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1.
通过禾谷多粘菌Polymyxa graminis L.休眠孢子分离接种感病大麦品种,并进行砂培养,获得13个纯化了的禾谷多粘菌分离物,且其中3个带有大麦黄花叶病毒(BaYMV)。用分别带有BaYMV和大麦温和花叶病毒(BMMV)的英国禾谷多粘菌分离物的游动孢子接种13个中国大麦品种,以及用BaMMV摩擦接种36个中外大麦品种,抗性鉴定结果游动孢子接种与摩擦接种一样,均与田间鉴定结果一致,且大麦对BaYMV的抗性与对BaMMV的抗性一致,从而这2种接种方法可用于大麦品种(系)和育种中间体对BaYMV抗性的快速鉴定和筛选。游动孢子或休眠孢子接种方法还可有效地鉴定大麦对禾谷多粘菌的抗性。 相似文献
2.
Djabbar Hariri Michel Meyer Hayat Prud'homme 《European journal of plant pathology / European Foundation for Plant Pathology》2003,109(9):921-928
In March 2002 in a French field, severe mosaic symptoms appeared on plants of the barley cultivar Tokyo with the rym5 locus controlling resistance to all European strains of barley yellow mosaic virus (BaYMV) and barley mild mosaic virus (BaMMV). Electron microscopic examination revealed that the disease symptoms were associated with the presence of flexuous particles which resemble bymoviruses. From these observations and after enzyme-linked immunosorbent assay analysis it was first determined that the plants could be infected by BaMMV and BaYMV. Mechanical transmission of these viruses to the barley cultivar Magie susceptible to both viruses was only possible for BaMMV. This new pathotype (BaMMV-Sil) from Sillery (Marne Department, 51, France), in contrast to another mechanically transmitted French BaMMV isolate (BaMMV-MF), could be transmitted mechanically to two barley cultivars (Tokyo, Misato Golden), Arachis hypogaea, Datura stramonium and Lactuca sativa. BaMMV-Sil was indistinguishable from three BaMMV isolates from Germany (G), Japan (Ka1) and France (PF) by monoclonal antibodies in ELISA while the Japanese isolate (Na1) and BaMMV-MF were distinguishable from all. The sequence of the 3-terminal region of BaMMV-Sil RNA1 was determined. Comparison with previously published sequence data of capsid proteins indicated that BaMMV-Sil was closely related to BaMMV-Ka1, BaMMV-G and another German isolate (BaMMV-ASL1). Resistance-breaking BaMMV strains able to infect cultivars carrying the rym5 locus have also been described in Japan (BaMMV-Na1) and Korea (BaMMV-Kor). No specific amino acid differences were detected between the capsid proteins of BaMMV-Sil, BaMMV-Na1, BaMMV-Kor and those BaMMV isolates that do not overcome the rym5 resistance gene. These results indicate that BaMMV-Sil is a new pathotype of BaMMV in France and suggests that the capsid protein is not the determining factor of the pathogenicity towards the resistance gene rym5. 相似文献
3.
ABSTRACT Soilborne wheat mosaic virus (SBWMV) is an agronomically important pathogen of wheat that is transmitted by the soilborne plasmodiophorid vector Polymyxa graminis. In the laboratory, attempts to generate SBWMV-infected plants are often hampered by poor infectivity of the virus. To analyze the mechanism for virus resistance in wheat cultivars, we developed novel inoculation techniques. A new technique for foliar inoculation of SBWMV was developed that eliminated wound-induced necrosis normally associated with rub inoculating virus to wheat leaves. This new technique is important because we can now uniformly inoculate plants in the laboratory for studies of host resistance mechanisms in the inoculated leaf. Additionally, wheat plants were grown hydroponically in seed germination pouches and their roots were inoculated with SBWMV either by placing P. graminis-infested root material in the pouch or by mechanically inoculating the roots with purified virus. The susceptibility of one SBWMV susceptible and three field resistant wheat cultivars were analyzed following inoculation of plants using these novel inoculation techniques or the conventional inoculation technique of growing plants in P. graminis-infested soil. The results presented in this study suggest that virus resistance in wheat likely functions in the roots to block virus infection. 相似文献
4.
