基于psbA trnH序列的十种棘豆属植物分子系统学研究

选择内蒙古28个样地采集的10种棘豆属植物56个单株,提取样品的基因组DNA,对其叶绿体psbA trnH序列进行扩增、测序,所得序列利用ClustalX软件进行对位排列,并用MEGA50软件采用最大似然法构建系统发育树。结果显示：（1）10种棘豆属psbA trnH序列的变异位点50个,信息位点36个,种间碱基差异百分率为34%,GC含量变化范围在2318%~2572%之间。（2）棘豆属与黄芪属各为一支,自展支持率达99%,这10种棘豆属植物可能为单系起源。（3）系统树中小叶小花棘豆与小花棘豆的样本独立成一支,支持将小叶小花棘豆作为小花棘豆的变种来处理。（4）多叶棘豆、砂珍棘豆和黄毛棘豆的样本相互混杂,表明亲缘关系很近,支持《内蒙古植物志》将三者归入真棘豆亚属轮叶棘豆组的观点。（5）缘毛棘豆与薄叶棘豆的样本聚成一支,支持将二者归入矮生棘豆组。研究表明,psbA trnH序列可为棘豆属下种间系统发育关系研究提供分子证据。     

基于psbA-trnH序列的十种棘豆属植物分子系统学研究

选择内蒙古28个样地采集的10种棘豆属植物56个单株,提取样品的基因组DNA,对其叶绿体psbA．trnH序列进行扩增、测序,所得序列利用ClustalX软件进行对位排列,并用MEGA5．0软件采用最大似然法构建系统发育树。结果显示：（1）10种棘豆属psbA．trnH序列的变异位点50个,信息位点36个,种间碱基差异百分率为3．4％,GC含量变化范围在23．18％～25．72％之间。（2）棘豆属与黄芪属各为一支,自展支持率达99％,这10种棘豆属植物可能为单系起源。（3）系统树中小叶小花棘豆与小花棘豆的样本独立成一支,支持将小叶小花棘豆作为小花棘豆的变种来处理。（4）多叶棘豆、砂珍棘豆和黄毛棘豆的样本相互混杂,表明亲缘关系很近,支持《内蒙古植物志》将三者归入真棘豆亚属轮叶棘豆组的观点。（5）缘毛棘豆与薄叶棘豆的样本聚成一支。支持将二者归入矮生棘豆组。研究表明,psbA-trnH序列可为棘豆属下种间系统发育关系研究提供分子证据。     

青藏高原六种棘豆属植物的染色体数目及核型报道

对6种棘豆属植物（Oxytropis）的13个居群样进行细胞学研究,其中黄花棘豆（O．ochrocephala）、绢毛棘豆（O．tatarica）、甘肃棘豆（O．kansuensis）和铺地棘豆（0．humifusa）为首次报道染色体数目（2n=16）和核型;在胀果棘豆（O．stracheyana）中（2n=48）首次发现B染色体。现有的细胞学资料表明：棘豆属植物中多倍体占总报道数的58％,这说明多倍化在本属植物的进化过程中起着非常重要的作用,但青藏高原仅有一种植物发现多倍体,多倍化并不占主导地位,而主要表现为二倍体水平上的结构变异,即核型不对称性的变化。     

10种棘豆属植物的trnL-F序列及其分子系统学研究

选择内蒙古27个样地采集的10种棘豆属植物54个单株,提取样品的基因组DNA,对其叶绿体trnL-F序列进行扩增、测序,所得序列利用ClustalX软件进行对位排列,并用MEGA5.0软件采用最大似然法构建系统发育树,以探讨棘豆属的种间关系与系统进化.结果显示:(1)10种棘豆属trnL-F的变异位点54个,信息位点46个,种间碱基差异百分率为1.9％,GC含量变化范围在30.69％～31.50％之间.(2)棘豆属与黄芪属各为一支,自展支持率达99％,支持棘豆属植物为单系起源.(3)系统树中小花棘豆的样本自成一支,为相对独立进化;多叶棘豆、砂珍棘豆和黄毛棘豆的样本相互混杂,表明亲缘关系很近,从而支持《内蒙古植物志》将三者归入真棘豆亚属轮叶棘豆组的观点.(4)刺叶柄棘豆的样本不同样地形成2个分支,对其亚属水平上的分类需进一步探讨.(5)缘毛棘豆与阴山棘豆的样本聚成一支,支持将二者归入矮生棘豆组.研究表明,trnL-F序列可为棘豆属下种间系统发育关系研究提供分子证据.     

