Chromosomal Location of HWA1 and HWA2, Complementary Hybrid Weakness Genes in Rice

Hybrid weakness phenomena in rice reportedly have two causes: those of HWC1 and HWC2 genes and those of HWA1 and HWA2 genes. No detailed study of the latter has been reported. For this study, we first produced crosses among cultivars carrying the weakness-causing allele on the HWA1 and HWA2 loci to confirm the phenotype of the hybrid weakness and the genotypes of the cultivars on the two loci, as reported earlier. We then confirmed that these cultivars belong to Indica. Subsequent linkage analysis of HWA1 and HWA2 genes conducted using DNA markers revealed that both genes are located in the 1,637-kb region, surrounded by the same DNA markers on the long arm of chromosome 11. The possibility of allelic interaction inducing hybrid weakness is discussed.     

水稻半显性矮秆基因Si-dd1的表型分析和精细定位

以粳稻品种日本晴在组织培养过程中分离出来的一个半显性矮秆突变体Si-dd1为研究对象,通过形态学分析,发现与野生型日本晴相比,矮秆Si-dd1(AA)和半矮秆Si-dd1(Aa)植株的株高降低。结实率下降,生育期延长,一次枝梗和二次枝梗增加。激素处理结果表明突变体Si-dd1(AA)与野生型对油菜素内酯反应基本相同,而在高浓度赤霉素处理下,突变体Si-dd1(AA)表现为一定程度上的钝感。Western blot对GID2表达量分析也确定这一结果。组织切片实验表明,突变体Si-dd1(AA)相对于野生型叶片主脉气孔变小,叶肉细胞增多,茎维管束数目增加。遗传分析结果表明该突变体基因受一对核基因控制。进一步利用分子标记将该基因定位在水稻第6染色体约244 kb区间内,目前该区段并未发现已报道的矮秆相关基因。     

一个水稻卷叶基因rl(t)的精细定位

 叶片适度卷曲是水稻理想株型塑造的重要组成部分。卷叶基因rl(t)在杂合状态下可使叶片适度卷曲,增加水稻产量,具有较高的育种利用价值。以卷叶珍汕97B\[携带rl(t)基因\]与平展叶品种奇妙香（轮回亲本）杂交并回交的BC5F3和BC5F4为定位群体,在前人关于rl(t)的定位区间内设计了15对多态性分子标记,将rl(t)精细定位于第2染色体上分子标记P95053和P113.6之间的11 kb范围内,遗传间距约0.04 cM。区间内只包含1个释义基因,预测编码GL2类同源异型结构域,属于同源异型盒家族中的HD GL2类（也称为HD ZIP Ⅳ）转录因子。卷叶基因rl(t)的精细定位为克隆目标基因和研究其调控机理奠定了基础。     

Identification and Fine Mapping of Heading Date Related Mutant Gene in Rice

A rice heading-date-related mutant was isolated from a 60 Co-γ-ray-induced mutation pool of Zhejing 22,a conventional japonica cultivar in Zhejiang Province,China.The mutant was characterized by a delayed heading date of almost 20 d longer than the wild type plant.Genetic analysis revealed that the mutation was controlled by a single nuclear-encoded recessive gene that was designed as HD(t)(heading date tentatively).To isolate the HD(t) gene,a map-based cloning approach was employed using 479 F 2 mutant individual plants derived from the cross between the hd(t) mutant(japonica) × Zhenshan 97(indica).Finally,the HD(t) gene was mapped to an approximate 53 kb region between the insertion and deletion(InDel) markers of 10-61W and 10-66W on chromosome 10.According to the genome sequence of Nipponbare,the target region contains 11 annotated genes.It is helpful for future cloning of HD(t) gene based on this fine mapping results.     

