黄淮地区小麦品种对小麦黄花叶病毒抗性评价

小麦黄花叶病是由禾谷多黏菌传播的小麦黄花叶病毒引起的病害,近年在黄淮麦区呈蔓延加重趋势。为了给病害的防治和抗病育种工作提供依据,本研究利用分级评价方法对黄淮地区推广的小麦品种进行了田间抗病性鉴定。两年鉴定结果表明,在145个供试小麦品种中,‘濮优938’、‘新麦208’、‘豫麦416’、‘新原958’、‘豫麦70-36’、‘泛麦5号’等70个品种表现为免疫,占总数的48.28%;‘豫麦47’和‘邯6172’表现为抗病,占总数的1.38%;‘洪育2号’、‘花培2号’、‘偃展4110’、‘豫麦41’、‘郑麦9023’等48个品种表现为中抗,占总数的33.10%;‘兰天06129’、‘兰天0591’、‘徐麦9158’、‘徐麦0054’、‘徐麦1108’等25个品种表现为感病,占总数的17.24%。研究结果为指导小麦黄花叶病区合理选择小麦品种提供了科学依据。     

Occurrence of barley yellow mosaic and barley mild mosaic bymoviruses in Greece

In March 1991, large chlorotic patches appeared in an autumn-sown barley crop growing near Thessaloniki, Greece. Leaves had characteristic mosaic symptoms and immunosorbent electron microscopy and enzyme-linked immunosorbent assay confirmed the presence of both soil-borne mosaic viruses of barley, barley mild mosaic and barley yellow mosaic bymoviruses. In the following year, similar symptoms appeared in a crop at Souroti, 30 km east of Thessaloniki but the disease has not been found in other areas of Macedonia. This report is the first record of these viruses from Greece and is the most southerly European record.     

The occurrence of two strains of barley yellow mosaic virus in England

Samenvatting Een aantal isolaten van het gerstegeelmozaïekvirus, afkomstig van verschillende plaatsen in Engeland, werden met elkaar vergeleken. Uit de resultaten, verkregen met ELISA, goudmerking en mechanische overdracht, kan worden geconcludeerd, dat tenminste twee stammen van het virus in Engeland voorkomen. Deze stammen zijn, wat betreft de wijze van overdracht en de serologische eigenschappen, gelijk aan die welke in de Duitse Bondsrepubliek zijn beschreven.     

The distribution of barley yellow mosaic virus (BaYMV) and barley mild mosaic virus (BaMMV) in UK winter barley samples, 1987-1990

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.     

National and local spread of barley yellow mosaic virus in the United Kingdom1

Barley yellow mosaic virus was first reported in the United Kingdom in 1980. Since then cumulative records of reports of disease, confirmed at the laboratory of the Agricultural Development and Advisory Service of the Ministry of Agriculture, Fisheries and Food, show how infection has spread from the east of England where it first occurred in quantity, to the west. Areas of concentrated infection appear to relate to areas of intensive winter-barley cultivation. Records suggest that infection may have occurred as early as 1976. Patterns of local spread in fields as defined in aerial photographs reflect the means by which the viruliferous vector may be passively moved in the soil. Other patterns reflect previous cropping. The higher frequency of infection on the sites of long-removed hedgerows is not explained.     

RNA/cDNA hybridization studies of UK isolates of barley yellow mosaic virus

The RNA components of two isolates of BaYMV from Streatley and Wiltshire were analysed by agarose gel electrophoresis. Northern blots of extracts of both isolates analysed with random-primed cDNA probes to RNA1 and 2 of the Streatley isolate showed little or no sequence homologies between the two isolates, confirming other evidence that they should be considered as different viruses.     

河南省主要推广品种对小麦黄花叶病毒抗性的评价

为了评价河南省主要推广品种对小麦黄花叶病毒(Wheat yellow mosaic virus, WYMV)的抗性,于2006—2010年在河南省西平县病圃进行了田间抗性鉴定试验和室内间接ELISA检测,并分析了病害严重程度对产量的影响。结果表明,在供试的62个品种中,仅有新麦208表现为免疫;豫麦70-36、泛麦5号、阜麦936、山东95519、豫麦70、高优503、豫麦9676、郑麦366和陕麦229等9个品种表现为抗病,占供试品种的14.5%;濮优938、兰考矮早8、新原958、花培2号、温优1号、豫麦18、郑麦9023、豫麦47、豫农201、偃展4110、豫麦36、百农878和豫麦49-198等13个品种表现为中抗,占供试品种的21.0%;另外39个品种表现为感病,占供试品种的62.9%。对48个品种进行了产量与病害严重度分析,发现随着病害的严重度增加,小麦的穗数、千粒重以及产量都有明显下降,严重度为1级时,平均减产9.6%;严重度达到2级和3级时,平均减产分别为30.3%和33.5%。     

