ω-黑麦碱基因沉默对小麦1B/1R易位系加工品质的影响

ω-黑麦碱是造成小麦1B/1R易位系加工品质差的一个重要因素,为探索解决这一问题,构建了ω-黑麦碱基因沉默表达载体,并通过农杆菌介导转化小麦品种金禾9123,获得3个T_0代转基因植株,再经连续的扩繁和PCR检测,获得纯合转基因T_4代株系。酸性PAGE检测结果表明,这些纯合转基因株系中ω-黑麦碱的总表达量平均下降53%。这些ω-黑麦碱基因沉默的转基因株系的面筋指数、沉降值和稳定时间均显著提高,而其农艺性状,如株高、穗粒数、千粒重和小区产量,均没有受到不良影响,说明沉默ω-黑麦碱基因可以在不影响产量的前提下提高小麦1B/1R易位系的加工品质。     

利用1RS特异标记和染色体原位杂交技术鉴定小麦1BL·1RS易位系

以小麦-黑麦1BL·1RS易位系(Kavkaz、山农030-1)、1AL·1RS易位系(Amigo)、荆州黑麦、八倍体小黑麦劲松49、1R-7R二体异附加系以及普通小麦中国春、辉县红、铭贤169、Chancellor等为材料,对65个黑麦1RS特异标记进行鉴定,从中筛选出8个稳定的标记,即NOR-1、SECA2/SECA3、SCSS30.2、Sec1Gene、Sec1Pro、ω-Sec-P1/P2、ω-Sec-P3/P4和IB-267,可用于检测1AL·1RS易位系或1BL·1RS易位系;另外3个特异标记O-SEC5′-A/O-SEC3′-R、IAG95-1和SCM-9可用于区别1RS来源不同的1AL·1RS和1BL·1RS易位系。利用这11个标记和染色体原位杂交技术对40份山东省近年育成小麦品种(系)进行检测,发现潍麦8号、鲁麦14、济宁13、山农664、山农优麦3号和烟农25为1BL·1RS易位系,而且是1RS的整臂易位系,未检测到1AL·1RS易位系和其他易位类型。     

1BL·1RS特异性分子标记的筛选及其对不同来源小麦品种1RS易位染色体的鉴定

1BL?1RS易位系在我国小麦育种和生产中占有重要地位,快速而准确地鉴定1BL?1RS易位系对小麦品质改良具有重要意义。本研究选用15个1BL?1RS特异性STS、SCAR和RAPD标记及22个1RS染色体上的SSR标记,检测不同来源的1BL?1RS易位系78份以及非1BL?1RS易位系品种10份和黑麦材料3份,其中1BL?1RS易位系包括周8425B及其衍生系36份、兰考906及其衍生系5份、矮孟牛及其衍生系8份和洛类1BL?1RS易位系品种29份。结果表明,7个STS标记、1个SCAR标记、3个RAPD标记和3个黑麦SSR标记可作为鉴别1BL?1RS易位系的可靠分子标记,其中ω-sec-p1/ω-sec-p2、ω-sec-p3/ω-sec-p4、H20和SECA2/SECA3标记最好,扩增效果稳定,重复性好,条带清晰,实验操作简单。周8425B及其衍生系、兰考906及其衍生系、矮孟牛及其衍生系与洛类1BL?1RS易位系的1RS染色体在分子标记检测中没有差异。     

黑麦重复序列在检测小麦品种中外源染色体的应用

本研究根据RAPD引物OPH20在黑麦中扩增出的特异序列pSc20H.2设计一对PCR引物pSc20ht-23/24,以来源于黑麦的小麦抗叶锈近等基因系材料TcLr45及感病对照Thatcher为亲本进行PCR扩增。并对42个小麦抗叶锈近等基因系及103个小麦品种材料进行检测。引物pSc20ht23/24在TcLr45中扩增出一条约750bp的条带,而在Thatcher中无扩增条带。对该特异片段回收、克隆测序为734bp。42个小麦抗叶锈近等基因系检测在TcLr26中扩增出与TcLr45相同的条带,而在同样来源于黑麦的小麦抗叶锈近等基因系TcLr25中未扩增出该条带;中国春-Imperial黑麦附加系1R-7R中除5R外均扩增出该条带;13个1B/1R易位系小麦品种也扩增出该条带;90个地方小麦品种中有16个扩增出该条带,6个品种经系谱分析具有黑麦遗传背景,表明该标记可用于检测小麦中含有的除黑麦5R染色体之外的外源染色质。     