新疆棘豆属棘豆组的修订

通过对大量标本和文献的研究,并结合野外居群的观察分析,澄清了《中国植物志》棘豆组中存在的分类学问题,对新疆棘豆属棘豆组植物的分类进行修订,确认产于新疆的棘豆属棘豆组植物8种、1变型,并重新编制了新疆棘豆属棘豆组的分种检索表,以及各种的分类学处理及地理分布.研究结果表明:少花棘豆归并在宽瓣棘豆中,其中少花棘豆为新异名;冰河棘豆应改为球花棘豆;冰川棘豆的学名更正为Oxytropis proboscidea;将黑萼棘豆并入长茎棘豆组中.此外,棘豆组增加了3个类群:等瓣棘豆、伊朗棘豆和奇台棘豆,其中等瓣棘豆和伊朗棘豆为新疆新记录种,白花球花棘豆为新变型.     

光棘豆悬浮细胞原生质体培养再生小植株(简报)

迄今为止,药用植物原生质体培养再生植株的报道还不多。光棘豆(Oxytropis leptophylla)是多年生豆科植物,可饲用,是一种常用的野生中草药。全株入药有清热解毒功能,用于治疗痈疤肿毒。已有研究表明,光棘豆具有离体培养时愈伤组织增殖快、植株再生频率高的特点。进行原生质体培养再生植株的研究将有助于光棘豆的改良和驯化,为其开发利用提供基础。本文首次报道了光棘豆悬浮细胞原生质培养再生小植株的结果。     

陕西棘豆属的种类、生活型及其地理分布

本文通过对陕西产的棘豆属(Oxytropis DC.)标本的研究,整理了陕西棘豆属15种、1变种、1改级新组合及1新变种,并描述了它们的地理分布。将该属的生活型划分为:长茎地面芽植物、半莲座地面芽植物、莲座地面芽植物及半灌木地上芽植物等。从中发现,棘豆在长期自然适应过程中,总是以本身的形态变异来适应外界环境的变化而形成一系列的生     

两种除草剂对狼毒和棘豆组织结构及膜代谢的影响

研究了自然状况下2种草原毒草狼毒(Stellera chamaejasme)和棘豆(Oxytropis ochrocephala)在除草剂“灭狼毒”和“灭棘豆”作用下组织结构和膜代谢的变化。在适当剂量的药剂处理下,两种除草剂分别对细胞膜系统产生影响．使膜脂过氧化生成MDA;细胞外渗液的电导率增大。“灭狼毒”和“灭棘豆”都可以使狼毒和棘豆叶片栅栏组织排列呈疏松变化趋势．细胞间隙增大．叶肉细胞结构破坏,形成大的空腔;保卫细胞萎缩．气孔下腔增大。这表明,这两种除草剂在各自作用的植物体内部即能破坏植物细胞的膜结构,引起原生质电解液外漏．导致细胞失水,同时还影响植物的运输机能．进而影响植物的结构,最终导致植物的死亡。     

