非生物因素诱导马铃薯抗真菌病害研究的新进展

真菌病害是限制马铃薯生产的主要因素之一。生产中控制马铃薯真菌病害的主要手段是喷施化学杀菌剂。随着揭示植物抗病性机理的逐步深入,利用生物或非生物因子诱导植物、使其增强抗病性的研究已取得许多令人瞩目的成果,结合本研究室的一些研究工作,着重介绍了利用非生物因素诱导马铃薯抗真菌病害研究的一些新进展,同时就利用非生物因子控制马铃薯真菌病害的前景及存在问题进行了讨论。     

基因沉默技术在抗真菌病害中的应用和展望

真菌病害严重威胁作物的产量和品质,给国家和人民造成巨大的经济损失。尤其是引起维管束病害的土传真菌,化学农药的作用效果很不理想。利用抗性基因进行遗传育种是目前生物防治的重要手段之一,但对于缺乏抗性资源的物种,面对强大的土壤真菌病害,研究者也时常束手无策。近年来,利用RNA干扰技术发展而来的宿主诱导的基因沉默(Host induced gene silencing,HIGS)策略,在抗病虫害领域逐渐崭露头角,但由于真菌侵染的复杂多样性及土壤传播的特性,HIGS在土壤真菌病害中的应用充满神秘和挑战。本研究室近期揭示了棉花黄萎病(一种严重的土壤真菌病害)的"罪魁祸首"——大丽轮枝菌的侵染结构和侵染过程;并首次证明了宿主植物内源小RNA能够跨界进入病原菌细胞中降解致病基因表达的抗病作用;在此基础上,本研究室利用HIGS在棉花上获得了对黄萎病抗性较高的品系,成功地开辟了抗土壤黄萎真菌病害的新天地,研究结果显示出基因沉默技术在这一领域强大的应用潜力和前景。     

北京大兴区甘薯根腐病原菌的分离及分子鉴定

针对北京市大兴区大肆爆发的甘薯根腐病病害,为确定造成该病害的优势真菌类型,开展了病害真菌的现状调查和快速检测鉴定工作。从患病甘薯根部分离真菌,通过真菌ITS区PCR扩增及系统发生关系等对病原菌的分子生物学鉴定和类群组成特点进行了分析。结果分离到两株病原真菌,分子鉴定结果表明这两株真菌均是尖孢镰刀菌(Fusarium oxysporum)。研究结果为甘薯根腐病病原菌的快速鉴定提供了依据,以期对甘薯根腐病的防治决策提供一定的参考。     

定陶汉墓出土汉砖表面及其储存环境真菌病害的分析与防治

【背景】定陶王墓地M2汉墓出土了一批处于防护层的重要汉砖,目前部分汉砖表面出现了真菌病害问题。【目的】根据现场文物保护状况,选取了5块汉砖表面的微生物病害样本,检测并分析了汉砖表面的真菌病害,将分离得到的7株真菌进行抑菌试验。【方法】使用扫描电镜观察、高通量测序、纯培养和抑菌试验等方法对样本中的真菌进行分析。【结果】发现未经抑菌处理的汉砖表面真菌病害问题严重,经75%乙醇和0.5%硝酸咪康唑处理过的汉砖表面真菌病害问题减弱。汉砖上的主要真菌不同,汉砖9表面含量最多的真菌为Boeremia,汉砖13表面含量最多的为虫草科(Cordycipitaceae)。然而硝酸咪康唑和硼酸硼砂并无抑菌效果,抑菌产品K100(2-甲基-4-异噻唑啉-3-酮)具有较好的抑菌效果。【结论】本研究对分析和防治汉砖表面的真菌病害及对汉砖进行科技保护具有重要意义。     

植物抗真菌病害基因工程研究概述

真菌病害是作物损失的主要原因之一。作物病害的80％由病原真菌所引起。真菌病的危害性极大,如19世纪中期,爱尔兰曾因晚疫病严重爆发而导致马铃薯绝产,致使100万人挨饿、200万人被迫背井离乡远迁北美。过去,人们对作物真菌病害的控制有三条途径:(1)选育并采用抗病品种,育种方法为通过有性杂交利用作物本身或近缘种中的抗性基因;(2)施用化学杀菌剂;(3)采取预防措施,如轮作、     