Present state and prospects of breeding for resistance or immunity to barley yellow mosaic virus1

The BaYMV resistance of German cultivars like Diana, Franka, Gloria or Sonate is due to one recessive gene (‘German gene’), located on barley chromosome 3. This gene and the gene Ym1 are most probably allelic (or tightly linked). Resistance of the American cv. Anson barley is inherited independently of the ‘German gene’ and Ym1. The haploidy technique is an efficient means for approaching major breeding goals: (1) to improve quality characteristics of cultivars carrying‘German resistance' (2) to adapt exotic germplasm carrying the gene Yml to European growing conditions; (3) to broaden the genetic base of BaYMV resistance by incorporating additional ‘new’ resistance genes.     

Identification of barley yellow mosaic virus by immuno-electron microscopy in barley but not in Polymyxa graminis or Lagena radicicola

Samenvatting Gerstegeelmozaïekvirus (BaYMV) werd in een perceel wintergerst (cv. Igri) gevonden by Wittem in Limburg, Nederland. Het virus werd met immuno-elektronen-microscopie geïdentificeerd in bladweefsel als BaYMV. In de wortels van geïnfecteerde planten werden alle vormen die van de schimmel-vector (Polymyxa graminis Led.) bekend zijn aangetroffen nl. cystosori, plasmodia en zoosporangia. Inwendig kon geen BaYMV worden aangetoond of waargenomen inPolymyxa ofLagena spp.Cooperative investigation of the ARS, USDA, the Nebraska Agricultural Experiment Station, and the Plant Protection Service, Wageningen. Research conducted under Project 21-12. Published as Paper No. 7787, Journal Series, Nebraska Agricultural experiment Station. Mention of a trademark or proprietary product does not constitute a guarantee or warranty by the U.S. Department of Agriculture and does not imply its approval to the exclusion of other products that may also be suitable.     

The effects of infection by barley yellow mosaic virus on the yield and components of yield of barley

Infection by barley yellow mosaic virus (BaYMV) was greater in a crop sown in October than in November and in cv. Maris Otter than in cv. Sonja. However, a greater proportion of plants of Sonja than of Maris Otter were infected, and more severely, with the soil-borne fungus vector of BaYMV. Polymyxagraminis. Indifferent years the yield of individual plants of Maris Otter was decreased by 15% and of Sonja by 40%. The spring barley cultivars Athos. Porthos. Georgie and Ark Royal were all infected with BaYMV when sown in autumn in infected soil. Infected winter barley cv. Igri lost up to 50% of yield when this was measured across a naturally infected patch of crop.     

Possibility of Bean yellow mosaic virus detection in Gladiolus plants by different methods

Journal of Plant Diseases and Protection - Serological and molecular methods were compared for the detection of Bean yellow mosaic virus (BYMV) in gladiolus plants. Plants showing mosaic symptoms...     

The identification of bean mosaic,pea yellow mosaic and pea necrosis strains of bean yellow mosaic virus

