稻瘟病菌无毒基因研究进展

水稻与稻瘟病菌之间的特异互作符合基因对基因假说。本文将从稻瘟病菌与水稻抗病基因间的互作特点、稻瘟病菌的分子标记、已克隆的稻瘟病菌无毒基因三个方面对稻瘟病菌无毒基因研究进展作简要介绍     

稻瘟菌无毒基因研究进展

稻瘟菌是引起水稻稻瘟病的病原物。水稻与稻瘟菌间存在广泛而特异的相互作用,是研究寄主与病原物互作的重要模式系统。本文对稻瘟菌与水稻互作最重要的激发子―无毒基因的研究现状进行了概括,讨论了无毒基因的定位、克隆方法以及已克隆无毒基因的功能及进化研究,同时对今后无毒基因研究的重要方向进行了探讨,为深入理解无毒基因的功能及与水稻可能的互作关系奠定了基础。     

稻瘟菌无毒基因研究进展

无毒基因编码的产物激发病原物与植物特异性相互作用。水稻与稻瘟菌之间的特异互作符合“基因对基因”关系。从研究稻瘟菌无毒基因的意义、已鉴定和克隆的稻瘟菌无毒基因、稻瘟菌无毒基因与其抗病基因的互作特点等几个方面,对稻瘟菌无毒基因研究进展作了简要评述 。     

湖南桃江病圃稻瘟病菌的无毒基因及水稻抗瘟单基因联合抗性分析

【目的】鉴定湖南省桃江病圃稻瘟病菌无毒基因型,为合理搭配种植湖南省水稻抗瘟品种和抗病育种提供依据。【方法】在湖南桃江病圃采集水稻品种"丽江新团黑谷"(LTH)稻瘟菌病样,用单孢分离法分离稻瘟病菌单孢并纯化获得单孢菌株,用针刺离体法将菌株接种到以"LTH"为轮回亲本培育而成的24个含单抗瘟基因的水稻5叶期第5叶片上,对供试菌株进行无毒基因鉴定,并应用联合致病性系数和联合抗病性系数分析抗瘟基因组合间的互作。【结果】供试92个稻瘟病单孢菌株含有全部的24个无毒基因,对24个已知含单抗瘟基因的水稻材料表现出不同程度的毒力水平,含水稻抗瘟基因Pi-20对供试菌株抗菌频率最高,达54.35%;通过联合致病性系数和联合抗病性系数分析抗瘟基因组合间的互作,结果表明最佳搭配组合为Pi-20×Pi-k~s(RAC=0.28,PAC=0.23)。【结论】湖南省桃江病圃稻瘟病菌致病力较强,24个抗瘟基因多已感病化,含抗性基因Pi-20与Pi-k、Pi-k~s、Pi-3组合的水稻品种目前可在湖南省推广利用,但需研究引进新的抗瘟基因。     

水稻稻瘟病抗性基因研究概况

稻瘟病是由稻瘟病菌引起的世界性水稻病害,对水稻生产构成严重威胁。分子标记辅助培育持久抗性品种是目前解决稻瘟病抗病品种感病化问题的有效措施。稻瘟病菌-水稻之间的相互作用机理,DNA分子标记的开发与应用,稻瘟病抗性基因定位、克隆与分离及其功能表达等方面的研究进展在很大程度上影响分子标记辅助育种的进程。就此方面的研究概况作一综述。     

水稻抗稻瘟病基因资源与分子育种策略

稻瘟病是水稻主要病害之一。利用抗病品种是防治稻瘟病最经济、有效和安全的措施。近年来,随着植物先天免疫机制、抗病分子生物学以及水稻和稻瘟菌基因组学研究的不断深入,一系列参与病原菌识别和防卫信号传导与应答,以及外源抗菌蛋白、病原菌激发子等抗病相关基因陆续被鉴定和克隆,为提高水稻抗稻瘟病能力提供了一些新的基因资源、育种策略和技术。本文概述了国内外近年来克隆的主要抗稻瘟病基因资源及其在分子育种研究中应用的进展,提出了通过转基因手段整合不同防卫反应关键调控基因的抗稻瘟病聚合育种策略。     

