Stabilization, culture and some properties of tulip halo necrosis virus

Tulip halo necrosis virus, obtained from tulips with leaf necrosis, is very labile in crude sap but can be transmitted consistently by inoculating Nicotiana clevelandii plants with extracts made in pH 8 phosphate buffer containing a stabilizing agent such as 0.2M 2-mercaptoethanol or 0.01M dithiothreitol. Of the fifteen species in five families of Angiosperms infected by inoculation with sap, few are suitable as sources of inoculum. Cultures of the virus can be maintained in Nicotiana clevelandii kept at 14 or 18d?C but not at 21d?C. Infectivity can be assayed in Chenopodium quinoa, in which necrotic local lesions are produced. Stabilized extracts of leaves were infective at a dilution of 1/16 but rarely at 1/32, and infectivity decreased disproportionately with dilution. Infectivity of all extracts was abolished in 10 min at 50d?C and of some at 45d?C, but survived when extracts were clarified using diethyl ether or trichlorotrifluoroethane. The virus was not transmitted by the aphid Myzus persicae.     

Contrasting patterns in the spread of two seed-borne viruses in pea embryos

The temporal and spatial patterns of pea seed-borne mosaic potyvirus (PSbMV) and pea early browning tobra-virus (PEBV) accumulation in pea embryos were analyzed using in-situ hybridization and immunohistochemistry. For PSbMV, which infects embryos after fertilization, the distribution changed as the embryo developed and some tissues remained free of virus infection. In contrast, embryos were uniformly infected with PEBV from the earliest stages of embryo development, and PEBV was detected in the egg cell and pollen grains, indicative of gametic transmission into the embryo. These observations suggest that gametically transmitted viruses may be appropriate as potential vectors for the ectopic and uniform expression of novel genes in embryonic tissues. Functional complementarity in the two processes of embryo invasion was tested following co-inoculation with PSbMV and PEBV. Instead of complementation, interference in PSbMV seed transmission by PEBV was observed; PEBV seed transmission remained unaffected by PSbMV.     

Purification and properties of Australian lucerne latent virus, a seed-borne virus having affinities with nepoviruses

An isolate of Australian lucerne latent virus (ALLV) from lucerne in New Zealand was mechanically transmitted to a few herbaceous hosts. It induced diagnostic symptoms in several species of the Chenopodiaceae, but was symptomless in most other hosts including lucerne and Trifolium subterraneum. It was seed transmitted in lucerne. When assayed to Chenopodium quinoa, infective C. quinoa sap lost infectivity after diluting to 10^-4, heating for 10 min at 55°C and storage for 4 days at 4°C. ALLV was purified from infected C. quinoa or pea plants by extracting sap in 0.1 m borate buffer (pH 7) containing 0.2% 2-mercaptoethanol and clarifying with 15% bentonite suspension, high and low speed centrifugation and sucrose density gradient centrifugation. Purified virus preparations contained isometric particles about 25 nm in diameter and sedimented as three virus components with sedimentation coefficients (s_20-w⁰) of 56 S, 128 S and 133 S. The 56 S component appeared to consist of nucleic acid-free protein shells. Polyacrylamide gel electrophoresis of virus preparations showed that ALLV contained a single protein species of mol. wt 55 000 and two RNA species of mol. wt 2.1 × 10⁶ and 2.4 × 10⁶. An antiserum to ALLV had an homologous titre of 1/256 to purified virus but failed to detect ALLV in infective sap of C. quinoa, pea or lucerne. Purified ALLV failed to react to antisera to 28 distinct isometric plant viruses including those to 10 nepoviruses.     

