Incidence of potato virus Y infection in seed and ware tubers of the potato cv. Record

The incidence of potato virus Y (PVY) infection was assessed in samples of potato tubers, cv. Record, taken from Scottish seed stocks and English ware crops grown from some of these seed stocks. PVY was readily detected by ELISA of tuber sprouts. PVY-infected tubers were found in 10 seed stocks of 84 tested. The mean level of virus infection was 0.23%, 0.76% and 0.56% in Super Elite, Elite and AA stocks respectively. In 46 commercial ware crops grown from some of these seed stocks, a substantial proportion of the harvested tubers in all but one of the crops were infected with PVY, the mean percentage of infected tubers was 58.5%. Ware crops grown from seven seed stocks in which PVY had been detected (mean 6.2% infection in seed) contained a mean of 70% infected tubers, compared with 56% infection in crops grown from 39 stocks in which PVY was not detected in the seed tubers. The predominant PVY strain detected in the ware crops was the veinal necrosis strain (PVY^vn).     

Further evidence on the nature of the dependence of carrot mottle virus on carrot red leaf virus for transmission by aphids

Preparations were made from chervil plants doubly infected with carrot mottle virus (CMotV) and its helper virus, carrot red leaf (CRLV), on which it depends for transmission by the aphid Cavariella aegopodii, by the procedure developed previously for CRLV. The preparations contained 25 nm isometric particles which were indistinguishable from those of CRLV but possessed aphid-transmissible infectivity of both viruses and manually transmissible infectivity of CMotV. Only one sedimenting and buoyant density component was detected. The manually transmissible CMotV infectivity was resistant to freezing and to organic solvents, treatments that destroyed the CMotV infectivity in extracts from singly infected plants. The aphid-transmissible CMotV infectivity in preparations from CRLV/ CMotV-infected plants, and that in extracts from CRLV/CMotV-carrying C. aegopodii, was abolished by treatment with CRLV antiserum but not with normal serum. These results show that transmission of CMotV by C. aegopodii is dependent on the packaging of its RNA in coats composed partially or entirely of CRLV particle protein. The aphid Myzus persicae does not transmit CRLV or CMotV from plants mixedly or singly infected with these viruses but it is a vector of beet western yellows virus (BWYV) and potato leafroll virus (PLRV) and it transmitted CMotV from plants that also contained either of these viruses. This suggests that the coat proteins of BWYV and PLRV can substitute for that of CRLV in packaging CMotV nucleic acid and thereby confer on it their own vector specificities.     

Application of enzyme-linked immunosorbent assay to the detection of potato leafroll virus in potato tubers

Factors affecting the detection of potato leafroll virus (PLRV) by enzyme-linked immunosorbent assay (ELISA) in tubers of field-grown potato plants with primary or secondary infection were studied. The reactions of extracts of virus-free potato tubers were minimised by pre-incubating the extracts at room temperature and by careful choice of the dilution of enzyme-conjugated globulin. PLRV was reliably detected in tubers produced by secondarily infected plants of all six cultivars tested. PLRV concentration was greater in heel-end than in rose-end vascular tissue of recently harvested tubers but increased in rose-end tissue when tubers stored at 4°C for at least 5 months were placed at 15–24°C for 2 wk. PLRV occurred at greater concentration in tubers from plants of cv. Maris Piper with natural or experimentally induced primary infection than in tubers from secondarily infected plants; again PLRV concentration was greater in heel-end than in rose-end vascular tissue. Plants whose shoots were infected earliest in the growing season were invaded systemically and produced the greatest proportion of infected tubers; plants infected late in the season also produced infected tubers but PLRV was not detected in their shoot tops. PLRV concentration in tubers from the earliest-infected plants was less than in tubers from later-infected plants. PLRV was detected reliably by ELISA in tubers from progenies that were totally infected but was not detected in all infected tubers from partially infected progenies. ELISA is suitable as a routine method of indexing tubers for PLRV, although the virus will not be detected in all infected tubers produced by plants to which it is transmitted late in the growing season.     

