小麦和无融合生殖披碱草杂交后代（BC2F2）的无融合生殖及胚胎发育过程中的异常现象研究

对小麦（Triticum aestivum）和无融合生殖披碱草（Elymus rectisetus）的染 色体数目为42的杂种后代（BC2F2）单株进行了RAPD检测和胚胎学研究。RAPD检测结果表明：染色体数目为42条的BC2F2单株的遗传组成与普通小麦的遗传组成十分接近,但是在部分单株中出现了披碱草的特异带。由此可以推测,经过回交和自交后小麦草的部分染色体片段已经整合进了小麦的染色体。在部分BC2F2单株胚胎学切片中发现了较高比例的（5%左右）双孢原、早发胚以及多胚囊等无融合生殖现象,直接表明了无融合生殖基因转移。由于基因整合的多样性,无融合生殖基因在有些单株中并没有充分表达,从而造成了某些单株胚胎发育的异常。     

披碱草 Elymus rectisetus无融合生殖及其转育的研究进展

披碱草Elymus rectisetus(Nees in Lehm）A Loeve et Connor(2n=6x=42）,SSYYWW）是目前发现的小麦族（Triticeae）中唯一的无融合生殖种,属二倍性孢子形成的假受精无融合生殖类型,无融合生殖能固定杂种优势,简化育种程序,缩短育种年限,因此E.rectisetus无融合生殖及其向小麦中导入的研究一直受到遗传育种学家的重视,与有性生殖相比,无融合生殖类型大孢子母细胞（MMC）的形成有三个显著特点：（1）MMC在早前期合点形成液泡;（2）MMC核显著伸长,呈椭圆形或哑玲形;（3）MMC周围缺乏含,胼胝质的细胞壁E.rectisetus与披碱草属内的种间杂交取得较大进展,了其分类和遗传学研究。E.rectisetus与近缘属杂交成功例子逐渐增多,目前国内外已成功进行了普通小麦与E.rectisetus属间杂交,为最终将E.rectisetus无融合生殖基因导入小麦奠定了基础。     

2n雄配子的无融合生殖披碱草（Elymus rectisetus）减数分裂行为研究

用能自然产生2n雄配子的无融合生殖六倍体披碱草为材料,研究了无融合生殖披碱草的减数分裂行为。结果表明：2n雄配子的无融合生殖披碱草减数分裂行为较为异常。在间期细胞内经常有微核存在;在前期I,有倒位环、多介染色体等异常现象;在中期I,染色体有不等分裂的倾向;在后期I和末期I,有染色体的单极分裂（63.9%）、染色走向一极的倾向（21.7%）和多极分裂（3.3%）等现象,单极分裂的结果是不减数配子的产生。在减数分裂Ⅱ中,有高比例的二分子孢子（55.7%）和三分子孢子（23.7%）的形成,二分子孢子在发育后期也直接导致了2n配子的产生。因此,染色体的单极分裂、二分体和三分体形成这3种方式是披碱草2n雄配子的形成的主要途径。     

大黍无融合生殖研究概况

从胚胎学和遗传学角度论述了大黍（Panicum maximum Jacq)的无融合生殖研究进展和存在的问题,展望了大黍作为无融合生殖基因供体。在无融合生殖研究上的利用前景。     

利用RAPD标记鉴定甜菜无融合生殖的同一性

目的：对具有无融合生殖特性的带有白花甜菜染色体的栽培甜菜单体附加系M14三代材料进行同一性鉴定。方法：通过RAPD随机扩增技术对M14三代材料的基因组DNA的扩增多态性进行分析。结果表明,M141998年、1999年、2000年三代材料的RAPD位点高度一致,遗传相似度S＝1,遗传距离D＝0,从而表明M14三代个体完全一样。结论：初步确定M14材料无融合生殖基因在其后代中是稳定传递的。     

