The role of weed hosts and the distribution and activity of vector nematodes in the ecology of tobacco rattle virus

At a site in eastern Scotland, nine common species of arable weeds were infected with tobacco rattle virus (TRV), and some of these, notably Viola arvensis and Stellaria media, comprised an overwintering reservoir of the virus. TRV was seed-borne both in naturally and in experimentally infected V. arvensis (2–10%), and occasionally in other weed species. In the glasshouse at 20 ^oC a naturally infective population of vector nematodes (Tricho-dorus spp.) kept in soil free of plants retained its infectivity for 20 wk, although few Trichodorus survived for this period. In the field, the incidence of TRV infection in potato (spraing disease) in plots kept free of weeds for 1–5 years was 3–4 times that in weed-infested plots but Trichodorus numbers did not differ appreciably between the two treatments. Presumably the virus is retained for long periods in its vectors and these feed on potato more frequently when other hosts are not available. Weeds are probably important in the long term as hosts of both TRV and its vectors, but in the short term weed control seems unlikely to prevent potato spraing because of the long persistence of TRV in vector populations. In the field, Trichodorus accumulated near the interface between topsoil and subsoil, and the incidence of spraing was greatest where the topsoil was shallowest. When cucumber seedlings were exposed to virus-carrying Trichodorus, TRV reached a greater concentration in roots at 20 ^oC than at 24 ^oC, and the virus was not detected in roots at 29 ^oC. In a sandy soil, TRV was transmitted only when the water content exceeded 15%, and at least 30 % water was needed for maximum transmission. Annual records of rainfall and spraing disease suggest that spraing is most prevalent when the summer is wettest. TRV is not confined to cultivated land. Stabilized sand dunes supporting a pure stand of Ammophila armaria were colonized by Trichodorus pachyder-mus, but TRV was detected only where the plant community had enlarged to include V. arvensis and other dicotyledons. In such situations, TRV may be introduced in the seed of V. arvensis, and the movement of soil by wind probably contributes to the dispersal of Trichodorus.     

Tobacco rattle virus 29K movement protein is the elicitor of extreme and hypersensitive-like resistance in two cultivars of Solanum tuberosum

Leaf infection experiments were used to analyze the host responses of Solanum tuberosum cultivars known to be resistant or susceptible to natural, nematode-mediated infection of tubers and necrosis induction ("spraing") by Tobacco rattle virus (TRV) isolate PpK20 (TRV-PpK20). Extreme and hypersensitive-like resistance (ER and HR-like, respectively) as well as spreading veinal necrosis and systemic infection were observed. Agroinfection of leaves with a DsRed-expressing TRV cDNA clone revealed ER to function on the single-cell level, inhibiting virus replication and possessing the potential to initiate a cell death response. HR-like necrosis was characterized by initial virus replication and cell-to-cell movement before the onset of necrosis. Transient agroexpression and Potato virus X (PVX)-mediated expression assays demonstrated that the 29K-PpK20 movement protein (MP) can elicit ER and HR-like cell-death. A TRV isolate, PpO85M, known to overcome the resistance to spraing in plants that are resistant to TRV-PpK20 encoded a variant 29K protein which did not elicit HR in PpK20-HR plants. Our results show that the TRV MP is the elicitor of both ER and HR-like cell-death, that no other TRV-encoded proteins or RNA replication are required for its elicitor activity, and that the host reactions are likely to be controlled by single dominant resistance genes.     

Rapid vascular movement of tobraviruses does not require coat protein: evidence from mutated and wild-type viruses

Early studies of the tobravirus Tobacco rattle virus (TRV) described two types of virus isolate with apparently different disease characteristics. M‐type isolates, which contain both viral genomic RNAs and form virus particles, could be passaged by mechanical inoculation and produced rapid but shortlived systemic symptoms. In contrast, NM‐type isolates, which contain only RNA1 and do not form virus particles, were difficult to passage by mechanical inoculation and were very slow to produce systemic symptoms. From the early observations on such isolates made in the 1960s, it has become accepted that M isolates with encapsidated TRV particles move rapidly through the vascular system whereas NM isolates containing only unencapsidated TRV RNA1 move only slowly via plasmodesmata from cell to cell and take many weeks to reach the upper parts of plants. However, we show that NM isolates of TRV and another tobravirus Pea early‐browning virus (PEBV) move into systemic tissue of TV. benthamiana and N. clevelandii by 6 days post inoculation, suggesting that this rapid movement occurs via the vasculature. The systemic movement of TRV and PEBV mutants lacking functional coat protein that have been modified to express the green fluorescent protein were examined by confocal microscopy. This confirmed that the tobraviruses do not require the CP for long distance movement via the phloem, a property that is shared with only a small group of plant viruses.     

