Morphology and mapping analysis of rice (Oryza sativa L.) clustered spikelets( Cl) mutant

The rice clustered spikelets (Cl) mutant exhibits a phenotype that most of branch apical have 2-3 spikelets clustered together,SEM (scanning electron microscope )observation suggested that the Cl gene controlled branch apical development,and influenced the terminal spikelets elongation,The spikelet number was reduced in mutant,indicating that Cl may also have an effect on spikelet number,To map Cl locus,two F2 mapping populations derived from the crosses between the Cl and ZhongHua11,and Cl and ZheFu802 were constructed ,respectively,The Cl locus was roughly mapped between two CAPS markers CK0214 and SS0324,A further fine mapping analysis showed that the Cl locus was mapped between makers R0674E and Cl12560,with genetic distances of 0.2 and 2.1 cM,respectively ,Then we found a PAC conting spanning Cl locus,the region was delimited to 196 kb.This results was useful for cloning of the Cl gene,Allelism test demonstrated that Cl was allelic to Cl2 another rice clustered spikelets mutant.     

Isolation and genetic characterization of a fragile plant mutant in rice (itOryza sauva) L.

The fragile rice mutant was isolated from an M₂ population of indica variety Shuang Ke Zao (SKZ) treated with g-rays, and designated as fp1 (fragile plant 1) because of its fragile leaves and culms. To map FP1 locus, an F² mapping population was derived from a cross between the fp1 and C-bao, a polymorphic japonic variety. The primary mapping result places the FP1 locus in an interval between two molecular markers, microsatellite marker RM16 (3.1 cM proximal to FP1) and STS marker G144a (9.1 cM distal to FP1) in the centromere region of chromosome 3. A CAPS marker C524a was further developed between RM16 and G144a, with 0.4 cM genetic distances to the FP1locus, providing a practical starting point for constructing a BAC contig spanning the FP1 locus and cloning the fp1 gene. Allelism test demonstrated that fp1 is allelic to bc1, a fragile rice mutant reported previously.     

Characterization and mapping of a lesion mimic mutant in rice （Oryza sativa L.）

A rice initiation-type lesion mimic mutant (lmi) was identified, which was isolated from an indica rice Zhongxian 3037 through γ radiation mutagenesis. Trypan blue staining and sterile culture revealed that the mutant spontaneously developed lesions on the leaves in a developmentally regulated and light-dependent manner. Genetic analysis indicated that the lesion mimic trait was controlled by a single resessive locus. Using public molecular markers and an F2 population derived from lmi and 93-11, we mapped the lmi locus to the short arm of chromosome 8, nearby the centromere, between two SSR markers RM547 and RM331. The genetic distance was 1.2 and 3.2 cM, respectively. Then according to the public rice genomic sequence between the two SSR markers, lmi was further finely tagged by three CAPS markers: C4135-8, C4135-9 and C4135-10. And lmi locus was a co-segregated with marker C4135-10, providing a starting point for lmi gene cloning.     

Characterization and mapping of a white panicle mutant gene in rice

A spontaneous white panicle mutant was found from the F6 progenies of an indicajaponica cross.The mutant exhibits white stripes on its basal leaves while the panicles,rachis and pedicel are milky white colored at flowering stage.Genetic analysis in an F2 population from the cross of Zhi7/white panicle mutant indicates that the white panicle phenotype is controlled by a single recessive nuclear gene,tentatively termed as wp(t).Using microsatellite markers,the wp(t) gene was anchored between the markers of SSR101 and SSR63.9 with a map distance of 2.3 and 0.8cM,respectively,and co-segregated with the marker of SSR17 on rice chromosome 1.     

Genetic analysis and gene cloning of a triangular hull 1 (tri1) mutant in rice (Oryza sativa L.)

Grain shape and size are two key factors that determine rice yield and quality. In the present study, a rice triangular hull mutant (tri1) was obtained from the progeny of japonica rice variety Taipei 309 treated with 60Co γ-rays. Compared to the wild type, the tri1 mutant presents a triangular hull, and exhibits an increase in grain thickness and protein content, but with a slight decrease in plant height and grain weight. Genetic analysis indicated that the mutant phenotype was controlled by a recessive nuclear gene which is stably inherited. Using a map-based cloning strategy, we fine-mapped tri1 to a 47-kb region between the molecular markers CHR0122 and CHR0127 on the long arm of chromosome 1, and showed that it co-segregates with the molecular marker CHR0119. According to the rice genome sequence annotation there are six predicated genes within the mapped region. Sequencing analysis of the mutant and the wild type indicated that there was a deletion of an A nucleotide in exon 3 of the OsMADS32 gene, which could result in a downstream frameshift mutation and premature termination of the predicted polypeptide. Both semi-quantitative and real-time RT-PCR analyses showed that this gene expressed highly in young inflorescences, while expressed at very low levels in other tissues. These results implied that the OsMADS32 gene could be a candidate of TRI1. Taken together, the results of this study lay the foundation for further investigation into the molecular mechanisms regulating rice caryopsis development.     

