2Ai-2染色体在小麦部分同源染色体代换背景中的遗传

用中间偃麦草2Ai-2染色体特异的EST-PCR标记检测5个小麦-中间偃麦草二体异代换系(包括端体代换系)与普通小麦中国春(CS)杂交后代群体,研究外源染色体2Ai-2通过杂种向后代的传递率及其结构变异,并用基因组原位杂交进行验证。结果表明,第二部分同源群不同染色体代换背景对外源染色体传递的影响不同,在2B代换系的杂种中外源染色体或片段显示优先传递,而在2D代换系的杂种中其传递力则较低,2B代换背景更有利于2Ai-2染色体或片段的传递;外源染色体在杂种后代传递过程中会发生变异,在多数组合中,变异出现在着丝粒处;与短臂相比,外源染色体长臂更容易在世代中丢失;端体代换系中的外源染色体端体在杂种后代传递过程中容易丢失,且也会发生结构变异。基因组原位杂交结果证明了分子标记跟踪外源染色体的可靠性。     

应用GISH与STS标记鉴定小麦-中间偃麦草抗黄矮病端体系

由大麦黄矮病毒引起的小麦黄矮病毒病是一个严重病害,至今在小麦属内还没有发现抗源。中间偃麦草2Ai-2染色体携带一个高抗黄矮病基因,对该基因的染色体臂定位将为制定抗病基因向小麦转移策略,筛选、开发特定的、与抗性连锁的分子标记的研究提供重要信息。本文对由小麦-中间偃麦草二体附加系Z6衍生的3个抗黄矮病端体系进行鉴定,通过分析端体的遗传构成、筛选与端体共分离的STS标记以确定端体在遗传上的染色体臂归属,从而明确BYDV抗病基因的染色体位置。以拟鹅冠草基因组[Pseudoroegneria strigosa (M. Bieb.) Löve,St]DNA为探针,中国春基因组(Triticum aestivum L., ABD) DNA作封阻分别对抗病亲本Z6及抗病端体系N530的根尖体细胞染色体进行原位杂交,结果表明,N530体细胞中有2个端体显示出与Z6中外源染色体2Ai-2短臂相似, 而与长臂不同的杂交信号。以小麦第2同源群的5个RFLP探针的DNA序列为基础,设计了6对PCR引物,对小麦-中间偃麦草二体异附加系、二体代换系和端体系进行扩增,结果表明,基于短臂探针psr126,psr131序列设计的2对引物,可在含有2Ai-2染色体及端体的抗黄矮病材料中特异扩增,而基于长臂探针psr112序列设计的1对引物,可在含有2Ai-2染色体的抗黄矮病材料中特异扩增,但不能在端体系进行特异扩增,证明外源端体为2Ai-2染色体的短臂。本研究不仅将黄矮病抗性基因定位于2Ai-2染色体的短臂上, 而且由RFLP探针psr126、psr131和psr112序列转化的标记STS₁₂₆ (sequence tagged site) STS₁₃₁和STS₁₁₂还可分别作为追踪2Ai-2染色体短臂和长臂的分子标记,用于抗病易位系辅助选择。     

Identification of wheat–Thinopyrum intermedium 2Ai-2 ditelosomic addition and substitution lines with resistance to barley yellow dwarf virus

Among the regenerated plants derived from immature hybrid embryos of wheat–Thinopyrum intermedium disomic addition line Z6 × common wheat variety ‘Zhong8601’, a plant with a telocentric chromosome and barley yellow dwarf virus (BYDV) resistance was obtained. The telocentric chromosome paired with an entire Thinopyrum chromosome to form a heteromorphic bivalent at meiotic metaphase I. Genomic in situ hybridization showed that the telosome originated from Th. intermedium. Two ditelosomic additions and one disomic substitution were identified among the offspring of the plant. Two random amplified polymorphic DNA molecular markers were identified among 150 random primers used to detect the different arms of the alien chromosome. These might be useful for developing translocation lines with BYDV resistance.     

