利用RAPD分析披碱草属、鹅观草属和猬草属模式种的亲缘关系

利用随机扩增多态性DNA（RAPD）技术对小麦族披碱草属、鹅观草属和猬草属3个属的模式种进行了基因组DNA多态性分析。42个引物产物的290条谱带中,257条（88.62%)表现出多态性,说明披碱草属、鹅观草属和猬草属3个属的模式种间具有丰富的遗传多样性。利用290个RAPD标记,计算材料间Nei氏遗传相似性系和遗传距离,在NTSYS程序中利用UPGMA进行聚类。结果表明,Elymus sibiricus种不同居群间的遗传差异较小,遗传距离在0.097-0.180之间。E.sibiricus,Roegneria caucasica和Hystrix patula的种间遗传差异明显,遗传距离在0.458-0.605之间。H.patula与E.sibiricus的亲缘关系较近。R.caucasica与E.sibiricus的亲缘关系较远。     

鹅观草属、披碱草属、猬草属和仲彬草属物种的RAMP分析及系统学意义

对鹅观草属、披碱草属、猬草属和仲彬草属4属23个物种进行了RAMP分析。结果表明属间变异极大,多态性极高。31个引物组合产生的286条DNA扩增片段均具有多态性。聚类分析显示鹅观草属、披碱草属、猬草属和仲彬草属物种各自聚为一类;Roegneria alashanica、R．elytrigioides和R．magnticaespes聚类在一起;猬草属的模式种Hystrix patula与披碱草属物种聚类在一起,而Hystrix duthiei和H．longearistata单独聚为一类;形态相似、染色体组相同、地理分布一致的物种聚类在一起。本研究结果基本上同形态学和细胞学研究结果相吻合,将鹅观草属、披碱草属和仲彬草属作为属分类等级处理比较恰当,而猬草属的系统地位有待进一步确认。RAMP标记可作为评价多年生小麦族物种遗传多样性和亲缘关系的一种分子标记技术。     

小麦族鹅观草属、披碱草属、猬草属和仲彬草属细胞质基因组PCR-RFLP分析

对鹅观草属、披碱草属、猬草属和仲彬草属23个物种和1份外类群共24份材料进行了细胞质基因组PCR-RFLP分析。3个叶绿体和3个线粒体通用引物扩增出的片段,用15种限制性内切酶对其进行酶切。在47种引物/酶组合中,获得329条DNA片段,其中304条具有多态性,占92.4%。结果表明鹅观草属、披碱草属、猬草属和仲彬草属材料存在属间和种间多态性,遗传相似系数较高。聚类分析显示仲彬草属单独聚为一类,鹅观草属R. grandis、R. aristiglumis、R. elytrigioides、R. alashanica、R. magnicaespes聚为一类,R. caucasica、R. ciliaris、R. amurensis、R. japonensis聚在一起,5个披碱草属材料、3个猬草属材料和1个鹅观草属物种R. kamoji聚为一类。这些结果与前人对其进行的RAPD和RAMP分析的结果基本一致。仲彬草属作为属分类等级处理是恰当的,对于鹅观草属、披碱草属和猬草属的系统地位和一些物种的分类处理,有待进一步研究。     

小麦族四个属模式种的醇溶蛋白分析

利用酸性聚丙烯酰胺凝胶电泳 (APAGE)对小麦族披碱草属、鹅观草属、猬草属和仲彬草属 4个属的模式种进行了醇溶蛋白电泳分析 ,结果表明 :(1 ) 4个模式种具有明显的醇溶蛋白遗传多样性 ,其种间醇溶蛋白多态性高达 92 .3 % ;(2 ) Elymus sibiricus和 H ystrix patula具有相似的醇溶蛋白带型 ,而 Roegneria caucasica和Kengyilia gobicola的带型基本相似 ,其醇溶蛋白图谱能够反映一定的系统关系 ;(3 )不同收集地的 E. sibiricus材料间也存在明显的醇溶蛋白遗传差异 ,新疆的 E. sibiricus具有较丰富的醇溶蛋白带纹 ,而甘肃的 E. sibiricus的醇溶蛋白带纹较少。     

小麦族鹅观草属三种植物的生物系统学研究

本文研究了禾本科小麦族鹅观草属的3个种:缘毛鹅观草(Roegneria pendulina Neuski 2n=4x=28),纤毛鹅观草(R. ciliaris (Trin.) Nevski 2n=4x=28)和鹅观草(R. kamoji Ohwi 2n=6x=42)及其种间杂种的形态变异和染色体配对行为。各杂种F_1的减数分裂染色体配对数较高,但杂种高度不育。在杂种减数分裂中还观察到一定频率的多价体形成。以上结果充分表明该3种植物享有两个共同的基本染色体组,在S和Y染色体组之间发生过染色体相互易位,缘毛鹅观草的染色体组可拟定为S~PY~P。     

