人类基因组的物理图谱与大规模DNA测序

１历史的回顾物理图谱的制作是与分子克隆技术分不开的。限制性内切酶的发现,导致了第一个物理图谱的完成（ＳＶ４０;Ｄａｎｎａ与Ｎａｔｈａｎｓ,１９７１）。新克隆技术,尤其是ＹＡＣ（ＹｅａｓｔＡｒｔｉｆｉｃｉａｌＣｈｒｏｍｏｓｏｍｅ）和ＢＡＣ（Ｂａｃｔｅｒ...     

小麦—簇毛表6VS／6AL易位系可转化人工染色体（TAC）文库的构建

可转化人工染色体（Ｔｒａｎｓｆｏｒｍａｔｉｏｎ ｃｏｍｐｅｔｅｎｔ Ａｒｔｉｆｉｃｉａｌ Ｃｈｒｏｍｏｓｏｍｅ,ＴＡＣ）是具有克隆和转移大片段基因能力的新型载体,是植被基因克隆和转化的有效工具。为了克隆泪科抗白粉病基因和其它基因,本研究用ＴＣＡ载体ｐＹＬＴＡＣ１７构建了带有抗白粉病基因Ｐｍ２１的小麦＝簇毛麦６ＶＳ／６ＡＬ易位系的基因组ＤＮＡ文库。该文库包含２１０万个克隆平均插入征段３５ｌｂ,相当于     

人Xp21．1－p21．3上3．5MbYAC重叠群构建及物理图谱分析

用Ａｌｕ－ＰＣＲ指纹图谱法分析了人Ｘｐ２１．１－ｐ２１．３上一系列的酵母人工染色体（ｙｅａｓｔａｒｔｉｆｉｃｉａｌｃｈｒｏｍｏｓｏｍｅ,ＹＡＣ）克隆,发现其中的两个ＹＡＣ克隆构成包含ＤＸＳ１６６位点的重叠群,而且这一重叠群与以前构建的包含ＤＭＤ基因全序列的ＹＡＣ重叠群相连接,ＹＡＣ克隆末端探针交叉杂交证实了这一重叠,使这一ＹＡＣ重叠群至少延伸至ＤＸＳ１６６位点,形成一个跨度为３．５Ｍｂ的ＹＡＣ重叠群。基于这些重叠的ＹＡＣ克隆绘制了这一区域的大尺度限制酶切图谱,并在这一图谱上定位了ＤＸＳ１６６位点,从而确定了ＤＸＳ１６６位点与ＤＭＤ基因的物理关系。这一工作为ＤＭＤ基因的５＇远端调控作用研究及该区域未知基因的克隆奠定了基础。     

染色体显微切割技术

最近十几年里,在对染色体特定基因研究和分子标记遗传图谱等研究方面,以经典的遗传作图为基础,出现了很多新方法,微切及微克隆技术（ＣｈｒｏｍｏｓｏｍｅＭｉｃｒｏｄｉｓｓｅｃｔｉｏｎａｎｄＭｉ－ｃｒｏｃｌｏｎｇ）是随着近１０年来分子生物学技术的发展而诞生的...     

与西瓜野生种质抗枯萎病基因连锁的RAPD标记

运用ＲＡＰＤ技术,采用混合分组分析（ｂｕｌｋｅｄｓｅｇｒｅｇａｎｔａｎａｌｙｓｉｓ,ＢＳＡ）方法进行了西瓜（Ｃｉｔｒｕｌｌｕｓｌａｎａｔｕｓ（Ｔｈｕｎｂ．）Ｍａｎｓｆｅｌｄｖａｒ． ｃｉｔｒｏｉｄｅｓ） 野生种质ＰＩ２９６３４１ 抗枯萎病基因连锁的分子标记研究。研究结果表明：西瓜野生种质Ｐ１２９６３４１ 抗枯萎病生理小种１ 的抗性由单显性基因控制,ＲＡＰＤ标记ＯＰＰＯＬ／７００ 与其抗病基因连锁,其遗传距离为３０ ｃＭ（ｃｅｎｔｉｍｏｒｇａｎ）。这为进行抗病分子标记辅助选择,以及最终定位与克隆其抗病基因打下了良好基础。     

亚洲象的染色体

亚洲象的染色体ＴＨＥＣＨＲＯＭＯＳＯＭＥＯＦＡＳＩＡＮＥＬＥＰＨＡＮＴ关键词亚洲象，核型，染色体带型ＫｅｙｗｏｒｄｓＡｓｉａｎｅｌｅｐｈａｎｔ，Ｋａｒｙｏｔｙｐｅ，Ｂａｎｄｉｎｇｏｆｃｈｒｏｍｏｓｏｍｅｓ中图分类号Ｑ９５９８４５本文１９９６－０８－...     

