Arabis mosaic and Prunus necrotic ringspot viruses in hop (Humulus lupulus L.)

Purified virus preparations made from nettlehead-diseased hop plants, or from Chenopodium quinoa, to which the virus was transmitted by inoculation of sap, contained polyhedral virus particles of 30 mμ diameter which were identified serologically as arabis mosaic virus (AMV). There were serological differences between AMV isolates from hop and from strawberry, and also differences in host range and in symptoms caused in C. quinoa and C. amaranticolor. AMV was always associated with nettlehead disease. The nematode Xiphinema diversicaudatum occurred in small numbers in most hop gardens, but was numerous where nettlehead disease was spreading rapidly. Preparations from nettlehead-affected hops also contained a second virus, serologically related to Prunus necrotic ringspot virus (NRSV), in mild and virulent forms which infected the same range of test plants but showed some serological differences. Mild isolates did not protect C. quinoa plants against infection by virulent isolates. Hop seedlings inoculated with virulent isolates of NRSV developed symptoms indistinguishable from those of split leaf blotch disease. Latent infection with NRSV was prevalent in symptomless hop plants. Nettlehead disease is apparently associated with dual infection of AMV and virulent isolates of NRSV. An unnamed virus with rod-shaped particles 650 mμ long was common in hop and was transmitted by inoculation of sap to herbaceous plants. Cucumber mosaic virus was obtained from a single plant of Humulus scandens Merr.     

A damaging outbreak of arabis mosaic nepovirus in blackcurrant, the occurrence of other nepoviruses in Ribes species, and the demonstration that alfalfa mosaic virus is the cause of interveinal white mosaic in blackcurrant

In a crop of blackcurrant (Ribes nigrum), cv. Baldwin in Eire, chlorotic mottling and ringspot symptoms in leaves on plants and severe crop loss was associated with infection with arabis mosaic nepovirus (ArMV) and the presence in the soil of its nematode vector, Xiphinema diversicaudatum. This is only the second report of ArMV damaging a crop of blackcurrant. Tomato black ring (TBRV) and raspberry ringspot nepoviruses were detected in single plants of redcurrant (R. rubrum) in England and flowering currant (R. sanguineum) in Scotland respectively; each of these infected plants showed foliar chlorotic line-pattern symptoms. This is the first record of TBRV in redcurrant. A single blackcurrant plant in New Zealand showing symptoms typical of those described for interveinal white mosaic disease, contained alfalfa mosaic virus (AMV). When AMV particles were purified and concentrated from herbaceous test plants and mechanically inoculated to young blackcurrant plants, several became infected with AMV and most infected plants developed systemic symptoms typical of the original disease. This provides the strongest evidence to date that AMV is the causal agent of interveinal white mosaic disease.     

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.     

A satellite-like nucleic acid of arabis mosaic virus associated with hop nettlehead disease

An isolate of arabis mosaic virus (AMV) from a hop plant with symptoms of nettlehead disease induced unusually severe symptoms when transmitted to Chenopodium quinoa. This isolate, called AMV-Ta, yielded particle preparations in which up to 80% of the nucleic acids consisted of a species of low molecular weight (SNA), estimated to be about 75 000 daltons by polyacrylamide gel (PAG) electrophoresis. An isolate free of detectable S-NA (AMV-To) was derived from AMV-Ta by inoculating plants with the two high molecular weight genomic RNA species of AMV (2–8 times 10⁶ and 1–3 times 10⁶ daltons; Murant, 1981) separated from S-NA by PAG electrophoresis. This isolate induced much milder symptoms in C. quinoa. Hop seedlings inoculated with AMV-Ta, either mechanically or by nematodes, developed characteristic nettlehead symptoms. Hop seedlings similarly inoculated with AMV-To remained free of nettlehead symptoms. Two species of S-NA associated with hop nettlehead isolates of AMV were detected at two sites in Kent, and two West Midlands sites. At both sites in Kent and at one of the West Midlands sites, the occurrence of the S-NA species was closely correlated with the incidence of nettlehead symptoms. At the other site in the West Midlands, the occurrence of nettlehead symptoms was too erratic to allow positive correlation of SNA with symptom development. Our results show that S-NA plays an active part in symptom production in experimentally inoculated plants of both hops and C. quinoa. In addition, the close correlation between the occurrence of AMV with additional nucleic acid species, and the incidence of nettlehead symptoms in commercially grown hops, suggests a role for S-NA in the aetiology of this disease.     

