水稻第六染色体长臂亚端粒区遗传图与物理图的整合

生物染色体亚闰区域在物种翰经过程中是高度活跃的。为了认识水稻染色体亚端粒区域的组织结构,用水稻第六染色体长臂亚端料区的ＲＦＬＰ标记Ｇ３４２和Ｒ１１６７作探针筛选ＢＡＣ文库,以得到的阳笥ＢＡＣ克隆为起点进行染色体眇地,构建了覆盖这２个分子标记区约５００ｋｂ的ＢＡＣ跨叠克隆群,将这一区域的跗图和物理图进行了整合。对１４个ＢＡＣ克隆插入末端进行了亚克隆,鉴定的７个亚克隆 端为单考贝或抵考贝序列,其中５个     

Transfer of sequence tagged site PCR markers between wheat and barley.

Transfer of mapping information between related species has facilitated the development of restriction fragment length polymorphism (RFLP) maps in the cereals. Sequence tagged site (STS) primer sets for use in the polymerase chain reaction may be developed from mapped RFLP clones. For this study, we mapped 97 STS primer sets to chromosomes in wheat and barley to determine the potential transferability of the primer sets and the degree of correspondence between RFLP and STS locations. STS products mapped to the same chromosome group in wheat and barley 75% of the time. RFLP location predicted STS location 69% of the time in wheat and 56% of the time in barley. Southern hybridizations showed that most primer sets amplified sequences homologous to the RFLP clone, although additional sequences were often amplified that did not hybridize to the RFLP clone. Nontarget sequences were often amplified when primer sets were transferred across species. In general, results suggest a good probability of success in transferring STSs between wheat and barley, and that RFLP location can be used to predict STS location. However, transferability of STSs cannot be assumed, suggesting a need for recombinational mapping of STS markers in each species as new primer sets are developed. Key words : sequence tagged sites, PCR, wheat, barley.     

Molecular genetics of growth and development in Populus. III. A genetic linkage map of a hybrid poplar composed of RFLP,STS, and RAPD markers

We have evaluated three DNA-based marker types for linkage map construction in Populus: RFLPs detected by Southern blot hybridization, STSs detected by a combination of PCR and RFLP analysis, and RAPDs. The mapping pedigree consists of three generations, with the F₁ produced by interspecific hybridization between a P. trichocarpa female and a P. deltoides male. The F₂ generation was made by inbreeding to the maximum degree permitted by the dioecious mating system of Populus. The applicability of STSs and RAPDs outside the mapping pedigree has been investigated, showing that these PCR-based marker systems are well-suited to breeding designs involving interspecific hybridization. A Populus genome map (343 markers) has been constructed from a combination of all three types. The length of the Populus genome is estimated to be 2400–2800 cM.Abbreviations RFLP restriction fragment length polymorphism - STS sequence-tagged site - PCR polymerase chain reaction - RAPD random amplified polymorphic DNA     

Characterization and Genetic Mapping of Simple Sequence Repeats in the Rice Genome

We searched partial sequences of over 22,706 rice cDNA and 1220genomic DNA clones to find and characterize simple sequencerepeats (SSRs) in the rice genome. The most frequently foundrepeated SSR motif in both cDNA and genomic DNA sequences wasd(CCG/CGG)n. The second most frequently found SSR was d(AG/CT)n.In contrast with mammalian genomes, in which d(AC/GT)n sequencesare the most abundant, d(AC/GT)n sequences were not frequentlyobserved in rice. Sequences containing d(CCG/CGG)n, d(AG/CT)nrepeats, and other SSRs were chosen for polymorphism detection.It was predicted that 17 of 20 SSRs in cDNA sequences were locatedin 5'-untranslated regions near initiation codons. Twenty-twoloci can be mapped on our RFLP linkage map by these SSRs. Sixmarkers were tested with 16 japonica rice varieties as templatesfor PCR. Two markers exhibited amplified fragment length polymorphismamong these rice varieties, implying that SSRs are polymorphicamong rice varieties which have similar genetic backgrounds.Even these polymorphic SSRs are located within or around geneswhich code ubiquitous proteins.     

