Reservoirs of plant virus disease: Occurrence of wheat dwarf virus and barley/cereal yellow dwarf viruses in Sweden

Non-crop plants such as grasses and volunteer plants are an inseparable part of the flora of crop fields and can influence virus incidence in crop plants. The presence of grasses as virus reservoirs can lead to a higher probability of virus incidence in crop plants. However, the role of reservoirs as an inoculum source in agricultural fields has not been well studied for many viral diseases of crops. Grasses have been found to constitute potential reservoirs for cereal-infecting viruses in different parts of the world. This study revealed that cereal-infecting viruses such as wheat dwarf virus (WDV), barley yellow dwarf viruses (BYDVs), and cereal yellow dwarf virus-RPV (CYDV-RPV) can be found among ryegrass growing in or around winter wheat fields. Phylogenetic analysis showed that a WDV isolate from ryegrass was a typical WDV-E isolate that infects wheat. Similarly, a ryegrass isolate of barley yellow dwarf virus-PAV (BYDV-PAV) grouped in a clade together with other BYDV-PAV isolates. Inoculation experiments under greenhouse conditions confirmed that annual ryegrass of various genotypes can be infected with WDV to a very low titre. Moreover, leafhoppers were able to acquire WDV from infected ryegrass plants, despite the low titre, and transmit the virus to wheat, resulting in symptoms. Information from the grass reservoir may contribute to improving strategies for controlling plant virus outbreaks in the field. Knowledge of the likely levels of virus in potential reservoir plants can be used to inform decisions on insect vector control strategies and may help to prevent virus disease outbreaks in the future.     

Characterization of wheatgrass-derived barley yellow dwarf virus resistance in a wheat alien chromosome substitution line

ABSTRACT Wheatgrass (Thinopyrum intermedium) possesses a high level of resistance to barley yellow dwarf virus (BYDV) subgroup I and subgroup II strains. A wheat line (P29), in which the 7D chromosome has been substituted with a group 7 chromosome from T. intermedium, was examined for the level of resistance to two subgroup I and two subgroup II BYDV strains. In P29 plants inoculated with the subgroup I PAV strains, the titer of virus in leaf and stem tissue was typically reduced 42 to 52% when compared with the BYDV-susceptible cv. Abe. P29 and 'Abe' had the same content of PAV in roots. These results and the absence of detectable virus in inoculated T. intermedium plants indicate that the complete resistance to subgroup I possessed by the wheatgrass has not been introgressed into P29. In contrast, P29 was completely resistant throughout the plant to the subgroup II strains, NY-RPV and NY-RMV, demonstrating that the complete resistance to subgroup II in T. intermedium was incorporated into P29. Further analysis of this resistance to NY-RPV showed that NY-RPV can replicate in mesophyll protoplasts of P29 and 'Abe', suggesting that this resistance is not operating at the single-cell level. Molecular marker analysis confirmed that the T. intermedium chromosome present in P29 is a different group 7 wheatgrass chromosome than that present in L1, a wheat line with BYDV resistance properties similar to those of P29.     

Occurrence of barley yellow dwarf virus in pastures of western France

As pasture grasses are preponderant in the agriculture of western France, their role as reservoirs of barley yellow dwarf virus (BYDV) and its aphid vectors has been studied from 1984 to 1986. Aphids were observed on most crops of five pasture grass species (brome grass, cocksfoot, tall fescue, Italian and perennial ryegrass) but in very low numbers. Rhopalosiphum padi was the most numerous species. The incidence of BYDV was high, with levels of infection ranging from 6 to 80% depending on the species of pasture grasses. Fescue pastures were highly infected with BYDV, whereas the virus was not detected in cocksfoot pastures. PAV-, RPV-, MAV-like isolates of BYDV were detected in pasture grasses, but RPV- and MAV-like isolates were only detected from ryegrass and brome grass, respectively. The role of these grasses as source of viruliferous aphids infecting cereals is discussed.     

Identification of barley yellow dwarf virus and cereal aphid Infestations In winter wheat by aerial photography

In 1976 distinctive patterns were identified on aerial photographs of winter wheat crops in East Anglia. The patterns consisted of numerous dark foci which were found to be associated with sooty moulds (mostly Cladosporium spp.) in the crops. Both green and mature crops were photographed in 1977 and the patterns were matched with crop inspection data. These suggested that barley yellow dwarf virus (BYDV) was the cause of the patterns and that sooty moulds secondarily invaded the infected plants. A different type of focal pattern appeared to be associated with damage caused by aphid feeding. All crops showing the pattern associated with BYDV were sown before 13 October but there was no relationship with sowing date for the crops damaged directly by aphids. Yield losses within foci were estimated by sampling and the total crop areas affected were calculated using an image analysis computer: yield losses were estimated to range from 10% (BYDV) to 2% (aphid feeding). The epidemiology of BYDV is discussed and reasons are suggested for the development and appearance of the foci.     

