Bean common mosaic virus and cucumber mosaic virus naturally infecting Aristolochia spp. plants in Brazil

In April 2022, Aristolochia plants with symptoms of mosaic were observed in a garden at Jardim Botânico Plantarum, Nova Odessa, São Paulo State, Brazil. Potyviridae-like particles were observed by transmission electron microscopy in leaf extracts. Total RNA extracted from symptomatic plants used in RT-PCR with universal and BCMV-specific primers detected the potyvirus bean common mosaic virus (BCMV). The cucumovirus cucumber mosaic virus (CMV) was identified only in Aristolochia littoralis plants that tested negative by RT-PCR for BCMV. Phylogenetic analysis grouped samples of Aristolochia in a different clade among samples of Phaseolus vulgaris. Phylogenetic analysis indicated that the CMV isolate from Aristolochia belongs to the CMV group IA. BCMV was mechanically transmitted to healthy plants of A. fimbriata, Chenopodium quinoa, P. vulgaris cv. Jalo and Macroptilium lathyroides. CMV was mechanically transmitted to plants of A. fimbriata and C. quinoa. The BCMV and CMV were aphid transmitted only by Aphis gossypii to Aristolochia plants. This is the first report of BCMV and CMV infecting Aristolochia plants in Brazil.     

Occurrence of papaya ringspot potyvirus and cucurbit viruses in Nepal

A survey of papaya and 10 cucurbitaceous vegetables (ashgourd, zucchini, watermelon, cucumber, pumpkin, bottlegourd, snakegourd, spongegourd, bittergourd and choyote) during 1989 and from 1992 to 1994 in more than 68 locations (both experimental plots and farmers' fields) covering 18 terai and inner-terai districts of Nepal, indicated that these crops were heavily affected with various virus-like symptoms. The most commonly observed symptoms were severe mosaic, leaf distortion, oily streaks or spots on papaya; leaf distortion, blisters and shoe stringing on zucchini; and mosaic or yellow mosaic, blisters, and leaf distortion on other cucurbits. Average incidence of plants with symptoms ranged from 75% to 100% on papaya; 85% to 100% on zucchini; 4% to 100% on cucumber; 4% to 100% on pumpkin and 10–100% on bottlegourd, choyote and watermelon. The virus isolated from papaya and zucchini was confirmed as papaya ringspot potyvirus — watermelon strain (PRSV-W). It was also detected in survey samples from ashgourd, bittergourd, snakegourd, spongegourd, zucchini, watermelon, bottlegourd and cucumber. Leaf extracts of some cucumber, choyote, pumpkin, zucchini and snakegourd samples reacted with cucumber mosaic cucumovirus (CMV) and zucchini yellow mosaic potyvirus (ZYMV) antisera. Leaf extracts of ashgourd, cucumber and pumpkin reacted with antibodies against cucurbit aphid-borne yellow luteovirus (CABW). No samples reacted with antiserum to watermelon mosaic-2 potyvirus (WMV-2) or squash mosaic potyvirus (SqMV). Some papaya and most cucurbits leaf samples cross-reacted with antibodies against Moroccan (Mor) and Algerian (Alg) isolates of WMV. The Nepalese PRSV isolate was related to but distinct from a PRSV-W type strain from France. This is the first report on the identity of ZYMV and CABW in Nepal.     

Application of accelerated storage test to lyophilized plant viruses

Summary The preservation of nine plant virus strains of tobamovirus and cucumovirus groups after freeze-drying in different lyophilic forms was examined. Quantitative studies on survival were performed. In tobacco mosaic virus (TMV) and cucumber mosaic virus (CMV), accelerated storage test at 70 – 100°C was applied for screening 20 protecting media. A perspective medium, 5% sorbitol, 3.6% dextran, for plant viruses lyophilization with high cryo- and xeroprotective effects was found.     

