应用单链构象多态性－聚合酶链反应研究我国大麦黄花叶病毒株系的分化

根据致病性差异,我国大麦黄花叶病毒（ＢａＹＭＶ）存在若干不同株系,血清学和核酸杂交等技术不能区分这些株系。但还由于致病性不同,各株系的核酸序列间必定存在差异。最近建立的单链构象多态性。聚合酶链反应（ＳＳＣＰ－ＰＣＲ）技术能灵敏而有效地诊断和区分核酸序列间的差异,从而进一步证实我国ＢａＹＭＶ不同株系的分化。     

Molecular Analysis of Zucchini yellow mosaic virus Isolates from Hangzhou, China

Isolates of Zucchini yellow mosaic virus were obtained from different cucurbit crops in Hangzhou city, China. The complete nucleotide sequences of four isolates and the 3′‐terminal sequences, including the coat protein coding region, of four others were determined and then compared with other available sequences. Phylogenetic analysis of the coat protein nucleotide sequences showed that these isolates fell into three significant groups, one of which (designated group III) consisted exclusively of Chinese isolates and is reported for the first time. Comparisons over the completely sequenced genomes showed that, typically for potyviruses, the 5′‐end of the genome was usually the most variable but that the group III isolate differed from the others most significantly in the N‐terminal part of the coat protein. Partially sequenced group III isolates also varied from other isolates in this region. Group III isolates appear to differ biologically from the other isolates because they do not cause symptoms in watermelon fruit but induce more severe symptoms on the watermelon leaves.     

利用异种动物抗血清双抗夹心法检测小麦黄花叶病毒

小麦黄花叶病毒(Wheat yellow mosaic virus,WYMV),属于马铃薯Y病毒科(Potyviridae),大麦黄花叶病毒属(Bymovirus),传播介体为禾谷多粘菌(Polymyxa graminis),与发生在欧美的小麦梭条花叶病毒(WSSMV)为同一属内的两种病毒。该病毒在我国分布广泛,在长江流域各省份以及济南、陕西等都有分布,对小麦生长.发育构成严重危害。一般可引起小麦减产10％～30％,严重时达70％,甚至绝产。以往对该病害的诊断主要是根据田间的症状表现,有时很难与由其他病原或环境因子引致症状相区分,目前,关于WYMV的问接酶     

Rapid production of recombinant barley yellow mosaic virus resistant Hordeum vulgare lines by anther culture

Summary In a winter barley breeding program for barley yellow mosaic virus (BaYMV) resistance, the resistant six-rowed cv. Franka was crossed to 17 susceptible and two resistant cultivars, three of which were tworowed. A total of 233,445 anthers of the 19 hybrids and their parents were cultured and 831 green plants regenerated. Anther culture responsiveness varied greatly between genotypes, and the responsiveness of F₁hybrids was generally related to that of the more responsive (high) parent. On average, 3.6 green plants were recovered from 1,000 cultured anthers, almost twice as many as in comparable spring barley experiments. Androgenetic green plants were tested for their reaction to mechanical inoculation of BaYMV. In crosses of resistant parents, all the cross progeny proved to be resistant, which indicates that both parents carry identical gene(s). In the crosses of the resistant cv. Franka to susceptible parents, an average of 62% of the androgenetic progenies were resistant, which indicates that probably more than one gene is responsible for Franka's BaYMV-resistance. From the crosses of Franka to two-rowed cultivars, 282 androgenetic plants were produced. When 132 of these were tested for their reaction to BaYMV, 79 (59.8%) were resistant, and 30 of the latter were shown to be two-rowed recombinant lines. Doubled haploid lines are field-tested for other agronomic characters including grain yield and its components.     