Twelve virus isolates from pea, broad bean, red clover and yellow lupin have been compared with the B25 strain of bean yellow mosaic virus (BYMV-B25), the E198 strain of pea mosaic virus (PMV-E198) and the pea necrosis virus (E178), which were described earlier (Bos, 1970).On the basis of host ranges, symptoms and bean and pea varietal reactions most isolates could be classified into three groups, representatives of which did not differ appreciably serologically. These groups were considered to be typicalbean yellow mosaic virus isolates (E212, L1, B25),pea yellow mosaic strain isolates of BYMV (E198, E204, Kow28) andpea necrosis strain isolates of BYMV (E197, E199, E221). From these results and from a survey of literature it is concluded that PMV is only a strain of BYMV.The pea necrosis virus (E178), described earlier as a distinct entity, is still considered a different virus. A severe pea necrosis isolate (Kow14) resembled E178 in many respects and was also more distantly related serologically to the BYMV isolates tested. Four other virus isolates from pea and broad bean (E196, Vf15, Vf18 and Vf30) could not yet be identified. Lettuce mosaic virus (LMV) was found to be serologically rather closely related to BYMV.Results of cross-protection tests were erratic, and particle length measurements were no help in differentiating the strains and viruses studied.Samenvatting Twaalf virusisolaten uit erwt, tuinboon, rode klaver en gele lupine werden vergeleken met de eerder beschreven (Bos, 1970) B25-stam van het bonescherpmozaïekvirus (BYMV), de E198-stam van het erwtemozaïekvirus (PMV) en het erwtenecrosevirus (E178) (Tabel 1).Op grond van waardplantreeksen, symptomen en de reacties van bone- en erwterassen (Tabel 2) konden de meeste isolaten worden ingedeeld in drie groepen, waarvan vertegenwoordigers serologisch niet duidelijk verschilden (Tabel 5). Een groen erwteisolaat (E212) en een met zaad overgaand isolaat uit gele lupine (L1) bleken typische bone-isolaten van hetbonescherpmozaïekvirus, dat duidelijke symptomen veroorzaakt in de meeste bonerassen en groen mozaïek in erwt (Fig. 1A) en tuinboon. InChenopodium amaranticolor geven deze isolaten in tegenstelling tot alle andere getoetste isolaten gewoonlijk systemische symptomen, die met het lupineïsolaat zeer hevig zijn (Fig. 4A).Twee erwtegeelmozaïekisolaten (E198 en E204) en een isolaat uit rode klaver (Kow28), die geelmozaïek in erwt en tuinboon doen ontstaan en slechts milde symptomen in een deel der op het bonescherpmozaïekvirus reagerende bonerassen, werden opgevat als behorend tot deerwtegeelmozaïekstam van het bonescherpmozaïekvirus.Drie erwtenecrose-isolaten (E197, E199, E221), die necrose veroorzaken in erwt (Fig. 3) en tuinboon (Fig. 2) terwijl de bonerassen gewoonlijk overgevoelig bleken, werden beschreven alserwteecrosestammen van het bonescherpmozaïekvirus.De drie voor erwtemozaïek onvatbare erwterassen bleken immuun voor alle isolaten van het bonescherpmozaïekvirus behalve E197, dat een latente systemische infectie gaf in Relonce.Het eerder als een aparte eenheid beschreven erwtenecrosevirus (E178) gedroeg zich ook nu duidelijk verschillend van de bonescherpmozaïekvirusisolaten. Het isolaat Kow14, dat in erwt eveneens ernstige necrose veroorzaakte, leek op E178 in de necrose die werd teweeggebracht in erwt en tuinboon, in de lokale vlekken in komkommerzaadlobben en in het ontbreken van systemische necrose inLupinus angustifolius, maar de meeste bonerassen waren onvatbaar voor Kow14. Het was ook serologisch minder nauw verwant aan de onderzochte bonescherpmozaïekvirusisolaten.Vier andere virusisolaten uit erwt en tuinboon konden nog niet worden geïdentificeerd. Eén ervan (Vf18) vertoonde een unieke latente systemische infectie in alle drie mozaïekonvatbare erwterassen (Tabel 2).Resultaten van de premunitieproeven (Tabel 3) waren wisselvallig en nergens werd een volledige bescherming verkregen. Deeltjeslengtemetingen (Tabel 4) bleken niet van nut bij de onderscheiding van de onderhavige stammen en virussen.Uit de verkregen resultaten en uit een overzicht van de literatuur wordt tenslotte geconcludeerddat het erwtemozaïekvirus opgevat moet worden als een stam van het bonescherpmozaïekvirus. Het laatstgenoemde virus is tamelijk nauw verwant aan het slamozaïekvirus, zoals met een antiserum tegen dit virus werd aangetoond.De variabiliteit van het bonescherpmozaïekvirus en zijn relaties met een groep van nauw verwante virussen wordt verder besproken. Biologische eigenschappen van de onderhavige virussen hoeven niet samen te vallen met de lichamelijke eigenschappen van hun deeltjes, inclusief de serologische. De virussen en hun stammen kunnen gemakkelijk worden onderscheiden met behulp van een beperkte reeks van differentiërende waardplantsoorten (Tabel 6). Een indeling van de betrokken virussen op grond van pathogeniteit is zowel van betekenis om praktische redenen, als voor het verkrijgen van inzicht in hun ontstaan.Guest worker from May through November 1973 as a fellow of the International Agricultural Centre, Wageningen. Research worker of the Institute of Plant Genetics, Polish Academy of Sciences, Pozna, Poland.     

