应用SSR分子标记分析小麦品种(系)的遗传重组

为了解小麦品种形成中亲本基因组的遗传重组和遗传保留区段的分布特点,对周麦18和百农AK58及其衍生品系共23个材料进行了全基因组SSR扫描分析。遗传重组分析表明,单交组合的平均重组数(12.3)低于回交组合(13.9);染色体4A、5A、7A、1B、3B、4B、7B、1D、2D、3D、5D、6D和7D重组发生较多,其余染色体重组相对较少,染色体的中间区段与远端区段重组数相当,分别为6.1和6.0。子代间基因组比较发现,一些染色体区段成为重组的多发区,如5D的gwm358–wmc357、6D的cfd49–barc196、7A的wmc158–barc23和7B的gwm274–gwm146区段,分别有35、19、15和14次重组。分析亲本传递给子代的染色体区段,发现子代继承亲本的遗传区段在14~29个,每个区段涉及2~8个多态性位点,大的遗传区段主要分布于4A、5A、5B、5D和7D染色体。以上基因组区域的关联性状是进一步研究的重点。     

软质小麦溶剂保持力关联分析

溶剂保持力(SRC)是软质小麦鉴定评价的重要指标。为获得与SRC关联的分子标记,提高育种效率,对不同硬度类型的176份品种的乳酸SRC、碳酸钠SRC、蔗糖SRC和水SRC进行SSR标记检测,并结合其在江苏里下河地区连续3个生长季的4种SRC表型数据,利用MLM模型进行了关联分析。以236对SSR引物共检测出1340个等位变异,平均每个位点5.5个等位变异,平均PIC值为0.4663。共检测到28个关联位点(P0.005),单个位点可解释3.19%~21.84%的表型变异;与乳酸SRC、水SRC、蔗糖SRC和碳酸钠SRC相关联的位点分别为13、7、6和2个;与水SRC关联的gwm642-1D在3年中均被检测到。在这些关联位点上发现有利等位变异,其中降低水SRC的等位变异有gwm642-A186、gwm642-A188和gwm337-A178,降低蔗糖SRC的等位变异有gwm337-A178和gwm337-A186,降低碳酸钠SRC的等位变异有cfa2257-A129等。这些结果为利用分子标记进行SRC辅助选择提供了重要信息。     

从野生二粒小麦导入普通小麦的抗白粉病基因MlWE18分子标记定位

野生二粒小麦(Triticum turgidumvar. dicoccoides)是小麦抗白粉病遗传改良的重要基因资源。利用野生二粒小麦WE18与普通小麦品种(系)连续多次杂交和自交,育成对白粉病菌生理小种E09高度抵抗的小麦新品系3D249(京双27//燕大1817/WE18/3/温麦4,F₇)。利用高感白粉病品系薛早和3D249组配杂交组合,获得杂种F₁代、F₂分离群体和F₃代家系,进行苗期白粉病抗性鉴定和遗传分析。结果表明,小麦品系3D249对E09小种的抗性受显性单基因控制,暂命名该基因为MlWE18。利用集群分离分析法(BSA)和分子标记分析,发现4个简单重复序列(SSR)标记(Xwmc525、Xwmc273、Xcfa2040和Xcfa2240)、1个EST-STS标记(Xmag1759)和1个EST-STS序列标记(XE13-2)与抗白粉病基因MlWE18连锁,在遗传连锁图谱上的顺序为Xwmc525–Xcfa2040–Xwmc273–XE13-2–Xmag1759–MlWE18–Xcfa2240。SSR标记的染色体缺失系物理定位结果表明,抗白粉病基因MlWE18位于小麦7A染色体长臂末端的Bin 7AL 16–0.85–1.00。与已知定位于该染色体区域的Pm基因遗传连锁图谱比较表明,MlWE18与抗白粉病基因Pm1、MlIW72、PmU、Mlm2033和Mlm80均位于7AL相同染色体区段。     