5.
D. Hariri M. Meyer J. Le Gouis N. Bahrman M. Fouchard C. Forget A. Andre 《European journal of plant pathology / European Foundation for Plant Pathology》2000,106(4):365-372
The reaction of thirty-four barley cultivars from European and Asiatic origin was analysed in six soils infected with barley yellow mosaic virus complex (BaYMV, BaMMV). These soils were selected from 16 sites for their differences in cultivar response. Amongst the six cultivars carrying the ym4 gene (Esterel, Express, Labéa, Majestic, Réjane, Vanoise), only cv Majestic was infected at one site with BaYMV and BaMMV. Concerning BaYMV, three cultivars were infected on all the soils and 19 on none of them. Twelve cultivars were differentially infected depending on the soil. In the case of BaMMV, four cultivars were infected on all the soils and 19 on none of them. Eleven cultivars were differentially infected depending on the soil. ELISA tests revealed the presence, in these soils, of variants of BaYMV and BaMMV that were able to overcome at least seven of the 12 known resistance genes (ym3, ym4, ym6, ym8, ym9, ym10, ym11) and the resistance of three varieties (Tosan Kawa 73, OU1 and Taihoku A) in which the genetic basis is unknown. Amplification by RT-PCR of the N-terminal region for three of BaYMV variants was performed. Nucleotide and amino acid sequences were determined and compared with the corresponding sequence of a common strain of BaYMV-G. A few nucleotide differences were detected between all the French isolates, but there were no strain specific amino acid differences. 相似文献
6.
Twenty plants of alfalfa cv. Beaver were screened for resistance to alfalfa mosaic virus (AIMV) severe strain A-515. ELISA screening on both inoculated and apical leaves at fixed temperature (20°C day, 16°C night) suggested the following three types of clonal response to AIMV infection: extremely resistant, AIMV not normally detected from either inoculated or apical leaves; resistant, AIMV detected from inoculated leaves only and did not spread systemically; susceptible, AIMV detected from both inoculated and apical leaves. When plants in the second category were maintained at high temperature (30°C), AIMV was detected from inoculated and apical leaves 6 and 12 days after inoculation, but was not detectable in the apical leaves thereafter. Plants in the first category remained extremely resistant at all temperatures tested. The results of comparative tests using progeny plants of extremely resistant, resistant and susceptible plants, and of their hybrids, suggested that the resistance to AIMV A-515 was controlled by a temperature-dependent recessive gene. 相似文献
7.
M. J. ADAMS 《Plant pathology》1991,40(1):53-58
Improved diagnosis of barley yellow mosaic (BaYMV) and barley mild mosaic (BaMMV) viruses was obtained by adjusting the buffers used in immunospecific electron microscopy (ISEM) to ensure a pH ≥ 7-0 and in ELISA by replacing ovalbumin with 10 g/l full cream milk powder.
Over 70% of samples of winter barley with symptoms of mosaic received from different sites in the UK during 1987-90 had BaYMV and 37% had BaMMV, with 11% containing both viruses. BaMMV was much more common on malting cultivars than on those grown for feed and this resulted in an easterly bias to the geographical distribution of the virus. Both viruses were, however, widely distributed in areas where winter barley is grown intensively. A small number of BaYMV records were from cultivars previously regarded as resistant and these are probably a distinct strain of the virus. 相似文献
Over 70% of samples of winter barley with symptoms of mosaic received from different sites in the UK during 1987-90 had BaYMV and 37% had BaMMV, with 11% containing both viruses. BaMMV was much more common on malting cultivars than on those grown for feed and this resulted in an easterly bias to the geographical distribution of the virus. Both viruses were, however, widely distributed in areas where winter barley is grown intensively. A small number of BaYMV records were from cultivars previously regarded as resistant and these are probably a distinct strain of the virus. 相似文献
8.
