水稻粳型亲籼系S-c座位基因型分析

S-c是控制水稻籼粳亚种间杂种F1花粉不育性的基因座位之一。在该座位,台中65的基因型为Sj/Sj,广陆矮4号的基因型为Si/Si。以台中65和广陆矮4号为遗传测验种,分别与4个粳型亲籼系配组,根据部分F2群体中植株花粉育性表型及与S-c紧密连锁分子标记基因型的偏态分离程度,测定了这4个粳型亲籼系在S-c座位的基因型,结果表明,G2416-3的基因型为Si-2/Si-2;G2605和G3004-4的基因型均为Si-1/Si-1;G2417-2-1的基因型为Sn/Sn。本文还对F1花粉不育性基因遗传分化的测定方法进行了讨论。     

水稻特异亲和基因S-e的分子定位

水稻籼粳亚种间杂种具有强大的优势，但亚种间杂种的不育性限制了这一优势的利用。开展杂种不育基因的定位工作，对于进一步了解杂种不育性的遗传基础，克服亚种间杂种的不育性具有重要的意义。本研究选用粳型品种台中65的近等基因系E47-1和籼型品种广陆矮4号为材料，利用74个SSR标记对杂种F2群体进行偏态分离标记的筛选，同时根据F2和F3群体花粉育性和具有偏态分离的SSR标记之间的连锁关系，对特异亲和基因(F1花粉不育基因)S-e座位进行了分子定位，取得了以下主要结果：1、利用116个均匀分布在水稻12条染色体上的SSR标记对籼粳两亲本进行多态性筛选。结果有101个SSR标记在亲本间具有多态性，15个SSR标记在亲本间无多态性，SSR标记在亲本间的多态率高达87．07％。2、选用74个亲本间具有多态性的SSR标记对E47-1／广陆矮4号组合F2群体的偏态分离进行了初步的筛选和分析。发现有6个染色体区段的9个SSR标记在F2群体中存在偏态分离，它们分别位于第3、第6、第7、第10、第11和第12染色体上，卡方值均达到显著或极显著水平。6个染色体区段中有2个严重偏态分离区段，分别位于第6和第12染色体。3、通过对F2群体的花粉育性和偏态分离区段的SSR标记基因型的相关关系分析，表明位于第12染色体上的SSR标记RMl9附近存在一个F1花粉不育基因。继而在该标记附近设计位置特异性微卫星标记PSM401、PSMl80、PSMl82，利用F3作图群体，将特异亲和基因S-e座位定位在分子标记PSM401、PSMl80和PSMl82、RMl9之间，该基因与各标记的遗传距离分别为2．3cM、1．3cM、3．7cM和4．3cM。4、选取在S-a、s-b、S-c、S-d、S-e五个座位均纯合、花粉表现为部分不育的F2单株，发展了另一R群体，表明该群体存在另一特异亲和基因座s-f。本研究利用SSR标记，对特异亲和基因S-e进行了分子定位。S-e座位的分子定位，进一步丰富和完善了特异亲和性的学术观点，并为分子标记辅助选育水稻的粳型亲籼系奠定了基础。     

谷子显性雄性不育基因Msch的AFLP标记

利用雄性不育是实现谷子杂种优势利用最经济、有效的途径之一.为了寻找与不育基因Msch紧密连锁的分子标记,提高不育系的选育效率,本研究构建了Msch不育/可育近等基因系(NILs),通过对400对AFLP引物组合进行筛选,找到了与不育基因紧密连锁的两个AFLP标记(P17/M37224和P35/M52208),与不育基因的遗传距离分别是2.1 cM和1.4 cM,而且位于不育基因的同一侧,标记间相距0.7 cM.这两个AFLP标记可有效用于分子标记辅助选择育种.     

