Genetic Analysis of Combining Abilities and Heterosis for the Contents of Soybean Isoflavone and Its Components Among the Soybean Varieties [Glycine max （L.） Merr.]

The genetic analysis of soybean isoflavone content and its components were carried out based on the NC Ⅱ mating design in eight soybean varieties. The results showed that the isoflavone contents and its components of soybean seed are quite differences among the tested materials, the contents of isoflavone and daidzein are controlled not only by additive effects and but also by non-additive effects, while the content of genistin is dominated by non-additive effects, and genistein, glycitin and daidzin are mainly controlled by additive effects. There are significant differences in the contents of isoflavone and its components among the combinations derived from different parents. Results also indicated that the tested traits are negatively heterosis except for the contens of daidzein and daidzin are positively heterosis based on the data of the GCA and SCA in average heterosis values. In this research we have a suggestion that soybean variety with high isoflavone should be used as one of the parents in the breeding program, and it is the best choice that the combinations crossed between two high isoflavone varieties or a high variety and a low one.     

QTL Mapping of Isoflavone,Oil and Protein Contents in Soybean （Glycine max L. Merr.）

Soybean （Glycine max L. Merr.） is the world＇s foremost source of edible plant oil and proteins, meantime, the biologically active secondary metabolites such as saponins and isoflavones are benefit to human health. The objective of this study was to identify quantitative trait loci （QTL） and epistatic interactions associated with isoflavone, protein, and oil contents in soybean seeds. An F13 recombinant inbred line （RIL） comprising 474 lines was derived from a cross between Jindou 23 and Huibuzhi cultivars. SSR technique was employed for mapping of the QTLs. The QTLs for isoflavone, protein, and oil contents were analyzed and 23 QTLs were detected based on the constructed linkage map. Six QTLs for isoflavone content were localized in linkage groups J, N, D2, and G, eleven QTLs for oil content were localized in the linkage groups A1, A2, B2, C2, and D2, and six QTLs for protein content were localized in linkage groups B2, C2, G, and H1. The correlative analysis demonstrated that the isoflavone content had significant correlation with protein content, while significantly negative correlations was existed between oil and protein content, and significantly positive correlations was existed between protein and oil content. All these findings have laid an important basis for the marker assisted breeding in soybean. The phenotypic correlations of quantitative traits may be resulted from the correlation of the QTL controlling those traits.     

Analysis of QTLs for the Trichome Density on the Upper and Downer Surface of Leaf Blade in Soybean [Glycine max （L.） Merr.]

Trichomes （plant hairs） are present on nearly all land plants and are known to play important roles in plant protection, specifically against insect herbivory, drought, and UV radiation. The identification of quantitative trait loci （QTL） associated with trichome density should help to interpret the molecular genetic mechanism of soybean trichome density. 184 recombinant inbred lines （RILs）, derived from a cross between soybean cultivars Kefeng 1 and Nannong 1138-2 were used as segregating population for evaluation of TDU （trichome density on the upper surface of leaf blade） and TDD （trichome density on the downer surface of leaf blade）. A total of 15 QTL were detected on molecular linkage groups （MLG） A2, Dla, Dlb, E and H by composite interval mapping （CIM） and among all the QTL, qtuA2-1, qtuD 1 a-1, qtuD lb-2, qtuH-2 qtuE-1, qtdDlb-2, and qtdH- 2 were affirmed by multiple interval mapping （MIM）. The contribution ofphenotypic variance of qtuH-2 was 31.81 and 29.4% by CIM and MIM, respectively, suggesting it might be major gene Ps loci. Only 10 pairs of main QTL interactions for TDU were detected, explained a range of 0.2-5.1% of phenotypic variations for each pair for a total of 22.8%. The QTL on MLG Dlb affecting trichome density were mapped near to Rsc-7 conditioning resistance to SMV （soybean mosaic virus）. This study showed that the genetic mechanism of trichome density was the mixed major gene and polygene inheritance, and also suggested that the causal nature between trichome density and other agronomic traits.     

