Gene expression profiling under different photoperiod/temperature conditions in a photoperiod-/thermo-sensitive genic male sterile line of rice （Oryza sativa L.）

A photoperiod-sensitive genic male-sterile (PSGMS) line was found in 1973 as a spontaneous mutant of the rice variety Nongken 58 (Oryza sativa ssp. japonica) in Hubei Province, China[1]. The fertility of this line was determined by day length and temperat…     

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 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 an incomplete recessive gene for leaf rolling in rice （Oryza sativa L.）

Genetic analysis and fine mapping of genes controlling leaf rolling were conducted using two backcrossed generations （BC4F2, BC4F3） derived from a cross between QMX, a non-rolled leaf cultivar as a recurrent parent, and JZB, a rolled leaf NIL of ZB as a donor parent. Results indicated that leaf rolling was mainly controlled by an incompletely recessive major gene, namely rl（t）, and at the same time, affected by quantitative trait loci （QTLs） and/or the environment. A genetic linkage map was constructed using MAPMAKER/EXP3.0 with eight polymorphic markers on chromosome 2, which were screened by BAS method from 500 SSR markers and 15 newly developed insertion/deletion （InDel） markers. The position of rl（t） was estimated with composite interval mapping （CIM） method using WinQTLcart2.5. Gene rl（t） was mapped between markers InDel 112 and RM3763, and 1.0 cM away from InDel 112 using 241 plants in BC4F2 population. To fine map r（t）, one BC4F3 line with 855 plants was generated from one semi-rolled leaf plant in BC4F2. Four new polymorphic InDel markers were developed, including InDel 112.6 and InDel 113 located between markers InDe1112 and RM3763. Based on the information of recombination offered by 191 rolled leaf plants and 185 non-rolled leaf plants from the BC4F3 line ,we mapped r（t） to a 137-kb region between markers InDel 112.6 and InDel 113. Homologous gene analysis suggested that r（t）was probably related to the process of leaf development regulated by microRNA.     

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.     

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…     

Morphological and physiological analysis of narrow and striped leaf 1 （nsl1） mutant of rice （Oryza sativa L.） and the gene mapping

The shape and color of rice leaves are impor- tant agronomic traits that directly influence the proportion of sunlight energy utilization and ultimately affect the yield and quality. A new mutant exhibiting stable inheritance was identified as derived from ethyl methane sulfonate （EMS）-treated restorer Jinhui 10, tentatively named as narrow and striped leaf 1 （nsll）. The nsll displayed pale white leaves at the seeding stage and then white striped leaves in parallel to the main vein at the jointing stage. Meanwhile, its leaf blades are significantly narrower than the control group of Jinhui 10. The chloroplast structures of cells in the white striped area of the nsll mutant break down, and the photosynthetic pigments are significantly lower than that of the wild type. Moreover, fluorescence parameters, such as Fo, Fv/Fm, ФpsⅡ, qP, and ETR, in the nsll mutant are significantly lower than those of the wild type, and the photosynthetic efficiency is also significantly decreased. These changes in leaf color and shape, together with physiological changes in the nsll, result in smaller plant height and a decrease in the most important agro- nomic traits, such as the number of grains per panicle, grain weight, etc. Genetic analysis shows that the narrow and striped traits of the nsll mutant are controlled by a single recessive nuclear gene, which is located between InDel 16 and InDel 12 in chromosome 3. The physical distance is 204 kb. So far, no similar genes of such leaf color and shape in this area have been reported, This study has laid asolid foundation for the gene cloning and function analysis of NSL 1.     

Identification of a novel tillering dwarf mutant and fine mapping of the TDDL（T） gene in rice （Oryza sativa L.）

Rice plant architecture is an important agronomic trait that affects the grain yield. To understand the molecular mechanism that controls plant architecture, a tillering dwarf mutant with darker-green leaves derived from an indica cultivar IR64 treated with EMS is characterized. The mutant, designated as tddl（t）, is nonallelic to the known tiilering dwarf mutants. It is controlled by one recessive nuclear gene, TDDL（T）, and grouped into the dn-type dwarfism according to Takeda＇s definition. The dwarfism of the mutant is independent of gibberellic acid based on the analyses of two GA-mediated processes. The independence of brassinosteroid （BR） and naphthal-3-acetic acid （NAA） of the tddl（t） mutant, together with the decreased size of parenchyma cells in the vascular bundle, indicates that the TDDL（7） gene might participate in another hormone pathway. TDDL（T） is fine mapped within an 85.51 kb region on the long arm of rice chromosome 4, where 20 ORFs are predicted by RiceGAAS （http：//ricegaas.dna.affrc. go.jp/rgadb/）. Further cloning of TDDL（T） will benefit both marker assisted selection （MAS） of plant architecture and dissection of the molecular mechanism underlying tillering dwarf in rice.     

