水稻线粒体DNA酶切带型研究

水稻IR36线粒体DNA经6种限制酶酶切,用脉冲电泳和长距离琼脂糖凝胶电泳分离酶切片段,获得高分辨率的清晰带型。每组酶切片段加和测得水稻IR36线粒体基因组大小分别为227kb(HindⅢ)、253kb(EcoRⅠ)、253kb(XhoⅠ)、294kb(BamHⅠ)、239kb(SalⅠ)和283kb(xbal)采用9个来自水稻和玉米线粒体基因组的基因探针与酶切条带杂交发现,水稻线粒体基因组含有包括编码基因在内的重复顺序。     

用垂直凝胶脉冲电泳分离染色体DNA

脉冲电场凝胶电泳(PFGE)是近几年发展起来的一种分离高分子DNA片段(50—10000kb)的有效方法。包括正交场,六边形场,反向场和垂直胶脉冲电泳。本文改进了垂直胶脉冲电场(TAFE)的条件,使酵母DCo4染色体电泳核型从11条带提高到14条。利用TAFE鉴定了蛋白酶消化法和TLS法制备的人基因A,其分子长度主要分布在200—450kb。     

小麦蓝矮植原体染色体DNA的分离

[目的]分离小麦蓝矮(WBD)植原体染色体DNA,并建立WBD植原体染色体分离纯化体系.[方法]采用差速离心和脉冲电泳(PFGE)方法富集纯化WBD植原体染色体DNA,并通过PCR和Southern blot进行检测验证,实时荧光定量PCR方法对分离纯化效果进行定量检测.[结果]脉冲电泳凝胶中出现一条大小约为650 kb的条带,经PCR检测和Southern blot分析表明该条带为WBD植原体的染色体DNA.实时荧光定量PCR检测结果表明采用差速离心与脉冲电泳结合的方法可以将WBD植原体基因组的相对拷贝数提高436.5倍.[结论]采用差速离心与脉冲电泳法结合可以有效地从感染WBD长春花中分离到纯的WBD植原体染色体DNA,WBD植原体染色体DNA大小约为650 kb.     

温敏核不育水稻5460S细菌人工染色体文库的构建和鉴定

为了构建温敏核不育 (TGMS)基因区域的精细物理图谱并最终分离TGMS基因 ,以温敏核不育水稻 5 46 0S为材料 ,摸索优化了构建植物细菌人工染色体 (BAC)文库的方法 ,构建了一个高质量的BAC文库 .该文库由 1 95 84个克隆构成 ,插入片段平均长度为 1 1 0kb ,相当于水稻单倍体基因组大小的 5倍 ;以分子量分别为 1 40和2 5 0kb的 2个大BAC克隆进行稳定性传代实验 ,经 1 0 0代传代后其插入的DNA片段仍然稳定存在 ;以线粒体和叶绿体基因为探针筛选BAC文库 ,未检验出叶绿体和线粒体DNA的污染 ;以和tms1基因连锁的 3个分子标记作为探针对BAC文库进行了筛选 ,每个探针至少可获得一个阳性克隆 ,利用热不对称性交错PCR(Tail PCR)法成功分离了阳性克隆的左右末端序列 .     

细胞质雄性不育高粱叶绿体 ndh D 基因的序列变异

片段SAAU－02 700特异地扩增自7种具可育细胞质的高粱材料的总DNA,含有叶绿体psa C(88bp)和ndh D(192bp)基因的部分序列。该片段与Eco Ri HindⅢ酶切的总DNA,线粒体DNA和叶绿体DNA杂交,在总DNA中获得了0.74kb的杂交带,而在叶绿体中获得0.74kb和0．45kb两条杂交带。与线粒体DNA无杂交;与经Hae Ⅲ酶切的总DNA杂交,在不育系中获得4．9kb的杂交带,而保持系的杂交带为4．45kb。参考GenBank中高粱的近缘物种玉米叶绿体基因组的序列,构建了ndh D基因区的酶切位点图谱,借此分析得出高粱不育系的叶绿体ndh D基因序列已发生改变。这种变异与高粱细胞质雄性不育反生的关系正在探讨中。     

水稻线粒体atpA基因的克隆及其与细胞质雄性不育的关系

本研究以水稻BT型细胞质雄性不育系秋光和相应的保持系秋光为材料,提取线粒体DNA,用限制性内切酶完全酶解,以玉米线粒体atpA基因和波菜叶绿体atpA基因作为探针,进行分子杂交,将保持系线粒体atpA基因定位在3.5kb的Bam HI酶切片段上,并且以pBR322为载体,克隆了这一片段,另外,在Bam HI完全酶解普带的杂交结果中,不育系线粒体基因组中有两条阳性杂交带,分别是3.5kb和2.9kb,而保持系线粒体基因组中只有3.5kb一条阳性杂交带,因而认为水稻不育系线粒体基因组中可能有两个atpA基因拷贝,而相应的保持系线粒体基因组中只有一个atpA基因拷贝。     

