An Integrated Genetic,Physical and Transcript Map of Homoeologous Chromosomes 12 and 26 in Upland Cotton(Gossypium hirsutum L.)

While Upland cotton(Gossypium hirsutum L.) represents 95% of the world production,its genetic improvement is hindered by the shortage of effective genomic tools and resources.The

Biochemical Genetic Mechanism and QTLs of Early Maturing without Yield Loss in Short-season Upland Cotton(Gossypium hirsutum L.)

The short season cotton(SSC) was important Upland plant ecotype(Gossypium hirsutum L.).The growth of SSC was very short that is 105 ～ 110 days(after planting). SSC could increase

QTL mapping for fiber quality and yieldrelated traits across multiple generations in segregating population of CCRI 70

Background:Cotton is a significant economic crop that plays an indispensable role in many domains.Gossypium hirsutum L.is the most important fiber crop worldwide and contributes to more than 95%of global cotto n production.Identifying stable quantitative trait locus(QTLs)controlling fiber quality and yield related traits are necessary prerequisites for marker-assisted selection(MAS).Results:A genetic linkage map was constructed with 312 simple sequence repeat(SSR)loci and 35 linkage groups using JoinMap 4.0;the map spanned 1 929.9 cM,with an average interval between two markers of 6.19 cM,and covered approximately 43.37%of the cotton genome.A total of 74 QTLs controlling fiber quality and 41 QTLs controlling yield-related traits were identified in 4 segregating generations.These QTLs were distributed across 20 chromosomes and collectively explained 1.01%?27.80%of the observed phenotypic variations.In particular,35 stable QTLs could be identified in multiple generations,25 common QTLs were con sistent with those in previous studies,and 15 QTL clusters were found in 11 chromosome segments.Conclusion:These studies provide a theoretical basis for improving cotton yield and fiber quality for molecular marker-assisted selection.

Construction of a linkage map and QTL mapping for fiber quality traits in upland cotton (Gossypium hirsutum L.)

With the development in spinning technology, the improvement of cotton fiber quality is becoming more and more important. The main objective of this research was to construct a high-density genetic linkage map to facilitate marker assisted selection for fiber quality traits in upland cotton (Gossypium hirsutum L.). A genetic linkage map comprising 421 loci and covering 3814.3 cM, accounting for approximately 73.35% of the cotton genome, was constructed using an F2 population derived from cross GX1135 (P 1 )×GX100-2 (P 2 ). Forty-four of 49 linkage groups were assigned to the 26 chromosomes. Fiber quality traits were investigated in F2 population sampled from individuals, and in F2:3 , and F2:4 generations sampled by lines from two sites and one respectively, and each followed a randomized complete block design with two replications. Thirty-nine quantitative trait loci were detected for five fiber quality traits with data from single environments (separate analysis each): 12 for fiber length, five for fiber uniformity, nine for fiber strength, seven for fiber elongation, and six for fiber micronaire, whereas 15 QTLs were found in combined analysis (data from means of different environments in F2:3 generation). Among these QTLs, qFL-chr5-2 and qFL-chr14-2 for fiber length were detected simultaneously in three generations (four environments) and verified further by combined analysis, and these QTLs should be useful for marker assisted selection to improve fiber quality in upland cotton.

Development of glyphosate-tolerant transgenic cotton plants harboring the G2-aroA gene

Given that glyphosate weed control is an effective strategy to reduce costs and improve economic outcomes of agricultural production in China,the development of glyphosate-resistant cotton holds great promise.Using an Agrobacterium-mediated transformation method,a new G2-aroA gene that encodes 5-enolpyruvylshikimate-3-phosphate synthase（EPSPS）was transformed into cotton cultivar K312.The transgenic cotton plants were regenerated from a callus tissue culture via kanamycin selection.Ten regenerated cotton plants were obtained and allowed to flower normally to produce fruit.The results from polymerase chain reaction（PCR）and Southern and Western blot analyses indicated that the target gene was integrated into the cotton chromosome and was expressed effectively at the protein level.The glyphosate tolerance analysis showed that the transgenic cotton had a high resistance to glyphosate.Further,even cotton treated with 45.0 mmol L^–1 of glyphosate was able to slowly grow,bloom and seed.The transgenic cotton may be used for cotton breeding research of glyphosate-tolerant cotton.

