猬草及其近缘属植物单拷贝核Pgk1基因序列的系统发育分析

文章对禾本科小麦族猬草属及其近缘属Thinopyrum(Eb)、Lophopyrum(Ee)、拟鹅观草属(St)、新麦草属(Ns)、大麦属(H)、赖草属(NsXm)和披碱草属(StH)植物共23个类群的单拷贝核Pgk1基因序列进行系统发育分析, 探讨猬草属及其近缘属植物的系统发育关系。序列分析发现Pgk1基因序列在L. arenarius和Psa. juncea中有81 bp的Stowaway家族DNA转座元件插入, 而在Hy. duthiei、Hy. duthiei ssp. longearistata和L. akmolinensis中有29 bp Copia家族的反转录转座元件插入。最大似然和贝叶斯推断进行的系统发育分析表明: (1)猬草属模式种Hy. patula与披碱草属、拟鹅观草属和大麦属具有密切的亲缘关系; (2)猬草属的其他物种Hy. duthiei、Hy. duthiei ssp. longearistata、Hy. coreana和Hy. komarovii与新麦草属和赖草属植物亲缘关系密切。研究结果支持将Hy. patula从猬草属组合到披碱草属中, 而Hy. duthiei、Hy. duthiei ssp. longearistata、Hy. coreana和Hy. komarovii应组合到赖草属中。     

小麦族披碱草属、鹅观草属和猬草属模式种的C带研究

采用改良的Giemsa C带技术,分析了小麦族披碱草属、鹅观草属和猬草属模式种的染色体C带带型。Elymus sibiricus、Roegneria caucasica和Hysrix patula的染色体在Giemsa C带带型上存在明显的差异,显示了这3个属模式种的物种特异性。3个模式种的Giemsa C带核型表明,C带带纹主要分布在染色体的末端和着丝粒附近,而中间带相对较少。对E.sibiricus、R.caucasica和H.patula的St、H、Y染色体组C带带型与其它物种的St、H、Y染色体组C带带型的差异进行了讨论。     

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。     

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。     

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。     

应用RAPD特异标记分析拟鹅观草属部分物种的基因组组成

选用小麦族中8个基本基因组(E、H、I、P、St、W、Ns、R)的特异RAPD引物进行PCR扩增检测,分析Pseudoroegneriagracillima、P.kosaninii、Roegneriaalashanica和R.magnicaespes这4个四倍体物种的基因组组成。结果表明:P.gracillima、P.kosaninii、R.alashanica和R.magnicaespes中除了含有St或经修饰的St基因组外,都不含E、H、I、P、W、Ns和R基因组,由此推断P.gracillima和P.kosaninii至少含有一个St或经修饰的St基因组,另一个基因组是否为Y基因组,需要进一步研究证实。结合前人细胞遗传学研究的结果,推断R.alashanica和R.magnicaespes为同源四倍体或部分同源四倍体,其基因组组成为StStStSt或St1St1St2St2。因此,结合外部形态特征以及前人细胞遗传学、分子标记研究和核型分析的结果,推断R.alashanica和R.magnicaespes与P.elytrigioides一样,也可能是在中国分布的四倍体拟鹅观草属物种,为系统整理和研究国产拟鹅观草属物种及其地理分布提供了DNA分子水平上的资料。     