大麦黄矮病毒侵染小麦miRNA鉴定和特征分析

大麦黄矮病毒(barley yellow dwarf viruses, BYDVs)引起的小麦黄矮病严重威胁我国麦类生产,造成严重经济损失。植物中的miRNA调控植物生长发育、信号转导及对外界压力的反应,通过调控植物抗性基因的表达影响植物与病原物的互作。本研究对感染BYDV-GAV后3 d、7 d及健康对照的‘小偃6号’小麦样品进行miRNA测序,合并去冗余后分别得到99、96、95个已知的miRNA序列和806、809、1 024个新miRNA序列。对这些miRNA进行差异表达分析,BYDV-GAV侵染后3 d和7 d的小麦样品,与对照相比上调表达的miRNA数量分别为3个和7个,下调表达的为14个和12个。将差异表达的miRNA利用psRNATarget进行靶基因预测,共得到1 254个靶标基因。靶基因的KEGG和GO富集分析,进一步明确了其功能及作用通路。对14个病毒病症状相关的靶基因进行定量分析,结果表明随病毒侵染时间的延长,这些靶基因出现差异性表达,显示miRNA参与了寄主与病毒的互作。研究结果有助于揭示BYDV-GAV与寄主小麦的互作机理。     

大麦黄矮病毒侵染小麦miRNA鉴定和特征分析

 大麦黄矮病毒(barley yellow dwarf viruses,BYDVs)引起的小麦黄矮病严重威胁我国麦类生产,造成严重经济损失。植物中的miRNA调控植物生长发育、信号转导及对外界压力的反应,通过调控植物抗性基因的表达影响植物与病原物的互作。本研究对感染BYDV-GAV 后3 d、7 d及健康对照的‘小偃6号'小麦样品进行miRNA测序,合并去冗余后分别得到99、96、95个已知的miRNA序列和806、809、1 024个新miRNA序列。对这些miRNA进行差异表达分析,BYDV-GAV侵染后3 d和7 d的小麦样品,与对照相比上调表达的miRNA数量分别为3个和7个,下调表达的为14个和12个。将差异表达的miRNA利用psRNATarget进行靶基因预测,共得到1 254个靶标基因。靶基因的KEGG和GO富集分析,进一步明确了其功能及作用通路。对14个病毒病症状相关的靶基因进行定量分析,结果表明随病毒侵染时间的延长,这些靶基因出现差异性表达,显示miRNA参与了寄主与病毒的互作。研究结果有助于揭示BYDV-GAV与寄主小麦的互作机理。     

从印度进口的洋葱中检出洋葱黄矮病毒

本文报道了从印度进口的洋葱中检出洋葱黄矮病毒。从印度进口的洋葱种球经过隔离试种,有1株洋葱幼苗发生整株矮化,叶片出现无规则的黄色条纹、皱缩等症状,经DAS—ELISA、RT-PCR检测和序列分析验证,确认该批从印度进口的洋葱鳞球茎中携带有洋葱黄矮病毒(Onion yellow dwarfvirus)。     

6种病毒抑制剂对西藏青稞上大麦黄矮病的防治效果

通过田间小区试验,开展了6种病毒抑制剂对西藏青稞上大麦黄矮病防治效果的研究.采用带毒蚜虫人工接种法,于青稞起身拔节期每株接种10～15头带毒麦长管蚜,7 d后灭蚜,灭蚜后3d喷施病毒抑制剂,在成株期出现黄矮病症状后调查病株率、病情指数、防治效果,以及长势和产量.结果表明,6种病毒抑制剂对青稞上大麦黄矮病有不同程度的防治...     

