Weed plants as sources of cucumber mosaic virus

Severe yellowing and stunting was widespread in lettuce crops in Britain in 1968. Cucumber mosaic virus was consistently obtained from affected plants and from weeds which were prevalent in lettuce fields. Infection was most frequent in Stellaria media but also occurred, more or less commonly, in Senecio vulgaris, Urtica urens, Tripleurospermum maritimum ssp. inodorum, Capsella bursa-pastoris, Lamium purpureum and Sonchus oleraceus. Most infected weeds were symptomless. Infected weeds were still common in January-April 1969 and are considered to be a major overwintering source of the virus for aphid transmission to lettuce.     

Relative incidence,spatial distribution and genetic diversity of cucurbit viruses in eastern Spain

Viral diseases that could cause important economic losses often affect cucurbits, but only limited information on the incidence and spatial distribution of specific viruses is currently available. During the 2005 and 2006 growing seasons, systematic surveys were carried out in open field melon (Cucumis melo), squash and pumpkin (Cucurbita pepo), watermelon (Citrullus lanatus) and cucumber (Cucumis sativus) crops of the Spanish Community of Valencia (eastern Spain), where several counties have a long standing tradition of cucurbit cultivation and production. Surveyed fields were chosen with no previous information as to their sanitation status, and samples were taken from plants that showed virus‐like symptoms. Samples were analysed using molecular hybridisation to detect Beet pseudo‐yellows virus (BPYV), Cucurbit aphid‐borne yellows virus (CABYV), Cucumber mosaic virus (CMV), Cucumber vein yellowing virus (CVYV), Cucurbit yellow stunting disorder virus (CYSDV), Melon necrotic spot virus (MNSV), Papaya ring spot virus (PRSV), Watermelon mosaic virus (WMV) and Zucchini yellow mosaic virus (ZYMV). We collected 1767 samples from 122 independent field plots; out of these, approximately 94% of the samples were infected by at least one of these viruses. Percentages for the more frequently detected viruses were 35.8%, 27.0%, 16.5% and 7.2% for CABYV, WMV, PRSV and ZYMV, respectively, and significant deviations were found on the frequency distributions based on either the area or the host sampled. The number of multiple infections was high (average 36%), particularly for squash (more than 57%), with the most frequent combination being WMV + PRSV (12%) followed by WMV + CABYV (10%). Sequencing of WMV complementary DNA suggested that ‘emerging’ isolates have replaced the ‘classic’ ones, as described in southern regions of France, leading us to believe that cucurbit cultivation could be severely affected by these new, emerging isolates.     

Characterisation of pumpkin yellow vein mosaic virus from India

Yellow vein mosaic disease symptoms occur frequently in pumpkin in India. Diseased plants show vein yellowing, which sometimes coalesces to form chlorotic patches. Infected plants are stunted and flowers drop prematurely, greatly reducing yields. Diseased plants are infected by a begomovirus, designated pumpkin yellow vein mosaic virus (PYVMV), which is transmitted readily and in a persistent manner by the whitefly, Bemisia tabaci. Transmission of PYVMV requires minimum acquisition and inoculation access periods of 30 min and 10 min, respectively. The minimum latent period in the insect is 6 h and the virus persists in the vector for at least 8 days. PYVMV has a narrow host range consisting of a small number of cucurbit species and some tobacco cultivars. It was detected serologically in diseased plants and in viruliferous B. tabaci using polyclonal antibodies in a double‐antibody sandwich enzyme‐linked immunosorbent assay. Reactions with monoclonal antibodies in a triple‐antibody sandwich ELISA showed that PYVMV has an epitope profile distinct from those of other begomoviruses from the Indian sub‐continent. Polymerase chain reaction amplified fragments from the putative viral coat and movement protein genes. Based on comparative phylogeny of complete coat protein gene sequences, PYVMV was most similar to the bipartite Tomato leaf curl New Delhi virus from India and appears to be a new strain of this virus.     

