Serological Studies on Mung Bean Yellow Mosaic Virus

Particles of mung bean yellow mosaic virus (MYMV) were purified by a method that yields up to 3 mg per kg of systemically infected Phaseolus vulgaris“Top Crop” and used to prepare antiserum. MYMV antiserum prepared gave a single precipitin line and had a titre of 1/512 with homologous virus in gel double-diffusion tests. MYMV was shown to be serologically related to other whitefly-transmitted viruses, bean golden mosaic virus, tobacco leaf curl virus and cassava latent virus.     

应用免疫电镜技术快速检测菜豆黄花叶病毒、马铃薯M病毒和燕麦花叶病毒

应用免疫吸附电流技术(ISEM)可有效地检测腐汁液中的菜豆黄花叶病毒(BYMV)、马铃薯M病毒(PVM)和燕麦花叶病毒(OMV)。BYMV,PVM和OMV三种抗血清的适宜工作浓度和对铜网的适宜包被时间均为1000倍和1小时,对同源病毒的适宜捕获时间分别为4℃下2、2和8小时。PVM和OMV的病汁液检测灵敏度均为稀释4000倍,而BYMV病汁液稀释16000倍时还能检测到少量病毒料子。ISEM捕获法和修饰法的结果表明,这三种病毒之间无血清学交叉反应。     

菜豆黄色花叶病毒(BYMV)—新疆苜蓿分离株的鉴定

从新疆苜蓿黄斑花叶病株上分离到病毒分离物M-4,该分离物能引起多种豆科值物系统花叶,并在藜科植物上产生局部褪绿斑,易经汁液摩擦接种和蚜虫传毒,不经菜豆种子传毒。病毒致死温度60—65℃,体外保毒期4—5天,稀释限点10~(-3)—10~(-4)。病毒粒体线状,长约660—740nm,宽15nm;在感病的寄主叶片细胞中,电镜观察到风轮状、带状和环状内含体。免疫电镜法测定,该分离物与菜豆黄色花叶病毒(BYMV)抗血清有血清反应。经SDS-聚丙烯酰胺凝胶电泳和氨基酸自动分析仪分析分别测得该病毒的衣壳蛋白亚基分子量为16,200道尔顿,氨基酸残基数128个。鉴定结果认为,分离物M-4是BYMV的一个株系。     

Statice Virus Y - a Virus related to Bean Yellow Mosaic and Clover Yellow Vein Viruses

The authors are greatly indebted to the Deutsche Forschungsgemeinschaft for financial support, to Miss B. M urthlm , Mrs. U. H erzberg , Mrs. B. H ane and Miss P. R ahse for reliable technical assistance and to Dr. M. H ollings , Dr. R. O. H ampton and Mr. D. Z. M aat for gifts of antisera.     

A Simple Solid-Phase Based Purification Procedure for Oligodeoxynucleotides

Abstract

A two-cartridge method for routine purification of DNA oligomers has been investigated. The full-length target oligonucleotides are purified using a method that select for intact 3′- and 5′-termini. The procedure results in purified DNA without the use of PAGE gels or HPLC.     

小麦黄花叶病毒的分离提纯及其血清学等特性

应用梯度离心和超速离心浓缩获得部分提纯的病毒制剂,产量约为7.45g/kg病叶提纯的病毒制剂的紫外吸收曲线呈典型的核蛋白吸收曲线,OD260/OD242和OD260/OD280的比值分别为1.24和1.38。病毒粒子呈线状,宽13—14nm,长度主要分布于250—300nm和550—700nm之间,1000nm以上的粒子也有检到。病毒外壳蛋白仅由一个分子量约为30Kd的亚基组成。在免疫电镜试验中、病毒粒子与日本WYMV抗血清发生强烈的血清学反应。新鲜病叶的超薄切片中可看到大量风轮体和膜状体。     

紫藤脉花叶病毒cp基因在大肠杆菌中的表达及抗血清的制备

采用RT-PCR方法自紫藤脉花叶病毒北京分离物(WVMV-BJ)的基因组中分离出其CP基因,连接到原核表达载体pET22b(+)上.获得的重组子pET-WVMVCP转化大肠杆菌BL21(DE3)后,用IPTG进行诱导表达.SDS-PAGE和Western blot分析表明,cp基因在大肠杆菌中获得了高效表达,融合蛋白分子量约为34.4 kDa.将融合蛋白纯化后免疫兔子,获得了特异性较高的抗血清.微量免疫沉淀法测定该抗血清的效价为1/1024,酶联法(enzyme-linkedimmunosorbant assay,ELISA)测定的效价为1/8192.     

