Infection of potato mesophyll protoplasts with five plant viruses

Methods are described for preparing potato mesophyll protoplasts that are suitable for infection with inocula of virus nucleoprotein or RNA. The protoplasts could be infected with four sap-transmissible viruses (tobacco mosaic, tobacco rattle, tobacco ringspot and tomato black ring viruses) and with potato leafroll virus, which is not saptransmissible. No differences were observed in ability to infect protoplasts with potato leafroll virus strains differing either in virulence in intact plants or in aphid transmissibility.     

STUDIES ON THE HOST RANGE, PROPERTIES AND MODE OF TRANSMISSION OF BEET RINGSPOT VIRUS

An apparently undescribed mechanically transmissible virus has been named beet ringspot virus (BRV). It occurs naturally in Scotland in sugar-beet, turnip, swede, potato and many kinds of weed plants. BRV is readily distinguished from raspberry ringspot virus by the symptoms produced in Chenopodium amaranticolor , French bean, tobacco and Petunia hybrida plants. BRV lost infectivity when heated for 10 min. at 63°C. but not at 60°C.: at 20°C. its longevity in vitro was about 3 weeks. BRV was precipitated by ammonium sulphate, ethanol and acetone.
Protection experiments with tobacco plants, and serological tests, gave no evidence that BRV was related to tobacco ringspot, raspberry ringspot, potato bouquet or tobacco rattle viruses, but showed that viruses isolated from different host plants and from different localities were strains of BRV.
BRV is soil-borne: in glasshouse experiments sugar-beet, beetroot, potato, turnip, swede, French bean, Fragaria vesca , oat and wheat plants often became systemically infected when grown in soil from the site of a disease outbreak, but the virus was restricted to the roots of many infected plants. When sugar-beet seedlings were grown in virus-containing soil, BRV was first detected in their roots, where its concentration increased, before progressively increasing amounts of virus were found in the shoots.
Soils from five localities were found to contain BRV. BRV has been found only where the soil is light in texture, and often in fields where raspberry ringspot virus occurs.     

STREAK—A VIRUS DISEASE OF TOMATOES

A comparison of streak disease of tomatoes, derived from commercial glasshouses, and experimental streak produced by combined inoculation of the viruses of potato mosaic and tobacco mosaic, is given in detail.
The characters employed in comparison are the host range of each virus and its resistance to various temperatures, to different concentrations of alcohol, and to ageing in vitro .
Glasshouse streak and tobacco mosaic show an equal resistance to alcohol, heat and ageing in vitro , and have, in addition, an identical host range. Treatment for 1 hour with 90 per cent, alcohol and for 10 minutes at 85⁰ C. did not destroy the infectivity of either of these viruses.
Glasshouse streak is shown not to contain the virus of potato mosaic, but is of itself able to produce necrosis in tomatoes without the participation of potato mosaic. The factors underlying this have not been determined.
It is concluded that tobacco mosaic and the mosaic of glasshouse streak are probably identical, and that much of the streak occurring in glasshouses is due to a single virus, and not a mixed infection of this with potato mosaic.     

Correlation of viral RNA biosynthesis with glucose-6-phosphate dehydrogenase activity and host resistance

Changes in glucose-6-phosphate dehydrogenase (G6P DH; EC 1.1.1.49) activity caused by infection of tobacco ( Nicotiana tabacum L.) leaves with potato virus Y (PVY), cucumber mosaic virus, potato virus X, tobacco rattle virus and turnip mosaic virus, the subcellular localisation of G6P DH isozymes in mesophyll protoplasts derived from healthy and PVY-infected tobacco leaves, as well as G6P DH control and the relationship of its isozymes with the degree of tobacco resistance to PVY multiplication, were studied. The activities of G6P DH were markedly increased in locally and systemically infected leaves and the time courses of the activity linearly correlated with those of virus multiplication. In leaves infected with PVY, the activity time courses of the crude and the partially purified G6P DH were coincident. This probably indicates the involvement of coarse regulation of the enzyme. PVY content linearly correlated with enhanced G6P DH activity in leaf discs derived from susceptible, tolerant and resistant cultivars of tobacco. The increased activity of the enzyme in infected protoplasts and plant tissues was predominantly caused by the increased activity of chloroplastic isozymes. This was confirmed by the specific staining of isozymes after electrophoretic separation of chloroplastic proteins of tobacco leaves. These findings enable the degree of resistance to virus multiplication to be quantified for the use of gene manipulation and breeding.     