Genomic insight into the divergence and adaptive potential of a forgotten landrace G.hirsutum L.purpurascens

Wild progenitors are an excellent source for strengthening the genetic basis and accumulation of desirable variation lost because of directional selection and adaptation in modern cultivars.Here,we re-evaluate a landrace of Gossypium hirsutum,formerly known as Gossypium purpurascens.Our study seeks to understand the genomic structure,variation,and breeding potential of this landrace,providing potential insights into the biogeographic history and genomic changes likely associated with domestication.A core set of accessions,including current varieties,obsolete accessions,G.purpurascens,and other geographical landraces,are subjected to genotyping along with multilocation phenotyping.Population fixation statistics suggests a marked differentiation between G.purpurascens and three other groups,emphasizing the divergent genomic behavior of G.purpurascens.Phylogenetic analysis establishes the primitive nature of G.purpurascens,identifying it as a vital source of functional variation,the inclusion of which in the upland cotton(cultivated G.hirsutum)gene pool may broaden the genetic basis of modern cultivars.Genome-wide association results indicate multiple loci associated with domestication regions corresponding to flowering and fiber quality.Moreover,the conserved nature of G.purpurascens can also provide insights into the evolutionary process of G.hirsutum.

陆地棉种子性状直接效应和母体效应的遗传分析

采用二倍体种子遗传模型及其分析方法,分析了陆地棉（Gossypium hirsutum L.) 5个品种及其配制的F_1、F_2和正反回交一代（BC_1;、BC_2、RBC_1和RBC_2）世代籽指、种仁率、容重和油分4个种子性状的直接效应、母体效应和细胞质效应。分析结果表明,4个棉子性状的遗传均以母体效应为主,种子直接遗传效应作用较小。各性状的直接效应与母体效应的协方差不显著。通过母体植株的遗传表现对这些性状选择更为有效。可以根据籽指小和容重大等性状母体植株的遗传表现间接选择高油分材料。母体加性效应大的亲本,其杂种后代的母体加性效应总值一般也较大。

棉花优异纤维品质性状的双列杂交分析(英文)

利用 5个具有不同纤维品质性状的品种 (系 )配制完全双列杂交组合 2 0个 ,通过亲本和F1的 2年随机区组试验 ,结果为除纤维整齐度受环境等因素影响较大 ,其余性状主要受遗传因素控制 ;在与环境的互作中 ,纤维强度和长度的互作效应小 ,麦克隆值的加性和母体效应及伸长率的显性效应与环境的互作较大 ,均达到了显著水平遗传主效中 ,所有的研究性状不存在母体效应 ,以加性为主 ;强度与长度加性遗传率高 ,分别占 77 6 %和 73 2 % ;麦克隆值的加性效应占 4 5 2 % ,显性效应所占的比例在纤维性状中最高 ,为 11 5 %。纤维品质性状的群体平均优势仅麦克隆值的较高 (3 2 % ) ,达到了显著水平 ,其余性状的优势仅为 - 0 4 %～ 0 7%。纤维品质性状的遗传结果与杂种优势一致。在杂种优势利用时 ,可以通过双亲平均值的高低来预测F1的纤维品质表现。纤维强度、长度和细度的加性遗传率高 。