Characterization of a wheat–Thinopyron intermedium substitution line with resistance to powdery mildew

Among the progenies of a hybrid between common wheat Triticum aestivum L. cv. Yannong 15 and Thinopyron intermedium, plant E99018 was identified with the chromosome number 2n = 42 and stable agronomic traits. An analysis of the metaphase chromosome pairing indicated that it formed 21 bivalents but that 2 univalents were present in the F₁ hybrid of this plant with common wheat. Resistance verification by race 15 and with mixed races of Blumeria graminis f. sp. tritici at the seedling and adult stages showed that at both stages, the plant was immune to powdery mildew. In situ hybridization with the genomic Th. intermedium and the St genome DNAs as probes and wheat DNA as a block has shown that it contained a pair of Th. intermedium chromosomes. On the basis of the hybridization pattern of the St genome probe to the critical chromosome, a conclusion was reached that this pair of chromosomes belonged to the E genome. Therefore, plant E99018 was a spontaneously formed substitution line. An analysis by 116 SSR markers indicated that the substituted wheat chromosome was 2D and the most likely substitution in E99018 is 2E(2D).     

Inheritance of traits associated with seed size in groundnut (<Emphasis Type="Italic">Arachis hypogaea</Emphasis> L.)

A new wheat-Thinopyrum substitution line AS1677, developed from a cross between wheat line ML-13 and wheat-Thinopyrum intermedium ssp. trichophorum partial amphiploid TE-3, was characterized by fluorescence in situ hybridization (FISH), sequential Giemsa-C banding, genomic in situ hybridization (GISH), seed storage protein electrophoresis, molecular marker analysis and disease resistance screening. Sequential Giemsa-C banding and GISH using Pseudoroegneria spicata genomic DNA as probe indicated that a pair of St-chromosomes with strong terminal bands were introduced into AS1677. FISH using pTa71 as a probe gave strong hybridization signals at the nuclear organization region and in the distal region of the short arms of the St chromosome. Moreover, FISH using the repetitive sequence pAs1 revealed that a pair of wheat 1D chromosomes was absent in accession AS1677. Seed storage proteins separated by acid polyacrylamide gel electrophoresis (APAGE) and sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) confirmed that AS1677 lacked the gliadin and glutenin bands encoded by Gli-D1 and Glu-D1, further confirming the absence of chromosome 1D. The introduced St chromosome pair belonging to homoeologous group 1 was identified by newly produced genome specific markers. AS1677 is a new 1St (1D) substitution line. When inoculated with stripe rust and powdery mildew isolates, AS1677 expressed stripe rust resistance possibly derived from its Thinopyrum parent. AS1677 can be used as a donor source for introducing novel disease resistance genes to wheat in breeding programs aided by molecular and cytogenetic markers.     

Segregation distortion in common wheat of a segment of Thinopyrum intermedium chromosome 7E carrying Bdv3 and development of a Bdv3 marker

Yellow dwarf (YD) disease is one of the most destructive diseases of cereals worldwide. Wheat (Triticum aestivum L.)–Thinopyrum intermedium 7E(7D) substitution line P29 carries resistance to YD, known as Bdv3, that originates on the long arm of chromosome 7E of Th. intermedium, and the resistance was introgressed into wheat chromosome 7D as T7DS.7DL–7EL in the translocation lines P961341 and P98134. Until now, quantification of YD viruses in cereal crops was usually done by enzyme‐linked immunosorbent assay (ELISA), which is time consuming and laborious. To facilitate this analysis, SSR‐Bdv3, a diagnostic molecular marker, was developed in this study. The transmission of the Th. intermedium segment with Bdv3 was investigated using the SSR‐Bdv3 marker and ELISA in F₂ and testcross progeny derived by crossing two wheat–Th. intermedium translocation lines to four common wheat cultivars. A Th. intermedium chromosome 7E segment in the translocation line P98134 was preferentially transmitted through male gametes in all of its crosses with the four wheat cultivars. However, the transmission frequency of the Th. intermedium 7E segment in another wheat–Th. intermedium translocation line, P961341, varied in different genetic backgrounds. The F₂ populations from reciprocal crosses of Chinese Spring and P961341 showed good fits to the expected ratio of 1 : 2 : 1. In this study, male preferential transmission for either chromosome 7E or chromosome 7D was observed in the progeny derived by crossing P961341 to other wheat cultivars.     