紫藤脉花叶病毒cp基因在大肠杆菌中的表达及抗血清的制备

采用RT-PCR方法自紫藤脉花叶病毒北京分离物(WVMV-BJ)的基因组中分离出其CP基因,连接到原核表达载体pET22b( )上。获得的重组子pET-WVMVCP转化大肠杆菌BL21(DE3)后,用IPTG进行诱导表达。SDS-PAGE和Western blot分析表明,cp基因在大肠杆菌中获得了高效表达,融合蛋白分子量约为34．4kDa。将融合蛋白纯化后免疫兔子,获得了特异性较高的抗血清。微量免疫沉淀法测定该抗血清的效价为1／1024,酶联法(enzyme-linked immunosorbant assay,ELISA)测定的效价为1／8192。     

Purification and Properties of the Geminivirus Euphorbia Mosaic Virus

Euphorbia mosaic virus was purified from infected plants of Nicotiana benthamiana. Highest concentrations of virus particles were found in infected plant tissue between 10–12 days after inoculation. The enzyme driselase assisted in purification of the virus particles from the infected tissue yielding about 600 μg/kg of plant material. Purified preparations showed a maximum absorption at 260–263 nm and the ratio of absorption at 260 and 280 nm was 1.4. The viral nucleic acid was digestedby DNase I and S₁ Nuclease but not RNase A. A single coat protein with a MW of 32,000 d and two DNA bands with a MW 0.96 × 10⁶ d (2870 nucleotides) and 0.90 × 10⁶ d (2700 nucleotides) were associated with the purified virus particles. Virus specific DNA was isolated from infected tissue between 7 and 15 days after inoculations.     

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.     

Identification of Genes for Resistance to Bean Common Mosaic Virus and Bean Common Mosaic Necrosis Virus in Snap Bean (Phaseolus vulgaris L.) Breeding Lines Using Conventional and Molecular Methods

Bean common mosaic virus (BCMV) and Bean common mosaic necrosis virus (BCMNV) are among the biggest threats for snap bean production in Bulgaria due to their seed, aphid and mechanical transmission. Old valuable Bulgarian snap bean varieties are being neglected, because of the high percentage of virus‐infected seeds. Breeding resistant cultivars is the best way to solve the problem. The genetic control towards both viruses is assured by one dominant I gene and a number of recessive (bc‐u, bc‐1, bc‐1², bc‐2, bc‐2² and bc‐3) genes. Our aim was to identify resistance gene combinations in advanced F8 breeding lines, derived from two crosses (A‐8‐40‐7‐2‐1 × IVT 7214) and (Zaria × RH 26D), by the application of conventional and molecular approaches. Four methods were applied for the characterization of their resistance gene makeup: (i) leaf‐abscission infection test designed to identify I gene by direct inoculation with NL3 strain of BCMNV; (ii) intact‐plant infection test with strain NY15 of BCMV to separate immune genotypes, possessing bc‐ubc‐1², bc‐ubc‐2^2,bc‐ubc‐2bc‐3, I, Ibc‐1², Ibc‐2² or Ibc‐3; (iii) PCR analysis with the following markers: SCAR – SW13 (for I gene), SBD5 (for bc‐1²), ROC11 (for bc‐3) and CAPS – eIFE4 (for bc‐3); and 4) high‐temperature (more than 30°C) infection test with NL3 of BCMNV to provoke systemic necrosis in I, Ibc‐1, Ibc‐1², Ibc‐1²bc‐2² or Ibc‐3. The four methods applied worked properly and complemented each other. Valuable gene combination (Ibc‐3) was established in seven breeding lines with immune reaction to BCMNV. They will be included in the snap bean breeding programme for virus resistance.     

Barley Yellow Mosaic Virus: Purification, Electron Microscopy, Serology, and other Properties of two Types of the Virus

From naturally infected barley plants two types of barley yellow mosaic viruses have been isolated in Federal Republic of Germany. Both are identical in morphology, showing a bimodal length distribution (270–289 nm and 568–600 nm), and in symptomatology. Both induce conspicuous cytoplasmic inclusions of the pinwheel type and laminated aggregates, as well as threedimensional crystal-like arrays of membrane material. The types differ, however, in buoyant density, serology, and transmissibility. One is transmissible by soil as well as mechanically (BaYMV-M), and does not react with a Japanese antiserum to the Japanese virus (BaYMV-J). The other type (BaYMV-NM) is only transmissible by soil and reacts with BaYMV-J-antiserum. From mechanically infected plants BaYMV-M was purified, and an antiserum was produced, from soil-infected plants only mixtured BaYMV-NM and -M could be obtained. BaYMV-NM prevailed during winter, but with rising temperatures in spring BaYMV-M was predominant. BaYMV-M and the -M-NM mixture had each two species of nucleic acids (2.7–2.8 × 10⁶ and 1.4–1.5 × 10⁶ d) and two major protein subunit bands were found in SDS-PAGE (35–36 × 10³ and c. 29 × 10³ d).     

Mechanical Transmission of Soil-borne Barley Yellow Mosaic Virus

Leaves of winter barley (Hordeum vulgare L.) cv. Gerbel were mechanically sap-inoculated with Barley Yellow Mosaic Virus (BaYMV). Different additives to the inoculation fluid were tested. Whereas the dilution of plant sap by water alone resulted in an infection rate of 43%, the addition of sodium sulphite (80 %) and potassium phosphate-buffer (89%) increased the proportion of infected plants substantially. Infectivity was further increased by repeated inoculation, when sodium sulphite yielded 96 % and potassium phosphate 100% of infection. The usefulness of the technique in further research and application is discussed.