基于叶绿体DNA trnL内含子序列数据的檀香目科间系统发育关系的研究

应用叶绿体DNAtrnL内含子序列分析檀香目科间的系统发育关系。取样研究的檀香目个体的trnL内含子序列长度在科间呈现较大差异(从291bp到587bp)。最大简约性分析产生的严格一致树与以前已发表的基于其它基因的檀香目的分子系统学研究结果大体一致。香芙木属(铁青树科)是最早分支出的类群：桑寄生科、槲寄生科分别表现为单系类群,檀香科为并系;桑寄生科和槲寄生科并不具密切亲缘关系,槲寄生科从檀香科内衍生出来。本研究表明,具相对高的核苷酸替换率的叶绿体DNAtrnL内含子序列可为高等级类群系统发育关系的研究提供更多的信息位点。     

基于线粒体基因组探讨鲸偶蹄类七种动物的系统发育关系

利用作者已测定的赤麂(Muntiacus muntjak)线粒体全基因组序列和从GenBank检索到的鲸偶蹄类有代表性的长须鲸、河马、奶牛、绵羊、猪、羊驼6种动物的线粒体全基因组序列,按顺序分别连接各自的13个蛋白编码基因、13个氨基酸序列、2个rRNA基因和22个tRNA基因成一个氨基酸序列或核苷酸序列,用DNASTAR软件统计碱基长度和组成;分析奶牛、绵羊和赤麂两两之间蛋白编码基因的序列差异;用MEGA计算7种动物12S和：16S rRNA基因的遗传距离;基于连接在一起的13个蛋白编码基因的氨基酸序列,用NJ法构建系统关系树。结果显示：①偶蹄目反刍亚目牛科的绵羊和同亚目鹿科的赤麂先聚为一亚支,然后与该亚目牛科的奶牛并为一支;猪形亚目猪科的猪和胼足亚目驼科的羊驼并为一支;鲸目须鲸亚目须鲸科的长须鲸和偶蹄目猪形亚目河马科的河马并为一支。②赤麂与绵羊的亲缘关系更近。③推测赤麂与绵羊和奶牛的分歧时间分别约在14．7和16．0百万年前。     

骨舌鱼超目的系统发育关系

通过对中国化石骨舌鱼类及骨舌鱼类现生主要类群的比较研究,用 PAUP 软件对31个分类单元的65个特征进行了分析,得到了16个最简约的分支图(步长为206,一致性指数为 0．4320,保留指数为0．7194)。严格合意树显示,中国早白垩世的骨舌鱼类(酒泉鱼、狼鳍鱼、固阳鱼、吉南鱼、同心鱼、西夏鱼、昆都仑鱼和华夏鱼)主要为骨舌鱼超目中不同等级的干群;与一般的观点不同,始舌齿鱼与蛟河鱼组成了姊妹群关系;骨舌鱼目由 Thaumaturus、弓背鱼亚目和骨舌鱼亚目组成;弓背鱼类与象鼻鱼类关系更近;Ostariostoma 为弓背鱼科的姊妹群;副狼鳍鱼与[骨舌鱼亚科+犁齿鱼亚科]组成了姊妹群,该姊妹群关系的建立,将骨舌鱼科的历史延伸到了早白垩世。     

基于ITS序列探讨忍冬属的系统发育关系

以七子花(Heptacodium miconioides)为外类群,运用MEGA软件对20种忍冬属植物进行系统发育分析,采用邻接法(NJ)和最大简约法(MP)构建系统发育树,从分子系统学角度探讨忍冬属下的亲缘关系.结果表明:(1)在NJ和MP系统树中,没有形成系统树的基部分支,忍冬亚属(Subg.Chamaecerasus)和轮花亚属(Subg.Lonicera)没有形成姐妹群关系.(2)在各系统树中,囊管组内的各种没有聚为一支,故认为对囊管组的划分应进一步探讨.(3)忍冬属ITS区(ITS1+ITS2)的信息位点达到11.0%,信息位点比较丰富,证明ITS序列可以为解决忍冬属植物的系统发育问题提供较强的证据.     

应用SuperTRI方法重建百合目的系统发育关系

SuperTRI是Ropiquet等(2009)发表的一种新的超树方法,可以通过合并所有系统发育信息来共同组建大的系统发育树.该方法克服了超矩阵法和传统超树法的一些限制,使提出的系统发育假说可信度更高,更具有统计说服力.本文应用SupperTRI方法重建了百合目(Liliales)主要类群的系统发育关系,并与超矩阵法的分析结果进行了比较.结果显示:(1) SuperTRI方法产生了与超矩阵法相似的拓扑结构,但节点支持率相对较低,其中再现性指数对评判分支的可信性更容易理解,在系统树图示方法上也更直观;(2)SuperTRI系统树证实百合科、菝葜科、垂花科和菝葜藤科为一单系分支;黑药花科为一独立分支;秋水仙科、六出花科、刺藤科为一单系分支,但这3个大分支间的关系未明;支持白玉簪科和金梅草科互为姐妹群,是百合目最基部类群.     