小麦-黑麦远缘杂交后代高分子麦谷蛋白亚基变异分析

采用十二烷基硫酸钠-聚丙烯酰胺凝胶电泳(SDS-PAGE) 方法, 分析了小麦-黑麦远缘杂交后代的66个株系的高分子量谷蛋白亚基(HMW-GS) 组成.结果表明:(1)在29个母本为MY 11的株系中,有6个株系的Glu-1等位基因相对于母本MY 11发生了变异,1 B/1 R易位系中Glu-1位点发生变异的频率为66.67%,非1 B/1 R易位系中Glu-1位点发生变异的频率为8.69%.在36个母本为A 42912株系中,3个株系的Glu-1等位基因发生变异且这3个株系皆为1 B/1 R易位系,1 B/1 R易位系中Glu-1位点发生变异的频率为60.0%,非1 B/1 R易位系Glu-1位点没有变异;(2)对于母本为MY 11的株系,Glu-1三个位点上等位基因的变异均只有2种,即Glu-A 1 a(86.20%)、Glu-A 1 c(13.79%)、Glu-B 1 b(89.65%)、Glu-B 1 c(10.34%)、Glu-D 1 a(3.45%)、Glu-D 1 d(96.55%).对于母本为A 42912的株系,仅在Glu-B 1位点发生变异,即Glu-B 1 b(91.66%)、Glu-B 1 c(8.33%);(3)供试株系共出现6种高分子谷蛋白亚基组合,即(1,7 8,5 10)、(Null,7 8,5 10)、(Null,7 9,5 10)、(Null,7 8,2 12)、(1,7 8,5 10)、(1,7 9,5 10),两种母本不同的株系类型均是母本型HMW-GS组合(1,7 8,5 10)占绝对优势.本文分析了1 B/1 R易位株系具有高频率HMW-GS变异的原因,并就这些材料在小麦优质育种中的利用策略作了探讨.     

小麦-黑麦代换系间、代换系与易位系间杂交后代染色体易位系的选育

为了选育有经济价值的易位系,探讨小麦-黑麦间产生易位的频率,本研究以小麦-黑麦代换系DS5R/5A和DS6R/6A为母本,以小麦-黑麦易位系克珍(Kezhen)和带有杀配子染色体的代换系DSGC1为父本,分别进行田间杂交。结果表明:DS5R/5A、DS6R/6A与DSGC1(2S)杂交结实率低,平均为27.7%,与克珍(T3B.3R)杂交结实率高于前者,平均结实率为59.3%,二者均好于远缘杂交的结实率,这也表明带有杀配子染色体的亲本影响结实率;对选出的54株DS5R/5A×DSGC1、DS6R/6A×DSGC1杂种后代与80株DS5R/5A×克珍、DS6R/6A×克珍杂种后代进行C-分带、原位杂交和分子标记鉴定后发现,二者的易位频率分别为11.1%和8.8%,并且多为染色体端部小片段易位,这种小片段易位可能是代换系间杂交部分同源染色体交换产生的。此外,也表明杀配子染色体在引起染色体断裂后可发生染色体易位。本研究共获得T5RL.5AS、T5RS.5DL、T5RS.5BL、T6RL.6DS、6RL.6BS以及T6RS.6BL等13个易位系,平均易位频率为9.6%。     

小麦-黑麦小片段易位系新种质的分子细胞遗传学鉴定

为创制有利用价值的小麦-黑麦易位系,选育小麦遗传改良的新种质,本研究运用形态学与分子细胞遗传学结合的研究手段,对小麦-黑麦代换系6R/6A×克珍杂种后代中选育的11个品系进行鉴定。结果表明,11个品系形态表现为大穗多花、多小穗、抗倒伏、籽粒饱满度好等优良性状。其中有4个品系2-13、2-18、2-20、2-21穗长超过14 cm。品系2-18、2-21,分蘖数为7个,2-17千粒重为35.24 g,品系2-19主穗粒数为54,均超过亲本。另有8个品系结实率也优于亲本。亲本克珍为小麦-黑麦小片段易位系,带有7R和3R染色体遗传成分,分子标记和原位杂交显示,11个品系均带有R组染色体成分,分别有10个、6个和3个品系带有黑麦6R、7R和3R染色体遗传成分。有9个品系可确定为小麦-黑麦小片段易位系,易位类型为端部易位和中间易位。本研究成果对小麦育种及种质改良具有重要意义。     

O型口蹄疫病毒VP1蛋白的原核表达及功能鉴定

为获得具有免疫原性的FMDV VP1蛋白,以O型FMDV重组质粒PMD18T-VP1为模板,利用PCR技术扩增得到O型FMDV VP1基因片段,将此基因片段与原核表达载体pET32a连接,构建重组表达载体,命名为pET-VP1,经PCR和测序鉴定后,用IPTG诱导表达,收集诱导的菌液进行SDS-PAGE电泳和Western-Blot分析.结果显示,在分子量约为45 ku处有1条明显的蛋白条带,且能被口蹄疫阳性血清识别,表达产物通过包涵体纯化后用透析法复性;ELISA检测结果显示,所复性的蛋白具有较高的活性.结果表明,FMDV VP1蛋白在大肠杆菌中得到高效表达,为开发诊断制剂和疫苗的研制打下基础.     

