利用生化及分子标记确定长穗偃麦草（Elytrigia elongatum,EE.2n=14） …

利用限制性片段长度多态性（ＲＦＬＰ）及等电聚焦（ＩＥＦ）技术确定普通小麦中国春－二倍体长穗偃麦草７个异附加系所附加的外源染以体与小麦染色体的部分同源性,共有８个生化标记,１３个ＲＦＬＰ标记在亲本间揭示了多态性,结果表明：长穗偃麦草的１Ｅ,２Ｅ,３Ｅ,４Ｅ,５Ｅ,６Ｅ,７Ｅ７条染色体分别与小麦染色体的１、２、３、４、５、６、７７个部分同源群具有部分同源关系,偃麦草的１Ｅ与７Ｅ、５Ｅ与７Ｅ染色体间可能     

小偃麦部分双二倍体及其异附加系异源染色体的GISH分析

应用ＴＩＳＨ对小偃麦部分双二倍体ＴＡＦ４６（２ｎ＝８ｘ＝５６）及其衍生的６个二体异附加系的中间偃麦草染色体组种类进行了分析、鉴定。以拟鹅冠草（Ｐｓ．ｓｔｒｉｇｏｓａ）ＤＮＡ为探针的分析结果表明,ＴＡＦ４６所含有的中间偃麦草染色体组为合成染色体组,即６条Ｓｔ组染色体和８条Ｅ组染色体。在其衍生的二体异附加系中,Ｌ４和Ｌ７含有Ｓｔ组染色体,Ｌ１、Ｌ２、Ｌ３、Ｌ５含有Ｅ组染色体。ＴＡＦ４６所含有的中间偃麦草染色体的部分同源群依次为ＩＥ（Ｌ３）、２Ｓｔ（Ｌ６）、３Ｅ（Ｌ２）、４Ｓｔ（Ｌ４）、５Ｅ（Ｌ５）、６Ｓｔ（Ｌ７）、７Ｅ（Ｌ１）。     

VE161小麦的外源染色体鉴定

通过染色体原位杂交、ＲＦＬＰ分析和染色体重双端体分析,对在小麦遗传育种研究中具有重要理论和应用价值的ＶＥ１６１小麦不育异代换系及其附加系进行了染色体鉴定。结果表明,ＶＥ１６１小麦代换的或附加的外源染色体为来自长穗偃麦草的４Ｅ染色体,被代换的小麦染色体为４Ｂ。过去曾鉴定为７Ｂ,可能是由于ＶＥ１６１早代染色体易位较多所致。同时发现,ＶＥ１６１小麦在５Ｂ,７Ｂ和１Ｄ所在的３个部分同源群中仍有染色体相互易     

小偃麦部分双二部体及其异附加系异源染色体的GISH分析

应用ＧＩＳＨ对小偃麦部分双二本ＴＡＦ４６及其衍生的６个二体异附加系的中间偃麦草染色体组种类进行了分析,鉴定,以拟鹅冠草ＤＮＡ为探针的分析结果表明,ＴＡＦ４６所含有的中间偃麦草洒色体组为合成染色体组,即６条Ａ１组染色体和８条Ｅ组染色体。在其衍生的二体异附加系中,Ｌ４和Ｌ含有Ｓｔ组染色体,Ｌ１、Ｌ２、Ｌ３、Ｌ５含有Ｅ组染色体。ＴＡＦ４６所含有的中间偃麦草染色体的部分同源群依次为ＩＥ（Ｌ３）、２Ｓｔ（Ｌ     

普通小麦4A染色体重排的原位杂交研究

以普通小麦第四部分同源染色体组的１３个ＲＦＬＰ（限制性片段长度多态性）标记为探针,通过原位杂交进行了物理定位和４Ａ染色体重排的物理特征研究。ＲＦＬＰ分析确定的标记所在的染色体臂和原位杂交结果相一致。位于４ＡＬ上的９个ＲＦＬＰ探针有６个的杂交点集中分布在距着丝点约６０％～７０％的区域内。本结果支持了４Ａ染色体来自于双重易位的假说,第一次易位产生的４ＡＬ／５ＡＬ染色体又和７ＢＳ发生易位,现在的４Ａ染色体结构为４ＡＬ／５ＡＬ／７ＢＳ,保留在４Ａ的５ＡＬ、７ＢＳ染色体片段约分别为０５μｍ、２２μｍ。所用ＲＦＬＰ标记杂交点聚集的区段分布于染色体臂的近端部,可能和易位断点及染色体的交换重组有关。４ＡＬ上Ｃ－带距着丝点的相对距离和各标记杂交点集中区段距着丝点的相对距离接近。     

