小菜蛾不同抗性品系及其杂交F_1代的生物适合度

构建了小菜蛾抗阿维菌素(A)、抗高效氯氰菊酯(B)和抗杀虫双(D)3个抗性品系及其6个杂交F1代(抗性品系分别两两杂交)以及1个敏感品系(S)的种群生命表,并计算了相对生物适合度。结果表明:A、B和D 3个抗性品系的相对生物适合度均比敏感品系S(生物适合度为1.0)低,分别为0.60、0.77和0.53;6个杂交F1代A♀+B♂、A♂+B♀、A♀+D♂、A♂+D♀、B♂+D♀和B♀+D♂的生物适合度分别为0.67、0.53、0.67、0.74、0.73和0.80,也比敏感品系的低,但和抗性品系的适合度相近或高于抗性品系。     

印度圆粒小麦抗条锈病新基因YrSph的遗传分析和SSR标记定位

 抗条锈病小麦新种质D31是以印度圆粒小麦（Triticum sphaerococcum Perc.）AS384与普通小麦品系94-3854杂交、回交选育而成的新品系。用中国小麦条锈病菌（Puccinia striiformis f.sp. stritici）流行生理小种条中32号对D31和Taichung29的杂交后代进行苗期及成株期抗条锈性遗传分析。结果表明,D31对生理小种条中32号表现为全生育期近免疫抗性反应,其抗性由1对隐性基因控制,暂命名为YrSph。利用BSA法对构建的F²遗传作图群体进行SSR标记分析。通过对400对微卫星引物的筛选和群体分析表明,抗性基因与 Xwmc149、Xwmc246、Xgwm372和Xwmc198 具有连锁关系,其中与 Xwmc246 标记连锁较近,遗传距离为8.8 cM。基因和标记之间的顺序为 Xwmc149-YrSph-Xwmc246-Xgwm372-Xwmc198 。根据作图结果,将D31所含的抗条锈病基因YrSph定位于2A短臂上。基于该基因的作图位置与系谱分析,认为该基因可能是1个新的抗条锈病基因。     

抗白粉病小麦——中间偃麦草双体异附加系的鉴定

对从中间偃麦草与普通小麦品种烟农15杂交后代(BC3F6)中选育的双体异附加系山农Line15的形态学、白粉病抗性、细胞学、基因组荧光原位杂交(G ISH)及R A PD进行鉴定分析。结果表明,它的主要形态性状介于双亲之间;白粉病抗性鉴定结果表明,山农Line15对白粉病高抗近免疫;根尖细胞染色体数目为2n=44,PM CMⅠ染色体构型为2n=22Ⅱ;以中间偃麦草总基因组D N A为探针的基因组荧光原位杂交(G ISH),结果表明,山农Line15是在小麦的遗传背景中附加了2条中间偃麦草染色体,为小麦—中间偃麦草双体异附加系;遗传分析表明,山农Line15的抗白粉病基…     

小麦抗白粉病基因Pm21 的抑制基因

 小麦-簇毛麦6VS. 6AL 易位染色体含有抗白粉病基因Pm21,在我国的小麦育种中被广泛应用。近年来,一些含有Pm21 基因的小麦品种(系)开始感染白粉病。为探索含Pm21 的品种(系)感染白粉病的原因,本研究在6VS. 6AL 易位系与小麦品系(种)R14 和川农12 的杂交后代中利用分子标记CINAU17-1086 和CINAU18-723 辅助选择的遗传背景相对简单的F7 和F8 近等基因系为材料,研究了小麦抗白粉病基因Pm21 的抗病性表达。结果发现,在3 个含有6VS. 6AL 易位染色体的感病F6 植株繁殖的F7 近等基因系中发生了白粉病抗性的分离,分离比率符合13 感病︰ 3 抗病的理论值。在随机选取的F7 感病小麦单株所繁殖的F8 近等基因系中,有7 / 13 的株系一致地重感白粉病,有6 / 13 的株系发生了抗白粉病的分离,其中2 / 13 的株系分离比符合3 感病︰ 1 抗病、4 / 13 的株系分离比符合13 感病︰ 3 抗病的分离模式。这一结果指出,小麦株系中的抗白粉病基因Pm21 的抗性表达受小麦基因组中的一对显性抑制基因所控制,该基因来源于小麦品种(系)川农12或R14,建议命名为SuPm21。本研究指出,在把外源基因引入小麦的研究中,有利的外源基因与不含抑制基因的受体遗传资源同等重要。     