普通小麦与东方旱麦草杂交世代的细胞遗传学研究

对普通小麦（TriticumaestivumL．）与东方旱麦草（Eremopyrumorientale（Ledeb）Jaub．etspach）属间杂种的回交和自交不同世代（BC2F1、BC3F1、BC2F2、BC3F2和BC2F3）进行了细胞遗传学研究。结果表明,BC2F1代（2n＝44）的植株回交产生的BC3F1代分离2n＝43植株的比例较高;为41．09％,2n＝44的植株类型的比例仅为4．11％;从自交后代BC2F2中分离2n=44植株类型的比例较高,为13．21％。回交二代（BC2F1）多数单株花粉母细胞（PMC）减数分裂过程中出现的单价体数较高,且回交结实率和自交结实率分别与该植株平均每PMC中出现的单价体数呈负相关,其相关系数分别为-0．6766和-0．7429。对BC2F3代部分种子进行的基因组原位杂交检测显示,2n＝44的不同植株所含有的外源染色体数目仍有不同。这些结果说明,由于外源染色体的存在,影响了小麦本身同源染色体的正常配对和分离,降低了小麦染色体的遗传稳定性。     

第二届无融合生殖国际会议概况

第二届无融合生殖国际会议于２００１年４月２４日－２８日在意大利科摩召开。参加会议的１５９人分别来自意大利、法国、德国、美国、俄罗斯、英国、日本、印度、中国等２８个国家。 会议内容包括无融合生殖机制与进化,农作物无融合生殖育种,无融合生殖基因的分离,胚珠与雌配子体发育,细胞周期与减数分裂,受精与孤雌生殖,胚胎发生,胚乳发育和无融合生殖的经济和生态等。 在无融合生殖的遗传学机制方面,提出了几种新模型。 Ｙｖｅｓ Ｓａｖｉｄａｎ根据一些禾本科植物无融合生殖胚胎学与遗传学研究结果提出了１对基因控制模型。Ｅ．…     

植物无融合生殖研究新进展

无融合生殖是指不经过雌雄配子融合而产生种子的一种特殊生殖方式,能使基因型的杂合性得以保持,从而可以固定杂种优势,对作物育种具有极其重要的意义。目前大量的研究都在设法将无融合生殖作为一种重要的植物育种手段。本文对近几年来无融合生殖新种质资源的发现、主要研究方法、遗传机制和相关基因等方面的最新进展作了介绍,并对无融合生殖研究中存在的问题和发展前景作了讨论。     

单子叶植物无融合生殖的研究进展

植物的无融合生殖是指不经过雌雄配子融合而产生种子的一种特殊生殖方式。由于利用无融合生殖途径可以固定杂种优势,从而改良现有植物的育种策略,因此对无融合生殖的研究已成为生物学科的新生长点。本文主要从无融合生殖的概念和类型,无融合生殖在单子叶植物中的分布,无融合生殖的胚胎学,分子生物学和遗传学机制及创造新的无融合生殖种质资源的方法等6方面对单子叶植物的无融合生殖的研究进展进行了综述,并提出了今后开展无融合生殖研究的思路和设想。     

单子叶植物无融合生殖的研究进展

植物的无融合生殖是指不经过雌雄配子融合而产生种子的一种特殊生殖方式。由于利用无融合生殖途径可以固定杂种优势 ,从而改良现有植物的育种策略 ,因此对无融合生殖的研究已成为生物学科的新生长点。本文主要从无融合生殖的概念和类型 ,无融合生殖在单子叶植物中的分布 ,无融合生殖的胚胎学 ,分子生物学和遗传学机制及创造新的无融合生殖种质资源的方法等 6方面对单子叶植物的无融合生殖的研究进展进行了综述 ,并提出了今后开展无融合生殖研究的思路和设想     

Asymmetric Somatic Hybridization Between Wheat (Triticum aestivum) and Bromus inermis