Studies on rose mosaic disease in field-grown roses produced in the United Kingdom

Arabis mosaic virus (AMV) and prunus necrotic ringspot virus (PNRSV), separately or together, caused in field-grown roses the range of symptoms recognised as rose mosaic disease. PNRSV infection alone generally induced chlorotic line patterns, ring-spots or mottles in the leaves at some time during the growing season; AMV plus PNRSV normally caused chlorotic vein-banding. However, during prolonged periods of high temperatures (c. 21 °C or more) vein banding occurred in some roses infected only with PNRSV. Isolates of PNRSV from rose had particles which were similar in shape, protein mol. wt, density and sedimentation coefficients to previously described isolates of PNRSV from cherry, plum and rose; all were cherry serotypes. In graft-inoculated roses, apple serotypes of PNRSV induced stunting and chlorosis, puckering and distortion of leaves, which closely resembled symptoms associated with rose mosaic in the USA and chlorotic mottle rose mosaic in New Zealand. To avoid possible confusion in using the name rose mosaic it is suggested that the virus(es) present in roses should be named.     

The isolation and identification of rhubarb viruses occurring in Britain

Virus-like symptoms were common in British crops of rhubarb. All plants tested of the three main varieties, ‘Timperley Early’, ‘Prince Albert’ and ‘Victoria’, were virus-infected. Turnip mosaic virus and a severe isolate of arabis mosaic virus (AMV) were obtained from ‘Timperley Early’; and ‘Prince Albert’ contained turnip mosaic virus, cherry leaf roll virus (CLRV), a mild isolate of AMV and, infrequently, cucumber mosaic virus (CMV). The main commercial variety ‘Victoria’ contained turnip mosaic virus, CLRV, a mild isolate of AMV and, infrequently, strawberry latent ringspot virus (SLRV). All the viruses were identified serologically. The rhubarb isolates did not differ markedly from other isolates of these viruses in herbaceous host reactions, properties in vitro or particle size and shape. A rhubarb isolate of CLRV was distinguished serologically from a cherry isolate of the virus. Turnip mosaic virus, CLRV and SLRV, were transmitted with difficulty, but AMV isolates were readily transmitted by mechanical inoculation. Turnip mosaic virus was also transmitted to rhubarb by Myzus persicae and Aphis fabae. CLRV was transmitted in 6–8% of the seed of infected ‘Prince Albert’ and ‘Victoria’ rhubarb and in 72% of the seed of infected Chenopodium amaranticolor. Mild isolates of AMV were also transmitted in 10–24% of the seed of infected ‘Prince Albert’ and ‘Victoria’ plants.     

Apple mosaic virus isolated from hop plants in Japan

A strain of apple mosaic virus was isolated from hop plants in Japan. The virus was purified from young hop plants and back-inoculated to virus-free hop plants obtained by meristem tip culture. Inoculated plants developed chlorotic spots, ringspots and a band pattern accompanied by necrosis in the inoculated and systemically infected leaves. Shoot tips of infected plants sometimes became necrotic and these symptoms resembled those of a ring- and band-pattern mosaiclike disease prevalent in hop gardens in Japan. Since apple mosaic virus was recovered from infected plants, it is likely that the virus was the causal agent of this disease. Agar gel double diffusion tests and ELISA showed the hop virus to be serologically closely related to apple mosaic virus (ApMV), and distantly related to prunus necrotic ringspot virus (PNRSV). The virus had a narrow host range, and infected only cucumber of 18 species of Cucurbitaceae, Chenopodiaceae, Leguminosae or Solanaceae inoculated. It produced chlorotic spots on the inoculated cotyledons of cucumber, but no systemic infection. By contrast, ApMV from apple and PNRSV from peach had wide host ranges and infected cucumber plants systemically.     