仲彬草属和鹅观草属几个种的核型研究

本文报道了仲彬草属2个种和鹅观草属3个种的核型,其核型均为首次报道。结果如下： Roegneria nutans,2n=4x=28=26m+2sm;R．abolinii,2n=4x=28=24m+4sm．R．aristiglumis, 2n=6x=42=32m+1Osm(2sat);Kengyilia tahelacana,2n=6x=42=36m(2sat)+6sm(2sat);K． zhoasuensis,2n=6x=42=34m(4sat)+8sm．根据核型特征,K．tahelacana和K．zhoasuensis两个六位体种归入K.engyilia属是正确的。     

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。     

鹅观草属与披碱草属属界划分的酯酶和过氧化物酶同工酶比较研究

本文采用聚丙烯酰胺凝胶电泳的方法对鹅观草属6种2变种、披碱草属6种以及作为对照的冰草属5种植物的酯酶和过氧化物酶同工酶进行了比较研宄,并根据酶谱的相似性指标,用数量分类中常用的排列方法对所分析的植物进行了二维排序。实验结果表明,尽管鹅观草属与披碱草属表现出具有较冰草属更近的亲缘关系,但二者之间仍存在着明显的界限。因此,本文资料支持将该二属分别作为独立的属对待。本文还讨论了同工酶资料与上述三属植物属下组的划分以及将排序的方法应用于同工酶谱定量分析的分类学意义。     

小麦族鹅观草属三个物种的关系研究

通过形态学特征比较、种间杂交、染色体组配对和繁育学资料,探讨鹅观草属拟披碱草组纤毛草系中的三个物种毛叶鹅观草、纤毛鹅观草和竖立鹅观草间的亲缘关系。结果表明毛叶鹅观草与纤毛鹅观草、竖立鹅观草存在一定的生殖障碍,纤毛鹅观草和竖立鹅观草不存在生殖障碍。建议将毛叶鹅观草作为纤毛鹅观草的亚种,而竖立鹅观草作为纤毛鹅观草的变种处理较为适宜。     

鹅观草属三个种的染色体组分析与同工酶分析

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. ciliaris (Trin.) Nevski)和竖立鹅观草(R. japonensis (Honda)Keng)的染色体组分析和二种同工酶电泳酶谱的分析,研究了这三个种的系统关系。两个种均含有两个相同的染色体组。R. kamoji和R. ciliari、R. japonensis的杂种F_1减数分裂均不正常,不能结实;而R. ciliaris和R. japonensis的正反交杂种F_1减数分裂规则,结实正常,两个种之间无生殖隔离。R. kamoji的酯酶和酸性磷酸酯酶同工酶谱与R. ciliaris和R. japonensis有明显区别,而后二种的上述酶谱无明显差异。上述结果均一致地支持了将R. ciliaris和R. japonensis合并为一种的观点,将R. japonensis处理为R. ciliaris的变种。     

Phylogeny of Hystrix and related genera (Poaceae: Triticeae) based on nuclear rDNA ITS sequences

The taxonomic status of Hystrix and phylogenetic relationships among Hystrix and its related genera of Pseudoroegneria (St), Hordeum (H), Psathyrostachys (Ns), Elymus (StH), Leymus (NsXm), Thinopyrum bessarabicum (E(b)) and Lophopyrum elongatum (E(e)) were estimated from sequences of the internal transcribed spacer (ITS) region of nuclear ribosomal DNA. The type species of Hystrix, H. patula, clustered with species of Pseudoroegneria, Hordeum, Elymus, Th. bessarabicum and Lo. elongatum, while H. duthiei ssp. duthiei, H. duthiei ssp. longearistata, H. coreana and H. komarovii were grouped with Psathyrostachys and Leymus species. The results indicate that: (i) H. patula is distantly related to other species of Hystrix, but is closely related to Elymus species; (ii) H. duthiei ssp. duthiei, H. duthiei ssp. longearistata, H. coreana and H. komarovii have a close affinity with Psathyrostachys and Leymus species, and H. komarovii might contain the NsXm genome of Leymus; and (iii) the St, H and Ns genomes in Hystrix originate from Pseudoroegneria, Hordeum and Psathyrostachys, respectively, while the Xm in Hystrix and Leymus has a complex relationship with the E or St genomes. According to the genomic system of classification in Tiritceae, it is reasonable to treat Hystrix patula as Elymus hystrix L, and the other species of Hystrix as species of a section of Leymus, Leymus Sect. Hystrix.     