Genetic Analysis and Gene Mapping of a Rice Tiller Angle Mutant tac2

Tiller angle, a very essential agronomic trait, is significant in rice breeding, especially in plant type breeding. A tiller angle controlling 2 (tac2) mutant was obtained from a restorer line Jinhui 10 by ethyl methane sulphonate mutagenesis. The tac2 mutant displayed normal phenotype at the seedling stage and the tiller angle significantly increased at the tillering stage. A preliminary physiological research indicated that the mutant was sensitive to GA. Thus, it is speculated that TAC2 and TAC1 might control the tiller angle in the same way. Genetic analysis showed that the mutant trait was controlled by a major recessive gene and was located on chromosome 9 using SSR markers. The genetic distances between TAC2 and its nearest markers RM3320 and RM201 were 19.2 cM and 16.7 cM, respectively.     

一个水稻分蘖角度突变体tac2的遗传分析和基因初步定位

  水稻散生突变体tac2是以恢复系缙恢10号为材料经甲基磺酸乙酯（EMS）化学诱变所得。该突变体苗期表型正常,分蘖期株型松散,分蘖角度较野生型显著增大,株高明显降低。外源赤霉素处理可以使该突变体株高恢复,但分蘖角度不受影响。遗传分析表明该突变性状受1对隐性主效基因控制。利用分子标记将该基因初步定位于第9染色体上的RM3320与RM201之间,遗传距离分别为19.2和16.7 cM。     

优质香型杂交水稻新组合川香优2号

川香优2号是四川省农科院作物所用川香29A与成恢177配组育成的香型杂交水稻新组合。稻米品质优，抗稻瘟病力较强，2002年3月通过四川省农作物品种审定委员会审定。     

利用基因组文库加速Xa23基因定位的染色体步移

 用距离水稻抗白叶枯病基因Xa23 0.8 cM的EST标记C189，扩增Xa23的近等基因系CBB23的基因组片段（0.8 kb）为探针,筛选水稻明恢63的TAC文库和广陆矮4号的PAC文库，对获得的7个阳性克隆用酶切法和Tail PCR法进行末端片段分离，获得15个末端片段， 用于感病亲本金刚30和抗病亲本CBB23之间的多态性检测，发现7个末端片段在双亲间有多态性，分别为69B、70N、81N、45B、45N、84N和84B。用这些末端片段作RFLP标记，对金刚30/CBB23的F2群体进行检测和连锁分析,结果表明这些标记与Xa23的遗传距离依次为0.4、0.4、0.4、0.5、0.6、0.6和1.1 cM。虽然69B、70N和81N与Xa23的遗传距离均为0.4 cM，但序列比对揭示69B与70N的物理距离为35 kb，与81N为95 kb，69B距Xa23最近。三者与Xa23的遗传距离虽然相同，但物理距离存在很大差异。这些末端片段标记加密了Xa23基因一侧的遗传图谱，并使其遗传距离缩短到0.4 cM，加速了Xa23的定位进程，为Xa23的分离克隆奠定了重要基础。讨论了这种染色体步移方法的适用条件。     

Fine Mapping of C(Chromogen for Anthocyanin)Gene in Rice

Seven residual heterozygous lines(RHLs)displaying different genotypic compositions in the genomic region covering probable locations of C (Chromogen for anthocyanin)gene on the short arm of rice chromosome 6 were selected from the progenies of the indica cross Zhenshan 97B/Milyang 46.Seeds were harvested from each of the seven plants,and the resultant F2:3 populations were used for fine mapping of C gene.It was shown in the populations that the apiculus coloration matched to basal leaf sheath coloration in each plant.By relating the coloration performances of the populations with the genotypic compositions of the RHLS,the C locus was located between rice SSR markers RM314 and RM253.By using a total of 1279 F2:3 individuals from two populations showing coloration segregation.the C locus was then located between RM111 and RM253,with genetic distances of 0.7 cM to RM111 and 0.4 cM to RM253.Twenty-two recombinants found in the two populations were assayed with seven more markers located between RM111 and RM253,including six SSR markers and one marker for the C gene candidate,OsC1.The C locus Was delimited to a 59.3-kb region in which OsC1 was located.     