Effects of Salicylate on Systemic Invasion of Tobacco Plants by Various Viruses

Salicylate watered onto soil in which White Burley tobacco plants were grown represents a reversible stress characterized by stomatal closure, slight slackening of plant growth and low chlorophyll loss. Salicylate affected viral pathogenesis in opposite ways. It had no effect against local and systemic infections by potato virus X (PVX), potato virus Y⁰ (PVY⁰) or tobacco mosaic virus (TMV), whereas it completely prevented systemic infection by alfalfa mosaic virus (AIMV) or tobacco, rattle virus (TRV) in a high proportion of treated plants. When infection moved from leaves inoculated with AIMV or TRV, the tendency to limit systemic spread was shown by the restriction of systemic infection to very limited areas erratically distributed in some uninoculated leaves. The salicylate-induced restriction of AIMV or TRV infectivity to inoculated leaves did not appear due to inhibition of virus multiplication because the inoculation of potentially resistant leaves of salicylate-reated plants resulted in virus antigen accumulation comparable to that of untreated controls. Salicylate may therefore inhibit some long distance virus transport function. Salicylate appears able to evoke true hypersensitivity only against systemic viruses able to induce local necrotic lesions, probably by activating some genetic information for resistance that is normally not expressed.     

Systemic Acquired Resistance Induced in Tobacco Plants by Localized Virus Infection Does Not Operate Against Challenging Viruses That Infect Systemically

Localized infections produced by tobacco necrosis virus (TNV) or tomato mosaic virus (ToMV) in White Burley tobacco induced a systemic acquired resistance in upper, uninoculated leaves. This resistance was effective against challenge infection by TNV or ToMV but not by potato virus Y, necrotic strain (PVYⁿ), tobacco mosaic virus (TMV) or tobacco rattle virus (TRV), viruses giving systemic infections. Systemic acquired resistance against TNV or ToMV was expressed as a reduction in lesion size but not in viral antigen content of the resulting necrotic local lesions. The acquisition of resistance was concurrent with an increased capacity of the resistant leaves to convert 1-aminocyclopropane-1-carboxylic acid into ethylene. Systemic acquired resistance was ineffective to contrast or minimize in whatever way the systemic challenge infection produced by PVY^N, TMV or TRV. Severity of symptoms and virus multiplication did not differ in resistant leaves from controls. This result does not allow any optimistic promise on possible application of the systemic acquired resistance against severe viral diseases of crops.     

Establishing a Corky Ringspot Disease Plot for Research Purposes

A method to establish two experimental corky ringspot disease (CRS) plots that had no prior CRS history is described. CRS is a serious disease of potato in the Pacific Northwest caused by tobacco rattle virus (TRV) and transmitted primarily by Paratrichodorus allius. ‘Samsun NN’ tobacco seedlings were inoculated with viruliferous P. allius in the greenhouse before they were transplanted into the field soil at the rate of 3,000 plus seedlings/ha. Care was taken to keep soil around plants in the greenhouse and transplants in the field moist to avoid vector mortality. The vector population in the soil of one of the fields was monitored by extraction, examination under microscope and bioassay on tobacco seedlings to ascertain that they were virus carriers. Presence of virus in tobacco bioassay plants was determined by visual symptoms on tobacco leaves and by testing leaves and roots using ELISA. Although TRV transmission was rapid, there was loss of infectivity in the first winter which necessitated a re-inoculation. After two years of planting infected tobacco seedlings, 100% of soil samples collected from this field contained viruliferous P. allius. In the second field, all five commercial potato cultivars, known to be susceptible, expressed symptoms of CRS disease indicating that the procedure was successful.     

Eliminating Tobacco Rattle Virus from Viruliferous Paratrichodorus allius and Establishing a New Virus-Vector Combination

A reliable method to eliminate tobacco rattle virus (TRV) from viruliferous Paratrichodorus allius populations was developed. This virus is vectored by P. allius in the Pacific Northwest and causes corky ringspot disease (CRS) of potato. The viruliferous nematodes that were reared on ''Vernema'' alfalfa or ''770'' scotch spearmint for at least 3 months did not transmit TRV to ''Samsun NN'' tobacco, a suitable indicator plant, and did not cause CRS symptoms on ''Russet Norkotah'' tubers. A new isolate of TRV was introduced into a nonviruliferous population of P. allius. First, tobacco plants were inoculated with a field population of P. allius that transmitted an isolate of TRV that caused severe symptoms on potato. The tobacco roots were then washed free from soil and dipped in 0.525% sodium hypochlorite to remove the initial nematode inoculum. After the disinfected tobacco plants recovered and began to grow, the virus-free population of P. allius was introduced around the root system to acquire the new virus isolate from tobacco roots. The newly established virus-vector combination caused CRS symptoms on ''Russet Norkotah'' that were characteristic of the more virulent virus isolate, indicating that the virus-free P. allius population had reacquired virus.     