A physical map of chromosome 4Hch from H. chilense containing SSR, STS and EST-SSR molecular markers

The construction of a physical map of chromosome 4H^ch from Hordeum chilense containing molecular markers capable of detecting segments of this chromosome in a wheat background would be very useful for marker-assisted introgression of 4H^ch chromatin into both durum and common wheat. With this aim, the applicability of 106 barley chromosome 4H primers (62 SSRs and 44 STSs) to amplify markers showing polymorphism between H. chilense and both common or bread and durum wheat was investigated. Twenty-five SSR (40.3%) and six STS (13.6%) barley primer pairs consistently amplified H. chilense products. Eight SSR (12.9%) and four STS (9.1%) barley primers were polymorphic between H. chilense and both common and durum wheat, 10 of them (6 SSRs and 4 STSs) were located on chromosome 4H^ch using both the addition line of chromosome 4H^ch in Chinese Spring wheat and a tritordeum line (an amphiploid between H. chilense and T. turgidum) nullisomic for chromosome 4H^ch. Additionally, 18 EST-SSR barley markers previously located on chromosome 4H^ch were screened for polymorphism; 15 were polymorphic between H. chilense and both durum and common wheat. For physical mapping we used a ditelosomic tritordeum line for the short arm of chromosome 4H^ch and a tritordeum line homozygous for a 70% terminal deletion of the long arm of 4H^ch. A total of 25 markers (6 SSRs, 4 STSs and 15 EST-SSRs) were mapped to chromosome 4H^ch. Eight markers were allocated on the 4H^chS, eight were mapped in the 30% proximal region of 4H^chL and nine were on the 70% distal region of 4H^chL, respectively. Arm location on barley chromosome 4H was also carried out using both 4HS and 4HL ditelosomic addition lines in wheat. All markers mapped may have a role in marker-assisted introgression of chromatin segments of chromosome 4H^ch in both durum and common wheat backgrounds. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Development and characterization of common wheat-Thinopyrum intermedium translocation lines with resistance to barley yellow dwarf virus

We developed some wheat-Th. intermedium translocation lines,Yw642, Yw443 and Yw243, etc., showing good BYDV resistance from L1by induced homoeologous pairing using CS ph mutant. Characterization ofthese wheat lines was carried out by GISH and RFLP analysis. The resultsof GISH showed that the lines, YWw42, Yw443 and Yw243, etc., arehomozygous wheat-Th. intermedium translocation lines, in which thechromosome segments of Th. intermedium were transferred to thedistal end of a pair of wheat chromosomes. RFLP analysis indicated that thetranslocation chromosome of the wheat lines is T7DS · 7DL-7XL. Thebreakpoint of the translocation is located on the distal end of 7DL, betweenXpsr965 and Xpsr680 about 90–99 cm from the centromere. The BYDVgene is located on the distal end of 7XL around Xpsr680, Xpsr687 andXwg380. The RFLP markers of psr680, psr687 and wg380 werecosegregated with the BYDV resistance respectively and could be used formolecular assisted selection (MAS) in wheat breeding program for BYDVresistance.     

The study of introgressive lines of Triticum aestivum × Aegilops speltoides by in situ and SSR analyses

Fluorescence in situ hybridization (FISH) with a genome‐specific repeat, Spelt1, and wheat simple sequence repeat (SSR) markers were used to analyse the chromosome constitution of two Triticum aestivum×Aegilops speltoides introgressive lines. The lines 170/98i and 178/98i carried one and two subtelomeric regions of Ae. speltoides (per haploid genome), respectively, marked by Spelt1 repeats according to FISH data. SSR analysis detected homoeologous substitution of wheat chromosome 7D with Ae. speltoides chromosome 7S in the lines 178/98i and 170/98i as well as the assumed terminal translocation in the short arm of chromosome 3A in the line 178/98i. Anthocyanin pigmentation of the coleoptiles was found in the lines 170/98i and 178/98i and resulted from the 7S (7D) substitution. It was demonstrated that Spelt1 could be effectively used for the rapid identification (without DNA isolation) of terminal translocations of T. aestivum×Ae. speltoides introgressive lines as well as for further analysis of the stability of the hybrid plants.     

