用转基因方法进行抗线虫农作物育种的研究进展

在许多农作物中,植物寄生线虫引起重大损失。有幸的是,某些植物对线虫有抗性,而且存在于栽培种和其近亲野生种中的抗性基因,可以用分子标记方法建立图谱。标记辅助的选择方法已广泛应用于育种工作中,两种抗线虫的基因已经通过定位克隆技术分离出来,并成功地在栽培作物中得到表达。建立线虫抗性的另一个方法是将具有杀线剂效应的基因导入植物中,该方法也已取得了一些进展。     

植物抗线虫基因与抗性机理研究进展

植物寄生线虫是严重危害农业生产的一类重要病原生物,对全球作物产量造成重大损失.抗线虫基因在植物抗线虫反应中发挥重要作用,发掘抗线虫基因并培育抗线虫品种是防治线虫病害的一条有效途径.抗线虫基因的定位与克隆对解析植物抗线虫性的分子机理做出了巨大贡献,明确线虫与寄主植物之间的互作关系及抗线虫机制,可以为制定和采取更加有效的防控策略提供借鉴.     

植物抗根结线虫机制研究进展

近年来,植物抗根结线虫机制研究已成为线虫研究领域的热点之一。本文主要从植物对根结线虫病的抗性结构、抗性基因、坏死反应以及相关酶类等方面的机制研究进展作一综述与展望。     

植物根腐线虫鉴定及抗性机制研究进展

根腐线虫是植物三大病原线虫之一,广泛分布于世界各地,为害多种粮食及经济作物,给农业生产带来巨大损失.根腐线虫的识别与鉴定是防治工作的重要环节,研究植物线虫抗性机制有利于培育抗性品种.为此,回顾了近年来根腐线虫鉴定及植物对根腐线虫抗性方面的研究工作,强调了线虫准确鉴定的重要意义,分析讨论了植物抗线虫的机制.     

植物抗线虫基因工程新途径及其在分子育种中的应用

 植物寄生线虫种类繁多、危害严重,给世界农业生产造成巨大经济损失。目前防治线虫通常采用轮作、杀线虫药剂、生物防治和应用抗性品种等措施,但存在一定局限性。随着植物与寄生线虫之间相互作用机制的深入研究以及分子遗传操作技术的逐渐成熟,利用基因工程技术构建环保、方便、有效的线虫防治策略逐渐成为研究热点。本文从植物抗线虫基因、抑制线虫的外源活性蛋白、特异表达启动子,以及RNAi介导的抗线虫基因工程策略等方面,简要概述了国内外近年来植物抗线虫基因工程新途径研究进展以及在分子抗病育种中的应用。     

植物寄生线虫分支酸变位酶基因的研究进展

 植物寄生线虫食道腺中表达的寄生基因编码的分泌蛋白在线虫侵入寄主植物、建立取食位点和抑制寄主的防御反应过程中起重要作用。利用植物寄生线虫食道腺削减cDNA文库及基于同源克隆等方法,鉴定了这些过程中起作用的分支酸变位酶(CM)基因。带有氨基酸末端信号肽的根结线虫CM、孢囊线虫CM与细菌CM的蛋白质序列非常相似。mRNA原位杂交表明,CM基因专门存在于植物寄生线虫的亚腹食道腺中。RT-PCR分析表明,它们的转录丰度在线虫寄生的早期丰度较高,在后期较低或者难以检测到。Southern杂交表明,这些CM基因为多基因家族。CM的蛋白质在专性内寄生线虫中广泛存在,表明这种多功能的酶在控制线虫侵染植物的过程中起重要作用。     

禾谷孢囊线虫(Heterodera avenae)的分子鉴定及抗性基因研究进展

禾谷孢囊线虫是温带禾谷类作物上的世界性重要病原线虫。本文回顾关于禾谷孢囊线虫的分子鉴定和亲缘分析等方面的研究,以及对国内外小麦品种抗性基因的筛选和应用等结果。根据上述方面的结果拟定更为合理的防治策略。     

