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Crisostomos I. Dovas Efstathios Hatziloukas Raphael Salomon Erhard Barg Yoel Shiboleth Nikolaos I. Katis 《European journal of plant pathology / European Foundation for Plant Pathology》2001,107(7):677-684
A survey identified viruses infecting garlic, leek and onion crops and wild Allium species in Greece. Virus identification was based on ELISA, immunoelectron microscopy, and occasionally on RT-PCR. Samples of cultivated Allium species were collected from five districts, whereas samples of twenty-seven wild Allium species were also collected from all over Greece. Onion yellow dwarf
virus (OYDV) and Leek yellow stripe virus (LYSV) were identified in 98.5% and 83.7% of all samples, respectively, and were found in all regions. Allexiviruses were also detected in all regions and their incidence ranged from 62.5% to 70.5% (depending on region and type of allexivirus). Garlic common latent virus (GCLV) was detected in samples from Arcadia (97.6%) and Evia (18.0%) and in one field in Larissa (23.0%). Shallot latent virus (SLV) was found only in two areas (Evros and Theva) and in fields planted with imported propagative material, from Iran and China. The incidence of virus-like symptoms in leek crops ranged from 10.0% to 90.0% in different regions and fields and all symptomatic plants were found to be infected by LYSV. Onion yellow dwarf virus was only found in seven symptomatic onion samples from southern Greece. Allium ampeloprasum spp. ampeloprasum and Allium flavum, were the only wild Allium species found to be infected with LYSV. Finally Turnip mosaic virus (TuMV) was found in A. sphaerocephalon, A. guttatum, A. subhirsutum, and A. neapolitanum. 相似文献
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本研究为明确吉林和黑龙江省毛葱病毒病发生率,从两省5个地区共采集255份毛葱样品。根据毛葱4种主要病毒基因组序列设计特异性引物,对胡葱黄条病毒Shallot yellow stripe virus(SYSV)和青葱X病毒Shallot virus X (SVX)、洋葱黄矮病毒Onion yellow dwarf virus (OYDV)和葱潜隐病毒Shallot latent virus (SLV)进行双重RT-PCR检测。结果表明,229份样品检出病毒,带毒率为89.8%,SLV的检出率最高,达87.06%,OYDV次之,为36.86%,SYSV检出率偏低,为0.78%;同时存在病毒复合侵染,其中双病毒复合侵染为SLV和OYDV,检出率为33.3%;三病毒复合侵染为SYSV、OYDV和SLV,检出率为0.78%,未发现4种病毒复合侵染。本研究为吉林和黑龙江种植区毛葱病毒病防治提供了参考依据。 相似文献
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P. Van Dijk 《European journal of plant pathology / European Foundation for Plant Pathology》1993,99(5-6):233-257
From 12 cultivated and mostly vegetatively propagatedAllium species and varieties tested for carlavirus infections, 94 virus isolates were obtained which varied greatly on indicator hosts.Chenopodium amaranticolor, C. quinoa, Celosia argentea var.plumosa Geisha,Nicotiana hesperis accession 67A andN. occidentalis accession P1 proved valuable for detection, isolation and propagation of part of the isolates. The latter three species are new experimental hosts for carlaviruses ofAllium species. Other isolates could only be transmitted toAllium species such as crow garlic (A. vineale) leek (A. ampeloprasum var.porrum) and onion (A. cepa var.cepa). The isolates were grouped into three viruses by differential hosts and host reactions and their reaction with four antisera.Shallot latent virus (SLV) was found in ever-ready onion (A. cepa var.perutile), grey shallot (unidentifiedAllium species), multiplier onion (A. cepa var.aggregatum), pearl onion (A. ampeloprasum var.sectivum), rakkyo (A. chinense), shallot (A. cepa var.ascalonicum), and Welsh onion (A. fistulosum). Virus isolates from garlic and Asian shallot, fully reacting with antiserum to SLV but differing in host reactions from the SLV type-isolate, are now described as garlic strain (SLV-G) and Asian shallot strain of the virus, respectively. The garlic latent virus from garlic described in Japan is now considered identical with SLV-G.A carlavirus almost universal in garlic, and also found in great-headed garlic (A. ampeloprasum var.holmense), in an unidentifiedAllium species, and occasionally in leek, did not react with the antisera to SLV and the Japanese garlic latent virus, and is now described as the new garlic common latent virus (GCLV). It appeared identical to a virus erroneously identified in Germany as garlic latent virus.The new