A linkage map of the pea (Pisum sativum L.) genome containing cloned sequences of known function and expressed sequence tags (ESTs)

 A linkage map of the pea (Pisum sativum L.) genome is presented which is based on F₂ plants produced by crossing the marrowfat cultivar ‘Primo’ and the blue-pea breeding line ‘OSU442-15’. This linkage map consists of 209 markers and covers 1330 cM (Kosambi units) and includes RFLP, RAPD and AFLP markers. By mapping a number of anchor loci, the ‘Primo’בOSU442-15’ map has been related to other pea linkage maps. A feature of the map is the incorporation of 29 loci representing genes of known function, obtained from other laboratories. The map also contains RFLP loci detected using sequence-characterized cDNA clones developed in our laboratory. The putative identities of 38 of these cDNA clones were assigned by examining public-sequence databases for protein or nucleotide-sequence similarities. The conversion of sequence-characterized pea cDNAs into PCR-amplifiable and polymorphic sequence-tagged sites (STSs) was investigated using 18 pairs of primers designed for single-copy sequences. Eleven polymorphic STSs were developed. Received: 18 June 1997 / Accepted: 11 August 1997     

Map construction of sequence-tagged sites (STSs) in barley (Hordeum vulgare L.)

 In order to identify sequence-tagged sites (STSs) appropriate for recombinant inbred lines (RILs) of barley cultivars ‘Azumamugi’ × ‘Kanto Nakate Gold’, a total of 43 STS primer pairs were generated on the basis of the terminal sequences of barley restriction fragment length polymorphism (RFLP) clones. Forty one of the 43 primer pairs amplified PCR products in Azumamugi, Kanto Nakate Gold, or both. Of these, two showed a length polymorphism and two showed the presence or absence of polymorphism between the parents. PCR products of the remaining 37 primers were digested with 46 restriction endonucleases, and polymorphisms were detected for 15 primers. A 383.6-cM linkage map of RILs of Azumamugi×Kanto Nakate Gold was constructed from the 19 polymorphic STS primer pairs (20 loci) developed in this study, 45 previously developed STS primer pairs (47 loci), and two morphological loci. Linkage analysis and analysis of wheat-barley chromosome addition lines showed that with three exceptions, the chromosome locations of the STS markers were identical with those of the RFLP markers. Received: 4 August 1998 / Accepted: 8 October 1998     

Construction of YAC Contigs on Rice Chromosome 5

A physical map of rice chromosome 5 was constructed with yeastartificial chromosome (YAC) clones along a high-resolution molecularlinkage map carrying 118 DNA markers distributed over 123.7cM of genomic DNA. YAC clones have been identified by colonyand Southern hybridization for 105 restriction fragment lengthpolymorphism (RFLP) markers and by polymerase chain reaction(PCR) screening for 8 sequence-tagged site (STS) markers and5 randomly amplified polymorphic DNA (RAPD) markers. Of 458YACs, 235 individual YACs with an average insert length of 350kb were selected and ordered on chromosome 5 from the YAC library.Forty-eight contigs covering nearly 21 Mb were formed on thechromosome 5; the longest one was 6 cM and covered 1.5 Mb. Thelength covered with YAC clones corresponded to 62% of the totallength of chromosome 5. There were many multicopy sequencesof expressed genes on chromosome 5. The distribution of manycopies of these expressed gene sequences was determined by YACSouthern hybridization and is discussed. A physical map withthese characteristics provides a powerful tool for elucidationof genome structure and extraction of useful genetic informationin rice.     

Determination of RAPD Markers in Rice and their Conversion into Sequence Tagged Sites (STSs) and STS-Specific Primers

We produced 102 randomly amplified polymorphic DNA (RAPD) markersmapped on all 12 chromosomes of rice using DNAs of cultivarsNipponbare (japonica) and Kasalath (indica) and of F2 populationgenerated by a single cross of these parents. Sixty random primers10 nucleotides long were used both singly and in random pairsand about 1,400 primer-pairs were tested. Using both agarosegel and polyacrylamide gel electrophoresis enabled us to detectpolymorphisms appearing in the range from <100 bp to 2 kb.The loci of the RAPD markers were determined onto the frameworkof our RFLP linkage map and some of these markers were mappedto regions with few markers. Out of the 102 RAPD markers, 20STSs (sequence-tagged sites) and STS-specific primer pairs weredetermined by cloning, identifying and sequencing of the mappedpolymorphic fragments.     

