宁夏水稻代表性种质及后代抗稻瘟病基因型分析北大核心CSCD

以96份宁夏水稻代表性种质资源和47份杂交后代为试验材料,采用宁夏稻瘟病菌生理小种人工接种和自然诱发相结合的方法对其进行稻瘟病抗性的大田鉴定和病圃鉴定,评价了每个材料的稻瘟病抗性;同时采用8个主效抗稻瘟病基因的功能标记对上述材料进行抗病基因的分子检测,得到了28个不同的抗稻瘟病基因型,将不同基因型的稻瘟病抗性评价进行了差异显著性分析。结果表明,同时含有Pita、Pib、Pikm、Pikh、Pi9和Pi5共6个抗病基因组成的基因型的水稻材料对稻瘟病的抗性极显著高于其他基因型的抗性。Pita基因单独与Pikm、Pikh、Pi2、Pi5基因聚合时均表现出正向聚合效应,其中Pita与Pikh基因的聚合效应最强。当Pib与Pita+Pikh聚合时,表现出负向聚合效应。这为宁夏地区通过基因聚合方法选育广谱持久抗稻瘟病水稻新品种提供了重要的参考依据。     

抗稻瘟病水稻资源抗性基因Pita、Pib、Pi9以及Pikm的分布研究

利用抗稻瘟病水稻资源品种杂交,聚合多个抗性基因是培育持久抗稻瘟病水稻新品种的主要育种途径.利用分子标记技术对水稻抗性资源进行基因型鉴定是分子辅助聚合育种的基础.通过以亚华种业科学院稻瘟病病圃抗病水稻资源为材料,利用特异性分子标记对Pi9、Pita、Pib以及Pikm基因在水稻抗稻瘟病资源的分布进行了鉴定,初步建立了抗性基因数据库.同时对抗性基因及与抗性反应的相关性进行了探讨,结果表明以Pi9为主效基因,同时聚合Pita和Pib抗性基因能提高持久抗稻瘟病能力.     

三基因聚合改良恢复系福恢673的稻瘟病抗性

为了改良水稻优良恢复系福恢673的稻瘟病抗性,以该恢复系为轮回亲本,以携有3个稻瘟病抗性基因(Pi-1、Pi-9和Pi-k~h)的优质恢复系金恢1059为供体亲本,通过回交育种结合分子标记辅助选择,选育出10个导入了这3个抗稻瘟病基因的福恢673近等基因系,其遗传背景恢复率为92.96%–98.59%。抗性鉴定结果表明,这些近等基因系及其与不育系宜香A配制的杂种一代均表现抗稻瘟病,抗性明显强于对照福恢673和宜优673,且半数以上杂种一代基本保留了原组合的主要优点。用近等基因系Line 9配组的杂交稻新组合两优7283和金泰优683在区试中均表现出产量高、稻瘟病抗性强、生育期适中等特点,表明该近等基因系具较好的应用前景。     

宁夏水稻代表性种质及后代抗稻瘟病基因型分析

以96份宁夏水稻代表性种质资源和47份杂交后代为试验材料,采用宁夏稻瘟病菌生理小种人工接种和自然诱发相结合的方法对其进行稻瘟病抗性的大田鉴定和病圃鉴定,评价了每个材料的稻瘟病抗性;同时采用8个主效抗稻瘟病基因的功能标记对上述材料进行抗病基因的分子检测,得到了28个不同的抗稻瘟病基因型,将不同基因型的稻瘟病抗性评价进行了差异显著性分析。结果表明,同时含有Pita、Pib、Pikm、Pikh、Pi9和Pi5共6个抗病基因组成的基因型的水稻材料对稻瘟病的抗性极显著高于其他基因型的抗性。Pita基因单独与Pikm、Pikh、Pi2、Pi5基因聚合时均表现出正向聚合效应,其中Pita与Pikh基因的聚合效应最强。当Pib与Pita+Pikh聚合时,表现出负向聚合效应。这为宁夏地区通过基因聚合方法选育广谱持久抗稻瘟病水稻新品种提供了重要的参考依据。     