Sint-Jan's-onion latent virus (SjoLV) from Utrechtse Sint-Jan's onion (unidentifiedAllium species) from the Netherlands and similar crops originating from other countries, did not induce reactions in test plants and could only be detected by electron microscope decoration tests. It reacted equally wellwith the antisera to SLV and GCLV. It was also present together with SLV in ever-ready onion, pearl onion, rakkyo, shallot, and Welsh onion. Garlic latent virus reported in Japan from hosts other than garlic should be regarded as SLV, SjoLV, or a mixture of these viruses.The carlaviruses were not detected in wild plants of ramsons (A. ursinum), and of the predominantly vegetatively propagated crow garlic (A. vineale), field garlic (A. oleraceum), and sand leek (A. scorodoprasum), collected in the Netherlands.Severe reactions in the indicator hosts incidentally revealed soil-borne viruses in shallot (the nepovirusesArabis mosaic virus (ArMV) and tomato black ring virus) and crow garlic (ArMV and the tobravirus tobacco rattle virus). Tobacco necrosis virus (necrovirus) was detected in roots of shallot. 相似文献
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Martin Verbeek Paul van Dijk Peter M. A. van Well 《European journal of plant pathology / European Foundation for Plant Pathology》1995,101(3):231-239
Mechanical inoculation tests and ELISA with sap from garlic plants used for sanitation by meristem-tip culture revealed four viruses, viz. garlic common latent virus (GCLV) (carlavirus), the garlic strains of leek yellow stripe virus (LYSV-G), onion yellow dwarf virus (OYDV-G) (aphid-borne potyviruses), and onion mite-borne latent virus (OMbLV-G) (taxonomically unassigned virus). The same tests performed on explants grownin vitro showed elimination efficiencies of 100% for LYSV-G, 92% for OYDV-G, 62% for GCLV, and less then 54% for OMbLV-G.Meristem tips excised from garlic cloves and bulbils, 0.15–1.0 mm in size, were tested for regeneration and efficiency of virus elimination after transfer to Murashige and Skoog medium. Successful regeneration into plantlets was obtained with 71% of the meristems from cloves and 72% of those from bulbils, but virus elimination was easiest from cloves: 38% of all explants from cloves and 25% of those from bulbils were virus-free. The efficiency of elimination increased with increasing weight of the cloves, irrespective of the virus. Small tip size seemed to favour virus elimination, but sizes smaller than 0.4 mm led to increasing failure of regeneration.Micropropagation was most successful when cytokinins were omitted from the medium and the garlic shoot was split. Multiplication factors of 3–6 were obtained. 相似文献
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P. van Dijk 《European journal of plant pathology / European Foundation for Plant Pathology》1993,99(2):1-48
Nearly 5700 plants of 14 cultivated and 8 wildAllium species and varieties from the Netherlands and other parts of the world, were tested for infection with aphid-borne potyviruses by ELISA, electron microscope decoration tests and/or inoculation onto test plants. This resulted in the detection of two known viruses, viz. leek yellow stripe virus (LYSV) and onion yellow dwarf virus (OYDV), and the discovery and characterization of two new viruses, viz. shallot yellow stripe virus (SYSV) and Welsh onion yellow stripe virus (WoYSV), and of six strains of these viruses. ‘Garlic mosaic’, ‘barlic yellow streak’, ‘onion mosaic’, ‘shallot mosaic’, ‘shallot X’, and ‘shallot yellows’ viruses, incompletely described in the literature, are now reidentified as well-known viruses or as strains or mixtures of such viruses. ‘Garlic yellow stripe virus’ is also a complex containing a potyvirus possibly differing from the viruses found in this survey. The symptoms of the potyviruses studied varied widely and ranged from mild to severe chlorotic to yellow striping of leaves, and they are of little diagnostic importance.LYSV was found in vegetatively propagated pearl onion (A. ampeloprasum var.sectivum) from Europe and Asia. It has decreased in leek crops (A. ampeloprasum var.porrum) in the Netherlands since the 1970, apparently due to