陆地棉重组自交系群体纤维品质及产量性状遗传变异分析

以陆地棉优质品系0-153和大面积推广的双价转基因抗虫棉品系sGK9708为亲本构建了含有196个F6:8家系的重组自交系群体。在4个环境中,纤维长度、纤维强度、麦克隆值、伸长率、整齐度指数、单株结铃数、铃重、衣分、子指、单株子棉产量及单株皮棉产量等性状均呈正态分布,且存在双向超亲分离。多环境下变异分析表明,各性状家系间及环境间存在极显著差异。除纤维伸长率外,其余各纤维品质及产量性状都具有较高的遗传力,在0.75以上。共有6个家系在纤维长度、细度和强度性状上均超过高亲,可作为优质纤维种质。相关分析显示,有些家系可能打破了纤维品质和产量性状间的负相关。通过聚类分析得出,该群体各系分在了不同的组,表明存在着一定的遗传差异。该群体是进行优异纤维品质相关基础研究的良好材料。

陆地棉显性无腺体指示性状的杂种优势利用研究

运用陆地棉显性无腺体系与2个有腺体系杂交，不去雄人工辅助授粉其真杂交种率为52．4％，与不育系授粉，其真杂种率为99．3％；配制的组合均有不同程度增产，而且纤维品质基本符合育种攻关要求；显性无腺体性状．棉花一出苗，通过下胚轴，即可识别，结合棉花育苗移栽和间苗的特点，淘汰假杂种的工作易于进行；表明了显性无腺体性状是一个优良的指示性状，可以利用。

陆地棉纤维品质和产量性状的遗传分析

两个陆地棉型纤维品质优异品系９４１７３和９４２５０分别与推广品种中棉所１２号、鲁棉１１号、中棉所１６号和鲁棉１０号杂交，按方法２模式Ⅰ配成６×６共２１个组合。纤维长度、马克隆值、籽棉产量、单铃重和籽指的Ｇ．Ｃ．Ａ．效应达显著水平，除衣分率外，上述各性状Ｓ．Ｃ．Ａ．效应均达显著水平。其中纤维长度、马克隆值和籽指Ｇ．Ｃ．Ａ．方差／Ｓ．Ｃ．Ａ．方差比值较大，证明以加性效应为主。Ｇ．Ｃ．Ａ．估算结果表明，９４１７３和９４２５０是提高陆地棉品种纤维品质性状育种非常有价值的亲本，通过杂交可同时兼顾后代纤维长度、强度和细度的改良。通过Ｓ．Ｃ．Ａ．的估算认为，在某些组合Ｆ１会有杂种优势出现，而在系谱选择中应注意其干扰。在纤维长度、马克隆值、籽棉产量、单铃重、衣分率和籽指的遗传模式推导中，只有纤维长度和衣分率符合加性＋显性模式。纤维长度为部分显性，长绒基因既有隐性，也有显性，广义遗传力为７８１７％，狭义遗传力为６７４４％；衣分率广义遗传力和狭义遗传力分别只有２６０８％和２１１６％，高衣分率基因较多的表现为隐性。

陆地棉花粉柱头生活力研究

在1d内的6个不同时间分别给母本柱头授以自然花粉和冰箱保存花粉，镜检穿过花柱基部的花粉管数，田间调查成铃率，收获后考种单铃种子数、健籽率和子指等。结果表明，自然花粉以上午10：00授粉成铃率最高，雌蕊柱头10：00和16：00为最佳接受花粉时间。

高品质陆地棉蔗糖代谢关键酶活性对纤维品质形成的影响

以高品质陆地棉鲁324系(324)、渝棉1号(YM-1)和普通陆地棉鲁棉研18(L18)为材料,研究蔗糖代谢关键酶活性变化对纤维品质形成的影响。结果表明,高品质陆地棉叶片蔗糖磷酸合成酶(sucrose phosphate synthetase,SPS)活性高,蔗糖合成能力强,主茎叶和果枝叶蔗糖含量高,蔗糖供应能力强。Logistic方程模拟纤维素累积过程,高品质陆地棉纤维素进入快速累积期的时间晚,终止期延后,快速累积持续期长,累积速率平缓,最终纤维素含量高,纤维比强度高。在纤维发育前期,高品质陆地棉蔗糖贮存较多,为次生壁发育提供了充足的初始底物。高品质陆地棉蔗糖合成酶(sucrose synthetase,SS)活性高,降解蔗糖能力强,酶活性迅速增加时期与纤维素快速累积期相吻合;SPS活性在纤维素快速累积期终止前均明显高于普通陆地棉。叶片SPS活性和棉纤维中SS、SPS活性与纤维素累积及纤维品质形成有密切关系。