小麦与彭梯卡偃麦草杂种及其衍生后代的细胞遗传学研究──Ⅱ．来自小麦和彭梯卡（长穗）偃麦草及中间偃麦草杂种后代11个八倍体小偃麦的比较研究

利用染色体配对分析和酯酶及种子醇溶蛋白电泳分析研究了我国育成的１１个八倍体小偃麦,结果表明：（ａ）来源于小麦和中间偃麦草杂交后代的６个部分双二倍体中,中１和中２的偃麦草染色体组不同于中３、中４、中５和小偃７８８２９的偃麦草染色体组;（ｂ）来源于小麦和长穗偃麦草杂交后代的５个部分双二倍体中,小偃７８４的偃麦草染色体组不同于小偃６９３和小偃７６３１中的偃麦草染色体组,表明在长穗偃麦草中有两个互不相同又不同于小麦的染色体组Ｅ和Ｆ,而小偃７４３０和小偃６８中的偃麦草染色体组很可能是Ｅ和Ｆ染色体组的重组体;（ｃ）小偃７８４中的长穗偃麦草染色体组和中５及小偃７８８２９中的中间偃麦草染色体组基本相同,而中２的中间偃麦草染色体组不同于小偃６９３和小偃７６３１中的长穗偃麦草染色体组Ｆ,这意味着在长穗偃麦草和中间偃麦草中可能只有一个共同的染色体组Ｅ。部分双二倍体中酯酶及醇溶蛋白偃麦草染色体特征带的存在和发现,为这些染色体或其片段导入小麦后的鉴定提供了方便。     

抗白粉病小麦染色体组型的分子标记与生化标记分析

应用与小麦第六同源群有关的分子和生化标记,包括ＤＮＡ探针ｐＳｃ５·３Ｈ３和ｐＳＲ１６７以及同工酶Ｅｓｔ－５和ａ－Ａｍｙ－１,对来自六倍体小黑麦Ｂｅａｇｌｅ与普通小麦科冬５８杂交后代Ｆ１花粉植株的抗白粉病株系Ｍ２４．Ｍ０９及Ｍ１７进行了分析。结果表明,Ｍ２４、Ｍ０９及Ｍ１７不同程度地含有黑麦染色体成分,而且电泳谱带差别较大,据此推断,Ｍ０９为６ＲＬ的易位系。因此,生化和分子标记不仅可以用于确定外源片段的存在,而且可以帮助确定染色体组型和外源片段的位置     

贻贝核型及染色体带型分析

本文对贻贝染色体进行了核型分析,其结果为：２ｎ＝２８,１２ｍ＋１０ｓｍ＋６ｓｔ,ＮＦ＝５０,ＴＣＬ＝１０３．９０μｍ,ＣＬ：２．７３５－４．７７４μｍ。第１、２、４、８、１１、１２对为中部着丝粒染色体（ｓｍ）,第３、５、７对亚端部着丝粒染色体（ｓｍ）。对贻贝染色体的Ｇ带,Ｃ带、银染色带进行了分析。银染结果表明,贻贝细胞中有四个银染核仁组织区,分布在第３、５对染色体长臂末端。     

贻贝(Mytilus edulis)核型及染色体带型分析

本文对贻贝染色体进行了核型分析,其结果为：２ｎ＝２８,１２ｍ＋１０ｓｍ＋６ｓｔ,ＮＦ＝５０,ＴＣＬ＝ １０３．９０μｍ,ＣＬ：２．７３５－４．７７４μｍ。第１、２、４、８、１１、１２对为中部着丝粒染色体（ｍ）;第６、９、１０、１３、１４对 为亚中部着丝粒染色体（ｓｍ）;第 ３、５、７对为亚端部着丝粒染色体（ｓｔ）。对贻贝染色体的Ｇ带、Ｃ带、银 染带进行了分析。银染结果表明,贻贝细胞中有四个银染核仁组织区（Ａｇ－ＮＯＲｓ）,分布在第 ３、５对染 色体长臂末端。     

先天性骨—肾畸形综合征小鼠（KM—1d）致病基因ld的染色体定位

对ＫＭ－１ｄ小鼠的致病基因ｌｄ进行染色体定位,采用异构蛋白及同功酶电泳技术和体外扩增技术对同源导入近交系小鼠Ｃ５７ＢＬ／６．ＫＭ－ｌｄ２０对染色上的１４个笔化标记基因位点和６１个ＳＳＬＰ位点进行筛选,发现ｌｄ基因与２号染色体上的Ｄ２Ｍｉｔ３０、Ｄ２Ｍｉｔ６２和Ｄ２ｉｔ６３３个ＳＳＬＰ位点连锁,从而把ｌｄ基因初步定位于２号染色体,为进一步对ｌｄ基因准确定位,培育了８６只（Ｃ５７ＢＬ／６＊ＫＭ－１在＊     

Use of RFLPs to determine the chromosome composition of tetraploid triticale (A/B)(A/B)RR.

