大鹅观草与阿拉善鹅观草杂种的形态学和细胞学研究

为探讨阿拉善鹅观草 ( R.alashanica( Keng) S.L.Chen)的染色体组组成 ,进行了大鹅观草 ( R.grandisKeng( 2 n=2 4 ,St St YY) )和阿拉善鹅观草种间杂交 ,对这两个种及其杂种 F1的形态学、繁育学和减数分裂染色体配对行为进行了研究。结果表明 :杂种 F1的形态特征介于父母本之间 ,其花粉母细胞减数分裂染色体平均构型为 :2 0 .4 0 +3.6 9 +0 .0 9 +0 .0 4 。表明阿拉善鹅观草含有一个修饰的 St基因组 ,即 Sta。     

鹅观草属5种植物的核型研究

本文首次对我国5种鹅观草属Roegneria植物的核型进行了分析。5个种的染色体数目均为2n=4x=28。它们的核型是:高株鹅观草 R.altissima,2n=4x=28=26m+2sm(SAT);假花鳞草 R.anthosachnoides,2n=4x=28=22m+4sm+2sm(SAT);长芒鹅观草 R.dolichathera,2 n=4x=28=20m+6sm+2sm(SAT);林地鹅观草 R.sylva-tica,2n=4x=28=22m+4sm+2sm(SAT);多变鹅观草R.varia,2n=4x=28=20m+6sm+2sm(SAT)。它们的核型均属2A型,每种植物均有一对随体染色体。     

鹅观草属4个种核型与进化的研究

报道了鹅观草属(Roegneria C. Koch)4个种的核型,即中华鹅观草,核型为2n=4x=28=28m(2SAT);裸穗鹅观草,核型为2n=4x=28=24m+4sm(2SAT);缘毛鹅观草,核型为2n=4x=28=22m+6sm(2SAT);缘穗鹅观草,核型为2n=4x=28=24m(2SAT)+4sm。4个种核型的共征和自征反映了形态划分中共属分种的合理性。尤其通过核型不对称性和相对进化程度的分析,表明中华鹅观草最原始,缘穗鹅观草最进化,裸穗鹅观草和缘毛鹅观草演化居中;狭颖草系高级于缘毛草系。核型不对称性所表示的进化程度似乎与系间颖芒的发生,种间花序的增长变粗、外稃芒的延伸相关。     

鹅观草和簇毛麦属间杂种的形态学和细胞遗传学研究

通过幼胚离体拯救培养,成功地获得鹅观草Roegneria kamoji Ohwi(2n=6x=42,StStHHYY)和 簇毛麦Dasypyrum villosum(L．)Candargy(2n=2x=14,VV)属间杂种,对这两个种及其杂种F_l的形 态学、繁育学和减数分裂配对行为进行了研究。结果表明：(1)鹅观草和簇毛麦形态差异极大,杂种F1 的形态特征介于父母本之间;(2)杂交结实率低,为11．63％;经幼胚组织培养,获2株杂种苗;杂种F_l高 度不育,表明亲本间存在极强的生殖隔离,是独立的生物学种;(3)杂种F_l体细胞染色体数目为稳定的 28条,减数分裂中期I染色体配对很低,其构型为：26．72Ⅰ+0．62Ⅱ+0．02Ⅲ。表明鹅观草的St、H、Y染色体组与簇毛麦的V染色体组部分同源性很低,它们的亲缘关系较远。     

大鹅观草与蛇河披碱草属间杂种的细胞遗传学研究

为探讨大鹅观草(Roegneria grandis,2n=4x=28)的染色体组组成,为其正确的分类处理提供细胞学依据。该研究通过人工远缘杂交,成功获得3株大鹅观草与蛇河披碱草(Elymus wawawaiensis,2n=4x=28)属间杂种F1植株。杂种植株形态介于两亲本之间,不育。亲本及杂种经I2-IK溶液染色后进行花粉育性检测,结果显示Roegneria grandis和Elymus wawawaiensis的花粉可育,育性高达94.6%和90.5%;杂种F1不育。花粉母细胞减数分裂中期I染色体配对结果显示,亲本花粉母细胞配对正常,均形成14个二价体,以环状二价体为主,Roegneria grandis有频率很低(0.04/细胞)的单价体出现;杂种F1平均每个花粉母细胞形成6.46个二价体,变化范围为5~8;在观察的83个花粉母细胞中,有35.2%的花粉母细胞形成了7个二价体,形成6个二价体的细胞占42.59%,较少细胞形成8个二价体;平均每个细胞形成14.66个单价体,变化范围为10~18;平均每细胞观察到0.14个三价体;杂种花粉母细胞染色体构型为14.66 I+6.46 II+0.14 III;平均每细胞交叉数为9.83,C值为0.35。结果表明:(1)R.grandis与Elymus wawawaiensis有一组染色体组同源的St染色体组,另外一组染色体组不是St或者H染色体组,Roegneria grandis的染色体组组成不是St Stg;(2)较低频率的三价体(平均0.14个/细胞),可能是由于R.grandis的St和Y染色体组间具有一定的同源性,也可能是染色体易位等原因导致,对于Y染色体组的起源还需深入地研究;(3)在不同地理来源的披碱草属和鹅观草属物种中St染色体组同源性不同,R.grandis与来自于北美的Elymus lanceolatus与E.wawawaiensis的St染色体组较与分布于亚洲的E.sibiricus和E.caninus的St染色体组同源性反而更高,其原因还需要进一步地研究。     

