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。     

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。     

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。     

抗稻瘟病基因Pib、Pita、Pi5、Pi25和Pi54在我国水稻微核心种质中的分布

稻瘟病抗性基因Pib、Pita、Pi5、Pi25和Pi54等对我国不同稻区的稻瘟病菌表现广谱抗性,在水稻育种中具有较高的利用价值。本研究利用各基因的功能性分子标记,检测并分析了Pib、Pita、Pi5、Pi25和Pi54在我国水稻微核心种质中的分布情况。结果显示,124份种质携带1～4个目标基因,其中黄丝桂占携带基因Pib、Pita、Pi5和Pi54;南雄早油占和乌嘴红谷分别携带3个基因Pita、Pi25和Pi54及Pita、Pi5和Pi54;叶里藏花和辽粳287等35份分别携带Pi5和Pi54、Pita和Pi54、Pib和Pi54、Pib和Pita、Pi25和Pi54、Pib和Pi5、Pita和Pi5、Pita和Pi25、Pi5和Pi25;抚宁紫皮粳子和隆化毛葫芦等86份分别携带单个目标基因。为了解我国水稻微核心种质的抗稻瘟病基因型,以及有效利用优异种质改良水稻抗瘟病性提供了信息。     

稻瘟病抗性基因Pita和Pib在我国水稻主栽品种中的分布

主效抗稻瘟病基因Pita和Pib在我国很多稻区表现高水平的稻瘟病抗性,被广泛应用于我国的水稻育种和生产.但这2个基因在国内主栽品种中的分布及利用情况一直缺乏详细的资料,致使育种利用上存在着盲目性.本研究利用源于Pita和Pib基因本身的特异性分子标记,结合稻瘟病菌接种鉴定,检测和分析了我国58份水稻主栽品种(杂交稻亲本)的Pita和Pib抗性基因型.结果表明,特籼占25、佳禾早占、密阳46、测64-7等4个籼稻品种携带Pita和Pib 2个基因;籼小占等4个籼稻品种(系)和早丰9号等5个粳稻品种携带抗性基因Pita;绵恢501等5个籼稻品种(系)和粳稻品种武育粳7号、辽粳454携带抗性基因Pib.     

辽宁地区水稻资源抗稻瘟病基因的检测分析

为了明确辽宁地区水稻资源中抗稻瘟病基因的分布情况及抗病效应,选取辽宁地区水稻资源176份,鉴定了抗稻瘟病基因pi21、Pi36、Pi37、Pita、Pid2、Pid3、Pi5及Pib在这些材料中的分布情况,并接种鉴定了这些材料对稻瘟病的抗性。结果表明:176份供试材料中,83份对稻瘟病表现抗病,栽培稻、杂草稻及农家种中抗病品种所占的比率分别为41.48%、1.14%及4.54%。抗稻瘟病基因pi21、Pi36和Pi37在所有参试材料中均未检测到,且分别有74份、49份、47份、52份及89份材料携带Pita、Pid2、Pid3、Pi5及Pib的抗病等位基因。抗病基因绝大部分分布在栽培种中,农家种和杂草稻中分布较少。不含有抗稻瘟病基因和只携带单个抗病基因的材料对稻瘟病的抗性均较差,而抗病基因聚合可不同程度提高材料的抗性。经检测,不含有本试验鉴定的pi21等8个已克隆抗病基因的材料共32份,其中表现抗病的占21.87%;只携带1个抗稻瘟病基因的材料为52份,表现抗病的占17.31%;携带2个抗稻瘟病基因的材料为39份,表现抗病的占69.23%,其中以携带Pita+Pi5的材料最多(14份),且均表现抗病;携带3个抗稻瘟病基因的材料为31份,表现抗病的占77.42%,以携带Pita+Pid3+Pi5的材料抗性最强;携带4个抗稻瘟病基因的水稻材料22份,表现抗病的占72.73%,携带5个抗病基因的水稻材料未检测到。     

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。     

优质稻品种粤农丝苗稻瘟病广谱抗性遗传及基因组成分析

粤农丝苗是广东省近年来选育的常规优质稻主栽品种,对稻瘟病具有很强的抗性,可作为恢复系亲本应用于杂交稻育种。本研究利用来源于华南稻区的稻瘟病菌株对粤农丝苗的抗谱进行测定。结果显示,粤农丝苗具有广谱抗性;为深入了解该品种的抗性基因组成和抗性遗传规律,对粤农丝苗×丽江新团黑谷的F2遗传分离群体进行抗病遗传分析,结果表明粤农丝苗的稻瘟病抗性可能受多基因控制;以Pi1、Pi2、Pi9、Pib、Pita等主效抗病基因分子标记进行检测,结果表明粤农丝苗至少包含Pi2和Pib两个抗性位点。本研究结果初步揭示了粤农丝苗高抗稻瘟病的遗传基础,为抗病品种的推广应用提供重要分子依据。     