水稻抗稻瘟病基因的标记辅助选择及定位克隆

水稻抗稻瘟病基因-稻瘟病菌无毒基因相互作用体系是当今植物分子病理学和抗病育种学研究领域的模式体系之一,其中抗病基因的分子定位与克隆及其标记辅助选择已成为该体系的重要内容。本文就这方面的研究进展作一简要综述,以期为水稻抗病育种提供有益的信息。     

稻瘟菌无毒基因的分子检测及其指纹类型分析

针对稻瘟菌中Avr-Pita与AvrPiz-t两个无毒基因,设计特异性引物,利用PCR方法对吉林省103株稻瘟菌菌株进行分子检测,并结合AVR-Pib、AVR-C039、PWL2和ACE1 4个无毒基因在其中85个菌株中的分布情况,绘制出基于这6个无毒基因的指纹类型.结果表明,Avr-Pita基因和AvrPiz-t基因在吉林省稻瘟菌中的分布频率分别为86.41%和62.14%;建立的指纹类型显示,85株稻瘟菌分布于9种类型中,其中类型1为主要类型,其分布频率为40.00%:根据30个已知生理小种的菌株在指纹类型中的分布情况,初步发现类型7与吉林省优势生理小种ZE1可能存在对应关系,并应用于稻瘟菌优势生理小种的特异性分子检测;其他指纹类型与中国生理小种并无明显对应关系.明确了无毒基因Avr-Pita与AvrPiz-t在吉林省稻瘟菌中的分布情况,构建了无毒基因的指纹类型,为水稻抗瘟育种和稻瘟菌优势小种的分子监测提供理论依据.     

水稻广谱抗稻瘟病基因研究进展

稻瘟病是水稻生产中的最严重病害之一,由于稻瘟菌小种的高度变异性,垂直抗性基因难以持续控制稻瘟病的危害,因此,克隆和利用广谱持久抗瘟基因被认为是解决稻瘟病问题最经济有效的策略。本文从广谱抗源的筛选与利用,广谱抗瘟基因的定位、克隆与应用等方面对水稻广谱抗稻瘟病基因研究取得的进展进行了概述,并介绍了广谱抗性分子机理的最新研究进展。基于国内外稻瘟病抗性基因研究的现状及趋势,以及我国丰富的抗瘟水稻种质资源,克隆越来越多的广谱抗瘟基因具有重要的理论与应用价值。     

水稻野生种质优异基因分子标记定位和利用的研究进展

野生稻由于长期处于野生状态,经受了各种灾害和不良环境的自然选择,抗逆性较强,是天然的基因库,保存着栽培稻不具有或已经消失了的特异基因。挖掘野生稻特异基因的研究日益受到重视。本文总结了近3年来在野生稻特异性状基因定位、克隆和育种利用方面的研究进展。 Abstract:Wild rice has adapted to weather and unfavorable environments under natural selection.It has been well recognized as a natural gene bank that conserves a lot of specific genes presently not available for extinct in the cultivated rice.There is an urgent need to explore these specific genes.The present paper summarized current researches in molecular mapping and cloning of useful genes from wild rice,and their potential application in breeding.     

Genetic Mapping of Magnaporthe grisea Avirulence Gene Corresponding to Leaf and Panicle Blast Resistant QTLs in Jao Hom Nin Rice Cultivar

The avirulence characteristic of Magnaporthe grisea isolate TH16 corresponding to Jao Hom Nin (JHN) rice cultivar was studied by mapping population of 140 random ascospore progenies derived from the cross between B1-2 and TH16 isolates. Segregation analyses of the avirulence characteristic performing on JHN rice at the seedling and flowering stages were performed in this mapping population. We used the reference map of Guy11/2539 to choose microsatellite DNA markers for mapping the avirulence gene. The genetic map of this population was constructed from 39-microsatellite markers. The genetic map was spanned by covering seven chromosomes with an average distance of 11.9 cM per marker. In mapping population the distribution of pathogenic and non-pathogenic progenies on JHN rice were found to be fitted to 1 : 1 ratio for two of the rice stages, seedling and flowering stages. The Quantitative Trait Loci (QTL) analysis for avirulence genes corresponding to two rice stages were located at the same region on chromosome 2 between markers Pyms305 and Pyms435. The LOD score and percentage of phenotypic variance explained (PVE) on two rice stages were 5.01/16.69 and 6.73/20.26, respectively. These loci were designated as Avr-JHN(lb) and Avr-JHN(pb) corresponding to leaf and panicle blast characteristics. The findings of this study can be the initial step for positional cloning and identifying any function of avirulence genes corresponding to leaf and panicle blast characteristics.     

