新疆野生油菜胞质雄性不育系1193A对应恢复基因的SSR标记分析

以油菜细胞质雄性不育系1193A和恢复系1193R2为亲本构建F2分离群体,并运用BSA法构建了可育和不育基因池。利用1521对SSR引物进行了多态性分析,结果表明有36对引物在亲本和基因池间都表现多态性,用F2单株验证表明有11对引物与恢复基因连锁,离恢复基因较近的2个标记CB10316和Bn GMS171分布在恢复基因Rf的两侧,遗传距离分别为3.9 c M和5.7 c M,可作为恢复系标记辅助育种的候选标记。     

利用SSR标记定位油菜细胞质雄性不育系1193A的恢复基因

以油菜细胞质雄性不育系1193A和恢复系1193R2为亲本构建F2分离群体,并运用BSA法构建了可育和不育基因池。利用1521对SSR引物进行了多态性分析,结果表明有36对引物在亲本和基因池间都表现多态性,用F2单株验证表明有11对引物与恢复基因连锁,离恢复基因较近的2个标记CB10316和Bn GMS171分布在恢复基因Rf的两侧,遗传距离分别为3.9 c M和5.7 c M,可作为恢复系标记辅助育种的候选标记。     

与圭亚那柱花草不育基因相关的SRAP标记的筛选

本研究旨在筛选与柱花草花粉不育基因相关的特异性分子标记,为今后筛选特异SCAR标记及建立柱花草稳定的雄性不育系提供新的理论基础,为柱花草杂交育种奠定基础。本研究以圭亚那柱花草1979(母本,花粉不育)和热研5号(花粉可育,轮回父本)的30株BC1F1代群体为材料,利用100对SRAP引物组合,筛选出在花粉不育基因池中稳定扩增的2个SRAP标记。经基因池各单株验证和群体单株验证,这2个标记仅在花粉不育个体中出现,表明这2个标记与柱花草花粉不育基因存在一定的连锁关系。     

棉花'晋 A'细胞质雄性不育恢复基因定位

用晋A衍生不育系与恢复系组配的分离群体进行遗传与定位分析,晋A恢复基因在F2和BC1的分离比例分别符合3∶1和1∶1,证明恢复基因由1对显性基因控制.用9个SSR标记和4个STS标记构建长度为82.1 cM的连锁群,恢复基因Rf定位在第19染色体(D08),与最近的标记CM042和CIR179分别相距5.4 cM和10.3 cM.以晋A衍生的7个不育系、4个保持系和10个恢复系对标记进行验证,分别扩增出同样的特异带型,说明与晋A恢复基因紧密连锁的标记可以直接用于晋A恢复系的分子标记辅助选择.     

一个玉米CMS-C恢复基因的精细定位

为挖掘玉米C型细胞质雄性不育(CMS-C,C-type cytoplasmic male sterility)的育性恢复基因并解析基因功能,用恢复系K932R与2个CMS-C同质异核不育系K169S和K932S分别构建2个F2定位群体,结合SSR分子标记和分离群体分析法全基因组重测序(BSA-reseq)技术定位育性恢...     

萍乡显性核不育水稻育性相关基因的定位和遗传分析

萍乡显性核不育水稻(Pingxiang Dominant Genic Male Sterile Rice,PDGMSR)是在水稻中首次发现的显性核不育材料,其育性由两对显性基因互作控制,一对是萍乡显性核不育基因Ms-p,另一对是显性上位恢复基因(dominant epistatic fertility restorer gene,Rfe)。两者共同存在时显性上位恢复基因能抑制不育基因的表达,从而使育性表现可育。本实验用一个对萍乡显性核不育水稻有恢复能力的水稻品种E823与萍乡显性核不育水稻配制杂交组合,将(萍乡核不育水稻/E823)F2作为定位群体,根据F3株系的育性分离,选择育性分离株系对应F2单株(基因型为Ms-pMs-pRefrfe和Ms-pms-pRferfe)构建可育池,用对应F2株系中的不育单株(基因型为Ms-pMs-prferfe或Ms-pms-prferfe)构建不育池,将显性上位恢复基因Rfe定位在水稻10染色体RM311和RM3152一侧,遗传距离分别为7.9cM和3.6cM。根据已有的Ms-p的定位结果,合成10染色体部分微卫星引物,对不育单株进行分析,发现RM171和RM6745位于Ms-p的两侧,距离分别为0.3cM和3.0cM。根据10染色体的测序结果,将Ms-p界定在约730kb的范围内,并构建了Ms-p的电子重叠群。植物显性核不育的育性恢复机理存在“复等位基因”和“显性上位互作”两种假说,贺浩华等用经典的遗传学方法证明了萍乡显性核不育水稻育性恢复的遗传机理属于“显性上位互作”。理论上认为,确定其遗传机理最为有效的方法是基因定位,如果不育基因和恢复基因位于同一位点,则其遗传机理属于“复等位基因”,否则为“显性上位互作”。本实验将不育基因和恢复基因定位在水稻10染色体不同的位点,用基因定位的方法证实了萍乡显性核不育水稻育性恢复的遗传机理属于“显性上位互作”。     

