rbcL基因序列分析对连香树料和交让木科系统位置的重新评价—？…

测定了悬铃木科和金缕梅科５个亚科的６个代表种的ｒｂｃＬ基因序列,对低等金缕梅类植物及新近提出的相关类群进行了分子系统发育分析,获得４个最简约树。简约树步长为８９３,其ＣＩ值和ＲＩ值分别为０．５５８和０．５９１。连香树科和交让木科与金缕海科及虎耳草科关系较近。尽管增加了金缕梅科的取样密度,它们之间进一步的关系仍未得到分辨,结合它们的形态特征,连香树科和交让木科应置于金缕梅目内。ｒｂｃＬ基因树上反映出     

L基因序列分析对连香树科和交让木科系统位置的重新评价——兼论低等金缕梅类的关系

测定了悬铃木科和金缕梅科5个亚科的6个代表种的rbcL基因序列, 对低等金缕梅类植物及新近提出的相关类群进行了分子系统发育分析, 获得4个最简约树。 简约树步长为893, 其CI值和RI值分别为0.558和0.591。 连香树科和交让木科与金缕梅科及虎耳草科关系较近。 尽管增加了金缕梅科的取样密度, 它们之间进一步的关系仍未得到分辨, 结合它们的形态特征, 连香树科和交让木科应置于金缕梅目内。 rbcL基因树上反映出传统的“低等”金缕梅类成员领春木科与毛茛类植物聚在一起; 悬铃木科与昆栏树科和水青树科关系较近, 而与金缕梅科关系较远; 杜仲科与低等金缕类的核心科——金缕梅科的关系似乎较除连香树科之外的其它低等金缕类成员近。 低等金缕类植物由一些古老、孤立的科组成, 且是多系的。     

rbcL基因序列分析对连香树科和交让木科系统位置的重新评价——兼论低等金缕梅类的关系

测定了悬铃木科和金缕梅科５个亚科的６个代表种的ｒｂｃＬ基因序列,对低等金缕梅类植物及新近提出的相关类群进行了分子系统发育分析,获得４个最简约树。简约树步长为８９３,其ＣＩ值和ＲＩ值分别为０．５５８和０．５９１。连香树科和交让木科与金缕梅科及虎耳草科关系较近。尽管增加了金缕梅科的取样密度,它们之间进一步的关系仍未得到分辨,结合它们的形态特征,连香树科和交让木科应置于金缕梅目内。ｒｂｃＬ基因树上反映出传统的“低等”金缕梅类成员领春木科与毛茛类植物聚在一起;悬铃木科与昆栏树科和水青树科关系较近,而与金缕梅科关系较远;杜仲科与低等金缕类的核心科———金缕梅科的关系似乎较除连香树科之外的其它低等金缕类成员近。低等金缕类植物由一些古老、孤立的科组成,且是多系的。     

四药门花属及其近缘植物ITS区序列分析和系统学意义

测定和分析了四药门花等１３种金缕梅科（Ｈａｍａｍｅｌｉｄａｃｅａｅ）植物的核糖体ＤＮＡ转录间隔区（ＩＴＳ区）及５８Ｓ编码区的序列。应用最大简约法构建的分子系统树表明：被分析的金缕梅亚科（Ｈａｍａｍｅｌｉｄｏｉｄｅａｅ）植物形成一个单系类群,亚科内及其中的金缕梅族（Ｈａｍａｍｅｌｉｄｅａｅ）内部呈复系演化（ｐｏｌｙｐｈｙｌｅｔｉｃ）的特征;支持秀柱花族（Ｅｕｓｔｉｇｍａｔｅａｅ）（含秀柱花属Ｅｕｓｔｉｇｍａ、牛鼻栓属Ｆｏｒｔｕｎｅａｒｉａ和山白树属Ｓｉｎｏｗｉｌｓｏｎｉａ）成立以及将蚊母树族（Ｄｉｓｔｙｌｉｅａｅ）与弗特吉族（Ｆｏｔｈｅｒｇｉｌｅａｅ）合并的观点,此结果与Ｅｎｄｒｅｓ（１９８９）系统接近;金缕梅族中金缕梅属（Ｈａｍａｍｅｌｉｓ）与弗特吉族中的弗特吉属（Ｆｏｒｔｈｅｒｇｉｌａ）、银缕梅属（Ｓｈａｎｉｏｄｅｎｄｒｏｎ）和水丝梨属（Ｓｙｃｏｐｓｉｓ）系统发育关系密切;四药门花属（Ｔｅｔｒａｔｈｙｒｉｕｍ）与木属（Ｌｏｒｏｐｅｔａｌｕｍ）属于同一个单系类群,它们与Ｈａｍａｍｅｌｉｓ的亲缘关系较远     

