水稻叶状颖壳突变体Oslh的遗传分析和OsLH基因的定位

通过γ射线诱变,从粳稻品种9522的M2代中筛选出一株具有叶状颖壳的突变体,定名Oslh(1h=leafy hull).Oslh突变体的开花时间要比野生型晚15 d左右,内外稃和浆片发育成了叶片状器官.Oslh突变体与粳稻品种9522回交结果表明Oslh突变性状可能由单核基因隐性突变造成.以Oslh突变体与籼稻品种广陆矮4号杂交的F2代群体为基因定位群体,利用SSR和InDel分子标记将Oslh突变位点定位在3号染色体上的SSR标记RM5475和InDel标记GY305之间,遗传距离分别为2.5 cM和1.9 cM.这些结果为克隆OsLH基因和研究花器官发育的调控机理奠定了基础.     

陆地棉超矮杆突变体基因的初步定位

陆地棉超矮杆是一种新发现的突变体材料。前期对其遗传规律的研究表明,超矮杆突变性状是受一对完全隐性基因du控制的质量性状。文章以"超矮1号"和"新陆早16"配置的F2为作图群体,通过对双亲以及近等基因池的筛选,在1 350对SSR引物中共获得70对多态性引物。而后检测F2作图群体每个单株的基因型,显示有36个标记可以连锁,分布在8个连锁群上,其中超矮杆突变性状位于连锁群LG01。与目标基因du连锁的分子标记有7个:NAU2679、NAU2749、NAU905、NAU2838、NAU5373、NAU2238和NAU4946,它们皆为共显性标记。依据现有的棉花遗传图谱,标记NAU4946、NAU2238、NAU905、NAU5373和NAU2679位于第6染色体上,而目标基因du位于NAU2238和NAU4946之间,遗传距离分别为3.3 cM和1.4 cM,由此推定du在第6条染色体上。     

用微卫星标记定位太空诱变玉米核不育基因

用姊妹交多代的太空诱变玉米雄性不育材料RP3195(A)×S37(自交系)的两个不同果穗的F2代群体作为育性调查和基因定位群体,这两个果穗的F2代群体分别为138株和247株。用326对微卫星引物进行差异筛选,其中有56对引物出现多态性,然后用56对引物对F2代群体进行分析,结果表明引物bnlg197和umc1012与不育基因连锁,其中在F2代群体的不同果穗中引物bnlg197与不育基因之间的遗传距离分别为7cM和14.5cM,标记umc1012在F2代群体(138株)中与不育基因之间的遗传距离为28.5cM,据此将该核不育基因定位在3L染色体上。     

水稻白色中脉Oswm2的遗传分析与分子标记定位

从T-DNA突变体库中获得一份以中花11为遗传背景的白色中脉突变体。该突变体剑叶以下叶片的中下部中脉表现为白色, 白色中脉附近的叶色微黄, 并且伴随株高等农艺性状的改变, 暂时将其定名为Oswm2(Oryza sativa white midrib 2)。遗传分析表明该突变性状受一对隐性单基因控制, 以Oswm2和粳稻02428杂交的F2分离群体作为定位群体, 将OsWM2基因定位在水稻第7染色体的SSR标记RM21478和RM418之间, 遗传距离分别为8.7和15.9 cM。     

水稻顶节间长度控制基因(EUI)的精细定位

通过对一水稻顶节间特异伸长突变体Mh-1进行经典遗传学和基因定位分析,认为该表型是一个核基因隐性突变所致。利用Mh-1与正常的T65-sd1杂交的F2群体对该位点定位研究分析,发现其与水稻第5条染色体长臂STS标记E30531和CAPS标记C903连锁,遗传距离分别为6．7cM和2．8cM。经进一步发展新的分子标记,将该基因精确定位在0．3cM的区域,为进一步克隆和研究该基因的分子机制奠定基础。     

萝卜细胞质雄性不育恢复基因的RAPD标记

以萝卜恢复系9802和不育系9802A配制杂交组合,并以174株个体组成的F2分离群体作为恢复基因的标记群体.以分离群体的不育株和可育株分别建立不育池和恢复池,利用100个RAPD引物对两池间的多态性进行研究.分析表明引物OPC6在两池间扩增出稳定的多态性差异.经连锁分析,证明标记OPC61900与萝卜细胞质雄性不育恢复基因连锁,遗传距离为11.6cM(Centimorgan).这个标记可应用于对育性恢复基因的标记辅助选择.     

