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。     

粘类小麦雄性不育恢复基因的遗传分析及RAPD标记

利用RAPD分子标记对粘类小麦雄性不育系ms（Kots）-90-110的恢复系Rk5451的恢复基因进行了标记定位。选取具有高恢复力的恢复系康本材料Rk5451和Rk5253为父本与ms（Kots）-90-110杂交．F1代再与保持系90-110回交;以90-110／／ms（Kots）-90-110／Rk5451的BC1F1代分离群体为研究对象．利用分离群体分组分析法（Bulked Segregant Analysis．BSA）．以350个随机引物对Rk5451的主效恢复基因进行RAPD分析．筛选到27个可在亲本间扩增出多态性的引物．其中引物S120经多次重复能在亲本间及不育和可育池间扩增出稳定的多态性片段S120-1745。     

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.     

红莲型杂交稻(红莲2号)及其骨干亲本的RAPD分析与鉴定

利用RAPD技术,从248个随机寡核苷酸引物（10－mer）中筛出18个引物对红莲型杂交稻组合红莲2号及其亲本（T－07A、T－07B、YD6－05）,另6个红莲型胞质不育系的骨干恢复和汕优63及其亲本共14份水稻材料进行分析。共检测到173个多态性标记。聚类分析结果表明：不育系与保持系间因核背景相似,遗传差异很小;杂种（F1）的基因型更倾向于恢复系;恢复系与保持系间遗传距离的相对较大,但各恢复系之间的遗传距离较小。利用这些标记能有效地地区交组合中不育系,保持系、恢复系和杂种（F1）。     

大白菜细胞核复等位雄性不育基因定位

以大白菜不育材料"939A"为母本,携带恢复基因的材料YDQ56A为父本构建隐性雄性不育F1S4分离群体,利用混合分组分析法(BSA)对不育基因初定位;同时以"939A"为母本,携带保持基因的材料yellow sason为父本构建显性雄性不育F2分离群体,对不育基因进行精细定位。结果在F1S4群体中获得与不育基因连锁的标记2个,A08_1900和Br ID111035,与不育基因分别相距8.8c M和2.5c M,物理距离为804.1kb;F2群体中不育单株与可育单株分离比符合3∶1,不育基因表现为显性。通过标记验证,F2和F1S4两个群体定位结果一致,均位于A08染色体末端,通过新标记的筛选获得不育基因两侧紧密连锁的标记Br19470306和Br19675586,与不育基因分别相距1.6c M和2.4c M,物理距离205.28kb,其中包含58个基因。该结果为大白菜雄性不育系的利用以及转育奠定了基础。     

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。     

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.     

小麦“BS20×Fu3”DH群体SSR遗传图谱的构建及不育基因的QTL定位

以小麦光温敏核雄性不育系BS20×Fu3双单倍体(DH)群体的289个系为材料,从1112对SSR和EST-SSR引物中筛选出多态性引物243对,利用其中128个SSR和6个EST-SSR标记构建遗传连锁图谱,该图谱覆盖长度为2749.2 c M,分布在小麦的19个连锁群(除4D、6A),不同连锁群标记数为2~15个,长度在15.3~244.4 c M之间,平均长度为144.7 c M,标记之间平均遗传距离为17.4 c M。同时构建3个DNA池(包括恢复池、北京不育池和阜阳不育池),用分离群体分组分析法(BSA)对育性进行分析,筛选出的多态性引物为Wmc264、Wmc73、Xgwm350,分布在3A、5B、2A/7D染色体上。同时用混合线性复合区间作图法(MCIM)对育性进行QTL分析,当F7.5时,检测到6个主效QTL,用复合区间作图法(CIM)对育性进行QTL分析,当LOD值2.5时,共检测到13个主效QTL,两种方法检测到一致的QTL有3个,分别为1BL的Wmc365-cfa2129、2BS的Wmc602-Xgwm148和3AL的Wmc264a-cfa2262区间的QTL。综合BSA和QTL的结果,位于1BL、2BS和3AL上的小麦光温敏不育基因是真实的。     

节瓜果皮颜色相关基因的ISSR标记分析

本研究选用节瓜F2代分离群体作为研究材料,采用分离体分组混合(bulked segregation analysis,BSA)分析法,结合ISSR标记技术,分别构建节瓜的淡绿色果皮基因池和墨绿色果皮基因池并对100条ISSR引物进行筛选扩增,进而对与节瓜果皮颜色性状控制基因连锁的分子标记进行分析研究,最终得到了在两基因池间具有多态性的标记G855-6。通过F2代群体验证,最终确定了ISSR标记G855-6与节瓜墨绿色果皮控制基因连锁,其交换值为8.95%,遗传距离为9.04 c M。     

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     

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.     

