St基因组中的CRW同源序列在偃麦草中的FISH分析

为了确定十倍体长穗偃麦草(Thinopyrum ponticum, Liu & Wang)和六倍体中间偃麦草(Th. intermedium, [Host] Barkworth & Dewey )的基因组组成, 根据野生一粒小麦(Triticum boeoticum)着丝粒自主型反转录转座子(CRW)序列设计特异引物, 以二倍体拟鹅观草(Pseudoroegneria spicata, Á Löve )基因组 DNA为模板进行PCR扩增, 筛选到一条St基因组着丝粒区相对特异反转录转座子的部分序列pStC1, 长度为1.755 kb (GenBank登录号: FJ952565), 其中有800 bp与小麦着丝粒反转录转座子(CRW)的LTR区高度同源, 另有小部分片段与其外壳蛋白编码基因(gag)部分同源, 并且包含一段富含AGCAAC碱基的重复序列。以pStC1为探针, 对十倍体长穗偃麦草的FISH检测结果显示其基因组组成为两个St组3个E组(St₁St₂E^eE^bE^x); pStC1与中间偃麦草杂交时, 不仅St基因组上有强烈的荧光信号, 而且E基因组一些染色体的近着丝粒区域也有杂交信号, 说明偃麦草属异源多倍体物种在其形成及进化过程中St与E基因组之间在着丝粒及近着丝粒相关区域可能存在协同进化。     

Identification of Blue-grained Wheat Translocation Lines Using Fluorescence in Situ Hybridization

The blue-grained wheat substitution line (blue 58) originated from wild hybridization between Triticum aestivum L. and Agropyron elongatum (Host) Beauv= Elytrigia elongatum (Host) Nevski= Thinopyrum ponticum (Host) Barkworth and Dewey (2n=10x=70) was irradiated and four translocation lines were screened by fluorescence in situ hybridization from the offsprings. The results obtained include the following: (1) both the two translocation lines, 9906 and 9902, have 42 chromosomes. The length of the translocated blue-grained segment was approximately one-third of the short-arm and one-half of the long-arm of the translocated wheat chromosome in 9906 and 9902, respectively, and the blue-grained translocated segment in 9902 was located on D genome; (2) both 9915 and 9904 have 44 chromosomes. One pair of chromosomes was translocated and two chromosomes from Th. ponticum were added in 9903, while two pairs of chromosomes were translocated in 9904 by blue-grained wheat segment. The location and application of blue-grained wheat translocation lines were discussed.     

蓝粒小麦易位系的荧光原位杂交鉴定

普通小麦（Triticum aestivum L.)和长穗偃麦草（Agropyron elongatum (Host)Beauv=Elytriga elongatum(Host)Nevski=Thinopyrum ponticum (Host)Barkworth and Dewey,2n=10x=70)杂交后选育出的蓝粒小麦异代换系（蓝５８）,２n=42其中９９０６中被易位蓝粒片段的相对长度约占易位小麦染色体短臂的１／３,而９９０２中被易位蓝粒片段的相对长度约占易位小麦染色体长臂的１／２,并将９９０２的蓝粒易位片段定位在小麦Ｄ组染色体上;（２）９９１５易位附加和９９０４易位－易位附加,其体细胞染色体数均为４４,其中９９１５的体细胞染色体只有一对发生了易位,另外队了两条长穗偃麦草染色体;而９９０４有两对染色体发生了易位,并易位系中控制蓝粒性状的长穗偃麦草染色体片段的定位和蓝粒小麦易位系的应用进行了讨论。     

Revision of Taeniatherum (Poaceae)

Three species are often accepted in Taeniatherum Nevski. Analysis of morphological characters show that indistinct limits occur between them. All taxa are found to be diploid (2n=14), with the same karyotype, but artificial hybridization shows genetical barrier to exist. For these reasons subspecific level is chosen for the taxa, viz. T. caput-medusae (L.) Nevski ssp. caput-medusae, T. caput-medusae ssp. crinitum (Schreb.) Melderis and T. caput-medusae ssp. asperum (Simk.) Melderis. Map showing known distribution of the subspecies is presented.     