中国桫椤科植物叶绿体trnL内含子和trnL-trnF基因间隔区序列的系统发育分析

运用对PCR产物直接测序和克隆后测序的方法测定了蚌壳蕨科1种和桫椤科11种(其中桫椤分别测定19株：小羽桫椤测定2株)植物的叶绿体trnL基因内含子和trnL-trnF基因间隔区序列。12种植物相应的长度介亍l004-l082之间,A T平均含量60．9％,G C平均含量39．1％。计算了不同种间以及种内不同个体间序列的碱基差别(转换值／颠换值)和Kimura遗传距离。序列数据经排列后分别进行最简约法、最大似然法和邻接法分析,结果显示：(1)白桫椤、海南白桫椤和大羽桫椤构成的分支最早和该科内其余植物组成的另一分支分歧,而后者又进一步分为刃个亚分支,分别和桫椤亚属、黑桫椤亚属对应,支持夏群的分类处理：(2)大桫椤～狭羽桫椤～毛轴桫椤～篦齿桫椤、多羽桫椤一白桫椤～海南白桫椤以及小羽桫椤一桫椤各自构成独立、自然的末端分支,再参照分支内植物间的遗传距蔼取值,建议将此3个末端分支依次归并为3种：大桫椤、白桫椤和桫椤;(3)白桫椤属在科内处于基部位置,桫椤属奇桫椤亚属和黑桫椤亚属为衍生分支,赞同Tryon关于桫椤科进化和囊群盖起源的假说。     

基于SSU序列的串珠藻目植物系统发育分析

通过18S rDNA基因(SSU)序列,构建了串珠藻目植物的系统发育关系.结果显示:SSU基因序列片段长度为1 871 bp,核苷酸变异位点有709个,占序列长度的38％;其中简约信息位点有169个,占序列长度的9％.用最大似然法、邻接法和贝叶斯法构建的系统树拓扑结构基本一致,都显示红索藻目的2个属独立于串珠藻目成单独分支,支持红索藻目的建立;胶串珠藻独立于其他串珠藻组植物,支持将其单独分组;数据同时支持将扭曲组和杂生组合并,建立Kumanoa属;但多芒组、绿色组、沼生组等因分子序列数据涉及的种类较少,其系统关系的确定还需要更多的证据.     

基于S6K1基因部分序列的鲤科鱼类系统发育关系及内含子1 Indel位点分析

鲤科鱼类在东亚分布广泛且数量丰富, 在物种演化上具有重要的系统发育地位. 本研究基于S6K1基因5′端功能调控序列, 通过PCR扩增、克隆和测序, 共获得30种鱼类S6K1 前端部分DNA序列(外显子1, 外显子2及内含子1), 对序列变异进行分析, 并采用邻接法(NJ)、最大简约法(MP)、最大似然法(ML)和贝叶斯法(Bayesian)重建鲤科鱼类系统发育关系. 亚口鱼科的胭脂鱼(Myxocyprinus asiaticus)作为外类群, 通过4种方法所得系统发育分支图大致相同, 均以较高的节点支持率支持雅罗鱼系和鲃系的划分, 雅罗鱼系包括雅罗鱼亚科东亚类群(East Asian group in Leuciscinae)、鲢亚科(Hypophthalmichthyinae)、鲴亚科(Xenocyprinae)、鲌亚科(Cultrinae)、相似文献   

基于多个叶绿体基因序列片段重建广义苋科系统发育关系

苋科(Amaranthaceae sensu lato)是石竹目(Caryophyllales)第二大科, 目前被普遍接受的苋科为其广义概念, 含狭义苋科(Amaranthaceae sensu stricto)和藜科(Chenopodiaceae)。然而到目前为止, 藜科是否应作为独立的科还存在争议。此外, 广义苋科内部各亚科之间的系统关系也尚未厘清。对广义苋科所有13个亚科代表类群进行取样(共59种), 基于8个叶绿体序列片段重建其系统发育关系, 并结合分子钟估算, 对该科及其主要分支的起源与分化时间进行推测。结果表明, 广义苋科与狭义苋科都是很好的单系, 但藜科并非单系, 因此不支持藜科在科级水平的地位, 支持广义苋科的观点。除了多节草亚科(Polycnemoideae)之外, 其它亚科的系统位置均得到很好的分辨。分子钟估算结果表明, 广义苋科于白垩纪晚期约69.9 Ma分化出该科的2个主要分支, 且该科在白垩纪-古近纪边界附近时期(约66.0 Ma)可能发生过快速辐射分化事件。     

