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蚜虫能够传播上百种植物病毒,是最重要的农业介体昆虫之一。蚜虫在刺探和取食植物过程中,唾液组分会连同附着在口针中的病毒粒子一同被分泌进入植物内,在调节植物诱导抗性、病毒侵染扩散、介体昆虫行为等过程中均有重要作用。本文围绕蚜虫传播病毒和获取病毒2个关键过程,总结分析了蚜虫独特的刺吸取食行为与传毒效率和获毒效率之间的联系;针对取食活动中关键的唾液蛋白在调控植物免疫抗性、帮助病毒侵染过程中的功能,阐述了蚜虫高效传播非持久病毒的分子基础;针对蚜虫的获毒过程,综述了病毒侵染植物间接调控蚜虫趋向和行为的作用方式。这些研究的开展将为解释蚜虫和病毒协同侵染的分子机制以及有效开展基于蚜虫取食行为调控的病虫害防控新技术提供思路。 相似文献
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M. Khelifa 《European journal of plant pathology / European Foundation for Plant Pathology》2017,147(2):339-348
In recent decades, mineral oil spray has been considered an effective means to reduce aphid-mediated spread of non-persistent viruses such as Potato virus Y (PVY). However, the mechanism by which mineral oil prevents viral outbreaks is not well-characterized. Despite the fact that several studies have investigated the effects of mineral oil on aphid feeding behaviour, vector fitness and virus attachment to vector mouthparts, the effect of oil treatment on the plant response has not been studied. To address this need, the current study has assessed the impact of Vazyl-Y mineral oil on the plant-vector-virus (i.e. potato-aphid-PVY) pathosystem in potato, with a particular focus on the plant response. These results show for the first time that oil treatment induces the expression of plant-virus interaction related genes in both local and systemic non-infected tissues, as well as in PVY-infected plants. Finally, the oil’s elicitation properties in reducing viral infectivity are discussed. 相似文献
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植物病毒病给蔬菜生产带来很大影响,目前蔬菜病毒防控主要采用非药剂措施,广谱抗病毒剂效果有限,需要基于新的药物靶点开发新的病毒抑制剂。G-四链体(G4s)是一种特殊的核酸高级结构,其在病毒基因组中的形成或解链可调节基因的复制、转录和翻译等过程,进而影响病毒增殖。一些可调节G-四链体结构稳定性的小分子呈现出抗病毒活性,使得G-四链体有望成为新的抗病毒药物的靶标。番茄丛矮病毒(tomato bushy stunt virus, TBSV)是一种分布广泛的植物病毒,有关其基因组的复制、转录和翻译等分子机制已研究得较为成熟,是一种研究病毒与寄主互作的模式病毒。揭示TBSV中G-四链体的结构及功能,有望为植物病毒基因中G-四链体的研究奠定基础。本研究通过生物信息学分析,在TBSV基因中鉴定出两条保守的、潜在的G-四链体可形成序列(putative G-quadruplex sequences, PQS)——TBSV-PQS2和TBSV-PQS4;通过紫外、荧光光谱和圆二色光谱(CD光谱)方法筛选出与TBSV-PQS2和TBSV-PQS4互作的G4配体;通过烟草体内侵染性克隆试验发现,G-四链体配体... 相似文献
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The study of the transmission biology of insect-borne plant viruses is important to develop disease control practices. We characterized the transmission of a nanovirus, Banana bunchy top virus (BBTV), by its aphid vector Pentalonia nigronervosa Coquerel (Hemiptera, Aphididae) with respect to temperature, vector life stage, and plant access time. Adult aphids transmitted BBTV more efficiently than third instar nymphs at all temperatures tested. Adult aphids transmitted the virus more efficiently at 25 and 30 degrees C than at 20 degrees C, but temperature had no impact on transmission efficiency by nymphs. By decoupling the relationship between temperature and aphid BBTV acquisition or inoculation, we determined that temperature affected inoculation events more strongly than acquisition. Longer plant access periods increased viral acquisition and inoculation efficiencies in a range of 60 min to 24 h. Both BBTV acquisition and inoculation efficiencies peaked after 18 h of plant access period. We also show that BBTV transmission by P. nigronervosa requires a latent period. Our results demonstrate that vector transmission of BBTV is affected by temperature, vector life stage, and plant access period. 相似文献
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植物病毒与介体蚜虫存在复杂的互作关系。前人关于植物病毒对蚜虫调控作用的研究主要集中在植物病毒通过寄主植物对蚜虫的间接影响上,未见植物病毒对介体蚜虫适合度直接调控的报道。鉴于此,我们以麦长管蚜Sitobion miscanthi (Takahashi)为试虫,以其传播的大麦黄矮病毒-GAV(Barley yellow dwarf virus GAV,BYDV-GAV)为测试病毒,以全纯人工饲料加入BYDV-GAV病毒提取液饲养麦长管蚜4 d,使之在不接触寄主植物条件下获毒,然后分别在全纯人工饲料和无毒小麦叶片上继续饲养,直至死亡。利用生命表技术分析麦长管蚜生长发育和繁殖参数。研究结果表明:在无毒小麦叶片饲养条件下,与未获毒对照麦长管蚜相比,获毒后麦长管蚜生活史参数成虫历期和产仔天数显著降低,繁殖力显著增加;种群参数内禀增长率、净繁殖率、周限增长率显著增加,平均世代周期显著降低。在全纯人工饲料条件下,与未获毒对照相比,获毒后麦长管蚜仅成虫历期和产仔天数显著下降,而其他生活史参数及种群参数均无显著差异。说明BYDV-GAV使得介体麦长管蚜在小麦叶片上的适合度显著提高,这是由麦长管蚜与寄主植物互作引起的,而病毒对介体麦长管蚜的适合度无直接调控作用。 相似文献
