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.     

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.     

Viruses Associated with a Mosaic Disease of Crotalaria juncea in Nigeria

Cowpea mosaic virus was one of the viruses isolated from Crotalaria juncea showing mosaic, distortion and puckering symptoms. The virus induced local necrotic lesions in Canavalia ensiformis, Cassia occidentalis, Nicotiana debneyi, N. occidentalis, N. repanda and N. sylvestris and some cultivars of Phaseolus vulgaris 4–6 days after inoculation. It induced local chlorotic spots, which later became necrotic, as well as systemic chlorotic spots, vein chlorosis, distortionand puckering in Chenopodium amaranticolor. Sap from systemically infected cowpea cv. ‘C20-55’was infective after dilution to 10^?5 but not 10^?6, after 10 min at 65°C but not 70°C, or after 4 days, but not 5 days, at a room temperature of 15–25°C. Infectious virus was recovered from fresh reproductive tissues of infected cowpea cvs ‘C20-55’and ‘Ife Brown’ plants but not after dehydration.     

The transmission of European wheat striate mosaic virus by Javesella pellucida (Fabr.) injected with extracts of plants and plant-hoppers

Virus-free individuals of the plant-hopper Javesella pellucida (Fabr.) infected plants with European wheat striate mosaic virus (EWSMV) after being injected at 5° C. with extracts of either plants or hoppers, but extracts of hoppers provided a better inoculum. Hoppers were unable to infect plants until at least 8 days at 20–25° C. after they were injected, and nymphs fed on infected plants similarly required 8 days before they gave infective extracts. Few hoppers survived more than a week after injection with untreated extracts of hoppers or with material sedimented from them by centrifuging the extracts at 8000g, but 60–70% survived injection with purer virus preparations. Injection of the virus seemed harmless, because as many hoppers survived CO₂ anaesthesis + injection, whether or not they later infected plants, as survived anaesthesis without injection. Attempts to determine the properties of the virus in vitro gave inconsistent results, but virus from hoppers was still infective after 10 min. at 30° C, 36 hr. at 5° C, precipitation at pH 4.0, storage for several months at -15° C, or at a dilution equivalent to 0.0014 g. hopper/ml. The best extraction medium contained 0.2 M-Na₂HPO₄+ ascorbic acid + 0.01 M-DIECA at pH 7.0–7.3. In sucrose density-gradients, EWSMV sedimented more slowly than tobacco mosaic virus. No specific particle with which infectivity could be correlated was seen by electron microscopy.     

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.     

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.     

Immunodiagnosis of plant viruses by a virobacterial agglutination test

A new virobacterial agglutination (VBA) test for the immunodiagnosis of plant viruses is described. The test is based on the agglutination of Staphylococcus aureus cells by virus particles after treatment of the cells with homologous antiserum. The agglutination occurs within 1–5 min. The sensitivity of the test is 0·1-0·4 μg virus/ml and is not affected by the shape of the virus particle. The use of affinity purified antibodies for sensitisation of S. aureus cells increases the sensitivity of the reaction 50-fold and enables the detection of tobacco mosaic and cucumber green mottle mosaic viruses at a concentration of 2 ng/ml. The VBA test allows the estimation of potato viruses X, S, M and Y in the eyes and sprouts of infected tubers and in the leaves of infected plants. The diagnosis of carnation mottle virus in carnation plants and of mushroom viruses in mushroom (Agaricus bisporus) fruit-bodies and mycelium are also described.     

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.     

Eggplant mosaic virus, and its relationship to Andean potato latent virus

Eggplant mosaic virus (EMV), obtained from Solanum melongena L. from Trinidad, is readily transmitted by inoculation of sap to several solanaceous and a few non-solanaceous plant species. Purified preparations of EMV contain isometric particles 30 nm in diameter, and with sedimentation co efficients of either 111 or 53 S. The particles have thirty-two major morphological subunits. EMV is closely serologically related to Andean potato latent virus and has a similar host range, but is more virulent. Also, whereas EMV accumulates fastest in Nicotiana clevelandii leaves at 20–24 °C, Andean potato latent virus accumulates fastest at 15 °C, and fails to attain a serologically detectable concentration at 24 °C. A few symptomatologically or serologically distinguishable strains of EMV were obtained. EMV has properties typical of viruses of the Andean potato latent subgroup of the turnip yellow mosaic group of viruses, and its present cryptogram is */*:*/*:S/S:S/Cl.     