The association between species of Trichodorus and Paratrichodorus vector nematodes and serotypes of tobacco rattle tobravirus

Virus transmission bait tests with single trichodorid nematodes from England, the Netherlands, Scotland or Sweden showed that a substantial degree of specificity occurs between trichodorid vector species and tobravirus serotypes. This specificity was more apparent with associations between Paratrichodorus vector species and tobravirus serotypes than with those between Trichodorus species and tobravirus serotypes. P. pachydermus transmitted PRN-serotype tobacco rattle virus (TRV) isolates, P. teres ORE-serotype isolates and P. anemones TRV isolates which did not react with any of the antisera used, but which could be distinguished from all other isolates by their symptomatology in Chenopodium test plants. T. viruliferus, T. primitivus and T. cylindricus transmitted RQ-serotype isolates and the latter species also transmitted TRV isolates reacting with TCB2 and pea early-browning SP5-antisera. Several TRV isolates transmitted by T. cylindricus failed to react with any of the antisera used.     

The purification and some properties of cocoa necrosis virus, a serotype of tomato black ring virus

Cocoa necrosis virus (CNV) was transmitted by sap inoculation to twelve of twenty-one species tested. It was propagated and assayed in Phaseolus vulgaris. Sap from P. vulgaris was infective after dilution to 10^-3but not 10^-4, after 10 min at 60 d?C but not 65 d?C, and after 4 but not 7 days at 20–24 d?C. Lyophilized sap from P. vulgaris was infective after 2 years in vacuo. Virus was prepared by extracting infected leaves of P. vulgaris with 0.1 M phosphate (pH 7.5) containing 0.05 M ethylene diamine tetra-acetate and 0.02 M thioglycollate. After clarification with n-butanol, virus was purified by precipitation with polyethylene glycol and several cycles of differential centrifugation. Such preparations were very infective and contained numerous particles, 24–26 nm in diameter with a hexagonal profile, which sedimented as two components with sedimentation coefficients (Sd?_20,w) of 101 S and 129 S. The absorption spectra of both components with maximum and minimum absorption at 259 and 240 nm respectively were typical of nucleoproteins (101 S component, A 260/280 = 1.63; A 260/240 = 1.40:129 S component, A260/280 = 1.78; A260/240 = 1.58) and indicated nucleic acid contents of ca. 35% for the 129 S component and ca. 20% for the 101 S component; values calculated from the sedimentation coefficients were 41 and 30% respectively. Only the 129 S component seemed to be infective and was not more so when mixed with 101 S component. Both components contained a single protein subunit weighing ca. 60000 daltons. Under certain conditions sap fractionated without butanol gave virus preparations containing empty protein shells (54 S) and small spherical particles (20–30 S) ca. 12 nm diameter. CNV is a serotype of tomato blackring virus and is distantly related to Hungarian chrome mosaic virus. The cryptogram of CNV is */*:*/(35–41):S/S:S/*.     

Pathology, soil transmission and characterization of cymbidium ringspot, a virus from cymbidium orchids and white clover (Trifolium repens)

Two strains of a virus, designated cymbidium ringspot virus (CyRSV), were isolated from cymbidium orchids and from Trifolium repens respectively in Britain. Experimentally infected cymbidiums developed slight chlorotic ring-mottle; T. repens developed flecks and mottling in the leaves, and slight stunting. Of 101 plant species tested, the cymbidium strain infected sixty-one (thirteen systemically) in twenty-three of thirty-five families; the clover strain infected sixty-four species (eighteen systemically) in twenty-two families. Both strains were propagated in Nicotiana clevelandii and assayed in Chenopodium quinoa. CyRSV was readily transmitted by inoculation of sap, and by foliage contact between plants, but not by the aphids Myzus persicae or Acyrtho-siphon pisum, nor through seed of T. incarnatum, Phaseolus vulgaris or N. clevelandii. Highly infective virus was released into soil from roots of infected N. clevelandii, and acquired by bait seedlings planted in such soil. Similar transmission occurred when purified virus was applied to the surface of sterilized soil containing bait plants; there was no evidence for any living soil vector. The virus was eliminated from 96 % of small cuttings taken from infected N. clevelandii plants grown at 35–37 °C for 9 wk. CyRSV was still infective in sap of N. clevelandii after dilution to 10?⁵-io–⁶ (only 2 × 10^_1 in cymbidium sap), or after 10min at 85–90 °C. It survived at least 10 months at c. 20 °C and more than 12 yr at 2 °C. Lyophilized sap was highly infective after over 13 yr at laboratory temperatures under high vacuum. Purified preparations made by clarification with n-butanol, followed by differential centrifugation and exclusion chromatography on controlled-pore glass beads, contained isometric particles c. 30 nm diam., with s°_20W= 137 S, and had a buoyant density in caesium chloride of 1–36 g/ml. The A 260/A 280 ratio was 1–55, and A max(26o)/A min(242) was 1–17. The virus contained c. 15 % of single-stranded RNA of mol. wt 1–7 × 10⁶; the nucleotide base ratios were: G27'8; A24/9; C2I-3; U26-I. There was one capsid polypeptide of mol. wt 43600. The virus was a good immunogen and a strongly reacting antigen in vitro; in Immunoelectrophoresis, each strain migrated as a single antigenic component towards the cathode. The cymbidium and clover strains were serologically closely related, although spurs were produced in immunodiffusion. No serological relationship was found to forty-three other isometric viruses, including eighteen tombusvirus isolates; CyRSV nevertheless shares many properties with tombusviruses, and we assign it provisionally to this group. The cryptogram is: R/r:1:7/15:S/S:S/O.     

