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。     

野牡丹科6种植物染色体数目及核型分析

研究了野牡丹科国产野牡丹属(Melastoma L.)4种植物和从国外引种的蒂牡花属(Tibouchina Aubl.)2种植物的染色体数目,并对4种野牡丹属植物的核型进行分析。结果表明, 野牡丹属植物的染色体数目为2n=24,为二倍体植物,蒂牡花属的蒂牡花(T. urvillean)和银毛野牡丹(T. heteromall)的染色体数目为2n=36。核型公式为：野牡丹(M. malabathricum) 2n=10m(2SAT)+14sm;毛稔(M. sanguineurn) 2n=10m+12sm+2st;地稔(M. dodecandrum) 2n=12m+12sm;细叶野牡丹(M. intermedium) 2n=12m＋10sm+2st。核型分析表明国产野牡丹属植物染色体为小染色体,绝对长度为0.43~1.79 µm;核型不对称系数为59.47~62.91,均属2B型。野牡丹属植物的核型为首次报道。     

风毛菊属5种植物的核型分析

采用常规压片法,对风毛菊属(Saussurea)5种植物的染色体数目和核型类型进行分析。结果表明:大耳叶风毛菊(S.macrota)核型公式为2n=2x=26=10m+12sm+4st,属2A型;长梗风毛菊(S.dolichopoda)核型公式为2n=2x=26=14m+8sm+4st,属2A型;川陕风毛菊(S.licentiana)核型公式为2n=2x=28=12m+16sm,属2B型;杨叶风毛菊(S.populifolia)核型公式为2n=2x=28=6m+18sm+4st,属2B型;尾叶风毛菊(S.caudata)核型公式为2n=2x=30=14m+14sm+2st,属2A型。这5种风毛菊属植物中,除大耳叶风毛菊染色体数目和核型类型与前人报道的一致外,其余4种植物的染色体数目和核型类型均为首次报道,并在川陕风毛菊中发现1对B染色体。     

黄精属5种植物的核型研究

本文报道了安徽省黄精属Polygonatum Mill．5种植物的染色体数目和核型。玉竹P. odoratum (Mill.)Druce黄山材料2n=16=10m(3sc)+6sm,滁县琅琊山材料2n=18=10m(1sc) +2sm+6st(2sc),二者均属2B核型． 长梗黄精P．filipes Mirr. 黄山材料2n=22=8m+8sm(2sc)+6st,属3B核型,安徽繁昌材料2n=14=10m+4sm和2n=16=8m +4sm+4st,二者均属2B核型。多花黄精(P.cyrtonema Hua)安徽黄山材料2n=20=8m+6sm+6st和2n=22=6m+8sm +4st+4t,二者均属3B核型,安徽滁县琅琊山材料2n=18=8m(2sc)+6sm+4st,属2B核型。长苞黄精(P．desoulayi kom．) 2n=22=10m(2sc)+6sm(1sc)+6st,属3B核型;轮叶黄精(P．verticillatum(L．)All．)2n=18=2m+2sm+10st+2t+2T和2n=24=6m+4sm+12st+2T,二者均属3B核型。其中玉竹2n=16,长梗黄精2n=14和2n=22,长苞黄精2n=22,轮叶黄精2n=18的染色体数目和核型均为首次报道。     

青藏高原东南缘五种火绒草属植物的核型

报道我国青藏高原东南缘5种6个居群火绒草属植物的染色体数目和核型.银叶火绒草Leontopodium souliei 2n =2x=24=13M+8m+3sm,1B;坚秆火绒草L.franchetii 2n=2x=26=6M+ 18m +2sm,2A;华火绒草L.sinense;四川木里海拔2406m的居群:2n=2x=26=4M+22m,1B,四川木里海拔3074m居群:2n=4x=52=16M+36m,1B;美头火绒草L.calocephalum 2n=4x=48=3M+43m +2sn,1B;毛香火绒草L.stracheyi 2n=4x=48=13M+35m,1A.对现有的染色体资料分析表明:火绒草属的染色体核型比较对称,但种间具一定的变异;多倍化可能是该属在我国青藏高原及其周边地区发生强烈物种分化的重要原因之一.     

