兼抗型成株抗性小麦品系的培育、鉴定与分子检测

小麦条锈病、叶锈病和白粉病是我国小麦的重要真菌病害,培育兼抗型成株抗性品种是控制病害最为经济有效和持久安全的方法。本研究选用由成株抗性育种方法培育的21份冬小麦高代品系和96份春小麦高代品系,在多个环境下进行这3种病害的成株期抗性鉴定,并利用紧密连锁的分子标记检测了兼抗型基因Lr34/Yr18/Pm38、Lr46/Yr29/Pm39和Sr2/Yr30的分布。田间鉴定表明,21份冬小麦品系中有17份兼抗3种病害,占80.9%;96份春小麦品系中有85份兼抗3种病害,占88.5%。分子标记检测发现,21份冬小麦品系均含QPm.caas-4DL,其中7份还含QPm.caas-2BS,9份还含QPm.caas-2BL;96份春小麦品系中,18份含Lr34/Yr18/Pm38,37份含Lr46/Yr29/Pm39,29份含Sr2/Yr30。以上结果表明,分子标记与常规育种相结合,可有效培育兼抗型成株抗性品种,为我国小麦抗病育种提供了新思路。     

CIMMYT小麦种质C615抗叶锈病QTL分析

由Puccinia triticina引起的叶锈病是小麦主要病害之一, 引进种质C615具有叶锈病成株期抗性, 但其抗病性遗传机制尚不清楚。本研究以抗病亲本C615与高感叶锈病亲本宁麦18构建的F_2:7代重组自交系群体为材料, 利用337对多态性SSR标记构建遗传连锁图谱, 结合2016、2017连续两年的叶锈病鉴定结果进行复合区间作图, 结果在1BL、2DS、3BS、4DL和6BS染色体上共发现了5个抗性QTL, 暂命名为QLr.njau-1BL、QLr.njau-2DS、QLr.njau-3BS、QLr.njau-4DL和QLr.njau-6BS。其中, QLr.njau-1BL、QLr.njau-3BS和QLr.njau-4DL在两年均被检测到, 分别解释10.1%~15.7%、10.9%~13.5%和8.2%~9.0%的表型变异; 另2个QTL只在一年被检测到, 解释6.2%和9.2%的表型变异。除QLr.njau-2DS外的4个抗性QTL均来源于抗病亲本C615。QLr.njau-1BL和QLr.njau-4DL分别与已报道的慢病性基因Lr46、Lr67在同一区域, QLr.njau-3B可能为一个新的抗叶锈病QTL。此外, 本研究在C615/扬麦13 (轮回亲本)BC₄F₅回交群体中选出了15个农艺性状优良且抗叶锈病的株系, 利用与C615所含抗性QTL紧密连锁的7个SSR标记对其进行基因型检测, 结果显示所有这15个株系均含有来自C615的抗性QTL, 且有3个株系聚合了全部抗性位点, 表明C615可作为抗源亲本用于高产、抗病育种。本研究结果将为分子标记选育抗叶锈品种提供材料和技术支撑。     

鲁麦21慢白粉病抗性基因数目和遗传力分析

以多年鉴定具有慢白粉抗性的小麦品种鲁麦21和感白粉病品种京双16及其杂交组合F_2:3和F_2:4代株系200个为材料, 于2005—2007年连续2个生长季, 在北京和安阳两地分别进行田间病害鉴定, 并采用质量性状和数量性状2种分析方法估算鲁麦21的慢病基因数目和遗传力。结果表明, 在这2个群体中至少存在4对抗性基因, 其广义遗传力为0.53~0.78。由于出现超亲分离, 因此推测京双16可能贡献1对微效抗病基因, 而鲁麦21至少含有3对慢白粉病抗性基因。     

