国产木兰科6属植物柱头表面形态比较

用扫描电镜对中国产木兰科单性木兰属、木兰属、木莲属、含笑属、拟单性木兰属和观光木属的42种植物柱头表面形态进行观察.结果表明,42种木兰科植物的柱头均为干柱头,包含单细胞乳突型和多细胞乳突型两类.单性木兰属和观光木属植物是单细胞乳突型;木莲属、含笑属和拟单性木兰属植物是多细胞乳突型;木兰属中木兰亚属植物两型均有,而玉兰亚属则均为多细胞乳突型.结合其他证据,本文支持单性木兰属、木莲属、含笑属、拟单性木兰属和观光木属的建立,并认为在系统学问题较复杂的木兰属中,玉兰亚属是一个相对独立的单系类群,将其独立成属也不无道理,而木兰亚属可能不是一个单系类群,还需要进一步的深入研究,积累更多的性状数据.     

木兰科植物染色体数目报道

木兰科5种（含笑属4种、木莲属1种）、1杂交种植物染色体基数均为x=19,且都是二倍体2n=38,未见多倍体和非整倍体.其中4种和1杂交种的染色体数目为首次报道.     

中国木兰科各属次生木质部的解剖特征及系统演化

综述了中国木兰科10属的次生木质部解剖学特征,包括导管分子,纤维管胞和木射线。同时,进一步讨论了其系统演化。这10属分为两亚科,即:木兰亚科(Magnoliodeae),包括木兰族(Magnolieae)和含笑族(Michelieae Law),木兰族有木莲属(Maglietia Bl.)、华盖木属(Manglietiastrum Law)、木兰属(Magnolia L.)、拟单性木兰属(Parakmeria Hu et Cheng)、单性木兰属[Kmeria(Pierre) Dandy]、长蕊木兰属(Alcimandra Dandy)共六属;含笑族有含笑属(Michelia L.)、合果木属(Paramichelia Hu)、观光木属(Tsoongiodendron Chun)共三属。鹅掌楸亚科[Liriodendroideae(Bark) Law],仅鹅掌楸属(Liriodendron L.)一属。大量的木材解剖学研究表明,木兰科的原始性很明显,但也有一些进化特征。可以通过属间的差别来分析本科的系统演化。木兰科的系统演化可简单总结为:木兰亚科[木兰族(木莲属,华盖木属,拟单性木兰属,单性木兰属→木兰属,长蕊木兰属)→含笑族]→鹅掌楸亚科。     

木兰科种子内种皮合点区形态及其系统学意义

在扫描电镜下系统研究了木兰科10属52种成熟种子内种皮合点区形态。该形态分为孔型和管型两大类。孔型为内种皮合点区具一小穿孔。木莲属Manglietia、香木兰属Aromadendron、盖裂木属Talauma(8种)、南洋含笑属Elmerrillia和鹅掌楸属Liriodendron具此类型。管型由内种皮合点区向下凹陷形成的小窝和由窝底向外伸出的小管组成。华盖木属Manglietiastrum、盖裂木属Talauma(3种)、长蕊木兰属Alcimandra、含笑属Michelia、合果木属Paramichelia和观光木属Tsoongiodendron具此类型。在木兰属部分种中还观察到两种形态之间的过渡类型。上述形态特征在属内稳定并为木兰科植物所特有,而且明显表现出原始类群的合点区形态大多为孔型,进化类群的合点区形态大多为管型的特点。     

铁线莲属21个类群的染色体核型分析

铁线莲属(Clematis L.)为毛茛科大属之一,具有重要的园艺与药用价值。为探讨铁线莲属植物染色体组演化规律,揭示属下组间及种间的亲缘关系,该研究采用常规压片法对铁线莲属21个类群的根尖进行处理、压片,对染色体的形态特征进行观察及核型分析,同时利用Ward联接法进行聚类分析研究。狭裂太行铁线莲、毛果扬子铁线莲、卷萼铁线莲、中印铁线莲、钝萼铁线莲的染色体形态为首次报道。结果表明:铁线莲属21个类群均为二倍体,染色体数均为16(2n=2x=16),除中印铁线莲外其他类群均具随体;长瓣铁线莲、钝萼铁线莲、芹叶铁线莲、褐毛铁线莲、C.flammula、毛果扬子铁线莲的染色体为“2B”型,其他类群染色体为“2A”型;铁线莲属核型不对称系数在60.29%~63.79%之间;铁线莲属植物染色体组表现的较为原始,种间核型存在广泛变异。综上结果表明,铁线莲属植物染色体数目应由二倍体向多倍体演化后通过多倍体的二倍化过程产生非整倍体方向演化。铁线莲属染色体的演化主要在二倍体水平上进行,通过产生染色体结构变异的方式实现,通过产生杂合染色体、加强核型不对称性、染色体类型改变以及随体染色体的变化四种途径进化。同时,核型特征在分组水平与物种水平上的划分与传统分类基本一致,说明核型分析可为铁线莲属下组一级分类提供一定的线索。该研究结果为铁线莲属植物系统分类、遗传演化与资源利用等研究领域提供了新的参考资料。     