广东地方稻种暹罗占抗稻瘟病基因分析

广谱抗病基因的利用是控制稻瘟病最有效和最经济的方法。来源于华南的地方稻种暹罗占对稻瘟病菌表现出广谱抗性,以普感品种丽江新团黑谷为轮回亲本选育的暹罗占近等基因系NIL-XLZ对测试的44个不同来源稻瘟病菌的抗性频率为84.4%,其抗谱优于广谱抗瘟基因Pi2、Piz,与抗瘟基因Pi9和Pi50相近。为进一步了解暹罗占抗稻瘟病的遗传基础,以感病品种广恢290为母本、暹罗占为父本,构建了广恢290/暹罗占的F2遗传分离群体。选取致病谱较广的稻瘟病菌代表菌株GD08-T19对来源于广恢290/暹罗占的F1与F2个体进行了抗病遗传分析,结果显示F1个体全表现抗病,1760个F2个体的抗感分离比率为4.06∶1,表明暹罗占至少含有一个显性的抗稻瘟病基因。利用分布于Pi2、Pi1、Pita座位附近的44对SSR引物,对构建的抗/感基因池及遗传分离个体进行了分析,将暹罗占含有的一个抗瘟基因定位于水稻第6染色体Pi2/Pi9/Pi50基因家族区域247 kb的范围内。抗菌谱分析、基因特异性分子标记检测及测序分析结果表明:暹罗占含有广谱抗瘟基因Pi50。本研究结果为暹罗占在水稻抗病育种上的应用提供了重要依据。     

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。     

The in silico map-based cloning of Pi36, a rice coiled-coil nucleotide-binding site leucine-rich repeat gene that confers race-specific resistance to the blast fungus

The indica rice variety Kasalath carries Pi36, a gene that determines resistance to Chinese isolates of rice blast and that has been located to a 17-kb interval on chromosome 8. The genomic sequence of the reference japonica variety Nipponbare was used for an in silico prediction of the resistance (R) gene content of the interval and hence for the identification of candidate gene(s) for Pi36. Three such sequences, which all had both a nucleotide-binding site and a leucine-rich repeat motif, were present. The three candidate genes were amplified from the genomic DNA of a number of varieties by long-range PCR, and the resulting amplicons were inserted into pCAMBIA1300 and/or pYLTAC27 vectors to determine sequence polymorphisms correlated to the resistance phenotype and to perform transgenic complementation tests. Constructs containing each candidate gene were transformed into the blast-susceptible variety Q1063, which allowed the identification of Pi36-3 as the functional gene, with the other two candidates being probable pseudogenes. The Pi36-encoded protein is composed of 1056 amino acids, with a single substitution event (Asp to Ser) at residue 590 associated with the resistant phenotype. Pi36 is a single-copy gene in rice and is more closely related to the barley powdery mildew resistance genes Mla1 and Mla6 than to the rice blast R genes Pita, Pib, Pi9, and Piz-t. An RT-PCR analysis showed that Pi36 is constitutively expressed in Kasalath.     

Phenotypic screening and molecular analysis of blast resistance in fragrant rice for marker assisted selection

Experiments were conducted to identify blast-resistant fragrant genotypes for the development of a durable blast-resistant rice variety during years 2012–2013. The results indicate that out of 140 test materials including 114 fragrant germplasms, 25 differential varieties (DVs) harbouring 23 blast-resistant genes, only 16 fragrant rice germplasms showed comparatively better performance against a virulent isolate of blast disease. The reaction pattern of single-spore isolate of Magnaporthe oryzae to differential varieties showed that Pish, Pi9, Pita-2 and Pita are the effective blast-resistant genes against the tested blast isolates in Bangladesh. The DNA markers profiles of selected 16 rice germplasms indicated that genotype Chinigura contained Pish, Pi9 and Pita genes; on the other hand, both BRRI dhan50 and Bawaibhog contained Pish and Pita genes in their genetic background. Genotypes Jirakatari, BR5, and Gopalbhog possessed Pish gene, while Uknimodhu, Deshikatari, Radhunipagol, Kalijira (3), Chinikanai each contained the Pita gene only. There are some materials that did not contain any target gene(s) in their genetic background, but proved resistant in pathogenicity tests. This information provided valuable genetic information for breeders to develop durable blast-resistant fragrant or aromatic rice varieties in Bangladesh.     

