大豆胞囊线虫抗性基因定位与克隆研究进展

大豆胞囊线虫(soybean cyst nematode, SCN)是大豆生产上一种危害严重的世界性害虫, 能给大豆生产造成极大损失。大豆抗性品种选育是防治其措施中最经济、有效的方法。大豆SCN抗性的分子遗传学研究是开展大豆SCN抗性分子育种的理论基础, 本文针对SCN抗性基因定位和克隆两个方面的研究现状进行了综述, 并对当前研究中存在的问题及发展前景进行了讨论与展望。     

大豆胞囊线虫抗性基因定位与克隆研究进展

大豆胞囊线虫（soybean cyst nematode,SCN）是大豆生产上一种危害严重的世界性害虫,能给大豆生产造成极大损失。大豆抗性品种选育是防治其措施中最经济、有效的方法。大豆SCN抗性的分子遗传学研究是开展大豆SCN抗性分子育种的理论基础,本文针对SCN抗性基因定位和克隆两个方面的研究现状进行了综述,并对当前研究中存在的问题及发展前景进行了讨论与展望。     

甘薯抗线虫病的遗传育种研究

甘薯线虫病是危害甘薯的主要病害,危害甘薯的线虫种类主要是根结线虫和茎线虫.甘薯生产上主要采用综合防治方法进行防治,其中选育抗病品种最为经济有效.本文综述了根结线虫和茎线虫病的抗源筛选、抗性机制、抗性的遗传和抗病育种等方面的研究进展,并展望了甘薯抗线虫病育种.     

甜菜夜蛾的抗性及抗性机理研究进展

甜菜夜蛾Spodoptera exigua(Hübner)是世界性农业害虫,近年来在我国由次要害虫上升为主要害虫。甜菜夜蛾对很多种化学杀虫剂和生物杀虫剂产生了抗性。本文分别阐述了甜菜夜蛾对常用杀虫剂如有机磷类、拟除虫菊酯类、氨基甲酸酯类、生长调节类杀虫剂、Bt杀虫剂等的抗性发展现状,并且对抗药性机理进行了总结,提出了抗性治理措施。     

双抗双高夏大豆种质鲁99-2的选育

优良种质创新是大豆新品种选育的关键。经过近20年的中间种质创新、亲本筛选、抗性选育、鉴定和品质检验等研究,育成了双抗双高的夏大豆优良种质鲁99-2。其对大豆胞囊线虫1、3、5号生理小种的抗性均为1级;对大豆花叶病毒y6株系的抗性也为1级;籽粒脂肪含量平均为22．09％,高值为22．67％;蛋白质含量平均为43．29％,高值为45．0％;蛋白质和脂肪合计含量平均为65．38％,高值达66．40％。鲁99-2的育成说明创造和利用优良种质、选择适宜的杂交亲本和采用有效的选育方法等对大豆育种至关重要。     

植物抗病毒病育种策略

为了得到抗病毒的寄主植物,植物育种学家进行了许多有益研究,形成了许多行之有效的抗病毒病育种策略。利用植物本身对病毒侵染所具有的一些免疫功能及其本身的一些抗性基因来获得抗性;利用来源于病毒自身基因的一些抗病性策略(PDR),如利用病毒外壳蛋白基因,病毒复制酶基因,病毒移动蛋白基因,病毒卫星RNA和反义RNA等,植物也可以获得抗性。近年来对由转录后RNA沉默引起的由RNA介导的病毒抗性策略(RMVR)也进行了深入地研究。除了PDR和RMVR以外,还有一些导致植物抗病毒的策略,包括利用美国商陆的病毒抗性蛋白(PAP),2',5’-寡腺苷酸合成酶,“植物抗体”以及病毒蛋白多肽来获得病毒抗性等。     

近年来国内外橡胶树育种研究新进展

从常规育种、高产育种和抗性育种方面综述近年来国外橡胶树育种研究的新进展,并结合我国橡胶树育种现状,提出我国橡胶树育种的方向,以期为我国橡胶树产量性状、遗传改良和抗逆性育种等提供借鉴.     