红豆杉科植物RAPD分析及其系统学意义

利用随机扩增多态性ＤＮＡ（ＲＡＰＤ）技术分析了红豆杉科（Ｔａｘａｃｅａｅ）红豆杉属（Ｔａｘｕｓ）、白豆杉属（Ｐｓｅｕｄｏｔａｘｕｓ）、穗花杉属（Ａｍｅｎｔｏｔａｘｕｓ）和榧树属（Ｔｏｒｒｅｙａ）的６种植物：红豆杉（Ｔａｘｕｓ ｃｈｉｎｅｎｓｉｓ （Ｐｉｌｇｅｒ）Ｒｅｈｄ）、南方红豆杉（Ｔａｘｕｓ ｃｈｉｎｅｎｓｉｓ ｖａｒ．ｍａｉｒｅｉ（Ｌｅｍｅｅ ｅｔＬｅｖｌ．）Ｃｈｅｎｇ ｅｔＭａｉｒｅＹｅｗ     

三尖杉科植物RAPD分析及其系统学意义

利用随机扩增多态性ＤＮＡ（ＲＡＰＤ）技术分析了三尖杉科植物三尖杉Ｃｅｐｈａｌｏｔａｘｕｓ ｆｏｒｔｕｎｅｉ Ｈｏｏｋ．ｆ．、粗榧Ｃｅｐｈａｌｏｔａｘｕｓ ｓｉｎｅｎｓｉｓＬｉ、海南粗榧Ｃｅｐｈａｌｏｔａｘｕｓ ｈａｉｎａｎｅｎｓｉｓＬｉ和篦子三尖极Ｃｅｐｈａｌｏｔａｘｕｓ ｏｌｉｖｅｒｉＭａｓｔ。,经筛选Ｏｐｅｒｏｎ公司的４组８０个引物,其中１１４个引物的谱带清晰呈多态性。采用ＵＰＧＭＡ法对各样本     

基于matK基因和ITS序列探讨大叶藻科的系统发育关系

比较分析了15种大叶藻的matK基因和ITS片段的核苷酸序列, 结果发现胞嘧啶(C)在两个目的片段上含量均较低。ITS基因片段检测到228处核苷酸替换, 表现出丰富的遗传多态性; matK基因片段上有249处核苷酸替换, 且大部分替换来自于第三密码子的同义替换, 种间在氨基酸水平上产生了一定的分化。基于matK基因和ITS片段, 利用邻接法、最大简约法、最大似然法和贝叶斯法构建的系统发育树结果基本一致, 明显分为4大支, 大叶藻亚属、异叶藻属、拟大叶藻亚属和虾形藻属分别构成一支。大叶藻亚属和拟大叶藻亚属的核苷酸差异值在29.09%-35.51%, 超过了屈良鹄等提出的大部分被子植物ITS属间核苷酸差异值(9.60%-28.80%), 在分子数据上两亚属都达到了属的水平。研究结果支持Tomlinson和Posluszny对大叶藻科的划分结果, 建议将大叶藻科分为4个属。       

