Characterisation of datura yellow vein virus, a newly described rhabdovirus from Australia

A previously undescribed sub-group 2 rhabdovirus was isolated in Queensland from Datura stramonium with symptoms of vein yellowing, leaf distortion and reduced leaf size. Particles accumulated in the perinuclear space of infected cells of D. stramonium and measured 77 × 166 nm in preparations from sap. The virus was named datura yellow vein virus (DYVV) and was graft-transmitted to several hosts in the Solanaceae including Lycopersicon esculentum, Nicotiana tabacum and Solanum melongena, but not to Capsicum annuum or Solanum tuberosum. DYVV was not transmitted by mechanical inoculation and no insect vector was found. Purified particles of DYVV contained four structural proteins with molecular weights of about 78, 47, 41 and 36 kd. The 78 kd protein bound the lectin concanavalin A, thus identifying it as the viral glycoprotein. DYVV was serologically distinct from 11 other rhabdoviruses belonging to both subgroups, including potato chlorotic stunt, potato yellow dwarf (2 isolates) and tomato vein yellowing viruses. The glycoprotein only of DYVV cross-reacted with a polyclonal antiserum to sonchus yellow net virus.     

Isolation and Characterization in Gynura aurantiaca of a Possible Citrus Rhabdovirus

Rhabdovirus particles were detected in greenhouse-grown Gynura aurantiaca plants during a study of citrus diseases, and some of their biological and physicochemical properties were determined. The gynura plants displayed vein clearing of young leaves as the earliest symptom and later on, an anomalous growth of some leaves. This syndrome could be easily transmitted by graft, dodder and, with more difficulty, by sap inoculation. Electron microscopy showed bacilliform virions of about 260 × 70nm, in perinuclear spaces. Purified rhabdovirus particles inoculated to healthy plants were infectious, showing that this virus was the causal agent of the gynura syndrome. An estimate of the buoyant density in sucrose of the virus gave a value of 1.17g/,cm³. Analysis of virion proteins by SDS-PAGE revealed four major bands of relative molecular mass 81.5, 56.6, 31.6 and 24.6 x 10³, suggesting that these corresponds to the G, N, M1 and M2 proteins respectively, of the subgroup B of plant rhabdoviruses. From these data we conclude that the rhabdovirus here described should be placed in the potato yellow dwarf virus subgroup of plant rhabdoviruses. The fact that a Citrus could be the original source of the virus is discussed.     

The occurrence of maize mosaic virus on sorghum in India1

A leaf disease of sorghum (Sorghum bicolor) characterised by fine discontinuous chlorotic streaks between the veins, was observed on sorghum grown during the 1987/88 post-rainy season in peninsular India. Early-infected plants were stunted, had shortened internodes, and produced poorly developed panicles. The virus was transmitted by the delphacid planthopper, Peregrinus maidis. Negatively stained leaf dip preparations contained bullet-shaped virus particles (208 ± 4.4 × 66 ± 1.0 nm) resembling those of rhabdoviruses. In ultrathin sections, the particles budded through the inner nuclear membrane and were present in the cytoplasm within membrane-bound vesicles that were apparently contiguous with the distended outer nuclear membrane. A method for purifying the virus was developed utilising polyethylene glycol (PEG) precipitation, Celite filtration and sucrose densitygradient centrifugation. An antiserum was produced in rabbits with a titre of 1/2650 in the precipitin ring interphase test. The virus could be detected in infected sorghum leaf tissues using a direct antigen coating form of enzyme-linked immunosorbent assay (DAC-ELISA). In immuno-double diffusion tests, the virus reacted positively with antisera to maize mosaic virus (MMV) from Reunion (MMV-RN) and Hawaii (MMV-HI), but not with antisera to barley yellow striate mosaic (BYSMV), cereal chlorotic mottle (CCMV), and cynodon chlorotic streak (CCSV) viruses. Thus, the virus isolated from sorghum is designated the MMV-S isolate. In DAC-ELISA tests, MMV-S reacted positively with antisera to MMV-R, MMV-HI, MMV-Florida isolate, CCSV, and CCMV, and weakly with antiserum to BYSMV. SDS-polyacrylamide gel electrophoresis revealed four major proteins of relative mass M_r 70 000, 59 000, 32 000 and 28 000. In electro-blot immunoassay, MMV and CCSV antisera detected the G and N proteins. These data suggest that MMV-S should be placed in the sonchus yellow net virus subgroup of plant rhabdoviruses.     