Molecular mapping of a stripe rust resistance gene in wheat cultivar Wuhan 2

Stripe rust (or yellow rust), caused by Puccinia striiformis f. sp. tritici, is one of the most destructive diseases of wheat worldwide. Growing resistant cultivars is the best approach to control the disease. To identify and map genes for stripe rust resistance in wheat cultivar ‘Wuhan 2', an F₂ population was developed from a cross between the cultivar and susceptible cultivar Mingxian 169. The parents, 179 F₂ plants and their derived F_2:3 lines were evaluated for responses to Chinese races CYR30 and CYR31 of the pathogen in a greenhouse. A recessive gene for resistance was identified. DNA bulked segregant analysis was applied and resistance gene analog polymorphism (RGAP) and simple sequence repeat (SSR) techniques were used to identify molecular markers linked to the resistance gene. A genetic map consisting of five RGAP and six SSR markers was constructed. The recessive gene, designated Yrwh2, was located on the short arm of chromosome 3B and flanked by SSR markers Xwmc540 and Xgwm566 at 5.9 and 10.0 cM, respectively. The chromosomal location of the resistance gene and its close marker suggest that the locus is different from previously reported stripe rust resistance genes Yr30, QYr.ucw-3BS, Yrns-B1, YrRub and QYrex.wgp-3BL previously mapped to chromosome 3B. Yrwh2 and its closely linked markers are potentially useful for developing stripe rust resistance wheat cultivars if used in combination with other genes.     

SSR and STS markers for wheat stripe rust resistance gene <Emphasis Type="Italic">Yr26</Emphasis>

Stripe (yellow) rust, caused by Puccinia striiformis f. sp. tritici (Pst), is one of the most devastating wheat diseases worldwide. Triticum aestivum-Haynaldia villosa 6VS/6AL translocation lines carrying the Yr26 gene on chromosome 1B, are resistant to most races of Pst used in virulence tests. In order to better utilize Yr26 for wheat improvement, we attempted to screen SSR and EST-based STS markers closely linked with Yr26. A total of 500 F₂ plants and the F_2:3 progenies derived from a cross between 92R137 and susceptible cultivar Yangmai 5 were inoculated with race CYR32. The analysis confirmed that stripe rust resistance was controlled by a single dominant gene, Yr26. Among 35 pairs of genomic SSR markers and 81 pairs of STS markers derived from EST sequences located on chromosome 1B, Yr26 was flanked by 5 SSR and 7 STS markers. The markers were mapped in deletion bins using CS aneuploid and deletion lines. The closest flanking marker loci, Xwe173 and Xbarc181, mapped in 1BL and the genetic distances from Yr26 were 1.4 cM and 6.7 cM, respectively. Some of these markers were previously reported on 1BS. Eight common wheat cultivars and lines developed from the T. aestivum-H. villosa 6VS/6AL translocation lines by different research groups were tested for presence of the markers. Five lines with Yr26 carried the flanking markers whereas three lines without Yr26 did not. The results indicated that the flanking markers should be useful in marker-assisted selection for incorporating Yr26 into wheat cultivars.     

小麦茎秆实心度对茎秆强度的影响及相关性状QTL分析

在QTL水平上研究茎秆实心度与强度的遗传关系及实心度对茎秆强度的影响,为小麦抗倒伏育种提供依据。利用普通小麦宁麦18与实秆小麦种质"武云实秆"的F2群体和F2:3家系,对小麦茎秆强度、实心度及影响实心度的相关性状包括厚径比、壁厚、茎粗和髓腔直径进行了相关分析,并对茎秆强度相关性状QTL进行分子标记定位及遗传效应分析。结果表明小麦茎秆强度与厚径比、壁厚均呈极显著正相关,与髓腔直径呈极显著负相关。基于复合区间作图法进行QTL定位,检测到与茎秆强度、厚径比、壁厚、茎粗和髓腔直径相关QTL共23个,分布在1B、3B、4A、4B、5A上,表型贡献率3.5%~44.0%。在染色体3B、4A和5A上的标记区间gwm547–gwm247、wmc718–wmc468和gwm156–gwm443均检测到贡献率很高的茎秆实心度相关QTL,说明在这3条染色体上可能存在控制茎秆强度的主效QTL。用普通小麦宁麦13(N13)×武云实秆的24个F7家系检验分子标记gwm247的可靠性表明利用标记gwm247选育茎秆实心度优于宁麦13的概率较大。研究结果为进一步精细定位相关主效QTL以及分子标记辅助改良小麦茎秆强度奠定了基础。     