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.     

Corn Stunt Spiroplasma in Dicotyledonous Plants

Corn stunt spiroplasma (CSS) was transmitted by the leafhopper vector Euscelidius variegatus (Kirschbaum) and produced symptoms on four dicotyledonous plant species, Sinapis alba L. (mustard), Pisum sativitm L. (pea), Raphanus sativus L. (radish) and Spinacia oleracea L. (spinach). The vectors became infective by microinjection with a broth culture of CSS. This insect also acquired CSS from infected mustard plants and transmitted it to healthy ones.     

Vector relationships and other characteristics of barley yellow striate mosaic virus (BYSMV)

Barley yellow striate mosaic virus (BYSMV) was inoculated by its planthopper vector Laodelphax striatellus (Homoptera, Delphacidae) to 44 species of Gramineae, 26 of which in eight tribes were infected. The virus was not transmitted through wheat seed nor did it infect five dicotyledonous hosts of other rhabdoviruses. The most susceptible species were in the tribes Festuceae and Hordeae. Barley, Bromus spp., oats, Phalaris canariensis, Setaria italica, Sorghum spp., and sweet corn cv. Golden were diagnostic hosts. Electron microscopy of crude sap was also a sensitive diagnostic method. Properties of BYSMV were determined by injecting L. striatellus with crude sap from infected barley. Sap was infectious after 10 min at 50–55 °C but not after 10 min at 60 °C, when diluted with buffer to 10^--² but not to 10^--³, when stored for 2 but not 4 days at 5 °C or when kept for 1 but not 2 days at 22 °C. The planthopper Javesella pellucida was an experimental vector of BYSMV but the virus was not transmitted by the leafhoppers Macrosteles sexnotatus or Psammotettix striatus (Homoptera, Cicadellidae). The latent period of BYSMV in L. striatellus was most commonly 15 or 16 days (minimum, 9 days; maximum, 29 days). The minimum acquisition access period for transmission was between 1 h and 5 h, and the minimum inoculation feeding time was 15 min. After 24 h and 8 day acquisition feeds, 30.4% and 42.8% respectively of L. striatellus transmitted BYSMV. When transferred daily, infective hoppers transmitted virus intermittently. The maximum retention of infectivity by L. striatellus was 36 days. Two of five infective females transmitted BYSMV transovarially. Larvae became infective in the second wk after hatching and transmitted for up to 3 wk.     

Studies on a virus causing stem grooving and graft-union abnormalities in Virginia Crab apple*

A virus was transmitted from apple trees to Nicotiana glutinosa and Chenopodium spp. and back to a range of woody indicators in which it affected only Virginia Crab; symptoms were grooves in the xylem, and swelling and necrosis of the scion immediately above the union with the stock. The virus was distinct from that causing stem pitting in Virginia Crab, because although easily detectable in several apple varieties, it was not found in many trees infected with stem pitting virus. The stem grooving virus has flexous particles 600–700 m/μ long, a heat inactivation point of 67 °C, a dilution end-point of 10^-3 in N. glutinosa sap and remains infective for at least 2 days at 20 °C.     