小麦新种质N9628-2抗白粉病基因的SSR分析

以抗白粉病的波斯小麦-小伞山羊草双二倍体Am9为母本, 与高感白粉病的普通小麦品种陕160杂交, 并用陕160回交一次, 从其后代中选育的普通小麦种质N9628-2对陕西省关中地区白粉病流行小种关中4号表现免疫。为了明确N9628-2所携带抗性基因的遗传方式及与抗性基因连锁的分子标记, 对该种质的抗白粉病基因进行了遗传分析和SSR标记分析。用高感白粉病品种陕160、陕优225与N9628-2杂交, F₁代对白粉病均表现高抗, F2代抗感分离比例均符合3∶1, 表明N9628-2的白粉病抗性由1对显性基因控制。通过208对SSR引物对陕160 ´ N9628-2 F2代抗感分离群体的142个单株的检测, 发现位于6A上的SSR位点Xwmc553和Xwmc684在双亲和抗、感池间有特异性, 并与抗性基因连锁, 遗传距离分别是10.99和7.43 cM, 表明抗病基因可能位于6A染色体上。 用中国春部分第6同源群的缺体-四体系和双端体系进行验证, 进一步将抗性基因定位在6AS。用连锁的SSR标记和相关亲本分析表明, 该抗病基因可能来源于小伞山羊草Y39, 它不同于已有抗白粉病基因, 可能是一个新基因。     

小麦全基因组NBS类R基因分析及2AL染色体NBS-SSR特异标记开发

NBS (nucleotide binding site)类基因是植物界中最重要的一类抗病基因。用信息学方法从普通小麦(Triticum aestivum L.)全基因组中分离出2406条含有NBS结构的完整蛋白序列,每条包含48~2272个氨基酸。根据NBS结构域两端是否连接CC或LRR结构域,将TaNBS分为N、CN、NL和CNL4类。对TaNBS所在scaffold序列的SSR位点进行诊断,从1203条scaffold序列上发现2177个SSR位点,以二碱基重复位点最多,占73.5%。针对小麦2AL染色体上的51个SSR位点开发标记,缺体-四体和双端体验证结果表明,有39个标记(76.5%)为2AL特异标记,其中24个特异标记在抗白粉病材料Khapli (2AL上携带Pm4a)和感病材料Chancellor间存在多态性。利用近等基因系Khapli/8*Cc筛选出3个可能与Pm4a连锁的NBS-SSR标记,分别是Sxaas_2AL22、Sxaas_2AL39和Sxaas_2AL46。本研究开发的与抗病序列紧密连锁的特异SSR标记可用于2AL染色体上抗病新基因的检测以及已有抗病基因的候选序列筛选。     

用RFLP鉴定普通小麦—纤毛鹅观草二体附加系中外源染色体的同源转化性

用小麦族7个部分同源群的40个RFLP探针对小麦——纤毛鹅观草二体附加系进行分析,在证实了原有细胞学鉴定结果的基础上,又进一步提供了纤毛鹅观草染色体部分同源群的分子证据。即96K025,96K026中添加的一对纤毛鹅观草染色体B属于第2部分同源群;96K012, 96K013中添加的一对染色体E属于第5部分同源群。对以上株系的衍生株系     

BAC-derived SSR markers chromosome locations in cotton

Bacterial artificial chromosome (BAC) libraries with large DNA fragment inserts have rapidly become the preferred choice for physical mapping. BAC-derived microsatellite or simple sequence repeats (SSRs) markers facilitate the integration of physical maps with genetic maps. The objective of this research was to identify chromosome locations of the BAC-derived SSR markers in tetraploid cotton. A total of 192 SSR primer pairs were derived from BAC clones of an Upland cotton genetic standard line TM-1 (Gossypium hirsutum L.). Metaphor agarose gel electrophoresis results revealed 76 and 59 polymorphic markers between TM-1 and 3–79 (G. barbadense) or G. tomentosum, respectively. Using deletion analysis method, we assigned 39 markers out of the 192 primer pairs to 17 different chromosomes or chromosome arms. Among them, 19 and 17 markers were localized to A-subgenomes (chromosome 1–13) and D-subgenomes (chromosome 14–26), respectively. The subgenome status for the remaining three markers remained unclear due to their two potential chromosome locations achieved by tertiary monosomic stocks deletion analysis. Chromosomal assignment of these BAC-derived SSR markers will help in integrating physical and cotton genetic linkage maps and thus facilitate positional candidate gene cloning, comparative genome analysis, and the coordination of chromosome-based genome sequencing project in cotton. Disclaimer: Mention of trademark, proprietary product, or vendor does not constitute a guarantee or warranty of the product by USDA, ARS and does not imply its approval to the exclusion of other products or vendors that may also be suitable. The U.S. Government’s right to retain a non-exclusive, royalty-free license in and to any copyright is acknowledged.     