Sequences of Tobacco Rattle Viruses from Potato

The RNA2 of the tobacco rattle virus (TRV) isolate 'Rostock' (TRV-R), and the coat protein gene (CP) of TRV isolate 'Mirow' (TRV-M) were sequenced. Both were isolated from potato. Sequence analysis revealed a 5' noncoding-region (NCR) and a CP gene, which are among the shortest of any tobravirus RNA2 sequenced so far. Downstream of the CP open reading frame (ORF) there was an ORF for a 8 k protein, that is probably a truncated 9 k protein, followed by an ORF for a 16 k protein and the 3' NCR. The 16 k protein and the 3' NCR showed a considerable sequence identity with the 3' end of TRV RNA1 and RNA2 from other TRV isolates. The high identity in the amino acid sequences of the CPs from TRV-R and TRV-M as well as other TRV isolates suggested that they are related to the TCM group of the genus Tobravirus and belong serologically to the RQ-serotype. This could be confirmed using a rabbit antiserum that was prepared against recombinant TRV-R CP expressed in bacteria. This serum was found to be suitable for differentiation of TRV-isolates.     

Serial passage of tobacco rattle virus under different selection conditions results in deletion of structural and nonstructural genes in RNA 2.

The RNA genome of tobacco rattle virus (TRV) is bipartite. RNA 2 of the nematode-transmissible TRV isolate PPK20 encodes the viral coat protein (cp) and proteins with molecular weights of 29,400 and 32,800 (29.4K and 32.8K proteins). When this isolate was serially passaged in tobacco by using phenol-extracted RNA as the inoculum in each transfer, defective interfering (DI) RNAs rapidly accumulated. A number of these DI RNAs were cloned. Six DI RNAs had single internal deletions in RNA 2 that removed most of the cp gene, the 29.4K gene, and the 5' half of the 32.8K gene. The borders of the deletions in these DI RNAs were found to be flanked in the genomic RNA 2 by short nucleotide repeats or sequences resembling the 5' end of TRV genomic and subgenomic RNAs. Two DI RNAs were found to be recombinants containing a 5' sequence derived from RNA 2 and a 3' sequence derived from RNA 1. When serial passage of TRV isolate PPK20 was carried out by using leaf homogenates as inocula in each transfer, accumulation of a DI RNA (designated D7) with a functional cp gene was observed. The deletion in D7 covered the 3' end of the cp gene, the 29.4K gene, and the 5' half of the 32.8K gene. An infectious cDNA clone of D7 RNA was made. In mixed infections, D7 RNA rapidly outcompeted RNA 2 but did not compete with RNA 1. The deletion in D7 RNA abolished the nematode transmissibility of the PPK20 isolate. These results may explain the observation that many laboratory isolates of tobraviruses have lost their nematode transmissibility and contain RNA 2 molecules of widely different lengths.     

Tuber induction and initiation during production and early field growth of transplants from in vitro-derived potato plants

In transplants from in vitro‐derived plantlets from very early potato (Solanum tuberosum) cultivars, a lower degree of tuber induction at the time of field planting is thought to increase tuber production. Leaf‐bud cuttings were used to assess the progress to tuber induction in in vitro‐derived potato plantlets during the transplant production phase and after subsequent transplanting into the field. Induction and initiation of tubers on the same plants were assessed to study the effects of the duration of transplant production and conditions during transplant production for cv. Gloria (very early) and cv. Bintje (mid‐early). In vitro‐produced plantlets were not induced by the time of planting but rapidly progressed to the induced state thereafter. The progress in induction with time and the change in percentage of plants showing tubers fitted typical sigmoid curves. Plantlets achieved 50% induction ca 15 days after planting into in vivo conditions, and 50% tuber initiation usually occurred 10 days later. Shorter transplant production periods reduced the degree of induction of the transplants at field planting. Transplant production for more than 2 weeks was required to allow conditions during that period to affect induction or initiation. Long‐term non‐inducing conditions delayed the progress to tuber induction in cv. Gloria and delayed tuber initiation in both cultivars. Cv. Gloria showed no faster progress to induction than cv. Bintje but initiated tubers earlier. The results suggest that the relation between progress to induction and tuber initiation is cultivar dependent and that leaf‐bud cuttings can be used successfully in very young in vitro‐derived plants for assessing the progress to tuber induction.     