中间偃麦草染色体2Ai-2特异PCR新标记的建立和St基因组特异序列的克隆

中间偃麦草麦、小麦和小麦－中间偃麦草2Ai－2附加系Z1、Z2、X6,代换系ZD28等进行RAPD分析,从320个RAPD引物中,鉴定出2Ai－2染色体特异的2个RAPD标记OPO05650和OPMO414000。利用这2个特异OPO05和OPM04,PCR扩增普通小麦CS（ABD）及其近缘植物中间偃麦草（E1E2St）、拟鹅冠草（St）,长穗偃麦草（E）、簇毛麦（V）、黑麦（R）、大麦（H）粗山羊草（D）等基因组DNA。结果表明,OPO05650和OPO41400均是2Ai－2染色体上St基因组区域的特异标记。将上棕2个特异片段分离回收、克隆、测序,根据测序结果重新设计、合成特异引物,成功地转换RAPD标记为SCAR（sequence characterizked amplifed region）标记SC－05和SC－M4。利用SCAR标记对不同材料进行分析的结果表明,凡含有2Ai－2染色体的抗黄矮病材料及拟鹅冠草均产生一条扩增带,不含2Ai－2染色体的材料,包括小麦、长穗麦草、簇毛麦、黑麦、在麦、粗山羊草以有含有其他他中间偃麦草染色休的附加系,均没有扩增产物,说明上棕2个SCAR标记是中间偃麦草2Ai－2染色体的特异性PCR标记,且是2Ai－2染色体上St基因组区域的特异性标记。克隆与鉴定中间偃麦草的2个SCAR扩增片段TiSCO5和TiSCM4。结果表明,克隆的中间偃麦草TiSCO5和TiSCM4特异片段,分别是St基因组特异性的寡拷贝序列有多拷贝重复序列,为St基因组遗传研究的新探针。     

长芒猬草与华山新麦草属间杂种的形态学和细胞学研究

为研究长芒猬草Hystrix duthiei ssp．longearistata的染色体组成,将其与华山新麦草Psathyrostachys huashanica进行了人工杂交,获得杂种F₁。对亲本及杂种F₁,花粉母细胞减数分裂染色体配对行为、繁育 特性和形态特征进行了比较分析。结果表明：杂种F₁的许多形态特征介于父母本之间,花粉完全不育, 结实率为0;杂种F₁花粉母细胞减数分裂中期Ⅰ染色体配对较高,55.12％的细胞形成5个或6个二价 体,其构型为：9.83Ⅰ+5.46Ⅱ+0.07Ⅲ,C-值为0.57。以上结果表明H．duthiei ssp．Longearistata含有Ns染色体组。本文还讨论了Hystrix与Leymus的关系。     

现生毛猬Neotetracus属与Hylomys及Neohylomys属齿系和颅骨的比较(英文)

鼩猬属Neotetracus是毛猬亚科Hylomyinae中一个个体小、对其知之甚少的成员。本文对其齿系(包括乳齿)和颅骨的特征进行了描述,并与毛猬属Hylomys及毛猬类其他近亲的齿系和颅骨形态进行了相应比较。由于现生的鼩猬属为一单型属,其惟一的种Neotetracus sinensis被一些研究者归入毛猬属,本文之所以进行这样的比较,目的是为了弄清楚这种归并是否合理。Neohylomys hainanensis是毛猬类的另一属种,亦有学者将其归入Hylomys属。尽管这一属种的材料不多,在此同样作了比较研究。比较表明,毛猬亚科上述三属间在齿列上的几乎每一颗牙齿和某些头骨形态上都有明显的差别,研究的结果为保留Neotetracus,Neohylomys和Hylomys属的独立存在提供了证据,并根据这三个属在形态上的差异对其相互间的进化水平进行了评估。现代的毛猬亚科动物生活在亚洲东南部一个相对小的地区,总共有5属6种。地史上,特别是在中、晚中新世期间,这一亚科几乎散布整个北半球,从亚洲到欧洲和北非,从旧大陆到新大陆都有其踪迹。那时的种类也比现在的多,迄今描述的化石已有9属47种。因此,有理由认为毛猬亚科是一类孑遗动物。毛猬亚科分布地区缩小的原因还不清楚,为了探讨和认识这一有意思的课题,本文对其历史和分布做了简要的阐述。     

Genome- and species-specific markers and genome relationships of diploid perennial species in Triticeae based on RAPD analyses.