Cantaloupe line CZW-30 containing coat protein genes of cucumber mosaic virus,zucchini yellow mosaic virus,and watermelon mosaic virus-2 is resistant to these three viruses in the field

Cantaloupe line CZW-30 containing coat protein gene constructs of cucumber mosaic cucumovirus (CMV), zucchini yellow mosaic potyvirus (ZYMV), and watermelon mosaic virus 2 potyvirus (WMV-2) was investigated in the field over two consecutive years for resistance to infections by CMV, ZYMV, and/or WMV-2. Resistance was evaluated under high disease pressure achieved by mechanical inoculations and/or natural challenge inoculations by indigenous aphid vectors. Across five different trials, homozygous plants were highly resistant in that they never developed systemic symptoms as did the nontransformed plants but showed few symptomatic leaves confined close to the vine tips. Hemizygous plants exhibited a significant delay (2–3 weeks) in the onset of disease compared to control plants but had systemic symptoms 9–10 weeks after transplanting to the field. Importantly, ELISA data revealed that transgenic plants reduced the incidence of mixed infections. Only 8% of the homozygous and 33% of the hemizygous plants were infected by two or three viruses while 99% of the nontransformed plants were mixed infected. This performance is of epidemiological significance. In addition, control plants were severely stunted (44% reduction in shoot length) and had poor fruit yield (62% loss) compared to transgenic plants, and most of their fruits (60%) were unmarketable. Remarkably, hemizygous plants yielded 7.4 times more marketable fruits than control plants, thus suggesting a potential commercial performance. This is the first report on extensive field trials designed to assess the resistance to mixed infection by CMV, ZYMV, and WMV-2, and to evaluate the yield of commercial quality cantaloupes that are genetically engineered.     

Duplex-immunocapture-RT-PCR for detection and discrimination of two distinct potyviruses naturally infecting sugarcane (Saccharum spp. hybrid)

A sensitive duplex-immunocapture-RT-PCR (D-IC-RT-PCR) technique was developed for detection and discrimination of taxonomically distinct Sugarcane streak mosaic virus (SCSMV) and Sugarcane mosaic virus (SCMV) that naturally infect sugarcane. D-IC-RT-PCR was performed using polyclonal antisera for capture of virions. Oligo 5'-d(T)18(AGC)-3' as a common reverse primer for both viruses and virus specific forward primers, 5'-AAGTGGTTAAACGCCTGTGG-3' and 5'-ATGTC(GA)AAGAA(GA)ATGCGCTTGC-3' were used for amplifying approximately 1400 and approximately 900 bp fragments of SCSMV and SCMV genomes, respectively from their 3' termini. To assess the applicability of the developed technique, 67 mosaic affected sugarcane samples were initially screened by direct antigen coating-enzyme-linked immunosorbent assay (DAC-ELISA) followed by D-IC-RT-PCR. In DAC-ELISA, approximately 69% of tested samples were shown to be positive for presence of SCSMV, approximately 28% for SCMV and approximately 10% for both viruses. In D-IC-RT-PCR both viruses were detected up to the dilution of 10(-4). In D-IC-RT-PCR, approximately 76% of tested samples were found to be positive for SCSMV, approximately 37% for SCMV and approximately 16% for both viruses. The sequence analyses of D-IC-RT-PCR amplicons of 3 isolates of each virus revealed that the designed primers were virus-specific. The developed technique had potential application for sensitive parallel detection of two viruses in sugarcane.     

Alfalfa mosaic and cucumber mosaic virus infection in chickpea and lentil: incidence and seed transmission

Samples collected in 1994 and 1995 from commercial crops of chickpeas and lentils growing in the agricultural region of south-west Western Australia were tested for infection with alfalfa mosaic (AMV) and cucumber mosaic (CMV) viruses, and for members of the family Potyviridae using enzyme-linked immunosorbent assay (ELISA). In 1994 no virus was detected in the 21 chickpea crops tested but in 1995, out of 42 crops, AMV was found in two and CMV in seven. With lentils, AMV and/or CMV was found in three out of 14 crops in 1994 and 4 out of 13 in 1995, both viruses being detected in two crops in each year. Similar tests on samples from chickpea and lentil crops and plots growing at experimental sites, revealed more frequent infection with both viruses. No potyvirus infection was found in chickpeas or lentils in agricultural areas either in commercial crops or at experimental sites. However, bean yellow mosaic virus (BYMV) was detected along with AMV and CMV in irrigated plots of chickpeas and lentils at a site in Perth. When samples of seed from infected crops or plots of chickpeas and lentils were germinated and leaves or roots of seedlings tested for virus infection by ELISA, AMV and CMV were found to be seed-borne in both while BYMV was seed-borne in lentils. The rates of transmission found through seed of chickpea to seedlings were 0.1–1% with AMV and 0.1–2% with CMV. Seed transmission rates with lentil were 0.1–5% for AMV, 0.1–1% for CMV and 0.8% for BYMV. Individual seed samples of lentil and chickpea sometimes contained both AMV and CMV. With both species, infection with AMV and CMV was sometimes found in commercial seed stocks or seed stocks from multiplication crops of advanced selections nearing release as new cultivars. Seed-borne virus infection has important practical implications, as virus sources can be re-introduced every year to chickpea and lentil crops or plots through sowing infected seed stocks leading to spread of infection by aphid vectors, losses in grain yield and further contamination of seed stocks.     

