Genetic distribution of the avirulence gene AVRPiz-t in Thai rice blast isolates and their pathogenicity to the broad-spectrum resistant rice variety Toride 1

Rice blast disease, caused by the filamentous fungus Pyricularia oryzae, is one of the most destructive diseases in rice worldwide. Breeding of resistant rice cultivars remains a cost-effective and environment-friendly means for controlling blast disease, but the resistance tends to break down over time because of the pathogen's rapid adaptation. In this study, AVRPiz-t gene sequences of 46 rice blast isolates were evaluated using a Southern blot analysis. The AVRPiz-t gene was present in 24 of 46 (52.2%) rice blast isolates. The pathogenicity assay showed that all blast isolates were avirulent against Japanese rice cv. Toride 1, which carries several rice blast resistance genes including Piz-t, Pii, Pi37, and Pi-ta. Screening for the Piz-t gene in Thai rice germplasm revealed that less than 20% of rice varieties harbour the Piz-t gene. Therefore, the Toride 1 rice variety could serve as an effective donor of rice blast resistance to be used in rice breeding programmes in Thailand. This study provides evidence for co-evolution between the rice blast resistance gene Piz-t and the rice blast fungal avirulence gene AVRPiz-t. Understanding this relationship will facilitate the sustainable development of breeding for rice blast resistance in the future.     

吉林省主栽水稻品种抗瘟性评价及抗瘟基因型鉴定

 为明确吉林省主栽水稻品种的抗瘟性和抗瘟基因型,选用了一套已明确其无毒基因组成的稻瘟病菌标准菌株对吉林省68个主栽水稻品种进行喷雾和离体划伤接种试验。结果表明,68个品种的抗瘟能力存在较大差异,中抗以上抗病品种达到44个,占供试品种的64.7％;抗瘟基因推导结果结合特异性分子标记检测表明,Pita、Pia、Pish、Pita2、Pib和Pi9等6个基因为吉林省主栽水稻品种中主要的抗瘟基因,并且品种中含有的抗瘟基因数量与抗瘟能力呈正相关;根据结果推测,测试的所有品种中可能不含有Pi2、Pikh、Pikm、Pi11和Pi12基因。本研究揭示了吉林省近年主栽水稻品种的抗瘟能力和抗瘟基因组成,明确了吉林稻区主效抗瘟基因和基因聚合对稻瘟病的抗性贡献,为进一步培育广谱持久抗瘟品种和合理布局抗病品种提供了重要参考。     

已知抗瘟基因在黑龙江省寒地稻区的评价与利用

 利用12个日本鉴别品种、7个中国鉴别品种、24个抗稻瘟病单基因系及6个当地主栽品种,对2006年采自该省主要积温区不同水稻品种的178个稻瘟病菌株进行了致病性测定。结果表明：2006年黑龙江省稻瘟病菌生理小种划分为104个日本小种,077.7号生理小种比例最高为4.49%,017.1号、017.5号、037.5号生理小种出现频率为3.93%。就抗性基因而言,抗瘟基因Pi9(t)在全省抗谱为97.75%,是较好的抗源可以在全省内广泛利用;Piz-5、Pi12(t)抗瘟基因抗谱分别为78.09%和78.65%,根据品种种植区域可以有选择地利用。就品种而言,抗瘟基因Pi9(t)、Piz-5是空育131;Pi5(t)、Pita-2是垦稻10号;Pi9（t）、Pita是上育397;Piz-5、Pi12(t)是垦稻12号等品种抗瘟改良的有利基因;在研究中同时加强对稻瘟病菌种群的监测和新抗源的发掘,有针对性地向主栽品种导入新的抗性基因。     