鹅观草属4个种的核型与进化

报道了4个种鹅观草属（Roegneria C. Koch）植物的核型,其核型公式如下：芒颖鹅观草(R. aristiglumis Keng et S. L. Chen), 2n=4x=28=22m+6sm（2SAT）;短颖鹅观草(R. breviglumis Keng), 2n=4x=28=20m（2SAT）+8sm;红原鹅观草(R. hongyuanensis L. B. Cai), 2n=4x=28=22m+6sm（2SAT）;山东鹅观草(R. shandongensis（B. Salomon）J. L. Yang, Y. H. Zhou et Yen), 2n=4x=28=24m（2SAT）+4sm。同时对染色体主要特征的演变规律进行了分析,揭示了鹅观草属4个种的相对进化程度以及宏观分类中2个组的系统发育关系,表明鹅观草属的半颖组在系统发育中派生了颖体短小的小颖组。     

纤毛鹅观草与本田鹅观草的生物系统学研究

本文通过对鹅观草属的两个种:本田鹅观草(Roegneria hondai Kitagawa)和纤毛鹅观草(R.ciliaris(Trin)Nevski)及其种间杂种的形态变异、染色体配对行为和同工酶电泳酶谱的分析,研究了这两个种间的亲缘关系,杂种F_1减数分裂染色体配对数很高,F_1自然条件下具有低的结实率。R.ciliaris根部和幼叶的酯酶、过氧化物酯同工酶谱与R.hondai的酶谱间存在差异。上述结果表明,R.ciliaris和R.hondai亲缘关系很近,享有两个共同的基本染色体组,可拟定R.hondai的染色体组为S~hy~h。R.ciliaris同R.hondai间的亲缘关系较R.ciliaris同R.pendulina和R.pendulina同R.hondai间更近。     

纤毛鹅观草同阿拉善鹅观草、大丛鹅观草间杂种细胞学研究

为了探索阿拉善鹅观草RoegneriaalashanicaKeng、大丛鹅观草RoegneriamagnicaespesD .F .Cui与纤毛鹅观草Roegneriaciliaris (Trin .)Nevski间的相互关系 ,将其进行了远缘杂交 ,通过幼胚离体培养 ,两个组合均成功合成了杂种。对亲本及杂种F1 花粉母细胞减数分裂中期Ⅰ染色体配对行为及形态学进行了统计分析。结果表明 ,上述物种的种间杂交较难进行 ,杂种F1 减数分裂染色体平均构型分别为 :R ciliaris×R alashanica 10 6 2Ⅰ 8 17Ⅱ 0 32Ⅲ 0 0 2Ⅳ (c -值 =0 4 4 ) ,R ciliaris×R magnicaespes 18 0 0Ⅰ 4 76Ⅱ 0 16Ⅲ (c -值 =0 2 1) ;杂种穗部特征多数介于双亲之间。阿拉善鹅观草、大丛鹅观草与纤毛鹅观草间至少有一个基因组具有较高的同源性 ,即为S基因组 ,本文对它们在分类中的地位也进行了讨论。     

鹅观草属三个种的形态变异与核型的研究

本文通过对鹅观草属的三个种:鹅观草(Roegneria kamoji Ohwi)、纤毛鹅观草(R. ciliars (Trin.) Nevski)和竖立鹅观草(R. japonensis(Honda)Keng)的形态学比较和核型分析研究了该三个种的系统关系。R. kamoji与R. ciliaris、R. japonensis形态上的差异明显,而后二个种差异甚小,难以进行划分。R. kamoji的核型公式为:2n=6x=42=30m+8sm+4SAT;R. ciliaris为:2n=4x=28=18m+6sm+4SAT;R. japonensis为:2n=4x=28=18m+6sm+4SAT。t-测验的结果表明R. ciliaris与R. japonensis的核型无显著差异。因此笔者认为R. ciliaris和R. japonensis应合并为一种系内的分类群。     

