侵染落葵的黄瓜花叶病毒分离物CP基因序列分析

通过间接酶联免疫法(ID-ELISA)检测到染病落葵病样中存在黄瓜花叶病毒（Cucumber Mosaic Virus,CMV）。从病叶中提取总RNA,用RT-PCR方法扩增得到657bp的CMV CP基因片断,将扩增产物与T载体连接并进行测序。用DNA MAN将得到的CP基因序列与GenBank收录的黄瓜花叶病毒两亚组部分株系或分离物的CP基因序列进行比较,结果表明该CP基因与CMV亚组Ⅰ、亚组Ⅱ之间的核苷酸序列同源性分别为91.17~95.43%和75.30~75.76%,推导氨基酸序列同源性分别为95.41~97.71%和81.28~81.74%,表明CMV-Ba与亚组Ⅰ同源关系密切。     

CMV甜瓜分离物外壳蛋白基因的克隆及植物表达载体的构建

从河南省临颖县采集的病毒感染的甜瓜样本经ELISA检测和接种分离获得黄瓜花叶病毒(Cucunber mosaic virus ,CMV) 分离物.把该分离物接种西葫芦, 从发病的叶片中提取总RNA,并以此为模板经RT-PCR扩增获得CMV的外壳蛋白(cp)基因,将其克隆到pUCm-T质粒上.经序列测定和分析,结果表明该cp基因由657个核苷酸组成,编码218个氨基酸.其核苷酸序列与黄瓜花叶病毒亚组I的分离物有较高的同源性,达92.2%～93.9%,与亚组II的同源性仅为76.8%～77.8%,与我国报道的CMV分离物的cp基因序列比较,除香蕉株系XB外核苷酸序列的同源性达91.8%～93.4%.根据这些分析,该CMV分离物属于亚组I.将cp基因通过中间载体pJIT163定向克隆到植物表达载体pBINPLUS中(重组双元载体质粒命名为pBCP),并经冻融法导入农杆菌中,经PCR及酶切鉴定,证实质粒已被导入.利用该植物表达载体对西瓜的遗传转化工作目前正在进行中.     

CMV甜瓜分离物外壳蛋白基因的克隆及植物表达载体的构建

从河南省临颖县采集的病毒感染的甜瓜样本经ELISA检测和接种分离获得黄瓜花叶病毒(Cucunbermosaicvirus,CMV)分离物。把该分离物接种西葫芦,从发病的叶片中提取总RNA,并以此为模板经RTPCR扩增获得CMV的外壳蛋白(cp)基因,将其克隆到pUCmT质粒上。经序列测定和分析,结果表明该cp基因由657个核苷酸组成,编码218个氨基酸。其核苷酸序列与黄瓜花叶病毒亚组I的分离物有较高的同源性,达92.2%～93.9%,与亚组II的同源性仅为76.8%～77.8%,与我国报道的CMV分离物的cp基因序列比较,除香蕉株系XB外核苷酸序列的同源性达91.8%～93.4%。根据这些分析,该CMV分离物属于亚组I。将cp基因通过中间载体pJIT163定向克隆到植物表达载体pBINPLUS中(重组双元载体质粒命名为pBCP),并经冻融法导入农杆菌中,经PCR及酶切鉴定,证实质粒已被导入。利用该植物表达载体对西瓜的遗传转化工作目前正在进行中。     

甘蔗花叶病毒E株系外壳蛋白基因原核表达载体的构建与表达

目的:用原核表达的方法获取大量带6个His标记的甘蔗花叶病毒E株系(ScMV-E)外壳蛋白(CP)。方法:用带有BamHⅠ和SalⅠ酶切位点的特异引物,以带有多个基因的重组质粒pNUSCP为模板,扩增出片段长度为942bp的ScMV-E外壳蛋白基因,亚克隆到pMD18-T载体上,转化E.coliDH5α,经双酶切检测获得阳性克隆。BamHⅠ和SalⅠ双酶切阳性克隆质粒,回收目的片段ScMV-E的CP基因。把目的片段插入表达载体pET29a( ),转化E.coliBL21(DE3),测序。结果:阳性质粒pET29a-CP在E.coliBL21(DE3)中得到大量特异表达。SDS-PAGE分析表明,该蛋白的相对分子质量约36000,与预测一致。结论:以上方法可以得到带6个His标记的目的蛋白,有利于纯化并获取高纯度的ScMV-E的外壳蛋白。     

Molecular Marker-Assisted Genotyping of Mungbean Yellow Mosaic India Virus Resistant Germplasms of Mungbean and Urdbean