Pathology and properties of tulip virus X, a new potexvirus

Tulip virus X (TVX), a previously undescribed mechanically transmissible virus, causes chlorotic and necrotic lesions in leaves and streaks of intensified pigmentation in tepals of tulip plants. The virus infected 22 of 42 other plant species in 10 of 14 families, but most host species were infected only erratically. TVX is best propagated in Chenopodium quinoa and assayed in C. amaranticolor. Spindleshaped inclusions were observed in epidermal cells of C. amaranticolor leaves. Leaf extracts from C. quinoa contained flexuous filamentous particles measuring c. 495 ×13 nm. The extracts were infective after dilution to 10^-9, after heating for 10 min at 60 °C but not at 65 °C, and after storage at c. 20 °C for 30 days or at -20 °C for 6 months. TVX particles were purified (500 μg/g C. quinoa leaf) from tissue extracts in 0.067 M phosphate buffer containing 10 mM EDTA at pH 7, by twice precipitating the virus with 8% polyethylene glycol in 0.2 M NaCl followed by differential centrifugation. The virus particles have a sedimentation coefficient (s_{20, w}) of 102 S. They contain a protein of mol. wt c. 22 500 and a nucleic acid that, when glyoxalated, migrates in agarose gel like single-stranded RNA of mol. wt 2.05 × 10⁶. TVX particles tend to aggregate, and evidence was obtained that a 118 S component which was consistently observed in purified preparations and in infective sap is an end-to-end dimer. A distant serological relationship was found between particles of TVX and those of viola mottle and hydrangea ringspot viruses, but no serological relationship was detected to nine other potexviruses. TVX is considered to be a distinct and definitive member of the potexvirus group.     

Crimson clover latent virus - a newly recognised seed-borne virus infecting crimson clover (Trigolium incarnatum)

Crimson clover latent virus (CCLV) was detected in five seed lots of crimson clover (Trifolium incarnatum) from Europe and in one from the United States of America. Ninety-seven per cent of all crimson clover plants examined were found to be infected but were without symptoms. Keeping crimson clover plants at 32–38°C for 34 days failed to free them from CCLV. The virus was not transmitted by Myzus persicae, but was transmitted by inoculation of sap to Chenopodium album, C. amaranticolor and C. quinoa. Twenty-four other plant species from seven families were not infected. CCLV was best propagated in C. quinoa in which it caused stunting and systemic chlorosis. Sap from infected C. quinoa was infective after dilution to 10^-2 but not 10^-3, after 10 min at 60°C but not 65°C, and after 20 days at 20°C. In neutral phosphotungstate, CCLV had isometric particles c. 26 nm in diameter with a hexagonal profile. About 20 to 80 A_1cm,260 units of purified virus were obtained from 1 kg of infected C. quinoa or C. amaranticolor leaves by extraction in 0.5 M phosphate buffer, pH 7.5, containing 0.01 M ethylene diamine tetra-acetate and 0.4% 2–mercaptoethanol and clarification with chloroform-butanol followed by two precipitations with polyethylene glycol (mol. wt 6000) and several cycles of differential centrifugation. Purified virus sedimented as three components with sedimentation coefficients (s°_{20, w}) of 52S, 101S and 122S. The 101S and 122S components had buoyant densities in CsCl of 1.438 and 1.495 g/cm³ respectively. From these values the nucleic acid content of the 101S and 122S components was estimated to be 32–35% and 40–41% respectively. The virus contained a single protein with an estimated mol. wt of 52 000 and two single-stranded RNA species of estimated mol. wt 1.6 × 10⁶ and 2.2 × 10⁶. CCLV was serologically unrelated to 31 other morphologically similar viruses. Although its vector is unknown, CCLV seems to have affinities with nepoviruses. The cryptogram of CCLV is R/1:2.2/40–41 + 1.6132–35:S/S:S/*.     