Purification and Characterization of Indian Cassava Mosaic Virus

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

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

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

Detection of new viruses in alfalfa,weeds and cultivated plants growing adjacent to alfalfa fields in Saudi Arabia

A total of 1368 symptomatic plant samples showing different virus-like symptoms such as mottling, chlorosis, mosaic, yellow mosaic, vein clearing and stunting were collected from alfalfa, weed and cultivated plant species growing in vicinity of alfalfa fields in five principal regions of alfalfa production in Saudi Arabia. DAS-ELISA test indicated occurrence of 11 different viruses in these samples, 10 of which were detected for the first time in Saudi Arabia. Eighty percent of the alfalfa samples and 97.5% of the weed and cultivated plants samples were found to be infected with one or more of these viruses. Nine weed plant species were found to harbor these viruses namely, Sonchus oleraceus, Chenopodium spp., Hibiscus spp., Cichorium intybus, Convolvulus arvensis, Malva parviflora, Rubus fruticosus, Hippuris vulgaris, and Flaveria trinervia. These viruses were also detected in seven cultivated crop plants growing adjacent to the alfalfa fields including Vigna unguiculata, Solanum tuberosum, Solanum melongena, Phaseolus vulgaris, Cucurbita maxima, Capsicum annuum, and Vicia faba. The newly reported viruses together with their respective percent of detection in alfalfa, and in both weeds and cultivated crop plant species together were as follows: Bean leaf roll virus (BLRV) {12.5 and 4.5%}, Lucerne transient streak virus (LTSV) {2.9 and 3.5%}, Bean yellow mosaic virus (BYMV) {1.4 and 4.5%}, Bean common mosaic virus (BCMV) {1.2 and 4.5%}, Red clover vein mosaic virus (RCVMV) {1.2 and 4%}, White clover mosaic virus (WCIMV) {1.0 and 5%}, Cucumber mosaic virus (CMV) {0.8 and 3%}, Pea streak virus (PeSV) {0.4 and 4.5%} and Tobacco streak virus (TSV) {0.3 and 2.5%}. Alfalfa mosaic virus (AMV), the previously reported virus in alfalfa, had the highest percentage of detection in alfalfa accounting for 58.4% and 62.8% in the weeds and cultivated plants. Peanut stunt virus (PSV) was also detected for the first time in Saudi Arabia with a 66.7% of infection in 90 alfalfa samples collected from the surveyed regions during the last visit that tested negative to all the previously detected viruses.     

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

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

Glitoria yellow vein virus, a tymovirus from Kenya

Clitoria yellow vein virus (CYW) was found in Clitoria ternatea and Abrus precatorius in coastal districts of Kenya, but was not detected in food legume crops. When transmitted by inoculation of sap, CYW infected many species in the Papilionaceae, commonly causing yellowing of secondary and smaller leaf veins. All the economically important food legumes grown in the area of occurrence were very susceptible, so that CYW is potentially very important. The virus also infected okra (Hibiscus esculentus) and species in the Solanaceae, but none of many species of Cucurbitaceae. CYW is serologically closely related to cocoa yellow mosaic and kennedya yellow mottle viruses, and more distantly to okra mosaic and desmodium yellow mottle viruses. Other properties of CYW^ typical of the tymoviruses include particle morphology (particle diameter c. 28 nm; two components) with sedimentation coefficients of 50S (top) and 109S (bottom); molecular weight of protein sub-units c. 20000; thermal inactivation point c. 72 ^oC; and longevity in vitro c. 3 wk.     

Recognition and differentiation of seven whitefly-transmitted geminiviruses from India, and their relationships to African cassava mosaic and Thailand mung bean yellow mosaic viruses

