RSP抗穗发芽基因育种利用研究初报

利用农艺性状优良、优质的红粒小麦品种绵阳11以及2个白粒、极易穗发芽(常年穗发芽在50%以上)的小麦品系YY2和88-1643与穗发芽抗性来源于长休眠节节麦的人工合成小麦RSP杂交,对3个组合的F2单株和F3株系的穗发芽测试,从RSP×绵阳11中筛选出15个与RSP相当的纯合抗性株系和27份穗发芽接近0的F3单株;从RSP×YY2和RSP×88-1643组合中共筛选出5份穗发芽在7%以下的白粒株系.这些株系或单株相对于RSP的高秆、晚熟等不利性状已有较大改良,为节节麦抗穗发芽基因向优质或白粒小麦转移研制出了更容易利用的中间材料.     

小麦穗发芽鉴定方法的比较与分析

穗发芽是小麦生产中较为严重的灾害之一,易受外界环境的影响,一旦发生不仅会影响产量,而且还会严重影响小麦的品质,因此培育抗穗发芽的小麦品种至关重要。该研究通过对65份小麦材料进行穗发芽试验,比较分析了小麦穗发芽抗性的常用方法,即籽粒发芽法、整穗发芽法和大田穗发芽法。结果表明:三种方法之间均呈极显著正相关关系,而且在1%水平上均存在极显著性差异;发芽指数与籽粒发芽率的相关性最高,能够更好地评价小麦材料的休眠特性,但不能得出材料的总体抗性;籽粒发芽法和整穗发芽法的变异程度相对较小,试验条件更易控制,可作为小麦穗发芽抗性评价的简易方法;多数参试材料的平均籽粒发芽率平均整穗发芽率平均大田穗发芽率,且三者差异程度均达到极显著水平,这说明麦穗的外部结构及外部环境对小麦穗发芽的影响显著。因此,籽粒发芽法可以从休眠性方面,对小麦种子资源进行初步筛选;整穗发芽法可用于穗发芽抗性的进一步鉴定和验证,评价小麦材料穗发芽的综合抗性;大田穗发芽法较易受自然条件的影响、变异程度较大,其结果可以作为室内发芽试验的参考数据。     

麦田节节麦发生动态及其对小麦产量的影响

于2009—2011年采用固定样方和随机样方取样的方法研究了山东肥城、河北永年和河南新乡3个地区冬小麦田节节麦的出苗规律及在田间的消长动态,同时研究了不同密度的节节麦对小麦生长的竞争效应。结果表明,节节麦的出苗、分蘖、株高和鲜重的变化与温度密切相关。节节麦有2个出苗高峰期,分别在冬前10月下旬—11月上旬和春季3月下旬—4月上旬。节节麦单株有效分蘖在山东省、河北省及河南省分别多于小麦3.0、3.4个/株和2.2个/株。节节麦对小麦产量的影响主要是通过抑制小麦的有效穗数而实现,对千粒重影响不明显,当节节麦密度为640穗/m2时,小麦产量损失率达28.38%。     

远缘杂交不需幼胚培养的节节麦基因型

六倍体普通小麦（Triticum aestivum L.)是由四倍体小麦（T.turgidum L.)与二倍体节节麦（Aegilops tanschii Coss.)天然杂交然后通过染色体自然加倍形成的异源多倍体。这一起源过程是自然条件下天然发生的,它的发生需要具备一个条件：四倍体小麦与节节麦的天然杂交种子在自然条件（没有幼胚培养等）下能够正常发芽出苗。我们从22份节节麦中发现来自中东的节节麦AS60在不采用幼胚培养等人工辅助条件下,仍然很容易与四体小麦和普通小麦产生有生活力的杂种植株。AS60与四倍体小麦的杂交种子有50．0％（反交）及57．1％（正交）的种子,而AS60与六倍体普通小麦的杂交种子则有45．5％不需幼胚培养等措施能够正常发芽,生长。AS60的这一特征正是普通小麦起源过程需要的条件。最后探讨了这一发现对小麦遗传改良和对普通小麦起源演化研究的意义。     

远缘杂交不需幼胚培养的节节麦基因型

六倍体普通小麦(Triticum aestivum L.)是由四倍体小麦(T.turgidum L.)与二倍体节节麦(Aegilops tanschii Coss.)天然杂交然后通过染色体自然加倍形成的异源多倍体.这一起源过程是自然条件下天然发生的,它的发生需要具备一个条件:四倍体小麦与节节麦的天然杂交种子在自然条件(没有幼胚培养等)下能够正常发芽出苗.我们从22份节节麦中发现来自中东的节节麦AS60在不采用幼胚培养等人工辅助条件下,仍然很容易与四倍体小麦和普通小麦产生有生活力的杂种植株.AS60与四倍体小麦的杂交种子有50.0%(反交)及57.1%(正交)的种子,而AS60与六倍体普通小麦的杂交种子则有45.5%不需幼胚培养等措施能够正常发芽、生长.AS60的这一特征正是普通小麦起源过程需要的条件.最后探讨了这一发现对小麦遗传改良和对普通小麦起源演化研究的意义.     