Host range and properties of potato black ringspot virus

Potato black ringspot virus (PBRV), obtained from cultivated potato in Peru, was found to have a very wide host range resembling that of tobacco ringspot virus (TRSV-B), to which PBRV is distantly related serologically. However, PBRV caused the more severe symptoms in many species and, unlike TRSV B, infected Lycopersicon esculentum and Cyamopsis tetragonoloba. In Solanum tuberosum, PBRV caused necrotic spots and ringspots in systemically infected leaves in the year of infection and was readily transmitted through tubers to progeny plants, most of which developed no obvious symptoms although systemically infected. TRSV-B infected non-inoculated S. tuberosum leaves only sporadically, did not induce symptoms in them and was not transmitted through tubers to progeny plants. PBRV was cultured in Nicotiana clevelandii and infectivity was assayed in Cheno-podium amaranticolor or C. quinoa. Virus particles were purified from leaf extracts, after clarification using chloroform, by precipitation with 6% polyethylene glycol and differential centrifugation. Purified preparations contained 25 nm diameter isometric particles with somewhat angular outlines, sedimenting as three components (T, M and B) at 49, 84 and 117 S, and containing a single protein species of mol. wt 59 000. Preparations of PBRV nucleic acid contained two species, estimated by polyacrylamide gel electrophoresis in non-denaturing conditions to have mol. wt of about 25 10⁶ (RNA-1) and 15 10⁶ (RNA-2). Infectivity was associated with B particles, preparations of which contained RNA-1 and RNA-2, presumably in different particles. M particles contained RNA-2, were not infective and enhanced infectivity only slightly when added to B particles. Similar relative amounts of RNA-1 and RNA-2 were extracted from unfractionated virus using phenol or Pronase, but preparations obtained using phenol were much the more infective. PBRV has properties typical of nepoviruses; its present cryptogram is (R/1):2–5/41 + 15/28 or 2 1 5/46:S/S:S/*, nepovirus group.     

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.     

Detection of potato leafroll and potato mop-top viruses by immunosorbent electron microscopy

Attachment of virus particles to antiserum-coated electron microscope grids (immunosorbent electron microscopy) provided a test that was at least a thousand times more sensitive than conventional electron microscopy for detecting potato leafroll (PLRV) and potato mop-top (PMTV) viruses. The identity of the attached virus particles was confirmed by exposing them to additional virus antibody, which coated the particles.
PLRV particles (up to 50/μm² of grid area) were detected in extracts of infected potato leaves and tubers, infected Physalis floridana leaves, and single virus-carrying aphids. On average, Myzus persicae yielded 10–30 times more PLRV particles than did Macrosiphum euphorbiae .
PMTV particles (up to 10/μm² of grid area) were detected in extracts of inoculated tobacco leaves, and of infected Arran Pilot potato tubers with symptoms of primary infection. Particles from tobacco leaves were of two predominant lengths, about 125 nm or about 290 nm, and fewer particles of other lengths were found than in previous work, in which partially purified or purified preparations of virus particles were examined, using grids not coated with antiserum.     

THE PATTERN OF FIELD INFECTION OF POTATO BY THE BEET RINGSPOT STRAIN OF TOMATO BLACK-RING, A SOIL-BORNE VIRUS

The potential importance of the beet ringspot strain of tomato black-ring, a soil-borne virus, was assessed by growing stocks of Kerr's Pink potato for 1 year on infested land and subsequently on uninfested land. The incidence of infection in two stocks was 39 and 8% in the first year on uninfested land, and 29 and 5% after 2 years.
The virus was usually restricted to the roots of plants in the first year of infection, but a few plants showed black rings and spots in their leaves. In the second year, 20–55% of the plants grown from tubers set by symptomless, but infected, mother plants were infected: many of these showed leaf necrosis, others had stunted shoots, and cupped and distorted leaves; some were symptomless although systemically infected. In the third and fourth years, most of the progeny from plants which had symptoms or which were symptomless but systemically infected, contained the virus: nearly all such infected plants were stunted and distorted or were symptomless. Infection decreased the weight of tubers produced by plants with severe necrotic spotting but not the yield of plants with less necrosis. The number and weight of tubers per plant were decreased by 15 and 20% respectively, in symptomless systemically infected plants, and by 20 and 30% in stunted plants.     

Increased sensitivity of detection of plant viruses obtained by using a fluorogenic substrate in enzyme-linked immunosorbent assay

