An analysis of spontaneous deletion sites in soil-borne wheat mosaic virus RNA2

Soil-borne wheat mosaic virus infectious clone and manipulation for gene-carrying capacity

A full-length infectious cDNA clone of soil-borne wheat mosaic virus (SBWMV; genus Furovirus; family Virgaviridae) was developed for agrobacterium delivery. The cloned virus can be agroinfiltrated to Nicotiana benthamiana for subsequent infection of wheat (Triticum aestivum, L.). The utility of the virus as a vector for gene silencing and expression was assessed through sequence insertions in multiple sites of RNA2. Virus-induced photobleaching was observed in N. benthamiana but not in wheat, despite the stability of the inserts. The SBWMV infectious clone can be used for further studies to investigate the biology of SBWMV through mutagenesis.

Stable deletions arising in the readthrough region of Soil-borne wheat mosaic virus RNA2 define the 5' limit of the functional promoter for the p19 subgenomic RNA

The appearance of de novo deletion mutations in the readthrough (RT) region (nucleotide positions 861-2591) downstream of the capsid protein (CP) gene of a Japanese strain of Soil-borne wheat mosaic virus RNA2 was examined using infectious transcripts. Mutant RNA2s with different deletions predominated in independent serial passage experiments but all best-adapted mutants retained the 3'-terminal portion of the RT gene in frame with the CP gene. The longest best-adapted mutation deleted the 1434 nucleotides between positions 1061 and 2494. When the RT protein was truncated by insertion of a termination codon plus an additional nucleotide to give a +1 frame-shift, after serial passages the progeny viruses regained the ability to express the C-terminal region of RT by an internal deletion. The 5' terminus of the p19 subgenomic RNA was identified at position 2598 and an essential transcription signal for this mRNA mapped between positions 2534 and 2563. A mutant in which this essential promoter element has been deleted cannot transcribe the p19 subgenomic RNA and has lost infectivity in planta. These results indicate that the 3'-terminal region of the RT gene has a major function in cis for expression of p19, which is essential for infecting plants. A reason for retaining the RT C-terminal region in stable deletion mutants is still unknown.

Detection and relative quantitation of Soil-borne cereal mosaic virus (SBCMV) and Polymyxa graminis in winter wheat using real-time PCR (TaqMan®)

Soil-borne cereal mosaic virus (SBCMV) was first reported affecting wheat crops in Italy in 1960 and has spread subsequently to many other European countries, including the UK. SBCMV causes a serious disease of wheat, reducing yield by up to 70%; growing resistant varieties represents the only economical means of control. Real-time RT-PCR and PCR assays based on TaqMan chemistry were developed for the detection and quantitation of SBCMV and its vector, Polymyxa graminis. Each assay incorporated an RNA or DNA specific internal control to facilitate quantitation. Nucleic acid extracts from SBCMV-infected plants were diluted in a nucleic acid extract from a healthy plant and amplified by real-time PCR to produce a standard curve. The standard curve was used to quantify the amount of SBCMV and P. graminis in plant samples. The sensitivity of the real-time assays were compared to established serological quantitation and conventional PCR methods by testing a range of SBCMV-infected wheat varieties. The results indicate that real-time assays were a 1000 times more sensitive than ELISA for the quantitation of SBCMV, and a 100 times more sensitive than conventional PCR for the quantitation of P. graminis. Real-time assays enabled sensitive, reproducible and specific detection of both virus and vector in wheat tissues. The real-time assays are potentially useful tools for determining variations in virus and vector concentrations in plant tissue from wheat varieties differing in resistance to SBCMV.

Effect of the Host and Temperature on the Formation of Defective RNAs Associated with Broad bean mottle virus Infection

ABSTRACT Previously, we demonstrated that Broad bean mottle virus (BBMV), a member of the genus Bromovirus, could accumulate RNA 2-derived defective interfering (DI) RNAs during infection. In this work, we study how host and environmental factors affect the accumulation of DI RNAs. Serial passages of BBMV through selected plant species reveal that, with low-multiplicity inocula, some systemic hosts (Vicia faba, Nicotiana clevelandii, and N. tabacum cv. Samsum) support DI RNA accumulation after the first passage cycle but other hosts (Phaseolus vulgaris, Pisum sativum, and Glycine max) do not. However, several passages with the high-multiplicity inocula can generate DI RNAs in pea plants. Local lesion hosts (Chenopodium quinoa, C. amaranticolor, and C. murale) remain free of the DI RNA components. The size of the de novo-formed DI RNAs depends on the host and on environmental conditions. For instance, broad bean plants cultivated in a greenhouse or in a growth chamber at 20 degrees C accumulated DI RNAs of 2.4 or 1.9 kb in size, respectively. A reverse trend was observed in pea plants. Lower temperatures greatly facilitated the formation of DI RNAs in broad bean and pea hosts after the first passage. The importance of these findings for the studies on DI RNAs are discussed.