不同生态区小麦品种的穗发芽抗性评价

本研究对来自不同生态区的137个小麦品种进行穗发芽抗性鉴定,计算相对发芽指数,并分析这些品种穗部籽粒性状、品质指标、吸胀萌发后0～72 h α-淀粉酶活性及其基因表达量与穗发芽抗性之间的关系。结果表明: 长江中下游麦区小麦的平均发芽指数最低,抗穗发芽品种最多,其次是长江上游麦区,黄淮麦区抗穗发芽品种相对较少。红粒品种小麦的相对发芽指数低于白粒品种,相对发芽指数与籽粒长度、宽度呈极显著正相关,与小穗数呈显著正相关,与穗型、穗色、穗长、小穗密度、穗粒数、千粒重无显著相关性。相对发芽指数与容重呈极显著负相关,与面团形成时间和出粉率呈显著负相关,与蛋白质含量、湿面筋含量、吸水率、稳定时间、沉降值、拉伸面积、延展性、最大阻力无显著相关性。不同品种的α-淀粉酶活性随吸胀萌发时间的延长呈上升趋势,萌发24～72 h的相对发芽指数与α-淀粉酶活性呈极显著正相关,穗发芽中抗以上品种萌发48 h后α-淀粉酶活性聚类分析结果与穗发芽鉴定结果一致。萌发后各时段α-淀粉酶基因表达量与相对发芽指数呈极显著正相关。     

小麦Vp-1基因RNA干扰表达载体的构建及遗传转化

小麦成熟期穗发芽是世界性的自然灾害,严重影响小麦的产量和品质.Viviparous-1(Vp-1)是促进胚成熟和休眠的主要转录调节因子,与小麦穗发芽抗性有着密切的关系.本实验根据小麦Vp-1基因序列,以植物表达载体pAHC25为基础,成功构建了含有反向重复序列的RNA干扰表达载体pAHC-WVpRi.采用基因枪法轰击小麦品种新春9号幼胚材料1825个,共获得34株T0再生植株.利用Bar基因引物和干扰片段特异引物对再生植株进行PCR检测,获得Bar基因和干扰片段均为阳性的植株3株,转化率为0.16%.本研究为深入分析Vp-1基因功能,进而通过分子育种进行小麦穗发芽抗性的遗传改良提供了科学依据.     

基于穗形特征与分子标记进行中国节节麦核心种质的创建

节节麦是普通小麦D基因组供体,遗传多样性丰富,而我国节节麦资源是有别于中东节节麦资源的重要基因源。为了合理高效地管理、评价、保护和利用我国节节麦资源,本研究将野生采集的762份中国节节麦资源作为试验材料,基于SSR标记分组状况,利用小穗长、护颖长、护颖宽、外稃长、外稃宽、内稃长、内稃宽、穗宽、粒长和粒宽等10个穗形性状指标,在欧氏距离、马氏距离和4种取样比例下构建节节麦核心种质候选集。进而采用均值差异百分率、极差符合率、方差差异百分率及变异系数变化率4个指标对不同方法构建的核心种质候选集的可行性和有效性进行评价,并利用原种质和核心种质的主成分分析法进行验证,最终确定基于欧氏距离、10%取样比例下、采用最小距离逐步取样法构建的包含76个样品的节节麦核心种质能够以最小的资源份数、最大限度地代表我国节节麦的遗传多样性。     

小麦抗穗发芽研究进展

穗发芽严重影响小麦品质和产量。种子自身休眠特性、α-淀粉酶活性、α-淀粉酶抑制剂、迟熟α-淀粉酶活性、种皮颜色、颖壳抑制物以及穗部形态等,均是影响小麦穗发芽的重要因素,其中对子粒休眠特性和α-淀粉酶活性的研究较为深入。位于第3染色体组上的R基因、休眠基因以及4AL上的Phs基因均与小麦穗发芽密切相关。已开发出一些与穗发芽抗性相关的分子标记,其中位于第3部分同源群的三重R基因和位于3B染色体的STS标记Vp1B3,以及位于3A染色体的主效QTL位点QPhs.ccsu-3A.1均可直接用于穗发芽抗性的筛选。本文对以上内容进行了详细论述,并就今后如何提高小麦穗发芽抗性进行了讨论。     