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Chickpea is one of the major legume crops in the northern parts of Algeria, with 60 000 ha sown. The different viral diseases observed on this crop are partially responsible for the low yields obtained. Of the viruses involved, bean yellow mosaic potyvirus (BYMV), associated with 'narrow-leaf disease, has been identified in the central parts of the country since 1994. The host range was screened and found to include species of Fabaceae, Solanaceae and Cucurbitaceae. Three aphid species ( Acyrthosiphon pisum, Aphis craccivora and Aulacorthum solani ) have been shown to transmit the virus. Two chickpea cultivars (ILC 3279 and ILC 482) carry BYMV in the seed cotyledons. The virus has been purified, antiserum has been produced and electrophoretic analysis has been conducted. 相似文献
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B. D. Harrison 《European journal of plant pathology / European Foundation for Plant Pathology》1992,98(2):1-12
Knowledge of the nucleotide sequences in the genomic nucleic acid of several potato viruses has enabled the open reading frames to be identified. These open reading frames are expressed by a variety of strategies, to produce proteins with functions in virus nucleic acid replication, virus particle production, cell-to-cell transport of virus and virus transmission by vectors. The activity of such proteins depends on their interactions with other viral or non-viral materials.Several other biological properties of plant viruses can also be related to individual viral gene products. For example, in plants co-infected with a specific pair of unrelated viruses, one virus can benefit from an ability to use the gene product of the second virus in replication, cell-to-cell transport or transmission by vectors. Similarly, different host resistance genes are targeted against viral replicase, movement protein or coat protein. Thus it is becoming possible to relate gene-for-gene (or more accurately, viral gene domain-host gene) interactions to events at the molecular level. Genetically engineered resistance to plant viruses likewise can be targeted against individual viral genes, and probably also against viral regulatory sequences. Such transgenic resistance seems likely to be as durable as conventional host resistance but durability should be improved by producing plants with combinations of resistances of different kinds, either conventional or genetically engineered, or both. 相似文献
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Insect-borne viruses promote several changes in plant phenotype, which can modify plant-vector interactions in favor of virus survival and dissemination. Although co-infections commonly occur in the field, little is known about their effects on interactions with the vector. The ecological interactions between Barley Yellow Dwarf Virus (BYDV) and its aphid vector, Rhopalosiphum padi, have been investigated extensively, but the vector’s behavior in more complex scenarios has yet to be examined. We assessed olfactory response and performance of R. padi to wheat singly and doubly infected by the pathogenic fungus Giberella zeae and BYDV. Non-viruliferous aphids preferred odors of BYDV-infected wheat over healthy wheat, as previously reported in the literature, and they were still preferentially attracted to BYDV-infected plant during co-infection. However, around 35% more non-viruliferous aphids chose healthy wheat over G. zeae-infected wheat. Viruliferous aphids did not show any preference to the treatments. BYDV-infected wheat was a superior host than healthy wheat for the aphids whose population increased in 25%. We observed a synergistic effect of the co-infected wheat, which was the best host for aphids, and promoted an elevation of 42% on population growth. Our results indicate that co-infection might be beneficial for virus spread as does not interfere with aphid olfactory preference and provides greater colony growth than in singly infected plants. 相似文献
