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。     

花生45S rDNA和5S rDNA的染色体定位研究

对四粒红和蜀花四号花生材料进行了核型分析,四粒红为2B核型,核型公式为2n=4x=40=38m＋2sm（4SAT）;蜀花四号为1B核型,核型公式为2n=4x=40=40 m（2SAT）。利用双色荧光原位杂交技术,对45S rDNA和5S rDNA这两个材料有丝分裂中期染色体上的物理位置进行了定位分析。定位结果表明,四粒红有6对45S rDNA位点,位于A2L、A7S、A9L、B3L、B7S、B8L（A和B分别代表基因组A和基因组B,L和S代表长臂和短臂,数字代表染色体序号,下同）;2对5S rDNA位点,位于A3S和B3S;蜀花四号有5对45S rDNA位点,位于A2L、A9L、B3L、B7S、B9L;2对5S rDNA位点,位于A3S和B3S。花生的45S rDNA位点具有可变性,5S rDNA则相对保守。     

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。     

普通小麦-簇毛麦6V代换系45S rDNA和5S rDNA位点的FISH分析

采用顺序基因组原位杂交和双色荧光原位杂交技术,对普通小麦-簇毛麦6v代换系K0736的45S rDNA和5S rDNA基因位点进行了分析.结果表明,该代换系2n=42,有1对簇毛麦6V染色体,为6V/6A代换系,45S rDNA位点有8对,位于7对染色体上.5S rDNA位点有6对,分别位于6对染色体上.在1AS、1BS、5DS的端部同时存在458 rDNA和5S rDNA位点,并在物理位置上紧密相邻.同时讨论了rDNA位点的数目和分布位置存在变异的可能因素.     

中国17种蔷薇属植物45S和5S的rDNA分布研究

为了探寻蔷薇属植物亲缘关系及系统发育研究的分子细胞遗传学证据,该研究采用双色FISH(荧光原位杂交)技术,对原产中国7个组的17种蔷薇属植物的45S和5S rDNA进行了定位分析。结果表明:(1)多数蔷薇属植物1组染色体对应1个45S rDNA位点和1个或2个5S rDNA位点,偶尔出现1~2个rDNA位点的丢失,但复伞房蔷薇(Rosa brunonii)的1组染色体对应了2个45S rDNA位点。(2)二倍体的蔷薇属植物至少有1对5S rDNA位点与45S rDNA位点共定位,而四倍体材料的5S rDNA位点与45S rDNA位点没有共定位,但所有四倍体材料均至少有1种rDNA信号纯合,表明它们应为二倍体直接加倍产生的同源四倍体。(3)绝大多数材料45S rDNA位于染色体短臂、5S rDNA位于染色体长臂,但缫丝花(R. roxburghii f. roxburghii)有1个5S rDNA信号位于染色体的短臂上,表明它与蔷薇属其他种的亲缘关系较远。(4)阿克苏地区和伊犁地区的疏花蔷薇的核型不同,且45S和5S rDNA的数量和位置不同,分子细胞遗传学证据也支持阿克苏地区的疏花蔷薇应为疏花蔷薇的新变种。(5)该研究中共有8个二倍体和6个四倍体蔷薇属植物的双色FISH为首次报道。研究认为,无论二倍体还是四倍体蔷薇属植物中出现的异形同源染色体、rDNA信号位置在同源染色体上的差异以及rDNA信号的增加和丢失,可能都与染色体结构变异和染色体重组有关,在分子细胞遗传学水平上证明染色体结构变异和染色体重组在蔷薇属植物演化过程中具有重要的作用。     

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。     

薏苡45S和5S rDNA的染色体定位研究(简报)

通过荧光原位杂交的方法确定了45S和5S正NA序列在薏苡前中期染色体上的位置.尽管具有20条染色体的薏苡是四倍体植物,但它的基因组中只有一个45S和5S rDNA位点.根据薏苡前中期染色体的核型,确定45S rDNA序列位于薏苡第2号染色体短臂上的次级缢痕区和随体上,5S rDNA序列位于第7号染色体长臂靠近着丝粒处,5S rDNA位点到着丝粒的百分距离是29.13±1.76.     