冬小麦穗发芽抗性及其遗传研究

1987—1989年在人工模拟降雨室对123个小麦品种进行了成熟期穗发芽抗性鉴定。重点研究了13个品种的穗发芽率、籽粒发芽率、籽粒含水量,籽粒吸水速率和α-淀粉酶活性的动态变化。并通过6个抗性不同品种的双列杂交,初步探讨了穗发芽抗性的遗传特点。结果表明:红粒品种普遍抗穗发芽,但白粒品种中也存在不少抗源;开花后35—40天是鉴定穗发芽抗性的适宜时期;这个对期的仔粒吸水速率阳α-淀汾酶活性是抗性鉴定的可靠指标;穗发芽抗性是遗传性状,存在母、子体抗性因子互作效应。     

Assessment of Aegilops tauschii for resistance to biotypes of wheat curl mite (Acari: Eriophyidae)

Aegilops tauschii, the wild diploid D-genome progenitor of wheat, Triticum aestivum L., is an important source of resistance to several arthropod pests and pathogens. A total of 108 Ae. tauschii accessions from different geographic regions were evaluated for resistance to biotypes of the wheat curl mite, Aceria tosichella Keifer, from Kansas, Nebraska, and Montana. The wheat curl mite is the only vector known to transmit wheat streak mosaic virus. Wheat curl mite resistance was detected in germplasm from all the geographic locations represented. The highest percentage of resistant accessions originated from Turkey, followed by Afghanistan and the Caspian Sea region of Iran. Sixty-seven percent of the accessions exhibited resistance to at least one wheat curl mite biotype and 19% were resistant to all the three biotyopes. Resistance to the accessions tested occurred more frequently in the Nebraska and Kansas biotypes (69% and 64%, respectively) than did resistance to the Montana biotype (42%), although the frequency of resistance was not significant. The differential reactions of accessions to the different wheat curl mite biotypes suggests that Ae. tauschii has at least five different genes for resistance to mite colonization. Ae. tauschii continues to be a very useful source for wheat curl mite resistance genes for bread wheat improvement.     

Analysis of relationships between Aegilops tauschii and the D genome of wheat utilizing microsatellites.

Sixty Aegilops tauschii accessions and 60 European hexaploid wheat varieties were analyzed with 14 wheat microsatellite (WMS) primer sets to (i) study the phylogeny of Ae. tauschii, (ii) search for a specific genotype of Ae. tauschii most closely related to the D genome of hexaploid wheat, and (iii) narrow down the presumed birthplace of the latter. An average of 6.5 and 4.0 alleles per locus was detected in Ae. tauschii and in wheat, respectively. The highest genetic diversity of Ae. tauschii was found in Transcaucasia and southeast of the Caspian Sea. Distribution of the 87 alleles (without null alleles) found in Aegilops did not allow differentiation of the species into the two subspecies strangulata and tauschii. Excluding null alleles, 41 alleles occurred parallel in wheat and in Aegilops. Data obtained in this study supports the view of the D genome of hexaploid wheat being a composite of several sources but does not support subsp. strangulata as the possible major source of the D genome. The highest number of region-specific alleles (three) in Ae. tauschii occurring also in the D genome of wheat, and therefore most indicative for its evolution was found in present-day Georgia, where subsp. strangulata is not endemic.     

普通小麦与粗山羊草属间杂种的染色体构型及其后代的育性特征

利用3个推广品种(莱州953、山农辐63、陕7859)分别与原产地不同的抗白粉病的6份粗山羊草[Aegilops tauschii(Coss.)Schmal.]杂交,得到63个无胚乳的种子,将56枚幼胚接种到N6 0.5mg/L IBA 0.2 mg/L NAA的培养基上进行褓姆培养,得到37个植株。其中莱州953与粗山羊草的杂交结实率和成苗率较高,分别平均为8.58%和4.82%。粗山羊草对白粉病的抗性基因在不同的杂交组合中受到不同程度的改变或抑制。以莱州953为父本,分别与不同组合的杂种F_1回交,大多数组合均得到回交种子,回交结实率平均为1.70%;以莱州953作母本,与莱州953/Y225 F _1回交得到2粒种子,说明普通小麦与粗山羊草的杂种F_1也能产生少量有授精能力的花粉。以山农辐63为父本与山农辐63/Y219 F_1回交亦得到回交种子。通过对普通小麦与粗山羊草6个杂交组合的杂种F_1PMCMI染色体构型的分析,一般多出现14个左右单价体和一定频率的多价体,并观察到可能为A、B组染色体形成的异形二价体;粗山羊草的D组染色体和普通小麦的D组染色体联会正常,可发生自由重组,从而为将粗山羊草的有益基因导入普通小麦提供了细胞学依据。     