甜菜夜蛾对虫酰肼的抗性选育、风险评估及交互抗性

虫酰肼是目前防治甜菜夜蛾Spodoptera exigua（Hübner）的一种主要杀虫剂,为评估其抗性风险,在室内进行了抗性筛选和交互抗性的研究。采用饲料感染法,在甜菜夜蛾饲养75代期间用虫酰肼筛选62代,与起始种群相比抗性上升39.2倍,与室内敏感品系相比抗性上升141.3倍。在筛选的早、中、后期,现实遗传力h²分别为0.1075（F₀～F₂₅）、0.2780（F₂₆～F₅₀）和0.0538（F₅₁～F₇₅）,整个筛选62代现实遗传力为0.1556。抗性种群筛选43次（F55）后停止用药筛选,饲养21代后,与敏感品系相比,抗性水平由63.5倍下降到21倍,抗性下降3倍。说明甜菜夜蛾具有对虫酰肼产生抗性的风险,且抗性衰退缓慢,短期内很难恢复到敏感水平。交互抗性测定结果表明,上述室内选育的抗性品系对甲氧虫酰肼具有71.4倍的高水平交互抗性,对阿维菌素具有13.1倍的中等水平交互抗性,对甲维盐、茚虫威和呋喃虫酰肼分别具有7.0、8.4和4.7倍的低水平交互抗性,但对溴虫腈交互抗性不明显（1.9倍）。结果提示： 间断交替使用虫酰肼可以延缓抗性的发展,但除溴虫腈外,虫酰肼和其他几种新型杀虫剂之间的轮用可能不是甜菜夜蛾抗性治理的有效策略。     

RNA干扰在植物抗根结线虫病基因工程应用中的研究进展

植物根结线虫病对农业生产的危害连年加重,以轮作和化学农药为主的传统防治难以满足现代农业生产的需要.以常规的抗性育种和表达外源蛋白为主的抗线虫转基因育种主要受限于抗性基因的匮乏.而近来RNA干扰技术的应用为抗线虫基因工程带来新的突破,通过构建RNA干扰载体,在转基因植物中表达寄生线虫重要基因的dsRNA或siRNA,并经口针取食被导入线虫体内,并引发线虫的系统性RNA干扰反应,导致其出现寄生、发育、代谢、运动等障碍甚至致死,从而使转基因植物实现对寄生线虫的抗性.本文综述了RNAi介导的抗根结线虫基因工程方面的研究进展,分析探讨了这种新的策略的特点并展望了它的应用前景.     

利用KASP标记筛选含rhg1和Rhg4位点的大豆抗病资源

大豆胞囊线虫(SCN,soybean cyst nematode)病是一种世界性大豆病害,培育抗SCN大豆品种是防治SCN的重要措施.本研究利用来自抗SCN主效位点rhg1和Rhg4的2个KASP标记,对487份大豆材料进行筛选,选择含有抗性位点且农艺性状优异的材料;通过室内接种大豆胞囊线虫2号、4号、5号生理小种和新...     

Population genetic structure of the sugar beet cyst nematode Heterodera schachtii: a gonochoristic and amphimictic species with highly inbred but weakly differentiated populations

The sugar beet cyst nematode Heterodera schachtii is a soil-dwelling phytoparasitic nematode that feeds on beet roots. It is an important pest in most sugar beet growing areas, and better knowledge of its genetic variability is an important step to preserve the durability of resistant sugar beet varieties. The population genetic structure of this species in northern France was studied using five microsatellite markers. A hierarchical sampling design was used to investigate spatial structuring at the scale of the region, the field and the plant. Multilocus genotypes were obtained for single individual second-stage larvae, using only one individual per cyst in order to avoid the analysis of closely allied individuals (larvae from the same cyst share at least the same mother). A consistent trend of heterozygote deficit at all loci was observed at all spatial scales. Heterozygote deficit at the level of individual plants argues against its generation through a Wahlund effect. Inbreeding could be due to very limited active dispersal of larvae in the soil, favouring mating between siblings, such as larvae emerging from the same cyst. Such behaviour could have important consequences for the evolution of virulence in increasing the production of homozygous virulent individuals. Moreover, an analysis of molecular variance (amova) reveals that only 1.6% of the genetic variability is observed among regions, 3.7% among fields of the same region and 94.6% within fields. The very low level of genetic differentiation among fields is also indicated by low values of FST (相似文献   

Genetic approaches to sustainable pest management in sugar beet (Beta vulgaris)