达乌尔黄鼠染色体银染核仁组织者分析

达乌尔黄鼠染色体银染核仁组织者分析ＡＮＡＬＹＳＩＳＯＮＣＨＲＯＭＯＳＯＭＥＳＡｇ－ＮＯＲＳＯＦＣＩＴＥＬＬＵＳＤＡＵＲＩＣＵＳＫｅｙｗｏｒｄｓＣｉｌｅｌｌｕｓｄａｕｒｉｃｕｓ;Ｃｈｒｏｍｏｓｏｍｅ;Ａｇ－ＮＯＲ达乌尔黄鼠（ｃｉｌｅｌｌｕｓｄａｕｒｉｃ...     

植物染色体显微切割技术的研究现状与展望

植物染色体显微切割技术的研究现状与展望马有志徐琼芳辛志勇（中国农业科学院作物育种栽培研究所,北京１０００８１）ＴｈｅＡｄｖａｎｃｅｓｏｆｔｈｅＴｅｃｈｎｉｑｕｅｏｆＰｌａｎｔＣｈｒｏｍｏｓｏｍｅＭｉｃｒｏｄｉｓｅｃｔｉｏｎＭａＹｏｕｚｈｉＸｕＱｉｏｎ...     

phbB,phbC基因克隆,序列分析及植物表达载体的构建

利用聚合酶链式反应技术,从真养产碱杆菌Ａｌｃａｌｉｇｅｎｅｓ ｅｕｔｒｏｐｈｕｓ Ｈ１６染色体ＤＮＡ中的主增并克隆了调控聚－β－羧基丁酸生物合成的两个关键酶基因;依赖ＮＡＤＰＨ的乙酰乙酰ＣｏＡ还原酶基因和ＰＨＢ合成酶基因。限制性内切酶图谱和核苷酸序列分析证实了克隆结果,并表明所克隆的基因与国外报道的有很高的同源性。     

蔗糖梯度离心纯化人类中期染色体

蔗糖梯度离心纯化人类中期染色体①施家琦唐冬生夏家辉（湖南医科大学医学遗传学国家重点实验室,长沙４１００７８）ＰｕｒｉｆｉｃａｔｉｏｎｏｆＨｕｍａｎＭｅｔａｐｈａｓｅＣｈｒｏｍｏｓｏｍｅｓｂｙＳｕｃｒｏｓｅＧｒａｄｉｅｎｔＣｅｎｔｒｉｆｕｇａｔｉｏｎＳ...     

Identification of a 118-kb DNA fragment containing the locus of blast resistance gene Pi-2(t) in rice

Rice blast disease, caused by the fungal pathogen Pyricularia grisea Sacc., is one of the most devastating crop diseases worldwide. Previous studies have shown that the dominant blast resistance gene Pi-2(t) confers resistance to a broad spectrum of pathogenic strains. Using a population of 292 recombinant inbred lines combined with bioinformatic analysis, we mapped Pi-2(t) between the SSR (simple-sequence repeat) marker SSR140 and the RFLP (restriction fragment length polymorphism) marker JSH12, 0.9 cM from both SSR140 and JSH12. A physical map consisting of six overlapping BAC (bacterial artificial chromosome) clones was anchored to the region containing the Pi-2(t) locus. By analyzing recombination events in this region, the Pi-2(t) locus was localized to a DNA fragment of 118 kb in length. The detailed genetic and physical maps of the Pi-2(t) locus will facilitate both molecular isolation of the gene and marker-assisted transfer of the gene in breeding programs.     

