Genetic Analysis and Preliminary Mapping of a Highly Male-Sterile Gene in Foxtail Millet(Setaria italica L.Beauv.) Using SSR Markers

Breeding of male-sterile lines has become the mainstream for the heterosis utilization in foxtail millet,but the genetic basis of most male-sterile lines used for the hybrid is still an area to be elucidated.In this study,a highly male-sterile line Gao146A was investigated.Genetic analysis indicated that the highly male-sterile phenotype was controlled by a single recessive gene a single recessive gene.Using F 2 population derived from cross Gao146A/K103,one gene controlling the highly male- sterility,tentatively named as ms1,which linked to SSR marker b234 with genetic distance of 16.7 cM,was mapped on the chromosome VI.These results not only laid the foundation for fine mapping of this highly male-sterile gene,but also helped to accelerate the improvement of highly male-sterile lines by using molecular marker assisted breeding method.

Rice molecular markers and genetic mapping:Current status and prospects

Dramatic changes in climatic conditions that supplement the biotic and abiotic stresses pose severe threat to the sustainable rice production and have made it a difficult task for rice molecular breeders to enhance production and productivity under these stress factors. The main focus of rice molecular breeders is to understand the fundamentals of molecular pathways involved in complex agronomic traits to increase the yield. The availability of complete rice genome sequence and recent improvements in rice genomics research has made it possible to detect and map accurately a large number of genes by using linkage to DNA markers. Linkage mapping is an effective approach to identify the genetic markers which are co-segregating with target traits within the family. The ideas of genetic diversity, quantitative trait locus（QTL） mapping, and marker-assisted selection（MAS） are evolving into more efficient concepts of linkage disequilibrium（LD） also called association mapping and genomic selection（GS）, respectively. The use of cost-effective DNA markers derived from the fine mapped position of the genes for important agronomic traits will provide opportunities for breeders to develop high-yielding, stress-resistant, and better quality rice cultivars. Here we focus on the progress of molecular marker technologies, their application in genetic mapping and evolution of association mapping techniques in rice.

Construction of a Genetic Map and Mapping Quantitative Trait Loci for Salt Tolerance During the Vegetative Stage in Tomato by SSR Markers

Quantitative trait loci （QTLs） contributing to salt tolerance during the vegetative stage in tomato were investigated. A moderately salt-sensitive Lycopersicon esculentum Mill.‘XF 98-7’ was hybridized with a salt-tolerant Lycopersicon pimpinellifolium accession LA2184, and F2 and F3 populations were developed. The F2 population was used for SSR mapping and the F3 families were evaluated for salt tolerance in solution cultures containing 1% NaCl. A LOD score threshold of 2.0 was chosen to identify putative QTLs and to estimate their additive effect and phenotypic variation. Two genomic regions （LEtat003-SSR139, SSR119-SSR17） were detected on chromosome 4 beating significant QTLs for salt tolerance, respectively accounted for 6.03% and 8.01% of the phenotypic variation. The QTL in the marker interval of LEtat003-SSR139 showed significant negative effects, while the other QTL in the marker interval of SSR119-SSR17 showed significant positive effects. The identification of genomic locations with both positive and negative effects on this trait suggests the likelihood of recovering transgressive segregants in progeny derived from these parental lines. Results and its application in developing salt-tolerant tomatoes as molecular markers are discussed in this paper.

Mapping QTLs Affecting Economic Traits on BTA3 in Chinese Holstein with Microsatellite Markers

It had been demonstrated that the strong and highly significant quantitative trait locus（QTL） can affect protein percentage on Bos Taurus Autosome 3（BTA3） at the position 52 cM, near the microsatellite DIK4353, with the 95% confidence interval spanning from 25 to 57 cM in Chinese Holstein population using QTL-express, MQREML, and GRIDQTL softwares. This study herein focused on such region of fine mapping QTLs for milk production and functional traits with 16 microsatellite markers with coverage of 33 cM between the markers BMS2904 and MB099 on BTA3 in a daughter-designed Chinese Holstein population. A total of 1 298 Holstein cows and 7 sires were genotyped for 16 microsatellites with ABI 3700 DNA sequencer. The variance components QTL linkage analysis（LA） and linkage-disequilibrium（LD） analysis（LA/LD） was performed to map QTLs for 7 traits, i.e., 305-d milk yield, fat yield, protein yield, fat percentage, protein percentage, somatic cell score and persistency of milk yield. Four strong and highly significant QTLs were detected for fat yield, fat percentage, protein percentage and somatic cell score at the position 40, 30, 27 and 26 cM, respectively. Two minor QTLs for milk yield and persistency of milk yield were identified at 42 and 46 cM, respectively. These findings provided a general idea for the fine mapping of the causal mutation for milk production and functional traits on BTA3 in the future.