Asymmetric hybridization was conducted between wheat and Brorrats inermis keyss which is a distanfiy related intergeneric plant (belonging to different tribe) of wheat and possesses some favorable traits, such as resistant to cold, drought and disease. Protoplasts isolated from young embryo-derived calli of common wheat ( Triticura aestivum L., tv. 99P, (AABBDD), 2n = 42) were fused with UV-treated protoplasts isolated from young embryo-derived calli of Bromus inermis by PEG method. Three clones (No. 1 ~ No. 3) were regenerated from the fusion products and differentiated into albino seedlings. The clones and the seedlings were all verified as hybrids by chromosome counting, isozyme and RAPD analysis. Their isozyme and RAPD pattern contained the characteristic bands of both parents as well as new band(s). The chromosome numbers of albino were in the range of 42~54 with small chromosomes of Bromus inerm/s and chromosome fragments. The above results confirmed that hybrid albinos were obtained.     

携带抗黄矮病基因的中间偃麦草染色体2Ai—2特异的分子标记

小麦－中间偃麦草二体异附加系Ｚ１、Ｚ２具有一对携带抗黄矮病基因的中间偃麦草染色体２Ａｉ－２。利用中间偃麦草（Ｔｈｉｎｏｐｙｒｕｍ ｉｎｔｅｒｍｅｄｉｕｍ （Ｈｏｓｔ） Ｂａｋｗｏｔｈ ａｎｄ Ｄｅｗｅｙ）和拟鹅冠草（Ｐｓｅｕｄｏｒｏｅｇｎｅｉａ ｓｔｒｉｇｏｓａ）基因组ＤＮＡ作探针,对Ｚ１、Ｚ２进行基因组原位杂交分析。结果表明,Ｚ１、Ｚ２附加的一对中间偃麦草染色体２Ａｉ－２为Ｓｔ－Ｅ染色体,Ｅ组染     

携带抗黄矮病基因的中间偃麦草染色体2Ai_2特异的分子标记

The wheat-Thinopyrum intermedium addition lines Z1,Z2 contain a pair of Th. intermedium chromosomes 2Ai-2 carrying the gene with resistance to barley yellow dwarf virus (BYDV). Genomic in situ hybridization (GISH) was used to analyze the chromosome constitution of Z1,Z2 by using genomic DNA probes from Th. intermedium and Pseudoroegneria strigosa. The results showed that the chromosome constitution of either Z1 or Z2 composes of 42 wheat chromosomes and two Th. intermedium chromosomes (2Ai-2). The 2Ai-2 chromosome is St-E intercalary translocation, in which the E genomic chromosome segment translocated into the middle region of the long arm of chromosome belonging to St genome. With the genomic DNA probe of Ps. strigosa, the GISH pattern specific to the 2Ai-2 chromosome may be used as a molecular cytogenetic marker. A detailed RFLP analysis on Z1, Z2 and their parents was carried out by using 12 probes on the wheat group 2 chromosomes. Twenty RFLP markers specific to the 2Ai-2 chromosome were identified. Two RAPD markers of OPR16 –350 and OPH09 -1580, specific to the 2Ai-2 chromosome, were identified from 280 RAPD primers. These molecular markers could be used to assisted-select translocation lines with small segment of the 2Ai-2 chromosome and provide tools to localize the BYDV resistance.     

Molecular characterization of a Thinopyrum intermedium group 2 chromosome (2Ai-2) conferring resistance to barley yellow dwarf virus.

The wheat--Thinopyrum intermedium addition lines Z1 and Z2 carry 21 pairs of wheat chromosomes and one pair of Th. intermedium chromosomes (2Ai-2) conferring resistance to barley yellow dwarf virus (BYDV). GISH results using the genomic DNA of Pseudoroegneria strigosa (S genome) as the probe indicated that the 2Ai-2 chromosome in Z1 and Z2 is an S-J intercalary translocation. Most of the 2Ai-2 chromosome belongs to the S genome, except for about one third in the middle region of the long arm that belongs to the J genome. The results of detailed RFLP analyses confirmed that the 2Ai-2 chromosome is extensively homoeologous to wheat group 2 chromosomes. Some new RFLP markers specific to the 2Ai-2 chromosome were identified. A RAPD marker, OP-R16(340), specific to the 2Ai-2 chromosome, was screened. We converted the RAPD marker into a sequence-characterized amplified region (SCAR) marker (designated SC-R16). The study establishes the basis for selecting translocation lines with small segments of the 2Ai-2 chromosome and localizing the BYDV resistance gene when introgressed into a wheat background.     