resistance in new cultivars. OYDV was common in onion (A. cepa var.cepa) from the former USSR and North Africa, and in European cultivars of shallot (A. cepa var.ascalonicum), with the exception of the highly resistant ‘Santé’, but was not detected during this survey in Asian shallot. European samples of ever-ready onion (A. cepa var.perutile), multiplier onion (A. cepa var.aggregatum) and tree onion (A. cepa var.viviparum) contained OYDV. It was also found in sand leek (A. scorodoprasum) from european gene collections. A strain of OYDV from onion and shallot in Morocco and Spain was virulent on onion and shallot cultivars resistant to common OYDV, as reported early for a similar isolate in the USA.Asian shallot appeared generally infected with the new SYSV, similar to OYDV in host range and symptoms but serologically distinct. It was not detected in onion and shallot from Europe or North Africa. A virulent strain of this virus caused striping in sap-inoculated garlic (A. sativum) and Formosan lily (Lilium formosanum). The new WoYSV, infecting Welsh onion in Indonesia and Japan, was earlier described in Japan as OYDV from rakkyo and Welsh onion. It appeared serologically closely related to SYSV and distantly to OYDV, but differed in its host range.Host-specific strains of LYSV and OYDV were detected in garlic, wild garlic (A. longicuspis), an unidentifiedAllium species (suffix-G), and great-headed garlic (A. ampeloprasum var.holmense) (suffix-GhG)., LYSV-G and OYDV-G infected on average 45% and 73%, respectively, of the garlic samples of worldwide origin. Symptoms of isolates of both strains varied in severity, implying the necessity of serological tests for disease diagnosis and health certification. LYSV-GhG was the cause of yellow striping in 93% of the great-headed garlic plants tested, mainly from the Mediterranean area. One sample was also infected with OYDV-GhG.Many samples from vegetatively propagated crops grown from non-certified planting stock contained a few plants free of potyviruses, implying the possibility to obtain healthy (and possibly resistant) selections of such cultivars avoiding meristem-tip culture. Cross-protection of garlic sets by a mild potyvirus isolate seems to be an alternative to the use of vulnerable virus-free sets.Generally, viruses and virus strains could not be transmitted to anyAllium species other than their natural host, except to the highly susceptible crow garlic (A. vineale). This species, and other predominantly vegetatively propagating wildAllium spp. (field garlic,A. oleraceum; ramsons,A. ursinum; sand leek), were found not to be reservoirs of viruses that might infectAllium crops in the netherlands. Streaking in vegetatively propagated wild leeks (A. ampeloprasum and closely related species) originating from the Mediterranean area and Asia was due to an undescribed miteborne virus. The survey confirmed that spread of potyviruses inAllium crops in the Netherlands is from planting sets, and from a neighbouring crop only if of the same species. 相似文献
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van der Vlugt RA Steffens P Cuperus C Barg E Lesemann DE Bos L Vetten HJ 《Phytopathology》1999,89(2):148-155
ABSTRACT An antiserum to shallot yellow stripe virus (SYSV) was raised and used in combination with a range of other antisera to potyviruses of Allium spp. in electron microscopic decoration experiments. The serological results corroborated an earlier finding that the type isolates of SYSV and Welsh onion yellow stripe virus (WoYSV) are closely related to each other and only distantly related to onion yellow dwarf (OYDV) and leek yellow stripe (LYSV) viruses, the two other major potyviruses infecting Allium spp. Moreover, the decoration results indicated that Japanese potyviruses named OYDV and Wakegi yellow dwarf virus are isolates of SYSV. Sequence analysis of the 3'-terminal regions of the SYSV and WoYSV ge-nomes revealed coat protein (CP) amino acid and 3'-nontranslated region (3'-NTR) nucleotide sequence identities of 95 and 89%, respectively. The CP amino acid and 3'-NTR nucleotide sequences of these viruses differed from those of OYDV and LYSV by >25 and >67%, respectively. The serological and molecular studies showed that SYSV and WoYSV are different strains of a potyvirus distinct from OYDV and LYSV. For priority reasons, we propose that these strains together with the Wakegi-type isolates of OYDV described in Japan be referred to as SYSV and that SYSV isolates from Allium spp. other than shallot be designated as the Welsh onion strain of SYSV (SYSV-Wo). 相似文献