Fine Mapping of C（Chromogen for Anthocyanin） Gene in Rice

Seven residual heterozygous lines (RHLs) displaying different genotypic compositions in the genomic region covering probable locations of C (Chromogen for anthocyanin) gene on the short arm of rice chromosome 6 were selected from the progenies of the indica cross Zhenshan 97B/Milyang 46. Seeds were harvested from each of the seven plants, and the resultant F_2:3 populations were used for fine mapping of C gene. It was shown in the populations that the apiculus coloration matched to basal leaf sheath coloration in each plant. By relating the coloration performances of the populations with the genotypic compositions of the RHLs, the C locus was located between rice SSR markers RM314 and RM253. By using a total of 1279 F_2:3 individuals from two populations showing coloration segregation, the C locus was then located between RM111 and RM253, with genetic distances of 0.7 cM to RM111 and 0.4 cM to RM253. Twenty-two recombinants found in the two populations were assayed with seven more markers located between RM111 and RM253, including six SSR markers and one marker for the C gene candidate, OsC1. The C locus was delimited to a 59.3-kb region in which OsC1 was located.     

水稻色素原基因C的精细定位

应用籼稻组合珍汕97B/密阳46的衍生材料,针对水稻第6染色体短臂色素原基因C的可能位置,筛选到在C基因周围区间呈不同基因型组合的7个剩余杂合体,收获种子建立F2∶3群体。在各个植株上,稃尖颜色和叶鞘颜色的表现完全相同。通过各个群体颜色表现与原剩余杂合体基因型的比较,将C基因定位于微卫星标记RM314与RM253之间。在该基础上,应用两个分离群体共1279个样本,经标记检测和连锁分析,进一步将C基因定位于RM111和RM253之间, 与RM111和RM253的遗传距离分别为0.7 cM和0.4 cM。最后,应用区间内的另外6个微卫星标记和1个源于C基因候选基因OsC1的标记,检测在RM111 C基因 RM253区间内发生了重组的22个个体,将C基因定位于一个大小为59.3 kb、涵盖C基因候选基因OsC1座位的区间中。     

一个水稻叶片白化转绿叶突变体的遗传分析和精细定位

 在水稻品种宜香B中发现了一个白化转绿叶突变体,经过多代自交获得了稳定的白化转绿叶色突变体。该突变体在4叶期前叶色为黄绿色,之后逐渐变绿,从苗龄4周到12周,突变体/野生型叶绿素含量比值从34.5%逐渐升高到99.4%。遗传分析表明该突变受1对隐性核基因控制,暂命名为gra。利用微卫星标记将gra初步定位于第10染色体标记RM596和RM5620之间,进一步利用极端个体定位法把gra精细定位于标记RM25522和RM25535之间。gra基因距RM25522和RM25535标记的遗传距离均为0.05 cM, 其物理距离约为136 kb。     

优质两系杂交稻两优363

利用自育优质香型两用核不育系360S与明恢63配组，育成了优质两系杂交稻新组合两优363。两优363不仅产量较高，而且米质优，理化指标和食味口感鉴评均达到优质米标准。2000年通过了贵州省农作物品种审定委员会审定，具有较好的推广应用前景。     

一个水稻新黄绿叶突变体基因的分子定位

在水稻品种武运粳7号中发现了一个黄绿叶自然突变体,经过多代自交形成了稳定的突变系。该突变系和武运粳7号的正反交F2代的遗传分析表明该材料的黄绿叶由1对隐性基因控制,命名为 ygl 2。利用已有的微卫星（SSR）标记和新发展的SSR标记将 ygl 2基因定位于RM1340、RM7269、RM6298、SSR6 16和RM7434、SSR6 5、SSR6 9、RM5957之间,排列位置为RM1340-RM7269-RM6298-SSR6 16 -ygl 2-RM7434-SSR6 5、SSR6 9-RM5957,它们之间的遗传距离分别为238、0.37、0.00、0.62、0.74、0.49、0.86和1.62 cM,这为 ygl 2基因的分子标记辅助选择育种和图位克隆奠定了基础。     

