Characterization of rice yellow mottle virus isolatesin Sudano-Sahelian areas

Summary.  The use of a panel of polyclonal antisera and monoclonal antibodies (MAbs) raised against West African isolates of rice yellow mottle virus (RYMV) in ELISA resulted in separation of 73 RYMV isolates into three distinct serogroups. Using a set of differential rice varieties, the serogroups could be correlated to two RYMV pathotypes. A relationship was found between serological properties of the RYMV isolates and their probable ecological origin. It was concluded that RYMV isolates originating in closely related agro-ecological zones displayed variability in coat protein and pathogenicity. This should be taken into account in developing tolerant or resistant rice varieties. Received September 17, 1996 Accepted January 10, 1997     

Nucleotide sequence of capsid protein gene of rice tungro bacilliform virus

Summary The sequence of 5,028 nucleotides, including one open reading frame (ORF), of rice tungro bacilliform virus (RTBV) dsDNA was determined. The predicted translational product comprises 1,675 amino acids and has M_r of 194, 134 (p194). The amino acid sequences of three tryptic fragments from the 32k capsid protein of RTBV (p32) were found in the predicted translational product indicating that the ORF codes for the RTBV capsid protein.     

Molecular analysis of two complete rice tungro bacilliform virus genomic sequences from India

The complete genomic sequences of two geographically distinct isolates of rice tungro bacilliform virus (RTBV) from India were determined. Both the sequences showed equal divergence from previously reported Southeast Asian isolates. Numerous insertions, deletions and substitutions, mostly in the intergenic regions, were found. The genome sizes were 7907 and 7934 bp respectively, 95 and 68 residues short of an infectious clone reported earlier. Between them, both the isolates showed high homology all along the genome, except for a 30-nucleotide insertion/deletion close to the 3' end of ORF III in one of them. Both the isolates indicated an unconventional start codon in ORF I, similar to the type isolate. In addition, as novel features, both the Indian isolates showed an unconventional start codon for ORF IV. Considering the low amounts of genome variability noticed in other RTBV isolates, the Indian isolates show that they have diverged sufficiently from the rest and should be considered belonging to a distinct strain.     

Inter- and intra-site genetic diversity of natural field populations of rice tungro bacilliform virus in the Philippines

Summary.  The genetic structure of rice tungro bacilliform virus (RTBV) populations within and between growing sites was analyzed in a collection of natural field isolates from different rice varieties grown in eight tungro-endemic sites of the Philippines. Total DNA extracts from 345 isolates were digested with EcoRV restriction enzyme and hybridized with a full-length probe of RTBV, a procedure shown in preliminary experiments capable of revealing high levels of polymorphism in RTBV field isolates. In the total population, 17 distinct EcoRV-based genome profiles (genotypes) were identified and used as indicators for virus diversity. Distinct sets of genotypes occurred in Isabela and North Cotabato provinces suggesting a geographic isolation of virus populations. However, among the sites in each province, there were few significant differences in the genotype compositions of virus populations. The number of genotypes detected at a site varied from two to nine with a few genotypes dominating. In general the isolates at a site persisted from season to season indicating a genetic stability for the local virus population. Over the sampling time, IRRI rice varieties, which have green leafhopper resistance genes, supported similar virus populations to those supported by other varieties, indicating that the variety of the host exerted no apparent selection pressures. Insect transmission experiments on selected RTBV field isolates showed that dramatic shifts in genotype and phenotype distributions can occur in response to host/environmental shifts. Accepted September 1, 1999/Received June 25, 1999     

The complete genome sequence of Piper yellow mottle virus (PYMoV)

This study reports the first complete genome sequence of Piper yellow mottle virus (PYMoV, KC808712) identified in black pepper. The genome is 7,622 nucleotides long, possessing four open reading frames (ORFs). ORF1, ORF2 and ORF4 of PYMoV are reported as hypothetical proteins of unknown function with a predicted molecular mass of 15.7, 17.1 and 17.9 kDa, respectively. ORF3 of PYMoV encodes a polyprotein of 218.6 kDa and consists of a viral movement protein (MP), trimeric dUTPase, zinc finger, retropepsin, RT-LTR, and RNAse H. Detailed PYMoV genome analysis confirmed that it is a member of the family Caulimoviridae, genus Badnavirus. Fragments of two additional novel sequences resembling those found in members of the family Caulimoviridae were also identified in the black pepper sample, and the viruses from which they were derived were tentatively named Piper DNA virus 1 and 2.     