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L. Bos N. Huijberts H. Huttinga D. Z. Maat 《European journal of plant pathology / European Foundation for Plant Pathology》1978,84(5):185-204
Since 1970 yellow stripe disease of leek (Allium porrum) has developed epidemically in the south-eastern part of the Netherlands coincident with increasing year-around cultivation of the crop. Many autumn and winter crops now become totally infected. Apparently similar attacks, first reported in Germany in 1937, are increasingly attracting attention in various European countries. This paper describes the leek yellow stripe virus (LYSV) as a new potyvirus related to onion yellow dwarf virus (OYDV), which was so far incompletely described. LYSV is hardly infectious to onion (A. cepa) and shallot (A. ascalonicum) and OYDV behaves similarly on leek. The leek virus further differs from OYDV in not being infectious toA. fistulosum and in causing distinct local lesions onChenopodium amaranticolor andC. quinoa. The two viruses closely resemble each other in external symptoms in their respective hosts, in persistence of infectivity in expressed sap, and in particle morphology and length (LYSV 820 nm; OYDV 833 nm). Intracytoplasmic inclusion bodies slightly differ. Further biophysical characters of the two viruses, such as sedimentation coefficient (OYDV 143 S), buoyant density in CsCl (LYSV 1.326; OYDV 1.306, or 1.258 in Cs2SO4), and molecular mass of coat protein subunit (LYSV 34000; OYDV 30000 dalton), are characteristic of the potyvirus group, but do not assist in judging their relationships. Serologically they are only distantly related if at all. The leek virus is not seed-borne. It is aphid-transmitted in the non-persistent manner and its main epidemic build-up is during late summer and autumn. The sole sources of infection are nearby leek crops. Awaiting the development of resistant leek cultivars, it is advised to avoid sowing leek seed beds and planting spring crops near overwintering leek, and to remove infected plants showing up during summer. 相似文献
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在吉林省7个主要甘薯种植区共采集85份甘薯叶片样品,利用小RNA深度测序技术对混合样品进行检测,经RT-PCR和测序验证,鉴定出样品中存在10种病毒,包括6种RNA病毒和4种DNA病毒。分别是马铃薯Y病毒科马铃薯Y病毒属的甘薯羽状斑驳病毒Sweet potato feathery mottle virus (SPFMV)、甘薯潜隐病毒Sweet potato latent virus (SPLV)、甘薯G病毒Sweet potato virus G (SPVG)、甘薯C病毒Sweet potato virus C (SPVC)、甘薯2号病毒Sweet potato virus 2 (SPV2);长线形病毒科毛形病毒属的甘薯褪绿矮化病毒Sweet potato chlorotic stunt virus (SPCSV);双生病毒科菜豆金色花叶病毒属的甘薯曲叶病毒Sweet potato leaf curl virus(SPLCV);玉米线条病毒属的甘薯无症状1号病毒Sweet potato symptomless virus 1 (SPSMV1);花椰菜花叶病毒科杆状DNA病毒属的甘薯杆状DNA病毒B Sweet potato badnavirus B (SPBV-B)和甘薯隐症病毒Sweet potato pakakuy virus (SPPV)。 相似文献
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P. van Dijk M. Verbeek I. Bos 《European journal of plant pathology / European Foundation for Plant Pathology》1991,97(6):381-399
While testing several samples of onion and of vegetatively propagated garlic, sand leek and shallot from a number of countries,
virus isolates with unusually flexuous particles were obtained by mite (Aceria tulipae) or sap transmissions. No aphid-borne poty-or carlavirus was transmitted by mites, and mite-borne virus isolates could not
be transmitted by aphids. The mite-borne isolates did not react with antisera to aphid-borne potyviruses ofAllium spp. or with the Agdia potyvirus group monoclonal. In contrast to the mite-borne onion and garlic mosaic viruses reported
in the literature, our mite-borne isolates induced no visible or only very mild symptoms inAllium spp., except isolates from shallot ‘Santé’ which caused diffuse striping. Heavily mite-infested test plants or plant samples
showed streaking and malformation due to mite feeding (tangle-top).