金缕梅亚科ITS序列分析及其系统学意义

根据金缕梅亚科22属（活塞花属Embolanthera除外）代表种的nrDNA ITS序列数据构建了分子系统树。结合形态解剖证据,金缕梅亚科可分为3个族,即①Ji木族LoropetaleaeZhangtrib.nov.,包括蜡瓣花属Corylopsis、Maingaya、Matudaea、活塞花属、四药门花属Tetrathyrium和Ji木属L;②DicorypheaeZhangtrib.nov.,包括毛枝花属Trichocladus、Dicoryphe、Neostrearia、Ostrearia、Noahdendron、秀柱花属Eustigma、牛鼻栓属Fortunearia、山白树属Sinowilsonia、Molinadendron;③金缕梅族Hamamelideae,包括Fothergilla、金缕梅属Hamamelis、Parrotiopsis、水丝利属Sycopsis、Parrotia、银缕梅属Shaniodendron、蚊母树属Distylium和拟母树属Distyliopsis。     

樟科润楠属植物ITS序列贝叶斯分析及其系统学意义

应用nrDNA Intemal Transcribed Spacer（ITS）序列,使用Bayesian分析法对樟科润楠属的系统学问题进行了初步探讨,结果表明润楠属在鳄梨属群中本身作为一独立分支,是一个自然的单系类群;由于其花被裂片果期宿存且强烈反转与同产自亚洲的楠属和油丹属存在清晰界线。本研究否定了前人依据花被片外面被毛情况及果实大小所建立的润楠属属下系统,但同时暗示着花序类型可能是解决润楠属下系统演化的关键性状。本研究对解决润楠属属内种间的系统演化关系尚有不足,建议今后补充更多的属内物种以及寻找新的分子标记进行更深入的研究。     

大熊猫及其近缘种rDNA序列变异和系统进化关系

应用ｒＤＮＡ间隔区Ｓｏｕｔｈｅｒｎ转换技术研究大熊猫及其近缘种的分子系统关系。通过比较大熊猫、小熊猫、黑熊、马来熊、浣熊和猞猁的ｒＤＮＡ间隔区限制性内切酶图谱,用最大似然法和简约法构建它们的分子系统树。结果表明大熊猫与熊具有较近的亲缘关系,与小熊猫和浣熊的亲缘关系较远。     

Molecular Phylogeny of Casuarinaceae Based on rbcL and matK Gene Sequences

rbcL (1310 bp) and matK (1014 bp), using 15 species representing the family. The study included analyses of Ticodendron (Ticodendraceae) and three species of Betulaceae as close relatives, and one species each of Juglandaceae and Myricaceae as outgroups. Analyses based on matK gene sequences, which provided a much better resolution than the analyses based on rbcL gene sequences alone, resulted in a single most parsimonious tree whose topology is almost identical with the strict consensus tree generated by the combined data set of rbcL and matK gene sequences. Results showed that Casuarinaceae are monophyletic, comprising four distinct genera, Allocasuarina, Casuarina, Ceuthostoma and Gymnostoma, which were not recognized until recently. Within the family, Gymnostoma is positioned at the most basal position and sister to the remainder. Within the remainder Ceuthostoma is sister to the Allocasuarina-Casuarina clade. Morphologically the basalmost position of Gymnostoma is supported by plesiomorphies such as exposed stomata in the shallow longitudinal furrows of the branchlets, a basic chromosome number x=8 and the gynoecium composed of two fertile, biovulate carpels. The three other genera, Allocasuarina, Casuarina, and Ceuthostoma, have invisible stomata in the deep longitudinal furrows of the branchlets, a higher basic chromosome number x=9 or 10–14 (unknown in Ceuthostoma), the gynoecium composed of one fertile and one sterile carpel with a single ovule (unknown in Ceuthostoma). The diversity of infructescence morphology found in the latter three genera suggests that they may have evolved in close association with the elaboration of fruit dispersal mechanisms. Received 14 September 2001/ Accepted in revised form 12 October 2001     