珍珠菜属三种植物的核型研究

对国产三种珍珠菜属 (Lysimachia)植物进行了核型研究 ,其中点腺过路黄 (LysimachiahemsleyanaMaxim .)染色体核型 2n =2 2 =2m +4sm +8st+8t,聚花过路黄 (L .congestifloraHesmsl.)核型 2n =2 4=2m +2sm +1 0st+1 0t及山萝过路黄 (L .melampyroidesR .Knuth)染色体数目 2n =2 2 ,核型 2n =2 2 =4m +6sm +4st+8t,为首次报道。本文还分析了黄连花亚属 (subgen.Lysimachia) 2组 8种植物的核型 ,结果表明黄连花组(sect.Lysimachia)核型类型 1A ,过路黄组 (sect.Nummularia)核型类型 3A或 3B。     

横断山及邻近地区八种菊科植物的染色体数目及核型

对横断山及邻近地区风毛菊属(Saussurea)、帚菊属(Pertya)和针苞菊属(Tricholepis)的8种菊科植物进行细胞学研究,其中异叶帚菊(Pertya berberidoides)(2n=2x=32=28m+4sm)、针苞菊(Trichole-pis furcata)(2n=2x=32=16m+ 16sm)、中甸风毛菊(Saussurea dschungdienensis)(2n=2x=30=30m+Bs)、丽江风毛菊(S.likiangensis)(2n 2x=32=26m+6sm)、倒齿风毛菊(S.retroserrata)(2n=2x=32=14m+18sm)和显梗风毛菊(S.peduncularis)(2n=2x=36=26m+ 10sm)为首次报道染色体数目和核型,长毛风毛菊(S.hieracioides)和三角叶风毛菊(S.deltoidea)的核型公式分别为:2n=4x=64=30m+34sm和2n=2x=34=22m+ 12sm,与前人报道的一致.8种植物中,除中甸风毛菊和异叶帚菊的核型不对称性为1B型外,其余6种的核型不对称性均属于2B型;在中甸风毛菊中首次发现B染色体.结合现有的细胞学资料分析表明,风毛菊属和帚菊木族的染色体数目存在变异,并且存在明显的非整倍性;此外,分布于横断山区的风毛菊属植物仪有两种倍性(二倍体和四倍体),而且多倍化并不占主导地位.     

桤木属7种植物的核型分析

利用改良去壁低渗法对分布于欧美地区的桦木科(Betulaceae)桤木属(Alnus Mill.)7种植物进行染色体数目与核型分析。结果显示:所有材料染色体形态比较一致,多为由中部(m)及近中部(sm)着丝点染色体组成。意大利桤木(A.cordata)为六倍体,体细胞染色体数为2n=6x=42,核型公式为2n=6x=42=36m+6sm;绿桤木(A.viridis)为八倍体,体细胞染色体数为2n=8x=56,核型公式为2n=8x=56=46m+10sm(SAT);薄叶桤木(A.tenuifolia)、灰桤木(A.incana)、欧洲桤木(A.glutinosa)、裂叶桤木(A.sinuata)和红桤木(A.rubra)均为四倍体,体细胞染色体数均为2n=4x=28,其核型公式分别为2n=4x=28=16m(1SAT)+12sm、2n=4x=28=22m+6sm、2n=4x=28=24m+4sm、2n=4x=28=24m+4sm、2n=4x=28=26m+2sm。其中红桤木(A.rubra)的核型属于1B型,其余均为2B型。     

兜兰亚属12种植物的核型分析

对兜兰亚属(Paphiopedilum subgenus Paphiopedilum)12种植物的染色体数目和核型进行了研究。结果表明：这12种植物的染色体数目和核型存在差异,其中菲律宾兜兰(P. philippinense)的核型公式为2n=2x=26=16m+10sm, 长瓣兜兰(P. dithanum)为2n=2x=26=20m+6sm, 密毛兜兰(P. densissimum)为2n=2x=26=22m+4sm, 飘带兜兰(P. parishii)和带叶兜兰(P. hirsutissimum)为2n=2x=26=24m+2sm, 亨利兜兰(P. henryanum)、虎斑兜兰(P. markianum)和根茎兜兰(P. rhizomatosum)为2n=2x=26=26m, 而胼胝兜兰(P. callosum)为2n=2x=32=2M+24m+6sm, 布玲兜兰(P. microchilum)为2n=2x=38=28m+10sm, 卷萼兜兰(P. appletonianum)和海南兜兰(P. hainanensis)为2n=2x=38=30m+8sm。兜兰亚属的染色体主要为中部着丝粒染色体, 未见随体;最长染色体与最短染色体之比为2.07~3.44, 臂比大于2的染色体比率为0~0.231,核不对称系数为53.50%~58.95%。长瓣兜兰、飘带兜兰、亨利兜兰、密毛兜兰、虎斑兜兰、带叶兜兰和根茎兜兰等6种的核型类型为1B型,其余6种为2B型。     