Properties of broad bean yellow band virus, a possible new tobravirus

A virus was transmitted from broad bean plants in Apulia (Southern Italy) with leaves showing yellow rings, line patterns or yellow vein banding and malformations and necrosis of pods. Symptoms in some, but not all, test plants were similar to those induced by tobraviruses. Purified virus preparations contained two classes of rod-shaped particles containing c. 5% nucleic acid with sedimentation coefficients of 186S and 276S. After centrifugation to equilibrium in CsCl gradients, two components were resolved, with buoyant densities of 1·298 and 1·316 g/cm³. Unfractionated virus preparations contained two species of single-stranded RNA with mol. wts of c. 1·06 × 10⁶ and 2·48 × 10⁶ and one species of coat protein with mol. wt of c. 21 300. The modal lengths of the two classes of particles, both in plant sap and in purified preparations, were 77 nm (S particles) and 202 nm (L particles). L particles accumulated in infected cells in paracrystalline aggregates, whereas S particles were randomly distributed in the cytoplasm of cells. The virus was serologically unrelated to two isolates of tobacco rattle virus and two isolates of pea early-browning virus. The virus, named broad bean yellow band, is considered a distinct tobravirus.     

Narcissus latent, a virus with filamentous particles and a novel combination of properties

As previously reported, narcissus latent virus (NLV) has flexuous filamentous particles measuring c. 650 nm × 13 nm, is manually transmissible to Nicotiana clevelandii and Tetragonia expansa, and is transmitted by the aphid Myzus persicae following brief acquisition access periods. In contrast to previous reports the virus particle protein has an apparent mol. wt of c. 45 kD. Moreover, infected cells in N. clevelandii leaves contain cytoplasmic inclusion bodies resembling those of potyviruses. In vitro translation of NLV RNA produced only one major product (mol. wt c. 25 kD) which was not precipitated by antisera to virus particle protein or to cytoplasmic inclusion protein. Antisera to 12 potyviruses and nine carlaviruses failed to react with sap containing NLV particles. Similarly antiserum to NLV particles did not react with particles of seven potyviruses or four carlaviruses. A weak reaction was detected between NLV particles and antiserum to particles of maclura mosaic virus (MMV), a virus which resembles NLV in particle morphology and particle-protein size, and in inducing pinwheel inclusions. The cytoplasmic inclusion proteins (CIPs) of NLV, MMV and from narcissus plants with yellow stripe symptoms were serologically inter-related. These proteins were also serologically related to, and had mol. wt similar to, the CIP of members of the potyvirus group. Particles with the size and antigenic specificity of those of NLV were found consistently in narcissus plants with yellow stripe disease. Narcissus latent and narcissus yellow stripe viruses therefore seem to be synonymous and, together with MMV, have properties distinct from those of any previously described virus group.     

Involvement of Volatile Substances in Systemic Resistance of Barley Against Erysiphe graminis f. sp. hordei Induced by Pruning of Leaves

Horsegram yellow mosaic disease was shown to be caused by a geminivirus; horsegram yellow mosaic virus (HYMV). The virus could not be transmitted by mechanical sap inoculation. Leaf dip and purified virus preparations showed geminate virus particles, measuring 15-18 * 30 nm. An antiserum for HYMV was produced and in enzyme-linked immunosorbent assay (ELISA) and immunosorbent electron microscopy (ISEM) tests HYMV was detected in leaf extracts of fieldinfected bambara groundnut, french bean, groundnut, limabean, mungbean, pigeonpea and soybean showing yellow mosaic symptoms. Bemisia tabaci fed on purified HYMV through a parafilm membrane transmitted the virus to all the hosts listed above but not to Ageratum conyzoides, okra, cassava, cowpea, Croton bonplandianus, Lab-lab purpureus, Malvastrum coromandalianum and tomato. No reaction was obtained in ELISA and ISEM tests between HYMV antibodies and extracts of plants diseased by whitefly-transmitted agents in India such as A. conyzoides yellow mosaic, okra yellow vein mosaic, C. bonplandianus, yellow vein mosaic, M. coromandalianum yellow vein mosaic, tomato leaf curl and cassava mosaic. HYMV was also not found to be related serologically to bean golden mosaic, virus.     

Transmission,Particle Size and Additional Hosts of the Rhabdovirus Causing Maize Mosaic in Shiraz,Iran1

The rhabdovirus causing maize mosaic in Shiraz, Iran, is transmitted by Ribautodelphax notabilis Logvinenko (Homoptera, Delphacidae). Average size of bullet-shaped virus particles in negatively stained leaf-dip preparations of naturally or experimentally infected plants was 81 × 179 nm. The virus is transmitted to wheat and barley causing mosaic and severe stunting. Similar virus particles have been observed in leaf-dip preparations of naturally infected wheat, barley and Sudangrass. This is believed to be the first record of the involvement of R. notabilis in virus transmission. The relationship of the described isolate with similar viruses infecting gramineous plants is discussed.     