硬粒小麦-粗山羊草人工合成小麦CI108抗条锈病新基因的鉴定、基因推导与分子标记定位

利用我国流行的小麦条锈菌生理小种CY28、CY29、CY30、CY31、CY32和水源11致病型4对102份硬粒小麦-粗山羊草人工合成小麦材料进行抗病鉴定,其中CI108（组合为GAN/Aegilops squarrosa 201）对上述6个流行生理小种均表现免疫。利用CY31对杂交组合CI108/铭贤169正交、反交的F₁材料以及F₂代群体进行抗病鉴定,结果表明其抗性受细胞核显性单基因控制。基因推导表明,CI108对30个条锈菌生理小种均表现抗性,其抗谱与23份已知抗条锈病基因品种（系）不同,与K733（含有Yr24）和洛夫林13（含Yr9+未知基因）相似,但CI108与洛夫林13、K733对多个条锈菌生理小种的抗性程度不同,洛夫林13、K733与CI108系谱不同,且缺乏CI108特异的SSR标记Xgwm456的抗病特异带。所以,CI108中抗条锈基因应该是不同于其他基因的抗条锈病新基因,暂命名为YrC108。进一步利用CI108/铭贤169的F₂群体、抗感分离分析池（BSA）筛选YrC108的SSR分子标记,找到了3个紧密连锁的标记,其中Xgwm456和Wmc419位于YrC108的一侧,与YrC108间遗传距离分别为0.6 cM和1.8 cM,Wmc413位于YrC108的另一侧,遗传距离为0.6 cM。本研究为小麦抗条锈病育种提供了高抗、广谱的新抗源和进行高效检测的分子标记。     

野生二粒小麦导入普通小麦的抗白粉病基因MlWE29分子标记定位

小麦白粉病是严重影响小麦生产的重要病害之一,培育和应用抗病品种是有效控制和减少病害的最经济有效的方法。野生二粒小麦是硬粒小麦和普通小麦的四倍体野生祖先种,是小麦抗病性遗传改良的重要基因资源。本研究利用来自以色列的野生二粒小麦WE29与普通小麦杂交,再用普通小麦连续回交和自交,育成高抗白粉病(Blumeria graminis f. sp. tritici)小麦新品系3D258(系谱为燕大1817/WE29//5*87-1, BC₄F₆)。将3D258和高感小麦白粉病的普通小麦品种薛早配制杂交组合,对其F₁、F₂代分离群体和F₃代家系进行白粉病抗性鉴定和遗传分析。结果表明3D258携带抗白粉病显性单基因,暂命名为MlWE29。利用集群分离分析法(BSA)和分子标记分析,发现6个SSR标记(Xgwm335、Xgwm213、Xgwm639、Xwmc415、Xwmc289和Xwmc75)和5个EST-STS标记(BE494426、BE442763、CD452476、BE445282和BE407068)与抗白粉病基因MlWE29连锁。利用中国春缺体-四体系、双端体系和缺失系将抗白粉病基因MlWE29标记物理定位于5BL染色体的0.59–0.79区域。这一普通小麦抗白粉病种质资源的创制及其连锁分子标记的建立为小麦抗病基因分子标记辅助选择、基因积聚和分子育种提供了新的物质基础。     