三种紫金牛属植物的核型研究

对紫金牛属三种植物进行了核型分析,其中朱砂根染色体数目2n=46、核型2n=46=42m+2sm+2st和紫金牛核型2n=92=58m+24sm+10st为首次报道;虎舌红核型公式为2n=44=40m+2sm+2st。核型分析结果显示,紫金牛属植物存在染色体数目非整倍体变异及多倍化的进化方式。     

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。     

角堇与大花三色堇染色体核型分析

以2份角堇与4份大花三色堇自交系为试验材料,采用染色体常规压片方法,观察和分析了它们的细胞染色体数目、相对长度、平均臂比等核型指标,以明确两种植物细胞学特点,为分类以及育种提供理论依据。结果表明:(1)2份角堇自交系染色体数目均为2n=2x=26,染色体基数为x=13,染色体核型公式分别为2n=2x=26=8m+12sm+6st、2n=2x=26=4m+16sm+6st,核型不对称系数为67.20%~70.10%,核型分类均属于3B。(2)4份大花三色堇自交系均为四倍体,其中2份(EYO-1-2-1-4、DSRFY-1-1-2)染色体数目为44,核型公式为2n=4x=44=4m+16sm+6st、2n=4x=44=16m+24sm+4st;2份(G10-1-3-1-4、XXL-YB-1-1-1-1)染色体数目为48,核型公式分别为2n=4x=48=8m+20sm+20st、2n=4x=48=4m+36sm+8st,核型不对称系数为66.74%~71.77%,核型分类属于2B、3B。     

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. __________ Translated from Acta Botanica Yunnanica, 2005, 27(3): 261–268 [译自: 云南植物研究, 2005, 27(3): 261–268]     

不同地域乌拉尔甘草基因组的FISH分析与染色体识别

在核型分析与染色体识别基础上,分别以番茄45S和5S rDNA为探针,对3种不同地域的乌拉尔甘草进行FISH分析.结果表明:内蒙古鄂托克前旗的乌拉尔甘草核型公式为2n=2x=16=6m+10sm (2SAT),新疆阿勒泰地区的乌拉尔甘草核型公式为2n=2x=16=4m+12sm(2SAT),内蒙古喀喇沁旗乌拉尔甘草核型公式为2n=2x=16=4m+12sm(2SAT);其第8染色体均带有随体.3种乌拉尔甘草基因组内均有1对5S rDNA和1对45S rDNA杂交位点.核型分析显示,5S rDNA杂交位点均位于第2染色体的短臂部位,45S rDNA杂交位点均位于第8染色体的次缢痕和随体部位.45S与5S rDNA在3种乌拉尔甘草中期分裂相上的位点数和分布情况高度一致,表明来自3种不同地域的乌拉尔甘草在染色体结构水平上没有较大的分化.     

风毛菊属6种植物的核型分析

采用常规压片技术对分布于横断山区菊科(Compositae)风毛菊属(Saussurea DC.)的6种植物进行染色体数目和核型分析。结果表明:尖苞雪莲（S.polycolea var.acutisquama）核型公式为:2n=2x=32=20m+12sm,属2B型;球花雪莲核（S.globosa）型公式为:2n=2x=34=16m+18sm,属2B型;重齿风毛菊(S.katochaete)核型公式为:2n=2x=32=8m+18sm+6st,属3B型;柱茎风毛菊(S.columnaris)核型公式为:2n=2x=32=24m+8sm,属2B型;禾叶风毛菊(S.graminea)核型公式为:2n=2x=28=8m+18sm+2st,属3B型;长毛风毛菊(S.hieracioides)核型公式为:2n=2x=32=12m+16sm+4st,属2B型。6个种染色体中均未发现随体。其中尖苞雪莲和柱茎风毛菊染色体为首次报道。     

