Introgression of sharp eyespot resistance from Dasypyrum villosum chromosome 2VL into bread wheat

Wheat sharp eyespot, a stem disease caused by the soilborne fungus Rhizoctonia cerealis van der Hoeven,has become a threat to wheat production worldwide. Exploiting resistance resources from wild relatives of wheat is a promising strategy for controlling this disease. In this study, a new wheat–Dasypyrum villosum T2DS·2V#4L translocation line in the background of Chinese Spring(CS) showed stable resistance to R. cerealis. Introgression of the T2DS·2V#4L chromosome into wheat cultivar Aikang 58 by backcrossing produced a marked increase in sharp eyespot resistance in NIL-T2DS·2V#4L in comparison with NILT2DS·2DL, and no detrimental effects of 2V#4L on agronomic traits were observed in the BC2F2, BC2F2:3,and BC2F2:4generations. Flow-sorted sequencing of 2V#4L yielded 384.3 Mb of assembled sequence, and8836 genes were predicted of which 6154 had orthologs in at least one of the 2AL, 2BL, and 2DL arms of CS, whereas 1549 genes were unique to 2V#4L. About 100,000 SNPs were detected in genes of 2V#4L and2DL in 10 sequenced bread wheat cultivars. A Kompetitive Allele Specific Polymerase chain reaction and30 conserved ortholog sequence markers were developed to trace the 2V#4L chromatin in wheat backgrounds. T2DS·2V#4L compensating translocation lines represent novel germplasm with sharp eyespot resistance and the markers will allow rapid detection in breeding programs.

簇毛麦(Dasypyrum villosum)GA20ox基因的分离和鉴定

通过RT-PCR技术克隆了簇毛麦(Dasypyrum villosum)赤霉素生物合成关键酶GA20ox基因的全长序列,命名为DvGA20ox,GenBank登录号为EU142949.该基因全长1080bp,推测编码359个氨基酸的蛋白质,具有植物GA20ox基因的典型保守结构域LPWKET和NYYPXCQKP.该基因推导编码蛋白质与小麦、大麦和黑麦草GA20ox蛋白的同源性分别为98%、97%和91%.该序列重组到原核表达载体pET-32a(+)获得的重组子pET-32a(+)-DvGA20ox转化大肠杆菌BL21pLysS后,IPTG诱导表达,SDS-PAGE分析表明,DvGA20ox基因在大肠杆菌中获得了高效表达,融合蛋白相对分子质量为55×103,与理论值相符.结果为深入研究DvGA20ox蛋白的结构与功能以及该基因与株高发育的关系奠定了基础.

Pm67, a new powdery mildew resistance gene transferred from Dasypyrum villosum chromosome 1V to common wheat(Triticum aestivum L.)

Powdery mildew, caused by the biotrophic fungus Blumeria graminis f. sp. tritici(Bgt), is a global disease that poses a serious threat to wheat production. To explore additional resistance gene, a wheatDasypyrum villosum 1 V#5(1 D) disomic substitution line NAU1813(2 n = 42) with high level of seedling resistance to powdery mildew was used to generate the recombination between chromosomes 1 V#5 and1 D. Four introgression lines, including t1 VS#5 ditelosomic addition line NAU1815, t1 VL#5 ditelosomic addition line NAU1816, homozygous T1 DL·1 VS#5 translocation line NAU1817, and homozygous T1 DS·1 VL#5 translocation line NAU1818 were developed from the selfing progenies of 1 V#5 and 1 D double monosomic line that derived from F1 hybrids of NAU1813/NAU0686. All of them were characterized by fluorescence in situ hybridization, genomic in situ hybridization, 1 V-specific markers analysis, and powdery mildew tests at different developmental stages. A new powdery mildew resistance gene named Pm67 was physically located in the terminal bin(FL 0.70–1.00) of 1 VS#5. Lines with Pm67 exhibited seedling stage immunity and tissue-differentiated reactions at adult plant stage. The sheaths, stems, and spikes of the Pm67 line were still immune, but the leaves showed a low degree of susceptibility.Microscopic observation showed that most penetration attempts were stopped in association with papillae on the sheath, and colonies cannot form conidia on the susceptible leaf of Pm67 line at adult plant stage, suggesting that the defence layers of the Pm67 line is tissue-differentiated. Thus, the T1 DL·1 VS#5 translocation line NAU1817 provides a new germplasm in wheat breeding for improvement of powdery mildew resistance.