The physical relationship of barley chromosome 5 (1H) to the linkage groups of rice chromosomes 5 and 10

 Using a recently developed polymerase chain reaction (PCR)-mediated approach for physical mapping of single-copy DNA sequences on microisolated chromosomes of barley, sequence-tagged sites of DNA probes that reveal restriction fragment length polymorphisms (RFLP) localized on the linkage maps of rice chromosomes 5 and 10 were allocated to cytologically defined regions of barley chromosome 5 (1H). The rice map of linkage group 5, of about 135 cM in size, falls into two separate parts, which are related to the distal portions of both the short and long arms of the barley chromosome. The markers on the rice map of chromosome 5 were found to be located within regions of the barley chromosome which show high recombination rates. The map of rice chromosome 10, of about 75 cM in size, on the other hand, is related to an interstitial segment of the long arm of chromosome 5 (1H) which is highly suppressed in recombination activity. For positional cloning of genes of this homoeologous region from the barley genome, the small rice genome will probably prove to be a useful tool. No markers located on rice chromosomes were detected within the pericentric Giemsa-positive heterochromatin of the barley chromosome, indicating that these barley-specific sequences form a block which separates the linkage segments conserved in rice. By our estimate approximately half of the barley-specific sequences of chromosome 5 (1H) show a dispersed distribution, while the other half separates the conserved linkage segments. Received: 29 February 1996 / Accepted: 28 June 1996     

Ordered YAC Clone Contigs Assigned to Rice Chromosomes 3 and 11

Yeast artificial chromosome (YAC) clones were arranged on thepositions of restriction fragment length polymorphism (RFLP)and sequence-tagged site (STS) markers already mapped on thehigh-resolution genetic maps of rice chromosomes 3 and 11. Froma total of 416 and 242 YAC clones selected by colony/Southernhybridization and polymerase chain reaction (PCR) analysis,238 and 135 YAC clones were located on chromosomes 3 and 11,respectively. For chromosomes 3 and 11, 24 YAC contigs and islandswith total coverage of about 46% and 12 contigs and islandswith coverage of about 40%, respectively, were assigned. Althoughmany DNA fragments of multiple copy marker sequences could notbe mapped to their original locations on the genetic map bySouthern hybridization because of a lack of RFLP, the physicalmapping of YAC clones could often assign specific locationsof such multiple copy sequences on the genome. The informationprovided here on contig formation and similar sequence distributionrevealed by ordering YAC clones will help to unravel the genomeorganization of rice as well as being useful in isolation ofgenes by map-based cloning.     

Single-strand conformation polymorphism of sequence-tagged site markers based on partial sequences of cDNA clones in Cryptomeria japonica

Sixty-seven sequence-tagged site (STS) markers were identified from partial sequences of cDNA clones obtained from the inner bark of Cryptomeria japonica. Polymorphisms of the STSs were investigated for the parental clones of a mapping population, Haara and Kumotooshi, using both single-strand conformation polymorphism (SSCP) and sequencing analysis. Twenty-two STSs showed nucleotide differences between Haara and Kumotooshi, of which 19 STS differences were detectable under the electrophoresis conditions we used here. We also analyzed SSC-polymorphism in 10 additional clones derived from various Japanese regions to evaluate the usefulness of the STSs developed here among other populations of C. japonica. Twenty-five, about 40%, of the STSs showed polymorphism under selected electrophoresis conditions. The genotype segregation for 19 STSs was investigated among the Haara x Kumotooshi F(1) population, and these STS markers were mapped on a linkage map. SSCP analysis of STSs was efficient in terms of cost and time, and it allows detection of a sufficiently high proportion of polymorphisms to provide a convenient means for mapping of expressed sequences on a linkage map and for studying various aspects of population genetics.     