RAPD-based analysis of introgression of barley genetic material into the genome of alloplasmic wheat lines (Hordeum geniculatum All./ Triticum aestivum L.)

Genomes of three alloplasmic wheat lines obtained on the basis of barley--wheat hybrid Horderum geniculatum All. (2n = 28) x Triticum aestivum L. (2n = 42)(Pyrotrix 28) were examined using random amplified polymorphic DNA (RAPD) analysis. Line L-29 was obtained after first backcross of the initial hybrid with the wheat variety Pyrotrix 28 and ten subsequent self-pollinating generations. This line was represented by euploid plants with typical to the common wheat chromosome number (2n = 42), as well as by aneuploids, which contained an additional telocentric chromosome in the main karyotype (2n = 42 + t). Lines L-26 and L-27 were obtained by two backcrosses of one BC1 plant with the wheat variety Novosibirskaya 67 and one subsequent self-polination of one BC3 plant. Chromosome number in all these plants corresponded to 2n = 40 + 4t. RAPD analysis was carried out using seven primers, which were previously proved to be effective for identification of the barley genome fragments within hybrid genomes of alloplasmic lines. The presence of barley genome fragments in line L-29 was revealed by use of five primers, while in lines L-26 and L-27 these fragments were detected by use of one primer. The significant difference in the number of barley RAPD fragments in the genomes of alloplasmic lines obtained at different backcrossing stages suggests more intense displacement of barley genome during backcrossing compared to self-pollination in BC1 plants.     

Features of the formation of self-fertile euploid lines (2n = 42) by self-pollination of the 46-chromosome barley-wheat BC1 hybrid Hordeum marinum subsp. gussoneanum Hudson (= H. geniculatum All.) (2n = 28) x Triticum aestivum L. (2n = 42)

We studied some features of the development of self-fertile 42-chromosome lines on the base of self-pollination progeny of 46-chromosome plants obtained by backcrossing of barley--wheat hybrids Hordeum marinum subsp. gussoneanum Hudson (= H. geniculatum All.) (2n = 28) x Triticum aestivum L. (2n = 42). The stabilization of karyotypes, resulting in 42-chromosome plants of the wheat type was generally completed by generation BC1F10. The plants of all self-pollination progenies, including BC1F10, showed some phenotypic traits characteristic of wild barley. Plants of BC1F10 with the chromosome sets 2n = 42 and 2n = 42 + t were analyzed by RAPD with a set of 115 primers. Fragments of the wild barley genome were detected in RAPD patterns with 19 primers. Cross-hybridization confirmed that these fragments belonged to the wild barley genome. We raised four phenotypically different 42-chromosome lines from grains obtained from plants of generation BC1F10, and these lines proved to be cytogenetically stable and self-fertile when grown in the field.     

Use of RAPD- and STS-analysis for marking genes of a homeologic group from chromosome 5 of common wheat

The search for STS (sequence-tagged site) and RAPD (random amplified polymorphic DNA) markers tightly linked to some genes of homeologous group 5 chromosomes of common wheat Triticum aestivum L., more specifically, awns inhibitor genes (B1), vernalization response gene (Vrn1), and homeologous chromosome pairing gene (Ph1), was conducted. To estimate the linkage of the gene with the marker, wheat lines marked with recessive alleles b1 and vrn1 were used. RELP (restriction fragment length polymorphism) and SSR (simple sequence repeat) analyses of isogenic wheat lines were conducted to characterize the chromosomal region transferred to the isogenic line from the donor parent. In RAPD analysis of isogenic wheat lines marked with recessive alleles b1 and vrn1, 95 arbitrary primers were used. To develop STS markers, analysis of the primary structure of RELP markers Xpsr426 and Xcdo504, tightly linked to the Vrn1 gene, and the Xpsr1201 marker, located at the Ph1 locus, was carried out. Two markers that are tightly linked to the Vrn1 gene (5AL)--RAPD marker Xr405 and STS marker Xsts426--were obtained in this work. In addition, there is every reason to believe that Xsts426 can be used as a PCR marker of genes Vrn2 (5BL) and Vrn3 (5DL), while Xsts1201, of the gene Ph1 (5BL).     