簇毛麦(Dasypyrum villosum L.)中一个γ-醇溶蛋白基因序列的研究

目的:研究簇毛麦中一个新的γ-醇溶蛋白基因序列及结构特点,为小麦品质育种和该类基因的进化分析提供资料。方法:利用基因组PCR技术从簇毛麦基因组中克隆到1个γ-醇溶蛋白基因(Dv-γ)的全编码序列,利用生物信息学研究其序列结构特点。结果:该序列与已知的γ-醇溶蛋白有着很高的相似性。推导的氨基酸序列包含5个典型的结构域,其中含有8个保守半胱氨酸残基,高变重复区Ⅱ中的重复单元与其他物种来源基因有较大区别。γ-醇溶蛋白中常见的乳糜泄抗原决定簇在其内部也有发现。进化分析表明,此基因与亚家族Ⅰ中的γ-醇溶蛋白基因有着较近的亲缘关系。结论:获得了一个新的γ-醇溶蛋白基因。

Genetic behavior of Triticum aestivum–Dasypyrum villosum translocation chromosomes T6V#4S·6DL and T6V#2S·6AL carrying powdery mildew resistance

T6V#2S·6AL and T6V#4S·6DL translocation chromosomes developed from the cross of wheat and different Dasypyrum villosum accessions have good powdery mildew （PM） resistance, but their pairing and pyramiding behavior remains unclear. Results in this study indicated that the pairing frequency rate of the two differently originated 6VS chromosomes in their F1 hybrid was 18.9% according to genomic in situ hybridization （GISH）; the PM resistance plants in the F2 generation from the cross between T6V#4S·6DL translocation line Pm97033 and its PM susceptible wheat variety Wan7107 was fewer than expected. However, the ratio of the resistant vs. the susceptible plants of 15：1 in the F2 generation derived from the cross between the two translocation lines of T6V#2S·6AL and T6V#4S·6DL fitted well. Plants segregation ratio （homozygous：heterozygous：lacking） revealed by molecular marker for T6V#4S·6DL or T6V#2S·6AL in their F2 populations fitted the expected values of 1：2：1 well, inferring that the pairing of the two alien chromosome arms facilitates the transmission of T6V#4S·6DL from the F1 to the F2 generation. A quadrivalent was also observed in 21% of pollen mother cells （PMCs） of homozygote plants containing the two pairs of translocated chromosomes. The chromosome pairing between 6V#2S and 6V#4S indicates that it will be possible to obtain recombinants and clarify if the PM resistance determinant on one alien chromosome arm is different from that on the other.

Development of EST-PCR markers specific to the long arm of chromosome 6V of Dasypyrum villosum

Expressed sequence tags-derived polymerase chain reaction(EST-PCR) molecular markers specific for alien chromosomes can be used to not only monitor the introgressed alien chromatin in wheat background, but also provide the evidence of the syntenic relationship between homoeologous chromosomes. In the present study, in order to develop high density and evenly distributed molecular markers specific for chromosome 6 VL of Dasypyrum villosum, 297 primer pairs were designed based on the expressed sequence tags(EST) sequences, which were previously mapped in different bins of the long arms of wheat homoeologous 6 AL, 6 BL, and 6 DL. By using the Triticum aestivum, D. villosum, T. durum-D. villosum amphiploid, and T. aestivum-D. villosum alien chromosome lines involving chromosome 6 V, it was found that 32(10.77%) primers could amplify specific bands for chromosome 6 V, and 31 could be allocated to chromosome arm 6 VL. These 6 VL specific markers provided efficient tools for the characterization of structural variation involving the chromosome 6 VL in common wheat background as well as for the selection of useful genes located on 6 VL in breeding programs.

