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.     

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。     

黄瓜霜霉病抗病基因的RAPD及SCAR标记

以感霜霉病黄瓜L18-10-2和抗霜霉病黄瓜129为亲本构建F2代分离群体,以F3代植株霜霉病抗性鉴定表示F2代各单株抗病性并得以区分各单株杂合或纯合感病性,采用RAPD技术和转SCAR的方法筛选黄瓜抗霜霉病基因分子标记.结果显示,在318条RAPD引物中有18条引物表现出两亲本间多态性,其中引物P18的SB-SP18561扩增片段与霜霉病抗病基因之间紧密连锁,根据交换率和Kosambi函数公式计算其遗传距离为7.85 cM.回收SBSP18561片段并克隆和测序,其准确长度为561 bp.将该RAPD标记转换为SCAR标记,长度为494 bp,命名为SSBSP18494.     

K型小麦细胞质雄性不育系育性恢复基因的RAPD和ISSR标记

利用RAPD和ISSR分子标记对K型小麦(Triticum aestivum L.)雄性不育恢复系LK783的主效恢复基因进行了标记定位.以K冀5418A//911289/LK783三交F1分离群体的极端不育株和极端可育株分别建立保持池和恢复池,利用418个RAPD和33个ISSR引物对两池间的多态性进行了研究.分析表明RAPD引物OPK18和ISSR引物UBC-845在两池间扩增出稳定的多态性差异,在分离群体上的验证结果表明LK783的育性恢复基因与两个引物的扩增位点有连锁关系,在染色体上位于两个引物的扩增位点之间,与OPK18450的遗传距离为(15.07±6.28)cM (centiMorgan),与UBC-845800的遗传距离为(8.20±4.85)cM.这两个引物可应用于对育性恢复基因的标记辅助选择.最后,利用中国春缺体-四体系和双端体系进一步将UBC-845800定位于1BS, 表明LK783的育性恢复基因也位于1BS.     

K型小麦细胞质雄性不育系育性恢复基因的RAPD和ISSR标记(英文)

利用RAPD和ISSR分子标记对K型小麦 (TriticumaestivumL .)雄性不育恢复系LK783的主效恢复基因进行了标记定位。以K冀 5 418A/ / 9112 89/LK783三交F1分离群体的极端不育株和极端可育株分别建立保持池和恢复池 ,利用 418个RAPD和 33个ISSR引物对两池间的多态性进行了研究。分析表明RAPD引物OPK18和ISSR引物UBC_845在两池间扩增出稳定的多态性差异 ,在分离群体上的验证结果表明LK783的育性恢复基因与两个引物的扩增位点有连锁关系 ,在染色体上位于两个引物的扩增位点之间 ,与OPK184 50 的遗传距离为 (15 .0 7± 6 .2 8)cM (cen tiMorgan) ,与UBC_845 80 0 的遗传距离为 (8.2 0± 4.85 )cM。这两个引物可应用于对育性恢复基因的标记辅助选择。最后 ,利用中国春缺体_四体系和双端体系进一步将UBC_845 80 0 定位于 1BS ,表明LK783的育性恢复基因也位于 1BS。     

油菜单显性核雄性不育基因的分子标记

以陕西省杂交油菜研究中心选育的单显性核不育油菜分离群体为材料,利用集群分离法（BSA）对该油菜单显性核不育基因进行了RAPD分析。在随机选取的300个10碱基随机引物中,引物S243（5′CTATGCCGAC3′）在可育集团与不育集团间扩增出特异而可重复的1．5kb的多态性片段OPU-031500,而在细胞质雄性不育和其它核不育类型油菜中均未扩增出上述特异性片段,从而确证此RAPD标记OPU-031500。片段是与甘蓝型油菜单显性核不育基因连锁的。将该多态性片段克隆并测序,发现其序列与拟南芥的一段DNA序列高度同源。根据同源序列及测序结果设计两对特异引物（P1／P2和P3／P4）,引物P3／P4在可育系中可扩增到约1．5kb的单一特异片断,而在不育系中无带,从而将RAPD标记转化为稳定可靠的SCAR标记。     