Analysis of Genetic Effects for Heterosis of Erucic Acid and Glucosinolate Contents in Rapeseed （Brassica napus L.）

The embryo,cytoplasmic,and maternal heterosis for erucic acid content (EAC) and glucosinolate content (GLS) of rapeseed (Brassica napus L.) were studied by using the genetic models for quantitative traits of seeds in diploid crops.Eight parents were included in a diallel mating design in two years.It was found that the heterosis of EAC and GLS was simultaneously controlled by genetic main effects and genotype×environment (GE) interaction effects.The general heterosis of most crosses for EAC was significantly positive,while it was not for GLS.The general heterosis was more important for two quality traits of rapeseed because of the low GE interaction heterosis in both years,especially for GLS.Among different genetic systems,significant positive embryo general heterosis and the negative maternal general heterosis were found for EAC and GLS in most hybrid crosses.Some hybrids with significant negative interaction heterosis were detected for either of EAC or GLS.In general,maternal general and interaction heterosis was more important for reducing EAC and GLS of rapeseed.     

Study on Accumulation Rule of Carbohydrates in Soybean （Glycine max（L.） Merrill）

Three soybean cultivars, Hefeng25 （HF25）, Suinongl4 （SN14） and Longxuanl （LX1） were used as materials and the accumulation features of carbohydrates were studied in leaves and stems. The results showed that the soluble sugar content in leaves and stems appeared the same trend of higher-lower-higher in three varieties. The changes of sucrose content in leaves appeared the same rule with that of soluble sugar, that is higher-lower-higher, while presented a rising trend in stems. The content of starch in leaves varied as a change of double apexes. The content of starch in stems appeared a change of single apex. In the same stage, there were some differences among carbohydrates. The content of soluble sugar and sucrose in SN14 was higher, and the starch content was lower.     

The Inheritance and Variation of Gum Content in Guar [Cyamopsis tetragonoloba （L.） Taub.]

Guar [Cyamopsis tetragonoloba （L.） Taub.] is one of the most important industrial crops due to its richness in gum. Understanding the inheritance of gum content is a key to its successful genetic improvement. Gum content expression is reported to be controlled by additive, dominant, and epistatic effects, and modified by the environment, fg%, a relative gum content calculated by comparing with the gum content of Kinman was used as gum content （%） in this experiment. Reciprocal crosses of two lines of guar, PI 217923 and Lewis, were made to study the heritability of gum content （fg%）. fg% of four plant introductions and four commercial varieties were studied in Lubbock in 1999-2002. Estimates of broadsense heritability （h^2 b,s.） of fg% in Lewis x PI 217923 and PI 217923 x Lewis were 75.53 and 52.74%, respectively. Estimates of narrow-sense heritability （h2 n.s.） of fg% were 40.00 and 29.00% thr Lewis x PI 217923 and PI 217923 x Lewis, respectively. At least one pair of genes were estimated to control the fg% expression in these two crosses, Significant differences of fg% were found among these eight entries. PI 217923 was found to have the highest fg% among the eight entries.     

Effects of phosphorus on nutrient uptake and rhizosphere acidification of soybean （Glycine max L.）

Pot experiment was conducted to examine how application of KH2PO4 （0-165 mg·kg^-1 P） to affect nutrient ion uptake and rhizosphere acidification of soybean （Glycine max L.） grown in greenhouse for 90 days. When supplied of 82 and 165 mg·kg^-1 P, soybeans showed excessive poison. Under all kinds of P levels, the K, Ca, Na and Mg concents in plant tissues were as below order K was nodules 〉 roots 〉 pods 〉 shoots; Ca was shoots 〉 roots 〉 nodules 〉 pods; Na was roots 〉 nodules 〉 pods 〉 shoots and Mg was shoots 〉 nodules 〉 roots 〉 pods. K concent in plant tisssues had greater effect on rhizosphere acidification than other cations in this experiment irrespective of P supply, and was significantly negative to pH. Na concentration was significantly positive to pH. Excessive P supply induced rhizosphere acidification, pH decreased as P supply increased from 82 to 165 mg·kg^-1. Ash alkalinity in shoots and roots was significantly positively correlated with rhizosphere pH irrespective of P supply. All these results suggested that P supply affected nutrient uptake, induced ash alkalinity to increase and rhizosphere pH to decrease in soybean.     