大丽轮枝菌毒素诱导表达陆地棉cDNA序列的克隆与定位

为获得陆地棉黄萎病抗性相关候选基因,利用棉花黄萎病菌大丽轮枝菌V991毒素粗提物诱导耐黄萎病陆地棉品种‘中棉12’应激基因的表达。在诱导幼根24h时间点提取总RNA,PCR法合成双链cDNA,应用抑制消减杂交技术[1],得到了差异表达的180个克隆。经反Northernblot筛选出15个受毒素粗提物诱导应激表达的阳性cDNA克隆,将其命名为Vdrg(responsegeneinducedbytoxinofVerticilliumdahliae)。本研究对所得阳性cDNA克隆进行了序列分析,并利用PimaS6与AcalaMaxxa海陆杂交四倍体棉花F2群体对Vdrg序列进行了棉花基因组定位。

陆地型长绒棉新种质主要经济性状基因效应分析

陆地型长绒棉亲本98301与高产亲本石远321杂交,P1、P2、F1、F2、B1和B26个世代的纤维长度(2.5%跨距)、纤维强度(束纤维拉力)、麦克隆值、单株籽棉产量、单株皮棉产量、衣分率、单株铃数、单铃重、籽指和青铃率10个性状平均数按MATHER和JINKS(1982)法进行联合尺度检测,随后根据6参数模型估算M、[D][、H][、I][、J]、[L]6种基因效应值,并删除显著性最小一值进行5参数估算,作符合性测验。结果表明,除纤维长度无自由度进行检验外,其余9个性状均符合“加性-显性-互作效应模式”,其中麦克隆值和籽指用较简单的“加性-显性模式”已能充分地描述其遗传性。3个纤维品质性状中,[D]和[H]均达极显著或显著水平。纤维长度的3种交互作用均极显著或显著,纤维强度的交互作用中只有[I]极显著,麦克隆值的[J]显著。在杂种优势理论值估算结果中,只有单铃重和籽指存在正向超高亲优势。据[L]与[H]值作用方向推断重复作用类型在交互作用方式中占主导。

ET-ISJ标记的开发及陆地棉遗传图谱构建

根据植物结构基因外显子拼接位点的保守序列,设计扩增外显子的ET-ISJ(exon targeted intron-exon splice junction)标记引物。利用1 280对ET-ISJ引物组合,对陆地棉品种渝棉1号和T586进行多态性筛选,获得69对多态性引物组合,占引物组合的5.4%。用多态性ET-ISJ引物组合检测(渝棉1号×T586)F2:7重组近交系群体,得到70个位点。以70个ET-ISJ标记位点与523个SSR、59个IT-ISJ、29个SRAP和8个形态标记进行连锁分析,构建的遗传连锁图谱包括59个连锁群和673个位点(68个ET-ISJ、510个SSR、58个IT-ISJ、29个SRAP和8个形态标记)。连锁图覆盖3 216.7 cM,约占棉花基因组的72.3%,标记间平均距离为4.8 cM。68个ET-ISJ标记分布于20条染色体。研究表明ET-ISJ标记多态性较高、稳定性好,可有效用于棉花与其他植物遗传连锁图谱构建。