Characterization of a Wheat- wheatgrass Translocation Line by FISH

The genomic DNA of wheatgrass (Agropyron intermedium (Host) P.B. = Elytrigia intermedia (Host) Nevski = Thinopyrum intermedium (Host) Barkworth and Dewey) was labelled with biotin-16-dUTP as a probe, and genomic DNA of common wheat ( Triticum aestivum L. ) "Chinese Spring" was used for blocking. Wheat-wheatgrass line 33 was examined by fluorescence in situ hybridization (FISH) technique. The terminal regions of a pair of chromosomes showed green fluorescent signals. It has been concluded that chromosome segrnents containing alien genes of wheatgrass are located at the terminal regions of wheat chromosomes in wheat-wheatgrass line 33, and the translocated segments were small. Wheat-wheatgrass line 33 has been proved to be a translocation line with chromosome segments of wheatgrass translocated to the terminal regions of wheat chromoSomes.     

中间偃麦草(Thinopyrum intermedium)18S-5.8S-26S rDNA位点在染色体上的分布及对其核ITS序列异质性的分析(英文)

中间偃麦草(Thinopyrum intermedium(Host)Barkworth et Dewey)是禾本科小麦族植物中的一个异源六倍体物种,是重要的牧草植物,在小麦的抗病育种中发挥了重要作用。利用荧光原位杂交(FISH)技术,在体细胞中期染色体上,对18S-5.8S-26S rDNA位点进行了物理定位,发现该物种有3～4对染色体携带18S-5.8S-26S rDNA主位点。结合基因组原位杂交(GISH)分析,证明中间偃麦草的St基因组中有一对同源染色体短臂末端携带一个主位点,其余2～3对主位点位于E基因组染色体上。对不同来源的材料研究表明:18S-5.8S-26S rDNA位点的数目(包括主位点和小位点)、位置、拷贝数在不同收集材料之间的差异较大,甚至在同一个体的不同细胞中也存在差异。讨论了rDNA物理作图数据在分析系统发育问题中的局限性。结合中间偃麦草的三个可能的二倍体基因组供体(Th.bessarabicum、Th. elongatum和Pseudoroegneria stipifolia)rDNA位点分析的结果,对中间偃麦草进化过程中rDNA位点的变化进行了分析,同时,对其中一份材料的核ITS序列进行了克隆、测序和系统发育分析,发现在中间偃麦草中,ITS序列具有很高的异质性。     

Chromosomal Distribution of the 18S-5.8S-26S rDNA Loci and Heterogeneity of Nuclear ITS Regions in Thinopyrum intermedium （Poaceae： Triticeae）

Fluorescent in situ hybridization (FISH) was used to investigate the chromosomal location of 18S-5.8S-26S rDNA loci in Thinopyrum intermedium (Host) Barkworth et Dewey (2n=6x=42). In all accessions and individuals studied, 3 or 4 pairs of major loci were detected. Subsequent genomic in situhybddization (GISH) analyses revealed that one pair was located on the ends of the short arms of one pair of homologous chromosomes of the St genome, while the other 2 or 3 pairs of major loci were located in the E genomes (including the E^o and E^b). It is suggested that 2 to 3 pairs of major loci were probably lost during the evolution of this hexaploid species. The variation in rDNA positions and copy numbers between the diploid donors and Th. interrnedium, as well as the diversity among the accessions of Th. intermedium confirmed that the rDNA gene family conveyed the characters of DNA mobile elements. The internal transcribed spacer (ITS) regions of the rDNA in Th. intermedium were also investigated. Sequence data of seven positive clones from one individual suggested high degree of individual heterogeneity exists among ITS repeats. Phylogenetic analyses showed that there were two distinct types of ITS sequences in Th. intermedium, one with homology to that of Pseudoroegneria species (St genome) and the other to that of the E genome diploid species. This showed that the ITS paralogues in Th. intermedium have not been uniformly homogenized by concerted evolution. The limitation of using the chromosomal location of rDNA loci for phylogenetic analysis is discussed.     