Mapping Human Telomere Regions with YAC and P1 Clones: Chromosome-Specific Markers for 27 Telomeres Including 149 STSs and 24 Polymorphisms for 14 Proterminal Regions

A YAC library enriched for telomere clones was constructed and screened for the human telomere-specific repeat sequence (TTAGGG). Altogether 196 TYAC library clones were studied: 189 new TYAC clones were isolated, 149 STSs were developed for 132 different TYACs, and 39 P1 clones were identified using 19 STSs from 16 of the TYACs. A combination of mapping methods including fluorescencein situhybridization, somatic cell hybrid panels, clamped homogeneous electric fields, meiotic linkage, and BLASTN sequence analysis was utilized to characterize the resource. Forty-five of the TYACs map to 31 specific telomere regions. Twenty-four linkage markers were developed and mapped within 14 proterminal regions (12 telomeres and 2 terminal bands). The polymorphic markers include 12 microsatellites for 10 telomeres (1q, 2p, 6q, 7q, 10p, 10q, 13q, 14q, 18p, 22q) and the terminal bands of 11q and 12p. Twelve RFLP markers were identified and meiotically mapped to the telomeres of 2q, 7q, 8p, and 14q. Chromosome-specific STSs for 27 telomeres were identified from the 196 TYACs. More than 30,000 nucleotides derived from the TYAC vector-insert junction regions or from regions flanking TYAC microsatellites were compared to reported sequences using BLASTN. In addition to identifying homology with previously reported telomere sequences and human repeat elements, gene sequences and a number of ESTs were found to be highly homologous to the TYAC sequences. These genes include human coagulation factor V (F5), Wee1 protein tyrosine kinase (WEE1), neurotropic protein tyrosine kinase type 2 (NTRK2), glutathioneS-transferase (GST1), and β tubulin (TUBB). The TYAC/P1 resource, derivative STSs, and polymorphisms constitute an enabling resource to further studies of telomere structure and function and a means for physical and genetic map integration and closure.     

Classification of rice germplasm. I. Analysis using ALP and PCR-based RFLP

The potential of using a PCR-based approach to detect DNA polymorphism for rice germplasm classification was compared with that of Southern-based RFLP analysis. Thirty-five Iranian rice varieties were studied along with 2 typical Indica and 3 typical Japonica varieties. Thirteen mapped RFLP markers were used as hybridization probes against Southern blots containing digests of one restriction endonuclease; 12 of the 13 probes detected polymorphism in the varieties. Fifteen sets of oligonucleotides derived from sequences near the ends of the same probes and of two other mapped probes were used as primers for PCR amplification of total genomic DNA of the varieties. Amplicon length polymorphisms (ALPs) were detected with 6 of the 15 sets of primers. To identify additional polymorphism, the PCR products were digested with nine different restriction endonucleases recognizing 4- or 5-bp DNA sequences and analyzed by gel electrophoresis in agarose and polyacrylamide. RFLPs were detected for 11 sets of primers, due to point mutations and to addition/deletion events that were too small to be detected as ALPs. Because PCR products are easily generated and may be analyzed in detail through the use of restriction endonucleases that cut rice DNA frequently, PCR-based RFLP analysis is a useful tool for the classification of rice germplasm.     

Isolation and characterization of five rice telomere-associated sequences

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Cloning (CAG/GTC)n STSs by an Alu-(CAG/GTC)n PCR method: an approach to human chromosome 12 and spinocerebellar ataxia 2 (SCA2).

We report here an Alu-(CAG/GTC)n PCR method for the cloning of STSs with (CAG/GTC)n sequences. We have applied this method to genomic DNA of a somatic cell hybrid containing human chromosome 12 where linkage has been found for a known familiar dominant ataxia (SCA2), which is thought to be due to a (CAG/GTC)n expansion. We have isolated several clones containing (CAG/GTC)n sequences, which include previously identified sequences that map to chromosome 12. This method could be a new PCR approach for the cloning of repeats based on their proximity to Alu sequences.     