trnK基因5′端内含子区序列在榆科(广义)系统发育研究中的应用

本文测定了广义榆科 Ulmaceae s．l．及其近缘类群的trn K基因5′端内含子区序列。在尝试利用该内含子区进行榆科系统发育研究的同时,探讨了其在植物系统学研究中的应用前景。利用PAUP软件进行的系统发育分析仅得到1棵最简约树。该简约树的树长为665步,其一致性指数(CI)和保持性指数(RI)分别为0.7714和0.7965。分析结果表明：广义榆科为多系群;狭义榆科Ulmaceae s．str．为荨麻目rticales其他类群的姊妹群;大麻科Cannabacea嵌在朴科Celtidacea中,即朴科为一并系群;系统位置有争议的2个属——白颜树属Gironniera和糙叶树属 Aphananthe与朴科类群聚为一支。本研究还表明trnK基因5′端内含子区序列分析在植物较低分类等级(如近缘属间,属下种间)的系统发育研究中具有很好的应用前景。     

Molecular phylogenetics of Diseae (Orchidaceae): a contribution from nuclear ribosomal ITS sequences

We present here the first molecular phylogeny of tribe Diseae (Orchidoideae: Orchidaceae). Nuclear ribosomal ITS1, 5.8S rDNA, and ITS2 sequences were compared for 30 Diseae, 20 Orchideae, and four Cranichideae and Diurideae outgroups. ITS - rDNA sequences exhibited a transition:transversion ratio of 1.3 and extensive ITS length polymorphism. Phylogenetic analyses using maximum parsimony identified seven major core orchidoid groups. The branching order of the five Diseae and two Orchideae clades was weakly supported but indicated paraphyly of Diseae, with Disperis sister to the rest, followed by successive divergence of Brownleea, Disinae, Coryciinae sensu stricto (s.s.), Satyriinae, and terminated by Orchidinae plus Habenariinae. Within the monophyletic Disinae, Herschelia and Monadenia were nested within a paraphyletic Disa and clustered with D. sect. Micranthae. Within monophyletic Satyriinae, Satyridium rostratum plus Satyrium bicallosum was sister to the rest of Satyrium, and then Satyrium nepalense plus S. odorum was distinct from a cluster of six species. Coryciinae are paraphyletic because Disperis is sister to all other core orchidoids. Coryciinae s.s. are sister to Satyriinae plus Orchideae, with Pterygodium nested within Corycium. Maximum likelihood analysis supported possible affinities among Disinae, Brownleeinae, and Coryciinae but did not support monophyly of Diseae or an affinity between Disinae and Satyriinae. Morphological characters are fully congruent with the well-supported groups identified in the ITS phylogeny.     

A phylogeny of Diprotodontia (Marsupialia) based on sequences for five nuclear genes

Even though the marsupial order Diprotodontia is one of the most heavily studied groups of Australasian marsupials, phylogenetic relationships within this group remain contentious. The more than 125 living species of Diprotodontia can be divided into two main groups: Vombatiformes (wombats and koalas) and Phalangerida. Phalangerida is composed of the kangaroos (Macropodidae, Potoroidae, and Hypsiprymnodontidae) and possums (Phalangeridae, Burramyidae, Petauridae, Pseudocheiridae, Tarsipedidae, and Acrobatidae). Much of the debate has focused on relationships among the families of possums and whether possums are monophyletic or paraphyletic. A limitation of previous investigations is that no study to date has investigated diprotodontian relationships using all genera. Here, we examine diprotodontian interrelationships using a nuclear multigene molecular data set representing all recognized extant diprotodontian genera. Maximum parsimony, maximum likelihood, and Bayesian methods were used to analyze sequence data obtained from protein-coding portions of ApoB, BRCA1, IRBP, Rag1, and vWF. We also applied a Bayesian relaxed molecular clock method to estimate times of divergence. Diprotodontia was rooted between Vombatiformes and Phalangerida. Within Phalangerida, the model-based methods strongly support possum paraphyly with Phalangeroidea (Burramyidae + Phalangeridae) grouping with the kangaroos (Macropodiformes) to the exclusion of Petauroidea (Tarsipedidae, Acrobatidae, Pseudocheiridae, and Petauridae). Within Petauroidea, Tarsipedidae grouped with both Petauridae and Pseudocheiridae to the exclusion of Acrobatidae. Our analyses also suggest that the diprotodontian genera Pseudochirops and Strigocuscus are paraphyletic and diphyletic, respectively, as currently recognized. Dating analyses suggest Diprotodontia diverged from other australidelphians in the late Paleocene to early Eocene with all interfamilial divergences occurring prior to the early Miocene except for the split between the Potoroidae and Macropodidae, which occurred sometime in the mid-Miocene. Ancestral state reconstructions using a Bayesian method suggest that the patagium evolved independently in the Acrobatidae, Petauridae, and Pseudocheiridae. Ancestral state reconstructions of ecological venue suggest that the ancestor of Diprotodontia was arboreal. Within Diprotodontia, the common ancestor of Macropodidae was reconstructed as terrestrial, suggesting that tree kangaroos (Dendrolagus) are secondarily arboreal.     