The mite-borne virus isolates could be classified with test plants and a discriminating antiserum into three groups, representing
two viruses and a strain of one of them. They are tentatively named onion mite-borne latent virus (OMbLV), garlic strain of
this virus (OMbLV-G), and shallot mite-borne latent virus (SMbLV). Mite transmission, length of virus particles (ca. 700 to
800 nm), and the presence of granular inclusion bodies in infected tissue indicate that the viruses belong to the mite-borne
genusRymovirus of the familyPotyviridae. OMbLV from shallot and onion, and OMbLV-G from garlic and sand leek, can be assayed onChenopodium murale but differ in their natural hosts. They are very common. SMbLV, to whichC. murale does not react, was isolated from shallot originating from Asia and Russia. 相似文献
12.
ABSTRACT The complete nucleotide sequence of wheat streak mosaic virus (WSMV) has been determined based on complementary DNA clones derived from the 9,384-nucleotide (nt) RNA of the virus. The genome of WSMV has a 130-nt 5' leader and 149-nt 3'-untranslated region and is polyadenylated at the 3' end. WSMV RNA encodes a single polyprotein of 3,035 amino acid residues and has a deduced genome organization typical for a member of the family Potyviridae (5'-P1/HC-Pro/P3/6K1/CI/6K2/VPg-NIa/NIb/CP-3'). Because WSMV shares with ryegrass mosaic virus (RGMV) the biological property of transmission by eriophyid mites, WSMV has been assigned to the genus Rymovirus, of which RGMV is the type species. Phylogenetic analyses were conducted with complete polyprotein or NIb protein sequences of 11 members of the family Potyviridae, including viruses of monocots or dicots and viruses transmitted by aphids, whiteflies, and mites. WSMV and the monocot-infecting, mite-transmitted brome streak mosaic virus (BrSMV) are sister taxa and share a most recent common ancestor with the whitefly-transmitted sweet potato mild mottle virus, the type species of the proposed genus "Ipomovirus." In contrast, RGMV shares a most recent common ancestor with aphid-transmitted species of the genus Potyvirus. These results indicate that WSMV and BrSMV should be classified within a new genus of the family Potyviridae and should not be considered species of the genus Rymovirus. 相似文献
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Kil Eui-Joon Ho Phuong Thi Fadhila Chairina Lal Aamir Vo Thuy Thi Bich Kim Mikyeong Lee Sukchan 《植物病害和植物保护杂志》2021,128(4):1091-1099
Journal of Plant Diseases and Protection - Plum pox virus (PPV) is a plant virus (genus Potyvirus, family Potyviridae) infecting stone fruit trees. Since the first report from Bulgaria in 1917, PPV... 相似文献
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Inoculation of a range of Allium species and two non-alliaceous species with isolates of Cladosporiumallii-cepae and C. allii , obtained from onion and leek, respectively, demonstrated that the two pathogens had distinct host ranges. Conidia of C. allii-cepae, applied either dry or in aqueous suspension, infected A. altaicum, A. fistulosum (Japanese bunching onion), A. cepa (bulb onion), A. cepa var. ascalonicum (shallot), A. galanthum, A. pskemense and A. vavilovii . Dry conidia of C. allii applied at a high concentration caused atypical necrosis on A. altaicum, A. fistulosum, A. cepa var. ascalonicum, A. galanthum, A. pskemense, A. vavilovii, A. sativum (garlic), A. ampeloprasum and A. porrum (leek). Only A. ampeloprasum and A. porrum became typically infected following inoculation with conidia applied dry at low concentration or in aqueous suspension. Isolates of C. allii from leek failed to infect A. vineale, the type host. The length of conidia of a single isolate of C. allii-cepae varied significantly on different Allium spp. 相似文献