应用分子标记技术改良京作1号的稻瘟病抗性

稻瘟病是危害水稻产量的重要生物胁迫之一。实践证明,解决这一问题的最有效方法是培育具广谱、持久稻瘟病抗性的品种并推广种植。本研究以优质、高产、感稻瘟病的京作1号为轮回亲本,与稻瘟病抗性基因Pi9、Pigm和pi21的供体材料进行杂交、回交和复交,结合分子标记辅助选择和农艺性状筛选,培育不同的单基因导入系和聚合系。苗期人工接种多个稻瘟病菌的结果显示,Pi9抗性改良系的抗性频率达到100%,Pigm抗性改良系平均为90%,均极显著高于轮回亲本京作1号的抗性频率,且农艺性状与京作1号基本一致。pi21抗性改良系的抗性水平与京作1号没有明显差异,单株产量极显著低于京作1号。与轮回亲本相比,Pi9和pi21聚合系的抗性频率极显著提高,达到93.33%,但单株产量明显降低。研究结果证实了Pi9和Pigm基因在大幅度提高抗瘟性的同时对主要农艺性状影响小,都具有较大的育种利用价值。基因pi21抗谱较窄,抗性不强,且可能存在对产量的负效应,不宜单独用来改良水稻品种的稻瘟病抗性,需要与抗性强的主基因聚合,通过多次回交和自交打破该基因与产量的不利连锁累赘。     

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。     

分子标记辅助选择改良水稻不育系臻达A及其杂交种的稻瘟病抗性

水稻抗稻瘟病基因Pi25是一个遗传传递能力强的广谱抗性基因。本研究以携带抗稻瘟病基因Pi25的BL27为抗源供体,与优质、配合力强、感稻瘟病的水稻保持系臻达B为受体亲本进行杂交、回交创制水稻抗病保持系新种质,再与臻达A测交和回交进行不育系转育,结合分子标记辅助选择和农艺性状筛选,获得3个抗性基因纯合、农艺性状和开花习性均与臻达A相似的改良不育系株系。利用福建省近年来致病性代表的22个稻瘟病菌株对3个改良不育系及其15个杂交种进行抗性鉴定,3个改良不育系的抗性频率为95.45%~100%,15个杂交种的抗性频率均达75%以上,而原始对照臻达A及其杂交种的抗性频率仅为54.55%和40.91%~63.64%。自然病圃诱发鉴定表明,3个改良不育系的叶瘟和穗颈瘟均为0级,表现高抗,而对照臻达A的叶瘟为5级,穗颈瘟为7级,表现感病;15个杂交种均表现良好的稻瘟病抗性。进一步分析比较15个杂交种的产量、农艺性状和稻米品质表现,结果表明臻达A-Pi25-3改良不育系的综合性状表现最优,继续回交转育,于2015年育成了稻瘟病抗性强、配合力好、群体整齐和性状稳定的不育系,命名为157A。研究表明,抗稻瘟病基因Pi25不仅在水稻不育系臻达A的遗传背景下的抗性表达完全,且在不同水稻恢复系测交种的背景下同样表现出较高水平的抗性,说明抗性基因Pi25对不育系稻瘟病改良的效果明显。创制的新不育系157A的稻瘟病抗性显著提高,还基本保留了原来不育系高配合力等优良特性,为选育高产、优质、抗病杂交稻新品种提供了不育系新种质。     

分子标记辅助选择聚合Xa23,Pi9和Bt基因

利用分子标记辅助选择将高抗水稻白叶枯病的Xa23基因、广谱高抗稻瘟病的Pi9基因、抗水稻螟虫和稻纵卷叶螟的Bt基因聚合到同一株系中,获得了三基因聚合的纯合株系。病、虫抗性鉴定结果显示：聚合了Xa23、Pi9和Bt基因的株系HB1471、HB1473能同时抗白叶枯病、稻瘟病和稻纵卷叶螟;与Xa23、Pi9基因的供体材料L10相比,对白叶枯病和稻瘟病的抗谱相同、抗性水平相当;对稻纵卷叶螟抗性与Bt基因的供体亲本MH63-Bt水平相当。Xa23、Pi9和Bt三基因纯合株系可以作为水稻育种的多抗供体材料。     

苦参凝集素蛋白基因转化水稻的研究

以水稻杂交品种‘云资粳41号’为受体材料,通过农杆菌介导法将苦参凝集素蛋白基因(SFL)导入水稻细胞,采用氯酚红法和PCR检测外源基因是否整合到水稻基因组中。结果显示:外源基因成功转入水稻基因组,并获得一批转基因水稻植株;转基因植株叶片离体接种稻瘟病菌的检测结果显示,转基因植株与对照(非转基因植株)相比有明显的抗性,证明SFL基因在水稻中得到表达。研究表明,基于SFL基因所具备的广谱抗菌作用,可以预期所得转基因水稻植株很可能对水稻的多种病原菌具有良好的抗性,为选育新的抗稻瘟病水稻新品种以及拓宽栽培稻抗病遗传基础增加抗稻瘟病基因奠定了基础。     