Tagging genes for blast resistance in rice via linkage to RFLP markers

Summary Both Pi-2(t) and Pi-4(t) genes of rice confer complete resistance to the blast fungal pathogen Pyricularia oryzae Cav. As economically important plant genes, they have been recently characterized phenotypically, yet nothing is known about their classical linkage associations and gene products. We report here the isolation of DNA markers closely linked to these blast resistance genes in rice. The DNA markers were identified by testing 142 mapped rice genomic clones as hybridization probes against Southern blots, consisting of DNA from pairs of nearly isogenic lines (NILs) with or without the target genes. Chromosomal segments introgressed from donor genomes were distinguished by restriction fragment length polymorphisms (RFLPs) between the NILs. Linkage associations of the clones with Pi-2(t) and Pi4(t) were verified using F₃ segregating populations of known blast reaction. Cosegregation of the resistant genotype and donor-derived allele indicated the presence of linkage between the DNA marker and a blast resistance gene. RFLP analysis showed that Pi-2(t) is closely linked to a single-copy DNA clone RG64 on chromosome 6, with a distance of 2.8+1.4(SE) cMorgans. Another blast resistance gene, Pi-4(t), is 15.3+4.2(SE) cMorgans away from a DNA clone RG869 on chromosome 12. These chromosomal regions can now be examined with additional markers to define the precise locations of Pi-2(t) and Pi-4(t). Tightly linked DNA markers may facilitate early selection for blast resistance genes in breeding programs. These markers may also be useful to map new genes for resistance to blast isolates. They may ultimately lead to the cloning of those genes via chromosome walking. The gene tagging approach demonstrated in this paper may apply to other genes of interest for both monogenic and polygenic traits.     

Two broad-spectrum blast resistance genes,<Emphasis Type="Italic"> Pi9</Emphasis>(<Emphasis Type="Italic">t</Emphasis>) and<Emphasis Type="Italic"> Pi2</Emphasis>(<Emphasis Type="Italic">t</Emphasis>), are physically linked on rice chromosome 6

To understand the molecular basis of broad-spectrum resistance to rice blast, fine-scale mapping of the two blast resistance (R) genes, Pi9( t) and Pi2( t), was conducted. These two genes were introgressed from different resistance donors, previously reported to confer resistance to many blast isolates in the Philippines, and were mapped to an approximately 10-cM interval on chromosome 6. To further test their resistance spectrum, 43 blast isolates collected from 13 countries were used to inoculate the Pi2( t) and Pi9( t) plants. Pi9( t)-bearing lines were highly resistant to all isolates tested, and lines carrying Pi2( t) were resistant to 36 isolates, confirming the broad-spectrum resistance of these two genes to diverse blast isolates. Three RAPD markers tightly linked to Pi9( t) were identified using the bulk segregant analysis technique. Twelve positive bacterial artificial chromosome (BAC) clones were identified and a BAC contig covering about 100 kb was constructed when the Pi9( t) BAC library was screened with one of the markers. A high-resolution map of Pi9( t) was constructed using BAC ends. The Pi2( t) gene was tightly linked to all of the Pi9( t) markers in 450 F(2) plants. These data suggest that Pi9( t) and Pi2( t) are either allelic or tightly linked in an approximately 100-kb region. The mapping results for Pi9( t) and Pi2( t) provide essential information for the positional cloning of these two important blast resistance genes in rice.     

Identification of RAPD markers linked to a major blast resistance gene in rice

Rice blast, caused byPyricularia grisea, is a major production constraint in many parts of the world. The Korean rice variety Tongil showed high levels of resistance for about six years when widely planted under highly disease-conducive conditions, before becoming susceptible. Tongil was found to carry a single dominant gene, designatedPi-10t, conferring resistance to isolate 106 of the blast pathogen from the Philippines. We report here the use of bulked segregant RAPD analysis for rapid identification of DNA markers linked toPi-10t. Pooled DNA extracts from five homozygous blast-resistant (RR) and five susceptible (rr) BC₃F₂ plants, derived from a CO39 × Tongil cross, were analyzed by RFLP using 83 polymorphic probes and by RAPD using 468 random oligomers. We identified two RAPD markers linked to thePi-10t locus: RRF6 (3.8 ± 1.2 cM) and RRH18 (2.9 ± 0.9 cM). Linkage of these markers withPi-10t was verified using an F2 population segregating forPi-10t. The two linked RAPD markers mapped 7 cM apart on chromosome 5. Chromosomal regions surrounding thePi-10t gene were examined with additional RFLP markers to define the segment introgressed from the donor genome.Pi-10t is likely to be a new blast-resistance locus, because no other known resistance gene has been mapped on chromosome 5. These tightly linked RAPD markers could facilitate early selection of thePi-10t locus in rice breeding programmes.     