Association of two barley yellow mosaic virus (RNA 2) encoded proteins with cytoplasmic inclusion bodies revealed by immunogold localisation

Summary Antisera were raised against the RNA 2-encoded proteins of 28 kDa and 70 kDa of barley yellow mosaic virus (BaYMV) by using the corresponding cDNA sequences of a German isolate for protein overexpression inEscherichia coli BL 21 and subsequent purification. The proposed processing of a 98 kDa precursor polyprotein encoded by the long open reading frame of RNA 2 to two proteins of 28 kDa and 70 kDa could be confirmed by immunoprecipitation of the in vitro transcribed and translated cDNA-clone of RNA 2 and Western blot analysis of fragmentated protein extracts of BaYMV-infected winter barley plants. In situ localisation studies of infected leaf tissue using immunogold labeling techniques for electron microscopy revealed that both viral proteins of BaYMV (RNA 2) were associated with the crystal-like cytoplasmic inclusion bodies. No other parts of the cells and no other inclusions (pinwheelstructures or aggregated virus particles) showed any gold labeling when the 28 kDa and 70 kDa antisera were used. We suppose that both RNA 2-encoded proteins take part in the formation of the crystal-like cytoplasmic inclusion bodies which are the most dominant structures in the cytoplasm of BaYMV-infected tissue. Possible functions of the 28 kDa and 70 kDa protein of BaYMV (RNA 2) are discussed.Abbreviations PBS phosphate-buffered saline - CEA chicken egg albumin - BaYMV barley yellow mosaic virus - BaMMV barley mild mosaic virus     

我国真菌传线状小麦花叶病毒病病原初步鉴定为小麦黄花叶病毒(WYMV)

由禾谷多粘菌（Ｐｏｌｙｍｙｘａｇｒａｍｉｎｉｓ）传播的线状小麦花叶病毒有两种,一种是加拿大首先报道的小麦梭条斑花叶病毒（ＷＳＳＭＶ）,另一种是日本报道的小麦黄花叶病毒（ＷＹＭＶ）。这两种病毒粒子形态以及血清学性质非常相似,但核酸序列存在一定差异。经反转录聚合酶链反应（ＲＴＰＣＲ）和单链构象多态性分析（ＳＳＣＰ）,明确我国广泛发生的禾谷多粘菌传线状小麦花叶病毒都是小麦黄花叶病毒,但供试的８个分离物ＲＮＡ１和ＲＮＡ２序列存在差异,无一彼此完全相同     

Detection of citrus yellow mosaic virus by PCR and nucleic acid spot hybridisation using non-radioactive probes in commercial citrus species

Citrus yellow mosaic virus (CYMV) was detected by polymerase chain reaction (PCR) in leaf samples of sweet orange, Rangpurlime, Pumello pink and acid lime and also in twig bark, fruit rind, fruit juice except fruit rag of sweet orange cv. Sathgudi, where all the positive samples showed bright amplification of the 726 bp band except in fruit rind. The CYMV could be detected by the biotin labelled probe of CYMV up to 1:100 dilutions by TE and TNE extraction methods in sweet orange cv. Sathgudi as well as Rangpurlime.     

Effects of turnip mosaic virus and turnip yellow mosaic virus on the survival, growth and reproduction of wild cabbage (Brassica oleracea)

Wild plants of Brassica oleracea (wild cabbage) are commonly infected with turnip mosaic poty virus (TuMV), turnip yellow mosaic tymovirus (TYMV) and several other viruses. A field experiment in which plants were inoculated either with TuMV or TYMV showed that virus infection significantly reduced survival, growth and reproduction. Relative to water inoculated-controls, plants infected with TYMV had greater mortality, were shorter, had a smaller leaf area and number, showed a greater amount of damage from herbivory and chlorosis, were less likely to flower and produced fewer pods and lower total seed output. Plants infected with TuMV did not appear to be adversely affected at first; however, mortality after 18 months was higher than control plants. Although TuMV infection had no effect on the number of plants flowering, the infected plants did produce fewer pods and a lower total seed output. We conclude that both viruses can significantly affect vegetative and reproductive performance of wild cabbage and hence that introgression of virus resistance (particularly when conferred by a major gene or a transgene) from a crop might increase plant fitness in natural populations of this species. Ecological risk assessments of virus resistance transgenes must do more than survey adult plants in natural populations for the presence of the target virus. Failure to detect the virus could be due to high mortality on infection with the virus.     