High temperature inactivation of cucumber and alfalfa mosaic viruses in Nicotiana rustica cultures

Cucumber mosaic (CMV) and alfalfa mosaic (AlfMV) viruses could not be detected in Nicotiana rustica tissues cultured at 32 °C for 16–18 days or at 40 °C for 5 days, but infectivity remained high in comparable tissue cultured at 22 °C. Incubation of infected cultures at 28–30 °C resulted in an initial reduction followed by a partial recovery in the infectivity of both viruses. The infectivity of CMV in tissues grown between 12 and 32 °C was highest in cultures grown at 12 °C. Although CMV infectivity was not detected in cultures after 16–18 days at 32 °C, virus was eliminated only after a further 30 days at 32 °C. When cultures were transferred from 32 to 22 °C after shorter treatment periods, infectivity rapidly increased to levels higher than those of infected tissues grown continuously at 22 °C. At 40 °C, CMV was eliminated from infected tissues after 9 days and AlfMV after 7 days. Cultures grown continuously at 40 °C deteriorated rapidly but, when grown under diurnal alternating periods of 8 h at 40 °C and 16 h at 22 °C, they remained viable and CMV was also inactivated.     

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.     

Tulip chlorotic blotch virus, a second potyvirus causing tulip flower break

Tulip chlorotic blotch virus (TCBV), an apparently undescribed potyvirus found in field grown tulips in Australia, causes symptoms in tulip leaves and flowers identical to those induced by tulip breaking virus (TBV). TCBV was transmitted mechanically to 14 of 34 species in four of 13 families. Nicotiana clevelandii is a suitable propagation host and Chenopodium amaranticolor a local-lesion assay host. TCBV was transmitted from tulip to tulip and TV. clevelandii by the aphid Myzus persicae. Unlike TBV it was not transmitted to Lilium formosanum either by M. persicae or by manual inoculation. Leaf extracts from TCBV-containing TV. clevelandii were infective after dilution to l0^-3 but not 10-⁴ and after heating for 10 min at 50°C but not 60°C; infectivity and particle recovery were adversely affected by freezing at -20°C. TCBV particles were purified (c. 1 mg/100g g N. clevelandii leaf) from tissue extracts in 0·3 M citrate buffer containing 10 mM EDTA and 0·2% (v/v) 2-mercaptoethanol at pH 7·4 by clarification with 8·5% (v/v) n-butanol followed by differential centrifugation and sucrose density gradient centrifugation. Purified particles measured c. 720 × 12 nm. Virus particle antigen was readily detected in leaf and tepal extracts of tulip by enzyme-linked immunosorbent assay. A distant serological relationship was found between particles of TCBV and those of bean yellow mosaic virus but no serological relationship was found to TBV or four other potyviruses.     

Some hosts, properties and possible affinities of a labile virus from Hypochoeris radicata (Compositae)

Hypochoeris mosaic virus (HMV) is common in Hypochoeris radicata (‘cat's ear’) in western Canada. It infected 10 of 53 mechanically inoculated species in five of twelve families, but was not transmitted by aphids or through seed or soil. Sap from infected Nicotiana clevelandii was sometimes infective after dilution to 10^-1 and occasionally 10², after 10 min at 45 but not 50°C, and after 1 but not 2 days at 20°C. Infectivity of crude nucleic acid extracts from infected leaves was rapidly abolished by RNase but not by DNase. Host sap contained very few rod-shaped particles or particle fragments mostly 21.0–22.5 nm in diameter, and up to 420 nm long but with predominant lengths of 120–140 and 240–260 nm. Many rods in purified virus preparations were less than 240 nm long, and the majority were c. 140 nm or shorter. The particles had a helical substructure with a pitch of 2.58 nm and contained a single type of protein of estimated mol. wt 24.5 × 10³. HMV showed no serological relationship to eight morphologically similar viruses (beet necrotic yellow vein, broad bean necrosis, barley stripe mosaic, peanut clump, potato mop-top, Nicotiana velutina mosaic, wheat soil-borne mosaic and defective strains of tobacco mosaic). It is probably a hitherto undescribed tobamovirus.     