Molecular Detection and Complete Genome Sequences of Tomato chlorosis virus Isolates from Infectious Outbreaks in China

Tomato chlorosis virus (ToCV) is a whitefly‐transmitted, phloem‐limited, bipartite Crinivirus. In 2012, severe interveinal symptoms characteristic of ToCV infections were observed in greenhouse tomato plants in the Shandong province of China. High levels of infestation by whiteflies (Bemisia tabaci), which transmit ToCV, were also observed on tomato plants in all the greenhouses investigated. The presence of ToCV was confirmed by specific RT‐PCR either in the sampled plants or in the whiteflies collected from the ventral surface of the leaves of diseased plants. The complete genomic nucleotide sequences (RNA1 and RNA2) of the Shandong isolate of ToCV (ToCV‐SDSG) were determined and analysed. ToCV‐SDSG RNA1 consisted of 8594 nucleotides encompassing four open reading frames (ORFs). ToCV‐SDSG RNA2 consisted of 8242 nucleotides encompassing nine ORFs. Phylogenetic analysis suggests that the Chinese ToCV‐SDSG isolate is most similar to the ToCV‐Florida isolate.     

Functions of the two particles of tobacco rattle virus

Functions of long and short particles of five different tobacco rattle virus (TRV) systems were studied by complementation experiments with the corresponding long and short species of ribonucleic acid (RNA). The progeny of long RNA species alone was proteinless or “free” infectious long RNA, whereas short RNA species alone did not replicate by themselves but appeared to be dependent on long RNA for replication. When both types of RNA derived from the same isolate were inoculated together, particulate virus with long and short particles was produced in more than 50% of the resulting primary infections. These virus systems obtained by homologous complementation resembled the parent isolates in all their characteristics. In addition, heterologous complementation tests were performed with long and short RNA, each derived from another isolate. Heterologous interaction could be observed in only 2 out of 20 possible combinations. As a result, two “mixed” TRV systems with respect to their particle length distributions were obtained, since their long and short particles resembled the ones from the other isolate. The symptoms produced by these mixed viruses were determined by the corresponding long RNA and appeared not to be influenced by the heterologous short one. However, the protein coat of both particles of the “mixed” viruses was specified by the corresponding noninfectious short RNA. Therefore, TRV is a system of at least two functionally defective and mutually complementing components which appear to be specialized in early and late functions.     

Tuber surface microorganisms influence the susceptibility of potato tubers to late blight

Potato tubers (cvs Cara and Bintje) were grown in compost in a glasshouse and immature tubers harvested 57, 68 and 78 days after planting. Two moisture levels were imposed after the first harvest by disconnecting the water supply to one of the treatments and allowing the soil in that treatment to dry naturally. Tubers from wetter compost (59.4% moisture holding capacity) were more resistant to Phytophthora infestans than those from drier compost (14.7% moisture holding capacity) 78 days after planting. The potential causes of this difference were investigated. Aqueous extracts of wet compost did not inhibit the growth of P. infestans. The susceptibility of the internal tuber tissue, from which the periderm had been removed, was different to whole tuber susceptibility. The internal tissue of tubers from wet compost was more susceptible (cv. Cara), or as susceptible (cv. Bintje) as that of tubers from dry compost 78 days after planting. Fungi were isolated from the surface of whole tubers and there were no differences between the populations of potentially antagonistic fungal genera on tubers from wet and dry compost. As the experiment progressed, the number of bacteria per gram fresh weight on tubers grown in wet compost increased, whereas that on tubers from drier compost decreased (cv. Bintje) or remained similar (cv. Cara). There were significantly (P= 0.008) more bacteria on the surface of tubers from wet compost 78 days after planting. When P. infestans was co-cultured in Petri dishes with randomly selected tuber surface bacteria, some isolates (≤ 16.7%) inhibited the growth of the fungus. The percentage of the total bacterial population that was antagonistic to P. infestans was not significantly affected by soil moisture level (P= 0.368). The greater numbers of bacteria, of which a proportion are antagonistic to P. infestans, on the surface of tubers grown in wet compost may account for the greater resistance to tuber blight in that instance.     