Epidemiology of three viruses infecting the rose in the United Kingdom

Studies on the epidemiology of arabis mosaic (AMV), prunus necrotic ringspot (PNRSV) and strawberry latent ringspot (SLRV) viruses were made in relation to commercial production of standard and bush roses. AMV or SLRV apparently induced either symptomless infection in rose cultivars and Rosa spp., or leaf symptoms ranging from small chlorotic flecks to severe chlorotic mosaic and, occasionally, plant death. Infection of R. canina ‘inermis’ or R. corymbifera by an isolate of SLRV from R. corymbifera also severely depressed flowering and hip formation. In addition, whereas this isolate could be graft-transmitted to all Rosa spp. tested, isolates from R. rugosa and R. multiflora failed to be graft-transmitted to R. canina ‘inermis’ or R. corymbifera. No difference was detected in graft-transmission tests of Rosa spp. with several isolates of AMV or PNRSV. In plantings of up to 7 yr none of the viruses was transmitted through pollen to healthy roses grown in nematode-free soil, and only SLRV was readily seed-transmitted, particularly in R. rugosa. Nevertheless, in soil containing viruliferous nematodes, AMV and/or SLRV were transmitted to c. 80% of healthy plants. AMV and particularly SLRV were each damaging to field-grown maiden rose bushes cv. Fragrant Cloud. SLRV delayed the onset of flowering, and reduced the number and size of blooms. Diseased bushes were less vigorous, and half or none of the AMV- or SLRV- infected bushes respectively, conformed to the British Standards Institution specifications for maiden bush roses. These results are discussed in relation to the commercial production of field-grown roses in the UK.     

Strains of Prunus necrotic ringspot virus in hop (Humulus lupulus L.)

Purified preparations of Prunus necrotic ringspot virus (NRSV) from hop plants formed two light-scattering zones when centrifuged in sucrose density gradients; the upper and lower zones contained particles 25 mμ and 31 mμ in diameter respectively whose sedimentation coefficients were 79 S and 107 S. NSRV isolates from hop were of two distinct serological types: ‘A’ strains, serologically very closely related to NRSV isolates from apple; and ‘C’ strains more nearly related to NRSV from cherry. The variety Fuggle is tolerant to hop mosaic (not related to NRSV) and different selections of apparently healthy female plants usually contained A strains; but C strains were usually isolated from nettlehead-diseased plants. Either A or C strains occurred in male plants grown with the hop-mosaic tolerant varieties. In mosaic-sensitive varieties (Goldings and Bramlings) apparently healthy female plants tested were usually infected with C strains; either A or C types occurred in mosaic-sensitive male plants. NRSV was not detected in the seventy-four hop seedlings obtained from virus-infected plants. Some varieties developed nettlehead when infected with NRSV (A) or (C) + the hop form of arabis mosaic virus, but not with NRSV (A) or (C) alone. Others developed nettlehead when infected with arabis mosaic virus + NRSV (C) but not with arabis mosaic + NRSV (A). A and C strains can multiply together in the same hop plant. There is evidence of partial antagonism, however, and the fluctuating behaviour of the nettlehead syndrome probably reflects changes in the relative concentration of the two serotypes.     

Health Status (Virus) of Native North American Humulus lupulus in the Natural Habitat

Ninety-one native North American Humulus lupulus plants from natural habitats in seven western and mid-western states of the U.S.A. were tested by ELISA serology for presence of two ilarviruses and three carlaviruses common to cultivated hops. All plants in natural habitats were free of detectable viruses. Propagations of 14 such plants from earlier collections had become infected, particularly with two carlaviruses (hop latent virus, American hop latent virus) after exposure for 22 years tobreeding nurseries. ELISA tests of some 284 hop plants primarily from breeding nurseries in Oregon indicated the following infection rates: Prunus necrotic ringspot virus, 85/284, 30%; apple mosaic virus, 88/234, 38%; hop mosaic virus, 59/158, 37 %; hoplatent virus, 104/158, 66 %; and American hop latent virus, 79/158, 50 %. Inoculum reservoirs of AHLV were sought among 53 principally perennial non-Humulus plant species surrounding AHLV-infected hop yards and nurseries. AHLV was neither indigenous to native North American H. lupulus nor detectable in these selected non-Humulus plant species. Breeding nurseries and commercial hop yards, thus, were the only detectable inoculum reservoir for AHLV.     

