FISH分析栽培高粱×拟高粱、甜高粱×拟高粱的染色体行为

采用荧光原位杂交技术对45S rDNA在栽培高粱×拟高粱、甜高粱×拟高粱F1的有丝分裂和减数分裂染色体进行定位研究。在有丝分裂中期染色体上2个杂种分别检测到2个杂交信号, 在减数分裂粗线期、终变期、中期Ⅰ染色体上45S rDNA位于一个二价体上, 说明这两个杂种携带45S rDNA的染色体为同源染色体。根据45S rDNA位点随细胞减数分裂过程的位置变化, 表明这两个杂种染色体配对行为正常, 平均构型为2n=2x=20(10Ⅱ), 证明45S rDNA可作为染色体的一个识别指标间接地观察细胞减数分裂过程染色体的变化行为。     

45S rDNA和5S rDNA在南瓜、丝瓜和冬瓜染色体上的比较定位

首次利用荧光原位杂交和双色荧光原位杂交技术对45S和5S rDNA在南瓜(Cucurbita moschata Duch)、丝瓜(Luffa cylindrical Roem)、冬瓜(Benincasa hispida Cogn)的有丝分裂中期染色体上进行了物理定位分析。南瓜有5对45S rDNA位点, 2对5S rDNA位点; 丝瓜具有5对45S rDNA位点, 1对5S rDNA位点; 冬瓜具有2对45S rDNA位点, 1对5S rDNA位点, 5S rDNA位点与其中一对45S rDNA位点都位于7号染色体短臂上, 并在物理位置上紧密相邻。45S rDNA在这3种作物染色体上数目变化较大, 但在染色体上都倾向分布在短臂末端, 其分布模式较为一致。5S rDNA在这3种作物染色体上数目相对保守, 但在染色体上分布的位置变化较大。文中讨论了45S rDNA和5S rDNA在植物基因组中不同的进化趋势。     

栽培荞麦45S和5S rDNA的染色体物理定位研究

采用双色荧光原位杂交技术,对栽培荞麦甜荞和苦荞有丝分裂中期染色体上的45S和5S rDNA基因物理位置进行了定位分析。结果表明,甜荞有4对45S rDNA位点,位于ⅠS、ⅡS、ⅢL、ⅤL(L和S代表长臂和短臂,罗马数字代表染色体序号,下同);2对5S rDNA位点,位于ⅠL、ⅣS。苦荞有5对45S rDNA位点,位于ⅠS、ⅡS、ⅢL、ⅤL、ⅦS;3对5S rDNA位点,位于ⅠL、ⅣS、ⅥS。甜荞与苦荞的45S和5S rDNA位点具有明显的差异,显示其起源上关系较远。依据中期染色体45S和5SrDNA位点信息及经典核型特征,可以准确鉴别甜荞与苦荞8对同源染色体。     

番茄的CPD带型和45S rDNA位点的鉴别

采用CPD（PI和DAPI组合）染色对番茄减数分裂粗线期和有丝分裂中期染色体进行了显带分析,随后用两种不同的45S rDNA克隆在相同的分裂相进行了荧光原位杂交定位分析。CPD染色在8条粗线期染色体上显示出了10条红色的CPD带纹,在6对有丝分裂中期染色体上显示出了12条CPD带纹。有丝分裂中期染色体上的CPD带纹与粗线期染色体上显著的带纹具有对应性。用改良的CPD染色程序清晰而稳定地显示出这些特征性的CPD带纹为番茄的染色体,特别是有丝分裂中期染色体提供了新的识别标记。用番茄的一个45S rDNA克隆进行的荧光原位杂交,不仅在位于2号染色体短臂的随体上显示了强的杂交信号,而且在粗线期染色体的5个CPD带区或有丝分裂中期染色体的4对CPD带区显示了弱的杂交信号。然而,用来自小麦的45S rDNA克隆pTa71进行的原位杂交却只在随体上显示了杂交信号。鉴于所用的两个45S rDNA克隆在序列上的差异,推断在番茄基因组中只有随体含有45S rDNA单位的编码区,即番茄只有一对45S rDNA位点。     

植物45S rDNA的染色体位置的CPD染色和FISH分析

采用PI和DAPI组合(CPD)染色结合45SrDNA探针的荧光原位杂交(FISH)对分属6个科的16种植物的45S rDNA的染色体位置进行了分析。在所有供试植物中,共检测到53个45S rDNA位点。大多数45S rDNA位点分布在染色体的短臂;位于染色体臂内和染色体末端的位点的比例大体相当;多数位于染色体臂内的45S rDNA位点有次缢痕形成,但rDNA重复单位簇所处的位置存在差异。根据45S rDNA所处的染色体臂的不同、距着丝粒远近的差异、形成次缢痕与否以及rDNA重复单位簇相对于次缢痕的位置等特征,将植物的45S rDNA位点划分为12种染色体分布类型。基于我们的结果和其他的报道对45S rDNA位点、核仁组织区(NOR)、次缢痕和随体相互之间的关系进行了分析。     