Effect of barley yellow dwarf virus on susceptibility of barley cultivars to net blotch (Pyrenophora teres) and leaf blotch (Rhynchosporium secalis)

The effect of barley yellow dwarf virus (BYDV) on the development of net blotch (Pyrenophora eves) and leaf blotch (Rhynchosporium secalis) was examined on seven barley cuitivars. Seedlings were infected with BYDV at the two-leaf stage (G.S. 12). Their susceptibility to three isolates of p teres and isolates of two races (U.K. 1, U.K. 2) of R. secalis was examined at the four-leaf stsge (G.S. 14) and when plants were more mature (G.S. 33/38). At G.S. 14 numbers of lesions produced by P. teres and R. secalis were reduced, on average, by 37 and 72% respectively, and at G.S. 33/38 by 61 and 74%.     

Symptom expression of yellow leaf disease in sugarcane cultivars with different degrees of infection by Sugarcane yellow leaf virus

Sugarcane yellow leaf virus (ScYLV) is present in many sugarcane growing areas of the world. It is suspected to cause yellow leaf disease (formerly called YLS, yellow leaf syndrome) of sugarcane. This study investigated symptom expression in a selection of cultivars classified into three groups; ScYLV-susceptible/infected, ScYLV-resistant and intermediately infected cultivars grown in plantation fields in the islands of Hawaii. Incidence of yellow leaf symptoms was correlated, though not tightly, to the presence of ScYLV. The correlation is based on two factors: (i) only ScYLV-infected cultivars (from both susceptible and intermediate groups) showed severe symptom expression, and (ii) ScYLV-infected plants had four times higher symptom incidence than virus-free plants of the same cultivar. The yellow leaf symptom expression fluctuated, peaking at 200, 350, 500 and 600 days after planting. These symptom peaks were correlated with an increase of ScYLV content in the intermediately infected group of cultivars. No nutritional, environmental or field factor could be identified which clearly influenced symptom expression. It is speculated that the symptom expression is elicited by assimilate backup in the stalks and that the fluctuation of symptom expression is caused by the growth rhythm of mature sugarcane stalks.     

Evaluation of Seed Transmission of Turnip yellow mosaic virus and Tobacco mosaic virus in Arabidopsis thaliana

ABSTRACT The mechanism of virus transmission through seed was studied in Arabidopsis thaliana infected with Turnip yellow mosaic virus (TYMV) and Tobacco mosaic virus (TMV). Serological and biological tests were conducted to identify the route by which the viruses reach the seed and subsequently are located in the seed. Both TYMV and TMV were detected in seed from infected plants, however only TYMV was seed-transmitted. This is the first report of transmission of TYMV in seed of A. thaliana. Estimating virus seed transmission by grow-out tests was more accurate than enzyme-linked immunosorbent assay due to the higher frequency of antigen in the seed coat than in the embryo. Virus in the seed coat did not lead to seedling infection. Thus, embryo invasion is necessary for seed transmission of TYMV in A. thaliana. Crosses between healthy and virus-infected plants indicated that TYMV from either the female or the male parent could invade the seed. Conversely, invasion from maternal tissue was the only route for TMV to invade the seed. Pollination of flowers on healthy A. thaliana with pollen from TYMV-infected plants did not result in systemic infection of healthy plants, despite TYMV being carried by pollen to the seed.     

Severe mosaic caused by zucchini yellow mosaic virus in cucurbits from Jordan

A virus disease causing severe mosaic in melon (the melon isolate) was identified as a strain of zucchini yellow mosaic virus (ZYMV). Identification was based on host range, aphid transmissibility, electron microscopy, and serological tests. The virus was recovered from all cultivated cucurbits in Jordan and from naturally infected Moluccella laevis. It was seed-transmitted in Ranunculus sardous. Host-range comparison showed that the melon isolate and a French isolate belong to a different biotype group from a Connecticut isolate (ZYMV-CT); this was confirmed by indirect ELISA. During 1987–1988. ZYMV appeared to be the predominant virus affecting cucurbits.     

First isolation of rose yellow mosaic virus in Japan

Rose yellow mosaic virus, which belongs to the Roymovirus genus in the Potyviridae family, was isolated here in Japan from a rose cultivar, Irish Mist. The full-length genomic sequence was similar to a strain in Minnesota, United States, which was the first ever isolated, with 85% nucleotide and 94% amino acid sequence similarities. Unlike the Minnesota strain, which lacks 220 nt including the 6K1 protein region, the Japanese isolate contains this coding region, which is commonly found in those of the Potyviridae.