Engineered resistance against plant virus diseases

The development of genetic engineering techniques has enabled the production of transgenic plants that are resistant to viral diseases. Expressing the coat protein (CP) gene of a virus in Iransgenic plants confers resistance against the virus from which the gene was isolated, and to other closely related strains and viruses. This approach has been demonstrated to be effective in conferring protection against viruses from different virus groups including alfalfa mosaic virus, cucumovirus. ilarvirus, potex-virus, potyvirus, tobamovirus and tobravirus. The data available indicate that several factors may affect the efficiency of the protection obtained including the level of the CP in the transgenic plants, the plant in which the CP gene is expressed and enviromental conditions. These and other aspects of coat protein mediated resistance are discussed.     

Occurrence and distribution of lettuce mosaic disease in Tehran province from Iran

Lettuce mosaic virus (LMV) Cucumber mosaic virus (CMV) and Tomato spotted wilt virus (TSWV) were identified in fields of Tehran province. In this study 452 leaf samples were collected from the fields throughout the Tehran province during 2002 and 2003. Distribution of Lettuce mosaic virus (LMV), Cucumber mosaic virus (CMV), Tomato spotted wilt virus (TSWV)and Arabis mosaic virus (ArMV) was determined with DAS-ELISA. Percentage of single Infection to LMV. CMV or TSWV was 20.58, 15.93 and 9.96% respectively. Also 15.28% of samples were co- infected with LMV+CMV, 8.19% with LMV+TSMV and 7.74% with CMV+TSWV. 4.65% of samples were Infected to all of these three viruses. LMV was found in 48.69%, CMV in 43.59% and TSWV in 30.54% of samples totally. Therefore LMV is major dominant agent of lettuce mosaic disease in Tehran province. This is the first report of occurrence of TSWV on lettuce in Iran and first report of CMV and LMV in Tehran province.     

四种广普性植物病毒高效mPCR检测方法的建立

本研究建立了能同时检测出烟草花叶病毒(TMV)、黄瓜花叶病毒(CMV)、马铃薯X病毒(PVX)和马铃薯Y病毒(PVY)的多重RT-PCR体系。TMV、CMV、PVX、PVY是四种广普性植物病毒,寄主范围广泛,并且常常发生复合侵染。本研究以上述四种病毒的CP基因部分序列设计引物,以反转录的cDNA为模板,建立多重RT-PCR反应体系,分别扩增出211～417bp的不同长度的基因片断,并通过序列测定来确认扩增序列的特异性。将反转录合成的cDNA进行浓度稀释,来对多重RT-PCR与单重RT-PCR的灵敏度进行比较,结果证明,多重RT-PCR体系能够同时快速检测这四种病毒,并且有很高的灵敏度。     

Diverse RNA viruses elicit the expression of common sets of genes in susceptible Arabidopsis thaliana plants

Systemic infections of plants by viruses require that viruses modify host cells in order to facilitate infections. These modifications include induction of host factors required for replication, propagation and movement, and suppression of host defense responses, which are likely to be associated with changes in host gene expression. Past studies of the effects of viral infection on gene expression in susceptible hosts have been limited to only a handful of genes. To gain broader insight into the responses elicited by viruses in susceptible hosts, high-density oligonucleotide probe microarray technology was used. Arabidopsis leaves were either mock inoculated or inoculated with cucumber mosaic cucumovirus, oil seed rape tobamovirus, turnip vein clearing tobamovirus, potato virus X potexvirus, or turnip mosaic potyvirus. Inoculated leaves were collected at 1, 2, 4, and 5 days after inoculation, total RNA was isolated, and samples were hybridized to Arabidopsis GeneChip microarrays (Affymetrix). Microarray hybridization revealed co-ordinated changes in gene expression in response to infection by diverse viruses. These changes include virus-general and virus-specific alterations in the expression of genes associated with distinct defense or stress responses. Analyses of the promoters of these genes further suggest that diverse RNA viruses elicit common responses in susceptible plant hosts through signaling pathways that have not been previously characterized.     