Purification and properties of arabis mosaic and tomato bushy stunt viruses isolated from lilac (Syringa vulgaris L.)

The paper gives more detailed characteristics of Arabis mosaic virus (AMV) and tomato bushy stunt virus (TBSV) isolated from lilac, the latter being identified in lilac (from plants suffering from yellow ring disease) for the first time. The isolate of TBSV from lilac, from which an antiserum with a titre of 1024 was prepared, is closely related to the artichoke strain. Information is given about two types of ringspot disease and about chlorotic ringspot of lilac. Whereas in the leaves of lilac suffering from ringspot disease (of ring mosaic type) the presence of AMV was demonstrated, the sap transmission from the leaves diseased with ringspot of linepattern (and wave-like mosaic) type failed; from the leaves affected by chlorotic ringspot a mixture of AMV and cherry leaf roll virus was identified. In addition, the polyetiological nature of “spring” mosaic and necrotic mosaic of lilac, in which bacteriumPseudomonas syringae van Hall, was found is dealt with. The TBSV was also identified in the isolate of necrotic mosaic.Additional index words: Lilac ringspot, chlorotic ringspot, yellow ring, “spring” mosaic, necrotic mosaic, cherry leaf roll virus,Pseudomonas syringae van Hall.     

A variant of the satellite RNA of groundnut rosette virus that induces brilliant yellow blotch mosaic symptoms in Nicotiana benthamiana

Some Malawian cultures of groundnut rosette virus (GRV) give rise to variants that, although still causing symptoms of the chlorotic type of rosette in groundnut, induce brilliant yellow blotch mosaic symptoms, instead of the usual veinal chlorosis and mild mottle, in Nicotiana benthamiana. One such isolate (YB) induced the formation in infected plants of a 0.9 kbp dsRNA having extensive sequence homology with molecules of similar size in other naturally occurring isolates of GRV. These dsRNA molecules were shown to be double-stranded forms of single-stranded satellite RNA molecules. Experiments in which the satellite was removed from and restored to isolate YB, or exchanged with those from other GRV isolates, showed that it carries the determinant for yellow blotch mosaic symptoms. Plants inoculated with the 0.9 kbp dsRNA (denatured or undenatured) developed yellow blotch mosaic even when the satellite-free GRV helper was not inoculated until 11 days later. The satellite RNA is therefore a very stable molecule. Prior infection of N. benthamiana with a GRV isolate containing a normal form of the satellite protected against expression of yellow blotch mosaic symptoms when the plants were later inoculated with isolate YB, whereas prior infection with satellite-free isolates did not. This provides a simple method of determining whether a GRV isolate has an associated satellite RNA. The YB satellite seems to be a newly recognised variant additional to those known to cause the chlorotic, green and other forms of groundnut rosette disease.     

Alfalfa mosaic virus isolates from lucerne in South Australia: biological variability and antigenic similarity

Alfalfa mosaic virus (AMV) was isolated from lucerne (Medicago sativa) plants with a variety of disease symptoms in eight of 13 sites in South Australia indicating that the virus is widespread in the state. The host ranges and symptomatology of the virus isolates varied considerably. Twelve selected local lesion isolates were shown to be distinct when mechanically inoculated to a range of plant species and cultivars. However, agar-gel diffusion and enzyme-linked immunoassay tests with polyclonal antisera prepared against glutaraldehyde-fixed virus preparations of the five most readily distinguishable AMV isolates, failed to reveal significant antigenic differences between the 12 virus isolates. This indicates that serological tests with polyclonal antisera can detect a wide range of AMV variants but would be unlikely to differentiate between strains. The wide host range and variability of AMV precluded the grouping of isolates into strains of the virus.     