Extension of the rice DH population genetic map with microsatellite markers

Genetic mapping of microsatellite markers was carried out in a rice DH population derived from across between Zaiyeqing 8 (indica) and Jingxi 17 (japonica). A total of 89 microsatellite markers, including 84 (GA)_n, 2(TCT)_n, 2(ATT)_n, and, l(ATC)_n motifs, were integrated relatively evenly into the established genetic map of the DH population. This will facilitate the utilization of microsatillite markers in rice gene mapping and marker aided breeding.     

小麦雌性不育基因的微卫星标记定位

以普通小麦新601×雌性不育小麦XND126的F2群体作为育性调查以及基因标记群体.通过对育性基因的分析,确定在此组合中雌性不育基因由1对主效基因控制;结合混合分组分析法(Bulk Segregant Analysis,BSA),首次对小麦雌性不育基因进行了SSR分子标记,通过对一千对微卫星引物的筛选,确定微卫星引物cfd36标记与主效基因连锁,遗传距离为20.2cM.     

Genetic analysis and molecular mapping of a presenescing leaf gene psll in rice （Oryza sativa L.）

A rice psl1 （presenescing leaf） mutant was obtained from a japonica variety Zhonghua 11 via radiation of ^60Co-γ in M2 generation. Every leaf of the mutant began to wither after it reached the biggest length, while the leaves of the wild variety could keep green for 25--35 d. In this study, genetic analysis and gene mapping were carried out for the mutant identified. The SSR marker analysis showed that the mutant was controlled by a single recessive gene （psl1） located on chromosome 2. Fine mapping of the psl1 locus was conducted with 34 new STS markers developed around psl1 anchored region based on the sequence diversity between Nipponbare and 93-11. The psl1 was further mapped between two STS markers, STS2-19 and STS2-26, with genetic distances of 0.43 and 0.11 cM, respectively, while cosegregated with STS2-25. A BAC contig was found to span the psl1 locus, the region being delimited to 48 kb. This result was very useful for cloning of the psl1 gene.     

Fine mapping of locus S-b for F1 pollen sterility in rice （Oryza sativa L.）

Strong heterosis existed in the hybrid of the subspe-cies in rice[1,2]. However, the partial sterility of the hy-brid hinders the utilization of the heterosis[3,4]. Ikehashi et al.[5,6] considered the female gamete as the main ste-rility form and proposed…     

RAPD tagging of a salt tolerant gene in rice

A salt tolerant rice mutant was obtained through tissue culture. The inheritance of salt tolerance in F2 population of mutant crossed with its original variety under salt stress was studied. According to the standard, the ratio of salt tolerant: sensitive was about 3:1 suggesting that there was a major gene related to salt tolerance in the mutant. By RAPD analysis with 220 10-mer primers, the gene was tagged by a 1.0 kb DNA fragment named OPS12-10 which was located on chromosome 7. The genetic distance between the major salt tolerant gene was 16.4 cm.     

水稻整体原位杂交实验技术方法的改进

以检测水稻SUPERWOMAN1(SPW1)/OsMADS16基因的表达模式为例,通过对杂交探针的制备、材料的固定及解离通透、显色等方面进行优化,获得背景值低、特异性高的SPW1/OsMADS16基因特异性表达结果.建立一套针对水稻的整体原位杂交技术,方法简单,费用低廉,可在离心管中多种材料同时进行.主要实验步骤包括探...     

上海地区杂草稻与水稻籽实形态差异比较研究

近年来,随着稻田直播技术的推广,杂草稻对栽培稻的危害也越来越大,比较杂草稻与水稻籽实之间的形态差异,能够为进境检验检疫中杂草稻的鉴别提供技术参考.从上海郊区(县)稻田内采集了包括杂草稻和水稻的98份样品,定量地测定了这98份样品的籽粒长和粒宽、籽粒长宽比、小穗长、芒长及株高,并对籽粒的颜色进行了分级.基于以上数据,应用聚类分析,发现98份样品可以区别出3组,分别包括57、33和8份样品,结合落粒性、穗形、种皮颜色及成熟时间等性状,明确组1为杂草稻,组2为栽培稻组,组3为少量形态上介于杂草稻和栽培稻的样品.应用主成分分析和无度量多维标定这两种排序方法对98个样品进行分析,进一步展示了各样品间的形态差异特点.方差分析发现,上海地区的杂草稻在粒长、粒宽、粒长/宽和小穗长这4个指标均显著地大于水稻,但是两者在株高和芒长上没有显著差异.     

Fine mapping of a semidwarf gene sd-g in indica rice（Oryza sativa L.）

The semidwarf gene sd-g which has been usedin indiea rice breeding in southern China is a new one, non-allelic to sd-1. To map sd-g, an F2 population derived fromthe cross between Xinguiaishuangai and 02428 was con-structed. The sd-g was roughly mapped between two mi-crosatellite markers RM440 and RM163, with genetic dis-tances of 0.5 and 2.5 cM, respectively. Then nine new poly-morphic microsatellite markers were developed in this region.The sd-g was further mapped between two microsatellitemarkers SSR5-1 and SSR5-51, with genetic distances of 0.1and 0.3 cM, respectively, while cosegregated with SSR418. ABAC contig was found to span the sd-g locus, the region be-ing delimited to 85 kb. This result was very useful for cloningof the sd-g gene.     