Tetraploid triticale, (A/B)(A/B)RR (2n = 28), is a botanical novelty, an amphiploid composed of a diploid rye and a 14 chromosome wheat genome made up of chromosomes of the A and B genomes of tetraploid wheat. Restriction fragment length polymorphism (RFLP) markers were used to elucidate the chromosome composition of the mixed wheat genome of 35 different tetraploid triticale lines. Of 128 possible A/B chromosome pair combinations, only 6 were found among these lines, with a prevalence of the 1A, 2A, 3B, 4B, 5B, 6B, and 7B karyotype. In most triticale lines stable wheat genomes made up of only homologous A or B genome chromosome pairs were identified, however, in some lines homoeologous chromosome pairs were found. In this paper we demonstrate that RFLPs can be used successfully as an alternative to C-banding for the identification of the chromosome composition of tetraploid triticale and discuss the possible selective advantage of specific chromosome composition.     

Detection of wheat-alien recombinant chromosomes using co-dominant DNA markers**

A study of homoeologous recombination along almost the complete genetic length of two homoeologous chromosomes in the Triticeae was conducted. Sears' phlb mutant was used to induce homoeologous pairing between chromosomes 7A of common wheat and 7Ai–l of Agropyron intermedium. 390 ph1b ph1b homozygous F₃ progeny were screened using six co-dominant DNA markers (RFLP loci). 63 of the progeny (16%) were putative recombinants, showing dissociation of RFLP markers within the arm(s). Progeny tests of self-fertile putative recombinants confirmed the dissociation phenotypes observed in the F₃ progeny. No recombination could be confirmed in 117 F₃ progeny plants having the Ph1– allele (control population). Frequencies and distribution of chiasmata along the chromosome arm 7AS were analysed using additional RFLP markers. The patterns of recombination between the two homoeologous chromosomes were found similar to those reported for homologous recombination between the same markers on short arms of group 7 chromosomes of Triticeae.     

Genome mapping of polyploid tall fescue (Festuca arundinacea Schreb.) with RFLP markers

Genetic mapping using molecular markers such as restriction fragment length polymorphisms (RFLPs) has become a powerful tool for plant geneticists and breeders. Like many economically important polyploid plant species, detailed genetic studies of hexaploid tall fescue (Festuca arundinacea Schreb.) are complicated, and no genetic map has been established. We report here the first tall fescue genetic map. This map was generated from an F₂ population of HD28-56 by Kentucky-31 and contains 108 RFLP markers. Although the two parental plants were heterozygous, the perennial and tillering growth habit, high degree of RFLP, and disomic inheritance of tall fescue enabled us to identify the segregating homologous alleles. The map covers 1274 cM on 19 linkage groups with an average of 5 loci per linkage group (LG) and 17.9 cM between loci. Mapping the homoeologous loci detected by the same probe allowed us to identify five homoeologous groups within which the gene orders were found to be generally conserved among homoeologous chromosomes. An exception was homoeologous group 5, in which only 2 of the 3 homoeologous chromosomes were identified. Using 12 genome-specific probes, we were able to assign several linkage groups to one of the three genomes (PG₁G₂) in tall fescue. All the loci detected by the 11 probes specific to the G₁ and/or G₂ genomes, with one exception, identified loci located on 4 chromosomes of two homoeologous groups (LG2a, LG2c, LG3a, and LG3c). A P-genome-specific probe was used to map a locus on LG5c. Comparative genome mapping with maize probes indicated that homoeologous group 3 and 2 chromosomes in tall fescue corresponded to maize chromosome 1. Difficulties and advantages of applying RFLP technology in polyploids with high levels of heterozygosity are discussed.Journal Series No. 12, 190     

Molecular markers for four leaf rust resistance genes introgressed into wheat from wild relatives.