Different variants of the satellite RNA of groundnut rosette virus are responsible for the chlorotic and green forms of groundnut rosette disease*

Groundnut plants with symptoms of rosette disease contain groundnut rosette virus (GRV), but GRV is transmitted by Aphis craccivora only from plants that also contain groundnut rosette assistor virus (GRAV). Two main forms of rosette disease are recognised, ‘chlorotic rosette’ and ‘green rosette’. GRV cultures invariably possess a satellite RNA and this is the major cause of rosette symptoms: satellite-free isolates derived from GRV cultures from Nigerian plants with chlorotic or green rosette, or from Malawian plants with chlorotic rosette, induced no symptoms, or only transient mild mottle or interveinal yellowing, in groundnut. When the satellite RNA species from GRV cultures from Nigerian green or Malawian chlorotic rosette were reintroduced into the three satellite-free isolates in homologous and heterologous combinations, the ability to induce rosette symptoms was restored and the type of rosette induced was that of the cultures from which the satellite RNA was derived. Thus different forms of the satellite are responsible for the different forms of rosette disease. Other forms of the satellite induce only mild chlorosis or mottle symptoms in groundnut. Individual plants may contain more than one form of the satellite, and variations in their relative predominance are suggested to account for the variable symptoms (ranging from overall yellowing to mosaic) seen in some plants graft-inoculated with chlorotic rosette.     

Verticillium Wilt of the Hop (Humulus Lupulus)

An account is given of the methods used to determine the relative pathogenicity of isolates of Verticillium albo-atrum from fluctuating and from progressive outbreaks of the wilt disease of hops. Isolates from fluctuating outbreaks were less pathogenic to young hop plants than those from progressive outbreaks, and it is suggested that this is the main cause of the differences in symptom incidence and intensity between the two types of outbreak in the field.     

Biological and Molecular Characterization of Alfalfa Mosaic Virus Infecting Trumpet Creeper (Campsis radicans) in Iran

Samples of trumpet creeper (Campsis radicans) leaves showing mottling and mosaic were collected from plants growing in a private garden in Tehran province, Iran, in 2012. Symptomatic leaf samples were tested for Alfalfa mosaic virus (AMV), Cucumber mosaic virus (CMV) and Peanut stunt virus (PSV) infection in enzyme‐linked immunosorbent assay (ELISA), using specific antibodies. None of the samples were positive for CMV and PSV; however, all reacted positively with that of AMV antiserum. In biological assay, systemic infection was found on Datura stramonium, Nicotiana tabacum cvs., White Burley, and Xanthi, 21 days postinoculation (DPI), while necrotic local lesions were obtained following inoculation of Phaseolus vulgaris and Vigna unguiculata within three to four DPI. Using a pair of primers specific for AMV, a DNA fragment of 880 bp was RT‐PCR‐amplified. Analysis of the sequences revealed the presence of 657 nucleotides of AMV complete coat protein (CP) gene (translating 218 amino acid residues). Phylogenetic analysis using neighbour‐joining (NJ) method clustered AMV isolates into two main types and the IRN‐Tru (GenBank Accession No. JX865593 ) isolate fell into type I. Pairwise nucleotide distances also confirmed two main types with the highest and lowest similarities for type I and II, respectively. The association of AMV with mosaic disease of C. radicans represents the first record from the world.     

Detection of Alfalfa mosaic virus (AMV) in pea field in Iran

During the spring and summer, in 2003-2004, pea viruses were identified in twenty pea fields of Tehran. Some leaf samples were collected randomly from pea fields of Tehran. Samples were tested by Double Antibody Sandwich Enzyme Linked Immunosorbent Assay (DAS-ELISA) technique using polyclonal antiserum of Alfalfa mosaic virus (AMV), AS-0001, DSMZ, Braunschweig, Germany). The samples were extracted in 0.1 M Phosphate buffer pH 7 to 7.5 and inoculated on Chenopodium amaranticolor, Chenopodium quina, Phaseolus valgaris, Vicia faba, Vignia unguiculata. Pea cultivars were infected by AMV, causing mild mosaic, translucent veins and a diffuse green-yellow of tender parts and spots may also was involved necrosis of tissue. Infected plants grow slowly and malformed pods produce fewer ovules. In Chenopodium amranticolor, C. quina chlorotic and necrotic flecks, and Vicia faba systemic mosaic had produced. Phaselous vulgaris and Viginia unguiculata are good assay hosts for strains that produce local lesions after 3-5 days in these plants. Back inoculated on Pisum sativum and Vicia faba and tested with DAS-ELISA that had been confirmed the results. This is the first report of AMV on pea from Iran.     