水稻防御反应相关基因对稻瘟病菌的响应

水稻与稻瘟病菌的互作已成为研究植物与病原真菌互作的模式系统。利用RT-PCR技术检测了6个水稻品种(分别含有抗病基因Pik-s、Pita、Pit、Pi1、Pi9的近等系及回交亲本丽江新团黑谷LTH)与稻瘟病菌互作过程中多个信号相关及PR基因的表达。结果表明带有稻瘟病抗性基因Pik-s、Pita、Pit的水稻品种和LTH对稻瘟病菌#626侵染表现为亲和互作,带Pi1和Pi9的水稻品种表现为非亲和互作;稻瘟病菌接种后,亲和互作中MAPK6和MAPK12表现为上调表达,带有抗性基因Pi9的水稻品种IRBL22中BIMK2表现为上调表达。总体来看,含有不同抗病基因的水稻近等系中的PR基因对稻瘟病菌的响应较为多样,非亲和互作中在早期或早中期表现为PR基因上调表达,而亲和互作中主要在晚期上调表达,说明这些PR基因表达的时间在植物与病原互作的不同时期发挥着不同的作用。     

Races of <Emphasis Type="Italic">Magnaporthe oryzae</Emphasis> in Australia and genes with resistance to these races revealed through host resistance screening in monogenic lines of <Emphasis Type="Italic">Oryza sativa</Emphasis>

Rice blast is the most serious disease threat to rice production worldwide. It is difficult to control due to the complex diversity and wide geographic distribution of the causal pathogen Magnaporthe oryzae. In Australia, rice blast occurs in northern Australia but remains exotic to the main south-eastern rice growing area; however, there is the potential for rice blast to threaten this area; in addition, rice production is currently expanding from south-eastern Australia into northern Australia, which makes rice blast a major concern and challenge to rice industry in Australia. Prior to this study, there was lack of information on the race status of M. oryzae present in Australia and on how to manage the disease through host resistance. The races of rice blast isolates collected in northern Australia was characterised based on the disease reactions of eight standard rice differentials used in an international race differential system. The following studies revealed genes conferring resistance to these races through investigating the responses of 25 monogenic rice lines with targeted resistance gene against different races. The rice blast isolates were characterised into five races: IA-1, IA-3, IA-63, IB-3 and IB-59. Genes Pi40, Piz-t, Pi9, Pi5(t) and Pi12(t) exhibited resistance to all the isolates belonging to five races. In addition, two genes showed complete resistance to multiple races, viz. Pi9 that showed complete resistance to races IA-1, IA-3, IA-63 and IB-3 and Pita2 that had complete resistance to races IA-3, IB-3 and IB-59. This study provides information about the races of M. oryzae in Australia. Genes identified conferring resistance to multiple races will not only streamline the identification via molecular markers of imported rice varieties with resistance to rice blast in Australia, but will also allow the Australian rice breeding program to develop new varieties with broad-spectrum resistance to rice blast and pyramid multi-gene resistance into Australian rice varieties.     

Relationship between Avirulence Genes of the Same Family in Rice Blast Fungus Magnaporthe grisea

A genetic cross between rice-field isolates of Magnaporthe grisea produced progeny segregating for avirulence/ virulence on six rice cultivars among nine race differentials, while on three other cultivars, Shin 2 (Pik-s), Aichi Asahi (Pia) and Ishikari Shiroke (Pii), parental and progeny isolates were all virulent. Based on segregation ratios in 115 progeny isolates, avirulence on Kanto 51 (Pik), Yashiro-mochi (Pita), Fukunishiki (Piz) and Toride 1 (Piz-t) is under monogenic control. On Tsuyuake (Pik-m) and Pi No. 4 (Pita-2), however, a disproportionate ratio in the segregation was observed, suggesting that avirulence on these two cultivars is controlled by two or more genes. Assuming that the avirulence gene AvrPik-m consists of at least two genes, AvrPik-m1 and AvrPik-m2, each of which functions in the whole gene AvrPik-m, and that one of AvrPik-m1 and AvrPik-m2 is AvrPik, we could account for the disproportion in the avirulence/virulence segregation of the progeny. This hypothesis would also be consistently applied for avirulence gene AvrPita-2. There seem to be two types of the avirulence genes : AvrPik-m, that is comprised of the tightly linked genes, AvrPik-ml (=AvrPik) and AvrPik-m2, and AvrPita-2, that is comprised of the loosely linked genes AvrPita-2A (=AvrPita) and AvrPita-2B. As one possible explanation of the rice resistant reaction to blast, multiple specificity was suggested for the first time for the blast fungus. On the contrary, the avirulence genes AvrPiz and AvrPiz-t were inherited independently, despite the corresponding genes for resistance (Piz and Piz-t) being located at the same locus. The cross of rice blast isolates (races 447 and 337) produced only 25 kinds of races in the progeny, although theoretically about 64 kinds of races should be produced if six avirulence genes segregated independently. Because no progeny are with AvrPik (or AvrPita) and without AvrPik-m (or AvrPita-2), the number of races theoretically should be 36 at most. A number of strains, such as races 377 and 737, with a single avirulence gene were obtained from this cross. These strains may be valuable for analysis of resistance genes in rice plant. Received 19 August 2002/ Accepted in revised form 11 November 2002     