小麦-黑麦染色体易位对充足水分供给条件下杂交小麦农艺性状的杂种优势效应

面包小麦-黑麦易位染色体已经广泛应用于小麦育种计划，以培育出高产、抗病品种。T1BL．1RS和T1AL．1RS可能赋予某些病害的抗性，如叶锈病(Lr26)、条锈病(Yr9)、秆锈病(Sr31)和白粉病(Rm8)。然而，在世界许多地区T1BL．1RS易位衍生的叶锈病、条锈病和白粉病抗性已经丧失了。T1AL．1RS     

小麦3个抗白粉病基因聚合于推广品种后代抗性的遗传分析

为了明确不同抗小麦白粉病基因聚合于推广品种后代的抗性表现,通过复合杂交,将抗小麦白粉病基因Pm4b,Pm13,Pm21聚合并转入推广品种,其后代(F1,F2)进行人工接种和表型抗病调查.结果表明,F1中凡是含有抗白粉病基因之一的材料均表现高抗或免疫.F2中Pm4b,Pm13和Pm21抗病基因聚合的抗病株占的比例最大(71.82%),Pm13和Pm21,Pm4b和Pm21聚合的抗病株占的比例次之(66.67%,64.14%),Pm4b和Pml3抗性基因聚合的抗病株占的比例较小(63.93%).2个抗病基因聚合体中含有Pm21基因的抗性最好.     

川麦42的1BS染色体臂对小麦主要农艺性状的遗传效应

川麦42的1BS染色体臂来源于人工合成小麦亲本Syn769。利用川麦42与含1BL/1RS易位系的四川小麦品种川农16构建的127个重组自交系(RIL, F₈),经3年4个环境的遗传评价,比较了川麦42的1BS和川农16的1RS染色体臂对小麦产量构成因子和产量的遗传效应。结果表明,RIL群体中川麦42的1BS染色体臂株系和川农16的1RS染色体臂株系在分蘖力、成穗率、全生育期、小穗数、收获指数和籽粒产量6个性状上存在显著差异; 1BS染色体臂有利于提高成穗率和收获指数,而1RS染色体臂有利于提高分蘖能力和增加小穗数,1BS株系的籽粒平均产量比1RS株系增加2.91%。鉴于1RS染色体臂上的抗条锈病基因丧失抗性,其携带的黑麦碱基因对加工品质有明显的负向作用,而川麦42的1BS染色体臂携带高抗条锈病基因YrCH42, 并对小麦籽粒产量有正向作用,因此建议在小麦遗传改良中利用川麦42的1BS替换1RS染色体臂。     

小麦品种扬麦16赤霉病抗扩展QTL定位及分析

扬麦系列品种赤霉病抗性在世界范围内得到重视,但其抗性遗传机制尚不清楚。扬麦16是近年来大面积推广的抗赤霉病品种,本研究以扬麦16与中麦895杂交构建的174个双单倍体(doublehaploidlines,DH)系为材料,于2017—2019年连续3年对该群体采用单花滴注进行赤霉病抗扩展鉴定。利用660KSNP芯片构建高密度遗传图谱,共检测到6个抗性QTL,分别位于2DL、3BL、4BS、4DS、5BL和6AS染色体上。除4BS位点外,其他5个抗性等位基因均来源于扬麦16。QFhb.yaas-4DS和QFhb.yaas-6AS均在多年被检测到,可解释8.8%～15.0%的表型变异;QFhb.yaas-2DL、QFhb.yaas-3BL仅在1年被检测到,分别解释10.5%和14.7%的表型变异;QFhb.yaas-5BL和来源于中麦895的QFhb.yaas-4BS仅在1年被检测到且效应仅为6.4%和8.3%。QTL效应分析结果表明,相较于单个位点,多个抗性QTL的聚合可显著降低赤霉病严重度。扬麦16抗赤霉病QTL将为揭示扬麦品种抗性遗传机制及开发相应分子标记奠定基础。     