Far‐eastern strains of bean common mosaic virus and methods of their immunodiagnostics

The paper presents data of investigation on the physico‐chemical and antigenic properties of capsid proteins of the Bean common mosaic virus isolated from Phaseolus plants in the Russian Far East (BCMV‐R) and from China (BCMV‐C). A method for isolation of the virus preparation was selected. The purified preparations of two isolates BCMV have been obtained. The presence of one polypeptide in structural proteins of virions was established and their molecular masses determined (BCMV‐R ‐ 31,6 kD; BCMV‐C ‐ 32,1 kD). Polyclonal antiserum was obtained with titre 1:12800 and the indirect and “sandwich"‐variants of ELISA were developed to detect this virus. The allied relationships were established with the bean yellow mosaic virus and with the type representative of the genus Potyvirus ‐ PVY. Based on the data of physico‐chemical and antigenic properties it was concluded that isolates BCMV‐R and BCMV‐C are two independent strains of this virus. The presence of strain‐, virus‐ and genusspecific epitopes of capsid proteine was revealed as a result of comparison of antigenic characteristics of the Russian Far Eastern and Chinese strains of BCMV. A high antigenic activity of capsid protein of the Russian Far Eastern strain was observed.     

Purification and Characterization of Indian Cassava Mosaic Virus

The Indian cassava mosaic virus (ICMV) was transmitted by the whitefly Bemisia tabaci and sap inoculation. ICMV was purified from cassava and from systemically infected Nicotiana benthamiana leaves. Geminate particles of 16–18 × 30 nm in size were observed by electron microscopy. The particles contained a single major protein of an estimated molecular weight of 34,000. Specific antiserum trapped geminate particles from the extracts of infected cassava and N. benthamiana plants in ISEM test. The virus was detected in crude extracts of infected cassava, ceara rubber, TV. benthamiana and N. tabacum cv. Jayasri plants by ELISA. ICMV appeared serologically related to the gemini viruses of Acalypha yellow mosaic, bhendi yellow vein mosaic, Croton yellow vein mosaic, Dolichos yellow mosaic, horsegram yellow mosaic, Malvastrum yellow vein mosaic and tobacco leaf curl.     

Peanut stripe virus - a new seed-borne potyvirus from China infecting groundnut (Arachis hypogaea)1

A new virus, peanut stripe (PStV), isolated from groundnut (Arachis hypogaea) in the USA, induced characteristic striping, discontinuous vein banding along the lateral veins, and oakleaf mosaic in groundnut. The virus was also isolated from germplasm lines introduced from the People's Republic of China. PStV was transmitted by inoculation of sap to nine species of the Chenopodiaceae, Leguminosae, and Solanaceae; Chenopodium amaranticolor was a good local lesion host. PStV was also transmitted by Aphis craccivora in a non-persistent manner and through seed of groundnut up to 37%. The virus remained infective in buffered plant extracts after diluting to 10^-3, storage for 3 days at 20°C, and heating for 10 min at 60°C but not 65°C. Purified virus preparations contained flexuous filamentous particles c. 752 nm long, which contained a major polypeptide of 33 500 daltons and one nucleic acid species of 3·1 × 10⁶ daltons. In ELISA, PStV was serologically related to blackeye cowpea mosaic, soybean mosaic, clover yellow vein, and pepper veinal mottle viruses but not to peanut mottle, potato Y, tobacco etch, and peanut green mosaic viruses. On the basis of these properties PStV is identified as a new potyvirus in groundnut.     

Further Studies on Cynara Rhabdovirus

Cynara rhabdovirus (CyRV) was isolated from symptomless artichoke plants in southern Italy using Nicotiana langsdorffii as susceptible host and immune serum to artichoke latent virus to eliminate this virus from inoculum. CyRV can infect several solanaceous species, has thermal inactivation point of 40-45°C, dilution end point between 10^?2 and 10^?5 and longevity in vitro at 4 and 20°C of 4-5 days and 6-24 h, respectively. It was purified and used for preparing antisera with homologous titre varying from 1: 16 to 1: 64. In decoration tests, the virus did not react against antisera to eggplant mottled dwarf virus (EMDV) and its antiserum did not decorate ivy vein clearing virus (IVCV). Ultrastructural aspects of CyRV infection in Datura stramonium and Nicotiana glutinosa were very like those described for the same virus in the past except for presence of longer virions which were often encountered in infected cells during this study.     