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Replication of positive-strand RNA [(+)RNA] viruses proceeds through well-orchestrated actions of both viral and host factors. Remarkable features of eukaryotic (+)RNA virus replication include hijacking of host factors by viral components and remodeling of intracellular membranes to establish the viral replication factory, where viral RNA is synthesized. Here we review recent progress in our understanding of how (+)RNA plant viruses use host factors to create favorable environments for viral RNA replication. 相似文献
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C. G. Webster B. A. Coutts R. A. C. Jones M. G. K. Jones S. J. Wylie 《Plant pathology》2007,56(5):729-742
The southwest Australian floristic region (SWAFR) is an internationally recognized 'hot spot' of global biodiversity and has an endangered flora. It represents a unique interface between an ancient ecosystem and a recent agroecosystem, providing the opportunity to investigate encounters where the recipient of the virus is an introduced crop and the donor a native plant and vice versa. Phylogenetic analysis of the virus coat-protein genes was used to study isolates of three potyviruses representing different 'new encounter' scenarios at this interface. The incidence, symptomatology, host range, non-persistent aphid transmission and considerable genetic diversity of the first indigenous virus described from the SWAFR, where it infects the native legume Hardenbergia comptoniana , and its potential to damage lupin, a locally important, newly introduced cultivated grain legume, was studied. The name Hardenbergia mosaic virus is proposed for this virus. Two other examples of 'new encounter' scenarios involving other legume-infecting potyviruses studied were: Passion fruit woodiness virus , which has been found only in Australasia, where it damages recently introduced species of Passiflora and legumes; and Bean yellow mosaic virus, which is not indigenous to Australia and was introduced recently to the SWAFR, where it infects a number of introduced legumes, but also damages the local native legume Kennedia prostrata . Isolates of the former had considerable genetic diversity consistent with the virus being indigenous, while isolates of the latter virus from K. prostrata had a low genetic diversity consistent with recent arrival. This research illustrates how introduced viruses can damage indigenous plants and indigenous viruses can damage introduced cultivated plants within this unique ecosystem, and how human activities can facilitate damaging 'new encounters' between plants and viruses. 相似文献
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高通量测序技术在植物及昆虫病毒检测中的应用 总被引:1,自引:0,他引:1
在过去的十几年中,测序技术的发展为分子生物学领域带来了革命性的变化。第二代测序(next-generation sequencing,NGS)技术以快速、高灵敏性、高通量、非序列依赖性等特点极大地促进了病毒诊断学研究领域的发展。NGS技术可以在不了解病毒的生物学特性、血清学特点及基因组信息情况下快速检测未知病毒。通过对总核酸样本进行NGS可以获得某个特定生态环境或种植系统中的所有病毒序列,即病毒组。通过大量的NGS数据可以分析寄主中某一病毒的基因组变化、构建病毒的准种以及研究病毒的进化和起源。本文介绍了高通量测序的方法在植物和昆虫病毒检测中的应用。 相似文献
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很多植物病毒经介体昆虫以持久循回型的方式水平传播至寄主韧皮部致病,而唾液腺是介体昆虫持久传毒的重要器官,也是植物病毒在介体昆虫内循回需要克服的最后一道防线。持久性植物病毒要完成水平传播,必须突破昆虫唾液腺屏障的阻碍,因此病毒和介体昆虫间形成了“攻”与“守”的较量与对决。揭示持久性植物病毒克服昆虫唾液腺屏障,实现水平传播的机制,对病害控制具有重要意义。该文着眼于介体昆虫唾液腺在持久传毒过程中的重要功能,回顾了虫传植物病毒突破介体昆虫唾液腺侵入屏障和释放屏障的分子机制,探讨了昆虫唾液蛋白通过调节植物或昆虫的适应性和行为促进或抑制病毒水平传播的功能,为制定阻断介体昆虫传播植物病毒途径的防控策略提供理论依据。 相似文献
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G. Li H. Lv S. Zhang S. Zhang F. Li H. Zhang W. Qian Z. Fang R. Sun 《Plant pathology》2019,68(6):1035-1044