野生二粒小麦导入普通小麦的抗白粉病基因MlWE29分子标记定位

小麦白粉病是严重影响小麦生产的重要病害之一,培育和应用抗病品种是有效控制和减少病害的最经济有效的方法。野生二粒小麦是硬粒小麦和普通小麦的四倍体野生祖先种,是小麦抗病性遗传改良的重要基因资源。本研究利用来自以色列的野生二粒小麦WE29与普通小麦杂交,再用普通小麦连续回交和自交,育成高抗白粉病(Blumeria graminis f. sp. tritici)小麦新品系3D258(系谱为燕大1817/WE29//5*87-1, BC₄F₆)。将3D258和高感小麦白粉病的普通小麦品种薛早配制杂交组合,对其F₁、F₂代分离群体和F₃代家系进行白粉病抗性鉴定和遗传分析。结果表明3D258携带抗白粉病显性单基因,暂命名为MlWE29。利用集群分离分析法(BSA)和分子标记分析,发现6个SSR标记(Xgwm335、Xgwm213、Xgwm639、Xwmc415、Xwmc289和Xwmc75)和5个EST-STS标记(BE494426、BE442763、CD452476、BE445282和BE407068)与抗白粉病基因MlWE29连锁。利用中国春缺体-四体系、双端体系和缺失系将抗白粉病基因MlWE29标记物理定位于5BL染色体的0.59–0.79区域。这一普通小麦抗白粉病种质资源的创制及其连锁分子标记的建立为小麦抗病基因分子标记辅助选择、基因积聚和分子育种提供了新的物质基础。     

黄淮麦区小麦品种(系)产量性状与分子标记的关联分析

为了获得与小麦产量性状关联的分子标记,筛选相关标记的等位变异,以128份黄淮麦区小麦品种(系)为材料,在4个环境下鉴定产量性状,并选用在小麦全基因组21条染色体上的64个SSR标记、27个EST-SSR标记和47个功能标记检测所有材料的基因型。91个SSR和EST-SSR标记共检测到315个等位变异,单个引物检测到2~7个等位变异,平均3.5个;47个功能标记共检测到107个等位变异,单个引物检测到2~5个等位变异,平均2.3个。关联分析表明,49个位点与4个环境的产量性状及其均值显著关联(P≤0.005),其中38个位点在2个或以上环境或均值下被重复验证,16个位点与2个或以上性状相关联。对相对稳定的等位变异作进一步分析,发掘了一批与产量性状相关的优异等位变异,如降低株高的等位变异Ax2*-null和UMN19*-A362,增加穗长的等位变异barc21-A220,增加可育小穗数的等位变异gpw2111-A156,增加总小穗数的等位变异swes65-A120,增加穗数的等位变异VRN-A1*-A1068,增加穗粒数的等位变异cfd5-A215和增加千粒重的等位变异wmc626-A170。研究结果对利用分子标记辅助选择进行小麦产量性状的遗传改良具有一定的指导意义。     

中国小麦LB0288中抗叶锈病基因的鉴定

明确中国小麦LB0288中所含的抗叶锈病基因,找到与其紧密连锁的DNA分子标记。将小麦LB0288和感病小麦品种Thatcher杂交,获得F1、F2代群体,用叶锈菌小FHTT分别对双亲及其杂交后代进行叶锈鉴定并进行标记分析。抗性鉴定结果表明F2代群体时呈现一对显性基因的抗感分离比例,经过亲本和抗感池间标记筛选以及F2代群体的标记检测,位于5DL的SSR标记barc144与抗病基因连锁,遗传距离为5.3 cM,同时Lr1的STS标记与之共分离,根据该基因的抗性特点和染色体位置推断为Lr1。此实验通过抗性鉴定、遗传分析和分子标记等手段确定LB0288中含有小麦抗叶锈病基因Lr1。     

Characterization and mapping of novel chlorophyll deficient mutant genes in durum wheat