高品质陆地棉铃-叶系统干物质质量的发育遗传研究

应用加性-显性发育遗传模型及条件与非条件的统计分析方法,对6个高品质陆地棉品种(系)及其30个F1组合的伏桃与对位果枝叶的干物质质量进行了研究。非条件方差分析表明,果枝叶质量在棉铃体积增大期主要受加性效应控制,内部充实期主要受显性效应控制;铃壳质量在不同发育时期均以加性效应为主;铃重在前中期主要受显性效应控制,后期以加性效应为主。条件遗传分析表明,影响果枝叶质量的净遗传效应在铃龄38 d至45 d达到高峰;控制铃壳质量的基因表达分别在铃龄17 d至24 d和铃龄38 d至45 d出现两个高峰;影响铃重性状的基因分别在铃龄17 d至24 d和铃龄31 d至38 d出现两个表达活跃的高峰,此后基因的表达量急剧下降。遗传相关分析表明不同发育时期的铃壳质量均与最终铃重成极显著的加性正相关。

陆海杂种棉花自然吐絮铃与霜后大铃的纤维品质差异比较分析

通过对两套材料(15个海岛棉及其陆海杂种F1与89个陆海杂种BC2F1群体株系)霜后大铃(未正常吐絮)与霜前自然吐絮铃纤维品质性状的分析,结果为除比强度和伸长率外,2003年的15个材料霜后大铃比正常吐絮铃的平均纤维长度短1.15mm、马克隆值降低1.00、整齐度减少2.16,差异都达到了极显著水平;除纤维长度外,2005年的89个群体株系霜后大铃比自然吐絮棉铃平均纤维比强度增加1.73cN/tex、马克隆值降低1.33、整齐度减少0.49、伸长率增加0.21,差异也都达到了极显著水平。霜后大铃与自然吐絮铃纤维品质均存在显著或极显著的正相关,不同材料霜后大铃纤维品质性状的变化趋势与自然吐絮铃的基本一致。这说明了霜后大铃对多数纤维品质性状具有显著的影响,特别是马克隆值和纤维整齐度。但是与自然吐絮棉铃一样,霜后大铃仍能基本反应材料间的纤维品质性状的遗传差异,这对陆海杂种棉花纤维品质遗传研究和育种选择意义重大。

新疆陆地棉高效体细胞胚胎发生系的培育及其遗传转化

为了筛选高频体细胞胚胎再生能力的棉花品种（系），提高农杆菌介导转化效率，本研究以新疆陆地棉03298品系经组织培养产生的三个不同世代的再生系03298R1、03298R2和03298R3为材料，分别进行农杆菌介导的遗传转化。在相同的培养体系下，03298再生系下胚轴和子叶外植体的分化率由5％（一代再生系03298R1）提高到10％-15％（二代再生系03298R2）再到23％～33％（三代再生系03298R3），表明连续组织培养定向筛选提高了03298再生系体细胞胚胎再生能力。PCR和southern杂交检测显示抗卡那霉素的再生植株成功整合了NPTII基因。本研究经组织培养筛选获得了高频体细胞再生能力的03298再生系，并建立了相应的高效遗传转化体系，为新疆陆地棉遗传改良提供了新受体材料及其配套的遗传转化体系。

利用四交群体构建陆地棉栽培品种间的SSR标记遗传图谱

作物遗传作图与QTL定位常应用在源于两自交系的单交群体上,是利用2个亲本之间的遗传多态信息;而育种实践中经常用到的四交群体却很少用于遗传作图。本研究将异交物种中F1分离群体的作图方法应用于常异花授粉作物棉花上,以4个陆地棉栽培品种泗棉3号、苏棉12、中4133和8891为亲本,构建陆地棉品种间四交作图群体泗棉3号/苏棉12//中4133/8891,利用JoinMap3.0构建了1张陆地棉栽培品种间的SSR标记遗传图谱。该图谱由56个连锁群组成,总长为2113.3cM,含有286个SSR多态位点,覆盖率达42.3%;单个连锁群的标记数2-24个,平均5.2个;长度为0.37-125cM,平均38.4cM;标记间的平均距离为7.4cM。这是目前报道的第1张覆盖率达40%的陆地棉栽培品种间的分子标记遗传图谱。