普通小麦与鹅观草属间杂种F1及BC1的分子细胞遗传学、育性和赤霉病抗性研究

通过胚拯救, 成功获得鹅观草Roegneria kamoji (2n=6x=42, SSHHYY)和普通小麦中国春Triticum aesti-vum (2n=6x=42, AABBDD)的正反交属间杂种F1, 并对这些杂种F1及其BC1的形态学、减数分裂配对行为、育性和赤霉病抗性进行研究。结果表明, (鹅观草×中国春)F1和(中国春×鹅观草)F1的形态介于双亲之间。杂种F1花粉母细胞减数分裂中期I染色体构型分别为40.33I + 0.78II + 0.03III和40.40I + 0.79II 。杂种F1高度雄性不育, 用中国春花粉与其回交可获得BC1代种子。(鹅观草×中国春) F1×中国春BC1植株的染色体数目主要分布在55~63之间, 单价体较多, 植株高度不育; (中国春×鹅观草)F1×中国春BC₁植株染色体数目也主要分布在55~63之间, 但其中部分植株拥有整套小麦染色体且能正常配对、分离, 可形成部分可育花粉粒, 能收到少量自交结实种子。在 (鹅观草×中国春)F1中有1株穗型趋向中国春, 其染色体数目为2n=63, 经染色体分子原位杂交(GISH)检测, 含有42条小麦染色体和21条鹅观草染色体。该杂种F1在减数分裂中期I平均每个花粉母细胞有26.40I+18.30II, 但植株高度雄性不育, 用中国春花粉回交能收到BC₁种子。(鹅观草×中国春) F₁ (2n=63)×中国春BC₁的染色体数目主要分布在40~59之间, 其中的外源染色体已经逐渐减少, 虽然该BC₁的穗型已接近中国春, 但仍然高度不育。赤霉病抗性鉴定结果显示, 所有杂种F1及大部分BC₁对赤霉病均表现出较好的抗性。     

Genomic constitutions of four Chinese endemic Elymus species: E. brevipes, E. yangii, E. anthosachnoides, and E. altissimus (Triticeae, Poaceae).

The objectives of this study were to determine the genomic constitution and to explore the genomic variation within four Chinese endemic Elymus species, i.e., E. brevipes (Keng) L?ve (2n = 4x = 28) and E. yangii B.R. Lu (2n = 4x = 28), E. anthosachnoides (Keng) L?ve (2n = 4x = 28), and E. altissimus (Keng) L?ve (2n = 4x = 28). Intraspecific crosses between different populations of the four Elymus species, as well as interspecific hybridizations among the four target species, and with six analyzer species containing well-known genomes, i.e., E. caninus (L.) L. (2n = 4x = 28, SH), E. sibiricus L. (2n = 4x = 28, SH), E. semicostatus (Lees ex Steud.) Melderis (2n = 4x = 28, SY), E. parviglumis (Keng) L?ve (2n = 4x = 28, SY), E. tsukushiensis Honda (2n = 6x = 42, SHY), and E. himalayanus (Nevski) Tzvelev (2n = 6x = 42, SHY), were achieved through the aid of embryo rescue. Chromosome pairing behaviors were studied in the parental species and their hybrids. Numerical analysis on chromosome pairing was made on the interspecific hybrids. With one exception, each meiotic configuration at metaphase I in the hybrids involving the target taxa and the analyzer species containing the "SH" genomes fit a 2:1:1 model with x-values ranging between 0.91 and 1.00; chromosome pairing in the hybrids involving analyzer parents with the "SY" genomes match a 2:2 model, with x-values between 0.97 and 0.99. All pentaploid hybrids with a genomic formula "SSYYH," except for two crosses having unexpected low c-values, had pairing patterns fitting the 2:2:1 model with x-values varying between 0.96 and 1.00. It is concluded based on hybridization, fertility, and chromosome pairing data that (i) the four target Elymus species are strictly allotetraploid taxa, (ii) they are closely related species, all comprised of the "SY" genomes, (iii) minor genomic structural rearrangements have occurred within the four Elymus species, and (iv) meiotic pairing regulator(s) exists in some of the Elymus taxa studied.     

鹅观草属——人工合成双二倍体(2n=10x=70)的细胞学及育性的研究

本文对缘毛鹅观草(Roegneria pendulina)、鹅观草(R.tsukushiensis var.transiens)及其人工合成杂种F_1、双二倍体进行了细胞学,育性等的分析和研究。结果表明双亲的减数分裂,花粉育性和结实性均正常,杂种F_1的减数分裂不规则且完全不育;当代双二倍体的染色体数目为70,其减数分裂构型为:6.04 Ⅰ+26.21 Ⅱ+1.52 Ⅲ+1.59 Ⅳ+0.02 Ⅴ:第二代双二倍体的染色体数目为70,个别植株为69,减数分裂构型分别为:4.16 Ⅰ+27.33 Ⅱ+0.50 Ⅲ+2.16 Ⅳ和4.79 Ⅰ26.26 Ⅱ+1.13 Ⅲ+2.13 Ⅳ。与期望染色体配对模式相比,双二倍体中二价体出现的频率有明显增大的趋势。在减数分裂AⅠ和AⅡ分别观察到数目不定的落后单价体,大部份的四分体中出现了微核。双二倍体的育性得到了很大程度的恢复,其花粉可染色性及结实率分别为54.4％和64.0％。     

Genome analysis of Elytrigia caespitosa, Lophopyrum nodosum, Pseudoroegneria geniculata ssp. scythica, and Thinopyrum intermedium (Triticeae: Gramineae).