云南部分木兰科植物染色体数目报道

木兰科是有花植物中最原始的科之一,有15属约250种。其中,我国有11属90多种。研究木兰科的染色体对植物的系统分类、植物进化及开花植物的起源有很重要的作用。但由于木兰科的染色体较小,细胞去壁较困难,所以对木兰科染色体的研究进行较缓慢。Whitaker (1933)首次对木兰属(Magnolia)进行细胞学研究发现,木兰科染色体基数为x=19。Janaki Ammal (1952)报道,在木兰科中,除木兰属外,     

木兰科植物的杂交亲和性

采用常规杂交育种的方法,在木兰科属内和属间进行了62杂交试验,结果表明,除木兰属的木兰亚属和玉兰亚属之间没有杂交亲和性外,木兰科其他属内都有杂交亲和性,这表明属内不存在生殖隔离,除拟单性木兰属与木兰属的木兰亚属之间有杂交亲和性外,其它属间都没有杂交亲和性,这表明这些属间存在着生殖隔离,因此,木兰科植物的杂交亲和性基本上支持根据形态特征所建立的木兰科科下分类系统,同时,建议将拟单性木兰属与木兰属的木兰亚属合并为木兰属,并将玉兰亚属从木兰属中分出作为玉兰属。     

木兰科植物的人工杂交

采用常规人工杂交方法,在木兰科中进行了68个组合杂交试验。结果表明：花粉活力随种类不同有很大差异,人工授粉后结实率很高,小孢子败育不是木兰科植物自然结实率普遍低的主要原因。木兰亚属种间杂交均表现为亲和,含笑属有些种间杂交不亲和;属间杂交多不亲和,但红元宝二乔玉兰与金叶含笑和云南含笑的杂交完全亲和,结实率高达80％～100％,表明玉兰亚属和含笑属间有较近的亲缘关系;观光木与金叶含笑、云南含笑虽有较高的杂交结实率,但杂交种子不能萌发,支持观光木属成立。     

用matK序列分析探讨木兰属植物的系统发育关系

用木兰科Magnoliaceae 57种植物的matK基因序列构建了该科的系统发育分支图。结果表明: (1)木兰属Magnolia L.是一个因为性状的趋同演化而建立的多系类群; (2)木兰亚属subgen. Magnolia和玉兰亚属subgen. Yulania (Spach) Reichenb.亲缘关系较远, 支持将后者从该属中分出建立玉兰属Yulania Spach, 木兰亚属作为木兰属保留; (3)木兰亚属的sect. Splendentes Dandy ex Vazquez组与皱种组sect. Rytidospermum Spach的两个美洲种M. macrophylla Michaux和M. dealbata Zucc.亲缘关系较近, 荷花玉兰组sect. Theorhodon Spach与常绿组sect. Gwillimia DC.的亲缘关系较近; (4)盖裂木属Talauma Juss.可以成立, 而其分布于亚洲的Blumiana Blume组可归入木兰属; (5)拟单性木兰属Parakmeria Hu &; Cheng、华盖木属Manglietiastrum Law以及单性木兰属Kmeria (Pierre) Dandy形成一个单系群, 与玉兰亚属和含笑属Michelia L.的亲缘关系较近。花的着生位置不足以作为木兰科的分族依据, 含笑族Michelieae和木兰族Magnolieae的特征及其界定应做修改。将玉兰亚属从木兰属分出后, 木兰属与含笑属无性状交叉,成为两个区别明显的属。     

