Sequence analysis of a soilborne wheat mosaic virus isolate from Italy shows that it is the same virus asEuropean wheat mosaic virus andSoilborne rye mosaic virus

The complete sequence of the two RNAs of a furovirus isolate from durum wheat in Italy was determined. Sequence comparisons and phylogenetic analysis were done to compare the Italian virus withSoilborne wheat mosaic virus (SBWMV) from the USA and with furovirus sequences recently published asEuropean wheat mosaic virus (EWMV), from wheat in France, andSoilborne rye mosaic virus (SBRMV), from rye and wheat in Germany. Over the entire genome, the Italian isolate RNA1 and RNA2 had respectively 97.5% and 98.6% nucleotide identity with EWMV, 95.5% and 85.8% with SBRMV-G and 70.6% and 64.5% with SBWMV. The Italian isolate was therefore clearly distinct from SBWMV The European isolates all appear to belong to the same virus and the nameSoilborne cereal mosaic virus may resolve earlier ambiguities.     

Sequence analysis of a soilborne wheat mosaic virus isolate from Italy shows that it is the same virus asEuropean wheat mosaic virus andSoilborne rye mosaic virus

The complete sequence of the two RNAs of a furovirus isolate from durum wheat in Italy was determined. Sequence comparisons and phylogenetic analysis were done to compare the Italian virus withSoilborne wheat mosaic virus (SBWMV) from the USA and with furovirus sequences recently published asEuropean wheat mosaic virus (EWMV), from wheat in France, andSoilborne rye mosaic virus (SBRMV), from rye and wheat in Germany. Over the entire genome, the Italian isolate RNA1 and RNA2 had respectively 97.5% and 98.6% nucleotide identity with EWMV, 95.5% and 85.8% with SBRMV-G and 70.6% and 64.5% with SBWMV. The Italian isolate was therefore clearly distinct from SBWMV The European isolates all appear to belong to the same virus and the nameSoilborne cereal mosaic virus may resolve earlier ambiguities.     

Use of Monoclonal Antibodies for the Serological Differentiation of Wheat and Oat Furoviruses

Twenty monoclonal antibodies (MAbs) to Chinese wheat mosaic virus (CWMV) were produced by immunizing BALB/c mice with purified CWMV. These MAbs and polyclonal antisera against CWMV and soil-borne wheat mosaic virus Oklahoma isolate (SBWMV-Okl) were used to differentiate the wheat and oat furoviruses, CWMV, SBWMV, oat golden stripe virus (OGSV) and European wheat mosaic virus (EWMV). Enzyme-linked immunosorbent assays and Western blotting showed that the dominant epitope(s) of CWMV was shared partially with OGSV whereas those of SBWMV were shared with CWMV, OGSV and EWMV in varying degrees. When CWMV virions were briefly digested with trypsin, coat protein fragments of about 12, 10 and 8 kDa were produced and these reacted with the polyclonal antisera and some MAbs, indicating that they contained dominant epitopes of CWMV and SBWMV. Computer analysis of the coat protein sequences suggested that the epitope shared between CWMV and OGSV was located at amino acids 35–40, whereas the dominant epitopes of SBWMV, which were shared with CWMV, EWMV and OGSV, were in the C terminal half of the coat protein     

Soilborne wheat mosaic virus movement protein and RNA and wheat spindle streak mosaic virus coat protein accumulate inside resting spores of their vector, Polymyxa graminis

To study virus-vector interactions between Soilborne wheat mosaic virus (SBWMV) or Wheat spindle streak mosaic virus (WSSMV) and Polymyxa graminis Ledingham, P. graminis was propagated in plants grown hydroponically. P. graminis accumulated to high levels in several barley cultivars tested. Multiple developmental stages of P. graminis could be identified in infected barley roots. Accumulation of SBWMV and WSSMV inside P. graminis sporosori in the roots of soil-grown winter wheat and hydroponically grown barley was compared to determine if data obtained from plants naturally infected plants and plants infected by manual inoculation were similar. WSSMV coat protein (CP), SBWMV RNAs, SBWMV movement protein but not SBWMV CP were detected in both soil-grown winter wheat and hydroponically grown barley roots. These data are the first direct evidence that SBWMV and WSSMV are internalized by P. graminis.     