Auswirkungen des Anbaus einer Wirts- und einer Nichtwirtspflanze unter wechselnden ökologischen Bedingungen auf die Populationsdynamik von Rhizoctonia solani Kühn und Fusarium solani f. pisi (Jones) Snyd. et Hans

An isometric virus was isolated from Helianthus annuus L. plants showing a yellow leaf spot mosaic on affected leaves. Infected plants were found in different ecological regions of Ukraine. A procedure of virus purification is described. The diametres of the virus particles were nonuniform and ranged from 50 to 120 nm. The sedimentation coefficient of the virus was 518–540 S and the floating density in the CsCl gradient was 1.22 g/cm³. The MW of proteins separated by electrophoresis amounted to 78±0.9, 58±0.8, 52±0.2, and 27±0.8 kDa, respectively. The virus was assigned to the tospoviruses for which sunflower is a new previously undescribed natural host plant.     

Assigning DYW-type PPR proteins to RNA editing sites in the funariid mosses Physcomitrella patens and Funaria hygrometrica

The plant‐specific pentatricopeptide repeat (PPR) proteins with variable PPR repeat lengths (PLS‐type) and protein extensions up to the carboxyterminal DYW domain have received attention as specific recognition factors for the C‐to‐U type of RNA editing events in plant organelles. Here, we report a DYW‐protein knockout in the model plant Physcomitrella patens specifically affecting mitochondrial RNA editing positions cox1eU755SL and rps14eU137SL. Assignment of DYW proteins and RNA editing sites might best be corroborated by data from a taxon with a slightly different, yet similarly manageable low number of editing sites and DYW proteins. To this end we investigated the mitochondrial editing status of the related funariid moss Funaria hygrometrica. We find that: (i) Funaria lacks three mitochondrial RNA editing positions present in Physcomitrella, (ii) that F. hygrometrica cDNA sequence data identify nine DYW proteins as clear orthologues of their P. patens counterparts, and (iii) that the ‘missing’ 10th DYW protein in F. hygrometrica is responsible for two mitochondrial editing sites in P. patens lacking in F. hygrometrica (nad3eU230SL, nad4eU272SL). Interestingly, the third site of RNA editing missing in F. hygrometrica (rps14eU137SL) is addressed by the DYW protein characterized here and the presence of its orthologue in F. hygrometrica is explained through its simultaneous action on site cox1eU755SL conserved in both mosses.     

Begomoviruses Associated with Leaf Curl Disease of Tomato in Java,Indonesia*

We report that several begomoviruses are associated with tomato leaf curl disease in Java, Indonesia. Tomato plants with leaf curl symptoms were collected from Bandung (west Java), Purwokerto (central Java), Magelang (central Java) and Malang (east Java) of Indonesia, the major tomato‐growing areas of the country. Viruses were detected using the polymerase chain reaction (PCR), with universal primers for the genus Begomovirus. PCR‐amplified fragments were cloned and sequenced. Based on sequence comparisons and phylogenetic analyses, the viruses were divided into three groups. With respect to amino acid (aa) identities of the N‐terminal halves of the coat proteins compared in this study, group I was most closely related to Ageratum yellow vein virus (AYVV) (97%), Ageratum yellow vein China virus‐[Hn2] (AYVCNV‐[Hn2]) (96%) and Ageratum yellow vein virus‐[Taiwan] (AYVV‐[Tai]) (95%), and ageratum‐infecting begomovirus from Java (99%). Group II had high sequence identity with a tentative species of tomato leaf curl Java virus (ToLCJAV) (96% aa) for the CP. Group III was most closely related to a proposed species of Pepper yellow leaf curl Indonesia virus (PepYLCIDV) (90% aa identity) by its partial CP sequence.     