紫粒小麦核型及45S rDNA位点分析

[目的]建立紫粒小麦的染色体核型,明确紫粒小麦45S rDNA位点的数量与染色体分布,为育种应用提供细胞遗传学资料。[方法]制备紫粒小麦有丝分裂中期染色体制片,通过染色体核型分析软件进行图像采集、染色体长度测量分析,获得紫粒小麦的核型;以45S rDNA为探针,通过荧光原位杂交技术分析其在紫粒小麦染色体上的数量和分布特点。[结果]紫粒小麦的核型特征为2n=6x=42=34m(2SAT)+8sm(2B),染色体上具有3对位于较长染色体臂的近端部45S rDNA杂交位点。[结论]紫粒小麦为六倍体(2n=6x=42),具有不对称的进化属性2B型;在染色体组上有3对45S rDNA位点分布在3对不同染色体,为深入研究紫粒小麦的系统分类提供了细胞学资料。     

大麦45S和5S rDNA定位及5S rDNA伸展纤维的FISH分析

用荧光原位杂交技术对45S和5SrDNA在大麦(Hordeum vulgare L．)有丝分裂中期染色体进行了确定分析,较强的45SrDNA信号共有2对,分别分布在大麦的第1染色体的短臂和第2染色体的长臂。而5SrDNA则只有1对杂交信号,位于第3染色体的长臂,但信号较弱。用伸展DNA纤维的荧光原位杂交(Fiber—FISH)技术测定了5SrDNA在大麦的基因组中的拷贝数,计算出5SrDNA的拷贝数约为408～416。对大麦品种中rDNA位点数目的可变性进行了讨论。     

基于荧光原位杂交的藜属植物核型分析

为精确地识别藜属植物染色体组的核型特征,该文研究了4种来自青海高原的野生藜属植物(灰绿藜、藜、菊叶香藜及杂配藜)和1种从美国引进的栽培藜麦品种PI614932-HX(3)基于染色体荧光原位杂交(rDNA FISH)的核型。利用5S rDNA和45S rDNA对5种藜属植物有丝分裂中期的染色体进行FISH研究。藜属植物的核型分析结果表明:(1)藜属植物中存在二倍体(2n=2x=18)和四倍体(2n=4x=36)两种倍性,藜麦和灰绿藜为四倍体,其余3种为二倍体。(2)藜麦、灰绿藜、藜、菊叶香藜及杂配藜的核型公式分别为2n=4x=36=34m(2AST)+2sm,2n=4x=36=32m(4AST)+4sm,2n=2x=18=16m(4AST)+2sm,2n=2x=18=18m及2n=2x=18=16m+2sm。(3)染色体由大部分的中部着丝粒染色体(m)和少部分近中部着丝粒染色体(sm)组成。(4)核型类型除了菊叶香藜为1B以外,其余均属于2B类型。(5)在藜麦、灰绿藜及藜中具有分布位置不同、数量不等的双随体。5S rDNA、45S rDNA FISH结果表明:(1)藜麦和灰绿藜的染色体上存在2对5S rDNA位点和1对45S rDNA位点,藜、杂配藜的染色体上存在1对5S rDNA位点和1对45S rDNA位点,菊叶香藜的染色体上只存在1对5S rDNA位点。(2)5S rDNA和45S rDNA位点均位于染色体的短臂上。该研究首次获得了藜属植物基于5S rDNA和45S rDNA荧光原位杂交核型,为藜属植物亲缘关系研究和细胞生物学研究提供了分子细胞遗传学依据。     

不同倍性柳枝稷45S rDNA的染色体定位研究

以3个四倍体和6个八倍体栽培品种的根尖为材料,利用荧光原位杂交技术,在核型分析的基础上,开展了不同倍性柳枝稷45S rDNA的染色体定位研究。研究结果表明,四倍体柳枝稷核型公式为2n=4x=36=32m(SAT)+4sm,且45S rDNA在四倍体柳枝稷染色体上分布稳定,位于3号染色体顶端。八倍体柳枝稷栽培品种以及同一栽培品种不同个体间45S rDNA信号分布位置和数目差异较大,可大致分为四类:第Ⅰ类为较强的45S rDNA信号分别分布于染色体两臂的顶端;第Ⅱ类为较强的45S rDNA信号位于染色体一臂内部,第Ⅲ类为较强的45S rDNA信号位于染色体一臂的顶端,第Ⅳ类为较弱的45S rDNA位于染色体一臂内部。八倍体柳枝稷不同栽培品种以及同一栽培品种不同个体间45S rDNA信号复杂性的成因可能与染色体同源重组以及染色体结构变异密切相关。     