Identification of quantitative Loci for tolerance to barley yellow dwarf virus in oat

ABSTRACT Molecular markers linked to quantitative trait loci conditioning tolerance to barley yellow dwarf virus (BYDV) were identified in oat (Avena sativa) using amplified fragment length polymorphism (AFLP) analysis. Near-isogenic and recombinant inbred lines (NILs and RILs, respectively) derived from a cross of Clintland64 (BYDV-sensitive) and IL86-5698 (BYDV-tolerant) were evaluated for their responses to an Illinois isolate of the PAV strain of BYDV. Individual markers identified in the analysis of the NILs explained up to 35% of the variability seen in the tolerance response. Single-point analysis of the marker data from the RIL population identified 24 markers in three linkage groups that were associated with tolerance to BYDV infection at P /= 3.0. These loci explained about 50% total of the variation in BYDV tolerance in multimarker regression analysis in both years. The BYDV tolerance loci A, C, E, and R were mapped to hexaploid oat restriction fragment length polymorphism linkage groups 2, 8, 36, and 5, respectively, by analyzing the segregation of the AFLP markers in the Kanota x Ogle RIL population.     

感染大麦黄矮病毒的小麦中vsiRNA特征分析

 RNA沉默是植物中一种保守的抗病毒机制,其以大量病毒来源的小干扰RNA(virus-derived small interfering RNAs,vsiRNAs)的产生为标志,病毒在侵染寄主过程中可通过vsiRNAs靶向寄主转录本以对抗这种防御机制。BYDV-GAV引起的小麦黄矮病导致小麦黄化和矮化症状,对小麦生产构成严重威胁。通过深度测序技术,分析了感染BYDV-GAV的感病小麦品种‘小偃6号’中vsiRNAs的特征,共得到11 384个vsiRNAs,并预测到37 784个寄主靶基因。发现来源于BYDV-GAV基因组的正义和反义链的vsiRNAs的数量分布大致相等,在5’末端具有A和C偏好性,长度主要在21nt~22nt。靶基因的功能分析表明这些靶基因参与了广泛的生物学功能,尤其是在寄主-病原物互作中占的比重最大。选取25个参与寄主-病原互作的抗性相关基因进行定量验证,发现接种BYDV-GAV后有15个明显下调,6个上调,4个微弱下调,表明测序结果和靶基因预测可靠。推测BYDV-GAV可以通过vsiRNAs干扰寄主抗性基因表达和信号转导,从而实现对感病寄主的侵染。研究结果对揭示BYDV-GAV与小麦互作的分子机制具有重要意义。     

感染大麦黄矮病毒的小麦中vsiRNA特征分析

 RNA沉默是植物中一种保守的抗病毒机制,其以大量病毒来源的小干扰RNA(virus-derived small interfering RNAs,vsiRNAs)的产生为标志,病毒在侵染寄主过程中可通过vsiRNAs靶向寄主转录本以对抗这种防御机制。BYDV-GAV引起的小麦黄矮病导致小麦黄化和矮化症状,对小麦生产构成严重威胁。通过深度测序技术,分析了感染BYDV-GAV的感病小麦品种‘小偃6号’中vsiRNAs的特征,共得到11 384个vsiRNAs,并预测到37 784个寄主靶基因。发现来源于BYDV-GAV基因组的正义和反义链的vsiRNAs的数量分布大致相等,在5’末端具有A和C偏好性,长度主要在21nt~22nt。靶基因的功能分析表明这些靶基因参与了广泛的生物学功能,尤其是在寄主-病原物互作中占的比重最大。选取25个参与寄主-病原互作的抗性相关基因进行定量验证,发现接种BYDV-GAV后有15个明显下调,6个上调,4个微弱下调,表明测序结果和靶基因预测可靠。推测BYDV-GAV可以通过vsiRNAs干扰寄主抗性基因表达和信号转导,从而实现对感病寄主的侵染。研究结果对揭示BYDV-GAV与小麦互作的分子机制具有重要意义。     

The occurrence and effects of barley yellow dwarf virus in maize in SW England

During 1975 and 1976 barley yellow dwarf virus was isolated, using the aphid Rhopalosiphum padi (L.) from five maize cultivars in the Exeter area. The isolates produced interveinal flecking, often accompanied by leaf reddening, in the maize cultivar Anjou 210 and several other susceptible cultivars. ln 1976 visual assessment of six commercial maize plantings indicated natural infections ranging from 11 to 14% of plants, whilst infection in a disease observation plot ranged from 0.8 to 27.5%. Population counts for the three aphid vectors Sitobion avenae (F.), Metopolophium dirhodum (W.) and Rhopalosiphum padi (L.), associated with the crop, corresponded closely with the Rothamsted Insect Survey results from Starcross, Devon.
The maize cultivars Anjou 210 and De Kalb 202 were grown in experimental plots with individual rows containing 0, 25, 50, or 100% barley yellow dwarf-infected plants. Infection caused severe stunting of Anjou 210 but had less effect on De Kalb 202. Dry matter yield losses of 50% for Anjou 210 and 27% for De Kalb 202 were recorded; there were also significant changes (p<0.05) in dry matter content, metabolisable energy, digestible crude protein and water soluble carbohydrate.     