Characterization and Expression Profiling of Genes Encoding the Gibberellin 3-oxidase in Dasypyrum villosum Dwarf Mutant

Gibberellin 3-oxidase catalyzes the conversion of inactive gibberellin(GA) species into GAs with biological activity and it is subjected to strict developmental controls in the life cycle of a plant. In this study, 33 gene sequences, encoding the gibberellin 3-oxidase(GA3ox) from Dasypyrum villosum and its dwarf mutant, were obtained. Each contained a 1 107 bp coding sequence(CDS) that encoded a putative protein containing 369 amino acids. The GA3ox protein showed 77% to 97% homology and shared the major conserved structural domains of GA3ox proteins with rice, sorghum bicolor, oat, barley, and wheat. Sequence alignment showed that there were 20 single nucleotide polymorphisms(SNPs) and 22 Insertion/deletions(In Dels) among these sequences, which could be divided into 2 haplotypes, haplotypes Ⅰ and Ⅱ. Haplotype Ⅰ was found in the wild type and was1 495 bp in length, and haplotype Ⅱ was found in the dwarf mutant and was 1 485 bp in length. The Q-PCR results showed that GA3ox was expressed in the leaves, roots, internodes, and stem nodes, and that there was a significant difference in the transcript level of the GA3ox between the wild type and dwarf mutant. The transcript levels of GA3ox in the leaves at the seedling stage, stem elongation stage and the heading stage, in the root and stem nodes at the stem elongation stage and in the internodes at the heading stage of the wild type, were significantly higher than those in the dwarf mutant. However, GA3ox expression in the rest of the wild type tissues at the 3 stages was slightly higher than or not different from the dwarf mutant.The results suggested that the wild type and mutant allele sequences of GA3ox in D. villosum showed 2 amino acid changes in exons and variations in the lengths of introns or the SNPs in introns, which most probably impaired the function of the enzyme,affected the GA3ox expression level, and eventually gave rise to dwarfing.

簇毛麦(Dasypyrumvillosum)矮秆突变体的鉴定

为给簇毛麦杂交后代群体中自然突变产生的矮秆突变体在小麦遗传改良中合理有效的利用提供理论依据,对该矮秆突变体的生物学及遗传学特性进行了初步研究。该突变体在苗期与对照植株无明显差异,在成熟期突变体株高30 cm,约为对照株高的1/3。突变株茎的倒一、二节间(最上部的两个茎节)长度分别为对照植株长度的1/9和1/6。细胞学观察表明,突变体的茎节细胞纵向延长受到抑制。此外,该突变株还表现出部分雄性不育,自然结实率低。花粉活力检测发现,突变株可育花粉只有20%,在外施GA3后花粉育性可得到恢复,推测该突变体为赤霉素敏感型矮秆突变体。遗传分析表明,矮秆突变性状受一个隐性基因控制。