The yellow-green leaf mutant has a non-lethal chlorophyll-deficient mutation that can be exploited in photosynthesis and plant development research. A novel yellow-green mutant derived from Triticum durum var. Cappelli displays a yellow-green leaf color from the seedling stage to the mature stage. Examination of the mutant chloroplasts with transmission electron microscopy revealed that the shape of chloroplast changed, grana stacks in the stroma were highly variable in size and disorganized. The pigment content, including chlorophyll a, chlorophyll b, total chlorophyll and carotene, was decreased in the mutant. In contrast, the chla/chlb ratio of the mutants was increased in comparison with the normal green leaves. We also found a reduction in the photosynthetic rate, fluorescence kinetic parameters and yield-related agronomic traits of the mutant. A genetic analysis revealed that two nuclear recessive genes controlled the expression of this trait. The genes were designated ygld1 and ygld2. Two molecular markers co-segregated with these genes. ygld 1 co-segregated with the SSR marker wmc110 on chromosome 5AL and ygld 2 co-segregated with the SSR marker wmc28 on chromosome 5BL. These results will contribute to the gene cloning and the understanding of the mechanisms underlying chlorophyll metabolism and chloroplast development in wheat.     

Identification and confirmation of quantitative trait loci for stachyose content in soybean seed

Stachyose is an unfavorable sugar in soybean meal that causes flatulence for non‐ruminant animals. Understanding the genetic control of stachyose in soybean will facilitate the modification of stachyose content at the molecular level. The objective of this study was to identify quantitative trait loci (QTL) associated with seed stachyose content using simple sequence repeat (SSR) and single nucleotide polymorphism (SNP) markers. A normal stachyose cultivar, ‘Osage’, was crossed with a low stachyose line, V99‐5089, to develop a QTL mapping population. Two parents were screened with 33 SSR and 37 SNP markers randomly distributed on chromosome 10, and 20 SSR and 19 SNP markers surrounding a previously reported stachyose QTL region on chromosome 11. Of these, 5 SSR and 16 SNP markers were used to screen the F_3:4 lines derived from ‘Osage’ x V99‐5089. Seed samples from F_3:5 and F_3:6 lines were analyzed for stachyose content using high‐performance liquid chromatography (HPLC). Composite interval mapping analysis indicated that two stachyose QTL were mapped to chromosome 10 and 11, explaining 11% and 79% of phenotypic variation for stachyose content, respectively. The SSR/SNP markers linked to stachyose QTL could be used in breeding soybean lines with desired stachyose contents. Chi‐square tests further indicated that these two QTL probably represent two independent genes for stachyose content. Therefore, a major QTL was confirmed on chromosome 11 and a novel QTL was found on chromosome 10 for stachyose content.     

Genetic analysis and identification of DNA markers linked to a novel Phytophthora sojae resistance gene in the Japanese soybean cultivar Waseshiroge

The Glycine max (L.) Merr. cultivar Waseshiroge is highly resistant to several races of Phytophthora sojae in Japan. In order to determine which Rps gene might be present in Waseshiroge, 15 differential cultivars were challenged with 12 P. sojae isolates. None had a reaction pattern identical to that of Waseshiroge, indicating that Waseshiroge may contain a novel Rps gene. In order to characterize the inheritance of Waseshiroge resistance to P. sojae isolates, 98 F₂ progeny and 94 F_7:8 lines were produced from crosses between the susceptible cultivar Tanbakuro and Waseshiroge. Chi-square tests indicated that segregation fit a 3:1 ratio for resistance and susceptibility in two F₂ sub-populations of 42 and 56 seedlings. This and a 46.27:1.46:46.27 (or 63:2:63) ratio for resistance: segregation: susceptibility among the 94 F_7:8 lines indicated that resistance was controlled by a single dominant gene. DNA analyses were carried out on Tanbakuro, Waseshiroge and the 94 F_7:8 lines, and a linkage map was constructed with 17 SSR markers and nine new primer pairs that amplify marker loci linked to Rps1 on soybean chromosome 3 (linkage group N). The closest markers, Satt009 and T000304487l, map to locations 0.9 and 1.6 cM on each side of the estimated position of the Rps gene, respectively. The results showed that the Rps gene in Waseshiroge is either allelic to Rps1, or resides at a tightly linked locus in a gene cluster. A three-way-contingency table analysis indicated that marker-assisted selection with the two flanking markers could be used in the development of new resistant cultivars.     