定向改良超级早稻中早39稻瘟病抗性

稻瘟病是水稻生产中最具毁灭性的病害之一,稻瘟病菌生理小种变异快,抗性品种推广3～5年后抗性衰退风险较高,改良及培育抗稻瘟病菌新致病小种的品种是防治该病害最经济有效的方法。本研究以携带稻瘟病抗性基因Pi25的材料R6为供体亲本,超级早稻中早39为受体亲本和轮回亲本,通过杂交、回交和自交以及分子标记辅助选择技术,并结合室内喷雾接种、田间注射接种叶瘟以及病圃自然发病区穗颈瘟鉴定。综合考量抗性表型、基因型以及农艺性状,筛选出4个携带Pi25基因,叶瘟及穗颈瘟抗性较中早39提高,且农艺性状良好的株系FY82、FY90、FY125、FY137,同时对育成品系的系谱组成和抗性相关位点进行研究,初步阐明了育成品系较轮回亲本抗性水平提高的遗传基础。     

黄淮区粳稻抗稻瘟病基因Pi-ta、Pi-b、Pi54、Pikm的分子检测

利用水稻稻瘟病抗病基因Pi-ta、Pi-b、Pi54 和Pikm的功能标记对2016年山东省水稻中晚熟组区试、机插秧组区试的32个参试品系及连云港农业科学院科企水稻联合体黄淮粳稻区试16个品系进行了分子标记检测,结合稻瘟病抗性接种鉴定,对基因型与表型进行相关性分析。结果表明48个品种中携带Pi-ta、Pi-b、Pi54和Pikm抗性基因的品种数分别为15个、25个、26个和21个,其中鲁资稻7号、连粳14JD24含有4个基因的抗性等位基因,YS-6-6、济稻1号、D400等13个品种分别含有3个基因的抗性等位基因,临稻10号、丰稻2号、天和糯303等8个品种不含抗性等位基因。稻瘟病鉴定结果表明,48份品种中,济稻1号、圣稻072、连粳14JD24等4个品种表现中抗（MR）;临稻10、YS-6-6、圣稻053等26个品种表现中感（MS）;晶稻180、临13-105、圣稻504等15个品种表现感病（S）;H11-15、润农9号、晶稻160表现高感（HS）。Pi-ta、Pi-b、Pi54、Pikm 4个抗性基因已在黄淮区粳稻抗稻瘟病育种中得到广泛应用。其中Pikm与稻瘟病抗性综合指数存在显著相关性（r=0.477 5,P<0.01）。     

水稻抗稻瘟病基因Pi-d（t）^1、Pi-b、Pi-tα^2的聚合及分子标记选择

冈46B(G46B)是水稻生产应用中的一个农艺性状十分优良的保持系,其主要的缺陷是稻瘟病抗性较弱,通过对地谷,BL-1,Pi-4号等三个分别含抗病基因Pi-d(t)^1、Pi-b、Pi-tα^2的稻瘟病抗性材料与G46B聚合杂交,并利用抗病基因连锁的分子标记对杂交后代进行辅助选择,在聚合杂交的F2代及B1C1代群体中共获得了15株含Pi-d(t)^1、Pi-b、Pi-tα^2等三个抗稻瘟病基因的材料,其可能的基因型分别为：三基因杂合体Pi-d(t)^1pi-d(t)^1,Pi-bpi-b／Pi-tα^2 pi-tα^2 4株,双基因杂合体10株,其中Pi-d(t)^1Pi-d(t)^1／Pi-bpi-b／Pi-tα^2pi-tα^2 6株,Pi-d(t)^1pi-d(t)^1／Pi-bpi-b／Pi-tα^2Pi-tα^2 3株,Pi-d(t)^1pi-d(t)^1,Pi-bPi-6,Pi-tα^2 pi-tα^2 1株,双基因纯合体Pi-d(t)^1Pi-d(t)^1/Pi-bpi-b/Pi-tα^2Pi-tα^2仅1株,这一研究结果为进一步改良G46B的稻瘟病抗性奠定了基础,同时这一研究结果表明利用分子标记可快速、有效地实现多个抗病基因的聚合,大大提高水稻抗病育种的效率。     

Identification of the blast resistance gene Picl(t) from Chaling common wild rice (Oryza rufipogon Griff.)