Near-isolines carrying four different genes for resistance to leaf rust were used to find linked molecular markers for these genes. Clones used to detect polymorphism were selected on the basis of the reported chromosomal location of the resistance genes. Both Lophopyron-derived resistance genes, Lr19 and Lr24, cosegregated with eight molecular markers assigned to chromosomes 7DL and 3DL, respectively. One clone cosegregated with Lr9 and two closely linked RFLP markers were found for Lr32, mapping at 3.3 +/- 2.6 and 6.9 +/- 3.6 cM from the resistance gene. The Lophopyron-chromatin segment in isolines carrying chromosomes 7E (Lr19) and 3E (Lr24) replaced a large portion of chromosome 7D and the distal portion of chromosome 3D, respectively. Clones assigned to these chromosomes on the basis of aneuploid analysis hybridized to 7E and 3E segments, thus confirming cytological results that these introgressed segments represent homoeologous chromosomes. The linked RFLP markers could be used to identify the resistance genes and generate new combinations in breeding populations, especially in the absence of disease in the environment or when virulence is lacking.     

Molecular genetic maps of the group 6 chromosomes of hexaploid wheat (Triticum aestivum L. em. Thell.).

Restriction fragment length polymorphism (RFLP) maps of chromosomes 6A, 6B, and 6D of hexaploid wheat (Triticum aestivum L. em. Thell.) have been produced. They were constructed using a population of F7-8 recombinant inbred lines derived from a synthetic wheat x bread wheat cross. The maps consist of 74 markers assigned to map positions at a LOD >= 3 (29 markers assigned to 6A, 24 to 6B, and 21 to 6D) and 2 markers assigned to 6D ordered at a LOD of 2.7. Another 78 markers were assigned to intervals on the maps. The maps of 6A, 6B, and 6D span 178, 132, and 206 cM, respectively. Twenty-one clones detected orthologous loci in two homoeologues and 3 detected an orthologous locus in each chromosome. Orthologous loci are located at intervals of from 1.5 to 26 cM throughout 70% of the length of the linkage maps. Within this portion of the maps, colinearity (homosequentiality) among the three homoeologues is strongly indicated. The remainder of the linkage maps consists of three segments ranging in length from 47 to 60 cM. Colinearity among these chromosomes and other Triticeae homoeologous group 6 chromosomes is indicated and a consensus RFLP map derived from maps of the homoeologous group 6 chromosomes of hexaploid wheat, tetraploid wheat, Triticum tauschii, and barley is presented. Key words : RFLP, wheat, linkage maps, molecular markers.     

Molecular Mapping of Wheat: Major Genes and Rearrangements in Homoeologous Groups 4, 5, and 7

A molecular-marker linkage map of hexaploid wheat (Triticum aestivum L. em. Thell) provides a framework for integration with the classical genetic map and a record of the chromosomal rearrangements involved in the evolution of this crop species. We have constructed restriction fragment length polymorphism (RFLP) maps of the A-, B-, and D-genome chromosomes of homoeologous groups 4, 5, and 7 of wheat using 114 F(7) lines from a synthetic X cultivated wheat cross and clones from 10 DNA libraries. Chromosomal breakpoints for known ancestral reciprocal translocations involving these chromosomes and for a known pericentric inversion on chromosome 4A were localized by linkage and aneuploid analysis. Known genes mapped include the major vernalization genes Vrn1 and Vrn3 on chromosome arms 5AL and 5DL, the red-coleoptile gene Rc1 on 7AS, and presumptively the leaf-rust (Puccinia recondita f.sp. tritici) resistance gene Lr34 on 7DS and the kernel-hardness gene Ha on 5DS. RFLP markers previously obtained for powdery-mildew (Blumeria graminis f.sp. tritici) resistance genes Pm2 and Pm1 were localized on chromosome arms 5DS and 7AL.     

Chromosomal control of the tolerance of gradually and suddenly imposed salt stress in the Lophopyrum elongatum and wheat,Triticum aestivum L. genomes

The facultatively halophytic Lophopyrum elongatum, closely related wheat, Triticum aestivum, and their amphiploid tolerate salt stress better if they are gradually exposed to it than if they are suddenly stressed. Lophopyrum elongatum has greater tolerance of both forms of salt stress than wheat, and its genome partially confers this tolerance on their amphiploid. Chromosomal control of the tolerance of both stress regimes in the L. elongatum and wheat genomes was investigated with disomic and ditelosomic addition lines and disomic substitution lines of L. elongatum chromosomes in wheat and with wheat tetrasomics. The tolerance of the sudden salt stress is principally controlled by L. elongatum chromosomes 3E and 5E and less by 1E, 2E, 6E, and 7E and the tolerance of gradually imposed salt stress principally by chromosomes 3E, 4E, and 5E, and less by chromosome 1E and 7E. Ditelosomic analysis indicated that genes conferring the tolerance of sudden stress are on chromosome arms 1EL, 5ES, 5EL, 6EL, 7ES and 7EL and those controlling the gradual stress regime are on 1ES, 1EL, 5ES, 5EL, 6ES, 7ES, and 7EL. In wheat, chromosomes in homoeologous groups 1, 3, and 7 and chromosomes in homoeologous groups 1, 4, and 6 were shown to enhance the tolerance of suddenly and gradually imposed stress, respectively. The arms of chromosome 3E individually conferred tolerance to neither stress regime. Chromosome 2E and wheat chromosomes 2B and 2D reduce the tolerance of both stress regimes in a hyperploid state. In 2E this effect was associated with arm 2EL. A potential relationship between the tolerance of these stress regimes and the expression of the early-salt induced genes is examined.     