Eight different genomes (E, H, I, P, R, St, W, and Ns) represented by 22 diploid species of the tribe Triticeae were analyzed using the random amplified polymorphic DNA (RAPD) technique. The genome relationships were obtained based on 371 RAPD fragments produced with 30 primers. The four species of the genus Psathyrostachys (having various Ns genomes) were closely related. The genomes Ee and Eb had a similarly close relationship and were distinct from all other genomes analyzed. Genomes P, R, and St were grouped in one cluster and genomes H and I in another. Genome W had a distant relationship with all other genomes. These results agree with the conclusions from studies of chromosome pairing and isozyme and DNA sequence analyses. Twenty-nine and 11 RAPD fragments are considered to be genome- and species-specific markers, respectively. One to six genome-specific markers were identified for each genome. These RAPD markers are useful in studies of genome evolution, analysis of genome composition, and genome identification.     

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.     

Genetic diversity and phylogeny in Hystrix (Poaceae, Triticeae) and related genera inferred from Giemsa C-banded karyotypes

The phylogenetic relationships of 15 taxa from Hystrix and the related genera Leymus (NsXm), Elymus (StH), Pseudoroegneria (St), Hordeum (H), Psathyrostachys (Ns), and Thinopyrum (E) were examined by using the Giemsa C-banded karyotype. The Hy. patula C-banding pattern was similar to those of Elymus species, whereas C-banding patterns of the other Hystrix species were similar to those of Leymus species. The results suggest high genetic diversity within Hystrix, and support treating Hy. patula as E. hystrix L., and transferring Hy. coreana, Hy. duthiei ssp. duthiei and Hy. duthiei ssp. longearistata to the genus Leymus. On comparing C-banding patterns of Elymus species with their diploid ancestors (Pseudoroegneria and Hordeum), there are indications that certain chromosomal re-arrangements had previously occurred in the St and H genomes. Furthermore, a comparison of the C-banding patterns of the Hystrix and Leymus species with the potential diploid progenitors (Psathyrostachys and Thinopyrum) suggests that Hy. coreana and some Leymus species are closely related to the Ns genome of Psathyrostachys, whereas Hy. duthiei ssp. duthiei, Hy. duthiei ssp. longearistata and some of the Leymus species have a close relationship with the E genome. The results suggest a multiple origin of the polyploid genera Hystrix and Leymus.     

CAPS markers specific to Eb, Ee, and R genomes in the tribe Triticeae.

Wild Triticeae grasses serve as important gene pools for forage and cereal crops. Understanding their genome compositions is pivotal for efficient use of this vast gene pool in germplasm-enhancement programs. Several cleaved amplified polymorphic sequence (CAPS) markers were developed to distinguish the Eb, Ee, and R genomes. With the aid of disomic addition lines of wheat, it was confirmed that all 7 chromosomes of Eb, Ee, and R genomes carry these genome-specific CAPS markers. Thus, the identified CAPS markers are useful in detecting and monitoring the chromosomes of these 3 genomes. This study also provides evidence suggesting that some Purdue and Chinese germplasm lines developed for barley yellow dwarf virus (BYDV) resistance are different from those developed in Australia. Furthermore, Thinopyrum intermedium and Thinopyrum ponticum were shown to have different genome constitutions. Sequence analyses of the 1272 bp sequences, containing Ty3/gypsy retrotransposons, from the Eb, Ee, and R genomes also shed light on the evolution of these 3 genomes.     