基于5.8SrDNA/ITS序列的内蒙古棘豆属植物分子系统学分析

对12种34个地理种群的内蒙古棘豆属植物核糖体ITS区段和5.8S基因序列进行比较分析,并采用Maximum Likelihood法构建系统发育树.结果表明:支持棘豆属植物为单系起源,支持《内蒙古植物志》将黄毛棘豆(Oxytropis ochrantha)、多叶棘豆(O.verticillaris)、二色棘豆(O.bicolor)和砂珍棘豆(O.racemosa)归入真棘豆亚属(Subgen.Euoxytropis)轮叶棘豆组(Sect.Baicalia Stell.ex Bunge)的观点.推测多叶棘豆和砂珍棘豆ITS2区段出现的C/T转换可能是其部分种群混杂在其他物种中的主要原因,但基因转换对于系统发育的影响仍尚未可知.研究不支持传统分类学上对鳞萼棘豆(O.squammulosa)与刺叶柄棘豆(O.aci ph ylla)的划分,系统发育树显示二者聚为一支,而非与传统分类学上界定的同组或同亚属植物形成一支;结合植物地理学研究结果,认为刺叶柄棘豆与鳞萼棘豆为地理替代种.推测刺叶柄棘豆可能为多系起源物种.线叶棘豆(O.fili formis)和东北棘豆(O.coerulea与真棘豆亚属物种构成姐妹群,而非单室棘豆亚属植物.研究认为在物种界定过程中,只将少数几个形态学特征作为主要分类依据欠妥.     

植物生长季节不同栖息地高原鼠兔的食物选择

本文采用胃内容物镜检分析法,对栖息于青藏高原矮嵩草草甸、垂穗披碱草草甸和杂类草草甸中的高原鼠兔的主要食物组成进行了比较分析,旨在探讨栖息地变化对高原鼠兔食物组成的影响,揭示高原鼠兔对栖息地变化的生存对策和适应性.研究结果表明:在矮嵩草草甸,高原鼠兔主要取食垂穗披碱草、早熟禾、蓝花棘豆和甘肃棘豆;在垂穗披碱草草甸,主要选择垂穗披碱草、甘肃棘豆、蓝花棘豆、矮嵩草和二柱头蔗草;在杂类草草甸,喜食植物种类为垂穗披碱草、蓝花棘豆、甘肃棘豆、早熟禾、弱小火绒草、长茎藁本、兰石草和红花岩生忍冬.在整个植物生长季节,高原鼠兔在3种栖息地共取食27种植物,其中垂穗披碱草、甘肃棘豆和蓝花棘豆在不同栖息地中选择指数较高,为高原鼠兔优先选择的食物;在不同栖息地,高原鼠兔取食植物有差别,垂穗披碱草草甸为16种、矮嵩草草甸为22种,杂类草草甸为24种;喜食食物比例也存在着明显差别,在垂穗披碱草草甸,垂穗披碱草比例高达40.5%,在矮嵩草草甸,甘肃棘豆比例也达到23.7%,而在杂类草草甸,选食比例最高的兰石草仅为14.6%,说明在该草甸高原鼠兔食物选择呈现泛化趋势.相似性指数分析结果也表明,杂类草草甸中高原鼠兔主要食物组成与其它两种栖息地有较大的区别.从而说明当栖息地植物群落种类组成发生变化后,高原鼠兔可以通过改变其食物组成而适应新的栖息地.     

Extensive homologous recombination between introduced and native regulatory plastid DNA elements in transplastomic plants

Homologous recombination within plastids directs plastid genome transformation for foreign gene expression and study of plastid gene function. Though transgenes are generally efficiently targeted to their desired insertion site, unintended homologous recombination events have been observed during plastid transformation. To understand the nature and abundance of these recombination events, we analyzed transplastomic tobacco lines derived from three different plastid transformation vectors utilizing two different loci for foreign gene insertion. Two unintended recombinant plastid DNA species were formed from each regulatory plastid DNA element included in the transformation vector. Some of these recombinant DNA species accumulated to as much as 10–60% of the amount of the desired integrated transgenic sequence in T0 plants. Some of the recombinant DNA species undergo further, “secondary” recombination events, resulting in an even greater number of recombinant plastid DNA species. The abundance of novel recombinant DNA species was higher in T0 plants than in T1 progeny, indicating that the ancillary recombination events described here may have the greatest impact during selection and regeneration of transformants. A line of transplastomic tobacco was identified containing an antibiotic resistance gene unlinked from the intended transgene insertion as a result of an unintended recombination event, indicating that the homologous recombination events described here may hinder efficient recovery of plastid transformants containing the desired transgene. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Chloramphenicol acetyltransferase as selectable marker for plastid transformation