云南省稻瘟病菌群体的致病性分析及交配型分布

为明确云南省不同稻区稻瘟病菌Magnaporthe oryzae的毒性频率及交配型分布,利用2007—2013年分离自云南省不同稻区的112株稻瘟病菌单孢菌株,对23个持有不同抗性基因的单基因系和持有Pi57(t)的水稻渗入系IL-E1454进行致病性测定。结果表明,稻瘟病菌对不同抗病基因的毒性频率存在很大差异,分离自粳稻区的稻瘟病菌菌株对持有Piz-t、Pi5、Pi9、Pi20和Pi57(t)这5个水稻品系的毒性频率分别为14.29%、5.36%、5.51%、5.36%和0;分离自籼稻区的稻瘟病菌菌株对持有Pik-h、Piz、Pita、Piz-5、Pita-2、Pi5、Pi7和Pi9这8个水稻品系的毒性频率分别为18.25%、9.13%、9.64%、7.50%、15.72%、0、13.05%和0;分离自陆稻区的稻瘟病菌菌株菌株对持有Pik-h、Pib、Pish、Pi1、Pi5、Pi9、Pi11和Pi57(t)这8个水稻品系的毒性频率分别为6.67%、3.33%、13.79%、13.33%、7.69%、6.67%、0和3.23%;交配型测定结果显示,陆稻区菌株可交配率为100.00%,...     

Pathogenicity and population structure analysis of Pyricularia oryzae in different districts of Jiangsu province,China

Rice blast caused by Pyricularia oryzae is one of the most destructive rice diseases worldwide. In this study, 224 isolates were isolated from neck blast samples from nine districts in Jiangsu. We analysed the resistance frequency of 24 resistance (R) genes using 32 monogenic rice lines from the International Rice Research Institute (IRRI), including Pii, Pik-h, Pi5, Piz-5, and Piz, which exhibit high resistance frequencies. PAC (pathogenicity association coefficients) and VAC (virulence association coefficients) analyses identified three combinations of R genes, Piz/Pii, Piz/Piz-5, and Piz/Pi5, as being suitable for use in Jiangsu. Mating-type analysis of P. oryzae isolates indicated that sexual reproduction occurred less frequently in northern Jiangsu than in other areas, which may affect genetic diversity and dissemination. Pot2-TIR analysis indicated that the genetic diversity of P. oryzae in Xuzhou was mainly due to the insertion of transposable elements, while that of Nanjing was due to both the insertion of transposable elements and sexual recombination. Therefore, some R genes or gene combinations were suitable for resistance breeding in Jiangsu, and repetitive-PCR (rep-PCR) is a cost-effective tool for genetically differentiating distinct cultivar-specific populations or lineages with well-defined virulence patterns, because of the close correspondence between rep-PCR based clusters and pathotypes of inbred lines.     