三例小麦细胞质雄性不育系线粒体DNA的扩增片段长度多态性分析

细胞质雄性不育是小麦杂种优势利用的重要途径,为了鉴定3例小麦雄性不育系的细胞质类型,对其线粒体DNA(mtDNA)进行扩增片段长度多态性(Amplified fragment length polymorphism,AFLP)分析。文中利用差速离心法和不连续蔗糖密度梯度超速离心法提取纯化小麦线粒体。结果表明:通过该提取方法获得的mtDNA,其质量和纯度能够满足PCR反应和遗传学分析。在64对选扩引物中,筛选到了4对特异性引物,其中引物E1/M7在ms(Kots)-90-110不育系扩增出3条特异条带;引物E4/M2在ms(Ven)-90-110不育系扩增出2条特异条带;引物E7/M6在ms(S)-90-110不育系中扩增出2条特异条带;引物E6/M4在ms(Kots)-90-110不育系中扩增出2条特异条带。这些特异引物可以用来作为鉴定具有粘果山羊草Aegilops kotschyi、偏凸山羊草Ae.ventricosa、斯卑尔脱小麦Triticum spelta 3类不育细胞质型小麦雄性不育系的细胞质分子标记,为研究小麦细胞质雄性不育机理奠定了分子基础。     

大豆曲茎性状的遗传分析和RAPD标记研究

曲茎遗传材料NG94-156与遗传背景不同的3个正常茎品种杂交,获得1个F2群体和2个重组自交家系(F7:8)。后代分离分析的结果表明,NG94-156的曲茎性状受两对隐性重叠基因控制。利用4个亲本和1个重组自交家系筛选260个RAPD随机引物,其中有1个引物S-506扩增出的多态性条带有较好的重复性。经过连锁分析,RAPD标记S-5061600与控制曲茎的基因的遗传距离为6.94 cM。     

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.     

细胞质雄性不育辣椒育性恢复基因特异分子标记的筛选

利用集团分离分析法(Bulked segregant analysis BSA),以辣椒细胞质雄性不育系BU-12、恢复系RF-12为材料共筛选了336条RAPD引物,其中引物S418在恢复系中呈现特异性扩增,得到一条约3000bp的特异片段。回扩得到两条片段,测序表明大小为1515bp,1162bp。荧光原位杂交证实1515bp片段为恢复系特有,命名为S418_(1515)。序列分析表明S418_(1515)为一新发现的序列,Blastn序列比对同源性小于40%,tBlastx比对发现该序列与水稻2、4、7、10号染色体的几个BAC克隆上的序列高度同源。推测可能与其具有相似的编码功能,为进一步从分子水平研究辣椒育性恢复打下了坚实的基础。根据测序结果设计特异引物,将S418_(1515)转化成特异PCR标记,证明能用于候选材料的初筛。     

细胞质雄性不育辣椒育性恢复基因特异分子标记的筛选

利用集团分离分析法(Bulked segregant analysis BSA),以辣椒细胞质雄性不育系BU-12、恢复系RF-12为材料共筛选了336条RAPD引物,其中引物S418在恢复系中呈现特异性扩增,得到一条约3000bp的特异片段。回扩得到两条片段,测序表明大小为1515bp,1162bp。荧光原位杂交证实1515bp片段为恢复系特有,命名为S4181515。序列分析表明S4181515为一新发现的序列,Blastn序列比对同源性小于40％,tBlastx比对发现该序列与水稻2、4、7、10号染色体的几个BAC克隆上的序列高度同源。推测可能与其具有相似的编码功能,为进一步从分子水平研究辣椒育性恢复打下了坚实的基础。根据测序结果设计特异引物,将S4181515转化成特异PCR标记,证明能用于候选材料的初筛。     