Sugar beet (Beta vulgaris) is an important arable crop, traditionally used for sugar extraction, but more recently, for biofuel production. A wide range of pests, including beet cyst nematode (Heterodera schachtii), root‐knot nematodes (Meloidogyne spp.), green peach aphids (Myzus persicae) and beet root maggot (Tetanops myopaeformis), infest the roots or leaves of sugar beet, which leads to yield loss directly or through transmission of beet pathogens such as viruses. Conventional pest control approaches based on chemical application have led to high economic costs. Development of pest‐resistant sugar beet varieties could play an important role towards sustainable crop production while minimising environmental impact. Intensive Beta germplasm screening has been fruitful, and genetic lines resistant to nematodes, aphids and root maggot have been identified and integrated into sugar beet breeding programmes. A small number of genes responding to pest attack have been cloned from sugar beet and wild Beta species. This trend will continue towards a detailed understanding of the molecular mechanism of insect–host plant interactions and host resistance. Molecular biotechnological techniques have shown promise in developing transgenic pest resistance varieties at an accelerated speed with high accuracy. The use of transgenic technology is discussed with regard to biodiversity and food safety.     

Isolation and characterization of microsatellite loci in the sugar beet cyst nematode Heterodera schachtii

We report the isolation of five microsatellites loci from the sugar beet cyst nematode (Heterodera schachtii). Multilocus genotypes were obtained on individual larvae freshly emerged from cysts. Allelic diversity ranged from four to 27 among the five loci. The primers were tested for cross‐species amplification in six other species of phytoparasitic nematodes of the Heterodera genus. Those molecular markers will be used to study the genetic structure of this obligatory parasite and how it is affected by the use of resistant plants.     

dsRNA-mediated resistance to Beet Necrotic Yellow Vein Virus infections in sugar beet (Beta vulgaris L. ssp. vulgaris)

Rhizomania, one of the most devastating diseases in sugar beet, is caused by Beet Necrotic Yellow Vein Virus (BNYVV) belonging to the genus Benyvirus. Use of sugar beet varieties with resistance to BNYVV is generally considered as the only way to maintain a profitable yield on rhizomania-infested fields. As an alternative to natural resistance, we explored the transgenic expression of viral dsRNA for engineering resistance to rhizomania. Transgenic plants expressing an inverted repeat of a 0.4 kb fragment derived from the BNYVV replicase gene displayed high levels of resistance against different genetic strains of BNYVV when inoculated using the natural vector, Polymyxa betae. The resistance was maintained under high infection pressures and over prolonged growing periods in the greenhouse as well as in the field. Resistant plants accumulated extremely low amounts of transgene mRNA and high amounts of the corresponding siRNA in the roots, illustrative of RNA silencing as the underlying mechanism. The transgenic resistance compared very favourably to natural sources of resistance to rhizomania and thus offers an attractive alternative for breeding resistant sugar beet varieties.     

Effective and specific in planta RNAi in cyst nematodes: expression interference of four parasitism genes reduces parasitic success

Cyst nematodes are highly evolved sedentary plant endoparasitesthat use parasitism proteins injected through the stylet intohost tissues to successfully parasitize plants. These secretoryproteins likely are essential for parasitism as they are involvedin a variety of parasitic events leading to the establishmentof specialized feeding cells required by the nematode to obtainnourishment. With the advent of RNA interference (RNAi) technologyand the demonstration of host-induced gene silencing in parasites,a new strategy to control pests and pathogens has become available,particularly in root-knot nematodes. Plant host-induced silencingof cyst nematode genes so far has had only limited success butsimilarly should disrupt the parasitic cycle and render thehost plant resistant. Additional in planta RNAi data for cystnematodes are being provided by targeting four parasitism genesthrough host-induced RNAi gene silencing in transgenic Arabidopsisthaliana, which is a host for the sugar beet cyst nematode Heteroderaschachtii. Here it is reported that mRNA abundances of targetednematode genes were specifically reduced in nematodes feedingon plants expressing corresponding RNAi constructs. Furthermore,this host-induced RNAi of all four nematode parasitism genesled to a reduction in the number of mature nematode females.Although no complete resistance was observed, the reductionof developing females ranged from 23% to 64% in different RNAilines. These observations demonstrate the relevance of the targetedparasitism genes during the nematode life cycle and, potentiallymore importantly, suggest that a viable level of resistancein crop plants may be accomplished in the future using thistechnology against cyst nematodes. Key words: beet cyst nematode (BCN), soybean cyst nematode (SCN), host induced, in planta RNAi, resistance, RNAi, transgenic Received 19 August 2008; Revised 25 October 2008 Accepted 27 October 2008     

Genetic localization of four genes for nematode (Heterodera schachtii Schm.) resistance in sugar beet (Beta vulgaris L.)