基因聚合选育抗赤霉病小麦新品系百农4299

小麦赤霉病是一种严重危害小麦生产的真菌性病害,其抗性由多基因控制,抗性机制复杂。type Ⅰ(抗侵入)和type Ⅱ(抗扩展)是小麦抵御赤霉病侵害的2种最主要抗性类型。在抗赤霉病育种中兼顾2种抗性,对于保证生产上抗性的稳定和持久有着重要意义。在前期研究中,作者所在课题组从小麦地方品种望水白中克隆了抗赤霉病扩展的主效QTL Fhb1,精细定位了Fhb4和Fhb5,获得了功能性/紧密连锁的分子标记。本研究利用这些标记,以小麦品系NMAS022作为供体亲本,现代小麦品种百农4199作为受体亲本,通过分子标记辅助回交育种方法选育成了聚合望水白Fhb1、Fhb4、Fhb5的小麦新品系百农4299。与百农4199相比,百农4299在2年的田间试验中type Ⅰ抗性至少增加了73%～74%, type Ⅱ抗性至少增加了83%～88%(以病小穗数计),并且产量潜力也得到了提高。上述结果证明了通过分子标记辅助选择聚合不同类型抗赤霉病QTL以提高小麦赤霉病抗性的可行性。抗赤霉病小麦品系百农4299有望成为一个新的抗赤霉病小麦品种。     

小麦品种周麦22抗叶锈病的QTL定位

小麦叶锈病（leaf rust）是对小麦危害最严重的真菌病害之一,原菌群体中新致病菌类型的不断出现导致部分抗叶锈病基因的抗性功能逐步丧失,不断发掘和研究利用新抗源基因、培育种植抗病品种是控制该病害最有效的方法。周麦22在田间成株期对叶锈病表现出良好的抗性,为解析周麦22成株期抗叶锈病的遗传基础,将周麦22与铭贤169杂交构建遗传群体,获得255个F_2:3家系群体,经2个年度的大田成株期抗叶锈病鉴定,并利用复合区间作图法对该群体的抗叶锈病QTL进行定位分析。结果显示,该群体成株期检测到2个抗叶锈病QTL位点,分别位于1BL和2BS染色体上,命名为QLr.hebau-1BL和QLr.hebau-2BS,分别解释9.62%~11.88%和16.89%~20.99%的表型变异,该位点对叶锈病抗性表现稳定,均来自抗病品种周麦22。初步的遗传定位结果显示,QLr.hebau-2BS可能为已知抗叶锈病基因LrZH22,而QLr.hebau-1BL是新的抗病QTL。     

利用百农AK58/碧蚂4号重组自交系定位小麦品质性状QTL

为发掘小麦品质性状相关数量性状位点(QTL),以小麦骨干亲本百农AK58和碧蚂4号衍生的包含248个株系的重组自交系群体为材料，利用4个环境获得的蛋白质含量、湿面筋含量、淀粉含量、沉降值和延伸性等品质参数及已构建的单核苷酸多态性(SNP)高密度遗传连锁图谱进行QTL定位。通过完备区间作图法共检测到60个品质性状相关QTL,分布于除6B以外的20对小麦染色体上。有21个QTL可以在2个或2个以上环境中被检测到，其中15个QTL的增效基因来自百农AK58,6个QTL的增效基因来自碧蚂4号。4A染色体上116.4～139.0 cM(629.36～701.53 Mb)是一个QTL簇，该区段同时定位了与蛋白质含量(QGpc.his-4A-2)、湿面筋含量(QWgc.his-4A-2)、沉降值(QSv.his-4A)和延伸性(QEx.his-4A)相关的QTL。分析重组自交系群体中1BL/1RS易位对品质性状的影响，发现1BL/1RS易位有助于提高籽粒蛋白质含量、湿面筋含量和沉降值，对淀粉含量有一定的负效应，推测1BL/1RS易位系对品质性状的作用可能和其遗传背景相关。     

QTL mapping of adult‐plant resistance to stripe rust in a ‘Lumai 21 × Jingshuang 16’ wheat population