两种麻山药典型病害根际土壤微生物多样性的研究

为了解两种典型病害土壤根际微生物群落结构,明确土壤病害与微生物多样性变化的关系,采用高通量测序对两种典型病害根际微生物多样性进行对比分析,结果表明,细菌多样性和丰度值表现为糊头病的土壤对照组根茎腐病组;而真菌变化更明显,两种病害土壤真菌多样性和丰富度均高于对照组。物种分类注释表明,不同处理土壤细菌种类与对照组基本一致,只是不同类别所占的比例各不相同,真菌中含有一些与病害发生有关的特有属,且比例变化较大,说明土壤微生物群落结构变化在一定程度上影响病害的发生。     

两种美丽的真菌(封一说明)

本期封面刊登的是两种真菌.真菌在生物界中也是一个不小的家族,根据魏景超《真菌鉴定手册》介绍,真菌约有5万余种.它们体态小,形姿各异.有些真菌引起植物发生病害,引起减产和降低产品质量.有些使人、畜中毒.另     

甘蔗内生解淀粉芽孢杆菌CGB15的分离、鉴定及生防活性

真菌病害占作物病害种类的一半以上,病原真菌是目前已知种类最多的作物病原菌。从作物根际与/或体内分离筛选具有生防活性的微生物,并应用于病害的防控,是除作物品种改良与化学防治外的另一种高效的病害防控策略。【目的】本研究拟筛选并分离鉴定对重要作物病原真菌具有拮抗作用的甘蔗内生细菌,为开发生物防治作物真菌病害新策略提供理论依据。【方法】采用平板对峙法初步筛选对病原真菌具有拮抗能力的甘蔗叶片内生细菌,通过16SrRNA基因测序鉴定其种属;进一步检测候选拮抗内生细菌对甘蔗鞭孢堆黑粉菌(Sporisorium scitamineum)致病发育过程关键步骤：有性配合/菌丝生长、冬孢子萌发的抑制率,田间试验检测其对甘蔗鞭黑穗病的防治效果;检测候选拮抗内生细菌对稻梨孢菌(Pyricularia oryzae)附着胞形成、离体叶片及盆栽条件下叶片病斑形成的抑制作用。【结果】分离自甘蔗叶片的细菌菌株,编号为CGB15,经分子鉴定为解淀粉芽孢杆菌(Bacillus amyloliquefaciens)。CGB15菌株能有效抑制甘蔗鞭孢堆黑粉菌有性配合/菌丝生长,对峙培养条件下使真菌菌落呈现光滑;抑制冬孢子萌发,...     

丛枝菌根真菌对植物根腐病的抑制效应及其机制

根腐病是一类危害严重的土传病害,常常导致作物产量和品质降低。丛枝菌根(AM)真菌是一类重要的土壤微生物,通过与植物根系建立共生体而发挥重要的生理生态功能。研究表明,AM真菌通过调节宿主植物一系列生理生化响应,诱导植物增强根腐病抗性。当前,利用AM真菌开展根腐病等土传病害的生物防治是植物与微生物互作领域的研究热点。本文全面梳理了AM真菌对宿主植物根腐病病原物的抑制效应,系统总结了AM真菌改变宿主植物根系形态结构、改善植物营养水平、与病原物竞争生态位点、激活植物防御体系、调节根系分泌物等方面的研究结果,分析了AM真菌抑制根腐病危害的作用机制,展望了AM真菌抑制根腐病危害的潜在机制和AM真菌高效利用面临的现实问题,旨在为利用AM真菌开展植物根腐病的生物防治提供理论依据。     

植物维管组织的难养菌的分离和培养

多种微生物,包括真菌、细菌、支原体、原生动物和病毒,都能诱发植物维管组织病害。容易培养的真菌和细菌的病原作用早已确立,而难养菌在植物病害中所起的作用却不易阐明。多数情况下,尽管没有任何证据说明染病植物体存在病毒体,却常常把这些病害看成是病毒所致。     