大豆异黄酮及其组分含量的配合力和杂种优势

 为了能在大豆异黄酮及其组分的育种中合理选配亲本，利用杂种优势，本研究选用8个异黄酮含量不同的大豆品种采用NCⅡ设计配置杂交组合，对大豆籽粒异黄酮及其组分含量进行遗传分析。研究结果表明，大豆籽粒异黄酮及其组分含量在供试品种间表现有明显的差异，籽粒异黄酮含量和黄豆甙元既受加性效应又受非加性效应的控制，染料木甙主要受非加性效应控制，染料木素、大豆甙元和大豆甙这3个性状的遗传主要受加性效应控制；不同亲本组配的不同组合的GCA和SCA差异较大。在中亲优势测定中，除黄豆甙元含量和大豆甙表现为正向超亲外，其余性状均表现为负向超亲。本研究认为在大豆高异黄酮育种中应选择高异黄酮材料作为亲本之一，选配组合时亲本最好采用高×高类型或高×低类型配置组合。     

Genetic Analysis of Combining Abilities and Heterosis for the Contents of Soybean Isoflavone and Its Components Among the Soybean Varieties [Glycine max (L.) Merr.]

The genetic analysis of soybean isoflavone content and its components were carried out based on the NC Ⅱ mating design in eight soybean varieties. The results showed that the isoflavone contents and its components of soybean seed are quite differences among the tested materials, the contents of isoflavone and daidzein are controlled not only by additive effects and but also by non-additive effects, while the content of genistin is dominated by non-additive effects,and genistein, glycitin and daidzin are mainly controlled by additive effects. There are significant differences in the contents of isoflavone and its components among the combinations derived from different parents. Results also indicated that the tested traits are negatively heterosis except for the contens of daidzein and daidzin are positively heterosis based on the data of the GCA and SCA in average heterosis values. In this research we have a suggestion that soybean variety with high isoflavone should be used as one of the parents in the breeding program, and it is the best choice that the combinations crossed between two high isoflavone varieties or a high variety and a low one.     

我国大豆根瘤内生菌资源多样性研究

植物内生菌已成为植物微生态系统中的重要组成部分,根瘤内生菌和根瘤菌普遍共存于特殊的根瘤生 境。比较了根瘤内生菌和根瘤菌与宿主间关系存在的区别,对大豆根瘤内生菌的种类、宿主和适应性、生物固氮、促 进植物生长、增强宿主抗逆、抗病能力以及联合修复环境污染等功能多样性进行论述,指出大豆根瘤内生菌研究的 发展方向,对进一步促进植物生长、发展可持续农业具有重要意义。 ）     

大豆(Glycine max(L.) Merr.)叶片抗氧化酶对干旱及复水的响应机制

采用10%PEG-6000模拟干旱胁迫,研究了抗旱品种晋大74与不抗旱品种晋大75两种大豆幼苗在水分胁迫及复水后叶片MDA含量、O2-·含量、SOD、CAT、APX及POD等的活性变化,旨在揭示抗氧化酶对干旱及复水的响应机制。结果表明,在干旱胁迫下,两种大豆叶片MDA及O2-·,含量都高于对照,且晋大75增加幅度显著大于晋大74;复水后晋大74中MDA及O2-·接近于对照水平,表明旱后复水产生了补偿效应。干旱胁迫下,晋大74通过保持较高的SOD活性或较低的APX、CAT降幅以减弱活性氧伤害,而旱后复水过程中晋大74通过维持较高的SOD、APX、CAT酶活性,利用其协同作用有效清除活性氧,避免膜伤害。总之,耐旱品种在干旱及复水过程中具有更强的抗氧化修复能力。     