水稻粳型亲籼系的分子标记辅助育种

分子标记辅助聚合育种是累加有利基因的有效手段。培育粳型亲籼系是有效克服水稻籼粳亚种间杂种不育性，从而利用水稻亚种间杂种优势的重要途径之一。本研究利用以PCR为基础的分子标记进行辅助选择，对不同粳型亲籼系中不同分化度的特异亲和基因进行了聚合，并将4个抗白叶枯病基因和来源于IR24的两个恢复基因导入粳型亲籼系中。主要结果如下：1、以粳型亲籼系G2417-2-1和粳型广亲和系G2605为亲本构建分离群体，利用本研究筛选的与S-b，S-c,S-d三个F1花粉不育基因座位紧密连锁的PCR标记进行辅助选择。在F2共选择到特异亲籼聚合植株6株，它们分别是58号，93号，94号，115号，139号，200号；广亲和聚合植株4株，它们分别是11号，14号，121号，177号。2、对当选聚合系的亲籼性和亲粳性综合分析表明：各个特异亲籼聚合系的亲粳性之间及各个广亲和聚合系的亲籼性之间都有显著差异。特异亲籼聚合系的平均亲籼性和平均亲粳性与亲本G2417-2-1相比都没有显著差异。广亲和聚合系的平均亲籼性高于亲本G2605，平均亲粳性显著低于亲本G2605。这些聚合系的亲和性与其MAS基因型相一致。3、利用四类粳型亲籼系与携带有2个恢复基因和4个抗白叶枯病基因的品系构建回交群体，应用本研究筛选的以PCR为基础的分子标记进行辅助选择。在BC1F1共选择到2个恢复基因和4个抗白叶枯病基因全杂合的植株19个，其中以IC31为受体的5株，以IC32为受体的11株，以IC33为受体的2株，以IC34为受体的1株。4、当选的19个单株自交繁殖BC1F2，利用与目标基因紧密连锁的单一分子标记进行MAS。共选择到各类可供进一步利用的材料393株，其中携带有两个纯合恢复基因的植株158株，同时携带有两个纯合恢复基因和两个纯合显性抗白叶枯病基因的植株40株。5、从上述158个植株中选出两个显性抗性基因均纯合或者任意三个抗性基因均纯合的植株共45株，通过标记加密进一步验证其基因型。结果表明，在Rf3，Rf4，Xa4，Xa21，xa5和xa13等六个基因座位上均带有纯合基因型的植株有3株。本研究通过粳型亲籼系不同分化度的特异亲和基因的聚合获得了新粳型亲籼系；通过聚合恢复基因和抗白叶枯病基因到粳型亲籼系中，使粳型亲籼系不仅能解决亚种间杂种不育性，用于两系杂交稻育种，而且由于具有抗白叶枯病基因，可以改善其对白叶枯病的抗性；由于有恢复基因而具有恢复能力，从而可以实现籼粳亚种间的三系配套。     