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。     

45S rDNA在小麦及其近缘物种染色体上的分布

将染色体C-分带和原位杂交技术相结合,系统研究了45S rDNA在栽培一粒小麦、野生二粒小麦、普通小麦、大麦、簇毛麦、硬簇麦、六倍体燕麦及鹅观草等物种染色体上的分布情况。这些物种染色体的次缢痕区都有45S rDNA位点, 某些非随体染色体上也有45S rDNA位点分布。以小麦—鹅观草1Rk^#1二体附加系为材料,通过顺序C分带-FISH技术首次将一个45S rDNA定位到1Rk^#1染色体短臂末端。     

25S rDNA在杨属植物染色体上的定位

利用荧光原位杂交技术对杨属(Populus)植物五个组中二倍体(2n=2x=38)代表种:毛白杨(P.tomentosa)、箭杆杨(P.nigravar.thevestina)、大叶杨(P.lasiocarpa)、小青杨(P.pseudo-simonii)、胡杨(P.euphratica);以及所发现的白杨组和黑杨组天然三倍体(2n=3x=57):毛白杨(P.tomentosa)、武黑1号(P.euramericana cv.Wuhei-1)进行了25S rDNA的染色体定位。二倍体毛白杨、箭杆杨、小青杨和大叶杨都具有4个25S rDNA位点,而胡杨只有2个较大的25S rDNA定位于1对小的染色体上,白杨和黑杨天然三倍体的两个种各有6个25S rDNA位点。同时作者还将杨属植物25S rDNA的分布变化与常规核型分析结果进行了比较。     

Variability of the 5S and 45S rDNA sites in Passiflora L. species with distinct base chromosome numbers

Cytologically, the species of Passiflora with known chromosome number can be divided into four groups: (1) 2n = 12, 24, 36; (2) 2n = 24; (3) 2n = 18, 72; and (4) 2n = 20. The base chromosome number proposed for the genus is x = 6, with x = 9, x = 10 and x = 12 being considered secondary base numbers. In the present study, variability of 5S and 45S rDNA sites was investigated in 20 species of these four groups to check the reliability of this hypothesis. In the group with x = 6, five diploid species (2n = 12) exhibit two 5S rDNA sites and two (P. capsularis, P. morifolia and P. rubra) or four (P. misera 2x and P. tricuspis) 45S rDNA sites. The hexaploid cytotype of P. misera had 12 45S rDNA sites and six 5S rDNA. A tetraploid species, P. suberosa, had ten 45S rDNA sites and four 5S rDNA sites, both in the same chromosomes as the 45S rDNA sites. In the group with x = 9, P. actinia, P. amethystina, P. edmundoi, P. elegans, P. galbana, P. glandulosa and P. mucronata displayed six 45S rDNA sites, whereas P. alata, P. cincinnata, P. edulis f. flavicarpa, P. edulis var. roxo and P. laurifolia had four sites. In this group, all species were diploid (2n = 18) and had only two 5S rDNA sites. Passiflora foetida, the only species with 2n = 20, had six 45S rDNA sites and four 5S rDNA sites. The species with x = 12 (2n = 24), P. haematostigma and P. pentagona, showed four 45S rDNA sites and two 5S rDNA. In general, the number and location of 5S and 45S rDNA sites were consistent with the hypothesis of x = 6 as the probable ancestral genome for the genus, while the groups of species with x = 9, x = 10 and x = 12 were considered to be of tetraploid origin with descending dysploidy and gene silencing of some redundant gene sites, mainly those of 5S rDNA.     

Karyotype analysis and physical mapping of 45S rDNA in eight species of Sophora,Robinia, and Amorpha

The karyotype analysis and physical locations of 45S rDNA were carried out by means of fluorescence in situ hybridization in three species,and two forms of Sophora,two species of Robina,and one species of Amorpha.S.japonica L.,S.japonica L.f.oligophylla Franch.,S.japonica L.f.pendula Loud.,and S.xanthantha C.Y.Ma.are all tetraploids with 2n=28.There were four 45S rDNA sites in pericentromeric regions of two Pairs of chromosomes in each of them.S.rubriflora Tsoong.is a triploid with 2n=21,and three sites were located in each satellite of group 5 chromosomes.In R.pseudoacacia L.(2n=2x=22),we examined four intensive signals in telomeric regions of two pairs of satellite chromosomes.In R.hispida L.(2n=2x=30),there were four other signals in centromeric regions besides those like in R.pseudoacacia.Amorpha fruticosa L.has most chromosomes(2n=40)among the eight materials,however,there were only six 45S rDNA loci and they laid in centromeric regions,and satellites of three pairs of chromosomes.45S rDNA is a valuable chromosomal landmark in karyotype analysis.The distribution and genomic organization Of rDNA in the three genera were also discussed.     