水稻短根毛突变体Ossrh2的表型分析与基因定位

在粳稻品种中花11为遗传背景的T-DNA突变体库中筛选获得一个遗传稳定的水稻（Oryzasativa）短根毛突变体Ossrh2（Oryza sativa short root hair2）。突变体在苗期表现为根毛数量减少,为野生型的61.4%,根毛长度明显变短,只有野生型的22.8%,同时根毛增粗,根毛形态也发生了变异,局部扭曲膨胀和分叉,除此之外突变体的地上部和根部生长情况与野生型相比没有显著差异。遗传分析表明,该突变性状受1对隐性单基因控制。通过对突变体T2和F2代的分子检测发现,该突变体表型非T-DNA插入引起。利用Ossrh2纯合体和籼稻品种Kasalath杂交构建的F2群体对OsSRH2进行基因定位,发现其与第10号染色体短臂上的SSR（simple sequence repeat）标记RM6370和RM474连锁,遗传距离分别为1.1cM和3.0cM。通过在两标记间发展3个新的STS（sequence-taggedsite）标记,将OsSRH2基因定位于标记S1227和S1531之间,物理距离约为304kb,为进一步克隆OsSRH2打下了基础。     

小麦新抗源CH5383抗条锈病基因的遗传分析及分子定位

CH5383是新育成的源于中间偃麦草的渗入系,对小麦条锈病和白粉病均表现免疫。为明确其抗性来源、遗传方式和抗病基因在染色体上的位置,将CH5383的系谱材料及其与高感条锈病品种(系)杂交的F1、F2和F2:3家系群体进行条锈病抗性鉴定。结果表明,CH5383对条锈病的抗性源于中间偃麦草,对条锈病生理小种CYR32的抗性由一对显性核基因控制,将此基因暂时命名为YrCH5383。从476对SSR引物中筛选到3对引物Xgwm108、Xbarc206和Xbarc77与抗病基因连锁,遗传距离分别是8.2 cM、10.7 cM和13.6 cM。根据这两对标记在染色体上的位置,将抗病基因定位到3B染色体的长臂上。3B染色体的长臂还未见有正式命名的抗条锈病基因的报道,推测YrCH5383可能是一个源于中间偃麦草的新抗条锈病基因。     

水稻无内稃突变体的遗传分析和基因定位

花器官发育异常的突变体是研究植物花发育分子遗传机制的良好实验材料,以水稻无内稃突变体为父本,生47、N625和CDR22为母本配制杂交组合进行性状遗传分析,根据F2代表型及X^2测验结果表明,突变性状是由单隐性基因控制的,选用突变体为父本,生47为母本杂交的F2群体作定位群体,利用SSLP标记的和RFLP标记将与突变性状相关的基因定位在第6染色体短臂上RFLP标记C498和RZ450之间,暂定名为npa-1。为进一步的基因克隆及功能研究奠定了基础。     

一个籼稻脆性突变体的生物学特性及基因定位研究

水稻脆性突变体是研究细胞壁组分结构形成机制的重要材料。通过离子束诱变籼稻9311获得1个茎秆、叶片均脆的突变体,命名为bc9311-1。bc9311-1突变体与野生型9311相比,分蘖数减少,结实率显著降低,其他农艺性状无明显差异。叶片和茎秆的细胞壁成分分析表明,与野生型相比,bc9311-1突变体茎秆中的纤维素和木质素含量明显降低,半纤维素和SiO2含量显著增加;叶片中的纤维素含量降低,半纤维素和木质素含量增加,SiO2含量无明显差异。遗传分析表明,该脆性突变体脆性性状受单隐性基因控制。以bc9311-1突变体与02428杂交的F2群体为基因定位群体,利用SSR标记将bc9311-1突变位点定位在水稻第1染色体上,位于SSR分子标记的RM1095和RM3632之间,遗传距离分别为0.6cM和3.4cM,与其中的标记RM1183表现共分离。这些结果为进一步克隆突变基因,揭示脆性性状的分子机制奠定坚实基础。     