Development of PCR-based markers linked to dominant genes for male-fertility restoration in Pampa CMS of rye (<Emphasis Type="Italic">Secale cereale</Emphasis> L.)

Cytoplasmatic male sterility (CMS) is the basis for commercial hybrid seed production of rye. Nuclear restorer genes are indispensable for a complete restoration of fertility of the CMS lines. The drawbacks of current European restorer lines require the utilisation of new genetic resources that have been recently detected in an Iranian primitive rye population (IRAN IX) and an Argentinean landrace (Pico Gentario). The introgression of these effective restorer genes (Rfp1 and Rfp2, respectively) into breeding material can be facilitated by marker-assisted selection. Using two F(2) populations based on crosses between the non-restorer inbred line Lo6 and the restorer IRAN IX, as well as Pico Gentario, RAPDs and AFLPs were screened and led to a closely linked marker set for each of these genes. The conversion of the closest markers into fragment-specific sequence-characterised amplified region (SCAR) markers resulted in flanking ranges of 2.9 cM (Rfp1) and 5.2 cM (Rfp2). The application of these markers in backcross programmes is discussed.     

Identification and mapping of Rf-I an inhibitor of the Rf5 restorer gene for Cms-C in maize (Zea mays L.)

The restoration of the C-type cytoplasmic male sterility (Cms) has been a common agriculture practice in the production of hybrid seed for many years. In this study, a series of crosses between select sterile and restorer lines, as well as a backcross population of (Cms-C77 × 6233) × 6233, were used to investigate the restoration of C-type Cms. Our results demonstrated that there was an inhibitor of the Rf5 restorer gene. This inhibitor gene, Rf-I, maps to chromosome 7 and is tightly linked with SSR markers, umc2326 and umc2327, at a genetic distance 4.7 and 3.4 cM, respectively. After analyzing our data combined with previous studies, we propose that the restoration of C-type Cms has two dominant genes, Rf4 and Rf5. Rf4 has the ability to restore all genotypes of Cms-C lines; however, there exists an inhibitor for the other restorer gene, Rf5; thus, it can restore only those genotypes of Cms-C lines lacking the Rf-I inhibitor.     

Molecular mapping of genes for opposite leafing in maize using simple-sequence repeat markers

Maize with opposite phyllotaxy (OP) and also initiating ears in opposite pairs is an aberrant mutant and also precious material for maize breeding and plant evolution studies. Mapping and identifying the markers closely linked to genes for the OP trait are essential for cloning the gene and marker-assisted selection in breeding. We established H14D, a near-isogenic line of the OP trait with H53 genetic background. We found that the OP trait is regulated by two independent dominant genes with mutually complementary relations, named Opp-1 and Opp-2. Screening of seven simple-sequence repeat (SSR) markers among the 105 pairs of SSR primers showed polymorphism between the inbred lines H14D and H53. The polymorphic SSR markers were then used to determine linkage with the trait in an F(2) population with 441 progeny, suggesting that SSR marker umc2094 in the Bin2.01 region is linked with Opp-1 at 6.7 cM, and bnlg1831 in Bin2.06 is linked with Opp-2 at 6.1 cM. Further investigation showed that bnlg1092 and umc1028 are linked to Opp-1 and Opp-2 genes, with genetic distances of 12.2 and 1.9 cM. It was also found that the four SSR markers flank the two OP genes, respectively. These results will be useful for marker-assisted selection breeding of OP maize and will also strengthen the basis for cloning of the opposite leafing gene.     

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。     

苹果Co基因的SSR标记定位（简报）

Columnar apple is an important genetic resource for tree form breeding of apple. In this study, 106 individuals of the F1 population derived from 'Spur Fuji' (coco)x 'Telamon'(Coco) were used as plant materials for screening SSR markers linked to gene. By bulked segregating analysis (BSA), eight SSR markers from the tenth linkage group of apple genome were tested. Finally, three of them, COL, CH02a10 and CH03d11, were identified to be SSR markers of Co gene. Linkage analysis showed that the genetic distance of COL, CH02a10 and CH03d11 to Co locus was 15.3cM, 22.2cM and 3.9 cM, respectively. On the linkage map of these markers, Co gene was located between COL and CH03d11.