A novel gene, <Emphasis Type="Italic">Pi40(t)</Emphasis>, linked to the DNA markers derived from NBS-LRR motifs confers broad spectrum of blast resistance in rice

Rice blast disease caused by Magnaporthe grisea is a continuous threat to stable rice production worldwide. In a modernized agricultural system, the development of varieties with broad-spectrum and durable resistance to blast disease is essential for increased rice production and sustainability. In this study, a new gene is identified in the introgression line IR65482-4-136-2-2 that has inherited the resistance gene from an EE genome wild Oryza species, O. australiensis (Acc. 100882). Genetic and molecular analysis localized a major resistance gene, Pi40(t), on the short arm of chromosome 6, where four blast resistance genes (Piz, Piz-5, Piz-t, and Pi9) were also identified, flanked by the markers S2539 and RM3330. Through e-Landing, 14 BAC/PAC clones within the 1.81-Mb equivalent virtual contig were identified on Rice Pseudomolecule3. Highly stringent primer sets designed for 6 NBS-LRR motifs located within PAC clone P0649C11 facilitated high-resolution mapping of the new resistance gene, Pi40(t). Following association analysis and detailed haplotyping approaches, a DNA marker, 9871.T7E2b, was identified to be linked to the Pi40(t) gene at the 70 Kb chromosomal region, and differentiated the Pi40(t) gene from the LTH monogenic differential lines possessing genes Piz, Piz-5, Piz-t, and Pi-9. Pi40(t) was validated using the most virulent isolates of Korea as well as the Philippines, suggesting a broad spectrum for the resistance gene. Marker-assisted selection (MAS) and pathotyping of BC progenies having two japonica cultivar genetic backgrounds further supported the potential of the resistance gene in rice breeding. Our study based on new gene identification strategies provides insight into novel genetic resources for blast resistance as well as future studies on cloning and functional analysis of a blast resistance gene useful for rice improvement.     

Identification of five new blast resistance genes in the highly blast-resistant rice variety IR64 using a QTL mapping strategy

Rice progenies used for the construction of genetic maps permit exhaustive identification and characterization of resistance genes present in their parental cultivars. We inoculated a rice progeny derived from the cross IR64 x Azucena with different Magnaporthe grisea isolates that showed differential responses on the parental cultivars. By QTL mapping, nine unlinked loci conferring resistance to each isolate were identified and named Pi-24( t) to Pi-32( t). They could correspond to nine specific resistance genes. Five of these resistance loci (RLs) were mapped at chromosomal locations where no resistance gene was previously reported, defining new resistance genes. Using degenerate primers of the NBS (nucleotide binding site) motif found in many resistance genes, two resistance gene analogues (RGAs) IR86 and IR14 were identified and mapped closely to two blast RLs (resistance identified in this study, i.e. Pi-29(t) and Pi-30(t) respectively). These two RLs may correspond to the Pi-11 and Pi-a blast resistance genes previously identified. Moreover, the ir86 and ir14 genes have been identified "in silico" on the indica rice cultivar 93-11, recently sequenced by Chinese researchers. Both genes encodes NBS-LRR-like proteins that are characteristics of plant-disease resistance genes.     

Identification and fine mapping of <Emphasis Type="Italic">Pi33</Emphasis>, the rice resistance gene corresponding to the Magnaporthe grisea avirulence gene <Emphasis Type="Italic">ACE1</Emphasis>

Rice blast disease is a major constraint for rice breeding. Nevertheless, the genetic basis of resistance remains poorly understood for most rice varieties, and new resistance genes remain to be identified. We identified the resistance gene corresponding to the cloned avirulence gene ACE1 using pairs of isogenic strains of Magnaporthe grisea differing only by their ACE1 allele. This resistance gene was mapped on the short arm of rice chromosome 8 using progenies from the crosses IR64 (resistant) × Azucena (susceptible) and Azucena × Bala (resistant). The isogenic strains also permitted the detection of this resistance gene in several rice varieties, including the differential isogenic line C101LAC. Allelism tests permitted us to distinguish this gene from two other resistance genes [Pi11 and Pi-29(t)] that are present on the short arm of chromosome 8. Segregation analysis in F₂ populations was in agreement with the existence of a single dominant gene, designated as Pi33. Finally, Pi33 was finely mapped between two molecular markers of the rice genetic map that are separated by a distance of 1.6 cM. Detection of Pi33 in different semi-dwarf indica varieties indicated that this gene could originate from either one or a few varieties.Communicated by D.J. Mackill     

