甘蔗花叶病的基因工程研究

甘蔗花叶病(Sugarcane mosaic disease)是世界上重要的病毒病害之一,严重的影响了世界甘蔗的产量。对甘蔗花叶病病原菌分类、病原系统侵染的过程、相关致病机理、病原菌检测手段以及抗甘蔗花叶病基因工程的研究现状与前景进行了综述。     

玉米矮花叶病研究进展

玉米矮花叶病(maize dwarf mosaic virus,MDMv)是世界上玉米产区普遍发生的病毒病害之一.自20世纪90年代以来,我国玉米矮花叶病发生严重,山西、甘肃、山东、河北以及北京等省市先后大流行,造成了巨大的农业经济损失.在我国玉米产区造成危害的主要是该病毒的B株系,主要借蚜虫传播和种子传播;在玉米矮花叶病的防治中,种植抗病品种,并辅以合理的栽培管理,可有效防止MDMV.本文主要综述玉米矮花叶病病毒的理化特性、玉米矮花叶病的发生危害、病原及其传播方式、发病条件、流行与防治、品种(自交系)抗性、抗性鉴定、抗性遗传及其抗病基因工程研究等方面的研究进展,以期为以后玉米矮花叶病的有效防治提供一定的参考.     

西瓜花叶病毒中国分离株全基因组核苷酸序列测定

西瓜花叶病毒(Watermelon mosaic virus,WMV)是马铃薯Y病毒属(Potyvirus)成员,主要危害西瓜和甜瓜,引起花叶病。在田间,该病害主要由蚜虫以非持久性方式传播。西瓜和甜瓜花叶病在国内陕西、山东、云南、辽宁、山西、新疆、河南和黑龙江等地广泛发生[1-6]。从20世纪80年代中期开始发生,逐渐上升为普遍发生的主要病害。我国大部分地区因西瓜和甜瓜病毒病造成的损失为30%~50%,甚至会绝产,西瓜花叶病毒已经成为制约西瓜和甜瓜高产稳产最主要的因素之一[7]。到目前为止,多数工作集中在对西瓜和甜瓜病毒病的鉴定,在分子生物学上仅限于对CP基因…     

新疆伊犁地区侵染蚕豆和三叶草的豌豆花叶病毒的鉴定

从伊犁地区采集的蚕豆花叶病和三叶草花叶病植株获得的病毒分离物,经接种子鉴别寄主,可系统侵染蚕豆、三叶草、豌豆,局部侵染苋色藜和菜豆。可通过蚕豆蚜进行非持久性传播,不通过种子传播。电镜下,病毒粒体呈线条状,平均长度为756nm。在汁液中的热钝化温度是55℃。体外存活期3天。在感病蚕豆叶超簿切片中,可观察到风轮状内含体。血清反应结果证明,该病毒与马铃薯Y病毒、菜豆黄色花叶病毒和菜豆普通花叶病毒有一定相关性。根据上述特性认为,从伊黎地区蚕豆花叶和三叶草花叶植株得到的病毒分离物,为豌豆花叶病毒(PMV)。     

辣椒抗烟草花叶病毒相关基因研究进展

病毒病是危害辣椒生产的主要病害之一。烟草花叶病毒(TMV)是最早被发现的病毒,它引起的烟草花叶病毒病是多种作物的重要病害,给辣椒等茄科作物的生产带来重大损失。文中综述了辣椒抗TMV防御反应中的相关基因及其研究进展,为明确辣椒抗TMV机理,挖掘抗病基因,选育抗病材料提供参考。     

广东省烟草花叶病病原病毒的鉴定

烟草花叶病是广东省产烟区的主要病害之一。我们在南雄等八个县进行调查,1983年至1984年的一般发病率为2～20％。根据血清学反应、病毒粒体形态、鉴别寄主反应及寄主范围、媒介昆虫种类、物理性质、交互保护反应等各项检验结果,鉴定广东省烟草花叶病病原是:三个黄瓜花叶病毒可能株系(普通株系CMV-C,烟草坏死株系CMV-TN,烟草黄色坏死株系(CMV-TYN),烟草花叶病毒(TMV),马铃薯病毒Y(PVY),烟草脉带花叶病毒(TVBMV)和烟草褪绿斑驳病毒(TCMV)(暂定)。     

浅析气象因子在烟草花叶病测报中的应用

烟草病毒病俗称烟草花叶病,是烟草病害中分布最广、发生最为普遍的病害之一。究其发病原因,气候对其的影响不可忽视。积极将气象因子应用在烟草花叶病测报中有利于烟草花叶病的防治。本文就此作了浅析。     

CMV和PVY复合感染引起的烟草叶脉坏死病

山东烟区烟草在大田生长期中常发生一种叶脉坏死、新生顶叶系统花叶的病害(图1、2)。1950年8月陈瑞泰在临朐城关一带,发现这一病害,1957年周家炽、莽克强也曾作过报道。六十年代以后,山东烟区病毒病渐趋严重。七十年代以来,黄瓜花叶病     