Genome Maps, Genetic Diversity and Marker-Assisted Selection for Soybean Improvement

Soybean [Glycine max (L.) Merr.] is a major legume used for human and livestock consumption. It has protein quality and oil contents that closely meet the dietary requirements for both humans and animals (Lusas, 2004).

Detecting mislabeling and identifying unique progeny in Acacia mapping population using SNP markers

Acacia hybrids offer a great potential for paper industry in Southeast Asia due to their fast growth and ability to grow on abandoned or marginal lands. Breeding Acacia hybrids with desirable traits can be achieved through marker assisted selection(MAS) breeding. To develop a MAS program requires development of linkage maps and QTL analysis. Two mapping populations were developed through interspecific hybridization for linkage mapping and QTL analysis. All seeds per pod were cultured initially to improve hybrid yield as quality and density of linkage mapping is affected by the size of the mapping population. Progenies from two mapping populations were field planted for phenotypic and genotypic evaluation at three locations in Malaysia,(1) Forest Research Institute Malaysia field station at Segamat, Johor,(2) Borneo Tree Seeds and Seedlings Supplies Sdn, Bhd.(BTS) field trial site at Bintulu, Sarawak, and(3) Asiaprima RCF field trial site at Lancang, Pahang. During field planting, mislabeling was reported at Segamat, Johor, and a similar problem was suspected for Bintulu, Sarawak. Early screening with two isozymes effectively selected hybrid progenies, and these hybrids were subsequently further confirmed by using species-specific SNPs. During field planting, clonal mislabeling was reported and later confirmed by using a small set of STMS markers. A large set of SNPs were also used to screen all ramets in both populations. A total of 65.36% mislabeled ramets were encountered in the wood density population and 60.34% in the fibre length mapping population. No interpopulation pollen contamination was detected because all ramets found their match within the same population in question.However, mislabeling was detected among ramets of the same population. Mislabeled individuals were identified and grouped as they originated from 93 pods for wood density and 53 pods for fibre length mapping populations.On average 2 meiotically unique seeds per pod(179 seeds/93 pods) for wood density and 3 meiotically unique seeds per pod(174 seeds/53 pods) for fibre length mapping population were found. A single step statistical method was used to evaluate the most informative set of SNPs that could subsequently be used for routine checks for mislabeling in multi-location field trials and for labelling superior clones to protect breeder’s rights. A preliminary set of SNPs with a high degree of informativeness was selected for the mislabeling analysis in conjunction with an assignment test. Two subsets were successfully identified,i.e., 51 SNPs for wood density and 64 SNPs for fibre length mapping populations to identify all mislabeled ramets which had been previously identified. Mislabeling seems to be a common problem due to the complexity involved in the production of mapping populations. Therefore, checking for mislabeling is imperative for breeding activities and for analyses such as linkage mapping in which a correlation between genotypic and phenotypic data is determined.

Constructing Molecular Marker Linkage Maps of Chromosome 14Sh and 22Sh and QTL Mapping for Major Traits by Use of Substitution Lines of Gossypium hirsutum L.

CSB14Sh,which is isogenic for its recurrent parent TM-1 except for chromosome 14 short arm,was crossed with TM-1,and the F2 population was produced.A total of 3800 SSR primer pairs covering the whole genome were used to screen polymorphism among two parents,TM-1 and CSB14Sh,

Genome Mapping to Enhance Efficient Marker-Assisted Selection and Breeding of the Oil Palm (<i>Elaeis guineensis</i>Jacq.)