水稻线粒体atpA基因的克隆及其与细胞质雄性不育的关系

本研究以水稻BT型细胞质雄性不育系秋光和相应的保持系秋光为材料，提取线粒体DNA，用限制性内切酶完全酶解，以玉米线粒体atpA基因和波菜叶绿体atpA基因作为探针，进行分子杂交，将保持系线粒体atpA基因定位在3.5kb的Bam HI酶切片段上，并且以pBR322为载体，克隆了这一片段，另外，在Bam HI完全酶解普带的杂交结果中，不育系线粒体基因组中有两条阳性杂交带，分别是3.5kb和2.9kb，而保持系线粒体基因组中只有3.5kb一条阳性杂交带，因而认为水稻不育系线粒体基因组中可能有两个atpA基因拷贝，而相应的保持系线粒体基因组中只有一个atpA基因拷贝。     

植物叶绿体与线粒体基因组DNA特异性比较研究

研究不同植物间叶绿体和线粒体基因组DNA的差异,探讨其在法庭科学中的应用价值.根据叶绿体和线粒体基因组DNA核苷酸序列的特点,分别设计了一系列相应的引物,经PCR扩增后,电泳鉴别不同的植物.结果表明在设计的一系列引物中,叶绿体基因组DNA的PCR产物差异不大,鉴别效果不明显;而线粒体基因DNA的PCR产物差异大,鉴别效果明显.因此以线粒体DNA为模板进行PCR扩增,在不同植物间存在良好的差异性,适合于不同植物间的鉴别,在法庭科学中具有实际应用价值.     

一种改良的大豆线粒体DNA提取方法

以大豆(Glycine max (L.) Merrill)黄化苗为材料,通过优化提取线粒体DNA(mtDNA)时差速离心过程中的离心力和离心时间,以及纯化过程中设置不同的蔗糖密度梯度和裂解液浓度,结合高盐法去除蛋白质,改良大豆mtDNA的提取方法。结果表明,该方法提取的mtDNA浓度和纯度较高,无叶绿体和核基因组DNA的污染,可用于后续大豆线粒体基因组的相关研究。     

荷斯坦奶牛瘤胃微生物元基因组Fosmid文库的构建与分析

采用包埋法提取荷斯坦奶牛瘤胃微生物大片段总DNA,纯化后脉冲场电泳回收大小为36～48 kb,与pcc2FOS vector连接,转染至大肠埃希菌EPI 300宿主细胞,构建瘤胃微生物Fosmid基因组文库.对文库进行鉴定,该文库平均插入片段大小约35 kb,共保存30 000个克隆,空载体率小于2%,库容达1 050 Mb.     

从植物细胞核分离大分子量核DNA

研究了从植物中分离百万碱基对级大分子量核DNA的方法。该方法利用差速离心分离植物细胞核,经低熔点琼脂糖块或低熔点琼脂糖微珠包埋,蛋白酶K原位裂解后制备大分子量核DNA。结果表明,选择不同生长时期的材料和不同的包埋细胞核方式对大分子量核DNA的制备有很大的影响,由黄化苗或幼嫩的绿叶为材料分离细胞核,进行胶块包埋是制备大分子量核DNA的最佳条件。利用该法获得的DNA分子量在200kb－5．7Mb之间,主要集中在2．2～5．7Mb之间;每一胶块DNAE量为18～20μg。与包埋原生质体制备大分子量核DNA的方法相比,该方法获得的DNA纯度较高,去除了大部分细胞器DNA的污染;易于被限制性内切酶部分和完全消化,其消化结果具可重复性。该方法操作简单、适用植物种类广泛,用该方法从水稻（OryzasativaL．）、苹果（MaluspumilaMill．）、大豆（Glycinemax（L．）Merr．）、玉米（ZeamaysL．）等多种植物材料中成功地制备了大分子量核DNA。该方法制备的核DNA适用于植物的脉冲交变电泳基因组分析和构建人工细菌染色体文库和人工酵母染色体文库。     

Rice chloroplast DNA: a physical map and the location of the genes for the large subunit of ribulose 1,5-bisphosphate carboxylase and the 32 KD photosystem II reaction center protein