利用揉面特性鉴定小麦1BL/1RS易位系

1BL/1RS易位系曾广泛用于小麦农艺性状改良,但对加工品质有明显的负面影响。利用404份F₅至F₈高代品系(试验I)和175份山东省主栽品种及高代品系(试验II),研究1BL/1RS易位对小麦揉面参数的影响,分析不同高低分子量蛋白亚基(HWM/LWM-GS)背景下1BL/1RS的揉面特性,探讨利用揉面特性鉴定1BL/1RS易位系的方法。结果表明,1BL/1RS易位系的揉面时间、峰值带宽及峰后1 min带宽显著低于非1BL/1RS易位系,而衰落角和带宽比(峰值带宽/峰后1 min带宽)显著高于非1BL/1RS易位系,说明1BL/1RS易位导致小麦的揉面特性显著变劣。易位系的揉面谱带的主要特征为峰后1 min谱带急剧衰落并变窄,带宽比显著增大,而非1BL/1RS易位系的峰后谱带衰落、变窄平缓或者稳定时间较长,带宽比较小。带宽比1.6可作为判断易位系的有效指标,即大于或等于1.6为1BL/1RS易位系,小于1.6为非1BL/1RS易位系,准确率达85.2%(试验I)和96.8%(试验II)。尽管优质HWM-GS背景对Glu-B3j(1BL/1RS易位系)的揉面特性有一定正向补偿作用,但品质特性仍显著劣于其他Glu-B3位点,带宽比表现尤为突出。因此,揉面特性不仅能测定育种材料的面团流变学特性,而且还能有效鉴别1BL/1RS易位系。     

冬小麦种质矮孟牛及其衍生后代1BL/1RS的分子和生化标记鉴定

本研究以小麦骨干亲本矮孟牛及其33个衍生品种(系)为材料,利用低分子量(LMW)麦谷蛋白Glu-B3位点的STS-PCR标记、醇溶蛋白Gli-B1位点的SSR标记和黑麦碱SEC-1b位点的STS-PCR标记进行复合PCR,检测1BL/IRS易位.结果表明,矮孟牛Ⅱ、Ⅳ、Ⅴ、Ⅵ和Ⅶ型含有1BL/1RS染色体,矮孟牛Ⅰ和Ⅲ型不含1BL/1RS;在矮孟牛的33个衍生后代中,25个含1BL/1RS,其余8个则不含1BL/1RS.利用A-PAGE技术对上述材料进行了黑麦碱蛋白的检测,结果与复合PCR一致,两种方法相结合能准确的检测1BL/1RS.     

Identification of Rye Chromosome 1R Translocations and Substitutions in Hexaploid Wheats Using Storage Proteins as Genetic Markers

Grain protein compositions of 106 advanced generation backcross lines from crosses involving ‘Amigo’ (1AL.1RS), ‘Aurora’, ‘Kavkaz’, ‘Skorospelka-35’ and ‘Sunbird’ (all 1BL.1RS) and ‘Gabo’ 1DL.1RS parents and 152 cultivars with unknown pedigree were analysed by one-dimensional SDS-PAGE. Eighty seven backcross lines and 16 cultivars carried one or other of these translocations, 2 cultivars had a 1R (1B) substitution, whereas 5 backcross lines were found to be heterogeneous for the 1BL.1RS translocation. The translocation lines were easily identified by the presence of secalins (Sec-1) controlled by rye chromosome arm IRS and a simultaneous loss of the gliadin (Gli-1) and/or triticin (Tri-1) protein bands controlled by the replaced wheat chromosome arm (1AS, 1BS or 1DS). Certain gliadins, showing no allelic variation among the genotypes analysed, were identified as markers for chromosome arms 1AS (M_r= 34 kd) and IBS (M_r= 42,33 kd). The whole chromosome substitutions 1R (1B) were recognized by scoring for the presence of Sec-1 and HMW secalin bands, Sec-3 (controlled by rye chromosome arm 1RL) and the absence of Gli-B1 and HMW glutenin subunits, Glu-B1 (controlled by wheat chromosome arm 1BL). The results have shown that protein electrophoresis provides a rapid and reliable technique for screening genotypes for these translocations and substitutions in a breeding programme.     