Physical location of homoeologous groups 5 and 6 molecular markers mapped in Triticum aestivum L

In situ hybridization was used to map 21 restriction fragment length polymorphism (RFLP) probes to linkage groups 5 and 6 of hexaploid wheat (Triticum aestivum L. em Thell.) in order to compare physical distances and genetic distances between adjacent markers. All 21 probes hybridized to the corresponding homoeologous chromosome arms. The linear order and linkage relationships among the DNA probes on the in situ-based physical maps were generally the same as those on the RFLP-based genetic maps. However, significant differences were observed between the centiMorgan distances on a linkage map and the physical distances of the probes using in situ-based techniques. The results indicated a clustering of polymorphic RFLP markers in the middle of all of the homoeologous group 5 and 6 chromosome arms. This suggests that the available linkage maps do not completely cover the physical length of the chromosomes. As with the genetic maps, the physical map clearly showed the presence of nonhomoeologous rearrangements in the terminal regions of chromosome arms 5AL and 6BS. However, the physical mapping gave an indication of the physical size of the rearrangements as well as their arm location.     

Chromosome synteny of the a genome of two evolutionary wheat lines

In order to estimate synteny between A^t and A polyploid wheat genomes belonging to different evolutionary lines (Timopheevi and Emmer), saturation of chromosome maps of Triticum timopheevii A^t genome by molecular markers has been conducted. Totally, 179 EST-SSR and 48 genomic SSR-markers have been used with the following integration of 13 and 7 markers correspondingly into chromosome maps of A^t genome. ESTSSR showed higher transferability and lower polymorphism than genomic SSR markers. The chromosome maps designed were compared to maps of homoeologous chromosome group of the T. aestivum A genome. No disturbances of colinearity, i.e., of the order of markers within the chromosome segments on which they had been previously mapped, were observed. According to the quantity assessment of markers amplifying in homoeologous chromosomes, the maximum divergence was detected in two groups (4A^t/4A and 3A^t/3A) among the seven chromosomes examined in the A ^t and A genomes. Comparison of molecular genetic mapping results with the published results of studying meiosis of F₁ hybrids and the frequency of chromosomes substitution in introgressive T. aestivum × T. timopheevii lines suggest that individual chromosomes of the A^t and A genomes evolve differently. Translocations were shown to introduce the major impact on the divergence of 4A^t/4A and 6A^t/6A chromosomes, while mutations of the primary DNA structure, on the divergence of homoeologous group 3 chromosomes. The level of reorganization of other chromosomes during the evolution in the A^t and A genomes was significantly lower.     

A linkage map of hexaploid oat based on grass anchor DNA clones and its relationship to other oat maps.

A cultivated oat linkage map was developed using a recombinant inbred population of 136 F6:7 lines from the cross 'Ogle' x 'TAM O-301'. A total of 441 marker loci, including 355 restriction fragment length polymorphism (RFLP) markers, 40 amplified fragment length polymorphisms (AFLPs), 22 random amplified polymorphic DNAs (RAPDs), 7 sequence-tagged sites (STSs), 1 simple sequence repeat (SSR), 12 isozyme loci, and 4 discrete morphological traits, was mapped. Fifteen loci remained unlinked, and 426 loci produced 34 linkage groups (with 2-43 loci each) spanning 2049 cM of the oat genome (from 4.2 to 174.0 cM per group). Comparisons with other Avena maps revealed 35 genome regions syntenic between hexaploid maps and 16-34 regions conserved between diploid and hexaploid maps. Those portions of hexaploid oat maps that could be compared were completely conserved. Considerable conservation of diploid genome regions on the hexaploid map also was observed (89-95%); however, at the whole-chromosome level, colinearity was much lower. Comparisons among linkage groups, both within and among Avena mapping populations, revealed several putative homoeologous linkage group sets as well as some linkage groups composed of segments from different homoeologous groups. The relationships between many Avena linkage groups remain uncertain, however, due to incomplete coverage by comparative markers and to complications introduced by genomic duplications and rearrangements.