Nazli D. Kutluk Yilmaz Rebecca L. Lyons Madeleine J. Smith Kostya Kanyuka 《European journal of plant pathology / European Foundation for Plant Pathology》2011,130(1):59-72
Polymyxa graminis is the vector of several important viruses, including Soilborne cereal mosaic virus, Wheat spindle streak mosaic virus, Barley yellow mosaic virus and Barley mild mosaic virus, of winter cereals worldwide. Surveys were carried out to detect these viruses and their vector P. graminis in 300 soil samples from the main wheat and barley production areas of the Anatolian part of Turkey collected in May 2002,
June 2004 and May 2005. For these surveys, various susceptible wheat and barley cultivars were pot grown in the collected
soil samples in a greenhouse and then analysed using ELISA and RT-PCR to detect the presence of different virus species. In
addition, a combination of light microscopy following roots staining with acid fuchsin and PCR was used for detection of P. graminis. All soil samples analysed were found to be free of these soilborne viruses and their vector. 相似文献
9.
Serological relationships between five fungally transmitted cereal viruses and other elongated viruses 总被引:2,自引:0,他引:2
F(ab')2 and protein A ELISA tests were used to investigate the serological affinities of five fungally transmitted cereal viruses: barley yellow mosaic (BaYMV), barley mild mosaic (BaMMV), oat mosaic (OMV), wheat yellow mosaic (WYMV) and oat golden stripe (OGSV). Within this group only BaYMV and WYMV were related. Chinese and UK isolates of BaYMV appeared to be similar. In tests using antisera to 29 other elongated viruses, BaYMV was related to one isolate of bean yellow mosaic poty virus (BYMV-G) and OGSV had affinities with BYMV-G, potato virus M, red clover vein mosaic (both carlaviruses) and perhaps Hordeum mosaic virus. The results were confirmed in immunoelectron microscopic tests. No affinities were found for BaMMV, OMV or WYMV. 相似文献
10.
用A蛋白免疫电镜技术,检测大麦病汁液中的大麦黄花叶病毒(BaYMV),其捕获抗血清的适宜工作浓度范围很宽,320-20,480倍均能达到满意的结果;抗原孵育条件以室温(约25℃)下30分钟或冰箱(约4℃)中3小时,捕获到的病毒粒子数量较多。应用这项技术,在稀释3,125倍的病汁液中还能检测到BaYMV粒子,比普通免疫电镜方法的灵敏度至少高5倍。BaYMV在病株中的分布以症状明显的花叶中含量最高,黄化叶中较少,茎和根中找不到病毒。利用该技术可以快速而灵敏地进行大麦品种抗病性的鉴定与筛选。本文最后还讨论了BaYMV的稳定性。 相似文献
11.
在实验室中利用灰飞虱接种小麦时出现一种新的病毒病症状,鉴定表明其病原为大麦黄条点花叶病毒(Barley yellow striate mosaic virus, BYSMV)。采用生物学测定、电镜观察、RT-PCR检测和序列分析的方法,明确了该病毒的粒体特性、危害症状及田间发生情况。接种试验表明该病毒通过灰飞虱传播,接种7~10 d后小麦新生叶片出现黄色斑点、斑驳,继而发展成黄色条纹,叶片对生且细而窄,重病株新叶扭曲,叶鞘不能伸长,病株矮化。对小麦病叶超薄切片电镜观察,发现细胞质中存在大量弹状病毒粒子,病毒粒体大小为(315~353)nm×(46~57) nm。利用特异性引物从病株总RNA中扩增出 565 bp基因片段,序列同源性分析显示与大麦黄条点花叶病毒(Barley yellow striate mosaic virus, BYSMV) Zanjan-1分离物聚合酶(L)基因对应序列的一致性为97 %,与北方禾谷花叶病毒(Northern cereal mosaic virus, NCMV) L基因对应序列的一致性为78 %~79 %。对采自河北邯郸、石家庄、保定、唐山的31株样品进行RT-PCR检测,25株检测到BYSMV,7株检测到水稻黑条矮缩病毒(Rice black streaked dwarf virus,RBSDV),其中5株为2种病毒复合侵染,结果表明BYSMV的田间分布较广。系统发育分析表明BYSMV-Lab/TS/ZX/QY 4个分离物与本研究的BYSMV亲缘关系密切。BYSMV是我国小麦上新发现的一种弹状病毒,并已形成危害,暂定名为小麦黄条纹矮缩病,应加强流行动态监测。 相似文献
12.