Molecular detection and characterisation of black raspberry necrosis virus and raspberry bushy dwarf virus isolates in wild raspberries

Virus‐derived small interfering RNAs (siRNAs) were extracted from leaves of wild raspberries (Rubus idaeus) sampled from three different regions in Finland and subjected to deep sequencing. Assembly of the siRNA reads to contigs and their comparison to sequences in databases revealed the presence of the bipartite positive‐sense single‐stranded RNA viruses, raspberry bushy dwarf virus (RBDV, genus Idaeovirus), and black raspberry necrosis virus (BRNV, family Secoviridae) in 19 and 26 samples, respectively, including 15 plants coinfected with both viruses. Coverage with siRNA reads [21 and 22 nucleotides (nt)] was higher in BRNV‐FI (Finland) RNA1 (79%) than RNA2 (45%). In RBDV, the coverage of siRNA reads was 89% and 90% for RNA1 and RNA2, respectively. Average depth of coverage was 1.6–4.9 for BRNV and 16.5–36.5 for RBDV. PCR primers designed for RBDV and BRNV based on the contigs were used for screening wild raspberry and a few cultivated raspberry samples from different regions. Furthermore, the sequences of BRNV RNA1 and RNA2 were determined by amplification and sequencing of overlapping contigs (length 1000–1200 nt) except for the 3′ and 5′ ends of RNA1 and RNA2 covered by primers. RNA1 of the Finnish BRNV isolate (BRNV‐FI) was 80% and 86% identical to BRNV‐NA (USA) and BRNV‐Alyth (UK), respectively, whereas the identity of NA and Alyth was 79%. RNA2 of BRNV‐FI was 84% and 80% identical to BRNV‐NA and BRNV‐Alyth, respectively, whereas NA and Alyth were 82% identical. Hence, the strains detected in Finland differ from those reported in the UK and USA. Our results reveal the presence of BRNV in Finland for the first time. The virus is common in wild raspberries and nearly identical isolates are found in cultivated raspberries as well. The results show that wild raspberries in Finland are commonly infected with RBDV or BRNV or both viruses and thus are likely to serve as reservoirs of RBDV and BRNV for cultivated Rubus spp.     

Comparison of nucleic acid hybridisation and other tests for detecting tobacco rattle virus in narcissus plants and potato tubers

All isolates of tobacco rattle virus (TRV) found in naturally infected narcissus leaves produced nucleoprotein particles, mostly in large concentrations but, because of antigenic diversity, less than half of the isolates were identified by immunosorbent electron microscopy (ISEM) and still fewer by enzyme-linked immunosorbent assay. All were identified by a nucleic acid hybridisation test in which DNA complementary to RNA-1 of strain PRN of TRV was allowed to react with nucleic acid extracted from leaf tissue. Spraing-affected tubers in some potato stocks yielded only NM isolates of TRV. These isolates do not produce virus particles and they were therefore not detected by ISEM. The infectivity of nucleic acid extracts from recently harvested tubers with spraing symptoms was much greater than that of extracts prepared from tubers after 8 months' storage. In other potato stocks, some spraing-affected tubers contained NM isolates and the rest contained particle-producing isolates (M isolates) of TRV. The infectivity of sap and of nucleic acid, extracted 7 months after harvest from tubers infected with M isolates, was much greater than that of nucleic acid extracted from comparable tubers infected with NM isolates. TRV was detected by nucleic acid hybridisation in extracts of almost all tubers containing either M or NM isolates, even when the tubers were not tested until 7–8 months after harvest. The probable sequence of events occurring after tubers are infected with TRV is outlined, and it is suggested that the virus will rarely become established in fields as a result of planting infected tubers.     