Genome-wide association analysis identified SNPs closely linked to a gene resistant to Soil-borne wheat mosaic virus

Key message

Using association and linkage mapping, two SNP markers closely linked to the SBWMV resistance gene on chromosome 5D were identified and can be used to select the gene in breeding.

Abstract

Soil-borne wheat mosaic virus (SBWMV) disease is a serious viral disease of winter wheat growing areas worldwide. SBWMV infection can significantly reduce grain yield up to 80 %. Developing resistant wheat cultivars is the only feasible strategy to reduce the losses. In this study, wheat Infinium iSelect Beadchips with 9 K wheat SNPs were used to genotype an association mapping population of 205 wheat accessions. Six new SNPs from two genes were identified to be significantly associated with the gene for SBWMV resistance on chromosome 5D. The SNPs and Xgwm469, an SSR marker that has been reported to be associated with the gene, were mapped close to the gene using F₆-derived recombinant inbred lines from the cross between a resistant parent ‘Heyne’ and a susceptible parent ‘Trego’. Two representative SNPs, wsnp_CAP11_c209_198467 and wsnp_JD_c4438_5568170, from the two linked genes in wheat were converted into KBioscience Competitive Allele-Specific Polymerase assays and can be easily used in marker-assisted selection to improve wheat resistance to SBWMV in breeding.     

Evidence that soilborne wheat mosaic virus moves long distance through the xylem in wheat

Summary Soilborne wheat mosaic virus (SBWMV) is a member of the genusFurovirus of plant viruses. SBWMV is transmitted to wheat roots by the plasmodiophorid vectorPolymyxa graminis. Experiments were conducted to determine the path for SBWMV transport from roots to leaves. The results of immunogold labeling suggest that SBWMV enters and moves long distance through the xylem. SBWMV may enter primary xylem elements before cell death occurs and then move upward in the plant after the xylem has matured into hollow vessels. There is also evidence for lateral movement between adjacent xylem vessels.Abbreviations SBWMV Soilborne wheat mosaic virus - TMV Tobacco mosaic virus - BMV Brome mosaic virus - PMTV Potato mop-top virus - BNYVV Beet necrotic yellow vein virus - WSSMV Wheat spindle streak mosaic virus - WSMV Wheat streak mosaic virus     

山东烟台小麦土传病毒病由小麦黄花叶病毒和土传小麦花叶病毒相关病毒复合侵染所致

在山东省烟台地区的小麦上发生一种由土壤中禾谷多粘菌Polymyxa graminis传播的病毒病,感病小麦植株表现矮化褪绿和花叶症状.我们于1997年4月从病区采集感病小麦植株,进行了病毒种类鉴定.直接电镜观察发现有二种病毒粒子,一种粒子呈棒状,占大多数,其长度约为300nm和150nm; 另一种粒子呈线状,数量较少,长度为500nm～700nm.免疫电镜结果表明,棒状病毒粒子仅与土传小麦花叶病毒(soil-borne wheat mosaic virus, SBWMV)抗血清反应,而不与小麦黄花叶病毒(wheat yellow mosaic virus,WYMV)抗血清和小麦梭条斑花叶病毒(wheat spindle streat mosaic virus,WSSMV)抗血清反应;反之,线状病毒仅与WYMV、WSSMV抗血清反应,而不与SBWMV抗血清反应.用WYMV和SBWMV两种抗血清同时进行修饰时,线状病毒粒子和棒状病毒粒子均发生反应.     

High Plains wheat mosaic virus: An enigmatic disease of wheat and corn causing the High Plains disease