To elucidate the genome constitutions of the tetraploid (2n = 4x = 28) species Elytrigia caespitosa, Lophopyrum nodosum, and Pseudoroegneria geniculata ssp. scythica and the hexaploid (2n = 6x = 42) Thinopyrum intermedium, meiotic pairing was studied in these species as well as 10 hybrids. Karyotype analysis with aceto-orcein stained root-tip cells was performed for the four species and the hybrids of T. bessarabicum with E. caespitosa, P. geniculata ssp. scythica, and T. intermedium. Karyotype analysis by Giemsa C-banding was carried out with the three tetraploid species and the two triploid hybrids involving T. bessarabicum. The species behaved as strict allopolyploids. All hybrids were male sterile with few stainable pollen grains. It is concluded from the results that the three tetraploid species have the genome formula JeJeSS and T. intermedium has the formula JeJeJeJeSS. The chromosomes of the Je and S genomes in these species had C-banding patterns differing from each other and from those of the extant diploid species. Based on these findings, the four species investigated should be placed in the same genus or the same section of a genus. However, new combinations are not proposed at this time pending future taxonomic investigation of the genome constitution of Elytrigia repens (L.) Nevski.     

国产毛茛属三种植物的核型研究

对国产三种毛茛属 (Ranunclus)植物进行了核型研究 ,其中昆明毛茛 (RanunculuskunmingensisW .T .Wang)染色体数目 2n=1 4及核型 2n =1 4 =6m +4sm +4st为首次报道 ;匍枝毛茛 (R .repenceL .)核型公式为 2n =4x =3 2 =8m +1 2sm +1 0st+2t,它是由两个不同的染色体组组成 ;刺果毛茛 (R .muricatusL .)核型公式为 2n=8x=64=1 0m +2 2sm +2 8st+4t,它也是由两个不同的染色体组组成     

Elymus与普通小麦属间杂种的细胞遗传学研究

本研究以Elymus pendulinus(Nevski)Tzvelev(2n=4x=28,SSYY)、E.shandongenisis B.Salomon(2n=4x=28,SSYY)与普通小麦(Triticum aestivum L.:2n=6x=42,AABBDD)进行了属间远缘杂交。通过对杂种胚的离体培养,两个组合均产生了杂种F_1植株。杂种F_1为多年生,植株生长旺盛;形态上介于亲本种之间而兼具双亲的某些特征;穗状花序发育正常,但均完全不育。两个组合的根尖和花粉母细胞染色体数目为2n-5x=35。通过对杂种减数分裂染色体配对行为的分析,发现其MI染色体的配对水平很低,二价体均为棒状,每细胞的平均染色体交叉数在0.25-0.31之间。这表明E.pendulinus t E.shandongensis 所含的SY染色体组与普通小麦的ABD染色体之间的同源程度很低。由于在E.shandongeasis 及其它具有SY染色体组的Elymus 单倍体中,SY染色体组之间的部份同源染色体配对数均明显高于该杂种中的配对数,这表明存在于普通小麦中的ph基因及其它具类似作用的基因系统能抑制SY染色体组之间的部份同源染色体配对。     

Two new Tibetan species of Elymus (Poaceae: niticeae) and their genomic relationships

Two Elymus species, E. cacuminus (2n = 4x = 28) and E. retroflexus (2n = 2x = 28). native to western China are described as species new to science. In order to determine genomic constitutions of the two species, intergeneric and interspecific hybridizations were carried out between the two new species and Pseudoroegneria spicata (2n = 2x = 14, SS), and sixteen other Elymus species, fifteen tetraploids (2n = 4x = 28) and one hexaploid (2n = 6x = 42), containing the "SH", "SY", and "SYH" genomes. Chromosome pairing behaviour was studied in the two species and their hybrids. Generally low meiotic pairing was observed in the hybrids with S- and SH-genome species and high pairing in the hybrids with SY- and SYH-genome species. It is concluded from this study that (i) the two new species are strict allotetraploid (2n = 4x = 28) and self-pollinating taxa (inbreeders) in nature; (ii) they contain the "SY" genomes and; (iii) they have close genomic relationships with the SY-genome Elymus species from the same or geographically adjacent areas.