小菜蛾对杀虫双的抗性遗传研究

利用室内选育的敏感品系和抗杀虫双品系为亲本,采用剂量对数—死亡机率值回归线(LD-P线)分析法,研究了小菜蛾对杀虫双的抗性遗传方式。结果表明,小菜蛾对杀虫双的抗性为多基因、常染色体遗传,正、反交F_1的显性度(D)值分别为0.39、0.28,即其主效基因为不完全显性。小菜蛾对杀虫双的抗性现实遗传力较低,h~2=0.052,产生抗性的速率较慢,室内选育119代,抗性仅达122.8倍。抗杀虫双品系和遗传杂交后代(F_1、F_2、BC)对拟除虫菊酯类、氨基甲酸酯类、有机磷类的代表杀虫剂溴氰菊酯、灭多威、敌敌畏等的交互抗性测定结果表明,它们对3种杀虫剂无交互抗性;亲本和杂交后代的多功能氧化酶环氧化活性与杀虫双的抗性水平呈正相关性;乙酰胆碱酯酶活性要比敏感品系低;羧酸酯酶活性与敏感品系无明显差异。     

花粉管通道法导入高粱DNA创造优良小麦新品系的分子聚合育种

采用优化的花粉管通道法将高梁(Sorghum bicolor L.)基因组DNA导入高感条锈病、籽粒粉质的稳定小麦品系,并借助幼胚培养挽救加代、早代变异筛选等技术,经多代连续选择优良变异系,获得2个稳定的优良变异新品系,其中2001502-23-26两年度位居省区试第一位,已申请生产试验和品种审定.变异新品系与感病受体小麦比较,某些生物学性状发生明显变异,对条锈病免疫,品质指标得到提升,HMW-GS发生明显变异,Gul D1位点基因发生等位变异,过氧化物酶发生明显变化,说明外源高粱基因导入引起了相应基因表达的变化,地区适应性也相应的较受体不同.这说明异源高粱基因组DNA导入小麦可实现高粱抗条锈性和HMW-GS等优良性状的遗传转育和聚合,达到生物学性状、产量、抗条锈性和品质指标等目标性状得到遗传改良的目的.性状改良的原因,推测可能是高粱抗条锈基因转化和HMW-GS基因生物诱变和多基因聚合的结果,而导入后代HMW-GS的GulD1位点基因的等位变异机理可归结为生物诱变所致,条锈病抗性的变异可能属于高粱抗锈基因的定向转移所致.     

小麦抗条锈病近等基因系Taichung29*6/Strubes Dickkopf抗病主效基因的单体分析

小麦品种Strubes Dickkopf是小麦条锈菌国际鉴别寄主,通过对以其为基因供体与完全感病品种Taichung29杂交转育而成的近等基因品系Taichung29*6/Strubes Dickkopf的单体分析,检测和定位Taichung29*6/Strubes Dickkopf中所含的抗条锈病主效基因,并明确其抗性特点。结果表明,Taichung29*6/Strubes Dickkopf对CY26小种的抗性由1对显性主效抗条锈基因所控制,定位在4B染色体上,暂定名为YrSD。同时说明Strubes Dickkopf中含有与Yr25不同的新的抗条锈病基因YrSD。     

小麦农家种红秃头和霸王鞭的抗白粉病基因分析及染色体定位

本研究对红秃头和霸王鞭两个小麦农家种抗白粉病基因推导显示,红秃头和霸王鞭均具有较宽的抗性谱,是良好的抗源品种,并可能携带新的抗病基因。抗白粉病遗传分析表明,红秃头对E09的抗性由1对显性基因控制,对E26和E30-2的抗性分别由1对隐性基因控制,其至少携带一显一隐2对抗白粉病基因;霸王鞭对E09的抗性由2对显性基因重叠或者独立控制,对E26的抗性由2对显性基因互补作用控制,对E30-2的抗性由1对显性基因控制,其至少携带2对显性基因。利用基因芯片结合集群分离分析法(Bulk Segregant Analysis,BSA)进行染色体定位推测出,红秃头的抗白粉病基因可能位于染色体7B和6B上,霸王鞭的抗白粉病基因可能位于染色体4A和7B上。     