大白菜杂交种'冠春'杂交率的RAPD分析

从春大白菜品种‘冠春’及其亲本中提取基因组DNA,用320个随机引物进行RAPD扩增,从中筛选出5 个可将亲本和子代区分的引物S4、S47、S73、S134和S194。S4产生父本特征带S4-370;S47和S134产生母本特征带S47-700 和S134-1200;S73和S494产生亲本互补的特征带S73-660、S73-730和S494-400、S494-1770,上述谱带均在子代中出现。以这5个引物产生的特征谱带建立杂交种‘冠春’及其亲本的RAPD特异指纹。通过对134个‘冠春’的种子进行纯度鉴定,结果表明2个父本和4个母本与大田检测结果完全一致。进一步验证了4种鉴定大白菜杂交种方法的可行性。     

陕油8号种子纯度的RAPD鉴定研究

从杂交油菜“陕油8号”及其亲本中提取基因组DNA,用100个RAPD随机引物进行扩增,从中筛选出3个可将亲本和子代区分的引物BA208、BA1090、BA497。BA208产生亲本互补的特征带BA208-1050bp、BA2081250bp;BA1090产生母本特征带BA1090-700bp,BA497产生父本特征带BA497-870bp,上述谱带均在子代中出现。以BA208产生的特征谱带作为分子标记对杂交油菜种子纯度鉴定得到了一致的结果,并与大田纯度检测结果一致。BA497可将“陕油8号”与当地4个主栽品种有效区分。此外,还对双引物共同鉴定杂交种子纯度问题进行了初步探讨。     

Identification of RAPD markers linked to a fertility restorer gene for theOgura radish cytoplasmic male sterility of rapeseed (Brassica napus L.)

Bulked segregant analysis was employed to identify random amplified polymorphic DNA (RAPD) markers linked to the restorer gene (Rfo) used in theOgura radish cytoplasmic male sterility of rapeseed. A total of 138 arbitrary 10-mer oligonucleotide primers were screened on the DNA of three pairs of bulks, each bulk corresponding to homozygous restored and male sterile plants of three segregating populations. Six primers produced repeatable polymorphisms between paired bulks. DNA from individual plants of each bulk was then used as a template for amplification with these six primers. DNA polymorphisms generated by four of these primers were found to be completely linked to the restorer gene with the polymorphic DNA fragments being associated either with the fertility restorer allele or with the sterility maintainer allele. Pairwise cross-hybridization demonstrated that the four polymorphic DNA fragments did not share any homology. Southern hybridization of labelled RAPD fragments on digested genomic DNA from the same three pairs of bulks revealed fragments specific to either the male sterile bulks or to the restored bulks and a few fragments common to all bulks, indicating that the amplified sequences are low copy. The four RAPD fragments that were completely linked to the restorer locus have been cloned and sequenced to develop sequence characterized amplified regions (SCARs). This will facilitate the construction of restorer lines used in breeding programs and is the first step towards map-based cloning of the fertility restorer allele.     

Inheritance of seed colour and identification of RAPD and AFLP markers linked to the seed colour gene in rapeseed (Brassica napus L.)

In China Polima cytoplasmic male sterility (cms) is currently the most important hybrid system used for the breeding of hybrids. In an effort to develop yellow-seeded Polima cms restorer lines, we used yellow-seeded, doubled haploid (DH) line No.2127-17 as the gene source in crosses with two elite black-seeded Polima cms R lines, Hui5148-2 and 99Yu42, which originated from our breeding programme. The inheritance of seed colour was investigated in the F₂, BC₁ and F₁-derived DH progenies of the two crosses. Seed colour was found to be under the control of the maternal genotype and the yellow seed trait to be partially dominant over the black seed trait. Segregation analysis revealed a single gene locus for the partial dominance of yellow seed colour. Of 810 randomly amplified polymorphic DNA (RAPD) primers, 240 (29.6%) revealed polymorphisms between the parents. Of the 240 RAPD primers and 512 amplified fragment length polymorphism (AFLP) primer pairs, four RAPDs and 16 AFLP pairs showed polymorphisms between the bulks, with two RAPD and eight AFLP markers being identified in the vicinity of the seed-coat colour gene locus using a DH progeny population—derived from the cross Hui5148-2×No.2127-17—of 127 individuals in combination with the bulked segregant analysis strategy. Seven of these latter ten markers were linked to the allele for yellow seed, whereas the other three were linked to the allele for black seed. The seed-coat colour gene locus was bracketed by two tightly linked markers, EA02MG08 (2.4 cM) and S1129 (3.9 cM). The partial dominance and single gene control of the yellow seed-coat colour trait together with the available molecular markers will greatly facilitate the future breeding of yellow-seeded hybrid varieties.     