水稻“三明”显性核不育基因的定位

"三明显性核不育水稻"突变体是由福建省三明市农业科学研究所于2001年在杂交组合"SE21S/Basmati370"的F2代群体中发现的。其不育性受1个显性基因控制(将该基因命名为SMS)。经过多代回交,该显性不育基因已导入籼稻品种佳福占的遗传背景中(将该不育材料称为佳不育)。为了定位SMS,文章将佳不育与粳稻品种日本晴杂交,并将F1与佳福占测交,构建了一个作图群体。利用SSR和INDEL标记,通过混合分离分析和连锁分析,将SMS定位于第8号染色体上两个INDEL标记ZM30和ZM9之间,约99 kb的区间内。该结果为克隆SMS奠定了基础。     

水稻“光身”突变体glr3的遗传分析及基因定位

在籼稻品种R401辐射诱变的M2群体中筛选到一个叶片表皮光滑突变体,在正常条件下,突变体叶片和颖壳光滑无毛。以毛叶粳稻品种Nipponbare和"光身"突变体作为亲本,构建了一个F2群体,通过调查该群体在正常种植条件下的表现,发现Nipponbare和"光身"突变体控制表皮毛性状的差异受单个主基因控制且"光身"为隐性,将该基因暂时命名为GLR3。利用该F2群体,采用BSA法将GLR3定位在第6染色体上,进一步对F2群体中417个典型的叶片光滑单株进行分子标记分析,将该基因定位在In Del标记ID27101和ID27199之间,与两标记相距皆为0.1 c M,两标记的物理位置相距98 kb。     

甘蓝型油菜温敏不育系417S育性遗传及RAPD分析

通过对新选育的甘蓝型油菜高温敏感生态型不育系417S与30份中外品种(系)进行测交、杂交和回交,研究其温敏不育性的遗传特点.结果表明:(1)30份品种(系)可不同程度的恢复417S的育性,其中24个品种(系)可完全恢复417S育性,占所配组合的80.0%;5个品种(系)可高度恢复417S的不育性,占所配组合的17.2%.(2)自然条件下同一组合正反交F2群体育性分离结果不同,人工控温条件下不同组合F2分离群体中可育与不育呈现15∶1分离,回交群体中出现3∶1分离,表明417S温敏不育性受细胞质和2对隐性重叠核基因共同控制.(3)以417S与1521C构成的回交一代群体为试材,采用分离群体分组分析法(BSA法)对回交一代群体构成的不育集团和可育集团筛选育性基因的RAPD标记,从247个供试引物中筛选出2个引物BA392(5′-AGTCACTCCC-3′)、S113(5′-GACGCCACAC-3′)在不育群体和可育群体间扩增出多态性产物.经进一步对F2分离群体的单株检测,引物BA392扩增出了得到重复验证和可靠的多态性扩增产物,其产生的特异条带BA392-400bp与417S温敏雄性不育的恢复基因连锁,遗传图距为6.0cM,可作为417S温敏不育恢复基因的连锁标记.     

葡萄雄性不育基因的初步定位

为了对葡萄雄性不育基因进行定位研究,以可育葡萄‘魏可’(Vitis vinifera L.)为亲本构建的自交群体88株为试验材料,运用分离群体分组混合分析法(bulked segregant analysis,BSA),构建了可育株和不育株基因池,结合SSR技术对葡萄雄性不育基因进行定位研究和生物信息学分析。该研究筛选到2个与葡萄雄性不育基因连锁的SSR标记VVMD34和VVIB23,且位于该基因两侧,遗传距离分别为3.5cM和1.9cM。2个标记间物理距离为1 134kb,在该区域总共预测到了111个候选基因。该研究对葡萄雄性不育基因的精细定位及分子标记辅助育种奠定了良好的基础。     

Genetic analysis,molecular tagging and mapping of the thermo-sensitive genic male-sterile gene (wtms1) in wheat