Molecular Systematics of Trilliaceae I. Phylogenetic Analyses of Trillium Using matK Gene Sequences

matK was conducted using 41 Trillium taxa and two out-group taxa (Veratrum maackii and Helonias bullata). A total of 1608 base pairs were analyzed and compared., and then there were 61 variable (36 informative) sites among Trillium species. Fifteen insertion/deletion events (indels) of six or fifteen base pairs were also detected. Phylogenetic analyses of the sequence data revealed that the subgenus Phyllantherum (sessile-flowered species) forms a distinct monophyletic group, whereas the subgenus Trillium (pedicellate-flowered species) does not form a monophyletic group, and is composed of three distinct groups and three basally located species in the tree: (1) the Erectum group, (2) the Grandiflorum group, and (3) the Pusillum group and (4) the three species, including T. govanianum, T. undulatum, and T. rivale. T .rivale appears to be the most basally diverged and a very specialized taxon among the ingroup members. Our matK data indicated that the closest relative of the subgenus Phyllantherum is the Grandiflorum group. The results are concordant with the results of the RFLP analysis of cpDNA and also more or less with those of the cladistic analysis of morphological characters. Received 11 September 1998/ Accepted in revised form 25 December 1998     

Phylogenetic Relationships of Amaryllidaceae Based on matK Sequence Data

matK gene, which is located in the chloroplast genome and evolves more quickly than the rbcL gene. A total of 31 species representing 31 of the 59 genera in the family were examined in this study. We also used 21 species from another ten families of Asparagales, four species from three families of Liliales and Acorus as outgroups. We obtained partial sequences of matK with lengths of 1,109–1,148 bp, corresponding to positions 230 to 1,343 of the Oryza sativa matK gene. The pairwise percentage sequence divergence ranged from 0 to 19.1% for all the species examined except Acorus, and 0 to 4.6% within Amaryllidaceae. Two methods of phylogenetic analysis, the Maximum Parsimony and Neighbor-Joining methods, were used. The trees obtained from these two analyses were fundamentally consistent. In both trees, the Amaryllidaceae sensu Dahlgren et al. formed a well-supported monophyletic clade with 100% bootstrap support. Amaryllidaceae were included in the Asparagales; however, its phylogenetic position within the Asparagales was not clearly resolved. Judging from the NJ tree, Agapanthus might be a sister group of the Amaryllidaceae, although bootstrap support for this was low. Character-state mapping was used to infer a center of origin and the biogeographic history of Amaryllidaceae. The result supports the hypothesis that the family evolved in Africa and subsequently spread to other continents, further suggesting that South America is the center of secondary diversification. Received 6 January 1999/ Accepted in revised form 8 April 1999     

基于ITS和matK序列的獐牙菜亚族 (龙胆科龙胆族)分子系统学

为探讨獐牙菜亚族（subtribe Swertiinae）各属之间和一些属内的系统关系,本研究选取了该亚族14属68种1变种,采用最大简约法（maximum parsimony）和贝叶斯法（Bayesian inference）对样品核基因ITS和叶绿体基因matK的两个片段进行独立和联合分析。结果显示：Bartonia位于亚族的最基部;喉毛花属（Comastoma）、肋柱花属（Lomatogonium）和假龙胆属（Gentianella）都非单系,处于同一个较为进化的分支中;獐牙菜属折皱组（Swertia sect. Rugosa）和獐牙菜组（S. sect. Swertia）亲缘关系最近,宽丝组（S. sect. Platynema）和藏獐牙菜组（S. sect. Kingdon Wardia）亲缘关系最近;口药花属（Jaeschkea）与獐牙菜属多枝组（S. sect. Ophelia）的大籽獐牙菜（Smacrosperma）亲缘关系最近。同时讨论了獐牙菜亚族形态分类与分子数据不一致的原因。     

Monophyly and generic relationships of polemoniaceae based on matK Sequences

Polemoniaceae are often considered a model family for studying evolutionary processes, yet a reliable phylogeny for the family is only now beginning to emerge. To test the monophyly of this family and to elucidate intergeneric relationships, we employed comparative sequencing of the chloroplast gene matK. Parsimony analysis of matK sequences representing 18 genera of Polemoniaceae and nine families from Asteridae sensu lato places Polemoniaceae apart from Solanaceae near Fouquieriaceae, Ericaceae, Sarraceniaceae, and Diapensiaceae. Both this and a subsequent analysis of 59 species of Polemoniaceae indicate that Cobaea is derived from within Polemoniaceae, rather than being the sister to Polemoniaceae as suggested by some authors. The tropical genera Bonplandia, Cantua, and Cobaea form a clade, and the remaining, primarily temperate genera, excluding Acanthogilia, form a second monophyletic group. Acanthogilia is placed ambiguously as sister to either the tropical or temperate groups depending on the location of the root for Polemoniaceae. Within the temperate lineage, Polemonium is sister to three large clades: a well-supported clade comprising Phlox, Gymnosteris, Linanthus, Leptodactylon, and Gilia filiformis; a moderately well-supported clade comprising Allophyllum, Collomia, Navarretia, and several species of Gilia; and a weakly supported clade comprising Eriastrum, Ipomopsis, Langloisia, Loeseliastrum, Loeselia, and several species of Gilia. In addition to revealing the extreme polyphyly of Gilia, this analysis suggests that Ipomopsis and Linanthus are also polyphyletic.     