Particles resembling those of geminiviruses were found by immunosorbent electron microscopy in extracts of plants infected in India with bhendi yellow vein mosaic, croton yellow vein mosaic, dolichos yellow mosaic, horsegram yellow mosaic, Indian cassava mosaic and tomato leaf curl viruses. All these viruses were transmitted by Bemisia tabaci whiteflies, all reacted with at least one out of ten monoclonal antibodies to African cassava mosaic virus (ACMV), and all reacted with a probe for ACMV DNA-1, but scarcely or not at all with a full-length probe for ACMV DNA-2. Most of the viruses were distinguished by their host ranges when transmitted by whiteflies, and the rest could be distinguished by their pattern of reactions with the panel of monoclonal antibodies. Horsegram yellow mosaic virus was distinguished from Thailand mung bean yellow mosaic virus by its lack of sap transmissibility, ability to infect Arachis hypogaea, failure to react strongly with the probe for ACMV DNA-2 and its pattern of reactions with the monoclonal antibodies. Structures resembling a ‘string of pearls’, but not geminate particles, were found in leaf extracts containing malvastrum yellow vein mosaic virus. Such extracts reacted with two of the monoclonal antibodies, suggesting that this whitefly-transmitted virus too is a geminivirus. All seven viruses from India can therefore be considered whitefly-transmitted geminiviruses.     

Partial characterisation of a new virus in brusca from the Venezuelan lowlands

Flexuous thread‐like virus particles c. 650–700 nm in length were isolated from brusca (Senna pallida) plants showing stunting, mosaic, vein yellowing and leaf malformation. The virus was mechanically transmitted to healthy Senna pallida, Cassia obovata and Cassia emarginata L. plant species. Virus particles sedimented in sucrose density gradients as one component, with a bouyant density of 1.2 g cm^?3 in caesium chloride equilibrium gradients. Virions contained a molecule of ssRNA with an apparent size of 6.4 kb. The dsRNA pattern showed one main band of about 12 kb, and two subgenomic dsRNA of c. 10 and c. 5.4 kb. Analyses of purified virus preparations by sodium dodecyl sulfate‐polyacrylamide gel electrophoresis (SDS‐PAGE) resolved two coat protein subunits, with mol. wt of c. 28 000 and 26 000 daltons. In Western blotting the virus coat proteins reacted with an homologous polyclonal antiserum and with an antiserum to Lettuce infectious yellow virus. Electron microscopic observations of cells from infected plants showed the accumulation of cytoplasmic vesiculate inclusion bodies and crystalline aggregates of virus particles within phloem tissue. Some of the physicochemical and ultrastructural properties of this virus resemble those of a Closterovirus; however, differences show it to be sufficiently distinct from any previously reported viruses. We proposed the name of Senna chlorotic stunt (SeCSV) for this virus.     

Yellow Vein Mosaic Disease in Okra (<i>Abelmoschus esculentus</i> L.): An Overview on Causal Agent,Vector and Management

Okra (Abelmoschus esculentus L.) belongs to the Malvaceae family and is one of the most essential and popular vegetables globally. It is rich in proteins, carbohydrates, and vitamins. Abiotic and biotic factors threaten okra productivity. Okra yellow vein mosaic disease (OYVMD) is the most destructive disease of okra. The causal agent, [(i.e., Okra yellow vein mosaic virus (OYVMV)] of this disease belongs to the family Geminiviridae and genus Begomovirus. OYVMV is a monopartite with additional ssDNA molecule. This virus has two components DNA-A for protein coding and DNA-B for symptoms induction. Whitefly transmits OYVMV in persistent manner. Characteristic symptoms of OYVMV infected okra plants are chlorosis, dwarfing, and yellowing of veins and fruits. High temperatures with moderate rainfall enhance the development of OYVMV disease and the whitefly population. However, high humidity with low temperature and rainfall has no significant role in developing the OYVMD and whitefly population. Moreover, the virus also affects the secondary metabolites in the infected okra plants. The virus can be managed through various strategies including the application of plant defense activators, the development of resistant varieties and by controlling its vector via pesticides and plant extracts. Various plant defense activators such as monopotassium phosphate (KH₂PO), salicylic acid, benzoic acid, and citric acid enhance resistance in okra against OYMVD. In addition, the resistance to OYMVD can also be achieved by successfully incorporating high yielding but resistant cultivars of acceptable quality. In this review, we have discussed history, economic impact, symptomology, disease development under a natural environment, genetics and management of OYVMV.     