Sugar beet (Beta vulgaris L.) is highly susceptible to the beet cyst nematode (Heterodera schachtii Schm.). Three resistance genes originating from the wild beets B. procumbens (Hs1 ^pro-1) and B. webbiana (Hs1 ^web-1, Hs2 ^web-7) have been transferred to sugar beet via species hybridization. We describe the genetic localization of the nematode resistance genes in four different sugar beet lines using segregating F₂ populations and RFLP markers from our current sugar beet linkage map. The mapping studies yielded a surprising result. Although the four parental lines carrying the wild beet translocations were not related to each other, the four genes mapped to the same locus in sugar beet independent of the original translocation event. Close linkage (0–4.6 cM) was found with marker loci at one end of linkage group IV. In two populations, RFLP loci showed segregation distortion due to gametic selection. For the first time, the non-randomness of the translocation process promoting gene transfer from the wild beet to the sugar beet is demonstrated. The data suggest that the resistance genes were incorporated into the sugar beet chromosomes by non-allelic homologous recombination. The finding that the different resistance genes are allelic will have major implications on future attempts to breed sugar beet combining the different resistance genes.     

DNA markers closely linked to nematode resistance genes in sugar beet (Beta vulgaris L.) mapped using chromosome additions and translocations originating from wild beets of the Procumbentes section

Summary Genes conferring resistance to the beet cyst nematode (Heterodera schachtii Schm.) have been transferred to sugar beet (Beta vulgaris L.) from three wild species of the Procumbentes section using monosomic addition and translocation lines, because no meiotic recombination occurs between chromosomes of cultured and wild species. In the course of a project to isolate the nematode resistance genes by strategies of reverse genetics, probes were cloned from DNA of a fragmented B. procumbens chromosome carrying a resistance gene, which had been isolated by pulsed-field gel electrophoresis. One probe (pRK643) hybridized with a short dispersed repetitive DNA element, which was found only in wild beets, and thus may be used as a molecular marker for nematode resistance to progenies of monosomic addition lines segregating resistant and susceptible individuals. Additional probes for the resistance gene region were obtained with a polymerase chain reaction (PCR)-based strategy using repetitive primers to amplify DNA located between repetitive elements. One of these probes established the existence of at least six different chromosomes from wild beet species, each conferring resistance independently of the others. A strict correlation between the length of the wild beet chromatin introduced in fragment addition and translocation lines and the repeat copy number has been used physically to map the region conferring resistance to a chromosome segment of 0.5-3 Mb.     

Sporamin-mediated resistance to beet cyst nematodes (Heterodera schachtii Schm.) is dependent on trypsin inhibitory activity in sugar beet (Beta vulgaris L.) hairy roots

Sporamin, a sweet potato tuberous storage protein, is a Kunitz-type trypsin inhibitor. Its capability of conferring insect-resistance on transgenic tobacco and cauliflower has been confirmed. To test its potential as an anti-feedant for the beet cyst nematode (Heterodera schachtii Schm.), the sporamin gene SpTI-1 was introduced into sugar beet (Beta vulgaris L.) by Agrobacterium rhizogenes-mediated transformation. Twelve different hairy root clones expressing sporamin were selected for studying nematode development. Of these, 8 hairy root clones were found to show significant efficiency in inhibiting the growth and development of the female nematodes whereas 4 root clones did not show any inhibitory effects even though the SpTI-1 gene was regularly expressed in all of the tested hairy roots as revealed by northern and western analyses. Inhibition of nematode development correlated with trypsin inhibitor activity but not with the amount of sporamin expressed in hairy roots. These data demonstrate that the trypsin inhibitor activity is the critical factor for inhibiting growth and development of cyst nematodes in sugar beet hairy roots expressing the sporamin gene. Hence, the sweet potato sporamin can be used as a new and effective anti-feedant for controlling cyst nematodes offering an alternative strategy for establishing nematode resistance in crops.