Variation between Turnip mosaic virus Isolates in Zhejiang Province,China and Evidence for Recombination

The 3′‐terminal sequences (c. 1700 nt) of the RNA genome of 10 Turnip mosaic virus (TuMV) isolates from different hosts in Zhejiang province, China, were determined. Phylogenetic analysis of the coat protein nucleotide sequences revealed that most TuMV sequences fell into two distinct clusters. The Chinese isolates B1‐B4 (from Brassica spp.) were similar and placed in the largest group (Group 1), while the isolates R1‐R6 (from Raphanus) were usually placed in a distinct but smaller group (Group 2). There were only approximately 90% identical nucleotides between the two groups. However, one isolate (R5) showed evidence of recombination in that the region between nucleotides 430 and 450, from the start of the coat protein gene and its 3′‐terminus, was a Group 1 type.     

Properties of spinach yellow mottle, a distinctive strain of tobacco rattle virus

A virus (isolate SYM) obtained from spinach plants in England with a severe yellow mottle disease induced symptoms resembling those of tobacco rattle virus (TRV) in several indicator species but caused systemic necrosis in Chenopodium amaranticolor and C. quinoa. It was transmitted to bait plants grown in soil containing the nematode Trichodorus primitivus. Purified virus preparations contained rod-shaped particles that were predominantly of four modal lengths: 188 nm (L particles), 101 nm (S particles), 57 nm and 48 nm (together called VS particles), containing RNA with mol. wts of 2.4, 1.5, 0.7 and 0.6 million, respectively. L particles (s°₂₀= 300 S) and S particles (230 S) greatly outnumbered VS particles (c. 150 S). All particles contained a single polypeptide species with estimated mol wt of 24 700, slightly larger than those previously reported for tobraviruses. Purified L particles were infective but both L and S particles were needed to induce the production of virus nucleoprotein particles. VS particles were not infective and apparently had no qualitative or quantitative effect on infection by L or by L plus S particles. S particles carried determinants for serological specificity and ability to invade C. amaranticolor systemically. Isolate SYM produced pseudo-recombinants with isolate PRN of TRV. Also, isolates CAM, OR and PRN of TRV, and isolate SYM, were found to be distantly related by three kinds of serological test. No relationship was detected between these isolates and pea early-browning virus in gel-diffusion precipitin tests or electron microscope serological tests, but a distant relationship between isolate SYM and pea early-browning virus was found by micro-precipitin tests. Isolate SYM therefore has closer affinities with TRV than with pea early-browning virus and is considered to be a distinctive strain of TRV.     

A Novel Satellite RNA of Cucumber Mosaic Virus Induces Unique Line-pattern Mosaic Symptoms in Tobacco

The CMV(YW) isolate of cucumber mosaic virus (CMV) induced unique line‐pattern mosaic symptoms in systemically infected leaves of tobacco (Nicotiana tabacum cv. Ky57). By northern hybridization analysis using cDNA to CMV(Y) satellite RNA as a probe, it was confirmed that CMV(YW) contained a satellite RNA. which was designated sat‐YW RNA; this was 388 nucleotides in length and did not have either a conserved domain that induces necrosis in tomato or chlorosis in tobacco. CMV(YW) free of sat‐YW RNA. which was isolated by the single lesion isolation method using Chenopodium amaranticolor, did not induce the unique line‐pattern mosaic symptom. Furthermore, the sat‐YW RNA‐mediated line‐pattern mosaic symptom was also induced by in vitro transcribed infectious sat‐YW RNA in tobaccos infected with either CMV(YW) or CMV(Y) genomic RNA. These results clearly demonstrated that sat‐YW RNA induces the unique line‐pattern mosaic symptom on CMV‐infected tobaccos.     