Development of broad virus resistance in non‐transgenic cucumber using CRISPR/Cas9 technology

Genome editing in plants has been boosted tremendously by the development of CRISPR/Cas9 (Clustered Regularly Interspaced Short Palindromic Repeats) technology. This powerful tool allows substantial improvement in plant traits in addition to those provided by classical breeding. Here, we demonstrate the development of virus resistance in cucumber (Cucumis sativus L.) using Cas9/subgenomic RNA (sgRNA) technology to disrupt the function of the recessive eIF4E (eukaryotic translation initiation factor 4E) gene. Cas9/sgRNA constructs were targeted to the N′ and C′ termini of the eIF4E gene. Small deletions and single nucleotide polymorphisms (SNPs) were observed in the eIF4E gene targeted sites of transformed T1 generation cucumber plants, but not in putative off‐target sites. Non‐transgenic heterozygous eif4e mutant plants were selected for the production of non‐transgenic homozygous T3 generation plants. Homozygous T3 progeny following Cas9/sgRNA that had been targeted to both eif4e sites exhibited immunity to Cucumber vein yellowing virus (Ipomovirus) infection and resistance to the potyviruses Zucchini yellow mosaic virus and Papaya ring spot mosaic virus‐W. In contrast, heterozygous mutant and non‐mutant plants were highly susceptible to these viruses. For the first time, virus resistance has been developed in cucumber, non‐transgenically, not visibly affecting plant development and without long‐term backcrossing, via a new technology that can be expected to be applicable to a wide range of crop plants.     

Detection of begomovirus associated with okra leaf curl disease

Leaf curl and yellow vein mosaic viral disease is the major constraint on okra (Abelmoschus esculentus L.) production in India. Amplified fragment sequence of DNA-β showed highest similarity of 91.7% with Bhendi yellow vein mosaic virus-Tamil Nadu (AJ308425, NC_003405) and lowest similarity of 48.5% with OKLCV (NC_004093), whereas coat protein specific amplified sequence showed highest homology with isolate of Madurai, Haryana, Ludhiana and lowest homology of 92% with Mesta yellow vein mosaic Bahraich virus (MYVMBV) (EU360303). The results obtained in the present study confirm that both the viral diseases of okra reported in southern India are caused by a begomovirus associated with DNA-β in which the plants show leaf curl symptoms and never develops yellow vein mosaic and those plants which show yellow vein mosaic, never develops leaf curl symptoms even in the same rows and field. The okra leaf curl is an emerging virus disease in India.     

Short Communication: Ageratum,Croton and Malvastrum harbour geminiviruses: evidence through PCR amplification

Ageratum conyzoides, Croton bonpladianum and Malvastrum coromandelianum are common weeds found around agricultural fields. In several cases these were found to exhibit vein yellowing and yellow mosaic symptoms. Using degenerate primers specific for whitefly-transmitted geminiviruses (WTGs), and total DNA isolated from such infected plants (exhibiting the above symptoms) as a template, 1.2kbp fragments were amplified and were shown to have homology to DNA-A of Indian tomato leaf curl virus (ITLCV) by Southern hybridization. In control experiments the same primers failed to amplify any DNA fragments from the total DNA isolated from healthy plants (no symptoms as above). These results show that Ageratum, Croton and Malvastrum harbour geminivirus(es).     

Virus diseases of garden lupin in Great Britain

Two viruses occur widely in lupins in Britain. Alfalfa mosaic virus (AMV), of which two strains were isolated, was found mainly in named Russell varieties. Lupin mottle virus (LMV), a previously undescribed strain of the bean yellow mosaic virus (BYMV) common pea mosaic virus (CPMV) complex, was found more commonly in seedling lupins. Cucumber mosaic virus (CMV) was isolated once. The AMV strains were differentiated by their reaction in Phaseolus vulgaris; they were serologically closely related. Both AMV and LMV were aphid transmitted but not transmitted in lupin seed. LMV was distantly serologically related to both BYMV and CPMV. It cross-protected against BYMV but not against CPMV and it differed from both these viruses in some host reactions. The CMV isolate from lupins was similar to type CMV. It was transmitted both mechanically and by aphid, easily from cucumber to cucumber, but with difficulty from cucumber to lupin.     