Genome constitutions of Thinopyrum curvifolium, T. scirpeum, T. distichum, and T. junceum (Triticeae: Gramineae).

The objective of this study is to elucidate genome constitutions of Thinopyrum curvifolium (Lange) D.R. Dewey, T. scirpeum (K. Presl) D.R. Dewey, T. distichum (Thunb.) A. L?ve, and T. junceum (L.) A. L?ve. Hybrids of T. sartorii (Boiss. &Heidr.) A. L?ve with T. scirpeum and T. junceum, as well as the hybrid between T. curvifolium and Pseudoroegneria geniculata ssp. scythica (Nevski) A. L?ve, were made and chromosome pairing at metaphase I was studied. The karyotype analyses of mitotic cells stained by aceto-orcein were conducted for both hybrids and the four target species. The Giemsa C-banding following acetocarmine staining was carried out for the above species and the triploid hybrid T. curvifolium x T. bessarabicum (Savul &Rayss) A. L?ve. Meiotic data indicate that all target species have two sets of the basic genome J, but they behave like true allopolyploids because of bivalentization. Karyotypes of T. curvifolium and its triploid hybrid with T. bessarabicum indicate that T. curvifolium contains two different versions of the Jb genome, designated as Jb3 and Jb4, rather than two Je genomes as previously believed. Thinopyrum scirpeum and T. elongatum (4x) have similar karyotypes. Both are segmental allotetraploids carrying two forms of the Je genome. Their genome formulae are Je2 Je3 and Je1 Je3, respectively. Thinopyrum distichum has a karyotype similar to T. junceiforme, which has the Jb2 Je2 genome formula. However, the two species differ in C-banding patterns, reflecting their geographical separation. Thinopyrum junceum is a hexaploid with two pairs of Jb2 genomes and one pair of the Je2 genome, and it has a C-banding pattern similar to that of T. junceiforme, which has one pair each of the Jb2 and Je2 genomes.     

Genome relationships between octoploid and decaploid Thinopyrutn ponticum

MOUSTAKAS, M., 1993. Genome relationships between octoploid and decaploid Thinopyrum ponticum . The genomic relationships between octoploid and decaploid Thinopyrum ponticum were determined by computer-aided karyotype analysis. All the chromosome pairs of the octoploid race can be matched with those of the decaploid chromosome race. Four chromosome pairs that were recognized as marker chromosomes in octoploid and decaploid T. ponticum were almost identical. It is suggested that the two chromosome races of T. ponticum are segmental allopolyploids with genome designations J^jJ^jJ^eJ^e and J^jJ^jJ^jJ^eJ^e. Genome designations Jand J^e represent the same genome but with structural differentiation. Phylogenetic relationships between Thinopyrum species may be indicated by the presence or absence and type of marker chromosomes in the different species.     

Physical localization of the 18S-5.8S-26S rDNA and sequence analysis of ITS regions in Thinopyrum ponticum (Poaceae: Triticeae): implications for concerted evolution

Fluorescence in situ hybridization was used in Thinopyrum ponticum, a decaploid species, and its related diploid species, to investigate the distribution of the 18S-5.8S-26S rDNA. The distribution of rDNA was similar in all three diploid species (Th. bessarabicum, Th. elongatum and Pseudoroegneria stipifolia). Two pairs of loci were observed in each somatic cell at metaphase and interphase. One pair was located near the terminal end and the other in the interstitial regions of the short arms of one pair of chromosomes. However, all of the major loci in Th. ponticum were located on the terminal end of the short arms of chromosomes, and one chromosome had only one major locus. The maximum number of major loci detected on metaphase spreads was 20, which was the sum of that of its progenitors. The interstitial loci that exist in the possible diploid genome donor species were probably 'lost' during the evolutionary process of the decaploid species. A number of minor loci were also detected on whole regions of two pairs of homologous chromosomes. These results suggested that the position of rDNA loci in the Triticeae might be changeable rather than fixed. Positional changes of 18S-5.8S-26S rDNA loci between Th. ponticum and its candidate genome donors indicate that it is almost impossible to find a genome in the polyploid species that is completely identical to that of its diploid donors. The possible evolutionary significance of the distribution of the rDNA is also discussed. Internal transcribed spacer (ITS) regions of nuclear DNA in Th. ponticum were investigated by PCR amplification and sequencing. The sequence data from five positive clones selected at random, together with restriction site analysis, indicated that the ITS repeated units are nearly homogeneous in this autoallodecapolypoid species. Combined with in situ hybridization results, the data led to the conclusion that the ITS region has experienced interlocus as well as intralocus concerted evolution. Phylogenetic analyses showed that the sequences from Th. ponticum have concerted to the E genome repeat type.     