二十二个抗稻瘟病基因在云南的利用价值评价

为了明确22个抗稻瘟菌基因在云南省的抗性水平及其利用价值,将采集、分离自云南省3个稻区的282个稻瘟病菌单孢菌株,接种于以丽江新团黑谷为轮回亲本培育而成的含有22个垂直抗性基因的水稻单基因系上.根据各稻区采集的菌株在水稻单基因系上的侵染率,分析出各垂直抗性基因在云南省各稻区的利用价值.持有Pi9、Piz5、Pi1、Pita2、Piz、Pikh、Pizt 7个垂直抗性基因的单基因系的侵染率分别为1.22%、2.40%、3.21%、4.82%、5.95%、7.23%、9.04%,可在籼稻区种植或作抗源使用;持有Pi9、Piz5、Pi1、Pita2、Piz、Pikh、Pizt、Pi12、Pita、Pib 10个垂直抗性基因的单基因系的侵染率分别为0.93%、 16.67%、10.19%、 5.09%、15.74%、15.74%、12.04%、9.26%、19.29%、11.11%,可在粳稻区种植或作抗源使用;持有Pi9、Piz5、Pi1、Pita2 4个垂直抗性基因的单基因系的侵染率分别为8.60%、13.83%、10.93%、18.04%,可在籼粳交错区种植或作抗源使用.同时用联合致病性系数和联合抗病性系数分析了病菌和单基因系的群体互作以及抗瘟组合的利用价值,结果表明:品种两两搭配后的RAC值大于0.80的组合有Pi9与Pita2、Pizt、Pi1、Piz,说明以上4种组合的抗病性最强,应用价值最大.     

云南省元阳县籼/粳型稻瘟病菌无毒基因Avr-Pia、Avr-Pita1和Avr-Pii多样性分析

为明确云南省元阳县籼/粳型稻瘟病菌中无毒基因的多样性及差异,采用接种鉴别品种方法和PCR技术对9株粳型菌株和21株籼型菌株中无毒基因Avr-Pia、Avr-Pita1和Avr-Pii的多样性进行分析。结果显示,30株稻瘟病菌菌株中无毒基因Avr-Pia、Avr-Pita1和Avr-Pii的平均出现频率分别为33.3%、76.7%和0,Avr-Pia、Avr-Pita1在籼型菌株和粳型菌株中的出现频率分别为4.8%和100.0%、66.7%和100.0%。Avr-Pia主要为存在/缺失的多样性,籼/粳型菌株对水稻品种Achiasahi(Pia)的致病率分别为100.0%和11.1%;Avr-Pita1可划分为3个类群,除菌株CH1195属于PO类群外,籼型菌株均属于J1类群,粳型菌株则属于J2/J3类群;籼/粳型菌株对水稻品种K1(Pita)的致病率分别为100.0%和0,且籼/粳型菌株Avr-Pita1蛋白序列在第83位和第192位氨基酸差异明显。Avr-Pii在30株稻瘟病菌菌株中均未检出,籼/粳型菌株对水稻品种Fujisaka No. 5(Pii)的致病率分别为100.0%和0。表明Avr-Pia和Avr-Pita1在粳型菌株中的出现频率高于籼型菌株且变异程度低,粳型菌株中可能存在其它无毒基因使其不能侵染Fujisaka No. 5。     

非亲和性稻瘟病菌对水稻的诱导抗性

为研究稻瘟病菌Magnaporthe oryzae不同菌株间的相互作用,选择与单抗性基因系水稻IRBL5-M （携带抗性基因Pi5）表现为亲和性的菌株HN52与非亲和性的菌株HN119为研究对象,将其单独或混合接种到单抗性基因系水稻IRBL5-M中,并通过荧光显微镜观察接种后水稻叶鞘的发病情况及病斑面积,测定接种后水稻内相关抗性基因OsWRKY45、OsNPR1、OsPR10、OsMAPK2的表达量以及活性氧的变化。结果显示,相较于单独接种亲和性菌株,混合接种后单抗性基因系水稻IRBL5-M病斑发病面积减少;混合接种中亲和性菌株HN52菌丝侵染能力降低,侵染菌丝细胞间扩展率显著降低73.13%;同时单抗性基因系水稻IRBL5-M中OsWRKY45、OsNPR1、OsPR10和OsMAPK2抗性基因表达量显著增加,水稻叶片中活性氧含量增加,表明在菌株混合侵染过程中,非亲和性菌株可通过激发水稻的抗性反应来降低亲和性菌株对水稻的侵染程度。     

