葡萄扇叶病毒移动蛋白在寄主体内的动态检测和免疫金标记

利用葡萄扇叶病毒法国分离物F13(Grapenive fanleaf virus, GFLVF13)移动蛋白抗体对杭州分离物(GFLVH)移动蛋白进行Western blot,分析表明移动蛋白在接种GFLVH 3d后的苋色藜(Chenopodium amaranticolor)系统叶中就可检测到,随着时间推移,其积累量逐渐升高,接种16d后达到最高值。接种32d后的病叶已经枯黄,但移动蛋白积累量并没有减少。超薄切片电镜观察发现,在感染GFLVH的昆诺藜(C.quinoa)和苋色藜的叶肉组织薄壁细胞中,病毒粒子呈纵列整齐地排列在小管状结构中,在胞间连丝中也发现有管状结构。免疫金标记显示胶体金能定位在细胞质、细胞壁和胞间连丝上,在管状结构也发现有少量的金粒子。这些结果进一步说明了GFLV是通过管状结构实现细胞间移动的。     

我国13种天南星科作物上的芋花叶病毒

用直接负染和免疫电镜方法从我国浙江省(杭州、奉化、温州等地)、上海、北京、福建、湖南等地的13种天南星科大田作物:芋(Colocasia esadenta)、魔芋(Amorphophallus sinesis)、药用植物:半夏(Pinellia ternata)、掌叶半夏(P. cordata)、盾叶半夏(P. pedatisecta)以及观赏植物:马蹄莲(Zantedeschia aethiopica)、海芋(Alocasia macrorrhiza)、象耳芋(Colocasia gigantea)、台果芋(Syngonium podophygum)、黄金葛(Scindapsus aureus)、广东万年青(Aglaonema modestum)、花叶芋(Caladium bicolar)、剑叶喜林芋(Philodendium oxycadium)上均检测到芋花叶病毒(Dasheen mosaicvirus, DMV)。在免疫吸附-免疫修饰电镜水平上,该病毒与DMV抗血清和PVY抗血清均有强阳性反应。在人工接种条件下,DMV各分离物均不侵染烟草等非天南星科供试植物,但接种天南星科指示植物Philodendr…     

烟草曲叶双生病毒的研究 I．广西分离物的生物学特性和血清学反应

烟草曲叶病已在广西九个产烟县(市)发生危害,一般为零星发生,局部地区平均发病率高达50％以上,造成严重经济损失。试验结果表明,此病仅可通过嫁接和烟粉虱(Bemisiatabaci)传染,而汁液摩擦、种子和中国菟丝子((Cuscuta chinesis)不传病。除普通烟(Nicotianatabacum)外,还可侵染枯斑三生烟(N.tabacum var.xanthi N)、番茄(Lycopersicon esculentum)和蔓陀罗(Datura stramonium)等鉴别寄主,产生典型的曲叶症状。ELISA检测结果表明,病烟叶提取液与非洲木薯花叶病毒(ACMV)的两个单抗(SCR 18和SCR 23)呈阳性反应,而与另外两个单抗(ACMV SCR 11和ICMV(印度木薯花叶病毒)SCR 52)呈阴性反应,用ACMV单抗SCR 18免疫吸附法制片,在电镜下观察到球状成对或单个的病毒颗粒,单颗粒直径为18nm,成对颗粒大小为15—18x 25—30nm。     

侵染扁豆的三叶草黄脉病毒的鉴定

1987年从泰安表现系统花叶的扁豆上分离到一个分离物B_2,汁液摩擦接种9科38种植物,它可侵染5科10种植物,在扁豆和昆诺藜上引起系统花叶,在苋色藜上引起局部枯斑。该分离物钝化温度为60—65℃,稀释限点为10~(-3)—10~(-4),体外存活期为3—5天。可由桃蚜传播;病毒粒体线条状,大小为700—760×12nm病叶细胞内有风轮状内含体,该分离物与三叶草黄脉病毒的抗血清有明显的-阳性反应。根据这些特性,该病毒属于马铃薯丫病毒组的三叶草黄脉病毒。     