The oil palm (Elaeis guineensis Jacq.) is one of the major cultivated crops among the economically important palm species. It is cultivated mainly for its edible oil. For a perennial crop like oil palm, the use of Marker Assisted Selection (MAS) techniques helps to reduce the breeding cycle and improve the economic products. Genetic and physical maps are important for sequencing experiments since they show the exact positions of genes and other distinctive features in the chromosomal DNA. This review focuses on the role of genome mapping in oil palm breeding. It assesses the role of genome mapping in oil palm breeding and discusses the major factors affecting such mapping. Generating a high-density map governed by several factors, for instance, marker type, marker density, number of mapped population, and software used are the major issues treated. The general conclusion is that genome mapping is pivotal in the construction of a genetic linkage map. It helps to detect QTL and identify genes that control quantitative traits in oil palm. In perspective, the use of high-density molecular markers with a large number of markers, a large number mapping population, and up-to-date software is necessary for oil palm genome mapping.

QTL Mapping for Fiber Quality Traits Based on a Dense Genetic Linkage Map with SSR,TRAP,SRAP and AFLP Markers in Cultivated Tetraploid Cotton

Cotton is one of the most important economic crops in the world,and it provides natural fiber for the textile industry.With the advancement of the textile technology and increased consumption demands on cotton fiber,both cotton yield and quality should be enhanced.However,cotton yield

玉米籽粒皱缩突变体sh2019的分子标记初步定位

玉米籽粒作为光合产物的重要贮藏器官,其发育直接影响百粒重和产量。本研究以玉米籽粒皱缩突变体sh2019、野生型玉米自交系Mo17及两者的杂交F_(2)代为材料,进行表型分析、遗传分析和分子标记初步定位。结果表明,突变体sh2019籽粒干瘪,种皮皱缩,百粒重和出苗率均比野生型显著下降,分别下降43.55%和69.56%。遗传分析发现突变体sh2019的籽粒皱缩表型受1对隐性核基因控制。利用F_(2)分离群体借助集团分离分析法进行的分子标记定位结果表明,sh2019基因被定位于玉米3号染色体上约30.18 Mb的物理距离内。本研究结果可为开展sh2019基因的精细定位及分子标记辅助育种奠定基础。

利用龙稻5号/中优早8号RIL群体定位粒形QTL

【目的】粒形是决定稻米产量、品质和商品价值的重要数量性状之一。本研究旨在利用水稻重组自交系群体鉴定控制粒形的QTL,为水稻粒形基因的挖掘和长粒形粳稻育种应用奠定基础。【方法】以短圆粒形的粳型超级稻品种龙稻5号(LD5)为母本和细长粒形的早熟籼稻品种中优早8号(ZYZ8)为父本构建包含176个家系的重组自交系群体测定粒长、粒宽、长宽比和粒厚等粒形性状,分析粒形性状间的关系并进行QTL定位和比较分析。【结果】利用区间作图法共检测到8个粒形QTL,分布在3、5、6、7和11号染色体上,表型贡献率范围为4.69%~18.89%,LOD值范围为2.52~8.74。这8个QTL包括3个粒长QTL qGL3、qGL7和qGL11,2个粒宽QTL qGW3和qGW5,2个粒厚QTL qGT3和qGT6,1个长宽比QTL qLWR3。其中,qGL3、qGL7、qGW3、qGW5和qLWR3可以在3个年份稳定检测到。利用多环境联合分析共检测到14个粒形QTL,包括qGL2、qGL3、qGL7和qGL11共4个粒长QTL;qGW3和qGW5共2个粒宽QTL;qGT3、qGT5和qGT6共3个粒厚QTL;qLWR3a、qLWR3b、qLWR5、qLWR7和qLWR11共5个长宽比QTL,分布在2、3、5、6、7和11号染色体上,表型贡献率范围为2.28%~15.78%,LOD值范围为4.20~20.90。与已克隆的粒形基因进行染色体位置比较发现,qGL3/qLWR3区间包含已克隆的GL3.1;qGW5区间包含已克隆的GW5;qLWR3b/qGT3区间包含已克隆的TGW3。【结论】利用区间作图法和多环境联合分析的方法从龙稻5号和中优早8号的重组自交系群体中共鉴定了14个粒形QTL,其中8个QTL是两种方法重复检测到的。这些QTL定位区间内包含已克隆的GL3.1、TGW3和GW5等粒形基因。