Characterization of Genome and Chromosomes in Octoploid Wheat wheatgrass Amphiploid Zhong 2 Using Fluorescence in situ Hybridization and Chromosome Pairing Analysis

Genomic constitution of octoploid wheat-wheatgrass amphiploid Zhong 2 was analyzed by chromosome pairing and fluorescence in sim hybridization techniques. The results indicated that the octoploid wheatwheatgrass chromosomes in Zhong 2 were derived from the distant homologous genomes of wheatgrass ( Agropyron intermedium (Host) P.B. = Elytrigia intermedia (Host) Nevski = Thinotopyrum intermedium (Host) Barkworth and Dewey, and thew distant homologous genomes were not from the E geaome of T. elongatum 2x. Zhong 2 contained 12 wheatgrass chromosomes in which a pair of chromosomes was involved in translocation between wheatgrass and wheat chromosomes.     

Study on Genomic Changes in Partial Amphiploids of Common Wheat Wheatgrass

According to conventional theory, little genomic changes should occur in homozygous and stable amphiploids of the grass family, particularly those involving polyploid wheat as a parent. In the present study, however, extensive genomic changes were detected in two octoploid partial amphiploids of common wheat ( Triticum aestivum L. )-wheatgrass ( Agropyron intermedium (Host) P.B. = Elytrigia intermedia (Host) Nevski = Thinopyrum intermedium (Host) Barkworth and Dewey), namely Zhong 3 and Zhong 5, by RFLP an, analysis using 10 low-copy, wheat chromosome-specific sequences and 33 representative homoeologous group-specific sequences as probes. C, enomic changes involved loss of wheat hybridization fragment (s) and/or acquisition of new fragment(s). Uniformity of the RFLP patterns among 5 individual plants taken respectively from Zhong 3 and Zhong 5 in two successive generations, suggested that genomic changes probably had occurred in the early few generations after octoploid amphiploid formation, and remained essentially static thereafter, The highly similar RFLP patterns between Zhong 3 and Zhong 5, which had identical genomic constitution but differed from each other due to involvement of different wheat varieties as parents imply that genomic changes were probably not at random. Possible causes for the extensive and rapid genomic changes in the newly formed plant amphiploids, as well as their implications for polyploid genome evolution and breeding application are discussed.     

蓝粒小麦花青素生物合成途径中的二氢黄酮醇4-还原酶基因的分子克隆

蓝色色素在蓝粒小麦种子糊粉层中的生物合成途径的分子生物学机制至今仍不清楚。应用RT—PCR和RACE方法从蓝粒小麦正在发育的种子中克隆到一个编码二氢黄酮醇4-还原酶的基因(DFR)。推测其为花青素生物合成途径中的一个关键基因,且与蓝粒小麦中蓝色色素形成密切相关;其开放阅读框编码一个包含354个氨基酸残基的多肽,与一些从其他植物中已克隆到的DFR有很高的同源性：大麦(94％)、水稻(83％)、玉米(84％)。从长穗偃麦草(2n=70)、蓝粒小麦、浅蓝粒小麦自交产生的白粒后代小麦以及中国春的基因组中分别分离到一个全长DFR序列。经聚类分析表明DFR cDNA核甘酸序列与从中国春基因组中克隆的DFR具有100％的同源性,且与长穗偃麦草、蓝粒小麦、白粒小麦基因组中分离的DFR均有很高的同源性。4个DFR基因组DNA均含有3个内含子,且它们之间的差异主要在内含子区,表明该基因在进化上很保守。经Southern杂交分析,DFR小麦中至少有3-5个拷贝,不同小麦材料间未见明显差异,但与长穗偃麦草有明显差异,属于一个DFR超基因家族。Northern分析表明该DFR在蓝粒和白粒种子的不同发育时期的表达存在明显差异,都在开花后大约18d表达最强,在同一时期的蓝白种子中,DFR蓝粒种子中的表达量高于白粒。DFR转录本在小麦和长穗偃麦草的幼叶中积累多,但在芽鞘中的表达显著低于幼叶中;在小麦的根和长穗偃麦草的发育种子中均未检测到DFR的表达。推测蓝粒小麦中可能存在调控DFR在蓝粒小麦中表达的调控基因,类似于玉米花青素合成途径中的调节基因。     