用微卫星标记定位小麦T型CMS的恢复基因

以T型细胞质雄性不育系 75 336 9A×恢复系 72 6 9 10的F2 群体作为育性调查和基因定位群体。通过育性分析 ,确定该恢复系含有 2个主效恢复基因 ;结合群分法 ,对恢复基因进行了SSR分子标记定位 ,在 2 30对微卫星引物中 ,微卫星标记Xgwm136和Xgwm5 5 0分别与 2个主效恢复基因连锁。这两个标记与Rf基因之间的遗传距离分别为 6 7cM和 5 1cM ,从而将该恢复基因定位在 1AS、1BS染色体上。     

甘蓝型油菜花瓣缺失基因的图谱定位

在无花瓣品系APT02和正常有花瓣品种中双4号构建的的F2分离群体中,运用AFLP和SRAP两种标记技术对甘蓝型油菜花瓣缺失基因进行分子标记和图谱定位。在两亲本间筛选20对AFLP引物和170对SRAP 引物,进一步通过BSA法筛选,获得了与甘蓝型油菜花瓣缺失基因WHB连锁的1个SRAP标记e8m3_4（600bp）和1个AFLP标记E3247_15（150bp）,标记与基因WHB之间的遗传距离分别为5 cM和13.5cM;构建了一个甘蓝型油菜(Brassica napus.L )的分子标记遗传连锁图谱,该图谱共包含213个AFLP标记、56个SRAP标记和1个形态标记,分布于17个主要连锁群、两个三联体和4个连锁对中,遗传图距总长2487.1cM,标记间平均距离为10.09 cM。通过图谱定位,控制花瓣缺失性状的基因WHB被定位到第4连锁群(LG4)上。     

Genetic analysis and high-resolution mapping of a premature senescence gene Pse(t) in rice (Oryza sativa L.).

A rice mutant, designated pse(t) (premature senescence, tentatively), was isolated from a T-DNA-inserted transgenic population. Senescence advanced more markedly in pse(t) than in wild-type ('Zhonghua 11', japonica) plants. Genetic analysis of pse(t) revealed that the premature senescence mutation was controlled by a single recessive nuclear gene, but that it was not induced by T-DNA insertion. In an effort to understand the genetic and molecular basis underlying premature senescence in rice, a map-based cloning strategy was used to localize Pse(t). High-resolution mapping of the Pse(t) locus was carried out using simple sequence repeat (SSR) and cleaved amplified polymorphic sequence (CAPS) markers. An F2 population, comprising 1691 pse(t) individuals derived from a cross of the pse(t) mutant with 'Longtepu' (indica), was constructed. Several new polymorphism markers were developed in this study. Genetic linkage analysis showed that the Pse(t) gene was located on the long arm of chromosome 7. It was found that the Pse(t) gene cosegregated with 3 markers and was flanked by markers SS22 and PP21. Thus, the Pse(t) gene is located within a genetic distance of 0.15 cM, corresponding to a physical distance of 220 kb. These findings provide the basic information that can be used for the final isolation of this gene in the rice premature-senescence pathway.     

Chromosomal location of a <Emphasis Type="Italic">Triticum dicoccoides</Emphasis>-derived powdery mildew resistance gene in common wheat by using microsatellite markers

The powdery mildew resistance has been transferred from an Israeli wild emmer (Triticum dicoccoides) accession "G-305-M" into common wheat by crossing and backcrossing (G-305-M/781//Jing 411*3). Genetic analysis showed that the resistance was controlled by a single dominant gene at the seedling stage. Among the 102 pairs of SSR primers tested, four polymorphic microsatellite markers (Xpsp3029, Xpsp3071, Xpsp3152 and Xgwm570) from the long arm of chromosome 6A were mapped in a BC(2)F(3) population segregating for powdery mildew resistance and consisting of 167 plants. The genetic distances between the resistance gene and these four markers were: 0.6 cM to Xpsp3029, 3.1 cM to Xpsp3071, 11.2 cM to Xpsp3152 and 20.4 cM to Xgwm570, respectively. The order of these microsatellite loci agreed well with the established microsatellite map of chromosome arm 6AL. We concluded that the resistance gene was located on the long arm of chromosome 6AL. Based on the origin and chromosomal location of the gene, it is suggested that the resistance gene derived from "G-305-M" is a novel powdery mildew resistance gene and is temporarily designated MlG.     