Chloroplast transformation remains a demanding technique and is still restricted to relatively few plant species. The limited availability of selectable marker genes and the lack of selection markers that would be universally applicable to all plant species represent some of the most serious technical problems involved in extending the species range of plastid transformation. Here we report the development of the chloramphenicol acetyltransferase gene cat as a new selectable marker for plastid transformation. We show that, by selecting for chloramphenicol resistance, tobacco chloroplast transformants are readily obtained. Transplastomic lines quickly reach the homoplasmic state (typically in one additional regeneration round), accumulate the chloramphenicol acetyltransferase enzyme to high levels and transmit their plastid transgenes maternally into the next generation. No spontaneous antibiotic resistance mutants appear upon chloramphenicol selection. Several lines of evidence support the assumption that plant mitochondria are also sensitive to chloramphenicol suggesting that the chloramphenicol acetyltransferase may be a good candidate selectable marker for plant mitochondrial transformation.     

A subset of conserved tRNA genes in plastid DNA of nongreen plants.

The plastid genome of the nonphotosynthetic parasitic plant Epifagus virginiana contains only 17 of the 30 tRNA genes normally found in angiosperm plastid DNA. Although this is insufficient for translation, the genome is functional, so import of cytosolic tRNAs into plastids has been suggested. This raises the question of whether the tRNA genes that remain in E. virginiana plastid DNA are active or have just fortuitously escaped deletion. We report the sequences of 20 plastid tRNA loci from Orobanche minor, which shares a nonphotosynthetic ancestor with E. virginiana. The two species have 9 intact tRNA genes in common, the others being defunct in one or both species. The intron-containing trnLUAA gene is absent from E. virginiana, but it is intact, transcribed, and spliced in O. minor. The shared intact genes are better conserved than intergenic sequences, which indicates that these genes are being maintained by natural selection and, therefore, must be functional. For the most part, the tRNA species conserved in nonphotosynthetic plastids are also those that have never been found to be imported in plant mitochondria, which suggests that the same rules may govern tRNA import in the two organelles. A small photosynthesis gene, psbI, is still intact in O. minor, and computer simulations show that some small nonessential genes have an appreciable chance of escaping deletion.     

The obligate root parasite Orobanche cumana exhibits several rbcL sequences

Orobanche species characterization using plastid sequences as molecular markers revealed that O. cumana contains at least two distinct rbcL sequences: one similar in size to the truncated rbcL pseudogene from O. cernua, a closely related species, and another with a size comparable to that of rbcL plastid genes from autotrophic plants. In this work, the nucleotide sequences of these two copies are reported and analysed. The organization of the O. cumana plastid genome was investigated using a long-distance PCR strategy in order to determine their localization. Because of the non-plastid localization of the rbcL larger copy, Southern blot and PCR chromosome-walking experiments were carried out to better characterize this transferred sequence and to identify its localization. Then the mode of multiple transfer of genetic information from plastid to nucleus and the concomitant plastid sequence disorganization and migration during parasitic plant evolution are discussed.     

PHYLOGENETIC IMPLICATIONS OF DIFFERENCES IN NUMBER OF PLASTID PHOSPHOGLUCOSE ISOMERASE ISOZYMES IN NORTH AMERICAN COREOPSIS (ASTERACEAE: HELIANTHEAE: COREOPSIDINAE)

Enzyme electrophoresis was employed to ascertain the number of loci encoding plastid phosphoglucose isomerase (PGI) in species representing all sections of North American Coreopsis. Several species from each of the closely related genera Bidens, Coreocarpus, Cosmos, and Thelesperma were also examined. Species in nine of the 11 sections of North American Coreopsis have two isozymes for plastid PGI, and nearly all species examined in the four other genera also have two (one species has three) isozymes. Since most diploid vascular plants have one plastid PGI isozyme, a gene duplication probably occurred in an ancestor that is common to Coreopsis and the other four genera. That is, two isozymes represent the ancestral number for Coreopsis. The two sections (Electra and Anathysana) apparently lacking the duplication are closely related woody plants restricted largely to Mexico. One gene encoding plastid PGI ostensibly was silenced in a common ancestor of these two sections. This is concordant with other data suggesting a close relationship between the two sections, i.e., they appear to represent a monophyletic group. The electrophoretic data also indicate that 1) the enigmatic monotypic section Silphidium is more closely related to eastern North American sections and not derived from section Electra; and 2) section Anathysana is not ancestral to the three California sections Leptosyne, Pugiopappus, and Tuckermannia; rather, it represents a terminal element closely related to and possibly derived from section Electra.     

