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1.
株高、分枝数及第1分枝高是油菜重要的农艺性状。本研究利用甘蓝型油菜GH06和P174杂交,F2通过单粒法连续自交至F11构建重组自交系群体,利用油菜60K芯片对该群体进行基因分型,构建高密度遗传连锁图谱。结果表明,该图谱包含2795个SNP多态性标记位点,总长1832.9 c M,相邻标记间平均距离为0.66 c M。在此图谱基础上采用复合区间作图法(CIM),检测到3个农艺性状的24个QTL。其中11个株高QTL分别位于A01、A06、A07、A08、A10和C06染色体,单个QTL解释5.00%~15.26%的表型变异;7个第1分枝高QTL分别位于A06、C05和C06染色体,单个QTL解释5.04%~12.99%的表型变异;6个分枝数QTL分别位于A03、A07、C01、C04和C06染色体,单个QTL解释5.95%~8.14%的表型变异。将156个拟南芥株高相关基因、10个拟南芥第1分枝高相关基因和148个拟南芥分枝数相关基因与QTL对应置信区间序列进行同源比较分析(E1E–20),分别找出了20个株高候选基因、3个第1分枝高候选基因以及12个分枝数候选基因。2个环境中在A07染色体上重复检测到的QTL置信区间检测到与株高相关的候选基因ATGID1B/GID1B和WRI1,A08染色体上重复检测到的QTL置信区间检测到SLR/IAA14和AXR2/IAA72个与株高相关的候选基因。在具有部分置信区间重叠的q2013FBH-C05-1和q2014FBH-C05-2区间均检测到第1分枝高候选基因PHT1;8,在A03和C06染色体上的QTL置信区间内,分别检测到4个分枝数候选基因,匹配E值介于0~3E–56之间。 相似文献
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四向杂交设计QTL分析的极大似然方法 总被引:2,自引:0,他引:2
四向杂交(four-way cross)设计是指4个纯系亲本参与杂交衍生分离群体的一种交配设计。尽管国际上已经提出基于四向杂交设计的迭代重新加权最小平方(iteratively reweighed least squares,IRWLS)QTL作图方法,但该方法忽略了双侧标记基因型内QTL基因型的混合分布特性,当QTL位置和标记的位置不重合时作图精度较低。本文根据四向杂交设计的数量遗传模型,发展出基于四向杂交设计和混合分布理论的QTL作图的极大似然估计方法。首先利用染色体上所有标记基因型联合计算该染色体上任一假定位置QTL的条件概率,然后根据混合分布理论建立基于EM算法实现的QTL作图的极大似然估计方法。以计算机模拟数据研究了QTL遗传力、样本容量和分子标记信息含量3个因素对方法的影响,结果表明,(1)在QTL的被发现能力上,标记信息不完全的四向杂交设计仅略低于信息完全时的四向杂交设计;(2)随着QTL遗传力、样本容量和标记信息含量的增大,QTL位置以及效应估计值的准确度和精确度逐步提高。 相似文献
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Osvin Arriagada Freddy Mora Joaquín C. Dellarossa Marcia F. S. Ferreira Gerardo D. L. Cervigni Ivan Schuster 《Euphytica》2012,186(3):907-917
The soybean cyst nematode (SCN) is one of the most economically important pathogens of soybean. Molecular mapping of quantitative trait loci (QTL) for resistance to SCN is a proven useful strategy in order to assist in the development of resistant soybean cultivars. In the present study, a Bayesian modeling approach was performed to map QTL controlling genetic resistance to SCN races 3 and 14. For this purpose, a population of recombinant inbred lines derived from the cross between line Y23 (susceptible) and cv. Hartwig (resistant) was used. A total of 144 microsatellites markers (Simple Sequence Repeats) were selected and synthesized for mapping purpose. Posterior marginal parameter distributions were computed using the Reversible Jump Markov Chain Monte Carlo (RJ-MCMC) algorithm. It was determined the existence of four QTLs on three linkage groups (LG); that is LG A2 for race 3, LG C2 for race 14, and LG G for both races. The estimates of posterior modes of the heritability were 0.038 and 0.53 for the LGs A2 and G respectively (race 3). For the race 14 the posterior modes of the heritability were 0.044 and 0.05 for the LGs C2 and G. The identified QTLs explained about 57 and 9 % of the total phenotypic variance, for the races 3 and 14, respectively. These results confirm the effectiveness of the Bayesian method to map QTL controlling resistance to SCN in soybean. Accordingly, integrating QTL mapping with Bayesian methods will enable response to selection for quantitative traits of interest in soybean to be improved. 相似文献
5.