Antibody-mediated resistance against plant pathogens

Plant diseases have a significant impact on the yield and quality of crops. Many strategies have been developed to combat plant diseases, including the transfer of resistance genes to crops by conventional breeding. However, resistance genes can only be introgressed from sexually-compatible species, so breeders need alternative measures to introduce resistance traits from more distant sources. In this context, genetic engineering provides an opportunity to exploit diverse and novel forms of resistance, e.g. the use of recombinant antibodies targeting plant pathogens. Native antibodies, as a part of the vertebrate adaptive immune system, can bind to foreign antigens and eliminate them from the body. The ectopic expression of antibodies in plants can also interfere with pathogen activity to confer disease resistance. With sufficient knowledge of the pathogen life cycle, it is possible to counter any disease by designing expression constructs so that pathogen-specific antibodies accumulate at high levels in appropriate sub-cellular compartments. Although first developed to tackle plant viruses and still used predominantly for this purpose, antibodies have been targeted against a diverse range of pathogens as well as proteins involved in plant–pathogen interactions. Here we comprehensively review the development and implementation of antibody-mediated disease resistance in plants.     

植物来源的镰刀菌抗性相关基因

镰刀菌是植物的重要病原真菌,其入侵植物体可引起镰刀菌病害,给农作物和其它植物的生产带来极大的危害。植物是抗性基因的重要来源之一,随着分子生物学技术的飞速发展,大量的镰刀菌相关抗性基因和抗性候选基因从不同的植物中被分离和鉴定,并应用于抗镰刀菌基因工程育种。对植物来源的镰刀菌抗性基因的种类及其作用机理、抗病候选基因、拟南芥-镰刀菌互作机制及基因调控进行了概述。     

Horizontal gene and chromosome transfer in plant pathogenic fungi affecting host range

Plant pathogenic fungi adapt quickly to changing environments including overcoming plant disease resistance genes. This is usually achieved by mutations in single effector genes of the pathogens, enabling them to avoid recognition by the host plant. In addition, horizontal gene transfer (HGT) and horizontal chromosome transfer (HCT) provide a means for pathogens to broaden their host range. Recently, several reports have appeared in the literature on HGT, HCT and hybridization between plant pathogenic fungi that affect their host range, including species of Stagonospora/Pyrenophora, Fusarium and Alternaria. Evidence is given that HGT of the ToxA gene from Stagonospora nodorum to Pyrenophora tritici-repentis enabled the latter fungus to cause a serious disease in wheat. A nonpathogenic Fusarium species can become pathogenic on tomato by HCT of a pathogenicity chromosome from Fusarium oxysporum f.sp lycopersici, a well-known pathogen of tomato. Similarly, Alternaria species can broaden their host range by HCT of a single chromosome carrying a cluster of genes encoding host-specific toxins that enabled them to become pathogenic on new hosts such as apple, Japanese pear, strawberry and tomato, respectively. The mechanisms HGT and HCT and their impact on potential emergence of fungal plant pathogens adapted to new host plants will be discussed.     

Genetic engineering strategies for enhancing tomato resistance to fungal and bacterial pathogens

The classification and detailed overview of the currently known effective strategies used to increase the resistance of tomato (Solanum lycopersicum L., syn. Lycopersicon esculentum Mill.) plants to infectious fungal and bacterial diseases by genetic engineering approaches are presented. Modern data on the mechanisms of the protective effect of heterologous genes on the enhancement of transgenic tomato resistance to fungal and bacterial pathogens are discussed.     

The Chitinase A from the baculovirus AcMNPV enhances resistance to both fungi and herbivorous pests in tobacco

Biotechnology has allowed the development of novel strategies to obtain plants that are more resistant to pests, fungal pathogens and other agents of biotic stress. The obvious advantages of having genotypes with multiple beneficial traits have recently fostered the development of gene pyramiding strategies, but less attention has been given to the study of genes that can increase resistance to different types of harmful organisms. Here we report that a recombinant Chitinase A protein of the Autographa californica nuclear polyhedrosis virus (AcMNPV) has both antifungal and insecticide properties in vitro. Transgenic tobacco plants expressing an active ChiA protein showed reduced damages caused by fungal pathogens and lepidopteran larvae, while did not have an effect on aphid populations. To our knowledge, this is the first report on the characterisation and expression in plants of a single gene that increases resistance against herbivorous pests and fungal pathogens and not affecting non-target insects. The implications and the potential of the ChiA gene for plant molecular breeding and biotechnology are discussed.     