Identification of avirulence genes in the rice blast fungus corresponding to three resistance genes in Japanese differentials

The pathogenicity of progeny from crosses among three Chinese isolates of Magnaporthe grisea collected from rice was tested on three Japanese differentials (Ishikarishiroke, Aichiasahi, K 59) having the blast resistance genes Pii, Pia, and Pit, respectively. Monogenic control was demonstrated for avirulence to the differentials. To identify resistance genes corresponding to the avirulence genes, the resistance and susceptibility in F₃ lines of the cultivars in response to the parents of the crosses were analyzed genetically. The three avirulence genes identified, designated Avr-Pii, Avr-Pia, and Avr-Pit, appear to correspond to resistance genes Pii, Pia, and Pit, respectively. The monogenic control of avirulence in the fungus and monogenic dominant resistance in rice cultivars supports a gene-for-gene relation in the Pii-, Pia-, or Pit-dependent resistance to the rice blast fungus in rice cultivars.     

东农415稻瘟病抗性遗传分析及基因定位

 粳稻品种东农415自育成以来一直以其早熟、抗病、高产特性而著称,在黑龙江省稻瘟病高发区种植20多年均表现高抗稻瘟病。本研究利用158个采集于黑龙江省不同稻区的稻瘟病菌株对东农415进行接种鉴定,结果表明东农415对黑龙江省稻瘟病菌株有很强的抗性,抗谱高达89.2%。以东农415与丽江新团黑谷(LTH)杂交衍生的F₁和F₂群体为遗传分析试验材料,通过接种鉴定,发现东农415对稻瘟病菌株F-10-11的抗性由一个显性基因控制。进一步采用分子标记结合隐性群体分离分析法,以对菌株F-10-11极端感病的99个F₂单株为作图群体,将东农415的抗病基因定位在第2染色体,距离基因两侧标记RM5300和RM213的遗传距离分别为7.6和3.0 cM,暂命名为Pi-dn(t)。将Pi-dn(t)位点映射到水稻参考基因组图谱上,在抗病位点基因组区段内发现3个编码基因Os02g56010、Os02g55540和Os02g56400具有抗病基因结构域,可作为Pi-dn(t)的候选基因。     

侵染优质稻美香占2号的稻瘟病菌生理小种鉴定及无毒基因分析

为明确优质稻种美香占2号的抗瘟性,并为其合理布局以及与不同品种的轮换种植提供科学依据,利用7个中国鉴别品种和11个抗稻瘟病单基因系,对2013—2017年自广东省美香占2号品种上分离获得的50株稻瘟病菌Magnaporthe oryzae菌株进行生理小种鉴定和无毒基因型分析。结果显示,50株稻瘟病菌菌株被鉴定为11个生理小种,其中优势小种分别为C13、B13、B01、B05和C05;50株稻瘟病菌菌株对IRBLkh-K3(仅含Pik-h基因)、NIL-e1(仅含Pi50基因)、IRBL9-W(仅含Pi9基因)和IRBLzt-T(仅含Piz-t基因)4个抗稻瘟病单基因系表现出极低的毒性,频率分别为4%、6%、6%和8%;对IRBLz-Fu(仅含Piz基因)、IRBLkp-K60(仅含Pik-p基因)和IRBLi-F5(仅含Pii基因)3个抗稻瘟病单基因系表现出相对较高的毒性,频率分别为88%、86%和80%;自美香占2号以及其它4个主栽品种上获得的70株稻瘟病菌菌株被聚为不同类群;2003—2007年供试菌株中无毒基因AvrPi9、AvrPiz-t、AvrPi50和AvrPik-h的出现...     

