A genome scan for quantitative trait loci affecting grain yield and its components of maize both in single-and two-locus levels

Maize is one of the most important cereal crops in the world. The hybrid yield advantage is responsible for about 10 percent of the total global maize production of 550 Mt[1]. It is exigent to study the yield traits so as to improve the hybrids per se in …     

玉米株高和穗位高遗传基础的QTL剖析

玉米是世界范围内具有经济重要性的作物之一.株高和穗位高是玉米育种过程中需考虑的2个重要农艺性状,对玉米产量、抗倒伏性及株型等都有较大影响.为进一步明确玉米株高和穗位高的遗传机制,本研究以B73×Zheng58的含有165个株系的F3∶4重组自交系群体为作图群体,利用覆盖玉米10条染色体189个SSR标记对株高和穗位高进行QTL定位分析.总共定位到5个株高QTL和6个穗位高QTL;这11个QTL分布在除2号和6号之外的其他8条染色体上.单个QTL表型变异贡献率的变幅为4.3%~14.2%.其中10个QTL与以前报道过的QTL的位置相近或重叠,而株高QTL(qPH04-01)是新发现的群体专一性的QTL,最靠近标记umc0371,表型变异贡献率为8.8%,是值得进一步研究和利用的位点.     

玉米产量相关性状的QTL定位与剖析

玉米因其自身具有高产潜质而成为了当今世界最重要的粮食作物之一.玉米产量是复杂的数量性状,由许多主/微效基因控制,易受各种环境因素影响.果穗是玉米的主要收获器官,籽粒性状是玉米品质的重要体现,因此发掘玉米穗部性状和籽粒性状相关QTL对玉米的遗传改良,培育优质高产的玉米具有重要意义.本研究白刺包谷(P2)和妻染黄(P13)为亲本构建了包含152个家系的F2∶3作图群体,选择在两亲本间具有多态性的176个微卫星标记构建遗传图谱,对产量相关性状进行了单环境的QTL定位与分析.最终定位到了14个QTL,分布在除9号染色体外的其余9条染色体上,单个QTL可解释的表型变异率为4.9％～18.8％.值得注意的是,在6号染色体上的百粒重和穗行数的一致性QTL(qHKW06-1和qERN06-1)与8号染色体上的穗行数QTL(qERN08-1)是本研究中特有的,其中qERN08-1解释了12.4％的表型变异率.     

Detecting quantitative trait loci for water use efficiency in rice using a recombinant inbred line population

Breeding rice with high water use efficiency (WUE) can ameliorate water shortage through water-saving irrigation.However,WUE is a complex quantitative trait and very few studies have been conducted to measure WUE directly.In this study,a recombined inbred line population derived from a cross between an indica lowland rice and upland japonica rice was used to dissect the genetic control of WUE by fine-monitored water supply experiments.Quantitative trait loci (QTL) were scanned for 10 traits including heading date (HD),water-consumption per day (water/d),shoot weight gain per day (shootw/d),root weight gain per day (rootw/d),kernel weight gain per day (kernelw/d),average WUE at whole plant level (WUEwhole/d),average WUE for up-ground biomass (WUEup/d),average WUE for grain yield (WUEyield/d),average economic index (econindex/d),and average root/shoot ratio per day (ratio/d).The results show that most of the traits were significantly correlated to each other.Twenty-four QTL (LOD ≥ 2.0) were detected for econindex,econindex/d,WUEyield,WUEyield/d,WUEup,WUEup/d,WUEwhole,WUEwhole/d,kernelw,kernelw/d,rootw,and water/d by composite interval mapping.These QTLs are located on chromosomes 1,2,4,6,7,8,and 12.Individual QTLs accounted for 4.97%-10.78% of the phenotypic variation explained.Some of these QTLs overlapped with previously reported drought resistance QTLs detected in this population.These results provide useful information for further dissection of the genetic basis and marker-assisted selection of WUE in rice.     

水稻芒长及其分布特征相关QTL的定位

水稻芒的性状与驯化过程密切相关,具体表现为芒长短和芒的分布等．利用一个无芒品种越光（轮回亲本）和一个有芒品种Kasalath杂交产生的回交重组自交系群体,在上海、海南两地对芒长和芒的分布（芒出现比例）进行了相关分析及其相关基因（QTL）定位,结果发现这两个性状间存在显著的正相关．共检测到影响这两个性状的12个QTL,分布在6条染色体上的7个区域,贡献率介于2．90％-53．24％,其正效应大多来自有芒亲本Kasalath,但也有3个QTL正效应来自无芒亲本越光,并对这个现象产生的原因进行了讨论．本研究检测到的QTL及其两侧的分子标记可以用于水稻驯化的研究和理想型无芒品种分子辅助育种．     

水稻DH群体剑叶宽度的QTL及其上位性和环境互作效应研究

利用基于混合模型的QTL定位方法,可以分析水稻DH群体在4个年份下剑叶宽度的QTL及其上位性效应和环境互作效应.结果发现,QTL除了具有自身的效应外,还可以参与上位性效应的形成,一个QTL可与多个QTL发生互作,可能起到诱发和修饰其他位点的作用.QTL与环境的互作效应以及上位性与环境的互作效应更多地被检测到,表明控制剑叶宽度的遗传因素易受环境影响.     