簇毛麦1V染色体SSR标记的筛选

选用位于普通小麦1A、1B、1D染色体上的32对微卫星引物对普通小麦中国春、簇毛麦、6个中国春-簇毛麦二体附加系和1个普通小麦-簇毛麦二体代换系进行SSR分析,发现引物Xgwm498在簇毛麦中扩增出2条长分别为110 bp和190 bp的片段（即Xgwm498/110和Xgwm498/190）, 这两个片段仅在簇毛麦、中国春-簇毛麦1Ha附加系中出现,其余2Ha、     

Genetic mapping of a new flowering time gene on chromosome 3B of wheat

The single chromosome substitution lines of chromosome 3B of the Czech alternative wheat variety Česká Přesívka (CP 3B) into two spring varieties Zlatka and Sandra, revealed clear differences in flowering time compared to the recipient varieties. To map this gene(s), recombinant substitution lines for chromosome 3B were produced from crosses of the substitution lines with their recipient parents and genetic maps developed using SSR markers. Two populations were mapped, Sandra//Sandra 3B/Sandra (CP 3B) and Zlatka//Zlatka/Zlatka (CP 3B). Combining the genotype data with phenotype data on flowering time in five independent experiments under natural long day or controlled short day conditions revealed a single flowering time QTL. This gene had an additive effect of 1–6 days, depending on environment and genetic background, and was mapped in both populations to a position in the region of marker Xbarc164 near the centromere on the long arm of 3B. Comparisons of the genetic maps with other 3B maps developed by the authors indicated that the QTL may be homologous to a QTL segregating in UK germplasm.     

小麦–华山新麦草异代换系DH2322的分子细胞遗传学鉴定

利用分子标记、细胞学、基因组原位杂交(GISH)等技术,结合田间农艺性状调查,对小麦–华山新麦草七倍体材料H8911与硬粒小麦D4286杂交F4代分离群体中株系DH2322进行了综合鉴定。华山新麦草基因组特异SCAR标记鉴定表明,DH2322含有华山新麦草遗传物质;细胞遗传学观察显示,DH2322染色体构型为2n=42=21 II;有丝分裂和花粉母细胞减数分裂中期I基因组原位杂交(GISH)鉴定表明,DH2322的染色体由40条小麦染色体和2条华山新麦草Ns染色体构成,且2条Ns染色体能完全配对为一个二价体;SSR和STS分子标记分析表明,DH2322缺失小麦D基因组的2D染色体,而含有华山新麦草的2Ns染色体;农艺性状分析结果表明,DH2322具有双亲的形态学特征,结实性好,穗长和穗粒数显著大于亲本。     

小麦抗白粉病新基因的AFLP和SSR标记及其染色体定位

M53 (YAV2/TEZ//Ae.squarrosa 249) 是硬粒小麦与粗山羊草的双二倍体合成种,携带一个抗白粉病新基因,暂命名为Pm-M53,该基因对北京地区白粉病优势生理小种15号表现免疫抗性。本研究利用来源于杂交组合M53/宛7107的一个F₂群体,在苗期采用白粉病15号小种（Blumeria graminis f. sp. tritici）接种,抗病反应型鉴定表明,抗感比例符合3∶1,说明其抗性受显性单基因控制;对部分F₂植株的F₃株系的抗病鉴定进一步证明了F₂鉴定的可靠性;利用AFLP和SSR标记技术结合F₂分离群体对目的基因进行了遗传作图,将目的基因定位在5D染色体的长臂上。其中AFLP标记P16M16_-109(Apm109)和P5M16_-161(Apm161)与目的基因的遗传距离分别为1.0和3.0 cM。SSR标记Xwmc289b、Xgwm583和Xgwm292与目的基因的遗传距离分别为20.0、33.0和24.0 cM。这些标记位于目的基因的两侧。利用中国春遗传背景的缺-四体和双端体结合AFLP标记Apm109确证了SSR标记定位的可靠性,进一步证明该基因是一个新的抗白粉病基因。     