国产12种乌头属和18种翠雀属植物的细胞学研究

研究了12种乌头属Aconitum L．和18种翠雀属Delphinium L．植物的染色体。在12种乌头属植物中,除粗花乌头A．crassiflorum为四倍体(2n=4x=32)外,其他种类都为二倍体(2n=2x＝16),中甸乌头 A.piepunense中有B染色体存在,牛扁亚属Aconitum subgen．Lycoctonum的二倍体植物与乌头亚属Aconitum subgen．Aconitum 植物的染色体在大小和形态上有明显区别;所有18种翠雀属植物都为二倍体(2n＝2x=16),其染色体在大小和形态上极为相似,但与乌头亚属的染色体易于区别。翠雀属植物的核型不对称性程度明显高于乌头属植物,因此从染色体证据来看,翠雀属要比乌头属进化。     

Genome differentiation in Magonoliaceae as revealed from meiotic pairing in interspecific and intergeneric hybrids

The cross compatibility within and between Yulania Spach and Michelia L.(Magnoliaceae) is relatively good and various such hybrids,obtained by conventional artificial hybridization,are available.The aim of the present study was to determine the extent of genome differentiation between the species involved in these crosses through the observation of chromosome pairing during meiosis in pollen mother cells (PMCs) of the hybrids.Chromosome pairing behavior was studied in five species (2n =38) and two interspecific hybrids of Michelia,eight species (2n =38,76 and 114) and 10 interspecific hybrids of Yulania,and three intergeneric hybrids between Michelia and Yulania.The results showed that chromosome pairing was normal with bivalent formation in diploid parental species and in interspecific hybrids.In addition to bivalents,multivalents were encountered in polyploid parental species and polyploid interspecific hybrids.In the intergeneric hybrids between a tetraploid Yulania and two diploid Michelia,19 chromosomes,most likely originating from Michelia,were unable to synapse from zygotene to metaphase I.Meiotic chromosome pairing indicated a high degree of homology between species within Michelia and Yulania and less homology between the genomes of these two genera.The differentiation of morphological characters and the distinctness of natural distribution also support the conclusion that these two genera are likely independent monophyletic groups.This suggests that the two genera were split at early evolution of Magnoliaceae and the overlapping characteristics in external morphology and internal structures of the two genera may be the result of parallel evolution or ancient common ancestry.     

Phylogenetic relationships in family Magnoliaceae inferred from ndhF sequences

The ndhF sequences of 99 taxa, representing all sections in extant Magnoliaceae, were analyzed to address phylogenetic questions in the family. Magnolia macrophylla and M. dealbata, North American species of Magnolia section Rytidospermum, are placed at the base in the subfamily Magnolioideae although its supporting value is low. In the remaining taxa, several distinctive lineages are recognized: (1) Magnolia, the biggest genus in the family, is not monophyletic; (2) Michelia, including section Maingola of Magnolia subgenus Magnolia, is closely related with Elmerrillia and sections Alcimandra and Aromadendron of Magnolia subgenus Magnolia; (3) the associates of Michelia are grouped with Magnolia subgenus Yulania and section Gynopodium of Magnolia subgenus Magnolia; (4) Pachylarnax forms a clade with sections Manglietiastrum and Gynopodium of Magnolia; (5) a well-supported Manglietia clade is recognized; (6) Caribbean species of section Theorhodon of Magnolia subgenus Magnolia, which are section Splendentes sensu Vázquez-Garcia, are closely allied with New World members of Magnolia subgenus Talauma; and (7) section Rytidospermum of Magnolia subgenus Magnolia and subgenus Talauma are polyphyletic. The separated clades in the molecular tree are considerably different from traditional taxonomic dispositions in the family. The molecular data strongly suggest that a taxonomic realignment of infrafamilial delimitations and compositions should be considered.     

木兰科的分支分析

主要以形态学、解剖学、细胞学为依据,以德坚木属为外类群,用分支分析的方法探讨了木兰科属间的系统发育关系。有２３个分支单位,选取３２个性状,根据外类群比较原则和化石地层学资料,确定了性状的祖征和衍征。对数据矩阵的分支分析使用ＰＡＵＰ３．１．１和Ｈｅｎｎｉｇ ８６ ｖ．１．５分别在Ｍａｃｉｎｔｏｓｈ和ＩＢＭ机上运行,前者以启发法,后者以ＢＢ命令运算,经严格一致化处理,得到一致化分支图。结果表明：１）木     