THE USE OF PLASTID DNA RESTRICTION ENDONUCLEASE PATTERNS IN DELINEATING RED ALGAL SPECIES AND POPULATIONS1

Plastid DNA band patterns generated by electrophoresis of endonuclease digests demonstrate remarkable conservation of DNA sequences at the species and subspecies level in flowering plants. Generally, patterns are identical or near-identical from different populations belonging to the same species. This methodology has now been applied to red algae to ascertain its value in systematic studies. Plastid DNA from nine bangiophycean and florideophycean red algae was isolated and cut with restriction endonucleases that recognize different 6-base pair sequences. The patterns generated upon the electrophoretic separation of digestion fragments show that within a species patterns are identical, but not within higher taxa. The proper identification of one Gracilaria population of uncertain taxonomic affinity was clearly established by this method of plastid DNA analysis. Differences between species in plastid DNA sequences were confirmed by probing blots of restriction fragments with known gene sequences. A number of heterologous plastid DNA probes were found to be sufficiently homologous to be useful in studying red algal DNA. Unexpectedly, supercoiled circular plasmids ranging in size from ca. 1.5–8 kb were found in some red algal species but not in others. The position of these plasmids in agarose gels following electrophoresis is uniform within a species but differs between different species of the same genus, contributing further patterns for taxonomic analysis.     

Evidence for duplication of the structural genes coding plastid and cytosolic isozymes of triose phosphate isomerase in diploid species of clarkia

Formal genetic analyses of the mode of inheritance of the multiple plastid and cytosolic isozymes of triose phosphate isomerase (TPI, EC 5.3.1.1) in annual diploid species of Clarkia (Onagraceae), native to California, suggest that each set of isozymes is specified by duplicate structural genes. In contrast, most diploid plant species possess one plastid and one cytosolic TPI isozyme each coded by a single locus. Linkage tests revealed that the two genes coding the plastid TPIs assort independently. Although the number of individuals sampled per species was small, the plastid isozymes were electrophoretically more variable than the cytosolic isozymes. The two gene duplications are the first reported that characterize an entire plant genus. Initial electrophoretic surveys of TPI in other genera of Onagraceae revealed that the duplication of the gene coding the plastid isozyme is apparently restricted to Clarkia, whereas that of the gene coding the cytosolic isozyme is present in most genera of the family. The separate phylogenetic distributions of the two duplications suggest that the processes that gave rise to them were unrelated.     

MutS HOMOLOG1 is a nucleoid protein that alters mitochondrial and plastid properties and plant response to high light

Mitochondrial-plastid interdependence within the plant cell is presumed to be essential, but measurable demonstration of this intimate interaction is difficult. At the level of cellular metabolism, several biosynthetic pathways involve both mitochondrial- and plastid-localized steps. However, at an environmental response level, it is not clear how the two organelles intersect in programmed cellular responses. Here, we provide evidence, using genetic perturbation of the MutS Homolog1 (MSH1) nuclear gene in five plant species, that MSH1 functions within the mitochondrion and plastid to influence organellar genome behavior and plant growth patterns. The mitochondrial form of the protein participates in DNA recombination surveillance, with disruption of the gene resulting in enhanced mitochondrial genome recombination at numerous repeated sequences. The plastid-localized form of the protein interacts with the plastid genome and influences genome stability and plastid development, with its disruption leading to variegation of the plant. These developmental changes include altered patterns of nuclear gene expression. Consistency of plastid and mitochondrial response across both monocot and dicot species indicate that the dual-functioning nature of MSH1 is well conserved. Variegated tissues show changes in redox status together with enhanced plant survival and reproduction under photooxidative light conditions, evidence that the plastid changes triggered in this study comprise an adaptive response to naturally occurring light stress.