发生在我国的小麦黄花叶病毒病 总被引:6,自引:0,他引:6
本文对山东荣成流行的一种小麦病毒病进行了鉴定。提纯的病毒颗粒为长线状,13×100—300nm及13×350—650nm。汁液接种感染小麦,但不感染烟草、苋色藜等植物。病土、病根以及含有禾谷类多粘菌(POlymyxa graminis)游动孢子的浸液可以传毒于小麦、大麦及黑麦。此病毒与大麦黄花叶病毒(BYMV)、小麦梭条花叶病毒(WSSMV)有血清学关系,与小麦土传花叶病毒(WSBMV)无血清学关系。病叶表皮细胞中有无定形内含体。超薄切片可见风轮状内含体。实验结果表明,荣城地区发生的这种小麦病毒病是小麦黄花叶病毒所致。 相似文献
13.
S. J. Baker A. C. Newton D. Crabb D. C. Guy R. A. Jefferies D. K. L. Mackerron W. T. B. Thomas & S. J. Gurr 《Plant pathology》1998,47(4):401-410
This study, carried out under field conditions, assessed the extent to which temporary breakdown of mlo- resistance, following relief of water-stress, was determined by genetic background and mlo allele. Commercial barley cultivars expressing the mlo gene for resistance to powdery mildew ( Erysiphe graminis ( Blumeria graminis ) f.sp. hordei ) were tested as well as doubled haploid progeny from spring barley genotypes, a proportion of which were sown in the field in two successive years. Plants were protected from natural rain by a mobile rain shelter and either watered by trickle-irrigation or allowed to dry. Percentage mildew infection resulting from natural inoculum was recorded and the doubled haploid genotypes were classified as resistant, intermediate or susceptible on the basis of their control (watered) treatment scores. In each of the three designated classes, particular genotypes developed infection levels, following relief of water-stress, that were higher than those observed on the well-watered controls. This was found not to be related to the mlo allele as there was no significant difference between the increases observed on resistant plants carrying mlo9 and resistant plants carrying mlo11 . Differences in the degree of breakdown of resistance were attributed to genetic background rather than to the specific mlo allele. 相似文献
14.
K. Kanyuka † D. J. Lovell O. P. Mitrofanova K. Hammond-Kosack M. J. Adams 《Plant pathology》2004,53(2):154-160
Several wheat genotypes, including eight with known field responses, were evaluated for their reaction to Soil-borne cereal mosaic virus (SBCMV, genus Furovirus) by growing in naturally infested soil under controlled environment conditions. Virus antigen titres in the foliage 8–9 weeks after sowing mostly reflected the field responses, showing that growth chamber-based tests can be used to improve the speed and reliability of germplasm screening. Such tests were used to determine the mode of inheritance of the SBCMV resistance in cv. Cadenza, commonly used in UK wheat-breeding programmes. One hundred and eleven doubled haploid (DH) lines derived from an F 1 of a cross between cvs Cadenza (resistant) and Avalon (susceptible) were evaluated. This DH population segregated for the reaction to SBCMV in a ratio of 1 : 1 (resistant : susceptible). This suggests that the SBCMV resistance is controlled by a single gene locus. As a first step towards identification of new sources of improved SBCMV resistance (e.g. immunity) as well as sources of the resistance to the virus vector, Polymyxa graminis , a set of 26 Triticum monococcum lines of diverse geographical origin was also screened. Most lines were susceptible to SBCMV, but one line of Bulgarian origin was resistant to the virus and possibly partially resistant to the virus vector. 相似文献
15.