小麦农家品种武都白茧儿抗条锈病基因遗传定位

小麦条锈病是由条形柄锈菌(Pst,Puccinia striiformis f.sp.tritici)引起的一种全球性重要真菌病害,严重影响小麦生产安全。发掘抗病基因,培育抗病品种是防治条锈病最为经济有效和安全的方法。武都白茧儿是甘肃陇南小麦农家品种,在整个生育期都表现出中到高抗条锈病,但其抗性基因尚不明晰。为解析武都白茧儿的条锈病抗性遗传机制,本研究利用抗病亲本武都白茧儿和感病亲本辉县红配制杂交组合,利用条锈菌生理小种V31/lab对其F2和F2:3群体进行苗期接种鉴定,结合混池测序和连锁分析定位抗性基因。结果表明,武都白茧儿对V31/lab抗性由一对隐性基因控制,暂命名为yrWUD。根据F2群体的混池外显子捕获测序和混池转录组测序结果,开发了12个高通量的KASP标记;通过连锁分析,将yrWUD定位在4AL染色体的2.6 cM遗传区间内,与侧翼标记4AL36和4AL11的遗传距离分别为0.9 cM和1.7 cM,对应13 Mb的物理区间(4A:610.26~623.35 Mb),其中3个抗病相关基因TraesCS4A02G329100、TraesCS4A02G330000和TraesCS4A02G330100在抗感池中差异表达,推测为yrWUD的候选基因。本研究定位了武都白茧儿的抗性基因yrWUD,用KASP标记4AL36在自然群体中检测了该基因的等位基因,研究结果为小麦抗条锈病育种提供了新基因和分子标记。

玉米花丝花青苷显色性状的QTL定位

玉米花丝颜色是玉米特异性和一致性判定的重要农艺性状。为解析玉米花丝花青苷显色性状的遗传机制,以绿色花丝自交系WL134和紫色花丝自交系D7杂交构建的213份DH系群体为研究材料,在2022年和2023年2 a环境下分别进行QTL定位分析。结果表明,花丝花青苷显色性状在不同家系、不同年份之间均存在显著差异,且广义遗传力为0.864。2 a的花丝颜色数据共检测到9个QTLs,分布于玉米的第2,3,5,6,8,9号染色体上,单个QTL的表型贡献率在4.83%~9.26%。在第5染色体上定位到一个稳定的在2 a数据中可重复检测到的位点qSC5,位于19.15~19.80 Mb,2022年检测的LOD值为4.65,贡献率7.22%,2023年检测的LOD值为5.76,贡献率7.17%,为主效QTL位点。与前人的研究比对发现,该位点为调控花丝花青苷显色的新位点。基于qSC5两侧的SNP标记,DH群体中极端紫色花丝家系中90.91%的基因型为CCCC,而绿色花丝家系中该基因型仅占44.00%。该标记与玉米花丝颜色显著相关,可能与调控花丝花青苷显色性状的关键基因连锁。

小麦Hussar衍生品系抗叶锈病基因分析

以抗叶锈病小麦品系Hussar的衍生品系H103P为抗病亲本,郑州5389为感病亲本杂交得到的234个F4家系群体为材料,进行抗叶锈病基因定位分析。利用带有不同毒力的16个叶锈菌生理小种进行苗期抗叶锈性鉴定,结果表明周麦22及携带Lr13、Lr23和Lr16单基因的载体品种对16个叶锈菌生理小种均表现感病,H103P对除PHKT外的所有小种表现抗病,表明H103P抗叶锈性与携带Lr13、Lr23和Lr16单基因的载体品种不同。利用5种强毒力混合菌种(THTT、PHTT^(②)、FHJS^(②)、PHKS、PHTT^(①))进行田间抗叶锈性鉴定,结果表明H103P、SAAR、周麦22以及Lr13载体品种田间表现均为高抗,234个F4家系群体抗性呈连续性分布,在田间表现出良好的成株期抗性。抗叶锈病基因定位分析结果表明,在小麦品系H103P中定位到1个位于小麦2BS染色体上的抗叶锈病基因,暂命名为LrHu。利用含有Lr13的特异性引物对H103P和郑州5389的扩增产物进行特异性酶切,结果发现小麦品系H103P含有抗叶锈病基因Lr13。小麦抗叶锈病基因LrHu与Lr13的关系还需进一步研究验证。