一个成株抗白粉病小麦-簇毛麦T2DS·2V#6L易位系的选育

白粉病是威胁全球小麦生产的一种严重病害,从小麦野生近缘种发掘成株抗白粉病基因资源对培育持久抗性品种十分重要。本研究从硬粒小麦-簇毛麦01I139(V#6)双二倍体AABBVV-3与普通小麦NAU0686杂交、回交的后代中鉴定到一个小麦-簇毛麦2V#6(2D)异代换系11-2V-1,利用11-2V-1在染色体2V和2D之间产生重组,将11-2V-1与高感白粉病普通小麦NAU0686杂交,F_(1)自交。利用GISH/FISH和分子标记对F_(2)世代131个单株进行分子细胞学鉴定,获得了小麦-簇毛麦T2DS·2V#6L易位系11-2V-2、2V#6S端体系11-2V-3和2V#6L端体系11-2V-4新种质。白粉病抗性鉴定发现,所有F_(2)单株苗期均高感小麦白粉菌生理小种E09,但成株期含有2V#6和2V#6L染色体臂的所有单株均表现高抗(IT=1~2),而仅含有2V#6S染色体臂或无外源染色体的单株均高感白粉病(IT=7~9),表明簇毛麦01I139的2V#6L染色体臂上携带成株抗白粉病基因,该基因可能与小麦-簇毛麦T2BS·2V#5L易位系携带的Pm62是等位基因。遗传效应分析表明,T2DS·2V#6L易位染色体在小麦背景传递正常,对主要农艺性状没有显著的负向影响,对穗长、每穗粒数和单株粒重还表现出一定程度的正向效应。因此,本研究创制的成株抗白粉病T2DS·2V#6L易位系11-2V-2为小麦抗白粉病育种提供了新抗源,也为后续簇毛麦2VL上优异基因遗传定位和图位克隆奠定了基础。

一年生簇毛麦基因资源挖掘与利用研究进展

一年生簇毛麦(Dasypyrum villosum (L.) Candargy)是普通小麦野生近缘种之一,也是近年来应用较广泛的小麦遗传资源。簇毛麦在长期进化过程中,形成了许多可用于小麦遗传改良的重要农艺性状,包括对非生物和生物胁迫的抗性、优良品质等。本文简述了簇毛麦与普通小麦的同源关系、与小麦属杂交亲和性,以及将簇毛麦染色体、片段、基因导入普通小麦的有效方法,综述了簇毛麦对白粉病、纹枯病、条锈病、眼斑病、黄花叶病、全蚀病、胞囊线虫病等病害的抗性基因和对应的染色体,簇毛麦品质基因(如:高赖氨酸含量和多态性贮藏蛋白等)和簇毛麦耐旱、光周期等其他基因。介绍了簇毛麦抗白粉病基因Pm21和PmV在小麦改良和育种中的应用及其巨大价值,展望了簇毛麦后续研究前景和可能存在的问题。本综述对挖掘与利用簇毛麦有益基因、拓宽小麦遗传资源、加快小麦遗传改良进程以及重要基因功能研究均具有参考价值。

InDel分子标记WC656的开发及其在鉴别小麦-簇毛麦5VS纯合易位中的应用

簇毛麦是小麦品种改良重要的遗传资源,其5VS上含有硬度基因Dina/Dinb、抗白粉病基因Pm55和抗条锈病基因Yr5V,创制普通小麦-簇毛麦5VS易位系新种质,对于高效利用5VS上的有益基因进行小麦品种遗传改良具有重要意义。为了便于鉴别普通小麦-簇毛麦5VS纯合易位,本研究以mInDel软件分析普通小麦中国春基因组序列,开发了小麦第5同源群短臂的InDel特异分子标记WC656,对小麦品种以及普通小麦-簇毛麦5VS.5AL和5VS.5DL易位系及其衍生后代进行PCR扩增,根据扩增片段大小来区分5AS、5BS、5DS染色体臂以及5VS易位系。结果表明,在21个普通小麦品种、小麦-簇毛麦5VS回交F 2代中杂合易位单株,均扩增出379 bp(5AS)、471 bp(5BS)、422 bp(5DS)3条带。在T5VS.5AL高代品系、回交F 2代中纯合易位单株扩增出471 bp(5BS)、422 bp(5DS)2条带,379 bp(5AS)条带缺失。T5VS.5DL高代品系、回交F 2代中纯合易位单株扩增出379 bp(5AS)、471 bp(5BS)2条带,422 bp(5DS)条带缺失。WC656鉴别的5VS纯合易位结果与顺序FISH-GISH分析结果一致。T5VS.5AL、T5VS.5DL具有抗白粉病、籽粒硬度指数低等优良特性。因此,利用InDel分子标记WC656可以鉴别普通小麦-簇毛麦T5VS.5AL、T5VS.5DL衍生后代中的纯合易位,PCR扩增实验操作相对简便,可以为分子标记辅助选育携有5VS纯合易位的软质弱筋小麦提供帮助。