RAPD Study on Inter species Relationships in Roegneria (Poaceae: Triticeae)

To assess the relationships among 26 species in Roegneria C. Koch, 34 random decamer primers were screened for RAPD fragments. 28 primers produced polymorphic RAPD products. Data from 16 primers were used for RAPD assay. By NTSYS-pc program, Jaccard' s genetic similarity coefficients were generated and dendrogram was constructed using UPGMA. It is concluded as follows: (1) Distinct genetic differences and extensive genetic diversity were present among the species. (2) There were some genetic differences between StY and StYH genomes, and StY and StYH had a certain degree of differentiations respectively which were related to geographic regions, the farther the geographic distribution between species, the less the similarity to each other. (3) When different accessions in a species, such as species with similar morphological characters, homologous genomes and similar geographic distribution, were clustered together respectively, it suggusted that they had closer relationships. (4) The awnless species R. alashanica Keng and R. magnicaespes (D. F. Cui) L. B. Cai, in Roegneria, were separated from the other species analysed in this study, indicating that these two species had intensive genetic differences from the others. (5) R. caucasica C. Koch, a species from Western Asia, was quite different from the other species contained StY genomes in Roegneria from Eastern Asia and Central Asia. (6) The results were in consistance with that of the analysis of morphology and chromosome pairing in the taxonomic treatments for R. ciliaris (Trin) Nevski and R. japonensis (Honda) Keng, R. tenuispica J. L. Yang et Y. H. Zhou and R. pendulina Nevski, and R. tsukushiensis (Honda) Ohwi and R. kamoji Ohwi. The present study discussed the usefulness of RAPD markers in the systematic study of Roegneria.     

Studies on Karyotypes of Two Species in Kengyilia and Three Species in Roegneria

The karyotypes of 3 species of Roegneria and 2 species of Kengyilia were analysed in this paper. They are all reported for the first time, and the karyotype formulae are as follows: R. nutans, 2n = 4X= 28 = 26m+ 2sm; R. abolinii, 2n = 4X =28 = 24m + 4sm; R. aristiglumis, 2n = 6X = 42 = 32m + 10sm (2sat); K. tahelacana 2n = 6X = 42 = 36m (2sat)+6sm (2sat); K. zhoasuensis, 2n = 6X= 42 = 34m(4sat)+ 8sm. According to the characters of karyotypes, K. tahelacana and K. zhoasuensis havethe S, Y, P genomes of genus Kengyilia.     

A Study on Karyotypes of 6 Species of Elymus in China

The present paper deals with the karyotype analysis of 6 species of Elymus which are native to Qinghai-Tibetan plateau. The number of somatic chromosomes in roottip cells of the 6 species and their karyotypes are reportad here for the first time, and they are all hexaploid, with 2n=6x=42. The karyotype formulae are as follows: E. melantherus, 2n=6x=42=32m+10sm, E. kengii, 2n=6x=42=34m+8sm, E grandiglumis, 2n=6x=42= 30 m+12 sm, E. laxiflorus, 2n=6x=42=32 m +10 sm, E. kokonoricus, 2n+6x=42=34 m +8 sm, E. longiglumis, 2n+6x=42=34 m+8 sm. No satellites have been founded in the 6 species and all the karyotypes belong to 1B or 2B type:     

鹅观草属三个物种及其居群间的醇溶蛋白分析

利用酸性聚丙烯酰胺凝胶电泳技术(APAGE)对小麦族鹅观草属3个物种:毛叶鹅观草、纤毛鹅观草和竖立鹅观草进行了醇溶蛋白电泳分析,23份材料电泳分离出22条相对迁移率不同的谱带,其中3条(16.6%)共同带,19条(83.4%)具多态性,每个材料可分离出9～16条谱带。结果表明:(1)三个物种具有相似的醇溶蛋白带型,但存在明显的种间差异;(2)同种不同居群间也存在遗传差异;(3)种间差异大于种内差异。     

A Biosystematic Study on Hybrids Between Psathyrostachys huashanica and Two Species of Roegneria

Intergeneric crosses were made betweem Psathyrostachys huashanica (2n=14, NN)and two Roegneria species, namely, R. ciliaris (2n=28, SSYY), and R. tsukushiensis (2n=42, SSHHYY). Two combinations of P. huashanica crossed with R. ciliaris and R. tsukushiensis produced adult hybrid plants. Although completely sterile, the hybrid plants developed rather vigorously, and were morphologically intermediate between the two parents.Two spikelets per node in part were observed in hybrids, which evidently came from P. huashanica. The chromosome configurations of R. ciliaris × P. huashanica and R. tsukushiensis × P. huashanica were 20.73 I+0.318 II, 24.80 I+1.578 II+0. 012 III, respectively. Polypolar division was found at anaphase I in meiosis of two hybrids. Abnormal meiosis in two hybrids was observed. The chromosome pairing indicates that there is only a little chromosome homoeology between “N” genome of P. huashanicaand “S”, “Y” or “H” genomes of R. ciliaris and R. tsukushiensis.     

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。