CMV和PVY复合感染引起的烟草叶脉坏死病

山东烟区烟草在大田生长期中常发生一种叶脉坏死、新生顶叶系统花叶的病害(图1、2)。1950年8月陈瑞泰在临朐城关一带,发现这一病害,1957年周家炽、莽克强也曾作过报道。六十年代以后,山东烟区病毒病渐趋严重。七十年代以来,黄瓜花叶病     

苜蓿花叶病毒马铃薯杂斑株系的分离和鉴定

在前茬为苜蓿的马铃薯田里,有一种叶上出现鲜黄病斑的马铃薯黄斑花叶病。病叶汁液在普通烟和心叶烟上产生黄斑花叶和斑驳。在菜豆和豇豆上产生红褐色和紫红色局部斑。部分提纯的病毒是平均直径20．6nm、长17．5—74nm的多组分短杆状粒体。致死温度55—60℃,稀释限点10-3,体外存活期3—4天。将分离物回接马铃薯,3--6周后,表现类似田间病株症状。接种紫花苜蓿呈现黄斑花叶。试验证明,引起上述病害的病原为苜蓿花叶病毒马铃薯杂斑株系,此种病害与国外报道的马铃薯杂斑病(Porto-calico disease)为同一种病害。此病可通过块茎传播。     

Identification of maize lethal necrosis disease causal viruses in maize and suspected alternative hosts through small RNA profiling

Maize lethal necrosis disease (MLND) is a devastating viral disease of maize caused by double infection with Maize chlorotic mottle virus (MCMV) and any one of the Potyviridae family members. Management of MLND requires effective resistance screening and surveillance tools. In this study, we report the use of small RNA (sRNA) profiling to detect MLND causal viruses and further the development of alternative detection markers for use in routine surveillance of the disease-causing viruses. Small RNAs (sRNAs) originating from five viruses namely MCMV, Sugarcane mosaic virus (SCMV), Maize streak virus (MSV), Maize-associated totivirus (MATV) and Maize yellow mosaic virus (MYMV) were assembled from infected maize samples collected from MLND hot spots in Kenya. The expression of the identified viral domains was further validated using quantitative real-time PCR. New markers for the detection of some of the MLND causal viruses were also developed from the highly expressed domains and used to detect the MLND-causative viruses in maize and alternative hosts. These findings further demonstrate the potential of using sRNAs especially from highly expressed viral motifs in the detection of MLND causal viruses. We report the validation of new sets of primers for use in detection of the most common MLND causal viruses MCMV and SCMV in East Africa.     

Plant viral synergism: the potyviral genome encodes a broad-range pathogenicity enhancer that transactivates replication of heterologous viruses.

Synergistic viral diseases of higher plants are caused by the interaction of two independent viruses in the same host and are characterized by dramatic increases in symptoms and in accumulation of one of the coinfecting viruses. In potato virus X (PVX)/potyviral synergism, increased pathogenicity and accumulation of PVX are mediated by the expression of potyviral 5' proximal sequences encoding P1, the helper component proteinase (HC-Pro), and a fraction of P3. Here, we report that the same potyviral sequence (termed P1/HC-Pro) enhances the pathogenicity and accumulation of two other heterologous viruses: cucumber mosaic virus and tobacco mosaic virus. In the case of PVX-potyviral synergism, we show that the expression of the HC-Pro gene product, but not the RNA sequence itself, is sufficient to induce the increase in PVX pathogenicity and that both P1 and P3 coding sequences are dispensable for this aspect of the synergistic interaction. In protoplasts, expression of the potyviral P1/HC-Pro region prolongs the accumulation of PVX (-) strand RNA and transactivates expression of a reporter gene from a PVX subgenomic promoter. Unlike the synergistic enhancement of PVX pathogenicity, which requires only expression of HC-Pro, the enhancement of PVX (-) strand RNA accumulation in protoplasts is significantly greater when the entire P1/HC-Pro sequence is expressed. These results indicate that the potyviral P1/HC-Pro region affects a step in disease development that is common to a broad range of virus infections and suggest a mechanism involving transactivation of viral replication.     