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M. Cecilia Perotto Eva E. Cafrune Vilma C. Conci 《European journal of plant pathology / European Foundation for Plant Pathology》2010,126(4):489-495
Yield losses caused by a second viral infection of garlic plants previously infected with either of the isolated Allexiviruses, Garlic virus-A (GarV-A) or Garlic virus-C (GarV-C), were evaluated in a field assay carried out over four consecutive growing seasons. The treatment groups included
virus-free plants (VF), plants infected only with GarV-A isolates (A), plants infected only with GarV-C isolates (C), and
plants infected with a mixture of viruses that naturally infect garlic, referred to as viral-complex plants (VC). From the
first crop cycle the different treatments were infected by other viruses that naturally infect garlic. At the end of the first
growth cycle, significant differences in yield were observed among the four treatments. The bulb weight for VF, C, and A treatments
was respectively 137%, 116%, and 96% higher than the bulb weight for the VC treatment. After the fourth growth cycle, however,
non-significant differences in garlic yield between the VC, C, and A treatments were observed, whereas the yield for the VF
treatment was higher than the VC treatment by 22%. Garlic yield decreased more rapidly in plants infected previously with
at least one Allexivirus and then infected with other naturally occurring viruses than the plants that were virus-free at the beginning (VF plants). 相似文献
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Picard Y Roumagnac P Legrand D Humeau L Robène-Soustrade I Chiroleu F Gagnevin L Pruvost O 《Phytopathology》2008,98(8):919-925
Based on the number of new reports during the last two decades, bacterial blight of onion (Allium cepa) is considered an emerging disease. The causal agent, Xanthomonas axonopodis pv. allii, is pathogenic to several Allium species after inoculation, but outbreaks worldwide have been primarily reported on onion. We describe a unique epidemiological situation in Réunion Island, France, with concomitant outbreaks on three Allium species, onion, leek (A. porrum), and garlic (A. sativum). There was no host specialization within Allium spp. among strains associated with the three host species. Based on amplified fragment length polymorphism (AFLP) and restriction fragment length polymorphism, strains associated with these outbreaks in Réunion Island were highly related genetically to strains isolated from diseased plant samples and contaminated seed lots in the neighboring island of Mauritius, where the disease has occurred since 1984. All AFLP haplotypes were identified as X. axonopodis pv. allii based on polymerase chain reaction analysis using specific primers, biochemical tests, and/or pathogenicity tests. Two genetically related groups of strains (A and B) that can be distinguished by AFLP, differential utilization of three carbon sources, and xanthomonadin pigment production were detected initially after establishment of the pathogen. In less than 10 years after the establishment of the pathogen there was nearly an extinction of group A strains in Réunion Island, suggesting differences in fitness between strains in the two groups. 相似文献
17.