Serological detection and antigenic variation of two whitefly-transmitted geminiviruses: tobacco leaf curl and croton yellow vein mosaic viruses

A panel of 25 monoclonal antibodies (MAbs) raised against particles of two heterologous whitefly-transmitted geminiviruses (begomoviruses) was used in triple antibody-sandwich ELISA (TAS-ELISA) to determine the detectability and epitope profiles of 26 Indian isolates of tobacco leaf curl virus (TLCV) and 13 of croton yellow vein mosaic virus (CYVMV). Stock cultures of the two viruses had indistinguishable epitope profiles although they differ in symptomatology and particle stability. Their epitope profiles also strongly resembled those of Indian isolates of bhendi (okra) yellow vein mosaic and Indian cassava mosaic (ICMV) viruses. TLCV isolates from Andhra Pradesh, Gujarat and Karnataka States differed slightly in epitope profile: they reacted with at least eight out of 10 MAbs raised to ICMV but only one to four out of 15 MAbs raised to African cassava mosaic virus (ACMV). Virus isolates serologically indistinguishable from TLCV were detected in symptom-bearing weeds (Acanthospermum hispidum, Ageratum conyzoides, Euphorbia geniculata, Parthenium hysterophorus) found in leaf curl-affected tobacco fields and shown previously to be experimental hosts of TLCV. Indian TLCV isolates had small, consistent differences in epitope profile from Pakistani isolates but large differences from isolates from Burkina Faso, Malawi or Uganda. Isolates from the three African countries reacted with four or five of the ACMV MAbs but only one or two of the ICMV MAbs, and there were small but consistent inter-country differences. CYVMV isolates from three Indian States showed less epitope variation than did Indian isolates of TLCV. TAS-ELISA with MAb SCR 18 was a more sensitive test for detecting Indian TLCV isolates than was double antibody-sandwich ELISA with polyclonal antibodies.     

黄瓜资源对黄瓜绿斑驳病毒广东分离物的抗性水平鉴定

【背景】黄瓜绿斑驳花叶病毒(Cucumber green mottle mosaic virus,CGMMV)是严重威胁葫芦科作物生产的毁灭性病原之一,该病毒已入侵我国十多个省份,危害西瓜、黄瓜等作物并造成严重的经济损失。早在2009年广东即发现CGMMV为害西瓜和黄瓜,但黄瓜等葫芦科作物对其抗性情况尚不清楚。【方法】采用人工机械摩擦接种方法,测定了14份黄瓜种质资源对CGMMV广东分离物的抗性水平。【结果】从广东葫芦病样中分离获得CGMMV,该病毒分离物MP基因序列与国内报道的各分离物同源率均在99%以上;14份黄瓜种质资源对该病毒分离物均表现为感病。【结论与意义】广东主要黄瓜资源对CGMMV均表现为感病,这为我省防控该病毒病提供了科学依据,也为黄瓜抗病育种提供了指导。     

Purification and Identification of a Rhabdovirus from Thunbergia alata

A subgroup 2 rhabdovirus was isolated in south-east Queensland from black-eyed Susan (Thunbergia alata) with symptoms of vein yellowing, vein clearing and leaf distortion. Bacilliform particles accumulated in the perinuclear space of infected plants and measured 69 ± 7 × 161 ± 8 nm in unfixed preparations. The virus was not transmitted mechanically. Purified preparations of the Thunbergia alata rhabdovirus (TaRV) contained four major proteins with molecular weights of 80 kD, 48 kD, 40 kD and 35 kD, similar to those of datura yellow vein virus (DYW), a newly described rhabdovirus from Australia. The 80 kD protein was identified as the viral glycoprotein. In immunoblots, the two largest proteins of TaRV reacted strongly with antiserum to DYW, but were serologically distinct from sonchus yellow net, cereal chlorotic mottle, potato yellow dwarf and lettuce necrotic yellows viruses. TaRV is considered to be a strain of DYW.