植物nrDNA ITS致同进化不完全现象及其进化意义

nrDNA是个多基因家族,在基因内往往有成千上万的拷贝,但通常只包含有一种序列,即所谓致同进化.因此,nrDNA ITS被广泛应用于植物系统与进化研究当中.近年来,部分研究发现,一些植物类群的基因组内nrDNA ITS也存在着较高的多样性,即致同进化不完全现象.该文就裸子植物和被子植物中nrDNA ITS存在致同进化不完全现象的原因和特点,nrDNA ITS假基因的识别,以及其进化意义等进行了综述.     

苏铁nrDNA ITS区的序列多态性:不完全致同进化的证据

本研究对苏铁(Cycas revoluta) nrDNA ITS进行克隆测序, 并以cDNA ITS为参照, 比较分析获得的序列的碱基变异、GC含量、5.8S二级结构的稳定性和5.8S保守基序的有无以及系统发育关系。结果发现苏铁nrDNA ITS存在较高的基因组内多样性, 同时, 这些分化的nrDNA ITS拷贝中包含有假基因的存在, 而且假基因与功能拷贝之间已经形成了较大的遗传分化, 这暗示假基因起源有较长历史。苏铁核仁组织区不仅多达16个, 而且分布在13条染色体上, 这可能是其nrDNA ITS致同进化不完全的主要原因。     

樟属植物ITS序列多态性分析

对樟科樟属(Cinnamomum Schaeffer) 17个代表样本的核糖体DNA内转录间隔区(nrDNA ITS)进行克隆测序。对获得的87条不同ITS序列的长度变异、GC含量、5.8S区二级结构的稳定性、遗传距离、进化模式以及系统发育关系进行了相关分析。研究结果显示, ITS序列在樟属植物内存在明显的多态性, 87条序列中的22条序列被鉴定为假基因序列, 其余65条序列为功能基因序列; 假基因序列采用中性进化模式, 变异明显大于功能序列。ITS序列在樟属植物中出现一致性进化不完全和假基因现象也可能发生在樟科其它类群中, 这可能是导致樟科植物ITS序列直接测序方式成功率低的重要原因。     

云南山茶(Camellia reticulata) nrDNA ITS序列多态性分析

对云南山茶 (Camellia reticulata) 8个品种的核核糖体DNA内转录间隔区(nrDNA ITS)进行克隆测序,将获得的ITS序列进行GC含量、 5.8S区二级结构的稳定性、替代模式、核苷酸多样性及系统发育关系的相关分析.实验结果显示,云南山茶8个品种的ITS序列存在丰富的基因组内多态性,同时包含中性进化的假基因,表明其ITS序列逃离了一致性进化.云南山茶ITS序列多态性的原因可能来自广泛的种间杂交,以及rDNA位点在基因组中有不确定的物理位置.ITS假基因为品种的物种形成研究提供了更全面的遗传证据,同时也提示了利用ITS假基因进行系统发育分析可能会对其真实的系统关系造成影响.     

山茶属植物ITS的多态性——一个广泛逃离一致性进化的实例

利用位于45S rDNA内转录间隔区（ITS）的3对SSR引物, 对山茶属（Camellia L.）的40个物种进行PCR扩增, 检测3个SSR位点的多态性, 研究物种倍性与多态性之间的关系。实验结果显示, 37个种（占92.5%）的ITS片段存在个体内长度多态性, 在这些种类的个体内至少有2–6类ITS拷贝, 表明山茶属植物的ITS片段存在广泛的非一致性进化; ITS序列上存在易于滑动的SSR位点, 并且其基因组中有较多位于不同染色体上的rDNA位点, 这很可能是山茶属植物ITS片段存在广泛多态性的原因。然而, 研究中没有发现多倍体种类ITS片段的多态性显著高于二倍体种类。山茶属植物ITS片段的多态性提示该属植物的rDNA可能存在更为复杂的进化模式, 在利用ITS片段解决该属植物的系统分类问题时应更为谨慎。     