Stripe rust, caused by Puccinia striiformis f. sp. tritici, is a devastating fungal disease in common wheat (Triticum aestivum L.) worldwide. Chinese wheat cultivars ‘Lumai 21’ and ‘Jingshuang 16’ show moderate levels of adult‐plant resistance (APR) to stripe rust in the field, and they showed a mean maximum disease severity (MDS) ranging from 24 to 56.7% and 26 to 59%, respectively, across different environments. The aim of this study was to identify quantitative trait loci (QTL) for resistance to stripe rust in an F₃ population of 199 lines derived from ‘Lumai 21’ × ‘Jingshuang 16’. The F₃ lines were evaluated for MDS in Qingshui, Gansu province, and Chengdu, Sichuan province, in the 2009–2010 and 2010–2011 cropping seasons. Five QTL for APR were detected on chromosomes 2B (2 QTL), 2DS, 4DL and 5DS based on mean MDS in each environment and averaged values from all three environments. These QTL were designated QYr.caas‐2BS.2, QYr.caas‐2BL.2, QYr.caas‐2DS.2, QYr.caas‐4DL.2 and QYr.caas‐5DS, respectively. QYr.caas‐2DS.2 and QYr.caas‐5DS were detected in all three environments, explaining 2.3–18.2% and 5.1–18.0% of the phenotypic variance, respectively. In addition, QYr.caas‐2BS.2 and QYr.caas‐2BL.2 colocated with QTL for powdery mildew resistance reported in a previous study. These APR genes and their linked molecular markers are potentially useful for improving stripe rust and powdery mildew resistances in wheat breeding.     

Exploring wheat landraces for rust resistance using a single marker scan

Marker-trait associations identified in diverse germplasm can be exploited in crop improvement programs. An attempt to establish such associations was made by evaluating 205 wheat landraces for stripe rust, leaf rust and stem rust responses in the field over three crop seasons. Diversity arrays technology was used to genotype the landraces and associations were identified using a single-marker scan. Sixty-eight markers were significantly associated with rust resistance. Several significantly associated loci coincided with the presence of known major genes or QTL for rust resistance. In contrast, many marker-rust response associations identified in this analysis for each of the three rust diseases uncovered new loci. Dual associations; stripe rust-leaf rust (1AL, 2BS, 2BL, 3DL, 5BS, 6BS and 7DL), leaf rust-stem rust (5BL) and stripe rust-stem rust (4BL and 6AS) resistance were also observed. These associations could enable a cost-effective targeted mapping of dual rust resistance. Some marker-trait associations identified in this study have been validated through genetic analyses and formal naming of resistance loci.     

南农92R系统白粉病抗源多抗性鉴定及其抗条锈性遗传分析

对南农92R系统白粉病抗源进行了多抗性鉴定,并对其抗条锈性进行了遗传分析。结果表明:4份南农92R系统白粉病抗源,不仅对白粉病多个小种免疫,而且对中国当前优势条锈菌生理小种均表现免疫,其中的92R178和92R137亦对供试3个叶锈菌优势小种均表现高抗至免疫。抗条锈性遗传分析显示92R089, 92R137分别具有一对完全显性的抗条     

The use of wild relatives in crop improvement: a survey of developments over the last 20 years