Phylogenetic Relationships of Citrus and Its Relatives Based on matK Gene Sequences

The genus Citrus includes mandarin, orange, lemon, grapefruit and lime, which have high economic and nutritional value. The family Rutaceae can be divided into 7 subfamilies, including Aurantioideae. The genus Citrus belongs to the subfamily Aurantioideae. In this study, we sequenced the chloroplast matK genes of 135 accessions from 22 genera of Aurantioideae and analyzed them phylogenetically. Our study includes many accessions that have not been examined in other studies. The subfamily Aurantioideae has been classified into 2 tribes, Clauseneae and Citreae, and our current molecular analysis clearly discriminate Citreae from Clauseneae by using only 1 chloroplast DNA sequence. Our study confirms previous observations on the molecular phylogeny of Aurantioideae in many aspects. However, we have provided novel information on these genetic relationships. For example, inconsistent with the previous observation, and consistent with our preliminary study using the chloroplast rbcL genes, our analysis showed that Feroniella oblata is not nested in Citrus species and is closely related with Feronia limonia. Furthermore, we have shown that Murraya paniculata is similar to Merrillia caloxylon and is dissimilar to Murraya koenigii. We found that “true citrus fruit trees” could be divided into 2 subclusters. One subcluster included Citrus, Fortunella, and Poncirus, while the other cluster included Microcitrus and Eremocitrus. Compared to previous studies, our current study is the most extensive phylogenetic study of Citrus species since it includes 93 accessions. The results indicate that Citrus species can be classified into 3 clusters: a citron cluster, a pummelo cluster, and a mandarin cluster. Although most mandarin accessions belonged to the mandarin cluster, we found some exceptions. We also obtained the information on the genetic background of various species of acid citrus grown in Japan. Because the genus Citrus contains many important accessions, we have comprehensively discussed the classification of this genus.     

金粉蕨属的分子系统学研究——基于5种叶绿体DNA序列片段

金粉蕨属（Onychium Kaulfuss）隶属广义凤尾蕨科中的凤尾蕨亚科。迄今为止,该属属下分组及种间界定等仍有诸多问题亟待解决。本研究选取5个叶绿体DNA 序列片段 （rbcL/atpA/matK/trnL-trnF/trnG-trnR）,采用最大似然法（ML）和贝叶斯法（BI）构建金粉蕨属的系统发育树。结果表明：（1）金粉蕨属的9个成员被分置于两大支上。其中野雉尾金粉蕨（Onychium japonicum(Thunberg) Kunze）、西藏金粉蕨（O.tibeticum Ching & S.K.Wu）、木坪金粉蕨（O.moupinense Ching）、湖北金粉蕨（O.moupinense var. ipii(Ching) K.H.Shing）、栗柄金粉蕨（O.japonicum var. lucidum(D.Don) Christ）、黑足金粉蕨（O.cryptogrammoides Christ）、繁羽金粉蕨（O.plumosum Ching）聚为一支;而金粉蕨（O.siliculosum(Desvaux) C.Christensen）和蚀盖金粉蕨（O.tenuifrons Ching）则聚为另一支,可为该属的属下分组提供分子系统学证据;（2）野雉尾金粉蕨与栗柄金粉蕨在系统树中并没有聚在一起,而是被其它类群分割开来,不支持将后者作为野雉尾金粉蕨的变种,建议将栗柄金粉蕨提升为种的等级;（3）系统树上木坪金粉蕨与湖北金粉蕨的样本聚在一个细支上,支持《中国植物志》将湖北金粉蕨作为木坪金粉蕨变种的分类处理;（4）西藏金粉蕨与野雉尾金粉蕨聚在一起,并得到较高的支持,说明两者的关系近缘。     