Purification and some properties of Tephrosia symptomless virus

Tephrosia symptomless virus (TSV), isolated from Tephrosia villosa, is widely distributed in coastal districts of Kenya. The virus was readily transmitted by inoculation of sap, but not by Aphis craccivora or Apion sp. (Curculionidae) or through soil. Host range was very restricted and it infected only 10 of 70 species tested in one of nine plant families; susceptible species were confined to five genera within the Papilionaceae. The virus was cultured, propagated and assayed in soybean. TSV remained infective after 10 min at 85°C, 3 wk at 20°C and 26 wk at -12°C; crude infective sap of Glycine max retained infectivity when diluted 10^-6 but not 10^-7. Virus was purified from systemically infected soybean by clarifying sap extracted in 0.06 m phosphate buffer containing 0.001 m EDTA and 0.1% thioglycollic acid (pH 7.5) with equal volumes of 1:1 n-butanol/chloroform followed by two cycles of differential and one of sucrose density gradient centrifugation. Purified preparations contained c. 33 nm isometric particles. TSV contained RNA and one protein of molecular weight 1.53. 10⁶ and c. 42 000, respectively. Analytical centrifugation indicated a single component with a sedimentation coefficient (s.20, w) of 127 S; in Cs₂SO₄ and CsCl isopycnic gradients a single virus band formed; buoyant density in CsCl was 1.361. TSV was not related serologically to any of 44 viruses in nine plant virus groups but it resembled the tombusviruses and other ungrouped viruses such as carnation mottle in some of its properties.     

Narcissus mosaic virus

Narcissus mosaic virus (NMV) is widespread in British crops of trumpet, large-cupped and double daffodils, but was not found in Narcissus jonquilla or N. tazzeta. Many commercial daffodil cultivars seem totally infected, and roguing or selection is therefore impracticable. Strict precautions by breeders and raisers to prevent infection of new cultivars is recommended. Healthy daffodil seedlings were readily infected with NMV by mechanical inoculation, but the virus was not detected in them until 17 months after inoculation, when a mild mosaic appeared. NMV infected twenty-eight of fifty-three inoculated plant species; only five (Nicotiana clevelandii, Gomphrena globosa, Medicago sativa, Trifolium campestre and T. incarnatum) were infected systemically, and NMV was cultured in these and assayed in Chenopodium amaranticolor and Tetragonia expansa. The virus was not transmitted to and from G. globosa or N. clevelandii by three aphid species, or through the seeds of Narcissus, G. globosa and N. clevelandii but was transmitted by handling. G. globosa sap was infective at a dilution of 10 ^-5 but not at 10^-6, when heated for 10 min. at 70° C. but not at 75° C, and after 12 weeks at 18° C, or 36 weeks at 0–4° C. NMV withstood freezing in infected leaves and sap, and purified preparations and freeze-dried sap remained infective for over 2 years. NMV was precipitated without inactivation by ammonium sulphate (313 g./l.) but was better purified by differential centrifugation of phosphate-buffer extracts treated with n-butanol. Such virus preparations from G. globosa, N. clevelandii, C. amaranticolor and T. expansa were highly infective, serologically active, produced a specific light-scattering zone when centrifuged in density-gradients and contained numerous unaggregated particles with a commonest length of 548–568 mμ. Antisera prepared in rabbits had precipitin tube titres of 1/4096. NMV was detected in three experimental hosts but not in narcissus sap. Unlike some viruses with elongated particles, NMV precipitates with antiserum in agar-gel. Purified preparations reacted with antiserum to a Dutch isolate of NMV but not with antisera to seven other viruses having similar particles and in vitro properties, or to narcissus yellow stripe virus.     