Polymyxa graminis and the cereal viruses it transmits: a research challenge

SUMMARY Polymyxa graminis is a eukaryotic obligate biotrophic parasite of plant roots that belongs to a poorly studied discrete taxonomic unit informally called the 'plasmodiophorids'. P. graminis is non-pathogenic, but has the ability to acquire and transmit a range of plant viruses which cause serious diseases in cereal crop species and result in significant yield reductions. The viruses are protected from the environment within P. graminis resting spores ('cysts') that may remain dormant but viable for decades (probably until a suitable host plant is encountered). The persistent, soil-borne nature of these diseases makes the use of virus-resistant crop varieties currently the only practical and environmentally friendly means of control.

USEFUL WEBSITES

http://www.rothamsted.bbsrc.ac.uk/ppi/links/pplinks/plasmod/index.html, http://www.dpvweb.net/, http://www.rothamsted.bbsrc.ac.uk/ppi/Iwgpvfv/index.html, http://www.rothamsted.bbsrc.ac.uk/ppi/links/pplinks/bymoviruses/index.html, http://oak.cats.ohiou.edu/~braselto/plasmos/

Construction of full-length cDNA clones to Soil-borne wheat mosaic virus RNA1 and RNA2, from which infectious RNAs are transcribed In vitro: virion formation and systemic infection without expression of the N-terminal and C-terminal extensions to the capsid protein

The 19-kDa capsid protein (CP) of Soil-borne wheat mosaic furovirus (SBWMV) is encoded in the 5'-terminal region of RNA2. In addition to CP, two CP-related proteins are translated from SBWMV RNA2: (1) a 24-kDa protein (N-CP) with an N-terminal 40-amino-acid extension initiated at an upstream in-frame CUG codon; and (2) an 83-kDa protein (CP-RT) with an about 580-amino-acid, C-terminal extension by partial translational readthrough at the UGA termination codon at the end of the CP gene. We examined requirements for N-CP and CP-RT on virion formation and systemic infection in wheat plants using full-length cDNA clones, from which infectious RNA can be transcribed in vitro. RNA2 mutants, which could not synthesize N-CP, CP-RT, or either infected wheat plants systemically in combination with the wild-type RNA1 transcripts, produced rod-shaped virus particles in uninoculated upper leaves. Original mutations which abolished translation of N-CP and CP-RT were confirmed on RNA2 extracted from purified virus from the upper leaves by nucleotide sequence analysis. These results indicate that neither N-terminal nor C-terminal extensions to the CP are required for virion formation and systemic infection of SBWMV in wheat plants.

Similarity and divergence among viruses in the genus Furovirus

Nucleotide sequences of RNAs 1 and 2 of a Japanese strain of soil-borne wheat mosaic virus (SBWMV), the type species of the genus Furovirus, and sorghum chlorotic spot virus (SCSV) were determined from cloned cDNA. The relationship among the Japanese and US strains of SBWMV, SCSV, oat golden stripe virus (OGSV), and recently proposed Chinese wheat mosaic and European wheat mosaic viruses (CWMV and EWMV) were examined at the nucleotide and amino acid levels. Pairwise comparisons of genome-encoded proteins among the six viruses showed that the US strains of SBWMV and CWMV were the most closely related pair in RNA 1 and the Japanese strains of SBWMV and EWMV were most closely related in RNA 2. SCSV was most distantly related to the other five viruses. Phylogenetic analysis indicated that there may have been an ancient reassortment between RNAs 1 and 2 of the four wheat-infecting viruses and OGSV, while SCSV was shown to have separated from the rest before the other five viruses diverged. The fact that CWMV and EWMV have almost identical biological properties as well as the sequence similarities to the two strains of SBWMV suggests that they be regarded as strains of SBWMV, considering that SBWMV consists of genetically diverged strains. OGSV and SCSV are distinct in biological properties in addition to genetic divergence in the genus Furovirus.