病毒诱导烟草的基因沉默

病毒诱导基因沉默是利用RNA介导病毒防卫机制的一项技术。构建含有目的基因片段的人工改造病毒载体,通过农杆菌侵染导致植物内源目的基因沉默。为建立病毒诱导基因沉默体系,选用烟草脆裂病毒（TRV）和烟草为实验材料。构建了八氢番茄红素去饱和酶基因（PDS）的基因沉默病毒载体,病毒载体侵染结果显示目的基因PDS沉默导致烟草幼苗出现光漂白现象。采用RT-PCR的方法检测目的基因PDS的沉默效果,结果显示PDS基因mRNA被显著降解。该体系的建市有利于将来对植物基因进行高通量功能分析。     

Some properties of an isolate of tobacco rattle virus from Northern Ireland

A virus obtained from soil in which potato plants had shown severe spraing symptoms induced symptoms on indicator plants typical of tobacco rattle virus (TRY). Purified virus preparations of a local-lesion isolate contained particles of two modal lengths, 192 nm and 94 nm containing RNA molecules of mol. wt 2.4 × 10⁶ and 1.23 × 10⁶. Virus coat protein had a mol. wt of c. 21 500. The virus was serologically distantly related to TRY (SYM) and pea early browning virus (PEBV) SP5, but did not react with TRY (CAM) or TRY (PRN) antisera. However, cDNA hybridisation indicated that the virus was more closely related to TRY (PRN) than either TRY (SYM) or PEBV (SP5). The virus isolate has been designated TRY (NI).     

Development of immunochromatographic test systems for express detection of plant viruses

Express immunochromatographic test-strip assays were developed for detection of five plant viruses varying in shape and size of virions: spherical carnation mottle virus, bean mild mosaic virus, rodshaped tobacco mosaic virus, and filamentous potato viruses X and Y. Multimembrane composites (test strips) with immobilized polyclonal antibodies against viruses and colloidal gold-conjugated antibodies were used for the analysis. The immunochromatographic test strips were shown to enable the detection of viruses both in purified preparations and in leaf extracts of infected plants with a sensitivity from 0.08 to 0.5 μg/ml for 10 min. The test strips may be used for express diagnostics of plant virus diseases in field conditions.     

Intracellular inclusions in epidermal cells of tobacco infected by tobacco rattle virus

Internal symptoms in epidermal cells of tobacco rattle virus infected tobacco were investigated. Ring-, elipsoid- and spindle-shaped inclusions were found in the period between the fourth and thirtieth day after inoculation of Samsun seedlings.     

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.     

转录后基因沉默系统研究烟草rbcS基因功能

初步建立了利用病毒载体诱导转录后基因沉默系统研究烟草(Nicotiana benthamiana)1,5-二磷酸核酮糖羧化酶／加氧酶小亚基(Ribulose-1,5-bisphosphate carboxylase／oxylase small subunit,rbcS)基因功能的模式。用携带与1,5-二磷酸核酮糖羧化酶／加氧酶小亚基基因同源的cDNA片段的烟草脆裂病毒载体(pTV．rbcS)侵染烟草(Nicotiana benthamiana),诱导内源rbcS基因沉默并在此基础上建立了研究rbcS基因功能的模式：初步进行了rbcS基因沉默后的表型分析、转录水平分析、蛋白质表达水平分析以及利用HPLC方法定量分析rbcS基因沉默后的光合色素变化。结果表明：病毒诱导基因沉默瞬时表达体系中烟草最佳侵染时期为苗龄21-24d,用于侵染的重组农杆菌的最佳浓度的OD值为1～1．5;烟草Rubisco小亚基的表达量可能调节Rubisco大亚基的表达量;烟草rbcS基因与光合作用中的光能收集无关。对rbcS基因沉默的烟草叶片及对照烟草叶片的部分重要光合作用指标分析表明,运用烟草脆裂病毒载体诱导转录后基因沉默系统研究烟草rbcS基因功能具有可行性,为进一步深入研究rbcS基因功能奠定了基础。     

Virus-induced gene silencing in Solanum species

Virus-induced gene silencing (VIGS) has been used routinely in Nicotiana benthamiana to assess functions of candidate genes and as a way to discover new genes required for diverse pathways, especially disease resistance signalling. VIGS has recently been shown to work in Arabidopsis thaliana and in tomato. Here, we report that VIGS using the tobacco rattle virus (TRV) viral vector can be used in several Solanum species, although the choice of vector and experimental conditions vary depending on the species under study. We have successfully silenced the phytoene desaturase (PDS) gene in the diploid wild species Solanum bulbocastanum and S. okadae, in the cultivated tetraploid S. tuberosum and in the distant hexaploid relative S. nigrum (commonly known as deadly nightshade). To test whether the system could be utilised as a rapid way to assess gene function of candidate resistance (R) genes in potato and its wild relatives, we silenced R1 and Rx in S. tuberosum and RB in S. bulbocastanum. Silencing of R1, Rx and RB successfully attenuated R-gene-mediated disease resistance and resulted in susceptible phenotypes in detached leaf assays. Thus, the VIGS system is an effective method of rapidly assessing gene function in potato.     