中间偃麦草染色体2Ai-2特异PCR新标记的建立和St基因组特异序列的克隆

中间偃麦草麦、小麦和小麦－中间偃麦草2Ai－2附加系Z1、Z2、X6,代换系ZD28等进行RAPD分析,从320个RAPD引物中,鉴定出2Ai－2染色体特异的2个RAPD标记OPO05650和OPMO414000。利用这2个特异OPO05和OPM04,PCR扩增普通小麦CS（ABD）及其近缘植物中间偃麦草（E1E2St）、拟鹅冠草（St）,长穗偃麦草（E）、簇毛麦（V）、黑麦（R）、大麦（H）粗山羊草（D）等基因组DNA。结果表明,OPO05650和OPO41400均是2Ai－2染色体上St基因组区域的特异标记。将上棕2个特异片段分离回收、克隆、测序,根据测序结果重新设计、合成特异引物,成功地转换RAPD标记为SCAR（sequence characterizked amplifed region）标记SC－05和SC－M4。利用SCAR标记对不同材料进行分析的结果表明,凡含有2Ai－2染色体的抗黄矮病材料及拟鹅冠草均产生一条扩增带,不含2Ai－2染色体的材料,包括小麦、长穗麦草、簇毛麦、黑麦、在麦、粗山羊草以有含有其他他中间偃麦草染色休的附加系,均没有扩增产物,说明上棕2个SCAR标记是中间偃麦草2Ai－2染色体的特异性PCR标记,且是2Ai－2染色体上St基因组区域的特异性标记。克隆与鉴定中间偃麦草的2个SCAR扩增片段TiSCO5和TiSCM4。结果表明,克隆的中间偃麦草TiSCO5和TiSCM4特异片段,分别是St基因组特异性的寡拷贝序列有多拷贝重复序列,为St基因组遗传研究的新探针。     

Identification of molecular markers for the detection of the yellow rust resistance gene Yr17 in wheat

The Yr17 gene, which is present in many European wheat cultivars, displays yellow rust resistance at the seedling stage. The gene introduced into chromosome 2A from Aegilops ventricosa was previously found to be closely linked (0.5 cM) to leaf and stem rust resistance genes Lr37 and Sr38, respectively. The objective of this study was to identify molecular markers linked to the Yr17 gene. We screened with RAPD primers, for polymorphism, the DNAs of cv. Thatcher and the leaf rust-resistant near-isogenic line (NIL) RL 6081 of cv. Thatcher carrying the Lr37 gene. Using a F2 progeny of the cross between VPM1 (resistant) and Thésée (susceptible), the RAPD marker OP-Y15580 was found to be closely linked to the Yr17 gene. We converted the OP- Y15580 RAPD marker into a sequence characterized amplified region (SCAR). This SCAR marker (SC-Y15) was linked at 0.8 ± 0.7 cM to the Yr17 resistance gene. We tested the SC-Y15 marker over a survey of 37 wheat cultivars in order to verify its consistency in different genetic backgrounds and to explain the resistance of some cultivars against yellow rust. Moreover, we showed that the Xpsr150-2Mv locus marker of Lr gene described by Bonhomme et al. [6] which possesses A. ventricosa introgression on the 2A chromosome was also closely linked to the Yr17 gene. Both the SCAR SC-Y15 and Xpsr150-2Mv markers should be used in breeding programmes in order to detect the cluster of the three genes Yr17, Lr37 and Sr38 in cross progenies. This revised version was published online in June 2006 with corrections to the Cover Date.