小麦成株期抗叶锈病基因Lr12精细定位

成株期抗叶锈病基因Lr12在生产上具有良好抗性,为Lr12进行精细定位并开发可靠的分子标记,以感病材料Thatcher和含Lr12抗性基因的近等基因系RL6011为亲本杂交产生F_(1),进一步自交产生F_(2)单株和F_(2∶3)家系。在田间利用5种强毒力叶锈菌混合小种(PHTT、THKS、THTT、PHTS和PHKS)接种F_(2)单株和F_(2∶3)家系进行成株抗叶锈性鉴定和抗性遗传分析。随后利用16K液相芯片对F_(2)的10个抗病单株和10个感病单株进行基因分型,获得与Lr12紧密连锁的SNP位点,确定抗病基因所在的染色体物理区间,开发SSR分子标记并构建遗传连锁图谱。结果表明,对RL6011(Lr12)/Thatcher的3494个F_(2)单株进行抗叶锈性鉴定,抗病单株与感病单株之间的分离比符合3∶1(χ^(2)_(3∶1)=0.14;P=0.71)。对685个F_(2∶3)家系进行抗叶锈性鉴定,抗病单株、抗病杂合单株与感病单株之间的分离比符合1∶2∶1(χ^(2)_(1∶2∶1)=2.01;P=0.37),表明Lr12为显性基因且群体分离符合单基因遗传规律。通过遗传连锁图谱分析成株期抗叶锈病基因Lr12基因位于SSR分子标记YK12817和YK12928之间,遗传区间为0.38 cM,对应中国春参考基因组(IWGSC.Ref.V1.0)中4BL染色体579.44~581.53 Mb物理范围内共2.09 Mb的物理区间。上述结果为预测候选基因提供了确定的依据。

关于Mapmaker/Exp遗传作图中标记分群和排序操作技术的讨论

Mapmaker/Exp(3.0)是国内外广泛使用的遗传连锁数据分析软件,在分子标记数量大时(多于500个)往往出现所绘制连锁图谱图距偏大的现象。本文从标记分群和标记排序两个遗传作图环节分析原因并概括出以下两个实施要点:(1)标记分群不应强求同一LOD值,对特殊的连锁群可试用不同LOD值;(2)在标记排序时,一次order命令后用ripple命令反复梳理有时并不能获得最佳排列顺序,而应多次使用order,每次order后用ripple反复梳理,经反复比较才能得出最佳排列顺序,必要时还须结合人工调整。通过大豆遗传作图实例比较了软件推荐思路2的通常用法和作者建议的新用法所构建的遗传图谱及相应QTL定位的差异,认为新用法具有更好的效果。

莴笋红叶基因图位克隆及分子标记开发

【目的】研究莴笋叶色变异的遗传基础,加速莴笋新品种育种进程,提高育种效率。【方法】通过构建红叶和绿叶莴笋杂交群体,分析遗传规律,利用混池分组分析法(BSA-seq)和图位克隆法精细定位并克隆了莴笋红叶基因Lactuca sativa Red Leaf 1(LsRL1),根据变异位点设计了分子标记用于红叶莴笋分子标记辅助育种。【结果】遗传分析结果显示F2分离群体中红叶个体与绿叶个体的分离比为3∶1,说明研究中莴笋叶色表型受一个基因控制,且红叶相对于绿叶为显性性状。混池分组分析法(BSA-seq)将莴笋叶色基因LsRL1初步定位在莴笋第5染色体336.00 Mb到339.64 Mb的范围内。利用图位克隆的方法进一步将LsRL1基因的范围缩小至2个Indel分子标记ls06和ls12之间的85.17 kb区间内,这一区间内包含2个基因LOC111892298和LOC111892911。亲本间差异位点分析将LsRL1的候选基因确定为LOC111892911,该基因在拟南芥中的同源基因编码一个bHLH转录因子,参与花青素合成途径的调控。【结论】基于LsRL1基因在2个亲本间的插入缺失变异,我们开发了一个可用于红叶莴笋分子标记辅助育种的Indel标记,以加速红叶莴笋的育种进程。