Fine mapping of the uniform immature fruit color gene u in cucumber (Cucumis sativus L.)

Mottled/uniform color at the flower end of immature fruit is a highly important external quality trait that affects the market value of cucumber. Genetic analysis of different F₂ and backcross populations revealed that one single recessive gene, u (uniform immature fruit color), determines the uniform immature fruit color trait in cucumber. Based on earlier studies, the u locus is located on chromosome 5 (Chr. 5). By combining bulked segregant analysis using 60 published molecular markers on Chr. 5, we found that eight markers are polymorphic and are linked to the u locus. In addition, we developed five new relevant polymorphic simple sequence repeat (SSR) markers between markers SSR16203 and SSR15818. Subsequently, the F₂ population (477 individuals) from the cross of S06 (uniform fruit color line) × S94 (mottled fruit color line) was used for fine mapping of the u gene. The u gene was mapped to a 313.2-kb region between markers SSR10 and SSR27, at a genetic distance of 0.8 and 0.5 cM, respectively. Moreover, validity analysis of the codominant markers SSR10 and SSR27 was performed using 50 lines with mottled/uniform fruit color, demonstrating that these two SSR markers can be used for marker-assisted selection of the mottled/uniform fruit color trait in cucumber breeding. The results of this study will facilitate the cloning of the u gene.     

小麦新品种济麦22抗白粉病基因的分子标记定位

为明确济麦22携带抗白粉病基因的染色体位置,利用济麦22与感病亲本中国春杂交,用小麦白粉菌(Blumeria graminis f. sp. tritici)强毒性小种E20对F₂抗、感分离群体和F_2:3家系进行抗病鉴定和遗传分析。结果表明,济麦22携带1个显性抗白粉病基因, 暂被命名为PmJM22。运用SSR和EST标记及分离群体分组分析法(bulked segregant analysis, BSA),将其定位在2BL染色体上,与4个SSR和5个EST标记间的连锁距离为7.7 cM (Xwmc149)到31.3 cM (Xbarc101)。通过分析2BL上其他抗白粉病基因的来源、染色体位置和抗性反应,认为PmJM22不同于Pm6、Pm26、Pm33和MlZec1。     

Molecular mapping of the blast resistance gene Pi49 in the durably resistant rice cultivar Mowanggu

Rice blast, caused by the fungus Magnaporthe oryzae, is the most devastating fungal disease of rice. Mowanggu, a local japonica cultivar in Yunnan Province, China, confers broad-spectrum resistance to this pathogen. To identify the resistance gene(s) in Mowanggu, we obtained an F₂ population and 280 F₈ recombinant inbred lines (RILs) from a cross between Mowanggu and CO39, a highly susceptible indica cultivar. A linkage map with 145 simple sequence repeat (SSR) and single feature polymorphism markers over 12 chromosomes was constructed using the 280 RILs. The resistance evaluation of the F₂ and F₈ populations in both the growth chamber and in a natural rice blast nursery showed that a single dominant gene controls blast resistance in Mowanggu. Moreover, nine quantitative trait loci, which were responsible for different partial resistance components, were mapped on chromosomes 2, 3, 6, 8, 9, and 12, making contributions to the phenotypic variation ranging from 3.03 to 6.18 %. The dominant resistance gene, designated Pi49, was mapped on chromosome 11 with genetic distance of 1.01 and 1.89 cM from SSR markers K10 and K134, respectively. The physical distance between K10 and K134 is about 181 kb in the Nipponbare genome. The Pi49 gene accounted for the major phenotypic variation of disease severity in the growth chamber (where plants were inoculated with single blast isolates) and also accounted for most of the phenotypic variance of disease severity, lesion number, diseased leaf area, and lesion size in the blast nursery. Our study not only identified tightly linked markers for introgression of Pi49 into elite rice cultivars via marker-aided selection but also provides a starting point for map-based cloning of the new resistance gene.     