Comparative Epidemiology of Three Virus Diseases on Zucchini Squash

Zucchini yellow mosaic virus (ZYMV), Papaya ringspot virus – type W (PRSV‐W) and Zucchini lethal chlorosis virus (ZLCV) cause important diseases on zucchini squash crops in Brazil. ZYMV and PRSV‐W belong to the genus Potyvirus and are transmitted by aphids, whereas ZLCV belongs to Tospovirus and is transmitted by the thrips Frankliniella zucchini. These three viruses may occur simultaneously in the field, and the epidemiology of the corresponding diseases may be determined by interactions among viruses, hosts and vectors. In this work, the progress of the diseases caused by these viruses was studied over a temporal and geographic range for three planting seasons (PS). For the lethal chlorosis (ZLCV), a monomolecular model was found to be the best fit for the data, though only during the third PS. For data collected during the first two PS, the Gompertz model was found to fit the data best. The spatial distribution of disease indicated disease aggregation at the end of the crop cycle. For the yellow mosaic (ZYMV), the model that best fit in the 1st PS was the logistic and in the 2nd and 3rd PS was monomolecular. The spatial pattern of the disease was random when the disease incidence was low but aggregated when the disease incidence was high. The common mosaic (PRSV‐W) showed the lowest incidence in all three PS. An exponential model was the best fit for data collected during all PS, and the spatial pattern of the disease was random. Interactions among the three viruses apparently did not result in changes in the epidemiology of the diseases. Removal of sources of inoculum and planting at an unfavourable time for reproduction of virus vectors are the two main measures recommended for the control of these diseases. The use of insecticide is indicated only for the control of the F. zucchini.     

Disease intensity of some tomato viroses in Serbia

In this paper we present the data on the disease intensity of the tomato plants grown in glass and plastic-houses, and in the open field. The infection was caused by the following viruses: Tomato mosaic virus (ToMV), Tobacco mosaic virus (TMV), Tomato spotted wilt virus (TSWV), Alfalfa mosaic virus (AMV), Potato virus X (PVX), Potato virus Y (PVY), Tomato black ring virus (TBRV), Tomato ringspot virus (ToRSV), Tomato aspermy virus (TAV), and Cucumber mosaic virus (CMV). These viruses represented most frequent tomato pathogens in Serbia. According to the obtained results, it could be concluded that 92.94% of the tested tomato plants grown in glass and plastic-houses, and 89.82% grown in the open field were infected by one of the above viruses. Most of the plant samples were infected by two or more viruses. The most frequent viruses — tomato pathogens in Serbia were ToMV, PVY and TMV.     

Virus diseases of subterranean clover

Subterranean clover (Trifolium subterraneum) is grown as a pasture legume in several temperate regions of the world where the soils are acidic and infertile, and the rainfall is winter dominant and less than 600 mm annually. It is particularly important in southern Australia where more than 16 million ha have been sown with this species as the pasture legume component. Nine viruses have been recorded infecting subterranean clover in the field. These are alfalfa mosaic, bean yellow mosaic (pea mosaic), beet western yellows, clover yellow vein, cucumber mosaic, pea enation mosaic, soybean dwarf (subterranean clover red leaf), subterranean clover mottle and white clover mosaic. In addition there is an important problem referred to as subterranean clover stunt that was assumed to be caused by a virus but whose aetiology is still unknown. The importance of these diseases is reviewed and details on their epidemiologies are outlined together with details on progress towards their control and some comments on matters worthy of attention in the future. Reference is also made to several exotic viruses known to infect subterranean clover experimentally that could possible cause problems if introduced into Australia.     

Exploring the diversity of plant DNA viruses and their satellites using vector-enabled metagenomics on whiteflies

Current knowledge of plant virus diversity is biased towards agents of visible and economically important diseases. Less is known about viruses that have not caused major diseases in crops, or viruses from native vegetation, which are a reservoir of biodiversity that can contribute to viral emergence. Discovery of these plant viruses is hindered by the traditional approach of sampling individual symptomatic plants. Since many damaging plant viruses are transmitted by insect vectors, we have developed "vector-enabled metagenomics" (VEM) to investigate the diversity of plant viruses. VEM involves sampling of insect vectors (in this case, whiteflies) from plants, followed by purification of viral particles and metagenomic sequencing. The VEM approach exploits the natural ability of highly mobile adult whiteflies to integrate viruses from many plants over time and space, and leverages the capability of metagenomics for discovering novel viruses. This study utilized VEM to describe the DNA viral community from whiteflies (Bemisia tabaci) collected from two important agricultural regions in Florida, USA. VEM successfully characterized the active and abundant viruses that produce disease symptoms in crops, as well as the less abundant viruses infecting adjacent native vegetation. PCR assays designed from the metagenomic sequences enabled the complete sequencing of four novel begomovirus genome components, as well as the first discovery of plant virus satellites in North America. One of the novel begomoviruses was subsequently identified in symptomatic Chenopodium ambrosiodes from the same field site, validating VEM as an effective method for proactive monitoring of plant viruses without a priori knowledge of the pathogens. This study demonstrates the power of VEM for describing the circulating viral community in a given region, which will enhance our understanding of plant viral diversity, and facilitate emerging plant virus surveillance and management of viral diseases.     