水稻F1花粉不育基因的精细定位及其遗传分化研究

水稻籼粳亚种间杂种的不育性限制了亚种间的遗传交流和杂种优势利用。本研究通过发展位置特异性的微卫星标记将F1花粉不育基因S-6座位进行了精细定位；通过分析近等基因系中代换片段的遗传效应，鉴定出了F1花粉不育基因S-d座位，利用位置特异性的微卫星标记将S-d进行了定位；根据基因组的序列资料和利用较大的作图群体对S-6和S-d两个座位进行了物理作图；通过分子标记辅助选择培育了一批复等位基因近等基因系，对育性基因的遗传分化进行了研究。取得了如下主要结果：1、根据S-6座位初步定位的结果发展位置特异性的微卫星标记，将F1花粉不育基因座S-6进行了精细定位。结果表明多态性标记均与S-6座位紧密连锁，其中R830STS、PSM7、PSM8、PSM9、．PSM59和PSM60位于S-6座位一端，与S-6座位遗传距离分别为1．5cM、1．2cM、0．9cM、0．9cM、0．9cM和0．9cM，而PSM202、PSM206、PSM208、RMl3、R2213SSTS和RM413位于S-6座位的另一端，与S-6座位的遗传距离分别为0．9cM、2．1cM、3．8cM、4．1cM、4．4cM和5．3cM。2、根据S-6座位精细定位的结果，从IRGSP下载了S-6座位所在区域克隆的序列，将克隆的序列进行了拼接，同时将与S-6座位紧密连锁的分子标记与序列拼接图进行了电子整合。根据整合的结果发展位置特异性的微卫星标记和STS标记，利用500株的作图群体，最终将S-6座位界定在PSM8与PSM215之间182．2kb的范围，其中PSM214、T17、T18和T19与S-6座位完全连锁。3、通过对近等基因系E11-5中代换片段遗传效应的分析，在第1染色体的代换片段上鉴定出一个新的F1花粉不育基因座S-d。根据基因组的序列发展位置特异性的微卫星标记将S-d座位进行了定位。结果表明多态性标记均与S-d座位紧密连锁，其中PSM27、PSM24、．PSM26、PSM23、PSM31、PSM25、PSM37、PSM41、PSM42、PSM43、．PSM44、．PSMl2和PSMl3位于S-d座位的一端，与S-d座位的遗传距离分别为10．6cM、7．2cM、7．2cM、6．8cM、6．8cM、6．4cM、6．4cM、4．8cM、4．8cM、3．2cM、1．6cM、0．4cM和0．4cM，而RM84、RM86、RM323、RMl和RM283位于S-d座位的另一端，与S-d座位的遗传距离分别为3．8cM、4．6cM、6．7cM、7．5cM和8．7cM。4、根据S—d座位定位的结果，从IRGSP下载了S-d座位所在区域克隆的序列，将克隆的序列进行了拼接，同时将与S-d紧密连锁的分子标记与序列拼接图进行了电子整合。根据整合的结果发展位置特异性的微卫星标记和STS标记，利用2160株的作图群体，最终将S-d座位界定在67．8kb的范围内，其中PSM93和PSM74位于S-d座位的两侧且各与S-d仅有一个重组，而PSM95、PSM96、T1和T2与S-d座位完全连锁。RiceGAAS注释分析表明在此区段有17个ORF。，其中3个ORF可能与杂种不育性有关。BLAST分析表明此段序列籼粳之间的同源性较低，这也可能是杂种不育的一个原因。5、通过分子标记辅助选择，在F1花粉不育基因s-n、s-6、s-c和s-d座位各培育了一批复等位基因近等基因系，测交分析表明各不育基因座位上的不育基因不仅分化为相对的S^i和S^j，而且基因型类型相同的复等位基因的遗传分化也达到了显著差异的水平。携带有多个复等位基因的近等基因系的测交分析表明，复等位基因近等基因系的遗传效应为各基因座位遗传效应的累加，各基因的遗传效应相互独立，彼此间无相互作用。     

一个内含子长度多态性标记与栽培稻F1花粉育性基因座连锁

本研究利用两份栽培稻(OryzasativaL.)种质HITAR005和IRGC20509杂交建立了含有500个单株的F2群体,采用内含子长度多态性标记对F2群体中的117株进行了标记基因型分析。研究发现一个内含子长度多态性标记,RI01594,其标记座位上与父本(IRGC20509)相同基因型的纯合植株完全消失,且母本纯合基因型植株与杂合基因型植株的比率符合1:1(!2C=0.90,"2C相似文献   

水稻显性早熟基因Ehd的SSR标记定位

以籼稻品种广陆矮4和粳稻品种台中65为亲本构建高世代回交分离群体,选用分布于水稻全基因组的145个SSR标记对亲本及抽穗期早熟基因进行分析.结果表明,114个标记在亲本间具有多态性,多态率78.6%;在BC3F1群体中,检测到10个标记的基因型来源于供体亲本广陆矮4号;在BC3F2定位群体中,早熟植株数与晚熟植株数的分离比例为3:1,早熟植株平均比晚熟植株提早抽穗21 d;通过SSR标记与抽穗期共分离分析将显性早熟基因Ehd界定在分子标记RM271和RM258之间;Ehd与标记RM184和RM271紧密连锁,遗传距离分别为2.6 cM和2.1 cM,此结果为该基因分子标记辅助选择奠定了基础.     

