Bunyaviridae) are phytopathogens responsible for significant worldwide crop losses. They have a tripartite negative and ambisense RNA genome segments, termed S (Small), M (Medium) and L (Large) RNA. The vector-transmission is mediated by thrips in a circulative-propagative manner. For new tospovirus species acceptance, several analyses are needed, e.g., the determination of the viral protein sequences for enlightenment of their evolutionary history. METHODOLOGY/PRINCIPAL FINDINGS: Biological (host range and symptomatology), serological, and molecular (S and M RNA sequencing and evolutionary studies) experiments were performed to characterize and differentiate a new tospovirus species, Bean necrotic mosaic virus (BeNMV), which naturally infects common beans in Brazil. Based upon the results, BeNMV can be classified as a novel species and, together with Soybean vein necrosis-associated virus (SVNaV), they represent members of a new evolutionary lineage within the genus Tospovirus. CONCLUSION/SIGNIFICANCES: Taken together, these evidences suggest that two divergent lineages of tospoviruses are circulating in the American continent and, based on the main clades diversity (American and Eurasian lineages), new tospovirus species related to the BeNMV-SVNaV clade remain to be discovered. This possible greater diversity of tospoviruses may be reflected in a higher number of crops as natural hosts, increasing the economic impact on agriculture. This idea also is supported since BeNMV and SVNaV were discovered naturally infecting atypical hosts (common bean and soybean, respectively), indicating, in this case, a preference for leguminous species. Further studies, for instance a survey focusing on crops, specifically of leguminous plants, may reveal a greater tospovirus diversity not only in the Americas (where both viruses were reported), but throughout the world.     

The molecular population genetics of the Tomato spotted wilt virus (TSWV) genome

RNA viruses are characterized by high genetic variability resulting in rapid adaptation to new or resistant hosts. Research for plant RNA virus genetic structure and its variability has been relatively scarce compared to abundant research done for human and animal RNA viruses. Here, we utilized a molecular population genetic framework to characterize the evolution of a highly pathogenic plant RNA virus [Tomato spotted wilt virus (TSWV), Tospovirus, Bunyaviridae]. Data from genes encoding five viral proteins were used for phylogenetic analysis, and for estimation of population parameters, subpopulation differentiation, recombination, divergence between Tospovirus species, and selective constraints on the TSWV genome. Our analysis has defined the geographical structure of TSWV, attributed possibly to founder effects. Also, we identify positive selection favouring divergence between Tospovirus species. At the species level, purifying selection has acted to preserve protein function, although certain amino acids appear to be under positive selection. This analysis provides demonstration of population structuring and species-wide population expansions in a multisegmented plant RNA virus, using sequence-based molecular population genetic analyses. It also identifies specific amino acid sites subject to selection within Bunyaviridae and estimates the level of genetic heterogeneity of a highly pathogenic plant RNA virus. The study of the variability of TSWV populations lays the foundation in the development of strategies for the control of other viral diseases in floral crops.     

Analysis of Tospovirus NSs Proteins in Suppression of Systemic Silencing

RNA silencing is a sequence-specific gene regulation mechanism that in plants also acts antiviral. In order to counteract antiviral RNA silencing, viruses have evolved RNA silencing suppressors (RSS). In the case of tospoviruses, the non-structural NSs protein has been identified as the RSS. Although the tomato spotted wilt virus (TSWV) tospovirus NSs protein has been shown to exhibit affinity to long and small dsRNA molecules, its ability to suppress the non-cell autonomous part of RNA silencing has only been studied to a limited extent. Here, the NSs proteins of TSWV, groundnut ringspot virus (GRSV) and tomato yellow ring virus (TYRV), representatives for three distinct tospovirus species, have been studied on their ability and strength to suppress local and systemic silencing. A system has been developed to quantify suppression of GFP silencing in Nicotiana benthamiana 16C lines, to allow a comparison of relative RNA silencing suppressor strength. It is shown that NSs of all three tospoviruses are suppressors of local and systemic silencing. Unexpectedly, suppression of systemic RNA silencing by NSs^TYRV was just as strong as those by NSs^TSWV and NSs^GRSV, even though NSs^TYRV was expressed in lower amounts. Using the system established, a set of selected NSs^TSWV gene constructs mutated in predicted RNA binding domains, as well as NSs from TSWV isolates 160 and 171 (resistance breakers of the Tsw resistance gene), were analyzed for their ability to suppress systemic GFP silencing. The results indicate another mode of RNA silencing suppression by NSs that acts further downstream the biogenesis of siRNAs and their sequestration. The findings are discussed in light of the affinity of NSs for small and long dsRNA, and recent mutant screen of NSs^TSWV to map domains required for RSS activity and triggering of Tsw-governed resistance.     