Phylogenetic relationships between Leymus (Poaceae,Triticeae) and related diploid Triticeae species based on isozyme and genome-specific random amplified polymorphic DNA (RAPD) markers

Abstract

To investigate the phylogenetic relationships between Leymus and related diploid species of the Triticeae tribe, the esterase isozyme (EST), superoxide dismutase (SOD) isozymes, and genome-specific random amplified polymorphic DNA (RAPD) markers were used to analyze for 14 Leymus species, together with two Psathyrostachys species (Ns), three Pseudoroegneria species (St), two Hordeum species (H), Lophopyrum elongatum (E^e), Australopyrum retrofractum (W), and Agropyron cristatum (P). The data were used to construct dendrograms by means of UPGMA in the NTSYS-pc computer program. The results suggested that (1) isozyme analysis can be used in the systematic studies of these perennial Triticeae; (2) there is a close relationship between Leymus, Psathyrostachys juncea, three Pseudoroegneria species, and Lophopyrum elongatum; (3) the Ns genome-specific RAPD marker was present in all 14 polyploid species of Leymus, while the E^e and P genome-specific RAPD markers were absent in 14 polyploid species of Leymus; the St, W and H genome-specific RAPD markers were present in some species of Leymus; (4) Leymus species have multiple origins, and different Leymus species derived their genomes from different donors.     

Phylogenetic Analysis of Leymus (Poaceae: Triticeae) Inferred from Nuclear rDNA ITS Sequences

To investigate the phylogenetic relationships of polyploid Leymus (Poaceae: Triticeae), sequences of the nuclear rDNA internal transcribed spacer region (ITS) were analyzed for 34 Leymus accessions representing 25 species, together with three Psathyrostachys species (Ns genome), two Pseudoroegneria (St genome) species, Lophopyrum elongatum (E(e) genome), and Thinopyrum bessarabicum (E(b) genome). The phylogenetic analyses (maximum likelihood and Bayesian inference) supported two major clades, one including 21 Leymus species and three Psathyrostachys species, the other with nine Leymus species and four diploid species. The ITS RNA secondary structure of the Leymus species was compared with that of their putative diploid donor. It is suggested that (1) the species from the same areas or neighboring geographic regions are closely related to each other; (2) L. coreanus, L. duthiei, L. duthiei var. longearistatus, and L. komarovii are closely related to other Leymus species, and it is reasonable to transfer these species from the genus Hystrix to Leymus; (3) the ITS sequences of Leymus are evolutionarily distinct; (4) the different Leymus species and different distribution of a species derived their Ns genome from different Psathyrostachys species; and (5) there is a close relationship among Leymus, Pseudoroegneria, Lophopyrum, and Thinopyrum, but it is difficult to presume that the St, E(e), and E(b) genome may be the Xm genome donor of the Leymus species.     

Identifying the genome of wood barley Hordelymus europaeus (Poaceae: Triticeae)

Wood barley, Hordelymus europaeus, was compared with other Triticeae species by Southern and fluorescence in situ hybridisation using total genomic DNA and repetitive sequences as probes. On Southern blots, the total genomic probe from H. europaeus hybridised strongly to DNA of its own species and to Leymus and Psathyrostachys, indicating the presence of Ns genome in H. europaeus. Furthermore, the total genomic probe from P. fragilis hybridised to DNA of H. europaeus as much as to all of the Psathyrostachys and Leymus species examined. Ns genome-specific DNA sequences isolated from L. mollis (pLmIs1, pLmIs44 and pLmIs53) hybridised essentially to H. europaeus and all of the species of Leymus and Psathyrostachys. Chromosomal localization of these clones on H. europaeus confirmed the presence of Ns genome-specific DNA on all chromosomes, indiscriminately. Under moderate hybridisation stringency the Ns genome-specific probes, together with repetitive sequences pTa71 and pAesKB7, produced species-specific RFLP banding profiles on Southern blots. A phenetic tree based on these profiles revealed a distinct Ns species cluster within the Triticeae, represented by Leymus and Psathyrostachys species. Hordelymus europaeus belonged to this Ns cluster. Chromosomal mapping of the 18S-25S and the 5S ribosomal genes, together with the repetitive sequence pLrTaiI, corroborated that H. europaeus was most probably related to Leymus, especially the European/Eurasian members of sect. Leymus. In an attempt to identify the genome of H. europaeus, different approaches were employed; the results clearly showed that wood barley had the Ns basic genome and nothing else.