Enzyme activity in wheat breeding lines derived from matings of low polyphenol oxidase parents

Polyphenol oxidase (PPO) in grain plays a major role in time-dependent discoloration of wheat (Triticum aestivum L.) products, especially fresh noodles. Breeding wheat cultivars with low or nil PPO activity can reduce undesirable product darkening. The low PPO line PI 117635 was crossed to two low PPO wheats, IDO580 and ‘IDO377s’, to determine whether matings between wheats with low levels of grain PPO would result in complementation, such that lines with still lower or nil PPO would be generated. Progeny in a population derived from PI 117635/IDO580 displayed no variation in PPO activity. In the F_3:4 populations derived from PI 117635/IDO377s, and the reciprocal IDO377s/PI 117635, normal distributions of low to high PPO activity were observed. Field-grown populations (F_3:5; F_3:6) derived from IDO377s crosses were analyzed for PPO activity and used to determine whether lines with nil PPO activity were generated. Of 239 lines, 154 were verified to have PPO activity that was not significantly different from the low PPO durum (Triticum turgidum var durum) cultivar ‘Ben’. PCR analysis showed that the populations were fixed for a putative low PPO allele at Ppo-A1. Using markers for Ppo-D1, it was found that the average PPO activity of lines with 490 bp PCR fragments from PPO29 was significantly lower than that of lines with 560 bp fragments from STS01. These results disagreed with that predicted from previous reports for markers for Ppo-D1 alleles. Thus, breeders should exercise caution when making selections using markers for alleles at Ppo-D1, as known markers might predict erroneous phenotypes and genotypes in some wheat backgrounds.     

杂交粳稻亲本产量性状优异配合力的标记基因型筛选

提高杂交粳稻竞争优势的关键是改良其恢复系产量性状的配合力。为使之更富成效,选用115个SSR引物扩增6个粳稻BT型不育系和12个恢复系的标记基因型,并按NCII遗传设计配制72个F1组合,分析18个亲本的单株日产量、单株有效穗数、每穗总粒数、每穗实粒数、千粒重5个性状的配合力,结合亲本SSR分子标记数据和性状配合力数据筛选了5个性状优异配合力的标记基因型。结果发现20个SSR标记基因型与亲本产量及其构成性状配合力显著相关。其中8个与亲本单个性状配合力相关;6个同时与亲本2个性状配合力相关;4个同时与亲本3个性状配合力相关;2个同时与亲本4个性状配合力相关。同时与多个性状配合力相关的标记基因型,对各性状的作用方向有正有负。RM152-165/170是单株日产量和单株有效穗数优异配合力效应最大的标记基因型,可使F1的相应性状值增加20.6%和12.7%。优异配合力的标记基因型可直接用于粳稻恢复系配合力的分子标记辅助改良。     

Development of genomic and EST-SSR markers in radish (Raphanus sativus L.)

Radish (Raphanus sativus L.) belongs to Brassicaceae family and is a close relative of Brassica. This species shows a wide morphological diversity, and is an important vegetable especially in Asia. However, molecular research of radish is behind compared to that of Brassica. For example, reports on SSR (simple sequence repeat) markers are limited. Here, we designed 417 radish SSR markers from SSR-enriched genomic libraries and the cDNA data. Of the 256 SSR markers succeeded in PCR, 130 showed clear polymorphisms between two radish lines; a rat-tail radish and a Japanese cultivar, ‘Harufuku’. As a test case for evaluation of the present SSRs, we conducted two studies. First, we selected 16 SSRs to calculate polymorphism information contents (PICs) using 16 radish cultivars and four other Brassicaceae species. These markers detected 3–15 alleles (average = 9.6). PIC values ranged from 0.54 to 0.92 (average = 0.78). Second, part of the present SSRs were tested for mapping using our previously-examined mapping population. The map spanned 672.7 cM with nine linkage groups (LGs). The 21 radish SSR markers were distributed throughout the LGs. The SSR markers developed here would be informative and useful for genetic analysis in radish and its related species.