10种病毒抑制剂对小麦黄矮病的防治效果

在田间条件下研究了10种病毒抑制剂对小麦黄矮病的防治效果。结果表明,不同药剂处理对小麦黄矮病均有一定的抑制作用,其中6%寡糖·链蛋白WP、25%宁南·嘧菌酯AS和0.5%菇类蛋白多糖AS的防效分别为64.26%、58.44%和53.18%。不同病毒抑制剂处理的小麦产量有不同程度的增加,6%寡糖·链蛋白WP、20%吗胍·乙酸铜WP、0.5%葡聚烯糖SP和25%宁南·嘧菌酯AS增产率分别为21.5%、20.9%、20%和19.5%。说明6%寡糖·链蛋白WP是一种有前途的小麦黄矮病抑制剂,可在农业生产实践中进行推广应用。     

The role of Poa annua in the epidemiology of barley yellow dwarf virus in autumn-sown cereals

Studies of cereal aphids and barley yellow dwarf virus (BYDV) from 1989 to 1992 revealed that Poa annua is an abundant weed of commercial winter barley crops during the summer months. P. annua was frequently infected with BYDV, and there were usually similarities with the BYDV infection of the surrounding barley crop. These P. annua weeds were often infested by cereal aphids both in July (pre-harvest) and in September (in cereal stubble fields). Poa -infested cereal stubbles may be major local sources of viruliferous aphids, increasing the risk of BYDV in nearby winter cereals. P. annua plays an important role in the epidemiology of S. avenae -transmitted BYDV.     

Coat protein-mediated resistance to isolates of barley yellow dwarf in oats and barley

Tissue cultures of GAF30/Park oats were biolistically co-transformed with constructs containing the coat protein (CP) genes of the P-PAV, MAV-PS1 or NY-RPV isolates of barley yellow dwarf virus (BYDV), together with a construct containing the bar gene for herbicide resistance and the uidA reporter gene. Transformed, herbicide-resistant tissue cultures were screened by PCR for the presence of the CP genes. Fertile regenerated plants were recovered from some CP-transformed tissue cultures. T₁ progeny of these plants were screened for resistance to the BYDV isolate corresponding to the introduced gene by inoculation with viruliferous aphids followed by ELISA tests. Variation in ELISA values for GAF30/Park control plants made interpretation of the data difficult, but oat plants resistant to each of the three isolates of BYDV (ELISA values less than 0.3; virus titers equivalent to less than 25% of infected controls) were identified in T₁ generations. Further testing of MAV-PS1 CP-transformed lines to the T₂ generation, NY-RPV CP-transformed lines to the T₃ generation and P-PAV CP-transformed lines to the T₄ generation identified further resistant plants. Similarly, immature embryos and calli of the barley cultivar Golden Promise were biolistically bombarded with constructs containing the CP gene of the P-PAV isolate of BYDV and the bar and uidA reporter genes, lines of self-fertile P-PAV CP-transformed barley plants were developed, and T₁plants were screened for resistance to P-PAV. Eight plants from six lines showed moderate to high levels of resistance to P-PAV that correlated with the presence of the CP gene. Plants giving low ELISA values were also found in other lines, even though the CP gene was not detected in these plants. Some T₂ plants derived from resistant parents that contained the CP gene were themselves highly resistant.     

Occurrence of barley yellow dwarf virus in cereals and grasses of the low-rainfall wheatbelt of South Australia

South Australia is in the dry temperate zone where most cereal crops are grown in an area of low rainfall, with a crop-free season from December to April. The incidence of barley yellow dwarf virus (BYDV) was assessed by ELISA from 1989 to 1991 in wheat crops and irrigated pastures of South Australia. The incidence of BYDV was low in most wheat crops of the low-rainfall area in 1989 and 1990 (less than 1% of plants infected), but moderate levels of infection (1–10%) were observed in some early-sown crops. BYDV infection was more widespread in the high-rainfall area (south east of South Australia). A high incidence of BYDV was observed in the irrigated pastures of the three areas surveyed (4–86%). Of the five previously described strains, the Rhopalosiphum padi/Sitobion avenae strain (PAV) was the most common in wheat samples (> 90%). PAV and the R. padi-specific strain (RPV) were found in pasture grasses, alone or in mixed infection. Virus incidence was greater in Festuca spp. (56%) and Lolium perenne (30%) than in other species (2-–9%).