含有拟病毒RNA的绒毛烟草斑驳病毒在克里夫兰烟原生质体内的增殖

利用酶联免疫吸附分析(ELISA)的双抗体夹心法和未标记免疫过氧化物酶法(PAP),研究了含有拟病毒RNA (Virusoid RNA)的绒毛烟草斑驳病毒(Velvet tobacco mottle virus,VTMoV)侵染克里夫兰烟(Nicotiana elevelandii A. Gray)原生质体的最适条件以及病毒在原生质体内增殖的一步生长曲线,建立了一种适宜VTMoV增殖的原生质体细胞体系。     

肉桂枝枯病病原研究

肉桂枝枯与可可毛色二孢(Lasiodiplodia theobromae)及肉桂泡盾盲蝽(Pseudodoniellachinensis)有关.后者吸食肉桂枝条的汁液,造成大量微小伤口,并携带该菌,是有效昆虫传媒,使肉桂枝条容易被该茵侵染,造成皮层坏死,引发极严重的枝枯病.     

湖南小白菜病毒病毒原种类鉴定

1983—1988年从湖南各地(以衡阳市郊为重点,包括湘北的岳阳,湘中的长沙、湘潭,湘南的郴州、零陵等地区)采集了小白菜病毒病标样812个,经指示植物鉴定、酶联检测、稳定性测定等方法将它们分为8个类型,其中有3类是单独侵染的,4类是复合侵染的,还有一类反应不明(待鉴定)。鉴定结果表明,湖南小白菜病毒病毒原的优势种类是芜菁花叶病毒(Tursip mosaic virus, TuMV),其次是黄瓜花叶病毒(Cucumber mosaic virus, CMV)和烟草花叶病毒(     

辣椒的烟草蚀纹病毒(TEV)鉴定初报

近年来辣椒病毒病在辽宁省各地发生较为普遍。为了弄清毒原种群,几年来,在我组鉴定出主要毒原为烟草花叶病毒(TMV)和黄瓜花叶病毒(CMY)的同时,又在从沈阳地区采集的21份标样中,鉴定出分离物6号,系烟草蚀纹病毒(TEV),这是在辣椒花叶病中检测出的一个新的毒原。辣椒分离物6号在以下的指示植物上,经摩擦接种后,叶面表现为:在辣椒上叶片呈黄化斑驳,心叶稍细长,有时叶肉并有微细蚀纹斑,植株略矮。在心叶烟上表现斑驳花叶,在普通烟(黄苗榆)叶上现蚀纹。在昆诺藜叶上生局部枯斑。在曼陀萝叶上生明脉和花叶。在百日草上生花叶症。在千日红和马铃薯上无症。采用其他原抗血清反证的方法,进行血清学反应测定,它对TMV、CMV、PVX、PVY的抗血清均无沉淀反应。采用辣椒6号分离物病叶,以叶浸蘸法,作电镜观察,病毒粒体为线状,长约730nm。病毒汁液体外三常规测定,其钝化温度约为55℃(10分钟);稀释限点为10~(-4);体外存活期5—6日(20℃)。因此初步认为它是侵染辣椒的烟草蚀纹病毒(TEV)。     

生物素标记GFV－cDNA探针的制备及在检测葡萄扇叶病毒上的应用

以整合到质粒中的ＧＦＶ－ｃＤＮＡ为模板经ＰＣＲ合成了生物素标记的ＧＦＶ单、双链探针。用合成的探针对提纯的ｃＦＶ－ＲＮＡ＿２、感染ＣＦＶ的昆诺藜叶及１８株而萄进行ＤＮＡ－ＲＮＡ杂交检测表明：检测提纯病毒ＲＮＡ＿２的灵敏度为１．５ｐｇ／斑点,感染ＧＦＶ的昆诺藜提取液最高稀释度可达４０９６０倍;１１株显示典型扇叶症状的样品杂交结果均为阳性,且汁液稀释４００～８００倍仍能测出,７株不显示典型扇叶症状的葡萄中３株受到ＧＦＶ的侵染。单、双链探针最适使用浓度分别为１／２００及１／１００。     