Summary By homogenizing rice leaves in liquid nitrogen, it was possible to isolate intact chloroplasts and, subsequently, pure rice chloroplast DNA from the purified chloroplasts. The DNA was digested by several restriction enzymes and fragments were fractionated by agarose gel electrophoresis. The sum of the fragment sizes generated by the restriction enzymes showed that the total length of the DNA is 130 kb. A circular physical map of fragments, generated by digestion with SalI, PstI, and PvuII, has been constructed. The circular DNA contains two inverted repeats of about 20 kb separated by a large, single copy region of about 75 kb and a short, single copy region of about 15 kb. The location of the gene for the large subunit of ribulose 1,5-bisphosphate carboxylase (Fraction I protein) and the 32 KD photosystem II reaction center gene were determined by using as probes tobacco chloroplast DNAs containing these genes. Rice chloroplast DNA differs from chloroplast DNAs of wheat and corn as well as from dicot chloroplast DNAs by having the 32 KD gene located 20 kb removed from the end of an inverted repeat instead of close to the end, as in other plants.     

水稻叶绿体DNA的提取和纯化

以籼稻品种珍讪97B为材料,采用溶液捣碎和不连续蔗糖梯度离心的方法提取了籼稻的叶绿体DNA,DNA经限制性内切酶酶解和琼脂糖胶电泳可以得到清晰的条带,来自蚕豆的核酮糖—1,5—二磷酸羧化氧合酶大亚基基因探针和23SrRNA基因探针可以与酶切条带杂交,由此确定了含这二种基因的BamHI酶切片段。     

The construction and characteristics of a BAC library for <Emphasis Type="Italic">Cucumis sativus</Emphasis> L. ‘B10’

Cloning using bacterial artificial chromosomes (BACs) can yield high quality genomic libraries, which are used for the physical mapping, identification and isolation of genes, and for gene sequencing. A BAC genomic library was constructed from high molecular weight DNA (HMW DNA) obtained from nuclei of the cucumber (Cucumis sativus L. cv. Borszczagowski; B10 line). The DNA was digested with the HindIII restriction enzyme and ligated into the pCC1BAC vector. The library consists of 34,560 BAC clones with an average insert size of 135 kb, and 12.7x genome coverage. Screening the library for chloroplast and mitochondrial DNA content indicated an exceptionally low 0.26% contamination with chloroplast DNA and 0.3% with mitochondrial DNA.     

Preparation of megabase-size DNA from plant nuclei

A novel technique has been developed for the preparation of high molecular weight (HMW) DNA from plant nuclei. This technique involves physical homogenization of plant tissues, nuclei isolation, embedding of the nuclei in low-melting-point agarose microbeads or plugs, and DNA purification in situ . This technique is simple, rapid, and economical, and the majority of the DNA prepared is over 5.7 Mb in size. The genomic DNA content of the HMW DNA prepared by this technique is enriched by at least threefold and the chloroplast DNA content is reduced by over twofold relative to that prepared from plant protoplasts by existing methods. The DNA is readily digestible with different restriction enzymes and partial digestions of the DNA could be reproducibly performed. This method has been successfully used for the preparation of HMW DNA from a wide range of plant taxa, including grasses, legumes, vegetables, and trees. These results demonstrate that the DNA prepared by this technique is suitable for plant genome analysis by pulsed-field gel electrophoresis and for the construction of yeast and bacterial artificial chromosomes.     

水稻核基因组DNA的YAC克隆和鉴定

将EcoRI部分消化的水稻(Oryza sativa L.)细胞核高分子量DNA电泳分部,回收大于200kb的片段,与内切酶消化过的酵母人工染色体(YAC)双质粒载体pJs97。pJS98DNA连接,转化酵母YPH252感受态原生质球,用ura^-,TrP^-双选择培养基直接筛选转化子,已获得2 000多个克隆。转化子DNA的southern杂交显示插入片段在200～820kb范围。     

Preparation of high molecular weight plant DNA and its use for artificial chromosome construction