SDS-PAGE of the high-molecular-weight subunits of wheat glutenin and the characterization of 1R (1B) substitution and 1BL/1RS translocation lines

Summary The high-molecular-weight subunits of glutenin from wheat 1R(1B) substitution and 1BL/1RS translocation lines were fractionated by SDS-PAGE. Two new subunits denoted R₁ and R₂ were characterized in 1R(1B) substitution, but not in 1BL/1RS translocation lines. R₁ and R₂ were proved to be rye proteins by 2d electrophoresis (NEPHGE x SDS-PAGE).In contrast to literature citations it was demonstrated that the cultivar Winnetou is a 1R(1B) substitution line and the cultivars Clement and Mildress both are 1BL/1RS translocation lines.     

Genetic, agronomic and quality comparisons of two 1AL.1RS. wheat-rye chromosomal translocations

The 1AL.1RS wheat-rye chromosomal translocation originally found in ‘Amigo’ wheat possesses resistance genes for stem rust, powdery mildew and greenbug biotypes B and C, but also has a negative effect on wheat processing quality. Recently, a second 1AL.1RS translocation carrying Gb6, a gene conferring resistance to greenbug biotypes B, C, E, G and I, was identified in the wheat germplasm line ‘GRS1201′. Protein analytical methods, and the DNA polymerase chain reaction were used to identify markers capable of differentiating the 1RS chromosome arms derived from ‘Amigo’ and ‘GRS1201′. The secalin proteins encoded by genes on 1RS chromosome arms differed in ‘Amigo’ and ‘GRS1201′. A 70 kDa secalin was found in the ‘Amigo’1AL.1RS, but did not occur in the ‘GRS1201’1AL.1RS. Polymorphisms detected by PCR primers derived from a family of moderately repetitive rye DNA sequences also differentiated the two translocations. When ‘GRS1201’was mated with a non-1RS wheat, no recombinants between 1RS markers were observed. In crosses between 1RS and non-1RS parents, both DNA markers and secalins would be useful as selectable markers for 1RS-derived greenbug resistance. Recombination between 1RS markers did occur when 1RS from ‘Amigo’ and 1RS from ‘GRS1201’were combined, but in such intermatings, the molecular markers described herein could still be used to develop a population enriched in lines carrying Gb6. No differences in grain yield or grain and flour quality characteristics were observed when lines carrying 1RS from ‘Amigo’ were compared with lines with 1RS from ‘GRS1201′. Hence, differences in secalin composition did not result in differential quality effects. When compared with sister lines with 1AL.1AS derived from the wheat cultivar ‘Redland’, lines with ‘GRS1201’had equal grain yield, but produced flours with significantly shorter mix times, weaker doughs, and lower sodium dodecyl sulphate sedimentation volumes.     

Development and application of a new codominant PCR marker for detecting 1BL·1RS wheat–rye chromosome translocations

The 1BL·1RS translocation has been widely used in wheat breeding programmes throughout the world. Unfortunately, this translocation has frequently resulted in unsatisfactory grain processing quality. Two primer combinations derived from the published sequence of a ω‐secalin gene on 1RS gave polymerase chain reaction (PCR) fragments 0.4 and 1.1 kb in size. Both fragments can be used to quickly detect 1BL·1RS translocations. By combining the PCR assay resulting in the 1.1‐kb fragment from 1RS and a PCR assay resulting in a 0.6‐kb fragment from the Glu‐B3 gene on 1BS, plants homozygous for the 1BL 1RS could clearly be distinguished from the heterozygous ones. This codominant marker was successfully applied to genotype a segregating F₂ population and a local cultivar collection.     

Cytological identification of 1B/1R wheat-rye translocations in winter wheat breeding lines

Summary The incorporation of rye (S. cereale L.) chromatin into winter wheat (T. aestivum L.) cultivars is often achieved via hybridization of unadapted wheat-rye translocation lines with adapted wheat germplasm. Identification of progenies possessing the translocated chromosome has traditionally involved phenotypic screening for the desired rye characteristics. In this study, the Giemsa N-banding technique was evaluated as a potential screening tool for detection of 1B/1R wheat-rye translocations. Five breeding lines were examined from the pedigree Aurora/2^*TAM W-101. The differential banding patterns of chromosome 1B contributed by TAM W-101 and chromosome 1B/1R contributed by Aurora allowed unequivocal identification of translocation genotypes. Three of the lines were found to be heterogeneous, whereby plants were homozygous for either the normal 1B or the translocated 1B/1R chromosome. The remaining two lines were observed to be homozygous and homogeneous for the translocated 1B/1R chromosome. The implication of N-banding chromosomal analyses to wheat breeding is presented.Contribution No. J-5172, Department of Agronomy, Oklahoma Agriculture Experiment Station, Oklahoma State University, Stillwater, OK74078.     