Increased labor costs and reduced labor pools for hop production necessitate the development of strategies that improve efficiency and automation of hop production. One solution for reducing labor inputs is the use of “short-trellis” hop varieties. Unfortunately, little information exists on the genetic control of this trait in hop, and there are no known molecular markers available for selection. This preliminary study was enacted to identify QTLs associated with expression of short-stature growth phenotype using SNPs identified within genome-assembled scaffolds. A bi-parental mapping population of 87 offspring was obtained from the cross, “Pioneer × 25/95/15”. Genotyping-by-sequencing was performed on parents and offspring. SNPs were identified using TASSEL v3.0 with either ‘Teamaker’ reference genome or ‘Shinsuwase’ genome. The genetic map derived from ‘Teamaker’ SNPs was far superior and was used for all further analysis. QTL analysis identified eight QTLs linked to short stature with five showing strong statistical association based upon three different statistical analyses. All eight QTLs were found on linkage group one. Evaluation of scaffolds containing SNP markers located at or surrounding QTL regions (±1 cM) identified 67 putative genes—several of which are known structural genes. A genome-wide scan of SNP markers identified an additional marker found on a scaffold containing a putative gene (Aspartyl protease family protein) known to induce dwarf characteristics in other species. Further validation of significantly associated markers on different populations is necessary prior to implementation in marker-assisted selection. 相似文献
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John A. Henning M. Shaun Townsend David H. Gent Nahla Bassil Paul Matthews Emily Buck Ron Beatson 《Euphytica》2011,180(3):411-420
Hop powdery mildew [Podosphaera macularis (Wallr.) U. Braun & S. Takam.] is best controlled via the production of resistant varieties. Recent evidence supports selection
against plant susceptibility genes to fungal pathogens as a more durable resistance mechanism than selection for resistance
genes. The objective of this study was to identify molecular-based QTLs, their genetic effects and epistasis among QTLs associated
with susceptibility to powdery mildew. Parents and offspring from the cross, ‘Perle’ × ‘USDA 19058M’, were clonally replicated
and inoculated in a greenhouse using a CRD experimental design in Corvallis, OR. DNA was extracted, purified and analyzed
via three different marker systems. Analysis of the resulting markers was based upon the “two-way pseudo-testcross” procedure.
QTL mapping using multiple interval mapping and Bayesian interval mapping analyses were performed using WinQTL Cartographer
2.5_003. Comparison amongst mapping analyses identified three persistent QTLs on three linkage groups without significant
epistatic effect upon expression. The persistent QTL on linkage group C7 had both additive and dominant effects controlling
phenotype expression. The presence or absence of the two AFLP markers bordering the QTL on C7 defined susceptibility in offspring.
This is the first report in hop identifying molecular markers linked to QTLs associated with disease susceptibility. 相似文献
8.
四种不同QTL作图方法的比较研究 总被引:2,自引:0,他引:2
应用区间作图法(IM)、复合区间作图法(CIM)、基于混合线性模型的复合区间作图法(MCIM)和多重区间作图法(MIM)对水稻杂交组合(培矮64S×日本晴)F2群体株高性状进行了QTL作图分析。结果表明,(1)在同一显著水平下(α=0.0023),4种方法共发现10个QTLs,其中IM法7个,CIM法10个,MCIM法3个,MIM法1个。CIM法的发现能力最强。(2)CIM法发现了IM法发现的全部QTLs,和左端标记的距离也基本一致。(3)4种方法检测到了同一QTL,且共同检测到QTL的贡献率最大。(4)4种方法估计的QTL的平均加性效应ā和显性效应 无显著性差异,同一QTL在显性效应的方向上表现一致。(5)建议使用多种作图方法共同作图,并优先标定共同发现的QTL。 相似文献
9.