Phylogenetic relationships and intraspecific variation of D-genome Aegilops L. as revealed by RAPD analysis

RAPD analysis was carried out to study the genetic variation and phylogenetic relationships of polyploid Aegilops species, which contain the D genome as a component of the alloploid genome, and diploid Aegilops tauschii, which is a putative donor of the D genome for common wheat. In total, 74 accessions of six D-genome Aegilops species were examined. The highest intraspecific variation (0.03-0.21) was observed for Ae. tauschii. Intraspecific distances between accessions ranged 0.007-0.067 in Ae. cylindrica, 0.017-0.047 in Ae. vavilovii, and 0.00-0.053 in Ae. juvenalis. Likewise, Ae. ventricosa and Ae. crassa showed low intraspecific polymorphism. The among-accession difference in alloploid Ae. ventricosa (genome DvNv) was similar to that of one parental species, Ae. uniaristata (N), and substantially lower than in the other parent, Ae. tauschii (D). The among-accession difference in Ae. cylindrica (CcDc) was considerably lower than in either parent, Ae. tauschii (D) or Ae. caudata (C). With the exception of Ae. cylindrica, all D-genome species--Ae. tauschii (D), Ae. ventricosa (DvNv), Ae. crassa (XcrDcrl and XcrDcrlDcr2), Ae. juvenalis (XjDjUj), and Ae. vavilovii (XvaDvaSva)--formed a single polymorphic cluster, which was distinct from clusters of other species. The only exception, Ae. cylindrica, did not group with the other D-genome species, but clustered with Ae. caudata (C), a donor of the C genome. The cluster of these two species was clearly distinct from the cluster of the other D-genome species and close to a cluster of Ae. umbellulata (genome U) and Ae. ovata (genome UgMg). Thus, RAPD analysis for the first time was used to estimate and to compare the interpopulation polymorphism and to establish the phylogenetic relationships of all diploid and alloploid D-genome Aegilops species.     

小麦A/B染色体组SSR标记在新小麦合成前后的比较研究

微卫星分子标记已广泛用于普通小麦遗传和进化研究。由于人工合成小麦与小麦品种之间存在高的遗传多样性,人工合成小麦已被大量应用于小麦分子标记工作中。但是,目前还缺乏人工合成小麦的异源六倍化过程对微卫星影响的研究。本研究直接比较了四倍体小麦与节节麦远缘杂交并经染色体加倍获得人工合成小麦前后,位于普通小麦A/B染色体组不同染色体臂上的66个特异引物揭示的微卫星位点的保守性和可转移性。结果表明,除了一个引物在新合成小麦中扩增出供体亲本没有的新带,一个引物在节节麦扩增出的产物在新合成小麦中消失,其他的所有微卫星引物的扩增产物在小麦合成前后是保守的,没有变异发生。所有的引物能够在四倍体小麦中扩增出微卫星产物,四倍体小麦中的扩增产物也出现在新的人工合成小麦中;有70%的引物能够在节节麦扩增出产物,其中的绝大多数产物也出现在新的人工合成小麦中。因此,普通小麦A/B染色体组的这些微卫星引物除了在人工合成小麦的A/B染色体组中扩增出产物,还能在其D染色体组中扩增出产物,也就是说,这些引物对人工合成小麦而言,并非是A/B染色体组特异的。根据该研究结果,讨论了小麦微卫星的可转移性和特异性问题,重点讨论了在应用人工合成小麦构建的遗传群体进行微卫星分子标记中的应用价值及其应该注意的问题。     

The origin of spelt and free-threshing hexaploid wheat

It is widely believed that hexaploid wheat originated via hybridization of hulled tetraploid emmer with Aegilops tauschii (genomes DD) and that the nascent hexaploid was spelt, from which free-threshing wheat evolved by mutations. To reassess the role of spelt in the evolution of Triticum aestivum, 4 disomic substitution lines of Ae. tauschii chromosome 2D in Chinese Spring wheat were developed and one of them was used to map the Tg locus, which controls glume tenacity in Ae. tauschii, relative to simple sequence repeat (SSR) and expressed sequence tag loci on wheat chromosome 2D. The segregation of SSR markers was used to assess the presence of Tg alleles in 11 accessions of spelt, both from Europe and from Asia. Ten of them had an inactive tg allele in the D genome and most had an active Tg allele in the B genome. This is consistent with spelt being derived from free-threshing hexaploid wheat by hybridization of free-threshing wheat with hulled emmer. It is proposed that the tetraploid parent of hexaploid wheat was not hulled emmer but a free-threshing form of tetraploid wheat.