Genetic analysis and mapping of rice （Oryza sativa L.） male-sterile （OsMS-L） mutant

A rice male-sterile mutant OsMS-L of japonica cultivar 9522 background, was obtained in M4 population treated with ^60Co γ-Ray. Genetic analysis indicated that the male.sterile phenotype was controlled by a single recessive gene. Results of tissue section showed that at microspore stage, OsMS-L tapetum was retarded. Then tapetal calls expanded and microspores degenerated. No matured pollens were observed in OsMS-L anther locus. To map OsMS-L locus, an F2 population was constructed from the cross between the OsMS-L (japonica) and LongTeFu B(indica). Firstly, the OsMS-L locus was roughly mapped between two SSR markers, RM109 and RM7562 on chromosome 2. And then eleven polymorphic markers were developed for further fine fine-mapping. At last the OsMS-L locus was mapped between the two lnDel markers, Lhsl0 and Lhs6 with genetic distance of 0.4 cM, respectively. The region was delimited to 133 kb. All these results were useful for further cloning and functional analysis of OsMS-L.     

转抗菌肽B基因水稻(Oryza sativa L.)植株的再生

通过研究除草剂Basta对水稻品种台安 1号愈伤组织生长的影响 ,确定了能抑制愈伤组织生长的最低剂量 ;在此基础上将抗菌肽B基因 (cecropinB)和bar基因导入了台安 1号基因组。除草剂抗性鉴定结果表明 :转基因植株表现出对Basta较强的抗性 .     

Salt tolerance of transgenic rice (Oryza sativa L.) with mtlD gene and gutD gene

Southern blot analysis indicated that mtlD gene (encoding mannitol-1-phosphate dehydrogenase) and gutD gene (encoding glucitol-6-phosphate dehydrogenase) had been integrated into the rice genome mediated by Agrobacterium tumefaciens LBA4404(pBIGM). The expression of the above two genes in transgenic rice plants was demonstrated by Northern blot analysis and enzymatic activity assay. Analysis of sugar alcohol showed that transgenic rice plants could produce and accumulate mannitol and sorbitol. The salt tolerance of transgenic plants was much higher than that of their controls.     

一个新的水稻矮秆突变体sd-sl的遗传与基因定位研究

新的矮秆基因的发掘、研究和利用对水稻育种和植物生长发育机制研究有重要的作用.用60Coγ射线辐照粳稻9522,获得一个能稳定遗传的突变体.该突变体表型为株高较野生型矮,叶片短而微卷.将该突变体与籼稻广陆矮杂交,F2代呈3∶1分离,说明该突变体受隐性单基因控制.通过InDel分子标记对F2代分离群体进行遗传定位,将该基因定位于第6染色体InDel标记OS604附近.随后又发展了多对有多态性的InDel分子标记,将该基因座位精细定位在InDel标记XL6-6和XL6-1之间,AP003490和AP005619上,两个引物之间的物理距离为118 kb.本研究为该克隆基因及其作用机理的探究奠定了基础.     

Identification of salt-tolerance QTL in rice (Oryza sativa L.)

Quantitative trait loci (QTLs) controlling salt-tolerance at the seedling stage in rice (Oryza sativa L.) were identified by interval mapping (SIM) and composite interval mapping (CIM) using a doubled haploid population ZJDH and its high resolution genetic linkage map. The population was derived from an inter-subspecific cross between an indica variety Zhaiyeqing8 (ZYQ8) and a japonica variety Jingxi17 (JX17). Analysis of survival days of seedlings treated with 0.7% NaCI revealed that a major salt-tolerance quantitative trait locus (QTL), Std, was present between markers RG612 and C131 on chromosome 1 when using both MAPMAKER/QTL 1.1 and PLABQTL 1.0 (SIM). Its allele which contributes to salt-tolerance was from ZYQ8. In addition, seven more QTLs which give additive effect on salt-tolerance are identified when using PLABQTL (CIM), and most of them were from JX17.