Distribution of Simple Sequence Repeat and AFLP Markers in Molecular Linkage Map of Rice

SSR (simple sequence repeat) and AFLP (amplified fragment length polymorphism) are PCR-based molecular markers developed in recent years. In this study, the authors analyzed the polymorphisms, inheritance and distribution of SSR and AFLP markers using an F2 population from a cross between cultivar "Aijiao Nante" ( Oryza sativa L. ssp. indica) and an accession of the common wild rice ( O. rufipogon Griff). A total of 200 new markers were obtained including 28 SSR and 172 AFLP markers. Six of the 28 SSR markers were developed by National Key Laboratory of Crop Genetic Improvement (NKLCGI) using DNA sequences from GenBank and the other 22 were from data published previously. The 172 AFLP markers were from a total 228 polymorphic bands amplified using 25 selected primer combinations. Mapping of the 200 new markers using NKLCGI' S previously developed RFLP map based on the same F2 population resolved these markers to all 12 rice chromosomes. Integration of the SSR and AFLP markers into the RFLP map resulted in a high density molecular linkage map containing 612 polymorphic loci.     

Microsatellite marker development,mapping and applications in rice genetics and breeding

Microsatellites are simple, tandemly repeated di- to tetra-nucleotide sequence motifs flanked by unique sequences. They are valuable as genetic markers because they are co-dominant, detect high levels of allelic diversity, and are easily and economically assayed by the polymerase chain reaction (PCR). Results from screening a rice genomic library suggest that there are an estimated 5700-10 000 microsatellites in rice, with the relative frequency of different repeats decreasing with increasing size of the motif. A map consisting of 120 microsatellite markers demonstrates that they are well distributed throughout the 12 chromosomes of rice. Five multiple copy primer sequences have been identified that could be mapped to independent chromosomal locations. The current level of genome coverage provided by these simple sequence length polymorphisms (SSLPs) in rice is sufficient to be useful for genotype identification, gene and quantitative trait locus (QTL) analysis, screening of large insert libraries, and marker-assisted selection in breeding. Studies of allelic diversity have documented up to 25 alleles at a single locus in cultivated rice germplasm and provide evidence that amplification in wild relatives of Oryza sativa is generally reliable. The availability of increasing numbers of mapped SSLP markers can be expected to complement existing RFLP and AFLP maps, increasing the power and resolution of genome analysis in rice.     

Construction of a DNA library from chromosome 4 of rice （Oryza sativa） by microdissection

A simple method to create a chromosome-specific DNA librqary of rice,including microdissection,amplification,charterization and cloning,is described.Rice chromosome 4 from a metaphase cell has been isolated and amplified by the Linker Adapter PCR (LA-PCR).The PCR products were labeled as probes with DIG-11-dUTP using the random priming method.Southern blot analysis with rice genomic DNA and specific RFLP markers demonstrated that the PCR products were derived from rice chromosome 4.A large library comprising over 100,000 recombinant plasmid microclones from rice chromosome 4 was constructed.Colony hybridization showed that 58% of the clones contained single or low-copy sequences and 42% contained repetitive sequences.The size of inserts generated by PCR ranged from 140bp to 500bp.This method will facilitate cloning of the specific chromosome DNA markers and important genes of rice.     

Alignment of molecular and classical linkage maps of rice,Oryza sativa

Application of genetic linkage maps in plant genetics and breeding can be greatly facilitated by integrating the available classical and molecular genetic linkage maps. In rice, Oryza sativa L., the classical linkage map includes about 300 genes which correspond to various important morphological, physiological, biochemical and agronomic characteristics. The molecular maps consist of more than 500 DNA markers which cover most of the genome within relatively short intervals. Little effort has been made to integrate these two genetic maps. In this paper we report preliminary results of an ongoing research project aimed at the complete integration and alignment of the two linkage maps of rice. Six different F₂ populations segregating for various phenotypic and RFLP markers were used and a total of 12 morphological and physiological markers (Table 1) were mapped onto our recently constructed molecular map. Six linkage groups (i.e., chr. 1, 3, 7, 9, 11 and 12) on our RFLP map were aligned with the corresponding linkage groups on the classical map, and the previous alignment for chromosome 6 was further confirmed by RFLP mapping of an additional physiological marker on this chromosome. Results from this study, combined with our previous results, indicate that, for most chromosomes in rice, the RFLP map encompasses the classical map. The usefulness of an integrated genetic linkage map for rice genetics and breeding is discussed.Abbreviations RFLP restriction fragment length polymorphism - chr chromosome - cM centiMorgan