A thermo-sensitive genic male-sterile (TGMS) wheat line ( Triticum aestivum L.) BNY-S was obtained from the spontaneous mutant of BNY-F. Its fertility was decided by the temperature during the differentiation stage of the spikelets. BNY-S was completely sterile when the temperature was lower than 10 degrees C during the differentiation stage of the spikelets, but fertile when the temperature was higher than 10 degrees C. Genetic analysis indicated that the sterility of BNY-S was controlled by a single recessive gene, which was named as wtms1. An F(2) population, consisting of 3,000 individuals from the cross between BNY-S and Lankao 52-24, was used for genetic analysis and statistical analysis of the TGMS and, out of them, 158 sterile and 93 fertile extremes were present for molecular tagging and mapping of the wtms1 gene. SSR (simple sequence repeat) and AFLP (amplified fragment length polymorphism) techniques combined with BSA (bulked segregant analysis) were used to screen markers linked to the target gene. As a result, wtms1 was preliminarily mapped on chromosome 2B according to SSR analysis. In AFLP analysis, 14 polymorphic AFLP loci were identified with a linkage relation to the wtms1 gene. Then linkage analysis using the F(2) population showed that three of them, E: AAG/M: CTA(163), E: AGG/M: CTC(220) and E: ACA/M: CTA(160), were linked to the wtms1 gene relatively close to a genetic distance of 6.9 cM, 6.9 cM and 13.9 cM, respectively. Finally, the wtms1 gene was mapped between the SSR marker Xgwm 374 and the AFLP marker E: AAG/M: CTA(163) with the distance of 4.8 cM and 6.9 cM, respectively. A partial linkage map was constructed according the SSR and AFLP data.     

水稻苗期耐盐突变体的遗传分析及基因定位

在籼稻品种R401辐射诱变的M2群体中筛选到一个苗期耐盐突变体, 在150 mmol/L的NaCl溶液处理下对照植株枯萎死亡, 而突变体植株依然存活。以粳稻品种Nipponbare(不耐盐)和耐盐突变体作亲本, 构建了一个F2群体, 调查该群体在150 mmol/L的NaCl溶液胁迫下的表现, 发现Nipponbare和耐盐突变体苗期耐盐性的差异受单个主基因控制, 耐盐为隐性, 将该基因暂时命名为SST(t)。利用该F2群体, 采用集团分离分析(Bulked segregant analysis, BSA)法将SST(t)定位在第6染色体上, 进一步对F2群体中137个典型的耐盐单株的分子标记进行分析, 将该基因定位在InDel标记ID26847和ID27253之间, 约2.3 cM (或406 kb)的区间内, 与两标记分别相距1.2 cM和1.1 cM。     

Cytological and molecular characterization of a novel monogenic dominant GMS in <Emphasis Type="Italic">Brassica napus</Emphasis> L.

A novel genic male sterile (GMS) line in Brassica napus L., which was identified in 1999, was found to be controlled by a monogenic dominant gene, which we have designated as MDGMS. The microspores of the MDGMS abort before the degradation of the tapetal cell layer. The F1 fertility from any fertile lines crossed with MDGMS segregated and the ratio was close to 1:1. Bulked segregation analysis (BSA) was employed to identify random amplified polymorphic DNA (RAPD) markers linked to the Ms gene in MDGMS. Among 880 random 10-mer oligonucleotide primers screened against the bulk DNA of sterile and fertile, one primer S243 (5′-CTATGCCGAC-3′) gave a repeatable 1500-bp DNA polymorphic segment S243₁₅₀₀ between the two bulks. Analysis of individual plants of each bulks and other types of GMS and cytoplasmic male sterility (CMS) lines suggest that the RAPD marker S243₁₅₀₀ is closely linked to the MDGMS locus in rapeseed. This RAPD marker has been converted into sequence characterized amplified region (SCAR) marker to aid identification of male-fertility genotypes in segregating progenies of MDGMS in marker-assisted selection (MAS) breeding programs.     

Genetics of resistance to anthracnose and identification of AFLP and RAPD markers linked to the resistance gene in PI 320937 germplasm of lentil (<Emphasis Type="Italic">Lens culinaris</Emphasis> Medikus)

Anthracnose, caused by Colletotrichum truncatum, is a major disease problem and production constraint of lentil in North America. The research was conducted to examine the resistance to anthracnose in PI 320937 lentil and to identify molecular markers linked to the resistance gene in a recombinant inbred line (RIL) population developed from a cross of Eston lentil, the susceptible parent, and PI 320937, the resistant parent. A total of 147 F(5:6) RILs were evaluated for resistance to anthracnose in the greenhouse using isolate 95B36 of C. truncatum. Bulked segregant analysis (BSA) strategy was employed and two contrasting DNA bulks were constructed based on greenhouse inoculation of F(5)-derived F(6) RILs. DNA from the parents and bulks were screened with 700 RAPD primers and seven AFLP primer combinations. Analysis of segregation data indicated that a major dominant gene was responsible for resistance to anthracnose while variations in the resistance level among RILs could be the influences of minor genes. We designate the major gene as LCt-2. MapMaker analysis produced two flanking RAPD markers OPEO6(1250) and UBC-704(700) linked to LCt-2 locus in repulsion (6.4 cM) and in coupling (10.5 cM), respectively. Also, three AFLP markers, EMCTTACA(350) and EMCTTAGG(375) in coupling, and EMCTAAAG(175) in repulsion, were linked to the LCt-2 locus. These markers could be used to tag the LCt-2 locus and facilitate marker-assisted selection for resistance to anthracnose in segregating populations of lentil in which PI 320937 was used as the source of resistance. Also, a broader application of the linked RAPD markers was also demonstrated in Indianhead lentil, widely used as a source of resistance to anthracnose in the breeding program at the Crop Development Centre, University of Saskatchewan. Further selection within the few F(5:6) lines should be effective in pyramiding one or several of the minor genes into the working germplasm of lentil, resulting in a more durable and higher level of resistance.     