Hypersensitive, race specific genes primarily have been deployed to control powdery mildew (Blumeria graminis (DC) EO Speer f. sp. tritici) in wheat (Triticum aestivum L.); however, recent efforts have shifted to breeding for more durable resistance. Previously, three quantitative trait loci (QTL) for adult plant resistance (APR) to powdery mildew in the winter wheat cultivar Massey were identified in a Becker/Massey (BM) F _2:3 population. Fourteen new simple sequence repeat (SSR) markers were added to the pre-existing BM F _2:3 linkage maps near the QTL for APR on chromosomes 1BL (QPm.vt-1BL), 2AL (QPm.vt-2AL), and 2BL (QPm.vt-2BL). Genetic linkage maps comprised of 17 previously and newly mapped SSRs from the BM population on chromosomes 1BL, 2AL, and 2BL were constructed in a USG 3209/Jaypee (UJ) F _6:7 recombinant inbred line (RIL) confirmation population, wherein the APR resistance of USG 3209 was derived from Massey. Interval mapping analysis of mildew severity data collected in 2002 (F _5:6) and 2003 (F _6:7) field experiments with marker genotypic data obtained in 2003 (F _6:7) confirmed the presence of the three QTL governing APR to powdery mildew in the UJ RILs. The QTL QPm.vt-1BL, QPm.vt-2AL, and QPm.vt-2BL explained 12–13, 59–69, and 22–48% of the phenotypic variance for powdery mildew severity in the UJ confirmation populations, respectively, in two field experiments. The current study verified that the elite wheat cultivar USG 3209 possesses the same QTL for APR as its parent Massey.     

小麦新品种“山农20”抗病基因的分子检测

山农20是2011年和2012年分别通过国家黄淮南、北片审定的小麦高产多抗新品种,在国家区试抗病性鉴定和生产中都表现出良好的抗黄淮麦区主要病害的特性。本研究利用与小麦抗白粉病、条锈病、叶锈病、纹枯病基因和抗赤霉病主效QTL紧密连锁的SSR、SCAR、STS等标记对该品种进行了分子检测,发现山农20含有6个抗白粉病基因(Pm12、Pm24、Pm30、Pm31、Pm35和Pm36),6个抗条锈病基因(Yr5、Yr9、Yr15、Yr24、Yr26和YrTp1),2个抗叶锈病基因(Lr21和Lr26),1个抗纹枯病基因(Ses1),但未检测到抗赤霉病主效QTL。分子检测结果部分解释了山农20的优良抗病性,也为利用分子标记辅助选择培育抗病稳产小麦新品种提供参考。     

12个主产区历史小麦品种抗叶锈病基因分析

近年来,小麦叶锈病发生有加重趋势,培育抗病品种是减轻小麦叶锈病危害的环保有效途径。用12个小麦品种及35个含已知抗叶锈病基因的载体品系在苗期接种19个不同毒性的叶锈菌生理小种,通过基因推导和系谱分析发掘待测品种中的抗叶锈病基因,并通过分子标记检测进一步验证;在田间接种强毒性混合生理小种,进行成株期病情严重度与普遍率调查,筛选慢锈性品种。结果表明,在石新828、百农3217、济南2号、泰山1号、石特14、晋麦2148、烟农15、小偃6号、温麦6号共9个品种中检测到Lr1、Lr26、Lr34、Lr37和Lr46共5个抗叶锈病基因,其中部分品种中发现多个抗性基因。成株期筛选出百农3217、平阳27、济南2号、泰山1号、石特14、晋麦2148、碧蚂4号、烟农15、小偃6号、温麦6号共10个慢叶锈性品种,其中碧蚂4号和小偃6号等品种是我国小麦育种的骨干亲本,探究这些品种中的抗病基因对培育小麦抗叶锈病品种具有重要意义。     

Spectrum of resistance conferred by ML-O powdery mildew resistance genes in barley

Summary Ten barley mutants and five Ethiopian barley lines representing 11 independently arisen powdery mildew resistance genes in the ml-o locus were tested at the seedling stage to cultures of the powdery mildew fungus from Europe, Israel, USA. Canada, and Japan. They were resistant with infection type 0/(4) in all tests. They were also resistant to field populations of the pathogen when scored in disease nurseries at more than 78 locations in 29 countries in Europe, the Near East, North and South America. New Zealand, and Japan. This indicates that the 11 genes confer the same, world-wide spectrum of powdery mildew resistance. They have no effect on several other barley diseases such as stripe rust and leaf rust.Part of the research reported here was carried out under IAEA Research Agreement No 1043 and Research Contract No 139-74-1 BIO DK with the European Atomic Energy Community.