A role for plant microtubules in the formation of transmission-specific inclusion bodies of Cauliflower mosaic virus

Interactions between microtubules and viruses play important roles in viral infection. The best-characterized examples involve transport of animal viruses by microtubules to the nucleus or other intracellular destinations. In plant viruses, most work to date has focused on interaction between viral movement proteins and the cytoskeleton, which is thought to be involved in viral cell-to-cell spread. We show here, in Cauliflower mosaic virus (CaMV)-infected plant cells, that viral electron-lucent inclusion bodies (ELIBs), whose only known function is vector transmission, require intact microtubules for their efficient formation. The kinetics of the formation of CaMV-related inclusion bodies in transfected protoplasts showed that ELIBs represent newly emerging structures, appearing at late stages of the intracellular viral life cycle. Viral proteins P2 and P3 are first produced in multiple electron-dense inclusion bodies, and are later specifically exported to transiently co-localize with microtubules, before concentrating in a single, massive ELIB in each infected cell. Treatments with cytoskeleton-affecting drugs suggested that P2 and P3 might be actively transported on microtubules, by as yet unknown motors. In addition to providing information on the intracellular life cycle of CaMV, our results show that specific interactions between host cell and virus may be dedicated to a later role in vector transmission. More generally, they indicate a new unexpected function for plant cell microtubules in the virus life cycle, demonstrating that microtubules act not only on immediate intracellular or intra-host phenomena, but also on processes ultimately controlling inter-host transmission.     

Virus Resistance in Cereals: Sources of Resistance, Genetics and Breeding

In cereals, soil-borne viruses transmitted by the plasmodiophorid Polymyxa graminis (e.g., Barley mild mosaic virus , Barley yellow mosaic virus or Soil-borne cereal mosaic virus ), have increased in importance due to the increase of the acreage infested and because yield losses cannot be prevented by chemical measures. Due to global warming, it is also expected that insect transmitted viruses vectored by aphids (e.g., Barley yellow dwarf virus , Cereal yellow dwarf virus ), leafhoppers ( Wheat dwarf virus ) or mites (e.g., Wheat streak mosaic virus ), will become much more important even in cooler regions. The environmentally most sound and also most cost effective approach to prevent high yield losses caused by these viruses is breeding for resistance. Therefore, in contrast to other reviews on cereal viruses, this study briefly reviews present knowledge on cereal-infecting viruses and emphasizes especially the sources of resistance or tolerance to these viruses and their use in molecular breeding schemes.     

Emerging geminivirus problems: A serious threat to crop production

Geminiviruses form the second largest family of plant viruses, the Geminiviridae, represented by four genera: Mastrevirus, Curtovirus, Topocuvirus and Begomovirus. During the last two decades these viruses have emerged as devastating pathogens, particularly in the tropics and subtropics, causing huge economic losses and threatening crop production. Epidemics caused by re‐emerging and newly emerging geminiviruses are becoming frequent even in regions that were earlier free from these viruses. Compared to mastreviruses and curtoviruses, begomoviruses have emerged as more serious problems in a variety of crops, for example, cassava, cotton, grain legumes and vegetables. Major contributory factors for the emergence and spread of new geminivirus diseases are the evolution of variants of the viruses, the appearance of the whitefly ‘B’ biotype and the increase in the vector population. Variability in geminiviruses has arisen through mutations, recombination and pseudorecombination. Genomic recombination in geminiviruses, not only between the variants of the same virus but also between species and even between genera, has resulted in rapid diversification. From the disease point of view, most virulent variants have developed through recombination of viral genomes such as those associated with cassava mosaic, cotton leaf curl, and tomato leaf curl diseases. Heterologous recombinants containing parts of the host genome and/or sequences from satellite‐like molecules associated with monopartite begomoviruses provide unlimited evolutionary opportunities. Human activity has also played an important role in the emergence of serious geminivirus diseases across the globe, like the changes in cropping systems, the introduction of new crops, the movement of infected planting materials and the introduction of host susceptibility genes through the exchange of germplasm.     

Genetic Diversity in RNA Virus Quasispecies Is Controlled by Host-Virus Interactions

Many RNA viruses have genetically diverse populations known as quasispecies. Important biological characteristics may be related to the levels of diversity in the quasispecies (quasispecies cloud size), including adaptability and host range. Previous work using Tobacco mosaic virus and Cucumber mosaic virus indicated that evolutionarily related viruses have very different levels of diversity in a common host. The quasispecies cloud size for these viruses remained constant throughout serial passages. Inoculation of these viruses on a number of hosts demonstrated that quasispecies cloud size is not constant for these viruses but appears to be dependent on the host. The quasispecies cloud size remained constant as long as the viruses were maintained on a given host. Shifting the virus between hosts resulted in a change in cloud size to levels associated with the new host. Quasispecies cloud size for these viruses is related to host-virus interactions, and understanding these interactions may facilitate the prediction and prevention of emerging viral diseases.