Molecular phylogeny and radiation time of Erysiphales inferred from the nuclear ribosomal DNA sequences

Phylogenetic relationships of Erysiphales within Ascomycota were inferred from the newly determined sequences of the 18S rDNA and partial sequences of the 28S rDNA including the D1 and D2 regions of 10 Erysiphales taxa. Phylogenetic analyses revealed that the Erysiphales form a distinct clade among ascomycetous fungi suggesting that the Erysiphales diverged from a single ancestral taxon. The Myxotrichaceae of the Onygenales was distantly related to the other onygenalean families and was the sister group to the Erysiphales calde, with which it combined to form a clade. The Erysiphales/Myxotrichaceae clade was also closely related to some discomycetous fungi (Leotiales, Cyttariales and Thelebolaceae) including taxa that form cleistothecial ascomata. The present molecular analyses as well as previously reported morphological observations suggest the possible existence of a novel evolutionary pathway from cleistothecial discomycetous fungi to Erysiphales and Myxotrichaceae. However, since most of these fungi, except for the Erysiphales, are saprophytic on dung and/or plant materials, the questions of how and why an obligate biotroph like the Erysiphales radiated from the saprophytic fungi remain to be addressed. We also estimated the radiation time of the Erysiphales using the 18S rDNA sequences and the two molecular clockes that have been previously reported. The calculation showed that the Erysiphales split from the Myxotrichaceae 190–127 myr ago. Since the radiation time of the Erysiphales does not exceed 230 myr ago, even when allowance is made for the uncertainty of the molecular clocks, it is possible to consider that the Erysiphales evolved after the radiation of angiosperms. The results of our calculation also showed that the first radiation within the Erysiphales (138–92 myr ago) coincided with the date of a major diversification of angiosperms (130–90 myr ago). These results may support our early assumption that the radiation of the Erysiphales coincided with the evolution of angiosperm plants. Contribution No. 152 from the Laboratory of Plant Pathology, Mie University     

Molecular phylogenetics of Phyllanthaceae: evidence from plastid MATK and nuclear PHYC sequences

Plastid matK and a fragment of the low-copy nuclear gene PHYC were sequenced for 30 genera of Phyllanthaceae to evaluate tribal and generic delimitation. Resolution and bootstrap percentages obtained with matK are higher than that of PHYC, but both regions show nearly identical phylogenetic patterns. Phylogenetic relationships inferred from the independent and combined data are congruent and differ from previous, morphology-based classifications but are highly concordant with those of the plastid gene rbcL previously published. Phyllanthaceae is monophyletic and gives rise to two well-resolved clades (T and F) that could be recognized as subfamilies. DNA sequence data for Keayodendron and Zimmermanniopsis are presented for the first time. Keayodendron is misplaced in tribe Phyllantheae and belongs to the Bridelia alliance. Zimmermanniopsis is sister to Zimmermannia. Phyllanthus and Cleistanthus are paraphyletic. Savia and Phyllanthus subgenus Kirganelia are not monophyletic.     

Turtle phylogeny: insights from a novel nuclear intron

Introns have gained considerable popularity as markers for molecular phylogenetics. However, no primers exist for a nuclear intron that amplifies across all turtles. Available data from morphology and mitochondrial DNA have not unambiguously resolved relationships within the superfamily Trionychoidea and the family Chelidae, which together form a large portion of extant turtle diversity. We tested the phylogenetic utility of a novel intron from the RNA fingerprint protein 35 (R35) as applied to these two areas of turtle systematics. We found the intron to be a single-copy locus that provides excellent resolving power for lineages among turtles, though problems with alignment made it impossible to infer deeper amniote relationships. Maximum parsimony and maximum likelihood both demonstrated the polyphyly of Trionychoidea and the reciprocal monophyly of Australian/New Guinea and South American chelid turtles. This is the first study to resolve such relationships with strong statistical support, and we suggest that R35 holds great promise for resolving additional persistent problems in the phylogeny of living turtles.     