簇毛麦对不同白粉病菌菌系的抗性反应及其在小麦遗传背景下的表达

 对引自原苏联的簇毛麦(Haynaldia vilosa L.Schur 2n=14VV)及其与硬粒小麦杂交育成的双二倍体TH1 TH1W TH2W TH3 TH3W,普通小麦-簇毛麦6D/6V异代换系及普通小麦亲本和已知抗白粉病基因的18个小麦品种为供试材料,用84个来自美国、德国、中国的小麦白粉病菌菌系进行苗期接种鉴定。发现簇毛麦及其衍生系对所有参试的白粉病菌系表现免疫和抗,比供试的已知抗性基因的18个小麦品种抗性强,抗谱广。其抗性基因在81086A、D311、墨75、陕7859、宛7107、冀麦30等小麦遗传背景下均能很好表达,呈显性遗传。     

弱光胁迫下黄瓜霜霉病抗性评价与分析

为明确弱光胁迫下黄瓜霜霉病田间发病规律及遗传特性,筛选抗霜霉病黄瓜品种,以15份黄瓜自交系为试材,在弱光条件下通过子叶接菌诱导寄主植株发病,同时结合田间发病率及病情指数调查进行复合抗性鉴定,进而筛选抗病组合,并对其分离世代进行抗性鉴定与遗传特征分析。结果表明,供试15份材料中共筛选出4个典型品系HB1、HB2、HB3和HB4,其病情指数分别是14.17、28.71、63.33和78.33,分别属于高抗、抗病、感病和高感病类型。这4个亲本的F1代及分离世代群体中霜霉病抗性与亲本抗性均存在正相关关系,抗性亲本的后代表现出较强的抗性;F2代群体病株分离现象比较明显,呈偏态分布,有明显的主基因+多基因存在特征,表明弱光胁迫下黄瓜霜霉病受主基因+多基因控制,主基因效应值较大。经田间抗病性鉴定分析,初步筛选出组合HB12、HB13和HB21为抗霜霉病组合,可用于后续抗病品种的选育。     

Main effects, epistasis, and environmental interactions of quantitative trait Loci for fusarium head blight resistance in a recombinant inbred population

ABSTRACT Chinese Spring Sumai 3 chromosome 7A disomic substitution line (CS-SM3-7ADS) is highly resistant to Fusarium head blight (FHB), and an F(7) population of recombinant inbred lines derived from the cross CS-SM3-7ADS x Annong 8455 was evaluated for resistance to FHB to investigate main effects, epistasis, and environmental interactions of quantitative trait loci (QTLs) for FHB resistance. A molecular linkage map consists of 501 simple sequence repeat and amplified fragment length polymorphism markers. A total of 10 QTLs were identified with significant main effects on the FHB resistance using MapQTL and QTLMapper software. Among them, CS-SM3-7ADS carries FHB-resistance alleles at five QTLs on chromosomes 2D, 3B, 4D, and 6A. One QTL on 3BS had the largest effect and explained 30.2% of the phenotypic variance. Susceptible QTLs were detected on chromosomes 1A, 1D, 4A, and 4B. A QTL for enhanced FHB resistance was not detected on chromosome 7A of CS-SM3-7ADS; therefore, the increased FHB resistance in CS-SM3-7ADS was not due to any major FHB-resistance QTL on 7A of Sumai 3, but more likely was due to removal of susceptible alleles of QTLs on 7A of Chinese Spring. QTLMapper detected nine pairs of additive-additive interactions at 17 loci that explained 26% phenotypic variance. QTL-environment interactions explained 49% of phenotypic variation, indicating that the environments significantly affected the expression of the QTLs, especially these epistasis QTLs. Adding FHB-enhancing QTLs or removal of susceptible QTLs both may significantly enhance the degree of wheat resistance to FHB in a wheat cultivar.     