A Revaluation of the Systematic Positions of the Cercidiphyllaceae and Daphniphyllaceae Based on rbcL Gene Sequence Analysis,with Reference to the Relationship in the “Lower” Hamamelidae

The rbcL gene sequences of six species representing five subfamilies of the Hamamelidaceae and the Platanaceae were determined and used in the phylogenetic analysis on the “lower” Hamamelidae sensu Endress (1989) and its allies newly suggested. Four most parsimonious trees were obtained, all having 893 steps with CI = 0.558 and RI = 0.591. The families Cercidiphyllaceae, Daphniphyllaceae, Hamamelidaceae and Saxifragaceae are closely located, while the relationships among them remain unsolved even if more representatives of the Hamamelidaceae were further added in this parsimony analysis. Our results confirm the phylogenetic trees revealed by Chase et al. (1993) and Soltis et al. (1997), instead of those of Hoot and Crane (1996). Considering the morphological features they share, it is suggested that the Cercidiphyllaceae and Daphniphyllaceae be placed into the Hamamelidales. The relationship between the Platanaceae and the Hamamelidaceae shown in our analysis is not so closed as suggested by the cladistic analyses by using morphological characters only(e.g. Lu et al., 1991), while those among the Platanaceae, Trochodendraceae and Tetracentraceae are close as indicated by this study. The Eupteleaceae falls into the Ranunculales. The Eucommiaceae seems to show closer relationship with the Hamamelidaceae, the “core” family of the “lower” Hamamelidae, than with the other members except the Cercidiphyllaceae. The rbcL gene trees imply that the “lower” Hamamelidae is a heterogeneous group,composed of isolated ancient families.     

Phylogenetic relationships of the Magnoliaceae inferred from cpDNA matK sequences

The coding region of the matK gene was sequenced to infer the phylogeny of the family Magnoliaceae. Phylogenetic analyses of 21 matK sequences representing ten genera of Magnoliaceae and three outgroups suggest relationships among both subfamilies and genera. Monophyly of the subfamily Liriodendroideae (the genus Liriodendron) and the subfamily Magnolioideae is strongly supported, respectively. Within the subfamily Magnolioideae, three clades are formed: (1) the genus Magnlietia, (2) the subgenus Magnolia, and (3) the subgenus Yulania, with the genera Michelia, Paramichelia, Tsoongiodendron, Alcimandra, Kmeria, Parakmeria and Manglietiastrum. However, the genus Magnolia is shown to be a polyphyletic group, and the genus Michelia a paraphyletic group. Relatively low sequence divergences are detected among genera of the the subfamily Magnolioideae, ranging from 0.14% to 1.70%, especially in the tribe Micheliinae (0.14–0.98%). Molecular evidence from matK sequence data suggests that the phylogenetic positions and the delimitation of the eight genera Magnolia, Michelia, Tsoongiodendron, Paramichelia, Alcimandra, Kmeria, Parakmeria and Manglietiastrum need to be reconsidered. Received: 2 January 2000 / Accepted: 12 February 2000     

基于线粒体细胞色素b基因序列的雀形目18种鸟系统发育关系

采用线粒体细胞色素b(cytochrome b)基因,利用DNA测序的方法研究了雀形目18种鸟类的分子系统发育关系。通过序列分析比对,运用邻接法和最大似然法构建了雀形目18种鸟类的系统发育树,结果表明,燕雀类和类的分歧程度达到了科级水平,建议分别独立成科;长尾山雀可从山雀科中分离出来,单列成科;柳莺归入柳莺亚科(Phylloscopinae),树莺归入大苇莺亚科(Acrocephalinae)。Cytb基因的各主要分支中存在着相对恒定的分子钟,根据鸟类mtDNA的cytb进化速度大约是每百万年1.6%,得到18种鸟的科间分歧时间在10.5百万年左右,科内分歧在9.0百万年左右。