Mungbean Yellow Mosaic India Virus (MYMIV) belonging to the genus begomovirus causes the yellow mosaic disease in a number of economically important edible grain legumes including mungbean (Vigna radiata), urdbean (Vigna mungo) and soybean (Glycine max). The disease is severe, critical, open spread and inflicts heavy yield losses annually. The objective of this study is to develop molecular markers linked to MYMIV-resistance to facilitate genotyping of urdbean and mungbean germplasms for MYMIV-reaction. Resistance-linked molecular markers were successfully developed from consensus motifs of other resistance (R) gene or R gene homologue sequences. Applying linked marker-assisted genotyping, plant breeders can carry out repeated genotyping throughout the growing season in absence of any disease incidence. Two MYMIV-resistance marker loci, YR4 and CYR1, were identified and of these two CYR1 is completely linked with MYMIV-resistant germplasms and co-segregating with MYMIV-resistant F₂, F₃ progenies of urdbean. The present study demonstrated that these two markers could be efficiently employed together in a multiplex-PCR-reaction for genotyping both V. mungo and V. radiata germplasms from field grown plants and also directly from the seed stock. This method of genotyping would save time and labour during the introgression of MYMIV-resistance through molecular breeding, as methods of phenotyping against begomoviruses are tedious, labour and time intensive.     

The Nucleotide Sequence and Genome Structure of Mung Bean Yellow Mosaic Geminivirus

Complete nucleotide sequences of the infectious cloned DNA components (DNA 1 and DNA 2) of mung bean yellow mosaic virus (MYMV) were determined. MYMV DNA 1 and DNA 2 consists of 2,723 and 2,675 nucleotides respectively. DNA 1 and DNA 2 have little sequence similarity except for a region of approximately 200 bases which is almost identical in the two molecules. Analysis of open reading frames revealed nine potential coding regions for proteins of mol. wt. > 10,000, six in DNA 1 and three in DNA 2. The nucleotide sequence of MYMV DNA was compared with that of bean golden mosaic virus (BGMV), tomato golden mosaic virus (TGMV) and African cassava mosaic virus (ACMV). The 200-base region common to the two DNAs of each virus had little sequence similarity, except for a highly conserved 33-36 base sequence potentially capable of forming a stable hairpin structure. The potential coding regions in the MYMV DNAs had counterparts in the BGMV, TGMV and ACMV, suggesting an overall similarity in genome organization, except for absence of 1L3 in MYMV DNA 1. The most highly conserved ORFs, MYMV 1R1, BGMV 1R1, TGMV 1R1 and ACMV 1R1, are the putative genes for the coat proteins of MYMV, BGMV, TGMV and ACMV, respectively. MYMV 1L1 has also a high degree of sequence similarity with BGMV 1L1, TGMV 1L1 and ACMV 1L1.     

大蒜花叶病毒外壳蛋白基因cDNA的克隆和序列分析

我们从自然发病的大蒜中分离得到了大蒜花叶病毒。以其基因组ＲＮＡ为模板合成了３＇末端部分ｃＤＮＡ。从中选出一批插入片段在２．０ｋｂ以上的重组克隆,经Ｎｏｒｔｈｅｒｎ点杂交分析证实了所选克隆与基因组ＲＮＡ同源。通过对若干个克隆的插入片段两端部分序列的测定,选出一个克隆ｐＧＭ４９５,其插入片段的长度约为２．４ｋｂ,３′末端存有一个Ｐｏｌｙ（Ａ）结构,它应包含了编码该病毒外壳蛋白全部序列。序列测定的结果表明,这个ｃＤＮＡ片段全长为２３７９ｂｐ,其中含有与酶切图谱分析结果相符的ＥｅｏＲＩ、ＰｓｔＩ及ＢａｍＨＩ酶切位点。第一个终止密码子ＴＡＡ与３′ｇ末端相距２６４ｂｐ,我们根据碱基序列推定的氨基酸序列与其它已发表的Ｐｏｔｙｖｉｒｕｓ的外壳蛋白氨基酸序列以及外壳蛋白翻译后加工的蛋白酶专一切点相比较后推测,编码该病毒外壳蛋白序列可能起始于３′末端上游的１１７０ｂｐ处,共编码３０２个氨基酸,其分子量为３６ｋＤ,略大于ＳＤＳ－ＰＡＧＥ所测定的３３ｋＤ,非编码区域长２６４ｂｐ,富含ＡＴ,并有多个终止密码子的存在。趾３′末端３２～２７ｂｐ处有一个ＡＡＴＡＡ序列。     