采用浸渍法研究了分别取食韭菜、大葱、圆葱和大蒜的韭菜迟眼蕈蚊4龄幼虫对大蒜油、苦参碱和辛硫磷的敏感性,用生化分析法测定了敌敌畏和大蒜油对幼虫体内乙酰胆碱酯酶和主要代谢酶活性的影响.结果表明:大蒜油对取食韭菜、大葱、圆葱和大蒜4龄幼虫的LC50分别为825.14、1202.2、1274.3和1412.4mg/L;辛硫磷分别为0.5437、1.1921、1.7713和1.9224mg/L,两种药剂对取食大蒜和圆葱幼虫的毒力较取食韭菜的差异显著.取食大蒜和圆葱的幼虫较取食韭菜的其体内乙酰胆碱酯酶活力降低,羧酸酯酶的活力明显提高,谷胱甘肽-S-转移酶的活力也有一定提高.寄主植物所含的硫醚类化合物对乙酰胆碱酯酶和代谢酶的诱导或抑制可能是引起药剂敏感性差异的主要原因. 相似文献
18.
During a survey of viruses of peanuts in South Africa a mechanically transmissible virus was isolated from a plant exhibiting chlorotic ringspots and blotches on the leaves. Typical potyvirus-like flexuous particles were detected by electron microscope examination. Pinwheel-shaped and laminated inclusions in ultrathin sections, reaction with a monoclonal antibody directed to a potyvirus common epitope, a single 33 kDa coat protein and aphid transmission using Myzus persicae all confirmed that the virus was a subdivision II member of the Potyviridae. Host range studies suggested that the virus was none of the previously reported potyviruses of peanuts or of subdivision II potyviruses. The serological relationships of the virus were studied using a range of 17 antisera to potyviruses in ELISA and immunosorbent electron microscopy (ISEM). The isolate reacted weakly with antisera to plum pox virus and bean yellow mosaic virus in ISEM only. Nucleotide sequence of a 624 bp DNA product was obtained following immuno-capture with a potyvirus common epitope antiserum, cDNA synthesis and PCR amplification with potyvirus specific primers which amplify the 3' untranslated region and a part of the coat protein gene. The sequence was only distantly related to a number of potyviruses, whether amino acid or nucleotide sequences were used for comparisons. It is proposed that the virus be named peanut chlorotic blotch virus and be accepted as a new member of the genus Potyvirus in the family Potyviridae. 相似文献
19.
Two Serotypes of Sweetpotato feathery mottle virus in Uganda and Their Interaction with Resistant Sweetpotato Cultivars 总被引:1,自引:0,他引:1
ABSTRACT Isolates of Sweetpotato feathery mottle virus (SPFMV, genus Potyvirus, family Potyviridae) were obtained in several districts of Uganda from sweetpotato plants infected with the sweetpotato virus disease (SPVD), the most important disease of this crop in Africa. A monoclonal antibody (MAb 7H8) raised against the coat proteins (CP) of a mixture of the SPFMV strain C (United States) and the isolate SPV-I (West Africa) distinguished Ugandan SPFMV isolates into those detectable and not detectable by the MAb. These two serotypes differed in prevalence in different districts of Uganda and in two common sweetpotato cultivars. Both serotypes could be transmitted simultaneously by single aphids. The serotypes differed in their ability to systemically coinfect sweetpotatoes that were infected with Sweetpotato chlorotic stunt virus (SPCSV, genus Crinivirus), the virus required to induce SPVD in SPFMV-infected plants. One sweetpotato breeding line, resistant to SPFMV from the New World, was infected by graft-inoculation with all SPFMV isolates from Uganda. Another SPFMV-resistant sweetpotato line became infected with SPFMV and developed SPVD only following coinoculation with SPCSV. 相似文献
20.
ABSTRACT The Cucumis melo accession TGR-1551 was found to be resistant to Watermelon mosaic virus (WMV, genus Potyvirus, family Potyviridae). The resistance resulted in a drastic and significant reduction of virus titer and infected plants were asymptomatic or exhibited mild disease symptoms. The same gene or closely linked genes restricted virus accumulation and ameliorated symptom expression. No effect was observed on virus accumulation in inoculated leaves, which suggested that the initial phases of infection were not affected. The resistance was effective against a range of WMV isolates from Spanish melon production areas. Using aphid inoculations, resistant plants showed a lower propensity for infection by WMV and for serving as virus sources for secondary spread once infected. Resistance was determined to be under recessive genetic control. 相似文献