云南省水稻稻瘟病菌无毒基因AVR-Pia变异及水稻抗性基因Pia的有效性

为进一步了解田间稻瘟病菌Magnaporthe oryzae群体中AVR-Pia基因的分布及变异,利用水稻单基因系IRBLa-C水稻品种对自云南省13个市(州)采集分离得到的471株稻瘟病菌菌株进行抗性基因Pia有效性测定;利用无毒基因AVR-Pia特异性标记对471株稻瘟病菌菌株进行PCR检测和测序,并分析稻瘟病菌群体中无毒基因AVR-Pia的分布及DNA结构变异;利用有效性结果和PCR检测结果对471株菌株进行反应型划分,筛选鉴定菌株;利用鉴定菌株对云南省112份地方稻种进行Pia基因鉴定。结果表明,在471株稻瘟病菌菌株中,对含有Pia基因的水稻单基因系IRBLa-C表现为抗病和感病的菌株数分别为139株和332株,所占比例分别为29.5%和70.5%;在471株稻瘟病菌菌株中,分别有244株和227株菌株含有无毒基因AVR-Pia和不含有无毒基因AVR-Pia,所占比例分别为51.8%和48.2%,无毒基因AVR-Pia主要为完全缺失变异;在471株稻瘟病菌菌株中,A-和V+反应型菌株数分别为56株和161株,共217株,占总菌株数的46.1%,在13个市(州)稻瘟病菌群体中,A-和V+反应型菌株所占比例差异较大,其中在普洱市、红河哈尼族彝族自治州、昭通市、玉溪市4个市(州)的比例较大,分别为77.8%、57.1%、52.1%和50.0%;在112份云南省地方稻种质资源中,有20份地方稻品种含有抗性基因Pia,主要分布在9个市(州)中。表明云南省13个市(州)绝大部分水稻产区水稻Pia基因已丧抗性,含Pia基因的水稻种质在云南省分布较广。     

Pi34-AVRPi34: a new gene-for-gene interaction for partial resistance in rice to blast caused by Magnaporthe grisea

The japonica rice (Oryza sativa) cultivar Chubu 32 has a high level of partial resistance to blast, which is mainly controlled by a dominant resistance gene located on chromosome 11. The partial resistance to the rice blast fungus (Magnaporthe grisea) in Chubu 32 has isolate specificity; isolate IBOS8-1-1 is more aggressive on Chubu 32 than are other isolates. We hypothesized that the gene-for-gene relationship fits this case of a partial resistance gene in Chubu 32 against the avirulence gene in the pathogen. The partial resistance gene in Chubu 32 was mapped between DNA markers C1172 (and three other co-segregated markers) and E2021 and was designated Pi34. In the 32 F₃ lines from the cross between a chromosome segment substitution line (Pi34⁻) from Koshihikari/Kasalath and Chubu 32, the lines with high levels of partial resistance to the M. grisea isolate Y93-245c-2 corresponded to the presence of Pi34 estimated by graphic genotyping. This indicated that Pi34 has partial resistance to isolate Y93-245c-2 in compatible interactions. The 69 blast isolates from the F₁ progeny produced by the cross between Y93-245c-2 and IBOS8-1-1 were tested for aggressiveness on Chubu 32 and rice cultivar Koshihikari (Pi34⁻). The progeny segregated at a 1 : 1 ratio for strong to weak aggressiveness on Chubu 32. The results suggested that Y93-245c-2 has one gene encoding avirulence to Pi34 (AVRPi34), and IBOS8-1-1 is extremely aggressive on Chubu 32 because of the absence of AVRPi34. This is the first report of a gene-for-gene relationship between a fungal disease resistance gene associated with severity of disease and pathogen aggressiveness.     