环介导等温扩增技术快速检测麦根腐平脐蠕孢

 为建立麦根腐平脐蠕孢简单快速的分子检测方法,基于环介导等温扩增(Loop-mediated isothermal amplification, LAMP)技术,以核糖体DNA的ITS为靶标序列,设计和筛选出一组麦根腐平脐蠕孢的特异性引物,成功开发可快速准确检测麦根腐平脐蠕孢的LAMP方法。甜菜碱作用测试显示LAMP体系中是否添加甜菜碱对扩增结果无明显影响;特异性测试显示该LAMP方法能够从14种植物病原菌中特异地检测出麦根腐平脐蠕孢;灵敏度测试显示该LAMP方法的检测极限为10^-3 ng·μL^-1,是常规PCR检测方法灵敏度的100倍;通用性测试显示该LAMP方法能够准确检测洛阳、安阳、开封和邯郸等不同地理来源的麦根腐平脐蠕孢菌株;发病组织检测显示该LAMP方法能够准确地从人工接种的小麦发病组织中检测出麦根腐平脐蠕孢,检出时间为侵染12 h及以上。这些研究结果表明所建立的麦根腐平脐蠕孢LAMP检测方法特异性好、灵敏度高、适用性强,可用于小麦根腐病的早期快速诊断。     

Identification and Mapping of Quantitative Trait Loci Conditioning Resistance to Southern Leaf Blight of Maize Caused by Cochliobolus heterostrophus Race O

ABSTRACT A random set of recombinant inbred (RI) lines (F2:7) derived from the cross of the inbred lines Mo17 (resistant) and B73 (susceptible) were evaluated for resistance to southern leaf blight (SLB) caused by Cochliobolus heterostrophus race O. The RI lines were genotyped at a total of 234 simple sequence repeat, restriction fragment length polymorphism, or isozyme loci. Field plots of the RI lines were inoculated artificially with an aggressive isolate of C. heterostrophus race O in each of two growing seasons in North Carolina. Lines were rated for percent SLB severity two (1996) or three (1995) times during the grain-filling period. Data also were converted to area under the disease progress curve (AUDPC) and analyzed using the composite interval mapping option of the PLABQTL program. When means of disease ratings over years were fitted to models, a total of 11 quantitative trait loci (QTLs) were found to condition resistance to SLB, depending upon which disease ratings were used in the analyses. When the AUDPC data were combined and analyzed over environments, seven QTLs, on chromosomes 1, 2, 3, 4, 7, and 10 were found to come from the resistant parent Mo17. An additional QTL for resistance on chromosome 1 came from the susceptible parent B73. The eight identified QTLs accounted for 46% of the phenotypic variation for resistance. QTL x environment interactions often were highly significant but, with one exception, were the result of differences in the magnitude of QTL effects between years and not due to changes in direction of effects. QTLs on the long arm of chromosome 1 and chromosomes 2 and 3 had the largest effects, were the most consistently detected, and accounted for most of the phenotypic variance. No significant additive x additive epistatic effects were detected. These data support earlier reports of the polygenic inheritance of resistance to SLB of maize.     

福建省丙环唑不同敏感性玉米小斑病菌的遗传多样性和致病性

 利用菌丝生长法、ISSR分子标记和分生孢子悬浮液喷雾接种法,探讨了福建省玉米小斑病菌对丙环唑的敏感性以及不同敏感性病菌群体的遗传多样性和致病性。敏感性测定结果表明,福建省玉米小斑病菌对丙环唑产生了抗药性,抗药性菌株的抗性倍数达到2.1~9.4倍。筛选获得的10条ISSR引物对55个菌株共检测出153个位点,其中多态性位点百分比高达93.46%。在敏感型、中间型和抗药型群体中多态性位点百分比分别为77.12%、69.93%和81.70%,在抗药型群体中,等位基因观测值、等位基因有效值、Nei’s遗传多样性指数和Shannon’s信息指数均高于敏感型群体,表明玉米小斑病菌抗药型群体的遗传多样性最丰富。聚类分析结果表明,病菌群体遗传多样性与抗药性水平和地理来源均有较高的相关性。致病性测定表明,丙环唑不同敏感性病菌群体对11个鲜食玉米品种均具有较强的致病性,但是,在9个玉米品种上,敏感型群体中强致病力菌株出现频率明显低于抗药型群体。研究结果为深入研究玉米小斑病菌群体遗传结构及其田间抗药性监测提供了理论基础。     

Quantitative trait loci for Fusarium head blight resistance in a recombinant inbred population of Wangshuibai/Wheaton