Expression of rice yellow mottle virus coat protein enhances virus infection in transgenic plants

Summary. The disease caused by rice yellow mottle virus (RYMV) is a major, economically important constraint to rice production in Africa. RYMV is mechanically transmitted by a variety of agents, including insect vectors. The production of resistant rice varieties would be an important advance in the control of the disease and increase rice production in Africa. We produced transgenic plants of the Oryza sativa japonica variety, TP309, to express a RYMV coat protein gene (CP) and mutants of the CP under the control of a ubiquitin promoter. Transgenic plants expressing genes that encode wild-type CP (wt.CP), deleted CP (ΔNLS.CP), mRNA of the CP, or antisense CP sequences of the CP gene were characterised. Eighty per cent (80%) of independent transgenic lines analysed contained CP gene sequences. Transgenic plants were challenged with RYMV and produced two types of reactions. Most of the plants expressing antisense sequences of the CP and untranslatable CP mRNA exhibited a delay in virus accumulation of up to a week, and the level of virus accumulation was reduced compared with non-transgenic TP309 plants. Transgenic plants expressing RYMV wild-type CP (wt.CP) and deleted CP (ΔNLS.CP) accumulated the highest levels of virus particles. These results suggest that antisense CP and untranslatable CP mRNA induced moderate resistance, whereas transgenic CP enhanced virus infection.     

Development of SYBR Green I based real-time PCR assays for quantitative detection of Rice tungro bacilliform virus and Rice tungro spherical virus

Rice tungro disease, caused by simultaneous infection of Rice tungro bacilliform virus (RTBV) and Rice tungro spherical virus (RTSV), is an important cause of reduced rice harvests in South and Southeast Asia. Although various biological, serological and molecular techniques have been reported previously for the detection of RTBV and RTSV, a method that determines accurately the exact viral load in a tungro affected plant is still not available. The present study describes a method for the absolute quantitation of RTBV and RTSV using SYBR Green I based real-time PCR. The number of copies of RTBV DNA and RTSV RNA present in a tungro affected rice plant at two different time points after inoculation was determined. The sensitivity of real-time PCR based detection was found 10(3)- and 10(5)-folds higher than dot-blot hybridization and standard PCR assays respectively. In addition, the method was used for the simultaneous detection of RTBV and RTSV in a single reaction on the basis of melt curve analysis.     

The molecular diversity and evolution of Rice tungro bacilliform virus from Indian perspective

Rice tungro disease is caused by a combination of two viruses: Rice tungro spherical virus and Rice tungro bacilliform virus (RTBV). This study was performed with the objective to decipher the molecular variability and evolution of RTBV isolates present in the tungro-affected states of Indian subcontinent. Phylogenetic analysis based on ORF-I, ORF-II, and ORF-IV sequences showed distinct divergence of Indian RTBV isolates into two groups; one consisted isolates from Hyderabad (Andhra Pradesh), Cuttack (Orissa), and Puducherry and another from West Bengal, Chinsura West Bengal, and Kanyakumari (Tamil Nadu). The results obtained from phylogenetic analysis were further supported with the single nucleotide polymorphisms (SNPs), insertion and deletion (INDELs) and evolutionary distance analysis. In addition, sequence difference count matrix revealed a maximum of 56 (ORF-I), 13 (ORF-II) and 73 (ORF-IV) nucleotides differences among all the Indian RTBV isolates taken in this study. However, at the protein level these differences were not significant as revealed by K (a)/K (s) ratio calculation. Sequence identity at nucleotide and amino acid level was 92-100 % (ORF-I), 96-100 % (ORF-II), 94-100 % (ORF-IV) and 86-100 % (ORF-I), 98-100 % (ORF-II) and 95-100 % (ORF-IV), respectively, among Indian isolates of RTBV. The divergence of RTBV isolates into two independent clusters of Indian and non-Indian was shown with the help of the data obtained from phylogeny, SNPs, and INDELs, evolutionary distance analysis, and conserved motifs analysis. The important role of ORF-I and ORF-IV in RTBV diversification and adaptation to different rice growing regions is also discussed.     