辛德毕斯病毒在BHK—21细胞中繁殖过程的研究

辛德毕斯病毒(Sindbis virus)在BHK—21细胞中繁殖的一步生长曲线表明,病毒感染后2小时便可产生大量的子代病毒;感染后6小时,病毒滴度达到最高峰,为109TCID50/ml电镜技术显示了病毒粒子的形态结构与形态发生过程。本文还对SbV的代谢合成动态及对宿主细胞的影响进行了研究和讨论。     

Detection and characterization of citrus tatter leaf virus (CTLV) and citrus yellow vein clearing virus (CYVCV) in citrus trees from Cyprus

Citrus tatter leaf virus (CTLV) was firstly reported of in California. After that, it reported in Australia, Korea, Nigeria, Japan, South Africa, and China. The transmission of this virus from plant to plant is very easy with mechanically. Citrus yellow vein clearing virus (CYVCV) was reported on lemon trees in India, Pakistan, Turkey and China. Foliar distortion, necrotic spots, chlorosis and wrinkling symptoms were observed in young lemon orchards in newly established orchards with trees imported from abroad. Therefore, surveys of citrus trees in Cyprus were performed for CTLV and CYVCV from 2013 to 2016. A total of 64 leaf samples from symptomatic citrus trees (41 lemon, 10 orange, 10 mandarin and three grapefruit samples) were collected for total nucleic acid extraction and RT-PCR with CTLV primers to amplify a 309 bp and a 614 bp fragment, respectively, of the 5′ end (100%) and high nucleotide sequence identity (99%) with isolates BJNM-2 and QC4 from China and isolate BDZ-1 from Australia. To our knowledge, this is the first report of CTLV from Europe.     

Lettuce big-vein virus: mechanical transmission and relationships to tobacco stunt virus

Big-vein diseased lettuce plants contained an agent that could consistently be transmitted mechanically to Chenopodium quinoa, in which it caused characteristic local lesions. Mechanical transmission was also possible to five other plant species including Nicotiana benthamiana, N. clevelandii and N. occidentalis, but not to lettuce. Symptoms in N. occidentalis were reminiscent of those of tobacco stunt disease. With zoospores of originally virus-free Olpidium brassicae, subcultured on the roots of N. occidentalis-P1, sap-inoculated either from lettuce or via C. quinoa, the agent could be transferred back to lettuce in which characteristic symptoms of big-vein were reproduced.
Infectivity in sap at room temperature was reduced by half after 2 h, and was practically lost after one day. Thermal inactivation was considerable at 45°C and complete at 50°C. Most infectivity was lost at dilution 1:5, and the dilution end-point was 1:10. The agent survived well in leaf material stored at -80°C, or in sap from leaves ground in buffer with DIECA and activated charcoal and freeze-dried. Mechanical transmission required low dilution (1:2) in the buffer with charcoal, and chilling of materials and utensils.
In lettuce, N. occidentalis-P1 and C. quinoa, with all isolates tested but one, infection was always associated with the presence of rod-shaped particles which in the literature have been associated with lettuce big-vein, and are similar to those described for tobacco stunt. Results obtained corroborate the assumption that these particles are the virions of lettuce big-vein virus. The virus also resembles tobacco stunt virus in mechanical transmissibility, instability in sap and symptoms on N. occidentalis.     

Properties of an unusual isolate of raspberry ringspot virus from grapevine in Germany and evidence for its possible transmission by Paralongidorus maximus