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）。     

Polymorphism analysis of genomic regions associated with broad-spectrum effective blast resistance genes for marker development in rice

Cultivated European rice germplasm is generally characterized by moderate to high sensitivity to blast, and blast resistance is therefore one of the most important traits to improve in rice breeding. We collected a panel of 25 rice genotypes containing 13 broad range rice resistance genes that are commonly used in breeding programs around the world: Pi1, Pi2, Pi5, Pi7, Pi9, Pi33, Pib, Pik, Pik-p, Pita, Pita ² , Piz and Piz-t. The efficiency of the selected Pi genes towards Italian blast pathotypes was tested via artificial inoculation and under natural field infection conditions. To characterize haplotypes present in the chromosomal regions of the blast resistance genes, a polymorphism search was conducted in the sequence regions adjacent to the blast resistance by examining DNA from the Pi gene donors with a panel of 5–7 potential receivers (cultivated European rice genotypes). Seven InDel and 8 presence/absence polymorphisms were directly detected by gel analysis after DNA amplification, while sequencing of 12.870 bp through 32 loci in different genotypes revealed 85 SNP (one SNP every 151 bp). Seven SSRs were additionally tested revealing 5 polymorphic markers between donors and receivers. Polymorphisms were used to develop 35 PCR-based molecular markers suitable for introgressing of Pi genes into a set of the European rice germplasm. For this last purpose, allelic molecular marker variation was evaluated within a representative collection of about 95 rice genotypes. Polymorphic combinations allowing introgression of the broad spectrum resistance genes into a susceptible genetic background have been identified, thus confirming the potential of the identified markers for molecular-assisted breeding.     

Blast resistance in rice: a review of conventional breeding to molecular approaches

Blast disease caused by the fungal pathogen Magnaporthe oryzae is the most severe diseases of rice. Using classical plant breeding techniques, breeders have developed a number of blast resistant cultivars adapted to different rice growing regions worldwide. However, the rice industry remains threatened by blast disease due to the instability of blast fungus. Recent advances in rice genomics provide additional tools for plant breeders to improve rice production systems that would be environmentally friendly. This article outlines the application of conventional breeding, tissue culture and DNA-based markers that are used for accelerating the development of blast resistant rice cultivars. The best way for controlling the disease is to incorporate both qualitative and quantitative genes in resistant variety. Through conventional and molecular breeding many blast-resistant varieties have been developed. Conventional breeding for disease resistance is tedious, time consuming and mostly dependent on environment as compare to molecular breeding particularly marker assisted selection, which is easier, highly efficient and precise. For effective management of blast disease, breeding work should be focused on utilizing the broad spectrum of resistance genes and pyramiding genes and quantitative trait loci. Marker assisted selection provides potential solution to some of the problems that conventional breeding cannot resolve. In recent years, blast resistant genes have introgressed into Luhui 17, G46B, Zhenshan 97B, Jin 23B, CO39, IR50, Pusa1602 and Pusa1603 lines through marker assisted selection. Introduction of exotic genes for resistance induced the occurrence of new races of blast fungus, therefore breeding work should be concentrated in local resistance genes. This review focuses on the conventional breeding to the latest molecular progress in blast disease resistance in rice. This update information will be helpful guidance for rice breeders to develop durable blast resistant rice variety through marker assisted selection.     

A rice blast-resistance genetic resource from wild rice in Yunnan, China.

Compared to Pi-ta(-) alleles, Pi-ta(+) alleles can cause blast resistance response. In this work, Pi-ta gene in multiple rice materials, including local rice cultivars, different types of O. rufipogon and O. longistaminata was detected by molecular cloning and sequence analysis. Results indicated that Pi-ta(+) alleles were rare alleles, because in all the tested materials, only the 'Erect' type of O. rufipogon (ETOR) from Jinghong county in Yunnan province contains a Pi-ta(+) allele. Another rice blast resistance gene, Pib, confers resistance to the Japanese strain of M. grisea, was also confirmed to be functional in this type of O. rufipogon. The results of pathogen inoculation test show that ETOR is more strongly resistant to the tested blast pathogen races than other types of O. rufipogon. The resistance of ETOR may at least partially depend upon the functioning of Pi-ta and Pib gene. As O. rufipogon has the same type of genome with the cultivated rice (O. sativa), Pi-ta(+) and Pib gene in Erect type of O. rufipogon can be used to improve the tolerance of cultivated rice to blast, either by traditional hybridization or by genetic engineering.     

利用微卫星标记鉴定水稻的稻瘟病抗性

应用水稻稻瘟病抗性基因Pid(t)紧密连锁的微卫星标记RM262对含有该抗病基因的品种地谷与感病品种江南香糯和8987的杂交F2群体进行遗传分析和抗性鉴定,结果表明,RM262的PCR扩增物在抗、感品种之间的多态性较好;在2个F2群体中,RM262和抗病基因间的重组率分别为5.74%和8.17%,应用该标记的抗性纯合和杂合带型选择抗性植株,其准确率可达98%以上。此外,还就分子标记辅助育种进行了讨论。     

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.