Infection of Anastrepha ludens following soil applications of Heterorhabditis bacteriophora in a mango orchard

To determine the efficacy of Heterorhabditis bacteriophora Poinar (Nematoda: Heterorhabditidae) for control of Anastrepha ludens (Loew) (Diptera: Tephritidae), field experiments were performed in a mango orchard with soil temperatures of 24–29 °C. The density of third‐instar A. ludens (50–500 larvae per plot) released into 0.25 m² wood‐framed experimental plots containing soil (16% wt/wt moisture) previously treated with 125 infective juveniles per square centimetre soil surface did not significantly influence the prevalence of infection by H. bacteriophora. In subsequent experiments, the percentages of infection of fly pupae were positively correlated with the concentration of infective stages applied to soil plots. The highest average percentage of infection (74% at 250 infective juveniles per square centimetre) was observed when fly larvae were released simultaneously onto soil, compared to larvae that emerged from laboratory‐infested mangoes over a period of 8 days (52% infection at 500 infective juveniles per square centimetre). Double applications of infective juveniles at an interval of 4 days did not greatly improve the prevalence of infection (～10% higher) compared to single applications. Between 9 and 15% of larvae that remained within infested mangoes became infected by nematodes, irrespective of the concentration of nematodes applied to each experimental plot. We conclude that effective control of A. ludens requires very high densities of H. bacteriophora. The successful use of this nematode for biocontrol of A. ludens will depend on identifying ways of overcoming the fly's ability to avoid infection.     

Transmission of the hop strain of arabis mosaic virus by Xiphinema diversicaudatum*

Hop plants became infected with the hop strain of arabis mosaic virus (AMV(H)) when grown in hopfield and woodland soil in which infected plants had been growing. Infection occurred in soil infested with the dagger nematode Xiphinema diversicaudatum, but neither in uninfested soil nor in soil previously heated to kill nematodes. X. diversicaudatum transferred direct from hop soils transmitted AMV(H) to young herbaceous plants and to hop seedlings; some of the hop seedlings developed nettlehead disease. A larger proportion of plants was infected using X. diversicaudatum obtained from a woodland soil and then given access to the roots of hop or herbaceous plants infected with AMV(H). AMV(H) was transmitted by adults and by larvae, in which the virus persisted for at least 36 and 29 wk, respectively. Difficulties were encountered in detecting AMV(H) in infected hop plants, due partly to the delay in virus movement from roots to shoots. Infection of hop shoots was seldom detected until the year after the roots were infested and sometimes nettlehead symptoms did not appear until the third year. Isolates of arabis mosiac virus from strawberry did not infect hop. The results are discussed in relation to the etiology and control of nettlehead and related diseases of hop.     

Arracacha virus B, a second isometric virus infecting arracacha (Arracacia xanthorrhiza; Umbelliferae) in the Peruvian Andes

Arracacha virus B (AVB), a previously undescribed virus, was found together with arracacha virus A or with a 750 nm flexous filamentous virus in arracacha (Arracacia Xanthorrhiza; Umbelliferae) growing in the Huanuco region of the Peruvian Andes. AVB was transmitted by inoculation of sap to 30 species from eight families out of 45 species from 10 families tested. It was transmitted through seed of Chenopodium quinoa but not by Myzus persicae. AVB was best propagated in C. Quinoa or Tetragonia expansa and assayed in C. quinoa, C. murale or C. amaranticolor. Sap from infeted <C. Quinoa was occasionally infective after dilution to 10^-4 but not 10^-5, after 10 min at 65 d? C but not 70 d? C, and after 12 but not 14 days at 20 d? C. In neutral phosphotungstate, AVB has isometric partilces c. 26 nm in diameter with a hexagonal profile. About 50- 150 A1 cm₂₆₀ units of purified virus were obtained from 1 kg infected C. quinoa leaf by extraction in 0.5 M phosphate buffer at pH 7.5, containing 0.05 M ethylene-daiminetetra-acetate (EDTA) and 0.2% mercaptoethanol, and clarificatin with chloroform, followed by two precipitations with polyethylene glycol and three cylces of differential centrifugation. Purified virus coefficent (Sd?_{20 w},) of 126 S and A₂₆₀/A₂₈₀ ratio of 1.80, bnut formed two isopycnic bands in CsC1 of buoyant density 1.481 and 1.492 g/cm³ with estimated nucleic acid contents of 40 and 41% respectively. AVB particles contained two proteins of mol.wt 26 000 (major component) and 20 000. AVB was not serologically related to any of 20 other morphologically similar viruses. Its properties suggest that it does not fall into any recognised group of viruses. the cryptogram of AVB is */*:*/40–41:S/S:S/*     