Rice blast, caused by the fungal pathogen Magnaporthe oryzae (M. oryzae), is one of the most destructive and widespread plant diseases in the world. Utilization of resistance genes in rice breeding is considered to be an effective and economical method to control this disease. To identify new sources of blast resistance, a set of 1160 introgression lines (ILs) containing chromosome segments of Chaling common wild rice (Oryza rufipogon Griff.) in the genetic background of an elite indica rice variety 93-11 were developed and phenotyped in the blast nursery. Thirty-three ILs displaying stable blast resistance in three consecutive years were obtained. Among them, one line, IL1043, was subsequently found to be resistant to all of the 28 M. oryzae isolates from different regions through artificial inoculation in greenhouse. By combining bulk segregant analysis coupled with next-generation sequencing (BSA-seq) and recessive class analysis (RCA), a major blast resistance gene in IL1043, designated Picl(t), was mapped on rice chromosome 6 flanked by the markers RM527 and Indel6 with an interval of approximately 925 kb, which covers the Pi2/9 locus. These results will facilitate fine mapping and cloning of Picl(t), and the linked markers will further provide a useful tool for rice blast resistance breeding.     

Application of a simplified marker-assisted backcross technique for hybrid breeding in rice

Hybrid rice has contributed greatly to the self-sufficiency of the food supply in China. However, bacterial blight is a major disease that limits hybrid rice production in China. The study was conducted to develop an efficient breeding technique to improve the bacterial blight resistance in hybrid rice. A marker-assisted backcross breeding technique was adopted to improve HN189, an elite restorer line containing the Pi1 gene. This breeding technique was simplified to foreground selection with only one generation of backcrossing and background selection based on phenotypic selection. A novel bacterial blight resistance gene, Xa23, was introgressed into HN189. Two improved restorer lines, HBH145 (with one generation of backcrossing) and HBH146 (with two generations of backcrossing), were obtained that had a significant bacterial blight resistance advantage over HN189. The corresponding hybrid combination Tianyou H145 (Tianfeng A / HBH145) was certified one year earlier than Qianyou H146 (Qianjiang 1A / HBH146). The use of the marker-assisted backcross breeding technique with one generation of backcrossing and without background selection in rice breeding programs shortened the breeding period of the rice.     

The eight amino-acid differences within three leucine-rich repeats between Pi2 and Piz-t resistance proteins determine the resistance specificity to Magnaporthe grisea

The rice blast resistance (R) genes Pi2 and Piz-t confer broad-spectrum resistance against different sets of Magnaporthe grisea isolates. We first identified the Pi2 gene using a map-based cloning strategy. The Pi2 gene is a member of a gene cluster comprising nine gene members (named Nbs1-Pi2 to Nbs9-Pi2) and encodes a protein with a nucleotide-binding site and leucine-rich repeat (LRR) domain. Fine genetic mapping, molecular characterization of the Pi2 susceptible mutants, and complementation tests indicated that Nbs4-Pi2 is the Pi2 gene. The Piz-t gene, a Pi2 allele in the rice cultivar Toride 1, was isolated based on the Pi2 sequence information. Complementation tests confirmed that the family member Nbs4-Piz-t is Piz-t. Sequence comparison revealed that only eight amino-acid changes, which are confined within three consecutive LRR, differentiate Piz-t from Pi2. Of the eight variants, only one locates within the xxLxLxx motif. A reciprocal exchange of the single amino acid between Pi2 and Piz-t did not convert the resistance specificity to each other but, rather, abolished the function of both resistance proteins. These results indicate that the single amino acid in the xxLxLxx motif may be critical for maintaining the recognition surface of Pi2 and Piz-t to their respective avirulence proteins.     

Genetic characterization and fine mapping of the blast resistance locus Pigm(t) tightly linked to Pi2 and Pi9 in a broad-spectrum resistant Chinese variety

The identification and utilization of broad-spectrum resistance genes have been proven the most effective and economical approach to control rice blast disease. To understand the molecular mechanism of broad-spectrum resistance to rice blast, we conducted genetic and fine mapping analysis of the blast resistance gene in a Chinese rice variety: Gumei 4 (GM4) identified with broad-spectrum resistance and used in rice breeding for blast resistance for more than 20 years. Genetic and mapping analysis indicated that blast resistance to nine isolates of different Chinese races in GM4 was controlled by the same dominant locus designated as Pigm(t) that was finely mapped to an approximately 70-kb interval between markers C5483 and C0428 on chromosome 6, which contains five candidate NBS--LRR disease resistance genes. The allelism test showed that Pigm(t) was either tightly linked or allelic to Pi2 and Pi9, two known blast resistance genes. Mapping information also indicated that another blast resistance gene Pi26(t) might also be located at the same region. Candidate genes were identified by sequence analysis of the Nipponbare and Pi9 locus and the corresponding region in GM4. Sequence divergence of candidate genes was observed between GM4 and model varieties Nipponbare and 9311, and Pi9. Our current study provides essential information and new genetic resource for the cloning of functional resistance gene(s) and for marker-assisted selection in rice breeding for broad-spectrum blast resistance.Yiwen Deng and Xudong Zhu contributed equally to this work.     

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。