Identification of quantitative trait loci underlying milling quality of rice (Oryza sativa) grains 总被引:3,自引:0,他引:3
Milling quality of rice grains is important to both producers and consumers. In this study, quantitative trait loci (QTLs) controlling brown rice rate (BR), milled rice recovery (MR) and head rice recovery (HR) were analysed by composite interval mapping over 2 years using 98 backcross inbred lines (BILs). A total of 12 QTLs for the three traits were detected, of which five were for BR, four for MR and three for HR. The proportion of phenotypic variation explained by individual QTLs ranged from 7.5 to 19.9%, and additive effects contributed by a single QTL accounted for 0.46 to 2.34% of the variation. QTL‐by‐environment interactions were observed by comparing QTL mapping of the same population grown in two consecutive years. Three of five QTLs for BR and two of four QTLs for MR were detected in 2 years, and all three QTLs for HR were detected in 1 year only. BR was significantly correlated with MR, and all four QTLs of MR were located in the same regions as those of BR. This indicated that QTLs for highly correlated traits could often be detected in the same interval. 相似文献
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Variation in root architecture is essential for the adaptation of plants to target environments. A non‐destructive gel‐based mini‐rhizotron system was used for root architecture trait phenotyping. This system has facilitated the visualization of root architectural traits in large genotype collection of rapeseed including 94 double haploid (DH) lines from “Express617” x “V8” and 439 inbred lines (ASSYST diversity set). A high‐density Express617‐V8 linkage map was used for quantitative trait loci (QTLs) identification in DH population based on standard composite interval mapping. 6K SNPs were analysed for association mapping of root traits in ASSYST diversity set. A large variation, broad segregation and medium–low heritability of root architectural traits, primary root length and growth rate, lateral root number, lateral root length and lateral root density, were observed. In the double haploid population, 11 QTL regions, and in the diversity set, 38 significant marker–trait associations were detected. Significant marker–trait associations proved that these are quantitatively inherited traits controlled by multiple genes which revealed to proceed for genetic improvement and selection of rapeseed lines with improved root system. 相似文献
11.
Hop with powdery mildew [HPM: caused by Podosphaera macularis (Wallr.) U. Braun & S. Takam.] results in significant losses in hop production by reducing yield and quality. One means of increasing yield and quality is the production of resistant hop lines. Breeding for resistance can be significantly improved and accelerated by use of marker-assisted selection. The objective of this preliminary study was to identify QTLs and markers for genetic resistance to HPM. A bi-parental mapping population between the resistant line “Newport” and susceptible line ‘21110M’. Phenotypic data was scored under controlled greenhouse conditions. Significant differences among offspring were observed and disease resistance did not follow a distinct binomial distribution, suggesting quantitative genetic control. Genotyping-by-sequencing resulted in approximately 375 K SNP markers, which were filtered down to 2263 markers mapped to 10 linkage groups. Interval Mapping identified four QTLs with one on linkage group 1 and three located on linkage group 6. Composite interval mapping identified three QTLs, all located on linkage group 6. Mixed linear models identified 15 markers associated with expression of resistance to HPM. Three of these 15 SNPs were also identified in QTL-CIM analysis. Evaluation of the scaffolds containing the significant SNP markers identified seven putative genes—several of which appear involved in disease resistance in other plant species. The SNP markers identified in this study still require validation in unrelated populations prior to implementation in breeding programs. 相似文献
12.