与高粱A2类型细胞质雄性不育性连锁的SSR标记的初步鉴定

高粱(Sorghum bicolor(L.)Moench)质核互作雄性不育类型有7种,即A1,A2,A3,A4,A5,A6和9E.对于雄性不育机理的研究以往都集中在A1类型上.本文运用SSR方法分析了高粱亲本622 A2,晋粱5号,它们的杂交种622 A2×晋粱5号,及其F2代323个单株的DNA,从60对SSR引物中筛选到与不育基因连锁的SSR标记Xtxp 65和Xtxp30,分别位于目的基因11.5 cM和20.0 cM处,其特异带型大小分别约为125 bp和250 bp.分子标记的有效利用有利于优良高粱不育系的选择,也为基于作图的基因分离奠定了基础.     

谷子显性雄性不育基因Msch的AFLP标记

利用雄性不育是实现谷子杂种优势利用最经济、有效的途径之一。为了寻找与不育基因Ms^ch紧密连锁的分子标记，提高不育系的选育效率，本研究构建了Ms^ch不育/可育近等基因系（NILs），通过对400对AFLP引物组合进行筛选，找到了与不育基因紧密连锁的两个AFLP标记（P17/M37₂₂₄和P35/M52₂₀₈），与不育基因的遗传距离分别是2.1 cM和1.4 cM，而且位于不育基因的同一侧,标记间相距0.7 cM。这两个AFLP标记可有效用于分子标记辅助选择育种。     

豫粳6号保持系与恢复系TR2604间杂种花粉不育基因的定位

阐明BT型杂交粳稻组合间育性差异的遗传基础有助于三系法杂交粳稻组合的选育。根据TR2604与豫粳6号A(B)、9201A(B)后代的花粉育性及小穗育性,明确了豫粳6号A(B)/TR2604 F1不育由双亲间特异性不亲和造成。遗传分析表明豫粳6号A(B)与TR2604 F1花粉不育受单基因S38(t)控制。以352株豫粳6号A/TR2604//TR2604、豫粳6号B/TR2604//豫粳6号B等群体中单株为定位群体,将S38(t)定位于第7染色体上标记RM18和RM234之间,与两标记遗传距离分别为0.43 cM和0.14 cM,两标记间物理距离约为180 kb,相关结果为S38(t)图位克隆工作奠定了基础。     

Molecular mapping of S-c, an F1 pollen sterility gene in cultivated rice

Hybrids between indica and japonica rice varieties usually show partial sterility, and are a major limiting factor in the utilization of heterosis at subspecific level. When studying male-gamete (pollen) abortion, a possibly important cause for sterility, six loci (S-a, S-b, S-c, S-d, S-e and S-f) for F₁ pollen sterility were identified. Here we report genetic and linkage analysis of S-c locus using molecular markers in a cross between Taichung 65, a japonica variety carrying allele S-c ^j, and its isogenic line TISL5, carrying alleleS-c ^j. Our results show that pollen sterility occurring in the hybrids is controlled by one locus. We used 208 RFLP markers, as well as 500 RAPD primers, to survey the polymorphism between Taichung 65 and TISL5. Six RFLP markers located on a small region of chromosome 3, detected different RFLP patterns. Co-segregation analysis of fertility and RFLP patterns with 123 F₂ plants confirmed that the markers RG227, RG391, R1420 were completely linked with the S-c locus. The genetic distances between the markers C730, RG166 and RG369 and the S-c locus were 0.5 cM, 3.4 cM, and 3.4 cM respectively. Distorted F₂ ratios were also observed for these 4 RFLP markers in the cross. This result suggests that the `one locus sporo-gametophytic' model could explain F₁ hybrid pollen sterility in cultivated rice. RG227, the completely linked marker, has been converted to STS marker for marker-assisted selection. This revised version was published online in August 2006 with corrections to the Cover Date.     