Arracacha virus A, a newly recognised virus infecting arracacha (Arracacia xanthorrhiza; Umbelliferae) in the Peruvian Andes

Arracacha virus A (AVA), a previously undescribed virus, is common in arracacha (Arracacia xanthorrhiza; Umbelliferae) in the Huanuco region of the Peruvian Andes. AVA was not transmitted by Myzus persicae, but was transmitted by inoculation of sap to 38 species from 10 families out of 63 species from 12 families tested. AVA was best propagated and assayed in Chenopodium quinoa and Nicotiana clevelandii in which it caused severe diseases. Sap from infected C. quinoa was occasionally infective after dilution to 10^-4 but not 10^-5, after 10 min at 65 °C but not 70 °C, and after 15 days at 20 °C. In neutral phosphotungstate, AVA has isometric particles c. 26 nm in diameter with a hexagonal profile, some of which were either fully or partially penetrated by the negative stain. Up to 50–200 E₂₆₀^1cm units of purified virus was obtained from 1 kg of infected N. clevelandii leaf by extraction in 0.05 M phosphate buffer at pH 7.5 containing 0.05 M ethylene diaminetetra-acetate, and clarification with chloroform, followed by differential precipitation with ammonium sulphate and three cycles of differential centrifugation. Purified virus sedimented as three components with sedimentation coefficients (S_20w^°) of 50 S, 92 S and 125 S and E₂₆₀/E₂₈₀ ratios of 0.65, 1.50 and 1.85 respectively. At equilibrium in CsCl gradients, buoyant densities of the 50, 92 and 125 S components were 1.32, 1.45 and 1.52 g/cm³ respectively. From the sedimentation coefficients and buoyant densities, the nucleic acid contents of the 92 S and 125 S components were estimated at 30–35% and 43–44% respectively. Only the 125 S component seemed to be infective but its infectivity was greater when mixed with the 92 S component. All three components contained a single protein with a molecular weight of 53 000. AVA was not serologically related to any of 33 other morphologically similar viruses. Although the vector is unknown, its properties suggest that it is a member of the nepovirus group. The cryptogram of AVA is */*: */43–44 +*/30–35: S/S:S/*.     

Identification of a Strain of Peanut Chlorotic Streak Virus Causing Chlorotic Vein Banding Disease of Groundnut in India

A virus disease characterized by chlorotic vein banding, chlorotic line pattern along the margins or midrib of mature leaflets and chlorotic spots/rings was observed on commercial groundnut crops in Rayalaseema area of Andhra Pradesh with an incidence from 1% to nearly 60%. The virus was transmitted by mechanical inoculation in extracts prepared with 0.01 M potassium phosphate butter, pH 8.0 to 21 species from the Chenopodiaceae, Cruciferae, Leguminosae and Solanaceae, Chenopodium quinoa was found to be a good local lesion host. The virus was neither seed-transmitted through 1591 groundnut seeds nor aphid-transmitted by Aphis craccivora, Myzus persicae and Rhopalosiphum maidis either in non-persistent or semi-persistent manner. The virus remained infective in buffered tobacco leaf sap at a dilution of 10^?5; in a 10^?1 dilution of buffered sap the virus was infective for 2–3 days at 22–29°C or when heated to 65°C for 10 min but not to 70°C. Clarification treatments with organic solvents with 10% chloroform was least damaging. The virus was purified from Nicotiana rustica leaves. Purified virus contained isometric particles of 51 nm in diameter with an electron dense core of 22 nm and two major polypeptides of 76 kDa and 36 kDa. A polyclonal antiserum to this virus was produced. In agar gel double diffusion, enzyme-linked immunosorbent assay and in electro-blot immunoassay rests the virus was related to peanut chlorotic streak virus and not to cauliflower mosaic, figwort mosaic and soybean chlorotic mottle viruses.     