The fluorogenic substrate 4-methylumbelliferyl phosphate (MUP) of alkaline phosphatase was compared with the chromogenic substrate p-nitrophenyl phosphate (NPP) in tests for plant viruses by enzyme-linked immunosorbent assay (ELISA). In tests on leaf extracts of squash infected with prune dwarf virus, Chenopodium quinoa and apple infected with apple mosaic virus (ApMV), and potato infected with potato leafroll virus (PLRV), MUP increased sensitivity 2–16 times, the smallest and greatest increases being obtained with ApMV (in apple) and PLRV respectively. In similar tests on 21 dormant PLRV-infected potato tubers, sensitivity was increased 2–4 times with 13 tubers, but the two substrates gave the same detection end-points with eight tubers. When individual seeds of potato plants infected with the Andean potato calico strain of tobacco ringspot virus were tested, the virus was detected in virtually all seeds by MUP-ELISA, but detection by NPP-ELISA was inefficient unless absorbance values were measured after overnight incubation at 4 °C, instead of after 2 h at room temperature. In tests on Myzus persicae carrying PLRV and Sitobion avenae carrying barley yellow dwarf virus (BYDV), both viruses were consistently detected in a greater proportion of individual aphids by MUP-ELISA than NPP-ELISA irrespective of whether incubation was for 2 h at room temperature or overnight at 4 °C. The effeciency of detection of virus in single viruliferous aphids by MUP-ELISA was not decreased by grouping with one or four non-viruliferous aphids but was decreased (PLRV) or greatly decreased (BYDV) by grouping with nine. MUP-ELISA and transmission tests to Physalis floridana seedlings (2–3 day inoculation access periods) both detected PLRV in most individual M. persicae, but the results obtained with the two methods did not correlate completely. In similar tests for BYDV in individual S. avenae, virtually all aphids transmitted BYDV to oat seedlings during a 3-day inoculation access period but it was subsequently detected by MUP-ELISA in less than half of them. By contrast, MUP-ELISA detected PLRV in most viruliferous M. persicae even after they had fed for 3 days on Chinese cabbage, a non-host for this virus.     

Detection of strains of African cassava mosaic virus by nucleic acid hybridisation and some effects of temperature on their multiplication

DNA probes, made by cloning double-stranded forms of each of the genome parts (DNA-1 and DNA-2) of the Kenyan type isolate of African cassava mosaic virus (ACMV-T), reacted strongly with extracts from Nicotiana benthamiana plants infected with ACMV-T, or with Angolan or Nigerian isolates that are closely serologically related to the type isolate. However, only the DNA-1 probes reacted with extracts of TV. benthamiana infected with a Kenyan coast isolate (ACMV-C), which is serologically less closely related to ACMV-T. DNA-1 and DNA-2 probes also reacted with extracts of mosaic-affected Angolan cassava plants, including some which have not yielded ACMV particles detectable by immunosorbent electron microscopy and from which virus isolates have not been transmitted to TV. benthamiana. These anomalous plants, unlike other naturally infected cassava plants, showed mosaic symptoms on all their leaves which, however, contained only traces of virus particle antigen detectable by enzyme-linked immunosorbent assay. They contain isolates of ACMV that are probably defective for particle production. ACMV-T particles accumulated optimally in N. benthamiana at 20–25°C. At 30°C fewer particles, which apparently had a slightly greater specific infectivity, were produced. At 15°C, considerable quantities of virus particle antigen, virus DNA and virus particles were produced but the particles were poorly infective, and the few that could be purified contained an abnormally large proportion of polydisperse linear DNA molecules, and fewer circular molecules than usual. Angolan isolates, whether particle-producing or not, likewise replicated better in cassava plants at 23 °C than at 30 °C. In contrast, ACMV-C attained only very low concentrations in N. benthamiana, but these were greater at 30 °C than at 23°C.     

Factors affecting the detection of potato leafroll virus in potato foliage by enzyme-linked immunosorbent assay

Using antiserum globulins that reacted only weakly with plant materials, potato leafroll virus (PLRV) at 10 ng/ml was detected consistently by enzyme-linked immunosorbent assay (ELISA). The reaction with PLRV particles was slightly impaired in potato leaf extracts that were diluted less than 10^-1 but not at greater dilutions. Antiserum globulins that reacted more strongly with plant materials could be used satisfactorily for coating microtitre plates but were unsuitable for conjugating with enzyme. The detection end-point of PLRV, in leaf sap of potato cv. Cara plants grown from infected tubers in the glasshouse, was about 10^-2 and the virus was reliably detected in extracts of composite samples of one infected and 15 virus-free leaves. PLRV concentration was much less in extracts of roots or stolons than in leaf extracts. The virus was detected in infected leaves of all 27 cultivars tested. PLRV was readily detectable 2 wk before symptoms of secondary infection developed in field-grown plants of cv. Cara and Maris Piper and remained so for at least 5 wk. Its concentration was slightly greater in old than in young leaves and was similar to that in glasshouse-grown plants. In field-grown plants of cv. Maris Piper with primary infection, PLRV was detected in tip leaves 21–42 days after lower leaves were inoculated by aphids; in some shoots it later reached a concentration, in tip leaves, similar to that in leaves with secondary infection. Symptoms of primary infection developed in the young leaves of some infected shoots but were inconspicuous and were not observed until at least a week after PLRV was detected by ELISA.     

The production of virus-free clones of some British potato varieties

Virus-free clones of some British potato varieties, of which all commercial stocks are infected, were obtained by culturing apical meristems of sprouts on tubers. The variety Golden Wonder was freed from potato virus A, Arran Comet from potato virus X, and Epicure, Orion and Sharpe's Express from potato virus S. Of the 196 meristems cultured, forty-one (21%) grew and of these twenty developed into plants, of which nineteen were virus-free. More of the excised meristems grew when the first leaf primordium was included than when not, and its inclusion seemed not to increase the chances of the progeny being infected.     