波斯小麦Cypa35-3成株期抗白粉病基因定位

源自苏联的波斯小麦Cypa35-3对陕西关中地区白粉菌优势小种表现为成株期高抗白粉病。为明确Cypa35-3抗白粉病基因所在染色体位置及其抗白粉病基因的遗传规律,利用Cypa35-3与高感白粉病的加拿大二粒小麦Flavescens进行杂交,在成株期自然发病条件下对亲本及其杂交F_(1)、F_(2)、F_(2)∶3群体进行白粉病抗性评价与遗传分析;选用分布于A、B染色体组14对染色体上共计601对SSR标记,利用分离群体分组分析法(BSA)对Cypa35-3的F_(2)群体进行多态性标记筛选。结果表明,Cypa35-3的成株期白粉病抗性受1对显性基因控制,暂命名为PmCypa35-3。通过群体筛选,获得4对位于1B染色体上的SSR标记,分别为Xbarc81、Xcfd48、Xbarc61、Xbarc302,其中Xbarc81、Xcfd48位于PmCypa35-3两侧,遗传距离分别为25.2 cM、8.6 cM。由此将成株期抗白粉病基因PmCypa35-3初步定位于1B染色体。通过与1B染色体上及波斯小麦中正式命名的抗白粉病基因的基因来源和标记位置进行对比,发现PmCypa35-3与它们均不相同,推测PmCypa35-3可能是一个新的小麦成株期抗白粉病基因,可作为小麦抗病育种的新抗源。

两个RIL群体中小麦籽粒品质相关性状QTL定位及KASP标记开发

本研究利用小麦55K SNP(55K single-nucleotide polymorphism)芯片和DArT(diversity array technology)标记对Avocet/Chilero和Avocet/Huites构建的两个F6重组自交系群体(recombinant inbred line,RIL)进行了小麦籽粒蛋白质含量(grain protein content,GPC)、湿面筋含量(wet gluten content,WGC)和沉降值(sedimentation value,SV)的QTL(quantitative trait loci)定位。共鉴定到68个与小麦籽粒蛋白质含量、湿面筋含量和沉降值相关的QTL,表型贡献率为3.60%~22.53%,其中,位于3A(2)、4D、5D(2)、6A(8)和7B染色体上的14个QTL可在多环境下被重复检测到。此外,在3A、3D、4B、5D、6A(2)和7B染色体上检测到7个QTL簇,位于3AS染色体9.32~60.01 Mb和6AS染色体38.47~82.95 Mb的稳定QTL簇C3A和C6A.2,同时与小麦籽粒蛋白质含量、湿面筋含量和沉降值显著相关,分别解释了6.55%~14.21%和3.83%~22.53%的表型变异。同时,在2个QTL簇中筛选到16个可能与籽粒蛋白质含量相关的候选基因,并根据候选基因开发了可供育种利用的KASP标记CGPC-6A-KASP-1和CGPC-6A-KASP-2。本研究为小麦籽粒品质相关性状的遗传改良提供了新的QTL位点和KASP标记,为分子标记辅助育种提供依据与参考。

基于MAPGIS的军事标图系统的设计

军事领域是一个非常特殊的行业 ,信息的安全性和空间数据的多样性是应用开发的重要问题 .在全球信息化日趋高速发展和逐步成熟的今天 ,军队信息化建设也必须与GIS技术紧密结合 ,跟上时代前进的步伐 .较系统地研究了GIS技术在军事标图绘制中的应用和集成问题 ,并提供了相应的理论方法和实现系统 .在此基础上介绍了以MAPGIS为开发平台的军事标绘系统的实用功能和特点 .首先分析了军事信息系统对地理信息数据的要求 ,并且评述了相关领域的研究现状 .然后较为系统地介绍了军事标图系统的总体设计 ,根据军事标绘对象的数据特征 ,设计符合要求的应用系统模型并提出了面向对象和无缝交互工具等的设计思想 .对军标对象数据模型和操作模型进行了详细地阐述和说明 ,并将这些模型在系统中进行了实现 .最后介绍了军事标图系统的主要模块和功能 ,探讨了今后GIS研究和发展的方向 .