Purification and properties of sweet potato mild mottle, a white-fly borne virus from sweet potato(Ipomoea batatas) in East Africa

A virus obtained from sweet potatoes in Kenya, Uganda and Tanzania was transmitted by inoculation of sap and by whiteflies (Bemisia tabaci). It infected forty-five of 119 plant species in fourteen of thirty-six plant families. It was propagated in Nicotiana glutinosa and N. tabacum, in which diagnostic symptoms of vein clearing, leaf curling and distortion developed. Cheno-podium quinoa was a good local lesion host. Different seedling lines of sweet potato differed greatly in their susceptibility to infection and in symptoms produced; some developed leaf mottling and were stunted, some were symptomless, and some appeared immune. The virus was transmitted by dodder (Cuscuta campestris) but not by aphids, or through seed of Ipomoea nil or N. clevelandii. Sweet potato sap contained strong inhibitors of infection, and a low concentration of virus. Virus-free cuttings of sweet potato were obtained by thermotherapy (4–5 wk at 35 °C), or by meristem-tip culture. The virus remained infective in sap of N. tabacum after dilution to 10-³, or after 10 min at 55 °C (but not 60 °C), 3 but not 7 days at 18 °C, or 42 but not 49 days at 2 °C. Infectivity was abolished by sonication or u.v. irradiation, by 2% formaldehyde or 2% tri-sodium orthophosphate, and was greatly decreased by 20 % CHC1₃ or 20 % ether. Purified virus preparations were obtained from N. tabacum by clarifying phosphate buffer extracts with n-butanol, virus precipitation with polyethylene glycol, and differential centrifugation. The virus sedimented as one band in density gradients, and produced a single sedimenting boundary in analytical centrifugation (s°20, w = 1555)- It contained one polypeptide species of mol wt 37700, and preliminary digestion experiments suggested a single-stranded RNA. Antisera prepared against the virus reacted specifically in precipitin tube tests with titres of 1/16384, but no serological relationships could be found between the virus and fourteen viruses of the potato virus Y group. Electron micrographs showed straight, filamentous particles c. 950 nm long when mounted in MgCl_a, but 800–900 nra long in EDTA. The present cryptogram is: (R/i):*/*:E/E:S/Al. This virus is probably the same as Sheffield's virus B.     

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.     

Biological and biochemical properties of an isolate of cherry rasp leaf virus from red raspberry

A mechanically transmissible virus obtained from symptomless plants of a red raspberry selection imported into Scotland from Quebec, Canada was indistinguishable serologically from a cherry isolate of cherry rasp leaf virus (CRLV). The raspberry isolate, CRLV-R, was graft transmitted to several virus indicator species and cultivars of Rubus without inducing noticeable symptoms. In Chenopodium quinoa sap, CRLV-R lost infectivity after dilution to 10^-5 or heating for 10 min at 60°C but was infective after 16 days (the longest period tested) at 18°, 4° or - 15°C. The virus particles are isometric, c. 28 nm in diameter, and were purified with difficulty from infected C. murale and C. quinoa plants. The particles comprise two nucleoprotein components with sedimentation coefficients of 89 and 115 S and are prone to aggregate during purification. When centrifuged to equilibrium in CS₂SO₄ solution, purified virus preparations formed two major components with p= 1·28 and 1·36 g/cm³. Virus particles contained two RNA species which, when denatured in glyoxal and electrophoresed in agarose gels, had estimated mol. wt of 2·56 × 10⁶ (RNA-1) and 1·26 × 10⁶ (RNA–2). Infectivity of CRLV-R RNA was abolished by treatment with proteinase K, suggesting that the RNA is linked to protein necessary for infectivity; RNA molecules contained polyadenylate. In reticulocyte lysates, CRLV-R RNA stimulated the incorporation of ³H-leucine, mainly into two polypeptides of estimated mol. wt 200 000 and 102 000. When electrophoresed in polyacrylamide gels, protein obtained from CRLV-R particles purified by centrifugation to equilibrium in Cs₂SO₄ separated into three bands with estimated mol. wt 26 000 , 23 000 and 21 000.