酸黄瓜南方根结线虫病抗性的解剖学及其细胞学研究

为探明酸黄瓜南方根结线虫病抗性的内在机理,以抗病材料酸黄瓜与感病材料北京截头为试材,对南方根结线虫侵入与幼虫发育、根的解剖学及线虫侵入诱导形成的取食位点的细胞学结构进行了比较研究。结果表明,抗病材料酸黄瓜根系中线虫侵入率极显著低于感病材料北京截头(P0.01),酸黄瓜能够有效抵抗南方根结线虫的侵入;抗、感材料根系中雌雄虫个体比例分别为1∶12和1∶5(P0.01),抗性反应能够抑制线虫取食和幼虫发育;酸黄瓜根的解剖结构与普通栽培黄瓜相似,酸黄瓜的根不具有结构抗性;抗病反应中细胞发生过敏性坏死,感病反应中无此类现象发生。抗侵入、抑制取食和坏死反应是抗病材料酸黄瓜抗性反应的主要特征。     

近年水稻主要线虫病害的研究进展

目前,以拟禾谷根结线虫Meloidogyne graminicola、水稻干尖线虫Aphelenchoide besseyi、水稻潜根线虫Hirschmanniella oryzae、水稻茎线虫Ditylenchus angustus和旱稻孢囊线虫Heterodera elachista为主的水稻寄生线虫侵染水稻以及其它禾本科作物引致的线虫病害,已造成了严重的经济损失。近年来,对拟禾谷根结线虫的致病机制和寄主的防御机制等方面的研究已取得了显著进展,但对其它水稻寄生线虫与寄主互作机制的研究还存在较大空白。水稻寄生线虫的防治多依赖化学农药,抗性品种和生物防治等措施的实施存在一定的局限性。本文对上述5种主要水稻寄生线虫病的发生为害、致病机制以及防治方法等进行了综述,并对水稻寄生线虫致病机理的研究以及抗性品种、生物防治和诱导化合物的应用进行了探讨。     

大豆种质资源对大豆孢囊线虫的抗性评价

 大豆孢囊线虫(Heterodera glycines Ichinohe,SCN)是大豆(Glycine max (L.) Merrill)生产中的毁灭性害虫,种植抗性品种是控制其危害、减少产量损失的最佳途径。本研究通过温室盆栽实验评价了300份大豆种质对大豆孢囊线虫3号和4号生理小种的抗性。分别筛选到高抗和中抗3号生理小种的大豆种质27份和21份;高抗和中抗4号生理小种的大豆种质11份和9份。在所有供试材料中有10份材料同时对大豆孢囊线虫3号和4号生理小种表现高抗。线虫侵染实验表明,抗性材料对大豆孢囊线虫的发育有阻碍作用,并能显著降低最终形成的孢囊数。     

Genetics of soybean-Heterodera glycines system

Genetics of resistance to soybean cyst nematode (SCN), Heterodera glycines Ichinohe is very complex. Crosses involving PI 437654, which is resistant to all races of cyst nematodes with other sources of resistance (Peking, PI 88788, and PI 90763) indicated that resistance to race 3 was controlled by four genes, two of which were dominant resistance genes and the other two were recessive resistance genes. For race 5, a four gene model with two recessive and two dominant resistance genes in epistasis has been proposed. For race 14, the results suggested a three gene model with one dominant and two recessive alleles. Several other plant introductions have been isolated which have different genes conditioning resistance. Most of the currently grown soybean varieties derived resistance from Peking and/or PI 88788. Resistance to SCN in these soybean varieties has broken down because of the emergence of several new races and populations of SCN. The use of PI 437654 or Hartwig and other plant introductions with different genes for resistance will broaden genetic diversity and stabilize yield.     

小麦对小麦孢囊线虫抗病性研究进展

由小麦孢囊线虫引起的小麦孢囊线虫病发生分布范围广,防治困难,严重危害我国小麦生产.在我国危害小麦的孢囊线虫主要包括禾谷孢囊线虫(Heterodera avenae)和菲利普孢囊线虫(H.filipjevi).种植抗病小麦品种是防治小麦孢囊线虫病最经济有效的措施,近10年来,我国科学家制定了小麦孢囊线虫抗性评价标准,测试...     

Post‐infection development and histopathology of Meloidogyne arenaria race 1 on Arachis spp.