The Effect of Chromosome 1B/1R Translocation on the Yield Potential of Certain Spring Wheats (Triticum aestivum L.)

Nearly 50 percent of the 1988 advanced breeding lines of the CIMMYT bread wheat breeding program possess the 1B/1R homozygous translocation. Hence, a trial was conducted to estimate the effect of 1B/1R chromosome translocation on the yield potential of some of our high-yielding spring wheats, where non-limiting levels of fertility, moisture, preventive pest and disease programs were used. In conclusing the 1B/1R lines seemed to have increased their above-ground biomass yield, number of spikes per meter², 1000-grain weight and test weight. They also exhibited a slight advantage over the 1B homozygous lines on grain yield. The observed difference, however, was non-significant, as was the plant height difference observed among the two groups. Varietal comparisons indicated that the 1B/1R group headed later than the 1B group.     

Characterization of the 1B/1R translocation in wheat using water extractable protein concentrate

Summary An electrophoretic procedure was developed to obtain patterns of water soluble proteins from the endosperm halves of seeds to detect the 1B/1R translocation in wheat cultivars. The water soluble proteins were precipitated with Coomassie Brilliant Blue R-250 and separated in a 10% polyacrylamide gel with sodium dodecyl sulfate. This procedure extracted protein bands (Mr 40,000, 44,000 and 45,000) corresponding to the -secalins of the rye parent which were present only in the wheat cultivars carrying 1B/1R translocation. By simplifying extract preparation and providing clear band resolution this procedure facilitates large scale screening of wheat lines for the rye translocation. Proteins with properties of overlapping solubilities are also discussed.Abbreviations CBB - Coomassie Brilliant Blue - DDW - deionized distilled water - DTT - dithiothreitol - HMW - high molecular weight - PAGE - polyacrylamide gel electrophoresis - Mr - relative molecular mass - SDS sodium dodecyl sulfate Contribution 1569 of Agriculture and Agri-Food Canada, Research Centre, Winnipeg, Canada     

Basic studies on hybrid wheat breeding using the 1BL-1RS translocation chromosome / Aegilops kotschyi cytoplasm system 1. Development of male sterile and maintainer lines with discovery of a new fertility-restorer

The Aegilops kotschyi cytoplasm and a 1BL-1RS translocation chromosome that consists of the long arm of wheat chromosome 1B and the short arm of rye chromosome 1R were transferred to six spring common wheat cultivars by repeated backcrossing. Resistance to leaf rust race 21B conditioned by the Lr26 gene and a secalin subunit encoded by the Sec-1 gene, both on the 1RS arm, were used as the selection markers of the translocation chromosome. Five of the six cultivars used were converted to complete male steriles, whereas the remaining one, cv. Kitamiharu 48, retained normal fertility, after transfer of both the 1BL-1RS chromosome and Ae. Kotschyi cytoplasm. Conventional gene analysis suggested that Kitamiharu 48 carries an incompletely dominant fertility-restoring gene. The F₁ hybrids between the male steriles and ordinary common wheat cultivars recovered fertility only at a low level, indicating that a single dose of the Rfv1 gene on the 1BS arm of wheat is insufficient for full fertility restoration under spring-sowing condition. Our results are in clear contrast to complete fertility restoration under fall-sowing condition reported by Nonaka et al. (1993). Combination of the 1BL-1RS chromosome / Ae. Kotschyi cytoplasm system with a new fertility-restoring gene discovered in Kitamiharu 48 may provide a breakthrough for spring-type hybrid wheat. This revised version was published online in August 2006 with corrections to the Cover Date.     

1BL/1RS易位对小麦产量性状和白粉病抗性的影响及其QTL分析

用PH82-2/内乡188杂交后代240个F_5:6家系,按照α-lattice设计,分别种植在安阳、焦作和泰安,对产量和抗白粉病等性状进行了考察。利用SSR和蛋白标记对群体进行部分连锁作图,分析1BL/1RS易位对产量及其相关性状的遗传效应。结果表明,1BL/1RS易位系对产量、穗数/m²和抽穗期的影响不显著;易位系的千