Konjac mosaic virus Naturally Infecting Three Aroid Plant Species in Andhra Pradesh,India

The genomes of three potyvirus isolates from, respectively, naturally infected Colocasia esculenta, Caladium spp. and Dieffenbachia spp. in Andhra Pradesh, India, were amplified by RT‐PCR using degenerate potyvirus primers. Sequence analysis of RT‐PCR amplicons (1599 nucleotides) showed maximum identity of 97% with the KoMV‐Zan isolate of Konjac mosaic virus (KoMV) from Taiwan (A/C AF332872). The three isolates had a maximum identity of 99.4%. The length of coat protein (CP) gene of three isolates was 846 nucleotides encoding 282 amino acids with a deduced size of 32.25 kDa. The CP gene of the isolates had, respectively, 78.1–95.7% and 88.2–96.4% identity at nucleotide and amino acid levels with KoMV isolates. The CP gene of the three isolates had 93.1–100% (nucleotide) and 98.2–100% (amino acid) identity. The 3′‐UTR of the three isolates showed maximum identity of 91.1–100% identity between and with other KoMV isolates. In the CP amino acid–based phylogenetic analyses, the isolates branched as a distinct cluster along with known KoMV isolates. The three potyvirus isolates associated with mosaic, chlorotic feathery mottling, chlorotic spots, leaf deformation and chlorotic ring spots on three aroids were identified as isolates of KoMV for the first time from Andhra Pradesh, India.     

Incidence and Control of Necrotic Leaf Mosaic Caused by Arabis Mosaic Virus in Lilium tigrinum splendens in the Netherlands

Necrotic mosaic on leaves and ring spots on bulb scales of Lilium tigrinum splendens, can be caused by arabis mosaic virus (AMV). Primarily infected bulbs can show spongy roots and large necrotic areas on creamy coloured bulb scales. Consecutive series of plants replanted for monthly periods in infested soil were mostly infected by AMV at a high rate (70%) throughout the year. Very low or undetectable numbers of Xiphinema diversicandatum, nematodes in soil dilution experiments infected lilies very efficiently (50–70 %). In general, soil disinfestation with dichloropropene, dazomet, methylbromide, and other disinfectants were variably fairly effective, particularly when yellow crocus among which couch was abundant, was previously grown for two years. The influx of AMV infected material into the soil was assumed to increase the number of AMV-carrying nematodes, and may be one cause of the failure of soil disinfestation. A survey of AMV infested soil in lily-growing regions in The Netherlands indicated its occurrence in a few fields only. Complex control measures applicable under growers' conditions, in addition to the variably effective soil disinfestation, are indicated.     

A yellow mosaic disease of horse chestnut (Aesculus spp.) caused by apple mosaic virus

A severe foliar yellow mosaic disease was observed in horse chestnut trees (Aesculus carnea and A. hippocastanum). Reactions in woody indicator plants grafted with diseased horse chestnut suggested the presence of an ilarvirus. Virus isolates obtained by mechanical inoculation of herbaceous test plants reacted with antisera to apple mosaic virus but not with antisera to its serotype prunus necrotic ringspot virus, or to prune dwarf virus. Yellow mosaic was induced in horse chestnut seedlings grafted with tissues from herbaceous hosts infected with horse chestnut isolates or with the European plum line pattern isolate of apple mosaic virus. Virus was detected by enzyme-linked immunosorbent assay (ELISA) in embryo and endosperm of immature seed from infected trees but not in mature seed, or progeny seedlings. Strawberry latent ringspot virus was detected in one of six A. hippocastanum trees with a leaf vein yellows disease.