Genetic analysis and gene mapping of a dominant presenescing leaf gene <Emphasis Type="Italic">PSL3</Emphasis> in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Leaf senescence as an active process is essential for plant survival and reproduction. However, premature senility is harmful to agricultural production. In this study, a rice mutant, named as psl3 (presescing leaf 3) isolated from EMS-treated Jinhui 10, displays obvious premature senility features both in morphological and physiological level. Genetic analysis showed that mutant trait was controlled by a single dominant gene (PSL3), which was located on rice chromosome 7 between SSR marker c7sr1 and InDel marker ID10 with an interval of 53.5 kb. The result may be useful for the isolation of the PSL3 gene.     

Genetic analysis and gene fine mapping for a rice novel mutant （rl9〈t）） with rolling leaf character

Much attention has been paid to leaf shape of rice in the process of ideotype breeding[1]. Several authors have reported that the rolling of leaf in some degree helps keep it erect, consequently optimizing canopy light transmission condition, which is good for dry matter accumulation and for high yield[2―6]. Rice as a polymorphic crop has many types of vari- ety with different morphologies. In terms of leaf shape, different cultivars with rolling leaf have been identifiedin rice germplasm. Le…     

水稻抗条纹叶枯病分子标记在不同品种中的扩增比较

以感水稻条纹叶枯病品种＂日本晴＂、高抗品种＂kasalath＂以及14个目前在我国长三角地区水稻生产中被认为在抵抗条纹叶枯病方面具有较好效果的水稻品种为材料,分析比较了14对分子标记引物扩增16个水稻品种基因组获得的DNA产物.结果显示：在14对分子标记引物中,有8对在扩增感病品种＂日本晴＂和高抗品种＂Kasalath＂水稻基因组时可获得多态性条带.因此推断这8个标记可在以这两个品种为亲本的抗条纹叶枯病选育中使用;并且,本研究结果还将为利用本试验收集的14个水稻品种为亲本的分子标记辅助育种提供重要的背景信息.     

Genetic analysis and gene mapping of leafy head （lhd）, a mutant blocking the differen-tiation of rachis branches in rice （Oryza sativa L.）

Flowers, fruits and seeds are products of plant re- productive development and provide the important sources of foods for humans. Therefore, the moleculargenetic mechanisms of floral development have been ahotspot of research of plant developmental biology[1]. Rice is one of the most important staple food crops. Theoutcome of its reproductive development would determine the yield and quality of grains. Rice is also a model plantof cereals. Hence, the study of rice reproductivedevelopment, esp…     

一个水稻白化致死突变体abl25鉴定及其基因定位

经Co60辐照的粳稻嘉花1号得到一个新的致死白化突变体albino lethal 25(abl25),该突变体从发芽至4叶期表现为白化苗,之后逐渐死亡.与野生型嘉花1号相比,abl25突变体的叶绿素含量和类胡萝卜素的含量大大降低,叶绿体结构不正常,说明其叶绿体发育受到严重阻碍,导致植物死亡.遗传分析表明:该突变体受一对隐性核基因(abl25)控制,进一步利用abl25与广占63S杂交的F2分离群体,将该突变体基因(abl25)定位于第2染色体上SSR标记RM424与Indel分子标记ID7330之间,随后利用新开发的分子标记和扩大群体将其定位在Indel分子标记ID9111和ID9261之间的150 kb内,发现abl25是一个新的水稻苗期白化致死基因.     

Identification and gene mapping of a narrow and upper-albino leaf mutant in rice (Oryza sativa L.)

The leaf blade consists of color and shape traits. Studies of leaf-blade development are important for improvement of rice yield and quality because it is an essential organ for photosynthesis. A narrow and upper-albino leaf mutant (nul1) was identified from among progeny of the indica restorer line Jinhui10 raised from seeds treated with ethyl methane sulfonate. Under field conditions, the mutant displayed narrow and upper-albino leaf blades with significantly decreased photosynthetic pigment contents throughout their development. The narrow-leaf trait is caused by a decreased number of small veins. In contrast to the wild type, the growth period was extended by approximately 8 d and agronomic traits, such as effective panicle number, percentage seed set and 1000-grain weight, declined significantly in the nul1 mutant. Genetic analysis suggested that the narrow and upper-albino leaf characteristics showed coseparation and were controlled by one recessive gene. The Nul1 gene was mapped onto chromosome 7 between the Indel marker Ind07-1 and the Simple Sequence Repeat marker RM21637. The physical distance between the markers was 75 kb and eight genes were annotated in this region based on the rice Nipponbare genome sequence. These results provide a foundation for cloning and function analysis of Nul1.