Brief historyIn 1993, severe mosaic and necrosis symptoms were observed on corn (maize) and wheat from several Great Plains states of the USA. Based on the geographical location of infections, the disease was named High Plains disease and the causal agent was tentatively named High Plains virus. Subsequently, researchers renamed this virus as maize red stripe virus and wheat mosaic virus to represent the host and symptom phenotype of the virus. After sequencing the genome of the pathogen, the causal agent of High Plains disease was officially named as High Plains wheat mosaic virus. Hence, High Plains virus, maize red stripe virus, wheat mosaic virus, and High Plains wheat mosaic virus (HPWMoV) are synonyms for the causal agent of High Plains disease.TaxonomyHigh Plains wheat mosaic virus is one of the 21 definitive species in the genus Emaravirus in the family Fimoviridae.VirionThe genomic RNAs are encapsidated in thread‐like nucleocapsids in double‐membrane 80–200 nm spherical or ovoid virions.Genome characterizationThe HPWMoV genome consists of eight single‐stranded negative‐sense RNA segments encoding a single open reading frame (ORF) in each genomic RNA segment. RNA 1 is 6,981‐nucleotide (nt) long, coding for a 2,272 amino acid protein of RNA‐dependent RNA polymerase. RNA 2 is 2,211‐nt long and codes for a 667 amino acid glycoprotein precursor. RNA 3 has two variants of 1,439‐ and 1,441‐nt length that code for 286 and 289 amino acid nucleocapsid proteins, respectively. RNA 4 is 1,682‐nt long, coding for a 364 amino acid protein. RNA 5 and RNA 6 are 1,715‐ and 1,752‐nt long, respectively, and code for 478 and 492 amino acid proteins, respectively. RNA 7 and RNA 8 are 1,434‐ and 1,339‐nt long, code for 305 and 176 amino acid proteins, respectively.Biological propertiesHPWMoV can infect wheat, corn (maize), barley, rye brome, oat, rye, green foxtail, yellow foxtail, and foxtail barley. HPWMoV is transmitted by the wheat curl mite and through corn seed.Disease managementGenetic resistance against HPWMoV in wheat is not available, but most commercial corn hybrids are resistant while sweet corn varieties remain susceptible. Even though corn hybrids are resistant to virus, it still serves as a green bridge host that enables mites to carry the virus from corn to new crop wheat in the autumn. The main management strategy for High Plains disease in wheat relies on the management of green bridge hosts. Cultural practices such as avoiding early planting can be used to avoid mite buildup and virus infections.     

Analysis of nucleotide sequence of wheat yellow mosaic virus genomic RNAs

Wheat yellow mosaic virus (WYMV) isolate HC was used for viral cDNA synthesis and sequencing. The results show that the viral RNA1 is 7629 nueleotides encoding a polyprotein with 2407 amino acids, from which seven putative proteins may be produced by an autolytie cleavage processing besides the viral coat protein. The RNA2 is 3639 nueleotides and codes for a polypretein of 903 amino acids, which may contain two putative non-structural proteins. Although WYMV shares a similarity in genetic organization to wheat spindle streak mosaic virus (WSSMV), the identities in their nucleotide sequences or deduced amino acid sequences are as low as 70% and 75 % respectively. Based on this result, it is confirmed that WYMV and WSSMV are different species within Bymovirus.     

A conserved locus conditioning Soil-borne wheat mosaic virus resistance on the long arm of chromosome 5D in common wheat

Soil-borne wheat mosaic virus (SBWMV) is considered to be one of the most important diseases in winter wheat regions of the central and southeastern United States. Utilization of resistant cultivars is the most efficient and environmentally friendly means of control. To identify potential quantitative trait loci (QTL) or effective gene(s) for SBWMV resistance, two independent recombinant inbred line populations, Pioneer 26R61/AGS 2000 (PR61/A2000, 178 lines) and AGS 2020/LA 95135 (A2020/LA, 130 lines), were developed. Pioneer 26R61 and AGS 2020 were resistant to SBWMV, and AGS 2000 and LA 95135 were susceptible. Based on the whole genome genotyping for the PR61/A2000 population and targeted mapping of chromosome 5D for the A2020/LA, the same major QTL QSbm.uga-5DL was identified in all environments with highly significant LOD values, explaining up to 62 and 65?% of the total phenotypic variation in the PR61/A2000 and A2020/LA populations, respectively. The location of the resistance QTL coincided with previously published SBCMV resistance genes Sbm1, Sbm _Claire and Sbm _Tremie on the long arm of chromosome 5D. A conserved locus was therefore proposed for conditioning SBWMV/SBCMV resistance in common wheat. Validation of the QTL using the flanking markers Xbarc177 and Xbarc161 in three cultivars and three elite lines with Pioneer 26R61 in their pedigrees indicated that the markers were suitable for marker-assisted selection.     