Lei Huang Ailan Zeng Pengyin Chen Chengjun Wu Dechun Wang Zixiang Wen 《Plant Breeding》2018,137(5):714-720
Salinity is a common abiotic stress causing soybean [Glycine max (L.) Merr.] yield loss worldwide. The use of tolerant cultivars is an effective and economic approach to coping with this stress. Towards this, research is needed to identify salt‐tolerant germplasm and better understand the genetic and molecular basis of salt tolerance in soybean. The objectives of this study were to identify salt‐tolerant genotypes, to search for single‐nucleotide polymorphisms (SNPs) and QTLs associated with salt tolerance. A total of 192 diverse soybean lines and cultivars were screened for salt tolerance in the glasshouse based on visual leaf scorch scores after 15–18 days of 120 mM NaCl stress. These genotypes were further genotyped using the SoySNP50K iSelect BeadChip. Genomewide association mapping showed that 62 SNP markers representing six genomic regions on chromosomes (Chr.) 2, 3, 5, 6, 8 and 18, respectively, were significantly associated with salt tolerance (p < 0.001). A total of 52 SNP markers on Chr. 3 are mapped at or near the major salt tolerance QTL previously identified in S‐100 (Lee et al., 2014). Three SNPs on Chr. 18 map near the salt tolerance QTL previously identified in Nannong1138‐2 (Chen, Cui, Fu, Gai, & Yu, 2008). The other significant SNPs represent four putative minor QTLs for salt tolerance, newly identified in this study. The results above lay the foundation for fine mapping, cloning and molecular breeding for soybean salt tolerance. 相似文献
13.
大豆籽粒大小与形状性状的QTL定位 总被引:2,自引:0,他引:2
大豆籽粒大小和粒形性状不仅与产量和外观品量紧密相关,还对机械化播种有着一定的影响。本研究采用大粒栽培品种冀豆12与小粒半野生地方品种黑豆(ZDD03651)杂交衍生的包含188个重组自交系的F6:8和F6:9群体为材料,对粒长、粒宽、粒厚、长宽比、长厚比和宽厚比的遗传结构进行分析,并分别以WinQTLCart 2.5、QTLNetwork 2.1和IciMapping 4.1 3种模型对以上性状的加性效应QTL,QE互作效应及上位性互作效应进行检测。6个性状的广义遗传率介于64.01%~79.57%,遗传力较高,且除粒厚外的其他性状受环境影响显著。共定位到加性效应QTL38个,单个QTL的贡献率介于2.21%~10.71%之间,分布在12条染色体的17个标记区间内,且12个染色体区段至少与两种性状相关。两种及以上模型同时检测到的QTL有24个,3种模型均能检测到的QTL共8个,分别为qSL-17-1、qSL-18-1、qSW-6-1、qST-2-1、qST-6-1、qSLT-2-2、qSWT-2-1和qSWT-20-1。检测到7对上位性互作QTL,分别涉及粒长、粒宽、长宽比、长厚比和宽厚比,互作效应贡献率介于0.78%~6.20%之间。QE互作效应贡献率均较低,介于0.0005%~0.3900%之间。以多种模型同时检测结果准确性较高,可为分子标记辅助育种工作提供可靠理论基础。 相似文献
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不同统计遗传模型QTL定位方法应用效果的模拟比较 总被引:5,自引:0,他引:5
分子遗传和数量遗传的结合,发展了QTL定位研究。随着定位方法与软件的建立和完善,QTL定位的研究越来越多。准确定位的QTL可用于分子标记辅助选择和图位克隆,而假阳性QTL将误导定位信息的应用。本文分析了迄今主要定位方法(软件)对于各种遗传模型数据的适用性。应用计算机模拟4类遗传模型不同的重组自交系群体(RIL),第一类只包含加性QTL;第二类包含加性和上位性互作QTL;第三类包含加性QTL和QTL与环境互作效应;第四类包含加性、上位性互作QTL和QTL与环境互作效应。每类按模拟QTL个数不同设两种情况,共分为8种数据模型(下称M-1~M-8)。选用WinQTLCart 2.5的复合区间作图(下称CIM)、多区间作图前进搜索(MIMF)、多区间作图回归前进选择(MIMR)、IciMapping 2.0的完备复合区间作图(ICIM)、MapQTL 5.0的多QTL模型(MQM)以及QTLnetwork 2.0的区间作图(MCIM)6种程序对8种不同遗传模型的RIL进行QTL检测。结果表明,不同程序适用的遗传模型范围不同。CIM和MQM只适于检测第一类模型;MIMR、MIMF和ICIM只适于检测第一类和第二类模型;只有MCIM适于检测所有4类遗传模型;因而不同遗传模型数据的最适合检测程序不同。由于未知实际数据的遗传模型,应采用在复杂模型程序,如QTLnetwork 2.0,扫描基础上的多模型QTL定位策略,对所获模型用相应模型软件进行验证。 相似文献