Towards map-based cloning of the barley stem rust resistance genes Rpg1 and rpg4 using rice as an intergenomic cloning vehicle

The barley stem rust resistance genes Rpg1 and rpg4 were mapped in barley on chromosomes 1P and 7M, respectively and the syntenous rice chromosomes identified as 6P and 3P by mapping common probes in barley and rice. Rice yeast artificial chromosome (YAC), bacterial artificial chromosome (BAC) and cosmid clones were used to isolate probes mapping to the barley Rpg1 region. The rice BAC isolated with the pM13 probe was a particularly excellent source of probes. A high-resolution map of the Rpg1 region was established with 1400 gametes yielding a map density of 3.6 markers per 0.1 cM. A detailed physical map was established for the rice BAC fragment containing the Rpg1-flanking markers pM13 and B24. This fragment covers a barley genetic distance of 0.6 cM and a rice DNA physical distance of ca. 70 kb. The distribution of barley cross-overs in relation to the rice DNA physical distances was extremely uneven. The barley genetic distance between the pM13 marker and Rpg1 was 0.1 cM per ca. 55 kb, while on the proximal side it was 0.5 cm per ca. 15 kb. Three probes from the distal end of the pM13 BAC mapped 3.0 cm proximal of Rpg1 and out of synteny with rice. These experiments confirm the validity of using large insert rice clones as probe sources to saturate small barley (and other large genome cereals) genome regions with markers. They also establish a note of caution that even in regions of high microsynteny, there may be small DNA fragments that have transposed and are no longer in syntenous positions.     

Molecular mapping of genes for resistance to rice blast (Pyricularia grisea Sacc.)

Two dominant genes conferring complete resistance to specific isolates of the rice blast fungus, Pyricularia grisea Sacc., were located on the molecular map of rice in this study. Pi-l(t) is a blast resistance gene derived from the cultivar LAC23. Its map location was determined using a pair of nearly isogenic lines (NILs) and a B₆F₃ segregating population from which the isoline was derived. RFLP analysis showed that Pi-l(t) is located near the end of chromosome 11, linked to RZ536 at a distance of 14.0±4.5 centiMorgans (cM). A second gene, derived from the cultivar Apura, was mapped using a rice doubled-haploid (DH) population. This gene was located on chromosome 12, flanked by RG457 and RG869, at a distance of 13.5+-4.3 cM and 17.7+-4.5 cM, respectively. The newly mapped gene on chromosome 12 may be allelic or closely linked toPi-ta. (=Pi-4(t)), a gene derived from Tetep that was previously reported to be linked to RG869 at a distance of 15.4±4.7 cM. The usefulness of markers linked to blast resistance genes will be discussed in the context of breeding for durable blast resistance.     

An approach to cloning of Pi-b rice blast resistance gene

A contig of clones from BAC rice genomic library encompassing blast resistance gene Pi-b was constructed. On an average eight clones (8 ± 2.6) were picked up by each marker, which was expected basing on the BAC library size (Nakamura et al. 1997). The 2.4 cM distance between flanking RFLP markers G 1234 and RZ 213 (Miyamoto et al. 1996) was spanned with 4 steps of contig including 25 clones. The physical distance of 370 kb between flanking markers corresponds to a small ratio of physical and genetical distances (155 kb/cM) due to a probable structure of the gene locus near the telomeric end of the chromosome. Markers cosegregating with blast resistance against Magnoporthe grisea were localized in a 2 kb restriction fragment. A new border marker was found on the telomeric side of the Pi-b gene, less than 10 kb from cosegregating markers. No clear marker for the centromeric side of the gene was found but the position of Pi-b rice blast resistant gene was narrowed to within at least 50 kb, which is to our knowledge the most precised estimation of the position of this gene.