Some properties of cocksfoot mottle virus

Cocksfoot mottle virus (CFMV) was transmitted by manual inoculation of sap to cocksfoot (Dactylis glomerata L.), wheat, oats and barley, but not to nineteen other monocotyledonous and thirteen dicotyledonous plant species. The virus was also transmitted by cereal leaf beetles (Lema melanopa L.). Adult beetles infected plants more frequently than larvae, and remained infective for up to 2 weeks after they had fed on infected plants. Seed from infected cocksfoot and oat plants produced virus-free seedlings. The infectivity of sap was lost during 10 min. at 65° C., and 2 weeks at 20° C., but survived many months at — 15° C. Purified virus preparations, made by various methods, contained numerous nearly spherical particles, about 30 mμ in diameter. In electron micrographs some of the particles were penetrated by negative stain though most appeared intact. However, all the particles migrated together in a centrifugal (sedimentation coefficient = 118 S) or electrophoretic field. The ultraviolet absorption spectrum, and the phosphorus and nitrogen contents of the virus preparations, were typical of a nucleoprotein containing about 25 % nucleic acid. Serological tests failed to show any relationship between CFMV and eleven other viruses with particles of similar shape and size.     

Pepino mosaic virus, a new potexvirus from pepino (Solanum muricatum)

Pepino mosaic virus (PepMV), a previously undescribed virus, was found in fields of pepino (Solanum muricatum) in the Canete valley in coastal Peru. PepMV was transmitted by inoculation of sap to 32 species from three families out of 47 species from nine families tested. It caused a yellow mosaic in young leaves of pepino and either a mild mosaic or symptomless infection in 12 wild potato species, five potato cultivars and potato clone USDA 41956 but S. stoloniferum and potato cultivars Merpata and Revolucion reacted with severe systemic necrotic symptoms. The virus was transmitted by plant contact but not by Myzus persicae. It was best propagated and assayed in Nicotiana glutinosa. Sap from infected N. glutinosa was infective after dilution to 10^-1 but not 10^-6, after 10 min at 65°C but not 70°C and after 3 months at 20°C. PepMV had filamentous particles with a normal length of 508 nm; the ends of some seemed damaged. Ultra-thin sections of infected leaves of N. glutinosa revealed many inclusions containing arrays of virus-like particles some of which were banded or whorled; small aggregates of virus-like particles were also common. The virus was purified by extracting sap from infected leaves in a solution containing 0·065 M disodium tetraborate, 0·435 M boric acid, 0·2% ascorbic acid and 0·2% sodium sulphite at pH 7·8, adding silver nitrate solution to the extract, and precipitating the virus with polyethylene glycol followed by two cycles of differential centrifugation. Particles of PepMV normally yielded two proteins with molecular weights of 26 600 and 23 200, but virus obtained from infective sap aged overnight yielded only the smaller protein suggesting that it was a product of degradation of the larger one. The virus is serologically related to two potexviruses, narcissus mosaic and cactus X and its properties are typical of the potexvirus group.     

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).     