Indian peanut clump virus (IPCV) infection on wheat and barley: symptoms, yield loss and transmission through seed 总被引:1,自引:0,他引:1
Wheat and barley crops were shown to be susceptible to Indian peanut clump virus (IPCV) under field conditions. In wheat, the Hyderabad isolate of IPCV (IPCV-H) induced symptoms resembling the rosette caused by soil-borne wheat mosaic virus, and these were apparent only three weeks after emergence. Early-infected plants were severely stunted and dark green, with chlorotic streaks on the youngest leaves, which turned necrotic as the plants aged; most of these plants died. Late-infected plants were also stunted and were conspicuous in the field because of their dark green appearance as a result of delayed maturity. The virus was detected by ELISA and nucleic acid hybridization in all plants with symptoms. These plants usually produced fewer tillers than healthy ones. Spikes were malformed, often did not emerge from the flag leaf, and they contained few, shrivelled seeds. Grain yield was decreased, on average, by 58%. In barley, IPCV-H caused severe stunting and general leaf chlorosis. As the plants aged, the leaves became necrotic and the few infected plants that reached maturity produced small spikes. IPCV-H antigens were detected by ELISA in every wheat seed from infected plants and the virus was transmitted through wheat seed at a frequency of 0.5–1.3%. Storage at 4°C for more than a year did not affect seed transmission frequency. The virus was detected in leaves and roots of seed-transmitted plants. Seed transmission was not detected in barley. The Durgapura isolate (IPCV-D) was detected in wheat crops (cv. RR-21) at 3 different locations in Rajasthan State, India. Infected plants showed reduced growth without any overt symptoms. 相似文献
16.
In Germany the furovirus Soil-borne cereal mosaic virus (SBCMV) and the bymovirus Wheat spindle streak mosaic virus (WSSMV) occur often together particularly in several rye production areas. Soil-borne wheat mosaic virus (SBWMV), a wheat infecting furovirus, has so far been found only in one field near Heidelberg. Each of these viruses is transmitted by Polymyxa graminis. The cultivation of resistant varieties is the only promising measure to prevent yield losses caused by soil-borne viruses. Resistance of wheat against the bymovirus WSSMV is comparable to the immunity of barley to the bymoviruses Barley yellow mosaic virus and Barley mild mosaic virus. In case of immunity no virus multiplication is observed in resistant cultivars. In contrast, all wheat cultivars are hosts of the furoviruses. All cultivars – including the resistant ones – can be infected following mechanical inoculation with SBWMV and SBCMV. Resistance to furoviruses is based on reduced levels of virus multiplication in roots and on inhibition of virus movement from roots to leaves. Because of the inhibited virus movement from roots to aerial parts of plants this type of resistance is referred to as translocation resistance. In spite of the different resistance mechanisms the absence of virus symptoms on the leaves is a common selection criterion for both immunity and translocation resistance. Therefore, the symptom free development of plants on uniformly infested fields is the best criterion for selecting wheat lines with resistance to soil-borne viruses. The limited suitability of other selection methods is discussed. 相似文献
17.
A virus having tubular particles (124, 142 and 167 nm) was manually transmitted from and to Anthoxanthum odoratum (sweet vernal grass). Other experimental hosts were Chenopodium quinoa, C. amaranticolor, Zea mays, Avena sativa and Hordeum vulgare (barley); winter cultivars of barley were more often infected than spring cultivars. In tests which simulated mechanical injury, the virus was transmitted from infected to healthy A. odoratum but not to healthy barley. The virus particles, which were seen as aggregates in the cytoplasm of A. odoratum leaf cells and in anther walls, reacted strongly in immunosorbent electron microscopy tests with antisera to strains of barley stripe mosaic hordeivirus. Nevertheless, the virus could be distinguished from the Type strain of barley stripe mosaic virus by reciprocal serological tests and by symptoms in infected barley cv. Black Hulless. Using an antiserum produced against the virus, a survey of A. odoratum in the field revealed one of 72 tested plants to be naturally infected. The virus is probably that described by Catherall & Chamberlain (1980) and named anthoxanthum latent blanching virus. 相似文献
18.