The reproductive behaviour of the root‐knot nematode Meloidogyne arenaria race 1 was compared on two wild species of Arachis (A. duranensis and A. stenosperma) and cultivated peanut (A. hypogaea cv. IAC‐Tatu‐ST). The three species were considered moderately susceptible, resistant, and susceptible, respectively. Penetration and development of the root‐knot nematode in the resistant species was reduced in comparison with that occurring in susceptible plants. Several cell features, including dark blue cytoplasm and altered organelle structure were observed in the central cylinder of A. stenosperma, indicating a hypersensitive‐like response (HR) of infested host cells. Neither giant cells, nor nematodes developed beyond the second stage, were found on A. stenosperma. Arachis duranensis showed a delay in the development of nematodes in the roots compared to A. hypogaea. The two wild peanut species were chosen to be the contrasting parents of a segregating population for mapping and further investigation of resistance genes.     

Selection for reproductive ability in Globodera pallida populations in relation to quantitative resistance from Solanum vernei and S. tuberosum ssp. andigena CPC2802

Four field populations of the nematode Globodera pallida were subjected to selection pressure for increased reproductive ability by rearing sub-populations continuously on four partially resistant potato genotypes for 12 generations. The resistance was derived from either Solanum vernei or from S. tuberosum spp. andigena CPC2802. After the 12th generation the original and sub-populations of nematodes were assessed for their reproductive ability on a susceptible genotype and on each of the partially resistant genotypes. Selection pressure was shown to have increased reproductive ability but the increases were specific to the source of resistance used. The average increase on the ex S. vernei clones was from 11% reproduction by the unselected populations to 35·5% reproduction after selection. On the clones derived from CPC2802, which had higher levels of resistance, the increases were larger with an average of 6·6% reproduction for the unselected but 47·4% reproduction after selection. The response to selection differed amongst the initial field populations with some rates of reproduction increased to as much as 79%. A RAPD based analysis of the original and sub-populations after selection indicated small but consistent changes in the genetic structure, which could have been a result of the selection pressure per se and/or the bottlenecks that the populations had gone though.     

Plant-derived enzyme inhibitors and lectins for resistance against plant-parasitic nematodes in transgenic crops

Due to increasing restrictions on the use of toxic and expensive nematicides, there is now a greater than ever need for crop cultivars that are resistant to plant-parasitic nematodes. Genetically engineered nematode resistance is not as well developed as other engineered traits but, even so, the first genetically modified plants with enhanced nematode resistance have been produced and tested. Plant-derived enzyme inhibitor and lectin genes are being evaluated for their ability to confer broad-spectrum nematode resistance in transgenic crop plants. Early indications are that these are likely to be effective. Gene pyramiding has potential to increase field durability and to widen the spectrum of nematodes controlled by any one transgenic line. © 1998 SCI.     

Host genetic resistance to root‐knot nematodes,Meloidogyne spp., in Solanaceae: from genes to the field

Root‐knot nematodes (RKNs) heavily damage most solanaceous crops worldwide. Fortunately, major resistance genes are available in a number of plant species, and their use provides a safe and economically relevant strategy for RKN control. From a structural point of view, these genes often harbour NBS–LRR motifs (i.e. a nucleotide binding site and a leucine rich repeat region near the carboxy terminus) and are organised in syntenic clusters in solanaceous genomes. Their introgression from wild to cultivated plants remains a challenge for breeders, although facilitated by marker‐assisted selection. As shown with other pathosystems, the genetic background into which the resistance genes are introgressed is of prime importance to both the expression of the resistance and its durability, as exemplified by the recent discovery of quantitative trait loci conferring quantitative resistance to RKNs in pepper. The deployment of resistance genes at a large scale may result in the emergence and spread of virulent nematode populations able to overcome them, as already reported in tomato and pepper. Therefore, careful management of the resistance genes available in solanaceous crops is crucial to avoid significant reduction in the duration of RKN genetic control in the field. From that perspective, only rational management combining breeding and cultivation practices will allow the design and implementation of innovative, sustainable crop production systems that protect the resistance genes and maintain their durability. © 2015 Society of Chemical Industry