Identification of polypeptide markers of barley yellow dwarf virus resistance and susceptibility genes in non-infected barley (Hordeum vulgare) plants

Summary Barley yellow dwarf (BYDV) is a group a closely related viruses which cause economic losses in a wide range of graminaceous species throughout the world. Barley plants can be protected from the effects of BYDV by the Yd2 resistance gene. Plants which contain the Yd2 gene also contain a constitutively expressed polypeptide which was not found in any plants without Yd2. Conversely, BYDV susceptible plants contain another constitutively expressed polypeptide which was not found in any of the BYDV-resistant lines examined. These two polypeptides appear to have the same molecular weight (as assessed by SDS-PAGE) and only slightly different iso-electric points. They also appear to contain an extensive range of similar antigenic determinants. Both polypeptides were found in F₁ hybrids made from resistant and susceptible plants. We suggest that these two polypeptides are the products of two allelic genes. Analysis of near-isogenic lines showed that the locus which controls the Yd2 resistance gene and the locus controlling the synthesis of the two polypeptides may be within ± 9 cM of each other. We have developed a Western blot technique which allows assessment of barley lines, 4-days after seed imbibition, for the presence of the Yd2 gene.     

Antisense RNA approach targeting Rep gene of Mungbean yellow mosaic India virus to develop resistance in soybean

The Yellow mosaic disease is caused by Mungbean yellow mosaic India virus (MYMIV) and Mungbean yellow mosaic virus (MYMV) belonging to the genus Begomovirus of the family Geminiviridae. Yellow mosaic disease (YMD) is a major constraint to the production of soybean in South-East Asia. In India, yield losses of 10–88% had been reported due to YMD of soybean. An effort has been made to generate resistant soybean plants, by a construct targeting replication initiation protein (Rep) gene sequences of MYMIV. A construct containing the sequences of Rep gene (566?bp) in antisense orientation was used to transform cotyledonary node explants of three soybean cultivars (JS 335, JS 95-60 and NRC 37). Transformation efficiencies of 0.2, 0.21 and 0.24% were obtained with three soybean cultivars, JS 335, JS 95-60 and NRC 37, respectively. The presence of transgene in T₁ plants was confirmed by polymerase chain reaction (PCR) and sequence analysis. The level of resistance was observed by challenge inoculation with the virus in T₁ lines. The inheritance of transgene showed classical Mendelian pattern in six transgenic lines.     

Durable field resistance to wheat yellow mosaic virus in transgenic wheat containing the antisense virus polymerase gene

Wheat yellow mosaic virus (WYMV) has spread rapidly and causes serious yield losses in the major wheat‐growing areas in China. Because it is vectored by the fungus‐like organism Polymyxa graminis that survives for long periods in soil, it is difficult to eliminate by conventional crop management or fungicides. There is also only limited resistance in commercial cultivars. In this research, fourteen independent transgenic events were obtained by co‐transformation with the antisense NIb8 gene (the NIb replicase of WYMV) and a selectable gene bar. Four original transgenic lines (N12, N13, N14 and N15) and an offspring line (N12‐1) showed high and durable resistance to WYMV in the field. Four resistant lines were shown to have segregated and only contain NIb8 (without bar) by PCR and herbicide resistance testing in the later generations. Line N12‐1 showed broad‐spectrum resistance to WYMV isolates from different sites in China. After growing in the infested soil, WYMV could not be detected by tissue printing and Western blot assays of transgenic wheat. The grain yield of transgenic wheat was about 10% greater than the wild‐type susceptible control. Northern blot and small RNA deep sequencing analyses showed that there was no accumulation of small interfering RNAs targeting the NIb8 gene in transgenic wheat plants, suggesting that transgene RNA silencing, a common mechanism of virus‐derived disease resistance, is not involved in the process of WYMV resistance. This durable and broad‐spectrum resistance to WYMV in transgenic wheat will be useful for alleviating the damage caused by WYMV.     