植物病原物无毒基因及其功能

植物抗病基因与病原物无毒基因产物间直接或间接相互作用导致产生的基因对基因抗性是植物抗病性的重要形式。无毒基因已在多种植物病原物 ,包括真菌、细菌、病毒和卵菌等中得到克隆。绝大多数已克隆无毒基因之间 ,及其与已知蛋白之间 ,均无显著序列同源性。然而 ,多数已克隆植物抗病基因有较高序列一致性 ,产物往往具有相似的结构域。由序列一致性很高的抗病基因产物与没有明显序列同源性的无毒基因产物相互作用 ,介导产生的过敏性细胞坏死和抗病性 ,在产生速度、强度和组织特异性等方面均可能有显著差异。无毒基因具有双重功能 :在含互补抗病基因植物中表现无毒效应 ,而在不含互补抗病基因植物中显示小种、菌株、致病型、或种特异性毒性效应     

国外引进水稻种质资源的稻瘟病抗性基因检测与评价

为了筛选出福建省水稻稻瘟病重发区育种中可利用的新抗性资源,在福建省上杭县对156份外引水稻种质资源进行了2年田间自然诱发鉴定,并对Pi2、Pi9、Pi5、Pi54、Pikm、Pita、Pia和Pib等8个稻瘟病抗性基因做了分子检测。结果表明:156份资源对苗瘟、叶瘟、穗颈瘟和综合抗性表现抗病的分别有10份、14份、29份和26份,且苗瘟抗性级别与叶瘟抗性级别(r=0.816,P<0.01)、苗瘟抗性级别与穗颈瘟抗性级别(r=0.347,P<0.01)、以及叶瘟抗性级别与穗颈瘟抗性级别(r=0.344,P<0.01),均呈极显著正相关。分子标记检测到携带稻瘟病抗性基因Pi9、Pi2、Pi54、Pikm、Pi5、Pib、Pia和Pita的水稻资源分别有1、6、20、22、37、88、101和106份,其中携带稻瘟病抗性基因Pi9和Pi2的水稻资源的抗性表现较好,表现抗病的超过60%,携带其他稻瘟病抗性基因的水稻资源表现抗病的均在50%以下;水稻资源携带0~6个稻瘟病抗性基因,随着携带抗性基因数目增加,抗病率呈上升趋势,综合抗性等级呈下降趋势。进一步研究发现,携带Pi9+Pi5+Pikm+Pia、Pi5+Pib+Pita+Pikm+Pia和Pi2+Pi54+Pib+Pita+Pikm+Pia等3个基因型的水稻资源,稻瘟病抗性较好。最后,筛选了8份稻瘟病抗性较好的材料,提供育种者参考、利用。     

水稻香味基因及其在育种中的应用研究进展

水稻(Oryza sativa)为世界上30多亿人口的主食,是最重要的粮食作物之一。作为栽培水稻类型之一的香稻,由于其稻米具有独特的香味,在国内外市场上深受广大消费者的青睐。近年来,随着水稻功能基因组和测序技术的快速发展,针对水稻香味基因的研究取得了较大进展,并开发了一系列的功能标记应用于香味基因筛选和品种培育。该文综述了水稻香味基因的遗传基础、基因功能及其调控、功能标记的开发及应用的新进展,以期为香稻新品种培育提供借鉴与参考。     

水稻穗瘟防卫反应相关基因的分离和鉴定

以遗传背景相近、对叶瘟抗性相同但对穗瘟抗性不同的两个水稻株系为材料,利用抑制消减杂交（SSH）技术构建穗瘟抗／感消减cDNA文库,经差异筛选及序列分析,共获得90个独立的差异表达cDNA克隆,根据与它们刚源的基因功能推测,这些克隆可能参与了对病原菌的防卫反应、信号传导和转录等一些重要的生物学过程。利ⅢRT-PCR分析了26个所筛选到的cDNA克隆在抗／感植株接种后的表达,17个基因的表达差异得到验证。对这螳差异表达基因在抗感株系接种后不同时间点的表达谱也进行了RT-PCR的分析。文章首次报道了什关水稻对穗瘟抗性在mRNA水平进行研究,为深入研究水稻对穗瘟抗性的遗传机理打下了基础。     