侵染广西罗汉果的小西葫芦黄花叶病毒的鉴定及抗血清制备

在广西临桂罗汉果花叶畸形病株上获得了一个线状病毒分离物LGL-1,寄主范围、蚜传能力测定、病毒粒子形态和细胞病理特征研究表明,它是马铃薯Y病毒科成员.采用马铃薯Y病毒科特异性简并引物做PCR扩增,并测定了分离物LGL-1的基因组3′-末端序列,序列分析表明它是小西葫芦黄花叶病毒（ZYMV）.系统进化树分析揭示,世界范围内的ZYMV分离物主要可分为3大群体,分离物LGL-1为中国特有群体Group Ⅲ成员.原核表达制备了分离物LGL-1的外壳蛋白抗血清,明确了ZYMV是引起广西罗汉果病害的主要病毒,并且比较了原核表达法和提纯病毒法制备的抗血清,在病样的间接ELISA法检测中结果的差异.     

Properties of the Coat Protein of a New Tobacco Mosaic Virus Coat Protein ts-Mutant

Amino acid substitutions in a majority of tobacco mosaic virus (TMV) coat protein (CP) ts-mutants have previously been mapped to the same region of the CP molecule tertiary structure, located at a distance of about 70 Å from TMV virion axis. In the present work some properties of a new TMV CP ts-mutant ts21-66 (two substitutions I21 T and D66 G, both in the 70-Å region) were studied. Thermal inactivation characteristics, sedimentation properties, circular dichroism spectra, and modification by a lysine-specific reagent, trinitrobenzensulfonic acid, of ts21–66 CP were compared with those of wild-type (U1) TMV CP. It is concluded that the 70-Å region represents the most labile portion of the TMV CP molecule. Partial disordering of this region in the mutant CP at permissive temperatures leads to loss of the capacity to form two-layer aggregates of the cylindrical type, while further disordering induced by mild heating results also in the loss of the ability to form ordered helical aggregates.     

黄瓜花叶病毒CP基因原核表达及抗血清的制备

把黄瓜花叶病毒 (CMV)西番莲分离物的外壳蛋白 (CP)基因 ,通过BamHI SacI位点定向插入pET 2 2b( )载体 ,转化大肠杆菌BL2 1 (DE3)中 ,经IPTG诱导下 37℃培养 6h ,SDS PAGE电泳示表达蛋白分子质量为 31 8kDa ,表达量占菌体总蛋白的 2 8 9%,表明该蛋白得到了高效表达。用冰冷的氯化钾溶液显色 ,用表达的特异蛋白质条带制备抗原 ,免疫家兔制备出病毒特异抗血清。采用ID ELISA测定抗血清效价为 1 0 -6;抗血清和CMV几个分离物均有特异反应 ,和TMV、菌体蛋白不发生非特异性反应 ;检测病毒灵敏度达 30ng ml,能够从稀释 31 2 5倍的感病植物汁液中检测出病毒     

Macroscopic Aggregation of Tobacco Mosaic Virus Coat Protein

The relationship between processes of thermal denaturation and heat-induced aggregation of tobacco mosaic virus (TMV) coat protein (CP) was studied. Judging from differential scanning calorimetry melting curves, TMV CP in the form of a trimer–pentamer mixture (4S-protein) has very low thermal stability, with a transition temperature at about 40°C. Thermally denatured TMV CP displayed high propensity for large (macroscopic) aggregate formation. TMV CP macroscopic aggregation was strongly dependent on the protein concentration and solution ionic strength. By varying phosphate buffer molarity, it was possible to merge or to separate the denaturation and aggregation processes. Using far-UV CD spectroscopy, it was found that on thermal denaturation TMV CP subunits are converted into an intermediate that retains about half of its initial -helix content and possesses high heat stability. We suppose that this stable thermal denaturation intermediate is directly responsible for the formation of TMV CP macroscopic aggregates.     

黄瓜花叶病毒衣壳蛋白基因转化辣椒研究

The plant expression vector of the coat protein(CP) gene of cucumber mosaic virus (CMV) BS strain was used to transform three kinds of pepper (Capsicum annuum) tissues (cotyledon, stem and root) by agrobacterium-mediated co-cultivation. 53%-68.4% of the total tissues (639) can be induced to be calli, but only cotyledon calli can be further regenerated to form shoots (regenerated efficiency 39.7%). 70%(42/60) of the putative transformed plants were confirmed to have CP gene in their genomes by Southern blot. The mRNAs and the CP were respectively found in 80% of transgenic plants by Northern blot and DAS-ELISA. 24 of the transgenic plants expressing CP gene of BS strain showed three kinds of resistant level (severe symptom, delay of symptomatic development, no symptom) to infection of CMV-BS and of CMV-P. However, there was distinctly higher resistance to inoculation of CMV-BS than that with CMV-P in these transgenic plants.     