ITS假基因对栎属系统学研究的影响及其对分子系统学研究的启示

核糖体rDNA ITS是被子植物系统发育研究中应用最广泛的分子标记之一。以前人们认为同一物种中的ITS序列因致同进化而使不同拷贝高度一致,在分子系统学研究中常以ITS1-5.8S-ITS2序列作为构建系统进化树的基础。近年来,在对一些被子植物的研究中发现这段序列在同一物种中具有多态性,有些拷贝中的5．8S区不具编码功能,人们把含有不具编码功能5．8S区的ITS1-5．8S-ITS2序列定义为ITS假基因序列,它对同源基因致同进化的假设形成了新的挑战。在诸多应用ITS序列重建系统进化关系的研究中,栎属系统学研究因ITS假基因的发现而倍受关注。本文以栎属为例回顾了ITS假基因的发现过程,分析了其对该属系统学研究的影响,为分子生物学在植物系统进化研究中的应用提供一些新的参考。     

ITS 假基因对栎属系统学研究的影响及其对分子系统学研究的启示*

核糖体rDNA ITS 是被子植物系统发育研究中应用最广泛的分子标记之一。以前人们认为同一物种
中的ITS 序列因致同进化而使不同拷贝高度一致, 在分子系统学研究中常以ITS1- 518S- ITS2 序列作为构建
系统进化树的基础。近年来, 在对一些被子植物的研究中发现这段序列在同一物种中具有多态性, 有些拷
贝中的518S 区不具编码功能, 人们把含有不具编码功能518S 区的ITS1-51 8S- ITS2 序列定义为ITS 假基因序
列, 它对同源基因致同进化的假设形成了新的挑战。在诸多应用ITS 序列重建系统进化关系的研究中, 栎
属系统学研究因ITS 假基因的发现而倍受关注。本文以栎属为例回顾了ITS 假基因的发现过程, 分析了其
对该属系统学研究的影响, 为分子生物学在植物系统进化研究中的应用提供一些新的参考。     

山茱萸科花粉形态研究

本文应用光学显微镜与扫描电子显微镜观察了山茱萸科Cornaceae4属(按照Wangerin1910年的概念)27种花粉形态,结果如下: 1.根据花粉特征,支持把青荚叶属Helwingia,桃叶珊瑚属Aucuba,鞘柄木属Torricellia三属分别独立成科的观点。 2.梾木属Cornus可明显区分为两种类型,即梾木型和四照花型;梾木型还可再分为三个亚类型.即灯台树亚型,长圆叶梾木亚型和梾木亚型。 5.支持四照花属应从梾木属中分出而独立成属;而在四照花属Dendronbenhamia下设立北美四照花亚属Subg. Apocarpea和四照花亚属Subg. Syncarpea;在梾木属下设立梾木亚属Subg. kraniopsis, 灯台树亚属Subg.Masomora等亚属的观点。 4.建立了—新亚属——长圆叶梾木亚属。     

药用野生稻复合体ITS1和ITS2序列变异及其系统进化分析

通过PCR扩增并测序分析稻属药用野生稻复合体5个野生稻种基因组完整的ITS区及5.8S区,并与栽培稻ITS序列进行比较,构建分子系统进化树,探讨了稻属药用野生稻复合体内不同种间的亲缘关系和系统进化.结果表明,ITS1和ITS2均有较高的G/C含量,ITS1序列的长度多态性相对较高,ITS2序列的碱基突变频率较高.药用野生稻和高秆野生稻亲缘关系很近,而与栽培稻亲缘关系较远;短药野生稻、斑点野生稻、澳洲野生稻与药用野生稻亲缘关系渐近.处于进化的过渡阶段.     

山羊草属异源多倍体物种核rDNA ITS区的进化

本文测定了山羊草属Aegilops 3个组中异源多倍体物种的核rDNA ITS区序列,并用邻接法进行了聚类分析。结果表明,多倍体物种的ITS区序列长度为559∽606bp,其中ITS1、ITS2分别有变异位点51、42个,且存在多态位点。多倍体种均与各自的某一祖先种构成稳定分支,说明在杂交-多倍化后,这些多倍体的ITS区在同步进化的作用下已向着其某一祖先种的ITS区进化。对于sect．Vertebrata的异源多倍体物种来说,其ITS区主要向其祖先种Ae．umbellulata(UU)的ITS区进化,这与山羊草属的细胞遗传学研究结果基本一致。在sect．Cylindropyrum和sect．Polyeides中,Ae．cylindrica(CCDD)朝着Ae．caudata (CC)进化;Ae．ventricosa(DDMvMv)朝着Ae．comosa(MM)进化;Ae．vavilovii(DDMMSS)朝着Ae．crassa (DDMM)进化。     