Characterization of derivatives from wheat-Thinopyrum wide crosses

Partial amphiploids are lines that contain 42 (38-42) wheat and 14 (14-18) alien chromosomes. They are derived by backcrossing wheat onto hybrids between wheat and either Thinopyrum intermedium (6x) or Th. ponticum (10x). GISH analysis has shown that, with possibly one exception, the alien genomes (chromosome sets) in partial amphiploids are found to be hybrids i.e. composed of chromosomes from more than one alien genome. The individual partial amphiploids are meiotically stable and nearly perfectly fertile, but hybrids between different lines were characterized by varying numbers of unpaired chromosomes and consequently variable degrees of sterility. Translocated chromosomes involving different Thinopyrum genomes or Thinopyrum and wheat genomes were found in partial amphiploids and consequently in the addition lines derived from them. Partial amphiploids have proven to be an excellent tertiary gene pool for wheat improvement, containing resistance to biotic stresses not present in wheat itself. Resistance to Barley Yellow Dwarf Virus (BYDV) and Wheat Streak Mosaic Virus (WSMV) have been found in partial amphiploids and addition lines derived from both Th. intermedium and Th. ponticum. Excellent resistance to Fusarium head blight has been found on a Th. intermedium chromosome that had substituted for chromosome 2D in wheat. Genes for resistance to leaf rust and stem rust have already been incorporated into wheat and tagged with molecular markers.     

蓝粒小麦花青素生物合成途径中的二氢黄酮醇4-还原酶基因的分子克隆

蓝色色素在蓝粒小麦种子糊粉层中的生物合成途径的分子生物学机制至今仍不清楚.应用RT-PCR和RACE方法从蓝粒小麦正在发育的种子中克隆到一个编码二氢黄酮醇4-还原酶的基因(DFR).推测其为花青素生物合成途径中的一个关键基因,且与蓝粒小麦中蓝色色素形成密切相关;其开放阅读框编码一个包含354个氨基酸残基的多肽,与一些从其他植物中已克隆到的DFR有很高的同源性:大麦(94%)、水稻(83%)、玉米(84%).从长穗偃麦草(2n=70)、蓝粒小麦、浅蓝粒小麦自交产生的白粒后代小麦以及中国春的基因组中分别分离到一个全长DFR序列.经聚类分析表明DFR cDNA核甘酸序列与从中国春基因组中克隆的DFR具有100%的同源性,且与长穗偃麦草、蓝粒小麦、白粒小麦基因组中分离的DFR均有很高的同源性.4个DFR基因组DNA均含有3个内含子,且它们之间的差异主要在内含子区,表明该基因在进化上很保守.经Southern杂交分析,DFR在小麦中至少有3～5个拷贝,不同小麦材料间未见明显差异,但与长穗偃麦草有明显差异,属于一个DFR超基因家族.Northern分析表明该DFR在蓝粒和白粒种子的不同发育时期的表达存在明显差异,都在开花后大约18 d表达最强,在同一时期的蓝白种子中,DFR在蓝粒种子中的表达量高于白粒.DFR转录本在小麦和长穗偃麦草的幼叶中积累多,但在芽鞘中的表达显著低于幼叶中;在小麦的根和长穗偃麦草的发育种子中均未检测到DFR的表达.推测蓝粒小麦中可能存在调控DFR在蓝粒小麦中表达的调控基因,类似于玉米花青素合成途径中的调节基因.     