Use of diverse sources of Fusarium head blight (FHB)-resistant germplasm in breeding may significantly improve wheat resistance to FHB. Wangshuibai is an FHB-resistant Chinese landrace unrelated to cv. Sumai 3, the most commonly used FHB-resistant source. In all, 139 F(6) recombinant inbred lines were developed from a cross between Wangshuibai and an FHB-susceptible cultivar, Wheaton, to map quantitative trait loci (QTL) for wheat resistance to initial infection (type I resistance), spread of FHB symptoms within a spike (type II resistance), and deoxynivalenol (DON) accumulation (type III resistance) in infected grain. The experiments were conducted in a greenhouse at Manhattan, KS from 2003 to 2005. More than 1,300 simple-sequence repeat and amplified fragment length polymorphism markers were analyzed in this population. Five QTL for type I resistance were detected on chromosomes 3AS, 3BS, 4B, 5AS, and 5DL after spray inoculation; seven QTL for type II resistance were identified on chromosomes 1A, 3BS, 3DL, 5AS, 5DL, and 7AL after point inoculation; and seven QTL for type III resistance were detected on chromosomes 1A, 1BL, 3BS, 5AS, 5DL, and 7AL with the data from both inoculation methods. These QTL jointly explained up to 31.7, 64, and 52.8% of the phenotypic variation for the three types of FHB resistance, respectively. The narrow-sense heritabilities were low for type I resistance (0.37 to 0.41) but moderately high for type II resistance (0.45 to 0.61) and type III resistance (0.44 to 0.67). The QTL on the distal end of 3BS, 5AS, and 5DL contributed to all three types of resistance. Two QTL, on 7AL and 1A, as well as one QTL near the centromere of 3BS (3BSc), showed effects on both type II and type III resistance. Selection for type II resistance may simultaneously improve type I and type III resistance as well. The QTL for FHB resistance identified in Wangshuibai have potential to be used to pyramid FHB-resistance QTL from different sources.     

甜玉米小斑病抗性的遗传分析与主效QTL定位

为培育抗病品种,利用抗小斑病甜玉米自交系T14和感小斑病自交系T18为亲本配制杂交组合,对玉米抗小斑病性状进行遗传分析和抗病基因分子标记定位,用主基因＋多基因混合遗传模型和P₁、P₂、F₁、B₁、B₂、F₂ 6世代联合分析的方法对单位叶面积病斑数量进行遗传分析,并应用复合区间作图法检测抗小斑病QTL。结果表明,单位叶面积病斑数量受2对加性-显性-上位性主基因控制,自交系T14的抗病性在各个分离世代都以主基因遗传为主。在第4染色体上检测到4个相互连锁的小斑病抗性QTL,解释表型变异的7.7%、30.9%、14.8%和11.5%;在第6染色体上定位了1个抗病QTL,可解释表型变异的37.7%。检测到的小斑病抗性主效QTL位于第4和第6染色体的特征与2对主基因的遗传模型相吻合。     

Quantitative trait loci for adult-plant resistance to Mycosphaerella graminicola in two winter wheat populations

Septoria tritici blotch (STB) is one of the most important leaf spot diseases in wheat worldwide. The goal of this study was to detect chromosomal regions for adult-plant resistance in large winter wheat populations to STB. Inoculation by two isolates with virulence to Stb6 and Stb15, both present in the parents, was performed and STB severity was visually scored plotwise as percent coverage of flag leaves with pycnidia-bearing lesions. 'Florett'/'Biscay' and 'Tuareg'/'Biscay', each comprising a cross of a resistant and a susceptible cultivar, with population sizes of 316 and 269 F(7:8) recombinant inbred lines, respectively, were phenotyped across four and five environments and mapped with amplified fragment length polymorphism, diversity array technology, and simple sequence repeat markers covering polymorphic regions of ≈1,340 centimorgans. Phenotypic data revealed significant (P < 0.01) genotypic differentiation for STB, heading date, and plant height. Entry-mean heritabilities (h(2)) for STB were 0.73 for 'Florett'/'Biscay' and 0.38 for 'Tuareg'/'Biscay'. All correlations between STB and heading date as well as between STB and plant height were low (r = -0.13 to -0.20). In quantitative trait loci (QTL) analysis, nine and six QTL were found for STB ratings explaining, together, 55 and 51% of phenotypic variation in 'Florett'/'Biscay' and 'Tuareg'/'Biscay', respectively. Genotype-environment and QTL-environment interactions had a large impact. Two major QTL were detected consistently across environments on chromosomes 3B and 6D from 'Florett' and chromosomes 4B and 6B from 'Tuareg', each explaining 12 to 17% of normalized adjusted phenotypic variance. These results indicate that adult-plant resistance to STB in both mapping populations was of a quantitative nature.     