An isolate of raspberry ringspot nepovirus (RRV-P) commonly found infecting grapevine in localised areas of the German Palatinate, was serologically closely related to, but distinguishable from, the English type strain of this virus (RRV-E) which is transmitted by Longidorus macrosoma. However, unlike RRV-E, RRV-P had a restricted herbaceous host range and produced symptoms reliably in only two hosts, Chenopodium quinoa and Nicotiana occidentalis-accession 37B: these symptoms were a faint systemic vein clearing which, on most occasions in C. quinoa, was transient. In in vitro studies with herbaceous plant sap, RRV-P infectivity was lost after diluting 1/100-1/500, after storage at 20^oC for 1–3 days and at 4^oC for 45 days: for similar studies with RRV-E, the values were 1/125 000, and more than 15 days at 20^oC and 4^oC, respectively. RRV-P was difficult to purify in quantity and in most preparations seemed to sediment as a single component corresponding to ‘bottom’ component of RRV-E. Purified particles of RRV-P, like those of RRV-E, contained a major polypeptide and two RNA species of Mx 54 000, 2.6 × 106 and 1.6 × 106 respectively. There was no evidence from RNA preparations from purified virus particles or, from analysis of dsRNA from infected plants, that RRV-P contained a satellite RNA. The incidence of RRV-P in vineyards was not associated with the presence in soils of Longidorus nematodes, but was associated with the distribution in the Palatinate of Paralongidorus maximus. Furthermore, results from an experiment in Germany in a vineyard planted with healthy grapevines in soil fumigated to destroy nematodes, showed spread of RRV-P into these plants from an adjoining source of infected grapevines and soil infested with P. maximus. In laboratory studies, RRV-P was transmitted by P. maximus at a very low level between grapevines (used as the virus source and test plants) but not to, or between, herbaceous hosts.     

Reactions and resistance ofChenopodium species to tobacco mosaic virus

Chenopodium species react on infection with tobacco mosaic virus by the formation of chlorotic or necrotic lesions and later by the abscission of infected leaves. A transition of local infection into the stem has been observed exceptionally inChenopodium quinoa, C. hybridum, andC. rubrum, but no systemic infection of the leaves followed. Systemic infection was demonstrated only inC. polyspermum andC. murale. The recovery of new sprouts was demonstrated in C.murale in the late chronic phase of infection.     

Sri Lankan passion fruit mottle virus, a potyvirus infecting golden passion fruit in Sri Lanka

A sap-transmissible virus, provisionally named Sri Lankan passion fruit mottle virus (SLPFMV), was isolated from Passiflora edulis f. flavicarpa and shown to induce leaf mottling and distortion in that host. The virus infected 23 species in five plant families with systemic infection being common in the Passifloraceae. Chenopodium amaranticolor was a good local lesion host and Passiflora foetida was a useful systemic host for purification. In P. foetida extracts, SLPFMV lost infectivity after 10 min between 70–75°C, 6–7 days at 20–23°C and at dilutions of 10^--⁵ -W^-6. The virus had flexuous, filamentous particles with a normal length of c. 841 nm. Two polypeptides of mol. wt c. 33 200 and 28 700 were detected in purified virus preparations, and a major species of double-stranded RNA (mol. wt 7.0 × 10⁶), was detected in infected plants. Pinwheels, tubular and laminated inclusions were found in ultrathin sections of infected P. edulis f. plavicurpa and cylindrical inclusions were observed in epidermal strips. SLPFMV was transmitted by the aphids Myzus persicae, Aphis spiraecola, A. gossypü and A. cruccivora after brief acquisition feeds. SLPFMV reacted with antisera to several potyviruses including passion fruit woodiness virus, passion fruit ringspot virus, potato virus Y and watermelon mosaic virus 2 and thus, apparently, is a member of the potyvirus group.     