Transmission characteristics and some other properties of bean yellow vein-banding virus, and its association with pea enation

Bean yellow vein-banding virus (BYVBV) has been found occasionally in mixed infection with pea enation mosaic virus (PEMV) in spring-sown field beans (Vicia faba minor) in southern England. Glasshouse tests confirmed that, like PEMV, BYVBV is transmissible by manual inoculation and by aphids in the persistent manner. However, BYVBV can be transmitted by aphids only from plants that are also infected with a helper virus, usually PEMV. Thus after separation from PEMV by passage through Phaseolus vulgaris it was no longer aphid-transmissible. It became aphid-transmissible again only after re-mixing in plants with PEMV or with a substitute helper, bean leaf roll virus (BLRV). It was not transmitted by aphids that fed sequentially on plants singly infected with PEMV and BYVBV. Thus the interaction between BYVBV and PEMV (or BLRV) that enables BYVBV to be transmitted by aphids seems to occur only in doubly infected plants. However, it was not transmitted by aphids from plants doubly infected with BYVBV and broad bean wilt virus (BBWV). BYVBV and PEMV were transmitted more readily by Acyrthosiphon pisum than by Myzus persicae; neither virus was transmitted by Aphis fabae. Phenol extracts of BYVBV-infected leaves were more infective than phosphate buffer or bentonite-clarified extracts and were sometimes infective when diluted to 1/1000. The infectivity of BYVBV in phosphate buffer extracts of leaves singly infected with BYVBV, unlike that in extracts of leaves doubly infected with BYVBV and PEMV (or BLRV), was destroyed by treatment with organic solvents. BYVBV infected 11 of 28 plant species that were inoculated with phenol extracts; seven of the infected species were legumes. No transmission of BYVBV was detected through seed harvested from infected field bean plants. Isometric particles c. 30 nm in diameter were seen in extracts of plants doubly infected with BYVBV and PEMV but not in extracts of plants infected with BYVBV alone. Leaves of plants infected with BYVBV, alone or with PEMV, contained membrane-bound structures c. 50–90 nm in diameter associated with the tonoplast in cell vacuoles. These structures were not found in healthy leaves. BYVBV has several properties in common with other known aphid-borne viruses that are helper-dependent and transmitted in a persistent manner. Possibly, as suggested for some of them, aphid transmission of BYVBV depends on the coating of its nucleic acid with helper virus coat protein.     

Properties of cocksfoot streak and cocksfoot cryptic, two viruses infecting cocksfoot (Dactylis glomerata) in Scotland

A Scottish isolate of cocksfoot streak virus (CSV-S) was found to have flexuous filamentous particles which, in sap of infected cocksfoot plants, had a modal length of 712 nm. It was transmitted from infected to healthy cocksfoot plants in a non-persistent manner by Myzus persicae and by mechanical inoculation of infective sap extracts containing an anti-oxidant. Apart from cocksfoot, mechanical inoculation of infective sap succeeded in infecting only four of 22 plant species tested. The infectivity of sap extracts containing 0.2% thioglycerol was lost after heating for 10 min at 55^oC but not 50^oC, storage at room temperature for 48 but not 24 hours, and after diluting 10^-2to 10^-3. Highly purified preparations of CSV-S particles sedimented as a single component with a sedimentation coefficient of 139S and had a buoyant density in rubidium bromide of 1.31 g/cm³. Virus particles were composed of one protein and one ssRNA species with estimated M_r of 31 000 and 3.2 times 10⁶respectively. In ELISA, an antiserum prepared to CSV-S detected the virus in all aerial parts of infected cocksfoot plants and, when present in the ratio of 1 infected leaf: 1000 healthy leaves. Both CSV-S-infected and -uninfected cocksfoot also contained a previously undescribed virus with isometric particles c. 30 nm in diameter. This virus, named cocksfoot cryptic virus (CCV), was seed-borne in two cvs of cocksfoot tested and its particles contained two dsRNA species of estimated M_r of 1.14 times 10⁶and 1.27 times 10⁶. Despite the fact that particles of CSV-S were largely free from CCV particles following exclusion chromatography on agarose beads prior to immunisation, immunoelectron microscopy (IEM) showed that the antiserum prepared to CSV-S also contained some antibodies to CCV. Evidence from IEM suggested a possible distant serological relationship of CCV to ryegrass and beet (BCV 1 or BCV 2, or both) cryptoviruses, all members of sub-group A of crypto viruses.