The transfer and characterization of resistance to common root rot from Thinopyrum ponticum to wheat.

Common root rot, caused by Cochliobolus sativus (Ito and Kurib) Drechs. ex Dastur, is a major soil-borne disease of spring and winter wheat (Triticum aestivum L. em Thell.) on the Canadian prairies. Resistance to common root rot from Thinopyrum ponticum (Podp.) Liu and Wang was transferred into wheat via crossing with Agrotana, a resistant wheat - Th. ponticum partial amphiploid line. Evaluation of common root rot reactions showed that selected advanced lines with blue kernel color derived from a wheat x Agrotana cross expressed more resistance than the susceptible T. aestivum 'Chinese Spring' parent and other susceptible wheat check cultivars. Cytological examination revealed 41 to 44 chromosomes in the advanced lines. Genomic in situ hybridization, using total genomic DNA from Pseudoroegneria strigosa (M. Bieb) A. L?ve (St genome) as a probe, demonstrated that the blue kernel plants had two pairs of spontaneously translocated J-Js and Js-J chromosomes derived from the J and Js genome of Th. ponticum. The presence of these translocated chromosomes was associated with increased resistance of wheat to common root rot. The lines with blue aleurone color always had a subcentromeric Js-J translocated chromosome. The subtelocentric J-Js translocated chromosome was not responsible for the blue kernel color. The genomic in situ hybridization analysis on meiosis revealed that the two spontaneous translocations were not reciprocal translocations.     

The effects of level of 2,4-D and time in culture on regeneration rate and chromosome numbers of regenerants from calli of the hybrid Triticum aestivum cv. Chinese Spring ph1b x Thinopyrum ponticum (2n = 10x = 70).

Thinopyrum ponticum (Podp.) Barkworth &D. R. Dewey (2n = 10x = 70) has excellent resistance for both leaf and stem rusts. Long-term callus cultures were established from the immature embryos of a hybrid between Triticum aestivum L. (2n = 6x = 42) x Th. ponticum. They were maintained in culture for over 2 years and continued to grow and have organogenetic capacity. With increasing time on a maintenance medium, the plant regeneration rates of the hybrid calli decreased when transferred to regeneration media containing 0.1, 0.2, or 0.5 mg/L 2,4-D, but the rate of decrease was much higher at 0.5 mg/L than at either 0.1 or 0.2 mg/L 2,4-D. After 3 months of subculture, the highest plant regeneration rate was obtained on the medium containing 0.5 mg/L 2,4-D (1.11 plantlets/callus), while on the 24th month of subculture the highest plant regeneration rate was obtained on the medium containing 0.1 mg/L 2,4-D (0.20 plantlets/callus). Thus, it was shown that as the calli aged it was important to reduce the level of 2,4-D in the regeneration medium. Over 2 years, a total of 667 regenerants were successfully transferred and grown to maturity. Chromosome numbers in root-tip cells were determined for 539 regenerants and ranged from 36 to 70. Telocentric chromosomes were frequent. A fertile plant was found among the regenerants after 15 months of subculture. It had 56 chromosomes with 2.15 (1-6) univalents, 22.76 (17-26) closed bivalents, 3.55 (1-9) open bivalents, and 0.41 (0-3) trivalents and was highly resistant to stem rust race 15B-1. Callus culture of wide hybrids can be used to introgress characters from alien species into wheat.     