Establishment,characterization and viral susceptibility of two cell lines derived from leopard wrasse Macropharyngodon geoffroy

Two new fish cell lines were established from skin (LWSK) and fin (LWFN) of leopard wrasse Macropharyngodon geoffroy. These cells grew optimally at 25° C in Leibovitz‐15 medium supplemented with 10% foetal bovine serum. Proliferation of M. geoffroy cells remained serum dependent up to cell passage 16, and cell‐plating efficiency ranged from 12 to 16%. Karyotypic analysis of these new cell lines at cell passage 8 indicated that both cell lines remained diploid with a peak chromosomal count of 144. PCR amplification of 16S mitochondrial DNA and the subsequent analysis confirmed that these cell lines were indeed derived from M. geoffroy. Results of viral challenge assays revealed that both LWSK and LWFN shared patterns of viral susceptibility similar to that of six fish viruses tested: LWSK and LWFN cells were highly permissive to channel catfish virus, spring viremia carp virus and snakehead rhabdovirus with high‐yield virus production ranging from 10^7·18±0·17 to 10^8·37±0·16 TCID₅₀ ml^?1 (mean ± s.d .). These newly established cell lines would be useful in attempts to isolate and study aquatic viruses, particularly the viral aetiology of green turtle fibropapilloma as M. geoffroy is known to be one of the common cleaner fish of green sea turtles.     

A Carlavirus and a Rhabdovirus Infecting Lonicera X brownii cv. Dropmore Scarlet in Western Canada

Chlorotic and necrotic spots, yellow mottle, and vein banding leaf symptoms were seen on two honeysuckle vines in the Botanical Garden, University of British Columbia. Electron microscopic examination showed the presence of rhabdovirus and carlavirus particles. This is the first report of a rhabdovirus in honeysuckle. The carlavirus may be honeysuckle latent virus, although it was transmitted to only three of its nine reported herbaceous hosts, and it was not transmitted by the reported aphid vector, Hydaphis foeniculi . Both types of virus particles were seen in mesophyll, phloem parenchyma and companion cells of honeysuckle. The rhabdovirus was not transmitted to any other host and, in honeysuckle, was found only in the Spring. As its concentration declined, the number of carlavirus particles increased.     

Oversummering Hosts For Some Cucurbit Viruses in the Jordan Valley

Variable mosaic and yellow symptoms were often encountered in weeds growing during the summer of 1987 and 1988 in the Jordan Valley. Cucumber mosaic virus was recovered in the summer only from Dolicus lablab or from Solatium nigrum. In addition to the cucurbit weeds watermelon mosaic virus-2 occurred in Malva parviflora. Zucchini yellow mosaic virus was found in all tested cucurbit weeds except for Ecballium elaterium. Moreover this virus was isolated from Sysimbirium irio and Crepis aspera. Cucumber vein yellowing virus was recovered from some cucurbits with vein yellowing.     

The Partial Characterization of a Badnavirus Infecting the Greater Asiatic or Water Yam (Dioscorea alata)

A bacilliform virus from Dioscorea alata, designated Dioscorea alata bacilliform virus (DaBV), from Barbados and West Africa and from other Dioscorea spp. from West African, Carribean, Asian and South American countries, has been characterized. The virus was transmitted by the mealybug, Planococcus citri and by mechanical transmission of partially purified preparations to several Dioscorea spp. DaBV was serologically related to a distinct bacilliform virus from Dioscorea bulbifera, to one isolate of sugarcane bacilliform badnavirus and two isolates of banana streak badnavirus (BSV) but was not related to another isolate of BSV or to Kalanchoe top spotting or cacao swollen shoot badnaviruses. The coat protein of DaBV was about 56 kDa and the nucleic acid was double-stranded DNA of about 7.5 kbp, part of which showed distant homology with other badnaviruses. Thus, DaBV is a distinct hitherto uncharacterized badnavirus.     

Garlic yellow streak virus, a potyvirus infecting garlic in New Zealand

In New Zealand, all garlic (Allium sativum) plants tested were infected by a virus with flexuous filamentous particles 700–800 nm long. This virus, called garlic yellow streak virus (GYSV), infected only two of 12 species tested and was transmitted to garlic by the aphid Myzus persicae in a non-persistent manner. In garlic sap, GYSV was infective at a dilution of 10^-4 but not 10^-3, after heating for 10 min at 60°C but not 65°C, and after 2 days but not 3 days at 25°C. The yield of virus, purified from naturally infected garlic, was 3–4 mg/kg fresh leaf. Preparations had A₂₆₀/A₂₈₀= 1.28 and A_man/A_min= 1.08. The virus particles had a sedimentation coefficient of 149S and a buoyant density in CsCl of 1.334 g/cm³. Mol. wt estimates for the virus nucleic acid were 2.95 × 10⁶ by electrophoresis in polyacrylamide gels and 3.46 × 10⁶ from the sedimentation coefficient (41.4S) in linear-log sucrose density gradients. Two polypeptides were detected in virus preparations; one (mol. wt 30 500) was possibly a breakdown product of the other (mol. wt 33 000). GYSV was serologically distantly related to onion yellow dwarf and leek yellow stripe viruses but was considered to be a separate virus because it differed from them in host range.