Electron Microscopical and Serological Detection of Virus-like Particles Associated with Lettuce Big Vein Disease

Very labile rod-shaped particles measuring 324 and 152 nm × 18 nm were isolated only from lettuce plants affected with lettuce big vein (LBV) but not from healthy ones. An antiserum to these particles was prepared which enabled us to diagnose LBV-affected plants, using immunosorbent electron microscopy (ISEM) and enzyme-linked immunosorbent assay (ELISA). Clearly positive reactions were obtained in ISEM and ELISA even when symptoms of LBV-affected plants raised in soil from various locations were indistinct. Higher ELISA values were obtained with extracts from leaves than with those from roots. In ISEM high numbers of particles were trapped from extracts of LBV-affected plants with antiserum to tobacco stunt virus.     

Purification and some properties of oat golden stripe virus

Oat golden stripe virus (OGSV) was maintained in oats by mechanical inoculation and purified by extraction of leaves in borate buffer, two cycles of centrifugation through sucrose cushions and isopycnic centrifugation in CsCl. An antiserum with a titre of 1/1024 in precipitin tests was prepared. Particle length distribution was bimodal with median values, respectively, of 150 and 300 nm from dip preparations. Measurements from immunosorbent electron microscopy (ISEM) and purified preparations showed that the particles had partially degraded during these procedures. The virus sedimented as two components of 168 S and 218 S and had a buoyant density of 1321 g cm^-3. Four isolates of OGSV reacted with the antiserum. Antiserum to members and possible members of the furovirus group were tested in ISEM decoration tests and in ELISA. OGSV was related to soil-borne wheat mosaic virus but not to beet necrotic yellow vein virus, hypochoeris mosaic virus or potato mop-top virus.     

Purification and particle properties of groundnut rosette assistor virus and production of a specific antiserum*

Purified preparations of the luteovirus, groundnut rosette assistor virus (GRAV), were made by treatment of groundnut leaf extracts with cellulase, followed by sucrose density gradient centrifugation. Yields of virus particles were about 0·5-1·0 mg/kg leaf material. The preparations contained isometric particles c. 28 nm in diameter with a sedimentation coefficient (s_{20, w}) of 115 S, a buoyant density in Cs₂SO₄ of 1·34 g/cm³, and A₂₆₀/A₂₈₀ of 1·86. The particles contained a single species of nucleic acid (presumably RNA), of mol. wt 2·09 × 10⁶and with no detectable polyadenylate sequence, and a single protein species, of mol. wt 24 × 10³. An antiserum produced in a rabbit had a titre of 1/256 in gel diffusion tests and detected GRAV in leaf extracts by ELISA. GRAV particles reacted in F(ab')₂-ELISA and immunosorbent electron microscopy (ISEM) tests with antisera to bean leaf roll, potato leafroll and tobacco necrotic dwarf luteoviruses, but did not react with antisera to carrot red leaf luteovirus.     

Identification and Nucleotide Sequence of a Tobacco rattle virus RNA-1 Variant that Causes Spraing Disease in Potato cv. Bintje

An isolate of Tobacco rattle virus (TRV) obtained from a site in the Netherlands induced symptoms of spraing disease in tubers of the potato variety Bintje, which is generally considered to be resistant to infection by TRV. The isolate contained two phenotypically distinguishable RNA‐1 variants, one of which was shown to carry the determinant for the ability to cause spraing in cv. Bintje. The nucleotide sequence of the coding region of this RNA‐1 was determined and found to differ at 5.2–5.4% of positions from other TRV RNA‐1 sequences in the database. The amino acid sequences of the predicted translation products were between 92 and 99% identical to those of a TRV RNA‐1 that did not cause spraing in cv. Bintje, with P1b being the most divergent and the replicase read‐through domain the least.     

黑龙江省及长春市烟草病毒病的种类鉴定

１９９１－１９９３年在黑龙江省主要烟区的１１个县及长春市采样,得１２９个毒株。经鉴别寄主测定,抗血清反应（板式酶联法或斑点酶联法）及电镜或免疫电镜观察,有ＴＭＶ（４３．４％）,ＰＶＹ（１７．８％）,ＣＭＶ（３．９％）,ＴＲＶ（０．８％）,ＴＳＷＶ等病毒,ＴＭＶ与ＰＶＹ混合侵染的占１０．１％,ＰＶＹ与其它病毒混合侵染的占１１．６％,另有５个标样为马铃薯Ｙ病毒组成员,１０个为未知。     

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.