二套小麦-簇毛麦染色体附加系苗期耐盐性及籽粒硒和叶酸的含量

簇毛麦(Dasypyrum villosum)作为小麦的近缘种,具有许多优良基因,是改善小麦耐盐性和提高小麦营养品质的理想材料。以小麦-簇毛麦#2和小麦-簇毛麦#3二体附加系为材料,进行耐盐性鉴定及籽粒中硒和叶酸含量的测定。发现小麦-簇毛麦#2附加系和#3附加系在盐胁迫下的萌发率分别为16.67%-43.33%、26.67%-70.00%,均高于对照中国春(6.65%);盐胁迫下附加系DA3V#3、DA7V#3、DA2V#3和DA5V#2的萌发率分别为70.00%、56.67%、53.33%和43.33%;盐胁迫下附加系的生长正常,株高和根长均大于对照中国春,其中DA4V#2和DA2V#3的株高分别达到15.2和16.1 cm,DA2V#3根长为3.4 cm;在14个附加系和对照中,DA2V#2和DA2V#3籽粒硒含量最高,分别为8.47和7.60μg/g。小麦-簇毛麦#2附加系和#3附加系籽粒中叶酸含量为9.00-26.10μg/100 g,大多数附加系高于对照中国春(10.98μg/100 g),其中,附加系DA4V#2和DA6V#2与对照差异达极显著水平,DA6V#2比对照增加2.4倍。簇毛麦2V#3、3V#3和5V#2染色体可能存在耐盐相关基因,2V染色体可能存在富硒相关基因,6V#2染色体可能携带籽粒叶酸合成的相关基因。

利用组织培养和辐射诱变创造高频率小麦与簇毛麦染色体易位

利用荧光原位杂交证明普通小麦与硬粒小麦-簇毛麦双二倍体杂种培养细胞和再生植株中能够发生属间染色体易位，易位染色体不仅有臂间易位，还有小片段易位，表明通过杂种组织培养是创造属间易位的一个可行的方法。辐射处理能够大幅度促进杂种愈伤组织细胞中的染色体数目和结构变异，特别是易位频率达到7.4％。观察还表明，培养时间对杂种愈伤组织细胞中染色体数目和结构变异都有较大影响，培养细胞的染色体变异在培养的初期阶段就已出现。在一定时间里，随培养时间的延长，未发生变异的细胞频率逐渐下降，染色体数目减少的细胞逐渐增多。培养时间对染色体数目增加的细胞频率影响不大。对于染色体结构变异，培养时间延长主要是提高了端着丝点染色体的频率。在杂种培养细胞中还观察到一定频率的染色体加倍细胞（2n=84），但是培养一段时间后这类细胞就逐渐消失了。

普通小麦-簇毛麦种质对菲利普孢囊线虫的抗性分析

菲利普孢囊线虫(Heterodera filipjevi)是在我国新发现的一种小麦病原线虫,已严重威胁我国小麦的安全生产。小麦近缘种属具有改良小麦所需的许多目标性状,是丰富小麦遗传变异、选育抗病品种的重要基因资源。采用室内接种鉴定法,从20份小麦近缘属种材料中发现簇毛麦(Dasypyrum villosum)高抗H.filipjevi。分别对3套普通小麦–簇毛麦染色体附加系和6VS易位系进行接虫抗性鉴定,结果6V染色体附加系高抗H.filipjevi;含6VS的易位系则表现感病。据此推测,簇毛麦6V染色体上可能含有抗H.filipjevi基因,且可能位于6VL上。