一个水稻披叶突变体的遗传分析和基因定位

在杂交育种后代中,发现了一个叶片披垂的突变体,暂命名为dl(t).通过两年观察,表现稳定遗传.以该突变体为父本,Y2B和缙香2B分别为母本配制杂交组合,F2遗传分析表明,该披叶性状由一对隐性基因控制.利用突变体与Y2B杂交得到的F2代群体进行基因定位,发现dl(t)基因位于第3染色体短臂上标记RM6038和RM5347之间,遗传距离分别为3.99 cM和0.94 cM.进一步在两标记之间发展新的分子标记,将该基因定位在RM6038和RM7576之间,分别相距3.99 cM和0.47 cM,且与RM1324共分离.这一结果表明该基因可能与已报道的水稻披叶突变基因dl(drooping leaf)等位.但该披叶突变体除叶片表现披垂外,其他性状与所有已报道的dl等位基因都不同,特别是花器官性状发育正常,这显然与已有报道的dl等位基因不同.     

Tagging of four fertility restorer loci for wild abortive—cytoplasmic male sterility system in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) using microsatellite markers

Tagging of restorer genes for wild abortive (WA) CMS source by studying a 222 individual plants from a F₂ population of a cross between IR58025A × IR42686R. The restorer line IR42686R that was used in this study had been previously derived through random mating composite population (RMCP) involving 12 parents facilitated by IR36 genetic male sterility. Four Rf genes were tagged to simple sequence repeats (SSR) markers on chromosomes 1, 7, 10, 12 by recessive class analysis. The recombination frequency between a positive marker and Rf locus was calculated using maximum likelihood estimator assuming that all the 46 extremely sterile individual plants were homozygous at the targeted Rf locus. The recombination frequency between the marker and the restorer trait were converted to genetic distances using Kosambi function. A new Rf locus designated as Rf7 on chromosome 12 was found to be linked to RM7003 at a genetic distance of 13.3 cM (LOD 6.12). We report here first, a new molecular marker (RM 6344) linked to Rf4 locus on chromosome 7 that was previously mapped by trisomic analysis. RM443 and RM315 were flanking the Rf3 gene at a genetic distance of 4.4 (LOD 10.29) and 20.7 cM (LOD 3.98) on chromosome 1, respectively. The Rf6 was flanked on both side with SSR markers RM258 and RM591 at a genetic distance of 4.4 (LOD 10.29) and 23.3 cM (LOD 3.39) located on chromosome 10. The random mating composite population is an excellent breeding approach to develop superior restorer lines and for pyramiding different Rf genes of different CMS systems. Rf genes tagged with closely linked SSR markers would be facilitating marker assisted selection (MAS) in hybrid rice breeding program by reducing time and workload for identifying potential restorers. L. Bazrkar and A. J. Ali equally contributed to this work.     

水稻抗稻瘟病基因Pi47的精细定位和候选基因分析

不断挖掘和克隆抗稻瘟病新基因, 是解析水稻抗病分子遗传机制和培育抗稻瘟病新品种的重要基础。Pi47是笔者从广谱、持久抗稻瘟病湖南地方品种湘资3150中鉴定的稻瘟病抗性基因, 前期研究将其初步定位于第11染色体标记RM224和RM5926间。本研究利用3个Pi47单基因系与感病亲本CO39杂交F₂群体1687个感病单株对Pi47精细定位, 利用6个STS标记对3个单基因系进行背景分析, 采用生物信息学方法进行了候选基因分析。结果表明, Pi47被精细定位于CAPS标记S32与K33间0.24 cM区域的171.2 kb物理区间内, 背景分析将Pi47进一步缩小至SC12和K33间67.8 kb的区间内; 该区间含有8个结构基因, 其中2个编码NBS-LRR抗病类似蛋白, 为Pi47的候选功能基因。稻瘟菌抗谱比较分析发现, Pi47单基因系与其定位区间内4个Pik位点的等位基因Pik、Pikm、Pikh和Pikp的近等基因系抗谱不同。这些结果为进一步克隆Pi47和利用其进行分子标记辅助选择培育抗稻瘟病水稻新品种奠定了基础。     

Genetic mapping of bph20(t) and bph21(t) loci conferring brown planthopper resistance to Nilaparvata lugens St?l in rice (Oryza sativa L.)