ABSTRACT Soilborne wheat mosaic virus (SBWMV) and Wheat spindle streak mosaic virus (WSSMV) are putatively transmitted to small grains by the obligate parasite Polymyxa graminis, but little is known about environmental requirements for transmission and the resulting disease incidence. We planted susceptible wheat and triticale cultivars in field nurseries on different autumn dates in 3 years and observed the incidence of symptomatic plants in each following spring. Autumn postplanting environment explained most of the variation in disease caused by both viruses. Little apparent transmission, based on eventual symptom development, of either virus occurred after the average soil temperature dropped below 7 degrees C for the remainder of the winter. To forecast disease, we tested an SBWMV transmission model in the field, based on laboratory results, that predicts opportunities for transmission based on soil temperature and soil moisture being simultaneously conducive. This model was predictive of soilborne wheat mosaic in 2 of 3 years. Zoospores of P. graminis have optimal activity at temperatures similar to those in the SBWMV transmission model. Furthermore, the matric potential threshold (as it relates to waterfilled pore sizes) in the SBWMV transmission model fits well with P. graminis as vector given the size restrictions of P. graminis zoospores. Conditions optimal for SBWMV transmission in the laboratory were not conducive for WSSMV transmission in the laboratory or for wheat spindle streak mosaic development in the field. This differential response to environment after emergence, as indicated by disease symptoms, may be due to virus-specific environmental conditions required to establish systemic infection via the same vector. Alternatively, the differential response may have been due to the involvement of a different vector in our WSSMV nursery than in our SBWMV nursery. Our results suggest that, as a control tactic for SBWMV or WSSMV, earliness or lateness of planting is less important in determining virus transmission and disease than the specific postplanting environment. Improved models based on the postplanting environment might predict virus-induced losses of yield potential, and in some cases, growers might avoid purchase of spring inputs such as pesticides and fertilizer for fields with greatly reduced yield potential. 相似文献
19.
ABSTRACT Sexual forms of two genotypes of the aphid Schizaphis graminum, one a vector, the other a nonvector of two viruses that cause barley yellow dwarf disease (Barley yellow dwarf virus [BYDV]-SGV, luteovirus and Cereal yellow dwarf virus-RPV, polerovirus), were mated to generate F1 and F2 populations. Segregation of the transmission phenotype for both viruses in the F1 and F2 populations indicated that the transmission phenotype is under genetic control and that the parents are heterozygous for genes involved in transmission. The ability to transmit both viruses was correlated within the F1 and F2 populations, suggesting that a major gene or linked genes regulate the transmission. However, individual hybrid genotypes differed significantly in their ability to transmit each virus, indicating that in addition to a major gene, minor genes can affect the transmission of each virus independently. Gut and salivary gland associated transmission barriers were identified in the nonvector parent and some progeny, while other progeny possessed only a gut barrier or a salivary gland barrier. Hemolymph factors do not appear to be involved in determining the transmission phenotype. These results provide direct evidence that aphid transmission of luteoviruses is genetically regulated in the insect and that the tissue-specific barriers to virus transmission are not genetically linked. 相似文献
20.
W. HUTH 《EPPO Bulletin》1989,19(3):547-553
During the last ten years yellow mosaic of barley has been spreading more and more in European countries and in some infested areas yield loss can only be prevented by growing resistant cultivars. Breeding of such cultivars is one of the most important goals of small-grain breeders. To select resistant cultivars, several methods are available such as mechanical inoculation, growing of plants in infested soil in the field or in growth chambers as well as using root powder of infected plants. The situation has recently been complicated by the discovery that yellow mosaic is caused by at least two distinct but closely related viruses (barley yellow mosaic virus and barley mild mosaic virus). Inoculation methods are not equally effective for these two viruses. Although it appeared initially that resistance to the two viruses was linked, there are now indications that some barley cultivars respond differently, and there may even be a third virus involved. Programmes for selection of resistant cultivars now have to take account of this. 相似文献