白菜rDNA及C-(0)t-1DNA的荧光原位杂交及其核型分析

以早熟白菜苔为实验材料,从其基因组DNA中分离出C0t-1 DNA并用生物素标记作探针,25S rDNA用地高辛标记作探针,对有丝分裂中期相染色体进行双色荧光原位杂交。每对染色体上均显示出了特定的C0t-1 DNA荧光原位杂交带型,5对染色体上显示出了25S rDNA荧光原位杂交带型。双色荧光原位杂交证实了C0t-1 DNA与25S rDNA二者具有一致的染色体位置特征,表明基于rDNA及C0t-1 DNA的荧光原位杂交核型分析技术,优于目前普遍采用的只基于rDNA的荧光原位杂交核型分析方法。结合C0t-1 DNA与25S rDNA的荧光原位杂交带型和传统的染色体的形态学标记分析方法及白菜已公布的基于rDNA分布的核型分析结果,创建了一个精确的白菜核型。     

Karyotyping of Brassica oleracea L. based on rDNA and Cot-1 DNA fluorescence in situ hybridization

To explore an effective and reliable karyotyping method in Brassica crop plants,Cot-1 DNA was isolated from Brassica oleracea genome,labeled as probe with Biotin-Nick Translation Mix kit,in situ hybridized to mitotic spreads,and where specific fluorescent bands showed on each chromosome pair.25S and 5S rDNA were labeled as probes with DIG-Nick Translation Mix kit and Biotin-Nick Translation Mix kit,respectively,in situ hybridized to mitotic preparations,where 25S rDNA could be detected on two chromosome pairs and 5S rDNA on only one.Cot-1 DNA contains rDNA and chromosome sites identity between Cot-1 DNA and 25S rDNA was determined by dual-colour fluorescence in situ hybridization.All these showed that the karyotyping technique based on a combination of rDNA and Cot-1 DNA chromosome landmarks is superior to all but one.A more exact karyotype ofB.oleracea has been analyzed based on a combination of rDNA sites,Cot-1 DNA fluorescent bands,chromosome lengths and arm ratios.     

Visualization by atomic force microscopy and FISH of the 45S rDNA gaps in mitotic chromosomes of Lolium perenne

The mitotic chromosome structure of 45S rDNA site gaps in Lolium perenne was studied by atomic force microscope (AFM) combining with fluorescence in situ hybridization (FISH) analysis in the present study. FISH on the mitotic chromosomes showed that 45S rDNA gaps were completely broken or local despiralizations of the chromatid which had the appearance of one or a few thin DNA fiber threads. Topography imaging using AFM confirmed these observations. In addition, AFM imaging showed that the broken end of the chromosome fragment lacking the 45S rDNA was sharper, suggesting high condensation. In contrast, the broken ends containing the 45S rDNA or thin 45S rDNA fibers exhibited lower density and were uncompacted. Higher magnification visualization by AFM of the terminals of decondensed 45S rDNA chromatin indicated that both ends containing the 45S rDNA also exhibited lower density zones. The measured height of a decondensed 45S rDNA chromatin as obtained from the AFM image was about 55–65 nm, composed of just two 30-nm single fibers of chromatin. FISH in flow-sorted G2 interphase nuclei showed that 45S rDNA was highly decondensed in more than 90% of the G2/M nuclei. Our results suggested that a failure of the complex folding of the chromatin fibers occurred at 45S rDNA sites, resulting in gap formation or break.     

Variation in rDNA locus number and position among legume species and detection of 2 linked rDNA loci in the model Medicago truncatula by FISH.

Within Fabaceae, legume species have a variable genome size, chromosome number, and ploidy level. The genome distribution of ribosomal genes, easily detectable by fluorescent in situ hybridization (FISH), is a good tool for anchoring physical and genetic comparative maps. The organisation of 45S rDNA and 5S loci was analysed by FISH in the 4 closely related species: Pisum sativum, Medicago truncatula, Medicago sativa (2 diploid taxa), and Lathyrus sativus. The 2 types of rDNA arrays displayed interspecific variation in locus number and location, but little intraspecific variation was detected. In the model legume, M. truncatula, the presence of 2 adjacent 45S rDNA loci was demonstrated, and the location of the rDNA loci was independent of the general evolution of the genome DNA. The different parameters relative to clustering of the rDNA loci in specific chromosome regions and the possible basis of rDNA instability are discussed.     