Nuclear Targeting of the Cauliflower Mosaic Virus Coat Protein

The entry of the viral genomic DNA of cauliflower mosaic virus into the nucleus is a critical step of viral infection. We have shown by transient expression in plant protoplasts that the viral coat protein (CP), which is processed from the product of open reading frame IV, contains an N-terminal nuclear localization signal (NLS). The NLS is exposed on the surface of the virion and is thus available for interaction with a putative NLS receptor. Phosphorylation of the matured CP did not influence the nuclear localization of the protein but improved protein stability. Mutation of the NLS completely abolished viral infectivity, thus indicating its importance in the virus life cycle. The NLS seems to be regulated by the N terminus of the precapsid, which inhibits its nuclear targeting. This regulation could be important in allowing virus assembly in the cytoplasm.     

Soybean Mosaic Virus: Vector Specificity and Coat Protein Properties

Aphid transmission studies of two soybean mosaic virus isolates have shown that both isolates are transmitted by Myzus persicae. Only one of the isolates is transmitted by Rhopalosiphum maidis. The R. madis non-transmissible isolate could be transmitted from plants co-infected with the R. maidis transmissible isolate; aphid acquisition factor did not seem to mediate this transmission. The two isolates could be differentiated by enzyme-linked immunosorbent assay experiments, but peptide mapping experiments revealed few differences between the isolates.     

A Point Mutation in the Coat Protein Gene Affects Long-Distance Transport of the Tobacco Mosaic Virus

A mutation resulting in substitution of positively charged Lys53 with negatively charged Glu in the coat protein was introduced in the infectious cDNA copy of the genome of wild-type tobacco mosaic virus strain U1. Kinetic analysis of long-distance virus transport in plants showed that systemic spread of the mutant virus was delayed by 5–6 days as compared with the wild-type one. On evidence of RNA sequencing in the mutant progeny, Glu50 of the coat protein was substituted with Lys after passage I to compensate for the loss of the positive charge at position 53. Electron microscopy revealed atypical inclusions (rodlike structures, multiple electron-dense globular particles) in the nuclear interchromatin space of leaf mesophyll cells infected with the mutant but not with the wild-type virus.     

Resistance to Tomato Yellow Mosaic Geminivirus and Presence of Viral DNA in Some Species of Solanaceae

In this work we studied tomato yellow mosaic geminivirus (ToYMV) symptoms and DNA presence in several species of Solanaeae: Lycopersivon esculentum, Lycoperstcon peru-vianum. Lycium barbarum, Nicotiaiiu benthautian, Solunum lycopersioides. Solanum quitoense and Solanum rickli . After mechanical and insect transmission, in both greenhouse and open field, we found plants of Lyiium barbarum and Solanum lycopersicoides to be resistance to ToYMV, Polymerase chain reaction analysis showed that the resistant plants did not contain viral DNA.     

甜菜坏死黄脉病毒外壳蛋白基因在甜菜转基因植株中的表达

甜菜坏死黄脉病毒(Beet Necrotic Yellow Vein Virus,BNYVV)是一种由甜菜多粘菌(Polymyxo be tae)传播的多分体植物病毒．基因组由4～5条单链正意RNA构成^[1]。60年代末,由Tamada首次报道^[2],这种病毒可对甜菜造成严重危害,侵染甜菜后产生丛根症状(Rhizomania),并导致甜菜产量和含糖 量的大幅度下降。除欧洲、北美及日本的严重发生以外,我国自70年代以来在东北、内蒙古及西北许多省区也有大量甜菜丛根病的发生报道^[3]。由于尚无有效药剂及措施用于甜菜丛根病或病毒传播介体的防治．在我国也无法采用大面积轮作作为防治手段,所以目前在世界各地及我国上述地区甜菜丛根病的发病面积逐年扩展,对甜菜生产和制糖业造成直接威胁。针对这一情况．本文报道了含有甜菜坏死黄脉病毒外壳蛋白基因的甜菜植株的转化再生工作,以期在甜菜亲本育种中获得新的抗性材料．为抗病毒品种的培育打下基础。