应用RAPD标记构建马尾松单株树遗传连锁图谱

利用马尾松（Ｐｉｎｕｓｍａｓｓｏｎｉａｎａ）崇义群体Ｃ－１６号单株上４０粒种子的胚乳为作图群体材料，用随机扩增多态性ＤＮＡ（ＲＡＰＤ）方法构建马尾松单株遗传连锁图谱，从被步筛选的８０个引物中，得到１６个具有多态性产物的引物，对这１６种引物进行Ｍｅｎｄｅｌｉａｎ１：１分离检测（卡方检验，Ｐ＜０．０５），我们得到符合Ｍｅｎｄｅｌｉａｎ１：１分离比例的ＲＡＰＤｓ标记４９个．通过对４９个标记的连锁关系进行分析，其中２９个标记分布在１２个连锁群上，总图距为４８３．３ｃＭ，平均图距为２８．４２ｃＭ，２０个标记没有连锁到任何连锁群上，需要继续进行大量标记的连续分析，构建完善的高密度的遗传图谱，使之能够对数量性状位点ＱＴＬｓ进行定位，从而进行分子标记辅助选择育种（ＭＡＳ）．     

基于局部分块三维物体表面三角划分算法

基于三维重建工作中物体截面轮廓线序列中相邻轮廓线基本相似的事实,提出了物体截面轮廓线点集之间三角划分的一种快速算法．算法首先寻找轮廓线的控制点,对每两条相邻轮廓线的控制点进行配对;然后将这样两条轮廓线之间的三角划分分配在多个小曲线段对之间进行,并且根据事先匹配的控制点,在每个小的区域中进行简便快速的三角划分．实验验证了算法的有效性．     

Construction of a genetic map and location of quantitative trait loci for dwarf trait in maize by RFLP markers

Using F₂ population derived from the cross of tall inbred 7922 by dwarf inbred 5003, an RFLP linkage map of maize has been constructed, on which 85 markers are distributed among 10 linkage groups and span maize genome about 1827.8 cM with an average distance (24.4 cM) between markers. 106 F_2:3 lines of the population were grown in a 10 × 11 simple rectangular lattice design of one-raw plots with two replications and evaluated for plant height (PH). With interval mapping procedure, 5 QTLs controlling plant height have been identified and their genetic effects and gene action determined. 2 major QTLs with opposite effect have been discovered. One for increasing plant height isph1 which is located at chromosome 2 and accounts for 51.8% of the total phenotypic variation; the other for decreasing plant height isph3 which is located at chromosome 5 and accounts for 38.6% of the total phenotypic variation. The chromosomal location ofph3 might be the same as or close to the position ofbv1, a dwarf mutant of maize.     

一种改进的基于系统命名的拓扑指数iMm与醛酮沸点间的定量关系研究

以系统命名法为基础,结合改进的支链编号规则,对脂肪族醛酮分子中的碳原子进行编号,并在此基础上建立了一种拓扑指数iMm.以72种脂肪醛和脂肪酮的沸点为例,进行定量关系-性质相关(QSPR)研究.72种醛酮沸点与其分子支链数NC和0Mm,1Mm之间存在良好的线性关系:log(720-Tb)=2.652 18+0.013 18NC-0.015 161Mm+0.001 20Mm,复相关系数为0.997 79.本方法为脂肪醛和脂肪酮沸点的归纳与定量表征、预测提供了非常有效的方法,为这类物质的气相色谱分离提供了一种方便易得的数据依据.     

有限段法解非均质变截面杆纵向振动固有频率

对于非均质变截面杆,我们把它划分为很多的小段,当每段的长度很小时,可认为在每段内是均质等截面杆。这样,每段杆所满足的微分方程就可精确求出;然后,利用段与段之间的连续条件导出了一个传递公式;最后,利用边界条件求出了固有频率。     

Fine mapping of <Emphasis Type="Italic">qHUS6.1</Emphasis>, a quantitative trait locus for silicon content in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Silicon is essential for optimal growth of rice (Oryza sativa L.). This study was conducted to fine map qHUS6.1, a quantitative trait locus (QTL) for rice hull silicon content previously located in the interval RM510–RM19417 on the short arm of chromosome 6, and to analyze the effect of this QTL on the silicon content in different organs of rice. Selfed progenies of a residual heterozygous line of rice were detected using 13 microsatellite markers in the vicinity of qHUS6.1. Three plants with overlapping heterozygous segments were selected. Three sets of near isogenic lines (NILs) were developed from the selfed progenies of the 3 plants. They were grown in a paddy field and the silicon contents of the hull, flag leaf, and stem were measured at maturity. Based on analyses of the phenotypic distribution and variance among different genotypic groups in the same NIL set, a significant genotypic effect was shown in the NIL set that was heterogenous in the interval RM19410–RM5815, whereas a significant effect was not found in the remaining 2 NIL sets that were heterogenous in either of the intervals RM4923–RM19410 or RM19417–RM204. On comparison among the physical positions of the 3 heterogenous segments, qHUS6.1 was delimited to a 64.2-kb region flanked by RM19410 and RM19417 that contains nine annotated genes according to the genome sequence of Nipponbare. This QTL showed strong effects on all of the three traits tested, and the enhancing alleles were always derived from the paternal line Milyang 46. The present study will facilitate the cloning of qHUS6.1 and the exploration of new genetic resources for QTL fine mapping.