The effect of homoeologous group 7 chromosomes upon adult plant resistance of wheat to yellow rust (Puccinia striiformis)

Aneuploid and intervarietal chromosome substitution lines of wheat ev. Chinese Spring were used to study the effects of homoeologous chromosomes 7A, 7B and 7D upon adult plant resistance to yellow rust ( Puccinia striiformis). Chromosomes 7B and 7D carry factors upon their short arms which interact to influence resistance. The results can be explained if there is a single locus determining resistance upon the short arms of chromosomes 7B and 7D. These loci may be homoeo-allelic; however, no evidence was found for a corresponding locus upon the short arm of chromosome 7A. Three homologous variants of the factor on 7D^S were found but no variation was found for the factor on 7B^S.     

Genome-wide association study for spot blotch resistance in Afghan wheat germplasm

Spot blotch (SB), caused by Bipolaris sorokiniana, is a devastating disease of wheat globally, especially in South Asia and South America. Understanding the genetics of resistance to SB is important for developing breeding strategies to improve resistance. A panel of 301 genotypes from Afghanistan was phenotyped over two crop seasons using a mixture of virulent B. sorokiniana isolates and genotyped using DArTSeq to obtain genome-wide markers. Fifty genotypes (16.6%) showed disease scores less than the resistant control. Principal component analysis using the genotypic data clustered the genotypes into five different groups. Among models used for genome-wide association mapping, the multilocus mixed model, and fixed and random model circulating probability unification algorithms were most effective in identifying significant marker-trait associations (MTA). Twenty-five MTAs at p ≤ .001 were identified on chromosomes 1A, 1B, 1D, 2B, 2D, 3A, 3B, 4A, 5A, 5B, 6A, 7A, and 7D, indicating the quantitative nature of resistance to SB. Phenotypic variation explained by these markers ranged from 2.0% to 17.7%, and genomic regions on the chromosomes 1D, 2D, 3A, 3B, 4A, 5A, and 5B coincided with loci identified in previous studies. Three single nucleotide polymorphism (SNP) markers on chromosomes 1B (SNP 1113207) and 5A (SNPs 5411867 and 998276) were significant in both crop seasons as well as in the combined analysis across seasons. Marker 5411867 is close to Vrn-A1, shown to be associated with SB in previous studies. Furthermore, among known SB resistance genes, Sb2 on chromosome 5B was predicted to be significant in this panel.     

Association mapping of quantitative resistance to Phaeosphaeria nodorum in spring wheat landraces from the USDA National Small Grains Collection

Stagonospora nodorum blotch (SNB), caused by Phaeosphaeria nodorum, is a destructive disease of wheat (Triticum aestivum) found throughout the United States. Host resistance is the only economically feasible option for managing the disease; however, few SNB-resistant wheat cultivars are known to exist. In this study, we report findings from an association mapping (AM) of resistance to P. nodorum in 567 spring wheat landraces of diverse geographic origin. The accessions were evaluated for seedling resistance to P. nodorum in a greenhouse. Phenotypic data and 625 polymorphic diversity array technology (DArT) markers have been used for linkage disequilibrium (LD) and association analyses. The results showed that seven DArT markers on five chromosomes (2D, 3B, 5B, 6A, and 7A) were significantly associated with resistance to P. nodorum. Genetic regions on 2D, 3B, and 5B correspond to previously mapped quantitative trait loci (QTL) conferring resistance to P. nodorum whereas the remaining QTL appeared to be novel. These results demonstrate that the use of AM is an effective method for identifying new genomic regions associated with resistance to P. nodorum in spring wheat landraces. Additionally, the novel resistance found in this study could be useful in wheat breeding aimed at controlling SNB.