First Report of Soil‐Borne Wheat Mosaic Virus (SBWMV)‐Infecting Triticale in Poland

The virus in naturally infected, stunted triticale plants was identified as soil‐borne wheat mosaic virus (SBWMV). The infected plants were collected in the Southern Wielkopolska region (Western Poland). Molecular analysis including RT‐PCR, and sequencing of the complete coding sequence of coat protein gene, was performed. The sequence of the Polish isolate of SBWMV (SBWMV‐Pol1) shared 100, 99 and 98% identities with the corresponding regions of De1 (AF519799), OKL‐1 (X81639) and US‐Nebraska (L07938) isolates of SBWMV, respectively. Phylogenetic analyses showed that the Polish isolate, SBWMV‐Pol1, clustered together with other SBWMV isolates. This is the first report of the occurrence of SBWMV in Poland and the second of its presence in Europe.     

Tobacco mosaic virus RNA directs the synthesis of a coat protein peptide in a cell-free system from wheat

Tobacco mosaic virus (TMV) RNA stimulates amino acid incorporation into protein in cell-free extracts from wheat germ, rye embryo and Escherichia coli. The properties of the wheat germ system are examined and the nature of the viral RNA-induced products studied with the aid of a virus mutant carrying a threonine → methionine replacement in its coat protein. A peptide containing this methionine residue is present in tryptic digests of mutant RNA-directed cell-free products, and is absent from digests of wild type RNA-directed products. The undigested cell-free product contains a very large number of polypeptides with molecular weights from 10,000 to 140,000, but little or no synthesis of correct sized coat protein is observed.     

The complete nucleotide sequence of the potexvirus white clover mosaic virus.

The complete nucleotide sequence (5845 nucleotides) of the genomic RNA of the potexvirus white clover mosaic virus (WC1MV) has been determined from a set of overlapping cDNA clones. Forty of the most 5'-terminal nucleotides of WC1MV showed homology to the 5' sequences of other potexviruses. The genome contained five open reading frames which coded for proteins of Mr 147, 417, Mr 26,356, Mr 12,989, Mr 7,219 and Mr 20,684 (the coat protein). The Mr 147,417 protein had domains of amino acid sequence homology with putative polymerases of other RNA viruses. The Mr 26,356 and Mr 12,989 proteins had homology with proteins of the hordeivirus barley stripe mosaic virus RNA beta and the furovirus beet necrotic yellow vein virus (BNYVV) RNA-2. A portion of the Mr 26,356 protein was also conserved in the cylindrical inclusion proteins of two potyviruses. The Mr 7,219 protein had homology with the 25K putative fungal transmission factor of BNYVV RNA-3.     

Occurrence of fungally transmitted wheat mosaic viruses in China

A soil-borne mosaic disease of winter wheat in Sichuan, Shaanxi, Hubei and Henan provinces was associated with infection by a virus with filamentous particles and that in Shandong, Anhui, Jiangsu and Zhejiang provinces by co-infection with this virus and soil-borne wheat mosaic virus. The virus with filamentous particles was identified serologically, by particle sizes, cytopathology and the molecular weights of the coat protein and the two RNA species to be either wheat spindle streak mosaic virus (WSSMV) or wheat yellow mosaic virus. These viruses are probably isolates of the same virus and the name WSSMV is preferred. In baiting tests using infested soil, the dilution endpoints for detecting WSSMV were 1/625-1/15625, and for the fungus vector, Polymyxa graminis, 1/3125-1/15625.     

Nucleotide sequence of Chinese rape mosaic virus (oilseed rape mosaic virus), a crucifer tobamovirus infectious on Arabidopsis thaliana