Analysis of the complete DNA sequence of rice tungro bacilliform virus from southern India indicates it to be a product of recombination

The complete nucleotide sequence of an isolate of rice tungro bacilliform virus (RTBV), collected from Kanyakumari, India, where RTBV was reported recently for the first time, has been analyzed. Sequence comparison revealed that the RTBV isolate from Kanyakumari (RTBV-KK) has a high degree of identity to the two previously reported RTBV sequences from India, RTBV-AP and RTBV-WB, which had been collected from field locations about 10 years ago and 1000–2000 km away from the collection site of RTBV-KK. Most of the sequence domains reported previously in other RTBV isolates were found to be conserved in RTBV-KK. Closer inspection revealed RTBV-KK to be a possible recombinant between RTBV-AP and RTBV-WB in the genomic region encompassing the coat protein gene.     

Complete genome sequence of arracacha mottle virus

Arracacha mottle virus (AMoV) is the only potyvirus reported to infect arracacha (Arracacia xanthorrhiza) in Brazil. Here, the complete genome sequence of an isolate of AMoV was determined to be 9,630 nucleotides in length, excluding the 3′ poly-A tail, and encoding a polyprotein of 3,135 amino acids and a putative P3N-PIPO protein. Its genomic organization is typical of a member of the genus Potyvirus, containing all conserved motifs. Its full genome sequence shared 56.2 % nucleotide identity with sunflower chlorotic mottle virus and verbena virus Y, the most closely related viruses.     

Complete sequence analysis of rice transitory yellowing virus and its comparison to rice yellow stunt virus

Rice transitory yellowing virus (RTYV), a member of the genus Nucleorhabdovirus, is closely related to or synonymous with rice yellow stunt virus (RYSV). To clarify the relationship between RTYV and RYSV, we determined the nucleotide sequence of the RTYV genome. The RTYV genome consists of 14,029 nucleotides. The overall nucleotide identity between RTYV and RYSV was 98.5%, and the deduced amino acid sequence identities between the seven genes in RTYV and RYSV ranged from 82.3 to 99.7%. The sequence information from RTYV revealed that these two viruses should be categorized as members of the same species rather than distinct species.     

The adaptation of Rice yellow mottle virus to the eIF(iso)4G-mediated rice resistance

The rymv1-3 allele of the eIF(iso)4G-mediated resistance to Rice yellow mottle virus (RYMV) is found in a few Oryza glaberrima cultivars. The same resistance-breaking (RB) mutations emerged in the central domain of the VPg after inoculation of isolates of different strains. The RB mutations were fixed, often sequentially, at codons 41 and 52 which paralleled an increase in virus accumulation. RB mutations also emerged after inoculation of an avirulent infectious clone, indicating that they were generated de novo in resistant plants. Only virus isolates with a threonine at codon 49 of the VPg broke rymv1-3 resistance, those with a glutamic acid did not. A small subset of these isolates overcame rymv1-2 resistance, but following a specific pathway. Comparison with the RB process of rymv1-2, a resistance allele found in a few Oryza sativa cultivars, showed similarities in the mode of adaptation but revealed converse virulence specificity of the isolates.     

Detection of molecular variability in rice tungro bacilliform viruses from India using polymerase chain reaction-restriction fragment length polymorphism

Rice tungro bacilliform virus (RTBV) with rice tungro spherical virus (RTSV) causes the destructive tungro disease of rice. In order to ascertain the molecular variability of RTBV in India, primers were designed to amplify a polymorphic DNA fragment of the virus. Polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) analysis on a number of field isolates indicated mixed infections and molecular heterogeneity in the viral genome.     

Stability of rice yellow mottle virus and cellular compartmentalization during the infection process in Oryza sativa (L.)

Rice yellow mottle virus (RYMV) is icosahedral in morphology and known to swell in vitro, but the biological function of swollen particles remains unknown. Anion-exchange chromatography was used to identify three markedly stable forms of RYMV particles from infected plants: (1) an unstable swollen form lacking Ca2+ and dependent upon basic pH; (2) a more stable transitional form lacking Ca2+ but dependent upon acidic pH; and (3) a pH-independent, stable, compact form containing Ca2+. Particle stability increased over the time course of infection in rice plants: transitional and swollen forms were abundant during early infection (2 weeks postinfection), whereas compact forms increased during later stages of infection. Electron microscopy of infected tissue revealed virus particles in vacuoles of xylem parenchyma and mesophyll cells early in the time course of infection and suggested that vacuoles and other vesicles were the major storage compartments for virus particles. We propose a model in which virus maturation is associated with the virus accumulation in vacuoles. In this acidic compartment, virus particles may bind Ca2+ to produce a highly stable, compact form of the virus. The localization of subcellular RYMV isoforms in infected cells and the corresponding biological properties of the virus are discussed.