Genetic diversity of sea-island cotton (Gossypium barbadense) revealed by mapped SSRs

In order to evaluate the genetic diversity of sea-island cotton (Gossypium barbadense), 237 commonly mapped SSR markers covering the cotton genome were used to genotype 56 sea-island cotton accessions. A total of 218 polymorphic primer pairs (91.98%) amplified 361 loci, with a mean of 1.66 loci. Polymorphism information content values of the SSR primers ranged from 0.035 to 0.862, with a mean of 0.320. The highest mean polymorphism information content value for the SSR motifs was from a compound motif (0.402), and for the chromosomes it was Chr10 (0.589); the highest ratio of polymorphic primers in Xinjiang accessions was from Chr21 (83.33%). Genetic diversity was high in Xinjiang accessions. AMOVA showed that variation was 8 and 92% among populations and within populations, respectively. The 56 sea-island accessions were divided into three groups in the UPGMA dendrogram: Xinhai5 was in the first group; accessions from Xinjiang, except the five main ones, were in the second group, and the other 34 accessions were in the third group. Accessions from the former Soviet Union and Xinjiang main accessions were closely related. Both PCA and UPGMA confirmed that Xinhai5 was distinct from the other accessions, and accessions from Xinjiang were in an independent group. Given the differences between principal components analysis and UPGMA results, it is necessary to combine molecular markers and pedigree information so that genetic diversity can be objectively analyzed.     

一个新水稻温敏感叶色突变体的遗传分析及其基因分子定位

在粳稻品种嘉花1号（Oryza sativa L.ssp.japonica＇ Jiahua No.1＇）种子经60Coγ射线辐照处理的后代中,发现了1个低温敏感叶色突变体mr21。在较低温度（〈25.0°C）条件下,该突变体幼苗叶色呈黄色;随着温度逐渐升高,叶色由黄转绿,其临界温度约为27.5°C;在低温条件下,突变体幼苗总叶绿素含量以及叶绿素a、b的含量均较野生型嘉花1号明显下降,表明该突变体的叶色性状具有明显的温敏感性。遗传分析表明,该突变体叶色性状受1对隐性核基因控制,暂将该突变基因命名为thermo-sensitive leaf-color1（tsl-1）。以该突变体与籼稻9311（Oryza sativa L.ssp.indica＇ 9311＇）杂交的F2代分离群体作为定位群体,利用SSR分子标记将tsl-1基因初步定位在水稻（Oryza sativa）第1号染色体短臂上的MM1799与RM8132分子标记之间,其遗传距离分别为2.4cM和3.0cM;然后,进一步利用扩大F2代群体及新发展的分子标记将tsl-1基因定位在分子标记InDel2与InDel4之间的198kb内。研究结果为今后对该基因的克隆和功能分析奠定了基础。     

利用SSR标记定位明恢63的2对恢复基因

选取珍汕97A和明恢63杂交组合的F2高可育和高不育单株构建基因池,利用302对SSR引物对其进行了多态性分析。结果表明,位于第1染色体上的RM1和位于第10染色体上的RM258,RM304在亲本,基因池间表现多态性,用F2单株验证证明它们与野败型恢复基因连锁,完全不育株分析表明,与恢复基因间的遗传距离分别为1.9,2.9和0.0cM,野败型,红莲型,BT型3种不育胞质恢复基因在第10染色体上可能为同一基因或家族成员。     

High-density Linkage Map of Cultivated Allotetraploid Cotton Based on SSR, TRAP, SRAP and AFLP Markers

A high-density linkage map was constructed for an F2 population derived from an Interspecific cross of cultivated allotetraploid species between Gossypium hirsutum L. and G. barbadense L. A total of 186 F2 individuals from the Interspecific cross of ＂CRI 36 × Hal 7124＂ were genotyped at I 252 polymorphic loci Including a novel marker system, target region amplification polymorphism （TRAP）. The map consists of 1 097 markers, including 697 simple se- quence repeats （SSRs）, 171 TRAPs, 129 sequence-related amplified polymorphisms, 98 amplified fragment length polymorphisms, and two morphological markers, and spanned 4 536.7 cM with an average genetic distance of 4.1 cM per marker. Using 45 duplicated SSR loci among chromosomes, 11 of the 13 pairs of homologous chromosomes were Identified In tetraploid cotton. This map will provide an essential resource for high resolution mapping of quantitative trait loci and molecular breeding in cotton.