Comparative karyomorphology and interrelationships ofSelaginella in Japan

Karyomorphological comparisons were made of 16 native and cultivated species ofSelaginella in Japan. The somatic chromosome numbers are 2n=16 inS. boninensis; 2n=18 inS. doederleinii, S. helvetica, S. limbata, S. lutchuensis, S. nipponica, S. selaginoides, S. tama-montana, andS. uncinata; 2n=20 inS. biformis, S. involvens, S. moellendorffii, S. remotifolia, andS. tamariscina; 2n=30 inS. rossii; and 2n=32 inS. heterostachys. The interphase nuclei of all species examined are uniformly assigned to the simple chromocenter type. The metaphase karyotype of 2n=16 (x=8) is 8 m (=median centromeric chromosomes)+8(st+t)(=subterminal and terminal). The group of the species having 2n=18 (x=9) is heterogeneous karyomorphologically: The karyotype ofS. nipponica is 2n=18=6 m+12(st+t),S. tama-montana 10 m+2 sm(=submedian)+6(st+t), andS. uncinata 6 m+7 sm+5(st+t). Although the remaining five species have the common karyotype 8 m+4 sm+6(st+t), the values of mean chromosome length are variable. Another group of the specles having 2n=20 (x=10) is homogeneous, since all species have the same karyotypes 8 m+4 sm+8(st+t) and have similar chromosome size. The karyotype of 2n=30 is 12 m+6 sm+12(st+t) and is suggested to be a triploid of x=10, and 2n=32=16m+16(st+t), a tetraploid of x=8. Thus, three kinds of basic chromosome numbers, x=8, 9, 10 are present in JapaneseSelaginella examined, and their karyomorphological relationships are discussed.     

Viola tricolor (Violaceae) is a karyologically unstable species

Viola tricolor is a pseudometallophyte covering heavy-metal-polluted and non-polluted areas. The species is a member of the evolutionarily young sect. Melanium of Viola. In this study, we sought to determine whether the karyotype of V. tricolor is stable with respect to chromosome structure or is altered depending on environmental conditions (heavy-metal-polluted vs. non-polluted areas). We established the karyotypes of plant material originating from a Zakopane meadow (non-metallicolous population) and from the Bukowno mine waste heap (metallicolous population), showing evident interpopulation differentiation in chromosome type (2M+20 m+2sm+2st vs. 18 m+8sm), in the number, size, and distribution of rDNA loci (25S and 5S), and also in chromosome mutations, mainly fission of chromosomes into acentric fragments and translocation of the fragments. Variable numbers of both 25S and 5S rDNA loci were distributed at different positions of the chromosomes and not on specific pairs of chromosomes. The results clearly indicate that the karyotype of V. tricolor results from the unstable genetic structure of the species. This character, typical for relatively young evolutionary groups, proves its membership to the Melanium section considered to be young within the genus Viola.     

Physical mapping of 5S and 45S rDNA loci in pufferfishes (Tetraodontiformes)

Chromosomal features, location and variation of the major and minor rDNA genes cluster were studied in three pufferfish species: Sphoeroides greeleyi and Sphoeroides testudineus (Tetraodontidae) and Cyclichthys spinosus (Diodontidae). The location of the major rDNA was revealed with an 18S probe in two loci for all species. The minor rDNA loci (5S rDNA) was found in one chromosome pair in tetraodontid fishes and four sites located on two distinct chromosomal pairs in C. spinosus. A syntenical organization was not observed among the ribosomal genes. Signal homogeneity for GC/AT-DNA specific fluorochromes was observed in diodontid fish except in the NORs regions, which were CMA₃-positive. Giemsa karyotypes of tetraodontid species presents 2n = 46, having the same diploid value of other Sphoeroides species that have been investigated. On the other hand, the karyotype of C. spinosus, described for the first time, shows 2n = 50 chromosomes (4m + 18sm + 12st + 16a). The foreknowledge of the karyotypic structure of this group and also the physical mapping of certain genes could be very helpful for further DNA sequence analysis.