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大豆苗期耐淹性的遗传与QTL分析 总被引:2,自引:0,他引:2
涝害是世界上许多国家的重大自然灾害。耐涝性可分为耐湿(渍)性和耐淹性。以科丰1号(高度耐淹)×南农1138-2(不耐淹)衍生的RIL群体(NJRIKY)为材料, 以盆栽全淹条件下的存活率为耐淹性指标, 采用主基因+多基因混合遗传模型分离分析法进行遗传分析, 并利用WinQTL Cartographer Version 2.5程序的复合区间作图法(CIM)及多区间作图法(MIM)进行QTL定位。结果表明, 两次试验的耐淹性均存在超亲变异, 试验间、家系间以及试验与家系互作间的差异均极显著; NJRIKY大豆群体的耐淹性为3对等加性主基因遗传模型, 主基因遗传率为42.40%; 在QTL分析中, 用CIM和MIM共同检测到3个耐淹QTL, 分别位于A1、D1a和G连锁群上的Satt648~K418_2V、Satt531~A941V、Satt038~Satt275 (B53B~Satt038)区间, 表型贡献率为4.4%~7.6%。分离分析与QTL定位的结果相对一致, 可相互印证。 相似文献
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小麦苗期性状能够指示品种的耐盐性。本研究以小麦骨干亲本燕大1817与品系北农6号衍生的230个重组自交系为材料,利用2013年3个不同时间的水培试验数据和已经构建的SSR和SNP高密度遗传连锁图谱分别对正常和盐胁迫条件下根数和最长根长等7个苗期性状进行QTL定位。利用完备复合区间作图法(ICIM)共检测到69个加性效应QTL(LOD≥2.5),分布于除1A染色体外的所有20条染色体上,单个QTL解释的表型变异率为2.70%~19.00%。有46个QTL的增效效应来自于燕大1817,有23个QTL的增效效应来自于北农6号。有12个QTL能够在3个或3个以上的环境中被检测到,在燕大1817中定位到稳定的多分蘖主效QTL QTn.cau-7BS.1和盐胁迫条件下特异表达的根数QTL QRn.cau-2A,解析了小麦骨干亲本燕大1817的繁茂性和抗逆性遗传基础,为解析小麦品种耐盐遗传机制和耐盐性的分子标记辅助选择提供了重要信息。 相似文献
17.
Genetics and mapping of quantitative traits for nodule number, weight, and size in soybean (Glycine max L.[Merr.]) 总被引:1,自引:0,他引:1
Sadal Hwang Jeffery D. Ray Perry B. Cregan C. Andy King Marilynn K. Davies Larry C. Purcell 《Euphytica》2014,195(3):419-434
Soybean research has found that nodule traits, especially nodule biomass, are associated with N2 fixation ability. Two genotypes, differing in nodule number per plant and individual nodule weight, KS4895 and Jackson, were mated to create 17 F3- and 80 F5-derived RILs. The population was mapped with 664 informative markers with an average distance of less than 20 cM between adjacent markers. Nodule traits were evaluated in 3-year field trials. Broad-sense heritability for nodule number (no. plant?1), individual nodule dry weight (mg nodule?1), individual nodule size (mm nodule?1), and total nodule dry weight (g plant?1) was 0.41, 0.42, 0.45, and 0.27, respectively. Nodule number was negatively correlated with individual nodule weight and size. Nodule number, individual nodule weight, and size are major components which likely contributed to increased total nodule weight per plant. Composite interval mapping (CIM) identified eight QTLs for nodule number with R2 values ranging from 0.14 to 0.20. Multiple interval mapping (MIM) identified two QTLs for nodule number, one of which was located close to the QTL identified with CIM. Six QTLs for individual nodule weight were detected with CIM, and one QTL was identified with MIM. For nodule size, CIM identified seven QTLs with R2 values ranging from 0.14 to 0.27. Five QTLs for total nodule weight were detected with CIM, one of which was located close to a QTL identified with MIM. These results document the first QTL information on nodule traits in soybean from field experiments utilizing a dense, complete linkage map. 相似文献
18.