Molecular mapping of the blast resistance genes Pi2-1 and Pi51(t) in the durably resistant rice 'Tianjingyeshengdao'

Tianjingyeshengdao' (TY) is a rice cultivar with durable resistance to populations of Magnaporthe oryzae (the causal agent of blast) in China. To understand the genetic basis of its resistance to blast, we developed a population of recombinant inbred lines from a cross between TY and the highly susceptible 'CO39' for gene mapping analysis. In total, 22 quantitative trait loci (QTLs) controlling rice blast resistance were identified on chromosomes 1, 3, 4, 5, 6, 9, 11, and 12 from the evaluation of four disease parameters in both greenhouse and blast nursery conditions. Among these QTLs, 19 were contributed by TY and three by CO39. Two QTL clusters on chromosome 6 and 12 were named Pi2-1 and Pi51(t), respectively. Pi2-1 was detected under both growth chamber and natural blast nursery conditions, and explained 31.24 to 59.73% of the phenotypic variation. Pi51(t) was only detected in the natural blast nursery and explained 3.67 to 10.37% of the phenotypic variation. Our results demonstrate that the durable resistance in TY is controlled by two major and seven minor genes. Identification of the markers linked to both Pi2-1 and Pi51(t) in this study should be useful for marker-aided selection in rice breeding programs as well as for molecular cloning of the identified resistance genes.     

Whole genome sequencing approaches to understand Magnaporthe-rice interactions

Due to the recent advances in DNA sequencing technologies, whole genome sequencing (WGS)-based approaches are now accelerating the pace of our research toward a better understanding of host-pathogen interactions. Using WGS-based methods, we have isolated three avirulence (AVR) genes: AVR-Pia, AVR-Pii and AVR-Pik from Magnaporthe oryzae and two cognate rice resistance (R-) genes: Pia and Pii. We briefly review our current understanding of the interactions between AVR-Pia and Pia, AVR-Pik and Pik, and AVR-Pii and Pii.     

云南药用野生稻对四种水稻主要病害的抗性鉴定

 对云南药用野生稻7个不同居群的稻瘟病、纹枯病、白叶枯病和细菌性条斑病抗型表型进行鉴定,筛选抗源,并检测已克隆的抗稻瘟病、抗白叶枯病基因在它们中的存在情况。结果表明:用云南稻瘟病菌毒性菌株16t接种云南药用野生稻7个居群,除勐海药野(7)表型为感病外,其他6个居群均为抗病;勐遮药用野生稻(4)和景纳上沟药用野生稻(1)分别不含Pib和Pi2基因片段,其他5个居群都含有Pib、Pi2、Pi9、Pid2、Pikp、Pis和Pi56等基因片段;所有的参试药用野生稻高抗纹枯病;除勐往药野(13)和澜沧孟矿药野(14)对细菌性条斑病菌菌株RS105表现为感病和勐遮药野(5)对菌株RS1-20表现为感病外,其他材料对菌株RS105和RS1-20都表现为抗病;云南白叶枯病菌强致病性菌株CX30-1、菲律宾菌株PXO99和PXO86对景纳上沟药用野生稻(1)和澜沧孟矿药用野生稻(14)具有强致病性,其他居群表现为抗病至中抗;7个居群都含有Xa5、Xa13、Xa21基因片段。本文首次报道了云南药用野生稻多个居群类型对4种主要病害的抗性,这些结果为深度挖掘利用云南药用野生稻资源的有效抗病基因奠定了基础。     

水稻主要抗瘟基因对福建稻瘟菌群体的抗性分析

 用1995-2003年间在福建省水稻产区采集的稻瘟菌代表菌系的108个分离菌,它们在CO39近等基因系上测定被划分为30个毒性类型,用它们在30个水稻抗稻瘟病近等基因系或单基因系品种上进行抗病性测定。结果表明水稻抗稻瘟病基因Pi-k^h抗性最强,抗性频率高达98.15%,Pi-1和Pi-9(t)也具有较高的抗性频率,是较好的抗源;对2个和3个Pi基因的联合抗性频率的分析,发现一些联合抗性频率极高,甚至有达到100%的组合,表明抗瘟育种采用多个Pi基因聚合,易于获得抗性强的品种。根据抗病基因与供试菌株互作的亲和性,对供试30个Pi基因可能的系统关系分析得到的初步信息可为抗病基因的聚合与布局策略提供参考。