Seed transmission of turnip yellow mosaic virus in winter turnip and winter oilseed rapes

This is the first record of seed transmission of turnip yellow mosaic virus (TYMV) in oilseed and turnip rapes. The seed transmission of TYMV in a naturally infected winter turnip rape (Brassica napus var. silvestris) cultivar Perko PVH was investigated. By ELISA 1.6%, 3.2% and 8.3% seed transmission of the virus was found in seed of plants from three localities. The proportion of infected seeds produced by artificially infected plants of winter oilseed rape (Brassica napus ssp. oleifera) and winter turnip rape cultivars was determined. The virus transmission rate, expressed as the proportion of virus-infected plants which germinated from the seed was for the oilseed rape cvs Jet Neuf 0.1%, Solida 0.4%, Silesia 0.8%, Darmor 1.2%, SL-507 0.2%, SL-509 0.0% and for the winter turnip rape cv. Perko 1.5%. ELISA cannot be used in direct tests on bulk seed lots to estimate proportion of infected seed, but must be used on germinated seedlings.     

Protective action of salicylic acid against bean yellow mosaic virus infection in Vicia faba leaves

In this study, morphological, ultrastructural and physiological modifications of faba bean (Vicia faba cv Giza 461) leaves in response to bean yellow mosaic virus (BYMV) infection and salicylic acid (SA) treatments were examined. Under BYMV stress, leaves showed symptoms including severe mosaic, mottling, crinkling, size reduction and deformations. Three weeks after virus inoculation, photosynthetic rate, pigment contents and transpiration rate were significantly reduced in response to BYMV infection.

Ultrastructural investigations of BYMV-infected leaves demonstrated that most chloroplasts with increased stromal area became spherical in shape and some lost their envelopes, either partially or totally. The internal structures of chloroplast, grana and thylakoids were dilated. Two kinds of inclusions were detected in BYMV-infected leaves: straight or slightly curved bands sometimes coiled or looped at the end, and electron opaque crystals with varied shapes. BYMV-infected cells showed lower chloroplast number in comparison to the control.

Spraying of SA on faba bean leaves helped to reduce or prevent the harmful effects produced after virus infection. Application of 100 μM SA three days before inoculation restored the metabolism of infected leaves to the levels of healthy controls. SA treatment improved plant health by increasing the photosynthesis rates, pigment contents and levels of other parameters studied similar to control values.

Moreover, SA treatment increased plant resistance against BYMV. This was observed through induction of chloroplast number, reduction in percentage of infected plants, decrease in disease severity and virus concentration of plants treated with SA prior to BYMV inoculation. Cells of SA-treated samples showed well-developed chloroplasts with many starch grains and well-organized cell organelles.

The present results provide an overview of the negative effects on faba bean leaves due to BYMV infection from physiological and subcellular perspectives. Also, a role of SA involved in induction of resistance against BYMV infection in bean plants is discussed.     

Transmission of Zucchini yellow mosaic virus by Colonizing and Non-colonizing Aphids in Greece and New Aphid Species Vectors of the Virus