Zhengong Yin Huidong Qi Qingshan Chen Zhanguo Zhang Hongwei Jiang Rongsheng Zhu Zhenbang Hu Xiaoxia Wu Candong Li Yong Zhang Chunyan Liu Guohua Hu Dawei Xin Zhaoming Qi 《Plant Breeding》2017,136(5):688-698
Plant height is closely related to seed yield of soybean. The goal of this study was to identify important loci affecting soybean plant height using meta‐analysis based on a reference physical map. Plant height related to QTLs was mapped across eight years with a RIL population by WinQTLCart v2.5. 182 QTLs related to plant height of soybean from database and our research were collected, and each QTL was projected onto the soybean physical map by software BioMercator v2.1. The confidence interval of meta‐QTL ranged from 0.09 to 5.07 Mb, and the mean phenotypic variance ranged from 4.9% to 73.0%. Furthermore, 4,259 candidate genes were located in these consensus QTLs, and 40 of them were involved in the plant growth and stem elongation and annotated as plant hormone signal transduction (pathway ID ko04075) in KEGG pathway. These results would lay a foundation for fine mapping of QTLs/genes related to plant height and marker‐assisted selection for breeding in soybean. 相似文献
19.
基于NC III和TTC设计的胚乳性状QTL区间作图方法 总被引:1,自引:1,他引:0
根据三倍体胚乳性状的遗传模型, 提出基于NC III以及TTC两种遗传设计的胚乳性状QTL作图新方法, 并通过计算机模拟数据, 对该方法的可行性和有效性进行了分析验证。模拟研究供试因素包括QTL遗传力、F2群体植株数和每家系混合样品测定的胚乳数。考察指标包括QTL的统计功效以及QTL位置和效应估计的准确度与精确度。结果表明, 2种设计均有较高的QTL统计功效, 在供试的大多数处理中, 即使QTL的遗传力只有5%, 其被发现能力也可达100%。两种设计均可有效区分胚乳QTL的各种遗传效应。基于TTC设计的胚乳QTL作图方法, 在QTL的统计功效、位置估计和效应估计上, 均优于NC III设计, 虽然这一优势随着QTL遗传力的提高以及样本容量的增大而有降低的趋势。 相似文献
20.
不同密度下玉米穗部性状的QTL分析 总被引:2,自引:0,他引:2
为研究玉米穗部性状对不同种植密度的遗传响应,以郑58和HD568为亲本构建的220个重组自交系群体为材料,于2014年春、2014年冬及2015年春分别在北京和海南进行3个种植密度的田间试验,调查玉米穗长、穗粗、穗行数和行粒数等表型性状。利用SAS软件计算穗部性状的最优线性无偏估计值(BLUP),并采用完备区间作图法进行QTL定位。结果表明,在3个种植密度下共检测到42个QTL,单个QTL可解释4.20%~14.07%的表型变异。3个种植密度下同时检测到位于第2染色体上控制穗行数的QTL。2个种植密度下同时检测到4个与穗粗、穗行数和行粒数有关的QTL,其中第4染色体上1个与穗行数有关的主效QTL,在低、中种植密度下可分别解释表型变异的10.88%和14.07%。此外,在第2、4和9染色体上检测到3个同时调控不同穗部性状的QTL。研究结果表明玉米穗部性状在不同种植密度下的遗传调控发生变化,在不同密度下共同检测到的稳定QTL可应用于精细定位或开发玉米耐密性分子标记用于辅助育种。 相似文献