First report of occurrence of two viruses on pea field in Iran

An intensive survey was conducted to identify virus diseases affecting pea crops in Tehran province of Iran. A total of 270 pea samples were collected randomly from pea fields. samples were tested by Double Antibody Sandwich Enzyme Linked Immunosorbent Assay (DAS-ELISA) using polyclonal antisera prepared against PSBMV (AS-0129, DSMZ, Braunschweig, Germany) and TSWV (AS-0580, DSMZ, Braunschweig, Germany). Virus disease incidence in pea samples was followed by PSBMV (33%) TSWV (24.4%) and PSBMV+TSWV (17.77). The positive samples with PSBMV were extracted in 0.05M phosphate buffer pH 6.5-7 containing 2% pvp and inoculated on Pisum sativum, Vicia faba, Chenopodium quinoa, Chenopodium amaranticolor. That produced in Pisum sativum; leaflets roll downwards, shoots curl, internodes shorten and plants are rosetted. Early infections reduce flower and fruit formation or eliminate their development. Broad bean has symptoms accompanied by a certain margin rolling and leaflet distortion. In Chenopodium amaranticolor necrotic local lesions and Chenopodium quinoa chlorotic local lesions had produced. The positive samples with TSWV were extracted in 0.01 M phosphate buffer containing 1% Na2 SO3 and inoculated on Petunia hybrida, Pisum sativum. TSWV causes several symptoms in infected peas, including brown leaf petiole and stem coloration, leaflet spotting, vein necrosis. In petunia hybrida after approximately 5 days showed local necrotic lesion. Biological purification in TSWV with chlorotic local lesions in Petunia hybrida and in PSBMV; chlorotic local lesions in Chenopodium quinoa were done. In PSBMV, back inoculated on Pisum sativum and Vicia faba also tested with DAS-ELISA. RT-PCR confirmed the results. This is the first report of PSBMV and TSWV naturally infecting pea in Iran.     

Nucleotide sequences of a Korean isolate of apple stem grooving virus associated with black necrotic leaf spot disease on pear (Pyrus pyrifolia)

Pear black necrotic leaf spot (PBNLS) is a disease of pears caused by capillovirus-like particles, which can be observed under the electron microscope. The disease was analyzed by Western blot analysis with antisera raised against apple stem grooving virus (ASGV) coat protein. cDNAs covering the entire genome were synthesized by RT-PCR and RACE using RNA isolated from Chenopodium quinoa infected with sap extracted from pear leaves carrying black necrotic spot disease. The complete genome sequence of the putative pear virus, 6497 nucleotides in length excluding the poly (A) tail, was determined and analyzed. It contains two overlapping open reading frames (ORFs). ORF1, spans from nucleotide position 37 to 6354, producing a putative protein of 241 kDa. ORF2, which is in a different reading frame within ORF1, begins at nucleotide 4788 and terminates at 5750, and produces a putative protein of 36 kDa. The 241 kDa protein contains sequences related to the NTP-binding motifs of helicases and RNA-dependent RNA polymerases. The 36-kDa protein contains the consensus sequence GDSG found in the active sites of several cellular and viral serine proteases. Morphological and serological analysis, and sequence comparison between the putative pear virus, ASGV, citrus tatter leaf virus and cherry virus A of the capillovirus suggest that PBNLS may be caused by a Korean isolate of ASGV.     

Particle purification and properties of cassava Ivorian bacilliform virus

A virus found in cassava from the north-west of the Ivory Coast was transmitted by inoculation with sap extracts to herbaceous species in six plant families. Chenopodium quinoa was used as a propagation host and C. murale was used for local lesion assays. The virus particles are bacilliform, c. 18 nm in diameter, with predominant lengths of 42,49 and 76 nm and a structure apparently similar to that found in alfalfa mosaic virus. Purified preparations of virus particles had A₂₆₀/A₂₈₀ of 1.7 ±0.05, contained one protein of M_rc. 22 000, and yielded three species of RNA with M_r (× 10^-6) of c. 0.7, 0.8 and 1.2. Although the virus particles were poorly immunogenic, an antiserum was produced and the virus was detected by enzyme-linked immunosorbent assay (DAS-ELISA) in leaf extracts at concentrations down to c. 6 ng/ml. Four other field isolates were also detected, including a strain which caused only mild systemic symptoms in C. quinoa instead of necrosis. The naturally infected cassava source plants were also infected with African cassava mosaic virus (ACMV) but when the new virus was cultured in Nicotiana benthamiana, either separately or together with ACMV, its concentration was the same. The new virus did not react with antisera to several plant viruses with small bacilliform or quasi-bacilliform particles, and alfalfa mosaic virus reacted only weakly and inconsistently with antiserum to the cassava virus. The new virus, for which the name cassava Ivorian bacilliform virus is proposed, is tentatively classified as the second member of the alfalfa mosaic virus group.     

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.