The complete nucleotide sequence of Chinese rape mosaic virus has been determined. The virus is a member of the tobamovirus genus of plant virus and is able to infect Arabidopsis thaliana (L.) Heynh systemically. The analysis of the sequence shows a gene array that seems to be characteristic of crucifer tobamoviruses and which is slightly different from the one most frequently found in tobamoviruses. Based on gene organization and on comparisons of sequence homologies between members of the tobamoviruses, a clustering of crucifer tobamoviruses is proposed that groups the presently known crucifer tobamovirus into two viruses with two strains each. A name change of Chinese rape mosaic virus to oilseed rape mosaic virus is proposed.Abbreviations 2-ME 2-mercaptoethanol - EDTA ethylenediaminetetraacetic acid - SDS sodium dodecyl sulfate - UTR untranslated region - MP movement protein - CP capsid protein - CRMV Chinese rape mosaic virus - TVCV turnip vein clearing virus - PaMMV paprika mild mottle virus - PMMV-I pepper mild mottle virus (Italian isolate) - PMMV-S pepper mild mottle virus (Spanish isolate) - ToMV tomato mosaic virus - TMV tobacco mosaic virus - TMGMV tobacco mild green mosaic virus - ORSV odontoglossum ringspot virus - SHMV sunn hemp mosaic virus - CGMMV cucumber green mottle mosaic virus - ORMV oilseed rape mosaic virus     

Evidence of HIV exposure and transient seroreactivity in archived HIV-negative severe hemophiliac sera

Amino acid sequence analyses indicate that the Soilborne wheat mosaic virus (SBWMV) 19K protein is a cysteine-rich protein (CRP) and shares sequence homology with CRPs derived from furo-, hordei-, peclu- and tobraviruses. Since the hordei- and pecluvirus CRPs were shown to be pathogenesis factors and/or suppressors of RNA silencing, experiments were conducted to determine if the SBWMV 19K CRP has similar activities. The SBWMV 19K CRP was introduced into the Potato virus X (PVX) viral vector and inoculated to tobacco plants. The SBWMV 19K CRP aggravated PVX-induced symptoms and restored green fluorescent protein (GFP) expression to GFP silenced tissues. These observations indicate that the SBWMV 19K CRP is a pathogenicity determinant and a suppressor of RNA silencing.     

Tolerance to ryegrass mosaic virus and its inheritance

Plant yield within and between four cultivars of perennial ryegrass infected with ryegrass mosaic virus (RMV) was closely related to symptom severity. Distribution of symptom severity was continuous in four perennial ryegrass and four Italian ryegrass cultivars infected with a severe RMV isolate, and also in another perennial ryegrass cultivar infected with a severe isolate of the virus, a mild one and one of intermediate severity. Symptom expression was polygenically inherited in both Italian (cv. RvP) and perennial (cv. S.24) ryegrass. Both additive and non-additive genetic variation was present in RvP, but the variation in S.24 was additive only. No significant maternal inheritance was present in either species.     

The complete sequence of a sugarcane mosaic virus isolate causing maize dwarf mosaic disease in China

The complete sequence of a potyvirus from maize in Zhejiang Province was determined. The RNA was 9596 nucleotides long, excluding the 3'-poly (A) tail, and there was a single long open reading frame (ORF) of 9192 nts encoding a 346.1 ku polyprotein. The polyprotein had substantial amino acid sequence homology with those encoded by the RNAs of a Chinese isolate of sorghum mosaic virus (SrMV-C) and a Bulgarian isolate of maize dwarf mosaic virus, but it was most closely related to sugarcane mosaic virus (SCMV) isolates, for which only partial sequences have been published. According to the published criteria for distinguishing potyviruses, the sequence reported here is clearly a strain of SCMV, but it also showed a surprisingly high amino acid homology with SrMV-C in the HC-Pro, P3 and Cl proteins.     

The complete sequence of a sugarcane mosaic virus isolate causing maize dwarf mosaic disease in China

The complete sequence of a potyvirus from maize in Zhejiang Province was determined. The RNA was 9596 nucleotides long, excluding the 3′-poly (A) tail, and there was a single long open reading frame (ORF) of 9192 nts encoding a 346.1 ku polyprotein. The polyprotein had substantial amino acid sequence homology with those encoded by the RNAs of a Chinese isolate of sorghum mosaic virus (SrMV-C) and a Bulgarian isolate of maize dwarf mosaic virus, but it was most closely related to sugarcane mosaic virus (SCMV) isolates, for which only partial sequences have been published. According to the published criteria for distinguishing potyviruses, the sequence reported here is clearly a strain of SCMV, but it also showed a surprisingly high amino acid homology with SrMV-C in the HC-Pro, P3 and Cl proteins.