裸子植物psbA基因分子进化式样的研究

为阐明裸子植物对陆生生境生态响应的分子机制,以新近的裸子植物分类系统为指导,基于psb A基因编码全序列对4亚纲53种代表植物进行分子进化分析。首先,依据"放松分子钟"模型重建裸子植物在时间尺度下系统发育关系;其次,采用6个模型(MEC/JTT、MEC/cp REV、M5、M7、M8、M8a)估测氨基酸位点ω值,并对各模型结果进行统计检测;随后,利用Bootstrap方法检PSBA蛋白内部氨基酸位点的共进化动态。结果表明,系统树提示的物种分化历程支持前期分类结果;光合系统反应中心核心PSBA蛋白有3个氨基酸位点(13、19和243)曾经受正选择压力;PSBA蛋白内部有多对氨基酸位点间构成了共进化网络。因此,psb A基因编码序列具有作为描绘裸子植物系统发育关系标记的潜力,PSBA蛋白部分位点经历了适应性进化,通过位点间共进化网络协同作用方式辅助裸子植物响应陆生生境。     

Molecular phylogenetics of subtribe Aeridinae (Orchidaceae): insights from plastid matK and nuclear ribosomal ITS sequences

We conducted phylogenetic analyses using two DNA sequence data sets derived from matK, the maturase-coding gene located in an intron of the plastid gene trnK, and the internal transcribed spacer region of 18S–26S nuclear ribosomal DNA to examine relationships in subtribe Aeridinae (Orchidaceae). Specifically, we investigated (1) phylogenetic relationships among genera in the subtribe, (2) the congruence between previous classifications of the subtribe and the phylogenetic relationships inferred from the molecular data, and (3) evolutionary trends of taxonomically important characters of the subtribe, such as pollinia, a spurred lip, and a column foot. In all, 75 species representing 62 genera in subtribe Aeridinae were examined. Our analyses provided the following insights: (1) monophyly of subtribe Aeridinae was tentatively supported in which 14 subclades reflecting phylogenetic relationships can be recognized, (2) results are inconsistent with previous classifications of the subtribe, and (3) repeated evolution of previously emphasized characters such as pollinia number and apertures, length of spur, and column foot was confirmed. It was found that the inconsistencies are mainly caused by homoplasy of these characters. At the genus level, Phalaenopsis, Cleisostoma, and Sarcochilus are shown to be non-monophyletic.     

Molecular phylogenetics of Fouquieriaceae: evidence from nuclear rDNA ITS studies

Molecular sequence data from the 18S-26S rDNA internal transcribed spacer (ITS) region support the monophyly of Fouquieria sensu lato (Fouquieriaceae) and the three subgenera (subg. Fouquieria, subg. Bronnia, subg. Idria) previously recognized within it. Resolution within subg. Fouquieria differs somewhat between parsimony and maximum likelihood (ML) trees. Section Fouquieria and sect. Ocotilla within subg. Fouquieria are not well supported as monophyletic groups. Uncertainty regarding placement of the root within Fouquieriaceae makes discussion of character evolution within the family difficult. Three root positions are consistent with rate-constant evolution of ITS sequences: (1) along the branch to subg. Idria, (2) along the branch to subg. Bronnia, and (3) along the branch to subg. Fouquieria. The first root position listed is equivalent to an outgroup rooting. The third root position listed is equivalent to a midpoint rooting. Of the three root positions above, only the third is along a branch that may be sufficiently long to act as a long-branch attractor. The first two root positions would result in character reconstruction suggesting that succulent growth forms and white floral pigmentation are ancestral within the family, with shifts to woody growth forms and to red floral pigmentation. The third root position results in equivocal reconstruction of the ancestral growth form, equivocal reconstruction of ancestral floral pigmentation in parsimony trees, and a suggestion of white floral pigmentation as ancestral in ML trees. Two previous hypotheses of polyploid origins are compatible with the molecular data presented here: (1) origin of the tetraploid F. diguetii from F. macdougalii, and (2) allopolyploid origin of the hexaploid F. burragei from the tetraploid F. diguetii and a diploid species similar to F. splendens. Direct descent of the hexaploid F. columnaris from the subg. Bronnia lineage is not supported by our data. An amphiploid origin of F. columnaris involving a member of the subg. Bronnia lineage and an extinct taxon outside subg. Bronnia, however, cannot be ruled out.