Multiple components of the resistance of potatoes to potato leafroll virus

In glasshouse experiments the ranking of potato genotypes for resistance to infection with potato leafroll virus (PLRV) using three concentrations of aphid-borne inoculum was the same as their field resistance ratings. In field-grown plants this resistance to infection increased in all genotypes as the plants aged but its rate of increase differed between genotypes. In tests on field-grown plants infected by aphid- or graft-inoculation, the proportion of virus-free progeny tubers increased the later the date of inoculation but was greater in resistant than in susceptible genotypes. This trend was most pronounced in the resistant clone G7445(1), in which the virus failed to move from the foliage to the tubers of some plants infected in glasshouse tests. The spread of PLRV will thus be minimised in crops of resistant compared with susceptible genotypes for three reasons: plants have greater resistance to infection, systemic spread of virus from their foliage to tubers is less likely and, as shown previously, the low concentration of virus particles in leaf tissue makes infected plants less potent sources of inoculum for aphids.     

Tobacco mosaic virus 126-kDa protein increases the susceptibility of Nicotiana tabacum to other viruses and its dosage affects virus-induced gene silencing

The Tobacco mosaic virus (TMV) 126-kDa protein is a suppressor of RNA silencing previously shown to delay the silencing of transgenes in Nicotiana tabacum and N. benthamiana. Here, we demonstrate that expression of a 126-kDa protein-green fluorescent protein (GFP) fusion (126-GFP) in N. tabacum increases susceptibility to a broad assortment of viruses, including Alfalfa mosaic virus, Brome mosaic virus, Tobacco rattle virus (TRV), and Potato virus X. Given its ability to enhance TRV infection in tobacco, we tested the effect of 126-GFP expression on TRV-mediated virus-induced gene silencing (VIGS) and demonstrate that this protein can enhance silencing phenotypes. To explain these results, we examined the poorly understood effect of suppressor dosage on the VIGS response and demonstrated that enhanced VIGS corresponds to the presence of low levels of suppressor protein. A mutant version of the 126-kDa protein, inhibited in its ability to suppress silencing, had a minimal effect on VIGS, suggesting that the suppressor activity of the 126-kDa protein is indeed responsible for the observed dosage effects. These findings illustrate the sensitivity of host plants to relatively small changes in suppressor dosage and have implications for those interested in enhancing silencing phenotypes in tobacco and other species through VIGS.     

Ultrastructural studies of plasmodesmatal and vascular translocation of tobacco rattle virus (TRV) in tobacco and potato

The studies focus on an ultrastructural analysis of the phenomenon of intercellular and systemic (vascular) transport of tobacco rattle virus (TRV) in tissues of the infected plants. TRV is a dangerous pathogen of cultivated and ornamental plants due to its wide range of plant hosts and continuous transmission by vectors—ectoparasitic nematodes. Two weeks after infection with the PSG strain of TRV, tobacco plants of the Samsun variety and potato plants of the Glada variety responded with spot surface necroses on inoculated leaf blades. Four weeks after the infection a typical systemic response was observed on tobacco and potato leaves, necroses on stems and lesions referred to as corky ringspot. Ultrastructural analysis revealed the presence of two types of TRV virions: capsidated and non-capsidated forms in tobacco and potato tissues. In the protoplast area, viral particles either occurred in a dispersed form or they formed organised inclusions of virions. We demonstrated for the first time the presence of non-capsidated-type TRV in the vicinity of and inside plasmodesmata. Capsidated particles of TRV were observed in intercellular spaces of the tissues of aboveground and underground organs. Expanded apoplast area was noted at the cell wall, with numerous dispersed non-capsidated-type TRV particles. These phenomena suggest active intercellular transport. Our ultrastructure studies showed for the first time that xylem can be a possible route of TRV systemic transport. We demonstrated that both capsidated and non-capsidated virions, of varied length, participate in long-distance transport. TRV virions were more often documented in xylem (tracheary elements and parenchyma) than in phloem. Non-capsidated TRV particles were observed inside tracheary elements in a dispersed form and in regular arrangements in potato and tobacco xylem. The presence of TRV virions inside the bordered pits was demonstrated in aboveground organs and in the root of the tested plants. We documented that both forms of TRV virions can be transported systemically via tracheary elements of xylem.