Template-Independent Repair of the 3′ End of Cucumber Mosaic Virus Satellite RNA Controlled by RNAs 1 and 2 of Helper Virus

RNA viruses which do not have a poly(A) tail or a tRNA-like structure for the protection of their vulnerable 3′ termini may have developed a different strategy to maintain their genome integrity. We provide evidence that deletions of up to 7 nucleotides from the 3′ terminus of cucumber mosaic cucumovirus (CMV) satellite RNA (satRNA) were repaired in planta in the presence of the helper virus (HV) CMV. Sequence comparison of 3′-end-repaired satRNA progenies, and of satRNA and HV RNA, suggested that the repair was not dependent on a viral template. The 3′ end of CMV satRNA lacking the last three cytosines was not repaired in planta in the presence of tomato aspermy cucumovirus (TAV), although TAV is an efficient helper for the replication of CMV satRNA. With use of pseudorecombinants constructed by the interchange of RNAs 1 and 2 of TAV and CMV, evidence was provided that the 3′-end repair was controlled by RNAs 1 and 2 of CMV, which encode subunits of the viral RNA replicase. These results, and the observation of short repeated sequences close to the 3′ terminus of repaired molecules, suggest that the HV replicase maintains the integrity of the satRNA genome, playing a role analogous to that of cellular telomerases.     

Occurrence, distribution and relative incidence of mosaic viruses infecting field--grown squash in Tehran province, Iran

Squash (Cucurbita pepo) belongs to Cucurbitaceae family. Every year Cucurbitaceae are planted world wide. They are one of the most important economic crops. Cucurbitaceae are threatened by viruses. Many viruses damage the plants of this family. Since nine viruses have been reported on squash from Iran. In this survey, during 2002--2003, to determine the distribution of Cucumber mosaic virus (CMV), Zucchini yellow mosaic virus (ZYMV) and Watermelon mosaic virus (WMV), 466 samples were collected from squash field in Tehran province. Infected plants showing symptoms such as: mosaic, yellowing, deformation, shoestring of leaves and fruit deformation and yield reduction. Distribution of CMV, ZYMV and WMV were determined by DAS-ELISA. Thepercentage of ZYMV, WMV and CMV were 35.6, 26.1 and 25.1% respectively. Triple infection (CMV+ZYMV+WMV) were found in 6.4% of samples. ZYMV were found the most frequently the viruses. This is the first report of WMV on squash in Tehran province.     

A new chrysanthemum potyvirus: molecular evidence

Abstract

A number of viruses are known to infect chrysanthemum plants, however in the present study a previously unknown potyvirus was detected using techniques such as ELISA, RT-PCR and hybridization. The ELISA-positive samples were amplified using a potyvirus group-specific primer which gave an amplification of ～850 bp. The amplified product was cloned and sequenced, and shows 72 – 73% homology with known potyviruses that infect chrysanthemums such as Potato virus Y potyvirus, Soyabean mosaic virus and Turnip mosaic potyvirus when compared to the sequence available in the database. However, present potyvirus isolates show 93% homology with Chilli veinal mottle virus and Pepper vein banding virus. The results were further confirmed by Northern hybridization. This is the first report of a potyvirus similar to Chilli veinal mottle virus, and Pepper vein banding virus infecting chrysanthemums.     

侵染天南星科植物病毒的分子鉴定及其生态学研究

通过病毒粒子部分提纯和形态学观察,发现侵染我国南方天南星科植物的病毒主要有线状和球状两种形态．经病毒基因组序列分析确定线状病毒为芋花叶病毒(DsMV);经血清学反应和序列分析确定球状病毒为黄瓜花叶病毒(CMV)．CMV CP基因序列同源性分析的结果表明,侵染天南星科的CMV是相对独立的种内变异类型,归属于亚组L同时,CMV存在对天南星科植物的适应性变异．对采自我国海南、湖南、浙江、上海等地的126个天南星科植物样品进行RNA核酸斑点杂交检测,获得病毒检测结果。海南省样品DsMV的检出率为73．3％,CMV的检出率为46．7％;湖南省样品DsMV的检出率为100％,CMV的检出率为38.5％;浙江省样品DsMV的检出率为93．0％,CMV的检出率为7．0％;上海市样品DsMV的检出率为100％,尚没有检测到CMV,首次证实了自然条件下CMV作为天南星科植物主要病毒的存在,在我国南方地区,该病毒对天南星科植物的自然侵染受到气候、季节和寄主等生态因子的影响。DsMV则在天南星科植物上普遍存在。     