Root bacteria from nematicidal plants and their biocontrol potential against trichodorid nematodes in potato

Trichodorid nematodes (Nematoda: Trichodoridae) are vectors of tobacco rattle virus (TRV), one of the causal agents of spraing disease in potato. Root bacteria from nematicidal plants and their control potential against Trichodoridae were the focus of this study. Bacteria isolated from the roots of 12 nematicidal plants and potato were characterized for their production of hydrolytic enzymes, hydrogen cyanide, phenol oxidation ability and antifungal activity towards the potato pathogen Rhizoctonia solani. Based on these functional traits, bacteria isolates were selected and tested in greenhouse conditions on potato (cv. Saturna) for their effect on plant growth, and screened for nematicidal activity against Paratrichodorus pachydermus and Trichodorus primitivus in naturally infested soil. Sixteen bacteria isolates out of 44 reduced nematode densities by 50–100%. Nine selected isolated were further tested by bacterizing potato tubers (cv. King Edward) which were planted in a trichodorid and TRV-infested soil. Four bacterial isolates consistently reduced nematode densities (by 56.7–74.4%) with no visual negative effect on plant growth. These isolates were tentatively identified, partly by fatty acid methyl ester (FAME) analysis as: Stenotrophomonas maltophilia, Bacillus mycoides, Pseudomonas sp., and one unidentified bacterium. The isolates originated from potato, Plantago major, Thymus vulgaris and Asparagus officinalis, respectively. Two Pseudomonas isolates obtained from Zinnia elegans and selected for their strong nematicidal activity in soil screening tests, did not reduce the nematode population when tested on potato. It is concluded that plants releasing nematicidal compounds may harbour nematode-antagonistic bacteria as well.     

Serological and molecular characterisations of the Egyptian isolate of Bean common mosaic virus

Bean common mosaic virus (BCMV) was isolated from the naturally infected bean plants collected from the Kafr El-Sheikh and El-Gharbia Governorates. BCMV induced sever mosaic, vein banding, malformation, leaf curling and stunting on bean plants cv. Giza 6. The isolated virus was propagated in bean plants cv. Giza 6. The identification of BCMV was carried out serologically by an indirect enzyme-linked immunosorbent assay using BCMV antiserum. Positive reaction indicated that the virus under study was related serologically to Potyvirus. The molecular biology techniques were used to identify and characterise the coat protein gene of BCMV. Oligonucleotide primers were designed for BCMV according to the published nucleotide sequences of BCMV and were successfully amplified with a DNA fragment (300 bp) from BCMV CP gene by RT-PCR. The total RNA was extracted from bean leaves and was reverse-transcribed and amplified using the oligonucleotide primer. The amplified product was analysed by gel electrophoresis. Also, Southern and dot blot hybridisations were used to establish the authenticity and specificity to the RT-PCR-amplified products of BCMV. The nucleotide sequences of the Egyptian isolate of BCMV/CP showed similarity with an isolate (BCMV-NY 15) which belongs to Puerto Rico.     

Brief Report of a New Highly Divergent Variant of Grapevine leafroll‐associated virus 3 (GLRaV‐3)

The alignment of the complete genomes of genetic variants of Grapevine leafroll‐associated virus 3 (GLRaV‐3) representing phylogenetic groups I, II, III and VI revealed numerous regions with exceptionally high divergence between group I to III and group VI variants. Oligonucleotide primers universal for all the above groups of the virus were designed in conserved short stretches of sequences flanking the divergent regions in the helicase (Hel) and RNA‐dependent RNA polymerase (RdRP) domains of the replicase gene and the divergent copy of the capsid protein (dCP) gene. Cloning and sequencing of the 549‐bp RT‐PCR amplicon of the helicase domain from grapevine cv. Shiraz lead to the detection of a variant of GLRaV‐3, which shared only 69.6–74.1% nt similarity with other variants, including the recently reported, new, highly divergent variant, isolate 139. This was confirmed by the results of the analysis of 517‐bp amplicon of the HSP70 gene of GLRaV‐3 generated in RT‐nested PCR based on degenerate primers for the simultaneous amplification of members of the Closteroviridae family designed by Dovas and Katis (J Virol Methods, 109, 2003, 217). In this genomic region, the variant shares 72.3–78.7% nt similarity with other variants of GLRaV‐3. This previously unreported, new, highly divergent variant was provisionally named GTG10. From the alignment of the HSP70 sequences primers for the specific RT‐nested PCR amplification of the variant GTG10 and members of group VI, and specific simultaneous amplification of variants of groups I, II and III, were designed. The results obtained from brief testing of various grapevines using all these primers suggest a relatively limited presence of GTG10 variant in vineyards.