Molecular mapping and genetic analysis of a rice brown planthopper (Nilaparvata lugens Stål) resistance gene

The brown planthopper (BPH), Nilaparvata lugens St?l, is a serious insect pest of rice (Oryza saliva L.). We have determined the chromosomal location of a BPH resistance gene in rice using SSR and RFLP techniques. A rice line 'B14', derived from the wild rice Oryza latifolia, showed high resistance to BPH. For tagging the resistance gene in 'B14X', an F2 population and a recombinant inbred (RI) population from a cross between Taichung Native 1 and 'B14' were developed and evaluated for BPH resistance. The results showed that a single dominant gene controlled the resistance of 'B14' to BPH. Bulked segregant SSR analysis was employed for identification of DNA markers linked to the resistance gene. From the survey of 302 SSR primer pairs, three SSR (RM335, RM261, RM185) markers linked to the resistance gene were identified. The closest SSR marker RM261 was linked to the resistance gene at a distance of 1.8 cM. Regions surrounding the resistance gene and the SSR markers were examined with additional RFLP markers on chromosome 4 to define the location of the resistance gene. Linkage of RFLP markers C820, R288, C946 with the resistance gene further confirmed its location on the short arm of chromosome 4. Closely linked DNA markers will facilitate selection for resistant lines in breeding programs and provide the basis for map-based cloning of this resistance gene.     

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.     

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。     

Genetic analysis and gene mapping of a rice few-tillering mutant in early backcross populations (Oryza sativa L.)

A rice mutant, G069, characteristic of few tiller numbers, was found in anther culture progeny from the F1 hybrid between an indica-japonica cross, Gui630×02428. The mutant has another two major features: delayed tillering development and yellowing apex and margin on the mature leaves. As a donor parent, G069 was further backcrossed with the recurrent parent, 02428, for two turns to develop a BC2F2 population. Genetic analysis in the BC2F2 population showed that the traits of few-tillering and yellowing apex and margin on the mature leaves were controlled by one recessive gene. A pool of equally mixed genomic DNA, from few-tillering individual plants in BC2F2, was constructed to screen polymorphism with simple sequence repeat (SSR) markers in comparison with the 02428 genome. One SSR marker and three restriction fragment length polymorphism (RFLP) markers were found possibly linked with the recessive gene. By using these markers, the gene of few-tillering was mapped on chromosome 2 between RFLP marker C     

Generation and mapping of SCAR and CAPS markers linked to the seed coat color gene in Brassica napus using a genome-walking technique.

The yellow seed coat trait in No. 2127-17, a resynthesized purely yellow Brassica napus line, is controlled by a single partially dominant gene, Y. A double-haploid population derived from the F1 of No. 2127-17 x 'ZY821' was used to map the seed coat color phenotype. A combination of AFLP analysis and bulked segregant analysis identified 18 AFLP markers linked to the seed coat color trait. The 18 AFLP markers were mapped to a chromosomal region of 37.0 cM with an average of 2.0 cM between adjacent markers. Two markers, AFLP-K and AFLP-H, bracketed the Y locus in an interval of 1.0 cM, such that each was 0.5 cM away from the Y locus. Two other markers, AFLP-A and AFLP-B, co-segregated with the seed color gene. For ease of use in breeding programs, these 4 most tightly linked AFLP markers were converted into reliable PCR-based markers. SCAR-K, which was derived from AFLP-K, was assigned to linkage group 9 (N9) of a B. napus reference map consisting of 150 commonly used SSR (simple sequence repeat) markers. Furthermore, 2 SSR markers (Na14-E08 and Na10-B07) linked to SCAR-K on the reference map were reversely mapped to the linkage map constructed in this study, and also showed linkage to the Y locus. These linked markers would be useful for the transfer of the dominant allele Y from No. 2127-17 to elite cultivars using a marker-assisted selection strategy and would accelerate the cloning of the seed coat color gene.