簇毛麦6VS特异转录序列P21461及P33259的获得及其分子标记在鉴定小麦-簇毛麦抗白粉病育种材料中的应用

簇毛麦6V#2S和6V#4S染色体臂分别携带抗白粉病基因Pm21和Pm V,在与小麦的杂种后代中,抗病基因与外源染色体臂共分离。开发鉴定2条外源染色体臂间多态性的序列,尤其是遗传信息相对缺乏的6V#4S染色体臂的序列,对于其在遗传与育种上的应用具有重要意义。本研究以携带6V#4S·6DL染色体的小麦易位系Pm97033及感病小麦亲本宛7107接种白粉菌的叶片转录组数据为资源,通过差异基因筛选、共线性分析、簇毛麦基因组扩增及测序验证的方法,鉴定出来自6V#4S的表达序列P21461和P33259,其中基于P21461序列设计的引物P461-5在簇毛麦6V#2S和6V#4S染色体臂的扩增产物具有30 bp的In Del和4 nt的多态性。用该引物转化的标记P461-5a可以鉴定抗白粉病小麦品种和高代品系所含的外源染色体,显示其在簇毛麦抗源鉴别和小麦抗病育种辅助选择中潜在的应用价值。根据P33259开发的标记P259-1可以对含有6V#4S染色体臂的材料进行特异扩增,但对6V#2S·6AL易位染色体没有扩增产物,因此P259-1可作为6V#4S·6DL易位染色体的特异分子标记。q RT-PCR分析结果显示,P21461的表达不受白粉菌诱导,而P33259在接菌后12 h和24 h的转录水平比接菌前提高约2倍,推测其可能参与Pm97033与白粉菌的早期互作。

簇毛麦HMW-GS及其启动子基因的克隆与序列分析

利用2对特异引物,从簇毛麦(Dasypyrum villosum)基因组中分离克隆出一个簇毛麦HMW-GS基因VHG-2(GenBank登录号为FJ600492)及其启动子序列VHGp-1(GenBank登录号为FJ600489).VHGp-1序列长度为1099bp,从5′至3′方向依次有E-box、N-box、G-box、HMW谷蛋白特异38bp增强子和TATA-box等典型的HMW-GS基因启动子作用调控元件,说明VHGp-1为簇毛麦HMW-GS的启动子基因.VHG-2序列长度为1572bp,具有单一完整的、可编码498个氨基酸的开放阅读框(ORF),该ORF推导的氨基酸序列结构分析表明,编码区依次包含由21个氨基酸残基组成的信号肽、105个氨基酸残基组成的N-末端区、330个氨基酸残基组成的中部重复区和42个氨基酸残基组成的C-末端区;中部重复区主要重复单元为6肽(PQQGQQ)和9肽(GYYPTSP/LQQ);有6个半胱氨酸残基(Cys),其中5个分布在N-末端区,1个分布在C-末端区,第3、4个相邻.这些特征与报道的y-型HMW-GS多肽结构基本一致,说明VHG-2是簇毛麦的y-型HMW-GS基因.系统进化分析表明,簇毛麦HMW-GS启动子序列(VHGP-1)与智利大麦(H.chilense)H基因组的D-hordein基因、拟鹅观草和阿拉善鹅观草St基因组的HMW-GS基因的启动子具有比较近的同源关系,簇毛麦HMW-GS基因(VHG-2)与冰草、拟鹅观草和中间偃麦草的y-型HMW-GS基因具有较近的同源关系.