Accelerated nrDNA evolution and profound AT bias in the medicinal fungus Cordyceps sinensis

Cordyceps sinensis is a reputed medicinal fungus growing parasitically on buried larvae of ghost moths in Asian high-altitude grassland ecosystems. We have analysed the intraspecific ITS nrDNA (ITS1, 5.8S gene, ITS2) variation among 71 sequences of C. sinensis available in EMBL/Genbank. The ITS sequences, submitted to Bayesian ML analyses, were distributed into five groups, referred to as A–E. Nine of the sequences (groups D and E) grouped with distantly related hypocrealean/clavicipitalean taxa and are interpreted as sequences erroneously accessioned under wrong taxon names. The remaining 62 sequences constituted three highly supported clades (groups A–C), that may represent cryptic (phylogenetic) species currently ascribed to C. sinensis. A remarkably high sequence divergence occurred in the 5.8S gene between the three groups. Sequences of groups B and C showed accelerated substitution rates and high AT nucleotide bias. We hypothesize that the accelerated evolution and AT bias have been caused by a shift in life historical attributes or ecology. We also suggest that the recorded differences in medicinal effects among C. sinensis populations may be attributed to the existence of genetically differentiated chemotypes in this morphotaxon.     

Characterization of angiosperm nrDNA polymorphism, paralogy, and pseudogenes

Many early reports of ITS region (ITS 1, 5.8S, and ITS 2) variation in flowering plants indicated that nrDNA arrays within individuals are homogeneous. However, both older and more recent studies have found intra-individual nrDNA polymorphism across a range of plant taxa including presumed non-hybrid diploids. In addition, polymorphic individuals often contain potentially non-functional nrDNA copies (pseudogenes). These findings suggest that complete concerted evolution should not be assumed when embarking on phylogenetic studies using nrDNA sequences. Here we (1). discuss paralogy in relation to species tree reconstruction and conclude that a priori determinations of orthology and paralogy of nrDNA sequences should not be made based on the functionality or lack of functionality of those sequences; (2). discuss why systematists might be particularly interested in identifying and including pseudogene sequences as a test of gene tree sampling; (3). examine the various definitions and characterizations of nrDNA pseudogenes as well as the relative merits and limitations of a subset of pseudogene detection methods and conclude that nucleotide substitution patterns are particularly appropriate for the identification of putative nrDNA pseudogenes; and (4). present and discuss the advantages of a tree-based approach to identifying pseudogenes based on comparisons of sequence substitution patterns from putatively conserved (e.g., 5.8S) and less constrained (e.g., ITS 1 and ITS 2) regions. Application of this approach, through a method employing bootstrap hypothesis testing, and the issues discussed in the paper are illustrated through reanalysis of two previously published matrices. Given the apparent robustness of the test developed and the ease of carrying out percentile bootstrap hypothesis tests, we urge researchers to employ this statistical tool. While our discussion and examples concern the literature on plant systematics, the issues addressed are relevant to studies of nrDNA and other multicopy genes in other taxa.     

Evolution of the 5.8S nrDNA gene and internal transcribed spacers in Carapichea ipecacuanha (Rubiaceae) within a phylogeographic context