Nineteen aphid species were tested for their ability to transmit Zucchini yellow mosaic virus (ZYMV) from and to zucchini under laboratory conditions. Sixteen species were found to be new vectors of ZYMV (i.e. Aphis craccae, Aphis fabae, Aphis nerii, Aulacorthum solani, Brachycaudus cardui, Brevicoryne brassicae, Hyalopterus pruni complex, Hyperomyzus lactucae, Macrosiphoniella sanborni, Macrosiphum rosae, Metopolophium dirhodum, Myzus cerasi, Rhopalosiphum maidis, R. padi, Semiaphis dauci and Sipha maydis). Their transmission efficiency by a single aphid was low (0.1–4.2%). Myzus persicae was used as a control and was the most efficient vector (41.1%, one aphid per plant). Hayhurstia atriplicis, Myzus ascalonicus and Sitobion avenae did not transmit the virus. In four out of six new vectors assayed in arena tests for propensity estimation, propensity was higher than efficiency. Data from an experimental zucchini field in northern Greece revealed a high correlation between ZYMV spread and alatae of the vector species. The most abundant aphid vectors during 2 years experimentation were M. persicae, Aphis gossypii and Aphis spiraecola. The possible role of the 16 new and the previously known aphid vectors in the epidemiology of ZYMV was investigated using data of transmission efficiency combined with the captures of their alatae in the Greek net of a Rothamsted type suction trap.     

Production of Bean yellow mosaic virus resistant subterranean clover (Trifolium subterraneum) plants by transformation with the virus coat protein gene

Transgenic lines of subterranean clover were constructed that contained three different Bean yellow mosaic virus (BYMV) coat protein (CP) gene constructs; full-length CP, the core region of the CP, and full-length CP plus the 3′ untranslated region of the viral genome. Transgenic plants containing the full-length and core CP gene constructs showed high and moderate levels of BYMV resistance. Resistance was measured as a lack or amelioration of viral disease symptoms, which was correlated with a reduction in virus levels and yield loss. A range of different resistance phenotypes was observed. They included reduced infection rates, delay and reduction in local lesion development, and delay and reduction in severity of systemic symptom development. Resistance levels were not correlated with transgene mRNA levels and no transgene-encoded protein was detected in any of the transgenic lines. This is the first example of genetically engineered virus resistance in a clover.     

侵染节瓜的小西葫芦黄花叶病毒CP基因的克隆、表达及其抗血清的制备

通过鉴别寄主反应、病毒部分序列测定确定了采自广州白云区表现花叶、斑驳症状的节瓜上的病毒为ZYMV。采用RT PCR方法扩增和克隆了该病毒的外壳蛋白基因 ,连接到原核表达载体pET 2 2b( )上。获得的重组子pET ZCP转化大肠杆菌BL2 1(DE3)后 ,用IPTG进行诱导表达。SDS PAGE和Westernblot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 33 0kD。将融合蛋白纯化后免疫兔子 ,获得了特异性较高的抗血清。ELISA测定其效价为 1 4 0 96     

Serological and biological variations of African cassava mosaic virus, in Nigeria

To determine the occurrence of variants of African cassava mosaic virus, 316 cassava leaf samples were collected from mosaic‐affected cassava plants in 254 farmers. fields in 1997 and 1998, covering the humid forest, coastal/derived, southern Guinea and northern Guinea savannas and arid and semi‐arid agroecologies of Nigeria. The samples were tested in triple antibody sandwich enzyme‐linked immunosorbent assay using a panel of 10 monoclonal antibodies (MAbs) against the virus in which 29 reaction patterns were observed. In cluster analysis, nine serotypes were obtained at 0.80 Jaccard similarity coefficient index in which at least 50% of isolates of each serotype reacted alike. The serotypes ranged between two extremes: serotype 1 with 90% isolates reacting with the 10 MAbs and serotype 8 in which 90% of its isolates failed to react with the antibodies. Isolates of serotypes 1, 2, 4 and 8 were widely distributed while those of the other serotypes were estricted to certain agroecologies. Four representative isolates 227 (serotype 1), 231 (serotype 2), 235 and 283 (serotype 8) elicited different responses in Nicotiana, benthamiana, with isolate 283 not able to infect this and other test plants used. The serological variations did not necessarily reflect the biological variations. In polymerase chain reaction tests, one out of the five pairs of ACMV primers tested distinguished only isolate 283. The humid forest, derived/coastal and southern Guinea savannas where most of the crop is grown in Nigeria had a high number of variants, which makes the agroecologies suitable for the selection of resistant cassava clones against ACMV.