Outbreak of Rice Blast Disease at Yeoju of Korea in 2020

Rice blast is the most destructive disease threatening stable rice production in rice-growing areas. Cultivation of disease-resistant rice cultivars is the most effective way to control rice blast disease. However, the rice blast resistance is easy to breakdown within years by blast fungus that continually changes to adapt to new cultivars. Therefore, it is important to continuously monitor the incidence of rice blast disease and race differentiation of rice blast fungus in fields. In 2020, a severe rice blast disease occurred nationwide in Korea. We evaluated the incidence of rice blast disease in Yeoju and compared the weather conditions at the periods of rice blast disease in 2019 and 2020. We investigated the races and avirulence genes of rice blast isolates in Yeoju to identify race diversity and genetic characteristics of the isolates. This study will provide empirical support for rice blast control and the breeding of blastresistant rice cultivars.     

Cloning and in silico Mapping of Resistance Gene Analogues Isolated from Rice Lines Containing Known Genes for Blast Resistance

We amplified resistance gene analogues (RGAs) from the genomic DNA of 10 rice lines having varying degree of resistance to Magnaporthe grisea by using degenerate primers and various RGAs were mapped in silico on different rice chromosomes. The amplified products were grouped into 3–8 restriction fragment length polymorphic classes by using Mbo1 and Alu1 restriction enzymes. Of 98 RGAs obtained in this study, 65 RGA clones showed more than 95% homology with various RGAs sequences present in the GenBank. Phylogenetic analysis of these RGAs formed 11 groups. Using sequence homology approach, RGAs isolated in this study were physically mapped on 23 loci on chromosomes 1, 2, 3, 4, 5, 6, 7, 8, 10, 11 and 12. Twenty RGAs were mapped near to the chromosomal regions containing known genes/QTLs for rice blast, bacterial leaf blight and sheath blight resistance. Thirty‐nine RGA sequences also contained open reading frame representing signature of potential disease resistance genes.     

Identification of Two Blast Resistance Genes in a Rice Variety, Digu

Blast, caused by Magnaporthe grisea is one of most serious diseases of rice worldwide. A Chinese local rice variety, Digu, with durable blast resistance, is one of the important resources for rice breeding for resistance to blast (M. grisea) in China. The objectives of the current study were to assess the identity of the resistance genes in Digu and to determine the chromosomal location by molecular marker tagging. Two susceptible varieties to blast, Lijiangxintuanheigu (LTH) and Jiangnanxiangnuo (JNXN), a number of different varieties, each containing one blast resistance gene, Pik^s, Pia, Pik, Pi‐b, Pi‐k^p, Pi‐ta², Pi‐ta, Pi‐z, Pi‐i, Pi‐k^m, Pi‐z^t, Pi‐t and Pi‐11, and the progeny populations from the crosses between Digu and each of these varieties were analysed with Chinese blast isolates. We found that the resistance of Digu to each of the two Chinese blast isolates, ZB13 and ZB15, were controlled by two single dominant genes, separately. The two genes are different from the known blast resistance genes and, therefore, designated as Pi‐d(t)1 and Pi‐d(t)2. By using bulked segregation method and molecular marker analysis in corresponding F₂ populations, Pi‐d(t)1 was located on chromosome 2 with a distance of 1.2 and 10.6 cM to restriction fragment length polymorphism (RFLP) markers G1314A and G45, respectively. And Pi‐d(t)2 was located on chromosome 6 with a distance of 3.2 and 3.4 cM to simple sequence repeat markers RM527 and RM3, respectively. We also developed a novel strategy of resistance gene analogue (RGA) assay with uneven polymerase chain reaction (PCR) to further tag the two genes and successfully identified two RGA markers, SPO01 and SPO03, which were co‐segregated toPi‐d(t)1 and Pi‐d(t)2, respectively, in their corresponding F₂ populations. These results provide essential information for further utilization of the Digu's blast resistance genes in rice disease resistance breeding and positional cloning of these genes.