Cytogenetic and molecular identification of three Triticum aestivum-Leymus racemosus translocation addition lines

Chromosome 2C from Aegilops cylindrica has the ability to induce chromosome breakage in common wheat （Tritivum aestivum）. In the BC1F3 generation of the T. aestivum cv. Chinese Spring and a hybrid between T. aestivum-Leymus racemosus Lr.7 addition line and T. aestivum-Ae, cylindrica 2C addition line, three disomic translocation addition lines （2n = 44） were selected by mitotic chromosome C-banding and genomic in situ hybridization. We further characterized these T. aestivum-L, racemosus translocation addition lines, NAU636, NAU637 and NAU638, by chromosome C-banding, in situ hybridization using the A- and D-genome-specific bacterial artificial chromosome （BAC） clones 676D4 and 9M13; plasmids pAsl and pSc119.2, and 45S rDNA; as well as genomic DNA of L. racemosus as probes, in combination with double ditelosomic test cross and SSR marker analysis. The translocation chromosomes were designated as T3AS-Lr7S, T6BS-Lr7S, and T5DS-Lr7L. The translocation line T3AS-Lr7S was highly resistant to Fusarium head blight and will be useful germplasm for resistance breeding.     

Extensive ribosomal DNA amplification during Andean common bean (Phaseolus vulgaris L.) evolution

The extent of 5S and 45S ribosomal DNA (rDNA) variation was investigated in wild and domesticated common beans (Phaseolus vulgaris) chosen to represent the known genetic diversity of the species. 5S and 45S rDNA probes were localized on mitotic chromosomes of 37 accessions by fluorescent in situ hybridization (FISH). The two 5S rDNA loci were largely conserved within the species, whereas a high variation in the number of 45S rDNA loci and changes in position of loci and number of repeats per locus were observed. Domesticated accessions from the Mesoamerican gene pool frequently had three 45S rDNA loci per haploid genome, and rarely four. Domesticated accessions from Andean gene pool, particularly from the race Peru, showed six, seven, eight or nine loci, but seven loci were found in all three races of this gene pool. Between three and eight loci were observed in accessions resulting from crosses between Andean and Mesoamerican genotypes. The presence of two to eight 45S rDNA loci in wild common beans from different geographic locations indicates that the 45S rDNA amplification observed in the Andean lineage took place before domestication. Our data suggest that ectopic recombination between terminal chromosomal regions might be the mechanism responsible for this variation.     

白菜rDNA及C0t-1DNA的荧光原位杂交及其核型分析

以早熟白菜苔为实验材料,从其基因组DNA中分离出C0t-1DNA并用生物素标记作探针,25SrDNA用地高辛标记作探针,对有丝分裂中期相染色体进行双色荧光原位杂交。每对染色体上均显示出了特定的C0t-1DNA荧光原位杂交带型,5对染色体上显示出了25SrDNA荧光原位杂交带型。双色荧光原位杂交证实了C0t-1DNA与25SrDNA二者具有一致的染色体位置特征,表明基于rDNA及C0t-1 DNA的荧光原位杂交核型分析技术,优于目前普遍采用的只基于rDNA的荧光原位杂交核型分析方法。结合C0t-1 DNA与25SrDNA的荧光原位杂交带型和传统的染色体的形态学标记分析方法及白菜已公布的基于rDNA分布的核型分析结果,创建了一个精确的白菜核型。     

The WW-HECT protein Smurf2 interacts with the Docking Protein NEDD9/HEF1 for Aurora A activation

Although the large majority of solid tumors show a combination of mitotic spindle defects and chromosomal instability, little is known about the mechanisms that govern the initial steps in tumorigenesis. The recent report of spindle-induced DNA damage provides evidence for a single mechanism responsible for the most prominent genetic defects in chromosomal instability. Spindle-induced DNA damage is brought about by uncorrected merotelic attachments, which cause kinetochore distortion, chromosome breakage at the centromere, and possible activation of DNA damage repair pathways. Although merotelic attachments are common early in mitosis, some escape detection by the kinetochore pathway. As a consequence, a proportion of merotelic attachments gives rise to chromosome breakage in normal cells and in carcinomas. An intrinsic chromosome segregation defect might thus form the basis of tumor initiation. We propose a hypothesis in which merotelic attachments and chromosome breakage establish a feedback loop that results in relaxation of the spindle checkpoint and suppression of anti-proliferative pathways, thereby promoting carcinogenesis.