Brown planthopper(BPH) is one of the most serious and destructive insect pests of rice in most rice growing regions of the world. In this study, two major resistance genes against BPH have been identified in an Oryza rufipogon (Griff.) introgression rice line, RBPH54. Inheritance of the BPH resistance in RBPH54 was studied by screening the resistance in parents, F1, F2 and BC1 generations against BPH biotype 2. A population of BC3F2 lines was developed and SSR markers were employed for the gene mapping, and new markers were designed for fine mapping of the resistance genes, while sequence information of BAC/PAC clones was used to construct physical maps of the genes. The results showed that the BPH resistance in RBPH54 was governed by recessive alleles at two loci, tentatively designated as bph20(t) and bph21(t). The locus bph20(t) was fine mapped to the short arm of chromosome 6 about 2.7 cM to the upper marker RM435 and 2.5 cM to lower marker RM540 and in a 2.5 cM region flanked by two new SSR markers BYL7 and BYL8 which were developed in the present study. The other BPH resistance locus bph21(t) was initially mapped to a region 7.9 cM to upper marker RM222 and 4.0 cM to lower marker RM244 on the short arm of chromosome 10. For physical mapping, the bph20(t)-linked markers were landed on BAC/PAC clones of the reference cv., Nipponbare, released by the International Rice Genome Sequencing Project. The bph20(t) locus was physically defined to an interval of about 75 kb with clone P0514G1. Identification and location of these two genes in the present study have diversified the BPH resistance gene pool, which give benefit to the development of resistant rice cultivars, and the linkage PCR-based SSR markers for the bph20(t) and bph21(t) genes would help realize the application of the genes in rice breeding through marker-assisted selection.     

水稻稻瘟病抗性基因Pi-2(t)的精细定位

利用重组自交系群体对水稻稻瘟病抗性基因Pi-2(t)进行精细定位, 将Pi-2(t)定位于分子标记RG64和AP22之间, 遗传距离分别为0.9 cM和1.2 cM. 该研究建立了Pi-2(t)基因和分子标记之间的紧密连锁, 为提高分子标记辅助选择育种的效率, 以及克隆该基因奠定了基础.     

Molecular mapping of the fertility-restoration gene Rf4 for WA-cytoplasmic male sterility in rice

The wild abortive cytoplasmic male sterility (CMS‐WA) system, an ideal type of sporophytic CMS in indica rice, is used for the large‐scale commercial production of hybrid rice. Searching for restorer genes is a good approach when phenotyping is very time‐consuming and requires the determination of spikelet sterility in testcross progeny. To establish more precisely the genetical and physical maps of the Rf4 gene, high‐resolution mapping of this locus was carried out using simple sequence repeat (SSR) markers and newly designed markers in a F₂ population. The genetic linkage analysis indicated that five SSR markers (RM6737, RM304, RM171, RM5841 and RM228) on the long arm of chromosome 10 were linked with the Rf4 gene. Rf4 was flanked by two SSR markers RM171 and RM6737 at distances of 3.2 and 1.6 cM, respectively. Also, within the region between Rf4 gene and RM171, a newly designed primer pair, AB443, produced two sterile‐specific markers, AB443‐400 and AB443‐500, 0.5 and 1.03 cM from the gene. The flanking markers identified give promise for their application in molecular marker‐assisted selection (MAS) and they are also suitable for starting chromosome walking to clone Rf4 gene in the near future.     