应用荧光原位杂交和染色体配对研究八倍体小冰麦中2的染色体组构成及染色体特征

通过染色体配对分析和荧光原位杂交（ＦＩＳＨ）技术对八倍体小冰麦中２的染色体组构成进行分析,结果表明：八倍体小冰麦中２含有的冰草染色体是来自天蓝冰草（Ａｇｒｏｐｙｒｏｎ　ｉｎｔｅｒｍｅｄｉｕｍ（Ｈｏｓｔ）Ｐ．Ｂ．＝Ｅｌｙｔｒｉｇｉａ　ｉｎｔｅｒｍｅｄｉａ（Ｈｏｓｔ）Ｎｅｖｓｋｉ＝Ｔｈｉｎｏｐｙｒｕｍ　ｉｎｔｅｒｍｅｄｉｕｍ　（Ｈｏｓｔ）Ｂａｒｋｗｏｒｔｈ　ａｎｄ　Ｄｅｗｅｙ）具同亲关系的染色体组,但冰草的这种同亲关系的染色体组不同于二倍体长穗偃麦草（Ｔｈｉｎｏｐｙｒｕｍ　ｅｌｏｕｇａｔｕｍ　２Ｘ）的Ｅ组染色体。中２含有１２条冰草染色体,且有一对染色体为小麦（Ｔｒｉｔｉｃｕｍ　ａｅｓｔｉｖｕｍ　Ｌ．）染色体和冰草染色体之间易位所形成的。     

八倍体小冰麦及其亲本种子醇溶蛋白和高分子量麦谷蛋白亚基的研究

对５个八倍体小冰麦种子醇溶蛋白和高分子量麦谷蛋白亚基的电泳谱带进行了分析,结果表明：八倍体小冰麦中１和中２的电泳谱带基本相同,中３、中４、中５的电泳谱带基本相同,但完全不同于中１和中２的类型。八倍体小冰麦中１和中２同天蓝冰草（Ａｇｒｏｐｙｒｏｎｉｎｔｅｒｍｅｄｉｕｍ（Ｈｏｓｔ）Ｐ．Ｂ．＝Ｅｌｙｔｒｉｇｉａｉｎｔｅｒｍｅｄｉａ（Ｈｏｓｔ）Ｎｅｖｓｋｉ＝Ｔｈｉｎｏｐｙｒｕｍｉｎｔｅｒｍｅｄｉｕｍ（Ｈｏｓｔ）ＢａｒｋｗａｒｔｈａｎｄＤｅｗｅｙ）在高分子量麦谷蛋白亚基上存在一条相同的谱带,在醇溶蛋白谱带上出现了小麦（ＴｒｉｔｉｃｕｍａｅｓｔｉｖｕｍＬ．）和冰草均没有的带型。中３、中４、中５在醇溶蛋白谱带上具有一条冰草×染色体组的特征谱带,其基因表达程度同冰草类似。从５个八倍体小冰麦种子醇溶蛋白和高分子量麦谷蛋白亚基的电泳图谱结果,分析了八倍体小冰麦染色体组构成及亲本来源,并探讨了八倍体小冰麦在优质麦育种过程中的价值。     

Molecular Cytogenetic Identification of a Wheat-Thinopyron intermedium (Host) Barkworth & DR Dewey Partial Amphiploid Resistant to Powdery Mildew

Wide cross and molecular cytogenetic methods were used to transfer the powdery mildew resistance gene from Thinopyron intermedium (Host) Barkworth & DR Dewey to wheat. Among the progeny of crossing common wheat (Triticum aestivum L.) Yannong 15 with Th. intermedium, a partial amphiploid E990256, with resistance to powdery mildew, was developed. It had 56 chromosomes and could form 28bivalents in pollen mother cells at metaphase I of meiosis. Resistance verification by race 15 at the seedling stage and by mixed strains of Erysiphales gramnis DC. f. sp. tritici Em. Marchal at the adult stage showed it was immune to powdery mildew at both stages. Gene postulation via 21 isolates of E. gramnis f. sp. tritici and 29 differential hosts showed it was nearly immune to all the isolates used, and its resistance pattem was different from all the mildew resistance genes used, which indicated it probably contained a new resistance gene to powdery mildew. Biochemical verification showed it might convey different Th. intermedium chromosomes from those of the wheat-Th. intermedium partial amphiploids Zhong 1-5. Genomic in situ hybridization analysis by using St genomic DNA as the probe showed E990256 contained a recombination genome of St and E.