Nuclear ribosomal DNA (nrDNA) constitutes a multicopy gene family that is used widely to test evolutionary hypotheses across a broad range of organisms. It is presumed that, as a result of concerted evolution, tandem nrDNA repeats are homogeneous within species and different between species. We sampled 77 specimens of a disjunct species (Carapichea ipecacuanha) from throughout its three geographic ranges and obtained 266 nrDNA sequences, of which 26 were obtained by direct sequencing and 240 by cloning of PCR products. Complementary sequence analyses, which included analyses of secondary structure stability, the pattern of base substitutions, GC content, and the presence of conserved motifs, were used to characterize the internal transcribed spacer (ITS) region (ITS1-5.8S nrDNA-ITS2). Our results showed that concerted evolution of the ITS region was incomplete in C. ipecacuanha, particularly in the Atlantic range. In the highly polymorphic populations of the Atlantic range, intraindividual variation was observed and involved 56 functional paralogs and 15 pseudogenes from two highly divergent ribogroups. The Amazonian range (with 12 functional paralogs) and the Central-American range (with five functional paralogs) were genetically depauperate and exhibited no pseudogenes. In the two latter ranges, almost complete homogenization of the ITS sequences had occurred. We argue that it is important to consider past evolutionary history when making inferences about the efficiency with which concerted evolution homogenizes tandem nrDNA repeats a single sequence.     

Analysis of nrDNA polymorphism in closely related diploid sexual, tetraploid sexual and polyploid agamospermous species

Nuclear sequences of ITS1-5.8S-ITS2 region of rDNA may be an important source of phylogenetically informative data provided that nrDNA is cloned and the character of sequence variation of clones is properly analyzed. nrDNA of selected Taraxacum sections was studied to show sequence variation differences among diploid sexual, tetraploid sexual and polyploid agamospermous species. We examined nucleotide characteristics, substitution pattern, secondary structure, and the phylogenetic utility of ITS1-5.8S-ITS2 from 301 clones of 32 species representing 11 sections. The most divergent sequences of ITS1&2 differed by 17.1% and in 5.8S only by 3.7%. The ITS1-5.8S-ITS2 characteristics, integrity and also stability of secondary structures confirmed that pseudogenes are not responsible for the above variation. The within-individual polymorphism of clones implies that the concerted evolution of ITS cistron of agamospermous polyploid Taraxacum is remarkably suppressed. Sequences of ITS clones proved to be a useful tool for mapping pathways of complex reticulation (polyploid hybridity) in agamospermous Taraxacum.     

A phylogenetic study ofSaxifraga sect.Saxifraga (Saxifragaceae) based on nrDNA ITS sequences

Parsimony analyses of 54 nrDNA ITS (Internal Transcribed Spacer) sequences ofSaxifraga sect.Saxifraga were performed. In addition to some unresolved clades, there is strong disagreement between the ITS phylogeny and previous classifications based primarily on morphology. The extensive cytological instability of sect.Saxifraga prevents previous cytotaxonomical results from resolving the incongruence between molecular and morphological data. Dissimilar topologies between chloroplast (matK) and nuclear (ITS) trees for eight species of sect.Saxifraga suggest that gene trees and the true species tree are not coincident. Recent and mid-term reticulation is proposed as an explanation for the incongruence between morphological, cytological, organellar, and nuclear data. Homogenization in multigene families, such as the ITS region, via concerted evolution may be the key to the interpretation of results based on ITS sequences within sect.Saxifraga. The use of organellar genes in a larger sample should help to determine whether extensive reticulation occurs in sect.Saxifraga, as has been documented in various genera of Saxifragaceae.     

Extensive 5.8S nrDNA polymorphism in <Emphasis Type="Italic">Mammillaria</Emphasis> (Cactaceae) with special reference to the identification of pseudogenic internal transcribed spacer regions

The internal transcribed spacer (ITS) region (ITS1, 5.8S rDNA, ITS2) represents the most widely applied nuclear marker in eukaryotic phylogenetics. Although this region has been assumed to evolve in concert, the number of investigations revealing high degrees of intra-individual polymorphism connected with the presence of pseudogenes has risen. The 5.8S rDNA is the most important diagnostic marker for functionality of the ITS region. In Mammillaria, intra-individual 5.8S rDNA polymorphisms of up to 36% and up to nine different types have been found. Twenty-eight of 30 cloned genomic Mammillaria sequences were identified as putative pseudogenes. For the identification of pseudogenic ITS regions, in addition to formal tests based on substitution rates, we attempted to focus on functional features of the 5.8S rDNA (5.8S motif, secondary structure). The importance of functional data for the identification of pseudogenes is outlined and discussed. The identification of pseudogenes is essential, because they may cause erroneous phylogenies and taxonomic problems. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.