Genetic diversity of Triticum turgidum L. based on microsatellite markers

Using microsatellite (SSR) markers, the genetic diversity and genetic relationships among 48 Triticum turgidum L. accessions, including 30 Triticum turgidum L. ssp. turgidum, 7 Triticum turgidum L. ssp. durum, 4 Triticum turgidum L. ssp. carthlicum, 3 Triticum turgidum L. ssp. paleocolchicum, 2 Triticum turgidum L. ssp. turanicum and 2 Triticum turgidum L. ssp. polonicum accessions, were investigated. A total of 97 alleles were detected on 16 SSR loci. At each locus, the number of alleles ranged from 2 to 14, with an average of 6.1. The Genetic similarity (GS) value ranged from 0.20 to 0.92, with the mean of 0.59. In cluster analysis, it was found the 48 Triticum turgidum L. accessions could be distinguished easily by SSR markers, whereas the 6 subspecies taxonomic entities of T. turgidum L. could not differentiate with each other, indicating that the morphological differences present among the 6 subspecies could not be reflected by the SSR markers. These results suggested that SSR markers had the superiority in detecting the genetic diversity of T. turgidum L., while it was not good for the studies of the phylogenic relationships among the subspecies of T. turgidum L.     

豆科三属八种植物的核型及rDNA定位研究

对豆科槐属的国槐(SophorajaponicaL.)、五叶槐(S.japonicaL.f.oligophyllaFranch.)、龙爪槐(S.japonicaL.f·pendulaLoud.)、黄金槐(S.xanthanthaC.Y.Ma.)(以上均为四倍体,2n=4x=28)、红花槐(S.rubrifloraTsoong.,2n=3x=21),刺槐属的刺槐(Robiniapseudoa-caciaL.,2n=2x=22)、毛洋槐(R.hispidaL.,2n=2x=30)和紫穗槐属的紫穗槐(AmorphafruticosaL.,2n=2x=40)核型进行了分析,并应用荧光原位杂交技术进行了45SrDNA的染色体定位。槐属4个四倍体种各具4个45SrDNA位点,位于两对染色体的着丝粒周围;红花槐,3个45SrDNA位点位于第5组染色体随体区域。刺槐,4个rDNA位点位于两对随体染色体端部;毛洋槐,8个rDNA位点,4个位于两对染色体的随体及次缢痕,另4个位于两对染色体着丝粒周围。紫穗槐,6个45SrDNA位点,分别位于3对染色体的着丝粒和随体。本文对rDNA作为染色体标记在核型分析中的应用及在基因组中的分布特点进行了讨论。     

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。     

Contrasting rDNA evolution in lima bean (Phaseolus lunatus L.) and common bean (P. vulgaris L., Fabaceae)

Phaseolus vulgaris has two 5S rDNA sites in chromosomes 6 and 10 and from two up to nine 45S rDNA sites depending on the accession. The presence of three 45S rDNA sites, in chromosomes 6, 9 and 10, is considered the ancestral state for the species. For P. lunatus, only one 5S and one 45S rDNA sites in distinct chromosomes were known. In order to investigate the homeologies among these rDNA-bearing chromosomes and the stability of the rDNA sites in P. lunatus, rDNA and P. vulgaris chromosome-specific probes were hybridized in situ to P. lunatus. The chromosomes bearing the 5S and the 45S rDNA of P. lunatus are homeologous to chromosomes 10 and 6 of P. vulgaris, respectively. In contrast to the common bean, no variation in the number of rDNA loci was detected, except for a duplication of the 5S rDNA in the same chromosome in a small group of cultivars. These results suggest that the 5S rDNA site in chromosome 10 and the 45S rDNA site in chromosome 6 represent the ancestral loci in the genus. The 5S rDNA site in chromosome 10 of P. vulgaris is located in the long arm, while in P. lunatus it is present in the short arm, suggesting the occurrence of a transposition or a pericentric inversion after separation of both lineages.     

Ribosomal RNA genes in soybean and common bean: chromosomal organization, expression, and evolution

Ribosomal RNA (5S and 45S) genes were investigated by FISH in two related legumes: soybean [Glycine max (L.) Merr.] and common bean (Phaseolis vulgaris L.). These species are both members of the same tribe (Phaseoleae), but common bean is diploid while soybean is a tetraploid which has undergone diploidization. In contrast to ploidy expectations, soybean had only one 5S and one 45S rDNA locus whereas common bean had more than two 5S rDNA loci and two 45S rDNA loci. Double hybridization experiments with differentially labelled probes indicated that the soybean 45S and 5S rDNA loci are located on different chromosomes and in their distal regions. Likewise, the common bean 45S and 5S rDNA loci were on unique chromosomes, though two of the 5S rDNA loci were on the same chromosome. FISH analysis of interphase nuclei revealed the spatial arrangement of rDNA loci and suggested expression patterns. In both species, we observed one or more 5S rDNA hybridization sites and two 45S rDNA hybridization sites associated with the nucleolar periphery. The 45S rDNA hybridization patterns frequently exhibited gene puffs as de-condensed chromatin strings within the nucleoli. The other condensed rDNA sites (both 5S and 45S) were spatially distant from the nucleolus in nucleoplasmic regions containing heterochromatin. The distribution of rDNA between the nucleoplasm and the nucleoli is consistent with differential gene expression between homologous alleles and among homoeologous loci.