Molecular mapping of the <Emphasis Type="Italic">Rf1</Emphasis> gene restoring pollen fertility in PET1-based F<Subscript>1</Subscript> hybrids in sunflower (<Emphasis Type="Italic">Helianthus annuus</Emphasis> L.)

Up to now a single cytoplasmic male sterility (CMS) source, PET1, is used worldwide for hybrid breeding in sunflower. Introgression of the restorer gene Rf1, responsible for fertility restoration, into new breeding material requires tightly linked markers to perform an efficient marker-assisted selection. A survey of 520 decamer primers by bulked segregant analyses identified five RAPD markers linked to the restorer gene Rf1. In a F(2) population of 183 individuals one of the RAPD markers, OPK13_454, mapped 0.8 cM from Rf1, followed by OPY10_740 with 2 cM. Bulked segregant analyses using 48 AFLP primer combinations identified 17 polymorphisms, which could be mapped in the same linkage group as Rf1. E33M61_136, and E41M48_113 were mapped 0.3 cM and 1.6 cM from the gene, respectively. Conversion of E41M48_113 into a sequence-specific marker resulted in a monomorphic pattern. However, two of the RAPD markers, OPK13_454 and OPY10_740, were successfully converted into SCAR markers, HRG01 and HRG02, which are now available for marker-assisted selection. To investigate the utility of these SCAR markers in other cross-combinations they were tested in a set of 20 lines. Comparison of the patterns of 11 restorer and nine maintainer lines of PET1 demonstrated that the markers OPK13_454/HRG01 and HRG02 were absent in all maintainer lines but present in all restorer lines, apart from the high oleic line RHA348 and the dwarf line Gio55. In addition, restorer lines developed from the interspecific hybrids Helianthus annuus x Helianthus mollis and H. annuus x Helianthus rigidus gave the same characteristic amplification products.     

水稻抗褐飞虱基因SCAR标记的获得

采用282个随机引物对药用野生稻1665和栽培稻桂99远缘杂交的抗褐飞虱近等基因系B3F4分离群体的不抗池DNA和抗池DNA进行了特异性RAPD标记筛选,从中筛选到一个具有明显的特异性扩增带谱的RAPD标记S1159,序列分析表明,S1159序列长度为1408bp,与基因库中已报道的水稻第四号染色体的BAC克隆(编号OSJNBa0070O11)序列(67114-69100)有51.86%的同源性。为了提高所找到的RAPD标记S1159在应用上的稳定性,将RAPD标记转化为SCAR标记检测近等基因系群体,结果表明与RAPD标记结果一致,说明该研究得到的RAPD标记具有较好的稳定性和重复性,为进一步的研究打下了良好的基础。     

Marker-assisted selection of restored male-fertile Brassica napus plants using a set of dominant RAPD markers

Bulked segregant analysis was used to identify RAPD markers in oilseed rape (Brassica napus L.) that were linked to a male fertility restorer gene for Ogura cytoplasmic male sterility. After screening for polymorphisms using 960 primers, 14 RAPD markers were mapped to a 25 cM region including the restorer locus, a mapping population of 242 F₂ individuals being employed. The map was used to select 11 markers that were investigated for polymorphisms between the restorer donor line and 46 recipient lines. A set of four RAPD markers, one in coupling phase with the restorer allele and three with the non-restorer allele, which were informative in all 46 combinations, were used in marker assisted selection of plants homozygous for the restorer allele. A total of 906 homozygous restored plants were found among the 4605 BC₁F₂ plants analysed. Phenotypic data of a subset of the classified plants was compared with the RAPD data and the expected number of recombinants was calculated from the map data. A close correspondence between the expected and observed numbers of plants with a deviating phenotype was found. Thus, use of a set of dominant RAPD markers provides a way obtaining reliable data for marker-assisted selection.