水稻新裂颖突变体sg1的遗传分析与基因定位

从中籼3037辐射突变体库中获得一个颖花开裂突变体(split glume1,sg1),表型分析发现该突变体不仅颖壳异常,且伴随着生育期提前,植株变矮,颖花退化等现象,结实率也显著降低。遗传分析和分子生物学分析结果表明该突变受1对隐性核基因控制,并最终将其定位在水稻第1染色体上分子标记M1-z21与M1-z27之间,物理距离约为47kb,这是一种控制颖花发育的新基因,通过预测发现该区段内存在6个开放阅读框。     

籼稻脂肪酶基因的遗传分析及定位

对籼稻材料PT46（高脂肪酶活性）和WP20（低脂肪酶活性）及其F2群体进行了脂肪酶活性的定量测定和遗传分析。χ2测验结果表明,F2群体表现型分布符合1∶2∶1的孟德尔分离比,表明脂肪酶活性高低由1对单基因控制,低脂肪酶活性为隐性性状。结合SSR分子标记,以F2群体为定位群体,将脂肪酶活性基因定位在水稻第3染色体上,与SSR标记RM7和RM232之间的遗传距离分别为14.8 cM和4.1 cM,暂命名为la（lipase activity）。采用人工老化的方法,以种子发芽率和老化指数评价两亲本及其F2群体的耐储藏特性,结合所测定的脂肪酶活性数据进行相关性分析。结果表明,随着老化时间的延长,脂肪酶活性高的材料,发芽率降低迅速,老化指数增加很快,而脂肪酶活性较低的材料,老化指数变化相对较慢,即脂肪酶活性低的材料较耐储藏。经10、20 d人工加速老化处理后的种子老化指数与种胚脂肪酶活性的相关系数分别为0.6165**和0.4703**,表明老化指数与脂肪酶活性呈显著正相关。     

水稻抽穗期基因的精细定位、克隆和生物学功能分析

介绍了水稻抽穗期QTL研究的进展,在相同亲本日本晴/Kasalath衍生的不同类型的多个群体中,共检测到15个QTL;应用高世代回交后代,精细定位了其中8个QTL;将在初步定位时同一区间检测到的1个控制种子休眠期QTL(Sdr1)和1个抽穗期QTL (Hd8),分解为两个紧密连锁的基因;将经过精细定位表明可能具有双重功能的单个孟德尔因子Hd3,分解为两个功能不同的紧密连锁的基因Hd3a和Hd3b;根据QTL近等基因系的光周期反应以及这些座位间上位性互作的研究,明确了其中6个QTL的生物学功能;应用图位法克隆了其中3个QTL,研究了它们的表达和调控,并与拟南芥的同源基因进行比较。为水稻其他数量性状以及其他作物数量性状的遗传学研究,提供了一个范例。     

水稻花器官发育基因DPS2的鉴定和精细定位

【目的】鉴定和克隆花器官发育相关基因,为进一步研究水稻花发育的分子机制奠定基础。【方法】在大田常规种植条件下比较了突变体dps2 (Defective pistil and stamens 2)和野生型春江06的主要农艺性状及花器官形态特征差异;扫描电镜及石蜡切片观察花药结构并用染色法观察花粉和胚囊的育性;利用图位克隆方法进行基因精细定位;qRT-PCR分析了花发育相关基因在野生型和突变体中的表达水平。【结果】dps2突变体抽穗期变长,不能正常扬花,雄蕊和雌蕊皱缩且花药和柱头数目增多;进一步研究发现,dps2突变体花药腔室塌陷,内无可见小孢子,即使部分花药形成腔室,花粉粒也无淀粉积累呈干瘪状。此外,突变体胚囊育性也受到影响;遗传分析表明该突变性状受一对隐性核基因控制,该基因位于第4染色体短臂上91.2 kb的区间内,区间内未见花器官发育相关基因的报道。qRT-PCR检测发现,水稻ABCDE模型中的B类、C类和E类基因的表达在突变体中显著升高。【结论】dps2突变体的雄蕊及雌蕊均发育异常,最终导致完全不育,推测DPS2可能在水稻第3轮雄蕊发育和第4轮雌蕊发育调控中发挥重要作用。