The organisation and interviral homologies of genes at the 3' end of tobacco rattle virus RNA1

The RNA1 of tobacco rattle virus (TRV) has been cloned as cDNA and the nucleotide sequence determined of 2 kb from the 3'-terminal region. The sequence contains three long open reading frames. One of these starts 5' of the cDNA and probably corresponds to the carboxy-terminal sequence of a 170-K protein encoded on RNA1. The deduced protein sequence from this reading frame shows homology with the putative replicases of tobacco mosaic virus (TMV) and tricornaviruses. The location of the second open reading frame, which encodes a 29-K polypeptide, was shown by Northern blot analysis to coincide with a 1.6-kb subgenomic RNA. The validity of this reading frame was confirmed by showing that the cDNA extending over this region could be transcribed and translated in vitro to produce a polypeptide of the predicted size which co-migrates in electrophoresis with a translation product of authentic viral RNA. The sequence of this 29-K polypeptide showed homology with two regions in the 30-K protein of TMV. This homology includes positions in the TMV 30-K protein where mutations have been identified which affect the transport of virus between cells. The third open reading frame encodes a potential 16-K protein and was shown by Northern blot hybridisation to be contained within the region of a 0.7-kb subgenomic RNA which is found in cellular RNA of infected cells but not virus particles. The many similarities between TRV and TMV in viral morphology, gene organisation and sequence suggest that these two viral groups may share a common viral ancestor.     

Resistance to tomato spotted wilt virus infection in transgenic tobacco expressing the viral nucleocapsid gene.

A recombinant plasmid containing the entire tomato spotted with virus (TSWV) nucleocapsid gene, with the exception of nucleotide encoding three N-terminal amino acids, was isolated by screening a complementary DNA library, prepared against random primed viral RNA, using a specific monoclonal antibody. The insert contained in plasmid pTSW1 was repaired and amplified by polymerase chain reaction, and the complete nucleocapsid protein gene was introduced into Nicotiana tabacum 'Samsun' by leaf disk transformation using Agrobacterium tumefaciens. Transgenic plants expressing the viral nucleocapsid protein were resistant to subsequent infection following mechanical inoculation with TSWV as indicated by a lack of systemic symptoms and little or no systemic accumulation of virus as determined by double antibody sandwich enzyme-liked immunosorbent assay. These results further extend the applicability of coat protein-mediated resistance, as previously demonstrated for a number of simple plant viruses composed of a positive-sense RNA genome encapsidated with a single species of coat protein, to a membrane-encapsidated, multi-component, negative-sense RNA virus.     

Nucleotide sequences in the RNA of mammalian leukemia and sarcoma viruses.

The nucleotide sequences in viral RNA from purified murine sarcoma and hamster leukemia viruses (S+H+) from HTG-1 cells and Rauscher leukemia virus (RLV) from JLS-V 9 cells have been examined by polynucleotide agarose affinity chromatography. There is at least one copy of poly(A) sequences per genomic viral RNA molecule. After heat denaturation of genomic viral RNA (S+H+), there are two types of viral subunits for 34S and 28S species: one that contains poly(A) sequences and one that does not. There are no detectable poly(U) tracts in the viral RNA. However, poly(C) sequences and poly(G) tracts were detected in viral RNA, although less poly(G) than poly(C) tracts were observed. In addition, heat-denatured genomic viral RNA has a greater affinity for poly(G) agarose column than native genomic viral RNA.     

Nucleotide sequence of beet western yellows virus RNA.

The nucleotide sequence of the genomic RNA (5641 nt) of beet western yellow virus (BWYV) isolated from lettuce has been determined and its genetic organization deduced. The sequence of the 3'terminal 2208 nt of RNA of a second BWYV isolate, obtained from sugarbeet, was also determined and was found to be very similar but not identical to that of the lettuce isolate. The complete sequence of BWYV RNA contains six long open reading frames (ORFs). A cluster of three of these ORFs, including the coat protein cistron, display extensive amino acid sequence homology with corresponding ORFs of a second luteovirus, the PAV isolate of barley yellow dwarf virus (BYDV) (1,2). The ORF corresponding to the putative viral RNA-dependant RNA polymerase, on the other hand, resembles that of southern bean mosaic virus. There is circumstantial evidence that expression of the BWYV RNA polymerase ORF may involve a translational frameshift mechanism. The ORF immediately following the coat protein cistron may be translated by in-frame readthrough of the coat protein cistron amber termination codon. Similar mechanisms have been proposed for expression of the corresponding ORFs of BYDV(PAV) (1).