Summary The availability of a substantial amount of high molecular weight DNA is an essential prerequisite for the construction of yeast artificial chromosome (YAC) libraries. Parameters concerning protoplast isolation and DNA extraction have been systematically analyzed. Conditions have been established for the obtainment of high molecular weight DNA from Arabidopsis thaliana and Nicotiana plumbaginifolia protoplasts either embedded in agarose plugs or in liquid suspension. Restriction fragments were obtained by partial and total digestion with different endonucleases, and separated by pulsed-field gel electrophoresis. Ligation of partially EcoRI-digested DNA (range 30–300 kbp) followed by transformation of yeast spheroplasts gave rise to YACs with an average size of 60 kbp. The introduction of a DNA size-selection step before ligation led to production of YACs in the range of 100–200 kbp. Clones of up to 460 kbp were obtained by blunt-end ligation of pre-selected unrestricted DNA.Abbreviations 2,4-D 2,4-dichloro phenoxyacetic acid - 6BAP 6-benzylaninopurine - BFP bovine serum albumin 0.1%, Ficoll 400 0.1%; polyvinylpyrrolidone 0.1% - CHEF clumped homogeneous electric field - DTT dithiothreitol - EDTA ethylenediaminetetraacetic acid - HMW high molecular weight - km kanamycin - LMP agarose low melting point agarose - MS Murashige and Skoog mediun - npt neomycin phosphotransferase - PEG polyethyleneglycol - PFGE pulsed-field gel electrophoresis - RFLP restriction fragrant lenght polymorphism - SDS sodium dodecyl sulphate - SSC sodium chloride 150 mM, sodiun citrate 15 nM, pH 7 - TAE TRIS-Acetate pH 8 40 mM, EDTA 2 mM - TE TRIS-HCl pH 8 10 mM, EDTA 1 mM - YAC yeast artificial chromosome     

A thermal denaturation study of the genomic DNAs from the North American genera of the fish family Percidae

The genomic DNAs of 1 1 species of percid fishes representing the five recognized North American genera are characterized using data from thermal denaturation assays. Base compositions were estimated from the transitional melting temperature of native and sonicated DNA and expressed as per cent guanine-cytosine (%GC) values. Among genera, %GC values for native DNAs (c, 23,000 base pairs in length) range between 38.3% GC for yellow perch, Perca flavescens (Mitchill), to 43.2% GC for sauger, Stizostedion cunadense (Smith). Significant variation in %GC values was observed among surveyed genera of the subfamily Percinae, which include Perca, Percinu, Etheostoma and Ammocrypfa . Melting profiles were generated for each species, and distinct GC rich regions were identified within the genomes of walleye, Sfizostcdion virreum (Mitchill) and Etheostoma spp. Compositional heterogeneity (CH) and asymmetry values were calculated from melting profile data. Patterns of variation in genomic characters differed among the genera surveyed. Members of the speciose genus Etheostomu showed relatively little variation in genomic characters, whereas Stizosredion exhibited significant interspecific variation.     

Novel method for preparation of the template DNA and selection of primers to differentiate the material rice cultivars of rice wine by PCR

As many rice wine brewers label the name of the cultivar of the material rice, authentication technology is necessary. The problems are (1) decomposition of DNAs during the fermentation, (2) contamination of DNAs from microorganisms, (3) co-existence of PCR inhibitors, such as polyphenols. The present authors improved the PCR method by (1) lyophilizing and pulverizing the rice wine to concentrate DNAs, (2) decomposition of starches and proteins so as not to inhibit DNA extraction by the use of heat-resistant amylase and proteinase K, (3) purification of the template DNA by the combination of CTAB method and fractional precipitation by 70% EtOH. To prevent the amplification of microorganism's DNAs during PCR, the present authors selected the suitable plant-specific primers. It became possible to prepare the template DNAs for PCR from the rice wine. The sequences of the amplified DNAs by PCR were ascertained to be same with those of material rice. Mislabeling of material rice cultivar was detected by PCR using the commercial rice wine. It became possible to extract and purify the template DNAs for PCR from the rice wine and to differentiate the material rice cultivars by the PCR using the rice wine as a sample.     

Selection of RAPD marker for growth of seedlings at low temperature in rice.

We have developed a polymerase chain reaction (PCR)-based assay that could effectively reduce the time period required to screen and select the cold tolerance gene of rice seedlings under field conditions. The two specific random amplified polymorphic DNA (RAPD) fragments for the assay were identified on the basis of quantitative trait loci (QTL) analysis which were found to be tightly linked to cold sensitivity. The two RAPD fragments, OPT8(600) in the cold sensitivity rice cultivar 'Dular (indica)' and OPU20(1200) in the resistance rice cultivar 'Toyohatamochi (japonica)', were identified after screening 11 RAPD fragments using 2 random primers on the genomic DNAs of 'Dular' and 'Toyohatamochi'. These primers, when used in a multiplexed PCR, specifically amplified a 0.6 kb and a 1.2 kb fragment in the sensitive and resistant rice cultivars, respectively. When this assay was performed on the genomic DNAs of 16 japonica, 3 Tongil (indica/ japonica), and 2 indica rice cultivars, the primers amplified a 0.6 kb fragment in all of the cold sensitivity rice cultivars or 1.2 kb fragment in all of the resistance ones. These markers can be of potential use in the marker-assisted selection (MAS) for cold tolerance in rice seedling. As screening for resistance can now be conducted independent of the availability of low temperature, the breeding of cold tolerance cultivars can be hastened.