Validation of molecular markers linked to fertility restorer gene(s) for WA-CMS lines of rice

The present study was carried out with the objective to validate the molecular markers, which have been previously reported to be linked to fertility restorer (Rf) gene(s) for WA-CMS lines of rice. Two mapping populations involving fertility restorer lines for WA-cytoplasm, viz., (i) an F₂ population derived from the cross IR58025A/KMR3R consisting of 347 plants and (ii) a BC₁F₁ population derived from the cross IR62829A/IR10198R//IR62829A consisting of 130 plants were analyzed. Nine SSR and three CAPS markers reported to be linked to Rf genes along with two previously unreported SSR markers were analyzed in the mapping populations. In both the populations studied, the trait of fertility restoration was observed to be under digenic control. Eight SSR markers (RM6100, RM228, RM171, RM216, RM474, RM311, MRG4456 and pRf1&2) showed polymorphism between the parents of the F₂ population, while the SSR markers RM6100 and RM474 showed polymorphism between the parents of both the F₂ and BC₁F₁ populations. Only one CAPS marker, RG146FL/RL was polymorphic between the parents of the BC₁F₁ population. RM6100 was observed to be closely segregating with fertility restoration in both the mapping populations and was located at a distance of ~1.2 cM. The largest phenotypic variation was accounted for the region located between RM311 and RM6100. Using the marker-trait segregation data derived from analysis of both the mapping populations, a local linkage map of the genomic region around Rf-4, a major fertility restoration locus on Chromosome 10 was constructed, and RM6100 was observed to be very close to the gene at a distance of 1.2 cM. The accuracy of the marker RM6100 in predicting fertility restoration was validated in 21 restorers and 18 maintainers. RM6100 amplified the Rf-4 linked allele in a majority of the restorers with a selection accuracy of 94.87%. Through the present study, we have established the usefulness of the marker RM6100 in marker-assisted selection for fertility restoration in segregating populations and identification of restorers while screening rice germplasm for their fertility restoration ability.     

滇一型杂交粳稻恢复基因的分子鉴定研究

用位于水稻第10染色体的微卫星标记OSR33、RM228对285份滇型材料进行恢复基因的分子鉴定研究，结果表明：①OSR33、RM228标记的基因型依材料的不同而出现分子量不同的带型，且带型与材料有关；②OSR33和RM228鉴定材料的准确率分别为96％和90％；OSR33、RM228标记的基因型值与黑染花粉率极显著正相关，可用于鉴别恢复系；③用Mapmaker／QTL软件分析供试材料的表现型，在OSR33、RM228之间，探测到1个与育性恢复有关的主效QTL，可解释83．2％的表型变异，与OSR33和RM228的遗传距离分别为3．3cM和7．0cM。     

Development and validation of microsatellite markers linked to the rice blast resistance gene <Emphasis Type="Italic">Pi-z</Emphasis> of Fukunishiki and Zenith

Rice blast resistance gene ‘Pi-z’ present in rice genotypes, Zenith and Fukunishiki, represents a potential source of blast resistance for the north-western Himalayan region of India. We tested the reliability of microsatellite markers linked to Pi-z for assessing blast resistance phenotype in crosses of commercial importance. A new set of microsatellite markers linked to Pi-z was also developed by exploiting the publicly available marker and genomic resources of rice. Of the three previously reported markers for Pi-z, only MRG5836 was suitable for the marker assisted selection of Pi-z. Among the 17 microsatellites selected from the putative region of Pi-z locus, two, RM8225 and RM8226 cosegregated with MRG5836 and were located at distance of 1.2–4.5 cM from the gene. A new microsatellite marker ‘SSR236’ was developed from the (CT)₁₆ repeat of PAC clone P0502B12, which exhibited closer linkage (0.6–1.2 cM) to Pi-z. Survey of the allelic diversity at the loci of the Pi-z linked microsatellite markers revealed that the Fukunishiki and Zenith type alleles were not present in majority of the local indica rice genotypes. As these markers are polymorphic between the Pi-z donors and a great majority of local indica rices tested, they can be used as a selection tool in rice breeding programs aimed at improving the blast resistance of local rices.