Non-AUG translation initiation in a plant RNA virus: a forty-amino-acid extension is added to the N terminus of the soil-borne wheat mosaic virus capsid protein

RNA 2 of soil-borne wheat mosaic virus (SBWMV), the type species of the genus Furovirus, encodes a protein previously hypothesized to be initiated at an in-frame non-AUG codon upstream of the AUG initiation codon (nucleotide positions 334 to 336) for the 19-kDa capsid protein. Site-directed mutagenesis and in vitro transcription and translation analysis indicated that CUG (nucleotides 214 to 216) is the initiation codon for a protein with a calculated molecular mass of 25 kDa composed of a 40-amino-acid extension to the N terminus of the 19-kDa capsid protein. A stable deletion mutant, which was isolated after extensive passages of a wild-type SBWMV, contained a mixture of two deleted RNA 2's, only one of which coded for the 25-kDa protein. The amino acid sequence of the N-terminal extension was moderately conserved and the CUG initiation codon was preserved among three SBWMV isolates from Japan and the United States. This amino acid sequence conservation, as well as the retention of expression of the 25-kDa protein in the stable deletion mutant, suggests that the 25-kDa protein is functional in the life cycle of SBWMV. This is the first report of a non-AUG translation initiation in a plant RNA virus genome.

Monoclonal antibodies detect a single amino Acid difference between the coat proteins of soilborne wheat mosaic virus isolates: implications for virus structure

ABSTRACT Four monoclonal antibodies (MAbs) were prepared against an isolate of soilborne wheat mosaic furovirus from Oklahoma (SBWMV Okl-7). Three MAbs had different reactivities in tests on SBWMV isolates from Nebraska (Lab1), France, and Japan. One MAb (SCR 133) also reacted with oat golden stripe furovirus. None of the MAbs cross-reacted with other rod-shaped viruses including beet necrotic yellow vein furovirus, potato mop-top furovirus, and tobacco rattle tobravirus. Sequence analysis of nucleotides between 334 and 1,000 of RNA 2, the region that encodes the coat protein (CP) and the first 44 amino acids of a readthrough protein, of the four SBWMV isolates revealed up to 27 base changes from the published sequence of a Nebraska field isolate of SBWMV. Most changes were translationally silent, but some caused differences of one to three amino acids in residues located near either the N- or C-terminus of the CPs of the different isolates. Two further single amino acid changes were found at the beginning of the readthrough domain of the CP-readthrough protein. Some of these amino acid changes could be discriminated by MAbs SCR 132, SCR 133, and SCR 134. Peptide scanning (Pepscan) analysis indicated that the epitope recognized by SCR 134 is located near the N-terminus of the CP. SCR 132 was deduced to react with a discontinuous CP epitope near the C-terminus, and SCR 133 reacted with a surface-located continuous epitope also near the C-terminus. Predictions of CP structure from computer-assisted three-dimensional model building, by comparison with the X-ray fiber diffraction structure of tobacco mosaic virus, suggested that the three CP amino acids found to differ between isolates of SBWMV were located near the viral surface and were in regions predicted to be antigenic.

Ribulose-1,5-bisphosphate carboxylase/oxygenase gene expression and diversity of Lake Erie planktonic microorganisms

Carbon dioxide fixation is carried out primarily through the Calvin-Benson-Bassham reductive pentose phosphate cycle, in which ribulose-1, 5-bisphosphate carboxylase/oxygenase (RubisCO) is the key enzyme. The primary structure of the large subunit of form I RubisCO is well conserved; however, four distinct types, A, B, C, and D, may be distinguished, with types A and B and types C and D more closely related to one another. To better understand the environmental regulation of RubisCO in Lake Erie phytoplanktonic microorganisms, we have isolated total RNA and DNA from four Lake Erie sampling sites. Probes prepared from RubisCO large-subunit genes (rbcL) of the freshwater cyanobacterium Synechococcus sp. strain PCC6301 (representative of type IB) and the diatom Cylindrotheca sp. strain N1 (representative of type ID) were hybridized to the isolated RNA and DNA. To quantitate rbcL gene expression for each sample, the amount of gene expression per gene dose (i.e., the amount of mRNA divided by the amount of target DNA) was determined. With a limited number of sampling sites, it appeared that type ID (diatom) rbcL gene expression per gene dose decreased as the sampling sites shifted toward open water. By contrast, a similar trend was not observed for cyanobacterial (type IB) rbcL gene expression per gene dose. Complementary DNA specific for rbcL was synthesized from Lake Erie RNA samples and used as a template for PCR amplification of portions of various rbcL genes. Thus far, a total of 21 clones of rbcL genes derived from mRNA have been obtained and completely sequenced from the Ballast Island site. For surface water samples, deduced amino acid sequences of five of six clones appeared to be representative of green algae. In contrast, six of nine sequenced rbcL clones from 10-m-deep samples were of chromophytic and rhodophytic lineages. At 5 m deep, the active CO2-fixing planktonic organisms represented a diverse group, including organisms related to Chlorella ellipsoidea, Cylindrotheca sp. strain N1, and Olisthodiscus luteus. Although many more samplings at diverse sites must be accomplished, the discovery of distinctly different sequences of rbcL mRNA at different water depths suggests that there is a stratification of active CO2-fixing organisms in western Lake Erie.