Turnip mosaic virus (TuMV), the only potyvirus known to infect brassicas, is a devastating virus threatening many economically important brassica crops, including cabbage, Chinese cabbage, oilseed rape and mustard. TuMV disease, which was first discovered in the United States, is now found worldwide, especially in Europe, Asia and North America. TuMV results in a yield loss of up to 70% and has a wide host range, infecting most cruciferous plants, as well as many non-cruciferous species. This virus is also characterized by high pathotype diversity because of its highly variable genome structure and has been divided into 12 pathotypes. These characteristics, as well as its nonpersistent transmission mode by as many as 89 aphid species, mean the disease is difficult to prevent through traditional methods such as the application of chemicals, prompting researchers to seek host resistance for effective control. During the last decade, extensive studies have been conducted to investigate inheritance, mapping and cloning of the TuMV resistance genes, and several NB-LRR- or eIF-encoding loci with divergent molecular mechanisms have been uncovered. These studies have greatly facilitated resistance breeding for brassica crops and have advanced our understanding of virus−host interactions. 相似文献
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Louise Mc Namara Kevin Gauthier Lael Walsh Gaël Thbaud Michael Gaffney Emmanuel Jacquot 《Pest management science》2020,76(7):2276-2285
Barley/cereal yellow dwarf viruses (YDVs) cause yellow dwarf disease (YDD), which is a continuous risk to cereals production worldwide. These viruses cause leaf yellowing and stunting, resulting in yield reductions of up to 80%. YDVs have been a consistent but low‐level problem in European cereal cultivation for the last three decades, mostly due to the availability of several effective insecticides (largely pyrethroids and more recently neonicotinoids) against aphid vectors. However, this has changed recently, with many insecticides being lost, culminating in a recent European Union (EU) regulation prohibiting outdoor use of the neonicotinoid‐insecticide compounds. This change is coupled with the growing challenge of insecticide‐resistant aphids, the lack of genetic resources against YDVs, and a knowledge deficit around the parameters responsible for the emergence and spread of YDD. This means that economic sustainability of cereal cultivation in several European countries including France and United Kingdom is now again threatened by this aphid‐vectored viral disease. In this review, we summarize the current knowledge on the YDV pathosystem, describe management options against YDD, analyse the impacts of the neonicotinoid ban in Europe, and consider future strategies to control YDV. © 2020 Society of Chemical Industry 相似文献
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Virus yellows is an important disease affecting yield in sugar beet in the UK. Myzus persicae (Sulzer) is the most effective and efficient aphid vector of the three viruses causing the disease: beet yellows virus, beet mild yellowing virus and beet chlorosis virus. Control of virus yellows disease is thus focused on the study and control of this aphid species. UK national surveys of virus yellows began in 1946 and these data helped to formulate disease forecasting schemes to optimise control. Over the years, in addition to improvements in farm hygiene, periodic changes and developments in control of the disease have occurred. To accommodate these important developments, virus yellows forecasting schemes have evolved accordingly. The most recent version has been adapted to take account of the current widespread use of imidacloprid seed treatment. Its application offers potential to optimise the rational use of aphicides such as imidacloprid so as to benefit beet growers and the environment by reducing prophylactic use of seed treatment. 相似文献