普通小麦与硬粒小麦-簇毛麦双二倍体杂种体细胞无性系的建立

普通小麦比较容易与硬粒小麦-簇毛麦双二倍体 TH_1和 TH_1W杂交,所选的 9个普通小麦品种或品系与 TH_1和 TH_1W的 19个杂交组合,平均结实率为 46.7％,共计获得 19个杂交组合2316粒杂种种子。正反交结果表明,以普通小麦为母本的杂交结实率高于反交结实率,但是在杂种幼胚愈伤组织诱导率受正反交的影响小于杂交结实率。在继代培养过程中,杂种幼胚愈伤组织生长迅速,甚至直接诱导出绿苗,共获得不同杂交组合2005株再生植株,移栽成活率达到95％以上。观察还发现有少量再生植株发生形态变异,但是组织培养对提高普通小麦×硬粒小麦-簇毛麦双二倍体杂种育性没有明显的作用。

节节麦-簇毛麦属间杂种的形态学和细胞遗传学研究

通过远缘杂交,结合杂种幼胚离体培养,获得了节节麦(Aegilopstauschii,2n=14,DD)和簇毛麦(Dasypyrumvillosum,2n=14,VV)的属间杂种F1。对杂种F1花粉母细胞减数(PMC)分裂中期Ⅰ(MⅠ)染色体配对行为进行观察发现,"节节麦×簇毛麦"杂种F1平均每PMC有1 25个棒状二价体,染色体的平均构型为2n=14=11 49Ⅰ+1 25Ⅱ(Xta=1 25),大部分被观察的细胞出现1～5个二价体,表明节节麦D染色体与簇毛麦V染色体间具有相对较高的部分同源配对,D和V染色体之间存在一定的部分同源性。F1植株高度自交不育,经染色体加倍处理后能够自交结实。

普通小麦与簇毛麦远缘杂交的受精和早期胚胎发育

用石腊制片法,对普通小麦“中国春”Triticum aestivum Lcv.ChineseSpring和簇毛麦Dasypyrum villosum (L) Candargy杂交的受精和早期胚胎发育进行了观察。结果表明, 簇毛麦花粉在小麦柱头上萌发良好, 花粉管可顺利长入花柱和胚囊。观察的210个小麦子房中, 13.81% 发生了双受精, 产生胚和胚乳; 16.19% 发生了卵细胞单受精,只产生胚而无胚乳;4.76% 发生了极核单受精,产生胚乳而无胚; 总受精率为34.76% ,成胚率为30.00% 。由于胚乳发育滞后于合子发育,生理不协调,胚乳缺乏或发育异常或解体, 最终难以获得有生活力的种子。在授粉后7～11d对杂种幼胚通过组织培养, 实行离体拯救, 会提高杂种植株的获得率, 为成功的簇毛麦外源基因转移到小麦中提供杂种生殖生物学证据。

鹅观草和簇毛麦属间杂种的形态学和细胞遗传学研究

通过幼胚离体拯救培养，成功地获得鹅观草ＲｏｅｇｎｅｒｉａｋａｍｏｊｉＯｈｗｉ（２ｎ＝６ｘ＝４２，ＳｔＳｔＨＨＹＹ）和簇毛麦Ｄａｓｙｐｙｒｕｍｖｉｌｏｓｕｍ（Ｌ．）Ｃａｎｄａｒｇｙ（２ｎ＝２ｘ＝１４，ＶＶ）属间杂种，对这两个种及其杂种Ｆ１的形态学、繁育学和减数分裂配对行为进行了研究。结果表明：（１）鹅观草和簇毛麦形态差异极大，杂种Ｆ１的形态特征介于父母本之间；（２）杂交结实率低，为１１．６３％；经幼胚组织培养，获２株杂种苗；杂种Ｆ１高度不育，表明亲本间存在极强的生殖隔离，是独立的生物学种；（３）杂种Ｆ１体细胞染色体数目为稳定的２８条，减数分裂中期Ⅰ染色体配对很低，其构型为：２６．７２Ⅰ＋０．６２Ⅱ＋０．０２Ⅲ。表明鹅观草的Ｓｔ、Ｈ、Ｙ染色体组与簇毛麦的Ｖ染色体组部分同源性很低，它们的亲缘关系较远。