Rapid introduction of disease resistance from rye into common wheat by anther culture of a 6x triticale × nulli-tetrasomic wheat

Powdery mildew (caused by Erysiphe graminis) and yellow rust (caused by Puccinia striiformis) are the two most serious wheat diseases found in China. Rye chromosomes, carrying genes for resistance to these diseases, were introduced into common wheat in two generations using chromosome engineering and anther culture. The F₁ hybrids from a cross involving a hexaploid triticale (×Triticosecale Wittmack) בChinese Spring’ nulli‐tetrasomic N6DT6A wheat aneuploid line were anther cultured and doubled‐haploid plants were regenerated. Using genomic in situ hybridization, C‐banding and biochemical marker analyses, one of the anther‐cultured lines (ZH‐1)studied in detail, proved to be a doubled‐haploid with one rye chromosome pair added (1R) and a homozygous 6R/6D substitution (2n= 44). The line was tested for expression of disease resistance and found to be highly resistant to powdery mildew and moderately resistant to yellow rust.     

Ph I-induced transfer of leaf and stripe rust-resistance genes from Aegilops triuncialis and Ae. geniculata to bread wheat

Leaf and stripe rusts are severe foliar diseases of bread wheat. Recently, chromosomes 5M^g from the related species Aegilops geniculata that confers resistance to both leaf and stripe rust and 5U^t from Ae. triuncialis conferring resistance to leaf rust have been transferred to bread wheat in the form of disomic DS5M^g(5D) and DS5U^t(5A) chromosome substitution lines. The objective of this study was to shorten the alien segments in these lines using Ph ^I-mediated, induced homoeologous recombination. Putativerecombinants were evaluated for their rust resistance, and by genomic in situ hybridization and microsatellite analyses. One agronomically useful wheat-Ae. geniculata recombinant resistant to leaf and stripe rust was identified that had only a small terminal segment of the 5M^gL arm transferred to the long arm of an unidentified wheat chromosome. This germplasm can be used directly in breeding programs. Only one leaf rust-resistant wheat-Ae. triuncialis recombinant, which consists of most of the complete 5U^t chromosome with a small terminal segment derived from 5AS, was identified. This germplasm will need further chromosome engineering before it can be used in wheat improvement. This revised version was published online in August 2006 with corrections to the Cover Date.     

Characterization of wheat-triticale doubled haploid lines by cytological and biochemical markers

Five wheat-triticale doubled haploid (DH) lines— M08, V209, DH220-14-2, DH696-3-4 and M16 —derived from anther culture of F₁s resulting from crosses involving hexaploid or octoploid triticale × hexaploid wheat, were characterized by cytological and biochemical markers. Cytological evidence from genomic in situ hybridization and C-banding indicated that DH lines M08 and V209 (2n= 42) each contained a pair of 1BL/1RS translocation chromosomes. DH220-14-2 (2n= 42) was also a translocated line with two pairs of chromosomes containing small fragments of rye. One of the translocation fragments carried the Sec-1R gene originating from the satellite region of 1RS; the origin of the other one remains unknown. DH696-3-4 (2n= 42) contained a 3D(3R) substitution. In M16 (2n= 44), three pairs of rye chromosomes, 3R, 4R and 6R, were present, 4R as an addition and 3D(3R) and 6D(6R) as substitutions. Biochemical, isozyme and storage protein markers confirmed the cytological conclusions. The advantages of transferring alien chromosomes or chromosome fragments into wheat and creating alien aneuploid lines by anther culture of hybrid F¹s are discussed.