Viruses detected in Ullucus tuberosus (Basellaceae) from Peru and Bolivia

Ullucus tuberosus (Basellaceae) plants from 12 locations in the Andean highlands of Peru and Bolivia contained complexes of either three or four viruses. Specimens from six sites in Peru contained a potexvirus, a tobamovirus, a potyvirus and a comovirus, but those from another location lacked the potexvirus. All samples from five sites in Bolivia lacked the tobamovirus. The potexvirus (PMV/U) is a strain of papaya mosaic virus differing slightly from the type strain (PMV/T) in inducing milder symptoms in some common hosts and failing to infect a few other species. It symptomlessly infected U. tuberosus, and infected 15 of 29 species from seven of nine other families. PMV/U showed a close serological relationship to PMV/T and to boussingaultia mosaic virus and a distant relationship to commelina virus X, but it is apparently unrelated to any of ten other potexviruses. The tobamovirus (TMV/U) induced symptomless or inconspicuous infection in U. tuberosus, and infected 21 of 30 species from six of eight other families. It showed a very distant serological relationship to some strains of ribgrass mosaic, tobacco mosaic and tomato mosaic viruses, but failed to react with antisera to cucumber green mottle mosaic, frangipani mosaic, odontoglossum ringspot and sunn-hemp mosaic viruses. The potyvirus, tentatively designated ullucus mosaic virus (UMV), alone in U. tuberosus induced leaf symptoms indistinguishable from the chlorotic mottling and distortion found in naturally infected plants. UMV infected 12 of 20 species from four other families, and was transmitted in the non-persistent manner by Myzus persicae. It showed a distant serological relationship to only two (bidens mottle and alstroemeria mosaic) of 25 members or possible members of the potyvirus group tested. Some hosts and properties of the comovirus are described in an accompanying paper. None of the four viruses infected potato (Solanum tuberosum) and, with the possible exception of UMV, they differed from viruses reported previously to infect three other vegetatively propagated Andean crops (Oxalis tuberosa, Arracacia xanthorrhiza and Tropaeolum tuberosum).     

马铃薯Y病毒HC-Pro中心区域在病毒协生作用中的主导地位

利用PCR方法获得了马铃薯病毒中国株系（PVY－C）HC－Pro基因的5个缺失突变体,构建了相应的植物表达载体。通过土壤农杆菌(Agrobacterium tumefaciens)介导法转化了烟草品种K326(Nicotina tabacum cv.k326)。PCR和Southern blot分析证明了HC－Pro基因及其缺失突变体已整合到烟草基因组中,Western blot表明它们在转基因烟草中得到了表达。侵染性试验发现HC－Pro中心区域介导转基因烟草中PVC－C和黄瓜花叶病毒（CMV）、PVY－C和马铃薯X病毒（PVX）之间的协生作用,从而明确了PVY－C HC－Pro中心区域为病毒协生作用的功能区域。     

Serological diagnosis and host range studies of important viral diseases of a few cucurbitaceous crops in Maharashtra,India

Around 39 well characterised viruses affect cucurbits crops in developing countries and their viral diversity may be the consequence for genetic and ecological diversity of their hosts. Indeed, cucurbits are grown in variety of climatic, environmental and agricultural conditions, and this may provide more or less favourable conditions for the specific viruses or their hosts. The presence of various viral diseases caused by different viruses in Maharashtra was studied from the infected samples collected from cucurbits and melons during the survey conducted in 2009–2010 in different locations. The virus isolates collected from various cucurbitaceous crops were established and their host ranges were studied by sap transmission. The study revealed Cucumber Mosaic Virus (CMV), Zucchini yellow mosaic virus (ZYMV), Watermelon mosaic virus (WMV) and Cucumber green mottle mosaic virus infections predominately found in Nashik region, and Watermelon bud necrosis virus (WBNV), CMV, ZYMV, WMV and Watermelon silver mottle virus (WSMoV) infections in Aurangabad and Paithan regions. In Sangamner region, the crop was mostly affected by WBNV, ZYMV and WSMoV, and CMV was found only in Sillod region. The protocols for performing sap transmission tests in assay hosts were standardised for ZYMV, CMV and WBNV. Using direct antigen-coating enzyme-linked immunosorbent assay, of all the plant parts, young leaves were found to have high concentration of virus and suitable for virus detection in screening programmes. CMV and ZYMV was found to have high concentration of virus and suitable for virus detection in screening programmes.