Sequence analysis of wheat and oat furovirus capsid protein genes suggests that oat golden stripe virus is a strain of soil-borne wheat mosaic virus

In northern blots, cDNA probes prepared to soil-borne wheat mosaic virus (SBWMV) RNA-1 and RNA-2 hybridized to RNA-1 and RNA-2, respectively, from a UK isolate of oat golden stripe virus (OGSV), as well as to their homologous RNAs. RT-PCR was used to amplify, clone and sequence a region of about 750 nucleotides spanning the capsid protein gene and part of the readthrough protein on RNA-2 from OGSV, a French isolate of SBWMV and two stable deletion mutants (Lab1 and Okl-7) of SBWMV isolates from Nebraska and Oklahoma respectively. There was very high (96.7-99.1%) nucleotide homology between all these sequences and the wild-type SBWMV sequences from Nebraska and Oklahoma. OGSV was more similar to SBWMV from France and Nebraska than were any of the isolates to SBWMV from Oklahoma. Of the few differences in the deduced amino acid sequences of the capsid proteins from the different isolates, OGSV differed from all SBWMV isolates only in one amino acid (isoleucine for valine at position 88). The high degree of similarity suggests that OGSV may best be classified as an oat strain of SBWMV.

The complete nucleotide sequence of RNA-2 of a fungally-transmitted UK isolate of barley mild mosaic bymovirus and identification of amino acid combinations possibly involved in fungus transmission

The complete nucleotide sequence of RNA-2 of a fungally-transmitted UK isolate of barley mild mosaic bymovirus (BaMMV isolate UK-F) was determined and compared with other published sequences, particularly UK-M, an isolate derived from the same source but which has been mechanically passaged for several years, has a deletion of about 1 kb and cannot be fungally transmitted. From an alignment of the BaMMV RNA-2 encoded protein with that for barley yellow mosaic bymovirus (BaYMV), several regions of consistent homology were identified and extensive searches made for similarities with the proteins of other fungally-transmitted viruses, especially amongst the furovirus capsid readthrough proteins which seem especially prone to deletion and which have already been implicated in fungus transmission. The amino acid combinations ER (glutamic acid-arginine) or QR (glutamine-arginine) were found consistently in all of the viruses. They occurred in positions predicted to be on the outside of the protein, and therefore available for interaction with the fungus vector, and were also within the regions prone to spontaneous deletion. In view of the lack of other structural or sequence homologies, it is suggested that these motifs are strong candidates for involvement in fungus transmission.

Fungal transmission of plant viruses

Thirty soilborne viruses or virus-like agents are transmitted by five species of fungal vectors. Ten polyhedral viruses, of which nine are in the family Tombusviridae, are acquired in the in vitro manner and do not occur within the resting spores of their vectors, Olpidium brassicae and O. bornovanus. Fungal vectors for other viruses in the family should be sought even though tombusviruses are reputed to be soil transmitted without a vector. Eighteen rod-shaped viruses belonging to the furo- and bymovirus groups and to an unclassified group are acquired in the in vivo manner and survive within the resting spores of their vector, O. brassicae, Polymyxa graminis, P. betae, and Spongospora subterranea. The viral coat protein has an essential role in in vitro transmission. With in vivo transmission a site in the coat protein-read through protein (CP-RT) of beet necrotic yellow vein furovirus determines vector transmissibility as does a site in a similar 98-kDa polyprotein of barley mild mosaic bymovirus. The mechanisms by which virions move (or are moved) into and out of the protoplasm of zoospores or of thalli needs study.