中国大豆资源异黄酮含量及其组分的遗传变异和演化特征

【目的】中国拥有丰富的栽培大豆和野生大豆资源,研究不同生态区大豆种质异黄酮含量的遗传变异和演化特征为专用型品种的选育奠定基础。【方法】以来自中国各生态区的580份地方品种、106份育成品种、209份野生大豆组成的895份大豆种质为材料,88份国外品种为参照,采用快速高效液相色谱法测定12种大豆籽粒异黄酮,分析其遗传变异和演化特征。【结果】全国野生大豆、地方品种与育成品种大豆异黄酮总含量(TISF)及其组分均存在很大变异。TISF变幅分别为927.29—7932.94、259.38—7725.45和489.67—5968.90μg·g-1,平均分别为2994.51、3241.33和2704.83μg·g-1。从野生种到地方品种再到育成品种,长期人工育种使染料木苷类总含量(尤其是丙二酰基染料木苷)与黄豆苷类总含量(尤其是乙酰基黄豆苷和丙二酰基黄豆苷)增加,大豆苷类总含量(尤其是乙酰基大豆苷)却明显降低,从而导致育成品种平均TISF低于野生种。各生态区的野生和栽培种质的TISF及其组分均有大量变异。野生种TISF与种质来源地经、纬度无显著性相关,栽培种则由于各地人工进化的差异形成了与地理经、纬度均有极显著负相关(r=-0.264和-0.380)的特点。从983份材料中优选出ZYD3621(TISF7932.94μg·g-1)、N3188(TISF7725.45μg·g-1)、N20793(TGL5122.21μg·g-1)等一批高TISF与高组分特异种质可供异黄酮育种利用。【结论】中国从野生种到地方品种再到育成品种,异黄酮含量及其组分的演化特点为栽培大豆平均异黄酮总含量、染料木苷类与黄豆苷类总含量均高于野生种,大豆苷类总含量低于野生种。中国各生态区域内大豆异黄酮及其组分均有丰富变异,从中筛选出一批高含量、高组分种质可供异黄酮育种利用。     

中国栽培大豆(Glycine max (L.) Merr.)微核心种质的群体结构与遗传多样性

【目的】评价中国栽培大豆微核心种质的群体结构和遗传多样性水平,为拓宽大豆遗传基础、发掘优异基因、改良大豆品种提供理论依据。【方法】利用大豆20个连锁群上的100个SSR位点,对来自全国28个省补充完善的248份栽培大豆微核心种质进行SSR遗传多样性及群体结构分析;采用PowerMarker Version 3.25软件统计等位变异数、平均等位变异数、多态性信息量(PIC值)及亚群特有等位变异数等参数;基于遗传距离建立了栽培大豆微核心种质的无根Neighbor-Joining树;用Structure2.2软件对微核心种质的群体结构进行评价。【结果】100个SSR位点在248份材料中共检测出等位变异1460个,每个位点变异范围为2—33个,平均为14.6个,每个位点PIC值变异范围为0.158—0.932,平均为0.743。基于模型的群体结构分析显示,依据LnP(D)无法判断最佳K值(群组数),但通过计算系数ΔK发现,K=3为微核心种质的最佳群体结构。结合种质的生态类型及品种类型分析发现,地理来源相同的种质具有聚在一起的倾向,但来源相同的种质也有分在不同组的情况。不同生态类型及品种类型间均存在较多的互补等位变异和特有等位变异。【结论】中国栽培大豆微核心种质具有丰富的遗传多样性,可以用来拓宽大豆品种遗传基础;不同生态类型及品种类型间存在较多的互补及特有等位变异,是种质创新及品种改良的物质基础;栽培大豆微核心种质存在明显的群体结构,为微核心种质在育种中的直接或间接利用提供了理论依据。     