Transgenic tobacco plants overexpressing chitinases of fungal origin show enhanced resistance to biotic and abiotic stress agents

Genes encoding defense-related proteins have been used to alter the resistance of plants to pathogens and other environmental challenges, but no single fungal gene overexpression has produced broad-spectrum stress resistance in transgenic lines. We have generated transgenic tobacco (Nicotiana tabacum) lines that overexpress the endochitinases CHIT33 and CHIT42 from the mycoparasitic fungus Trichoderma harzianum and have evaluated their tolerance to biotic and abiotic stress. Both CHIT33 and CHIT42, individually, conferred broad resistance to fungal and bacterial pathogens, salinity, and heavy metals. Such broad-range protective effects came off with no obvious detrimental effect on the growth of tobacco plants.     

Conversion of compatible plant-pathogen interactions into incompatible interactions by expression of the Pseudomonas syringae pv. syringae 61 hrmA gene in transgenic tobacco plants

The hrmA gene from Pseudomonas syringae pv. syringae has previously been shown to confer avirulence on the virulent bacterium P. syringae pv. tabaci in all examined tobacco cultivars. We expressed this gene in tobacco plants under the control of the tobacco Delta0. 3 TobRB7 promoter, which is induced upon nematode infection in tobacco roots (Opperman et al. 1994, Science, 263, 221-223). A basal level of hrmA expression in leaves of transgenic plants activated the expression of pathogenesis-related genes, and the transgenic plants exhibited high levels of resistance to multiple pathogens: tobacco vein mottling virus, tobacco etch virus, black shank fungus Phytophthora parasitica, and wild fire bacterium Pseudomonas syringae pv. tabaci. However, the hrmA transgenic plants were not significantly more resistant to root-knot nematodes. Our results suggest a potential use of controlled low-level expression of bacterial avr genes, such as hrmA, in plants to generate broad-spectrum resistance to bacterial, fungal and viral pathogens.     

兰花抗病毒基因工程研究进展(综述)

兰花病毒病严重影响兰花产业的发展,研究和探索防治兰花病毒病的新技术、新途径已成为众多研究者普遍关注的焦点。本文综述目前抗兰花病毒研究中应用的各种抗病毒基因工程策略,包括病毒来源基因中的外壳蛋白基因和运动蛋白基因介导的抗性策略,RNA介导的抗病毒策略,植物自身的抗病毒基因介导的抗性策略,利用多基因介导的抗性策略,以及抗体基因介导的抗性策略等。最后对兰花抗病毒基因工程的发展及应用进行了展望。     

Recent fungal diseases of crop plants: is lateral gene transfer a common theme?

A cursory glance at old textbooks of plant pathology reveals that the diseases which are the current scourge of agriculture in many parts of the world are a different set from those that were prominent 50 or 100 years ago. Why have these new diseases arisen? The traditional explanations subscribe to the "nature abhors a vacuum" principle-that control of one disease creates the condition for the emergence of a replacement-but does little to explain why the new pathogen succeeds. The emergence of a new disease requires a series of conditions and steps, including the enhanced fecundity of the new pathogen, enhanced survival from season to season, and spread around the world. Recently, evidence was obtained that wheat tan spot emerged through a lateral gene transfer event some time prior to 1941. Although there have been sporadic and persistent reports of lateral gene transfer between and into fungal plant pathogens, most examples have been dismissed through incomplete evidence. The completion of whole genome sequences of an increasing number of fungal pathogens no longer allows such proposed cases of lateral gene transfer to be dismissed so easily. How frequent are lateral gene transfers involving fungal plant pathogens, and can this process explain the emergence of many of the new diseases of the recent past? Many of the apparently new diseases are dependant on the expression of host-specific toxins. These are enigmatic molecules whose action requires the presence of plant genes with products that specifically encode sensitivity to the toxin and susceptibility to the disease. It is also notable that many new diseases belong to the fungal taxon dothideomycetes. This review explores the coincidence of new diseases, interspecific gene transfer, host-specific toxins, and the dothideomycete class.