Rapid HPLC Method for Determination of 12 Isoflavone Components in Soybean Seeds

It is important to determine the isoflavone components by high-performance liquid chromatography(HPLC)for the molecular assistant selection of isoflavone in soybean.Based on the standard samples of 12 isoflavone components,the isoflavone components were analyzed using the determination of absorbance peaks method by HPLC.The results showed that there were different maximum ultraviolet(UV)absorbance for the aglycones of daidzein,glycitein,and genistein,which were at 250,257,and 260 nm,respectively.A linear gradient elution of acetonitrile(13-30%)containing 0.1% acetic acid as a mobile phase was applied on a YMC-C18 column at 35℃.The 12 isoflavone components were determined using the UV detector by HPLC.We concluded that this is a rapid and precise method which adapted to determine the large numbers of samples with microanalysis.     

幼苗期大豆根系性状的遗传分析与QTL检测

【目的】研究幼苗期大豆根系性状的遗传规律并进行QTL定位,推进大豆品种选育进程。【方法】以栽培大豆晋豆23为母本,半野生大豆灰布支黑豆（ZDD2315）为父本及其所衍生的447个RIL作为供试群体,取亲本及447个家系各30粒种子,用灭菌纸包裹后分别于2013年5月27日、6月28日放置在清水培育,每组试验设置3次重复,环境温度20-28℃,幼苗长到V2期,分别于2013年6月8日、7月8日对幼苗期相关根部性状数据进行测量。采用主基因+多基因混合遗传分离分析法和复合区间作图法,对大豆幼苗期根系性状进行遗传分析和QTL定位。定位所用图谱全长2 047.6 cM,包括27个连锁群,232个标记位点。【结果】主根长、侧根数、根重、根体积和茎叶重各形状之间均呈现极显著正相关;下胚轴长和下胚轴重表现极显著正相关,与茎叶重表现出显著正相关。主根长受3对等效主基因控制,侧根数受2对重叠作用主基因控制,根重和根体积受4对等效主基因控制,下胚轴长受4对加性主基因控制,下胚轴重受4对加性-加性×加性上位性主基因控制,以上性状均没有检测到多基因效应。茎叶重受加性多基因控制,没有检测到主基因效应。共检测到24个与主根长、侧根数、根重、根体积、茎叶重、下胚轴长和下胚轴重相关的QTL,分别位于A1、A2、B1、B2、C2、D1b、F_1、G、H_1、H_2、I、K_2、L、M、N和O连锁群上。其中,主根长共检测到5个QTL,分布在B1、L、N、O连锁群上。解释的表型变异范围为7.05%-13.18%。侧根数共检测到4个QTL,分布在A1、D1b、I、L连锁群上。解释的表型变异范围为8.21%-16.43%。根重共检测到3个QTL,分布在F_1、G、N连锁群上。解释的表型变异范围为7.55%-10.85%。根体积,5月27日试验结果,共检测到3个QTL,分布在K_2和M连锁群上。解释的表型变异范围为8.44%-12.39%。6月28日试验结果,没有定位出主效QTL。茎叶重共检测到5个QTL,分布在A1、A2和N连锁群上。解释的表型变异范围为11.43%-38.91%。其中,qSW1-a2-1、qSW2-a2-1和qSW2-a2-1均定位在A2染色体上。下胚轴长,5月27日试验结果,共检测到1个QTL,分布在H_1连锁群上,表型贡献率为7.86%。6月28日试验结果,没有定位出主效QTL。下胚轴重共检测到3个QTL,分布在B2、C2、H_2连锁群上。解释的表型变异范围为7.70%-12.48%。【结论】幼苗期根系性状的遗传机制较复杂,茎叶重受多基因控制,其余性状主要受主基因控制。抗逆品种根系从幼苗期根系生长就表现出发根早、生长快、主根长、侧根多等特点,在实际育种过程中,需要对根系各性状间的关系进行综合考虑,确保根系整体健壮发达,协调统一。