中国木兰科植物修订

对中国产的木兰科植物３个大属即木莲,木兰和含笑进行了分类修订工作,共提出新组合５个,新异名８个,澄清２种和１亚种。     

A Preliminary Study on the Taxonomy of the Family Magnoliaceae

A new system of classification of Magnoliaceae proposed. This paper deals mainly with taxonomy and phytogeography of the family Magnoliaceae on the basis of external morphology, wood anatomy and palynology. Different authors have had different ideas about the delimitation of genera of this family, their controversy being carried on through more than one hundred years (Table I). Since I have been engaged in the work of the Flora Reipublicae Popularis Sinicae, I have accumulated a considerable amount of information and material and have investigated the living plants at their natural localities, which enable me to find out the evolutionary tendencies and primitive morphological characters of various genera of the family. According to the evolutionary tendencies of the characters and the geographical distribution of this family I propose a new system by dividing it into two subfamilies, Magnolioideae and Liriodendroideae Law (1979), two tribes, Magnolieae and Michelieae Law, four subtribes, Manglietiinae Law, Magnoliinae, Elmerrilliinae Law and Micheliinae, and fifteen genera (Fig. 1 ), a system which is different from those by J. D. Dandy (1964-1974) and the other authors. The recent distribution and possible survival centre of Magnoliaceae. The members of Magnoliaceae are distributed chiefly in temperate and tropical zones of the Northern Hemisphere, ——Southeast Asia and southeast North America, but a few genera and species also occur in the Malay Archipelago and Brazil of the Southern Hemisphere. Forty species of 4 genera occur in America, among which one genus (Dugendiodendron) is endemic to the continent, while about 200 species of 14 genera occur in Southeast Asia, of which 12 genera are endemic. In China there are about 110 species of 11 genera which mostly occur in Guangxi, Guangdong and Yunnan; 58 species and more than 9 genera occur in the mountainous districts of Yunnan. Moreover, one genus (Manglietiastrum Law, 1979) and 19 species are endemic to this region. The family in discussion is much limited to or interruptedly distributed in the mountainous regions of Guangxi, Guangdong and Yunnan. The regions are found to have a great abundance of species, and the members of the relatively primitive taxa are also much more there than in the other regions of the world. The major genera, Manglietia, Magnolia and Michelia, possess 160 out of a total of 240 species in the whole family. Talauma has 40 species, while the other eleven genera each contain only 2 to 7 species, even with one monotypic genus. These three major genera are sufficient for indicating the evolutionary tendency and geographical distribution of Magnoliaceae. It is worthwhile discussing their morphological characters and distributional patterns as follows: The members of Manglietia are all evergreen trees, with flowers terminal, anthers dehiscing introrsely, filaments very short and flat, ovules 4 or more per carpel. This is considered as the most primitive genus in subtribe Manglietiinae. Eighteen out of a total of 35 species of the genus are distributed in the western, southwest to southeast Yunnan. Very primitive species, such as Manglietia hookeri, M. insignis and M. megaphylla, M. grandis, also occur in this region. They are distributed from Yunnan eastwards to Zhejiang and Fujian through central China, south China, with only one species (Manglietia microtricha) of the genus westwards to Xizang. There are several species distributing southwards from northeast India to the Malay Archipelago (Fig. 7). The members of Magnolia are evergreen and deciduous trees or shrubs, with flowers terminal, anthers dehiscing introrsely or laterally, ovules 2 per carpel, stipule adnate to the petiole. The genus Magnolia is the most primitive in the subtribe Magnoliinae and is the largest genus of the family Magnoliaceae. Its deciduous species are distributed from Yunnan north-eastwards to Korea and Japan (Kurile N. 46’) through Central China, North China and westwards to Burma, the eastern Himalayas and northeast India. The evergreen species are distributed from northeast Yunnan (China) to the Malay Archipelago. In China there are 23 species, of which 15 seem to be very primitive, e.g. Magnolia henryi, M. delavayi, M. officinalis and M. rostrata, which occur in Guangxi, Guangdong and Yunnan. The members of Michelia are evergreen trees or shrubs, with flowers axillary, anthers dehiscing laterally or sublaterally, gynoecium stipitate, carpels numerous or few. Michelia is considered to be the most primitive in the subtribe Micheliinae, and is to the second largest genus of the family. About 23 out of a total of 50 species of this genus are very primitive, e.g. Michelia sphaerantha, M. lacei, M. champaca, and M. flavidiflora, which occur in Guangdong, Guangxi and Yunnan (the distributional center of the family under discussion) and extend eastwards to Taiwan of China, southern Japan through central China, southwards to the Malay Archipelago through Indo-China. westwards to Xizang of China, and south-westwards to India and Sri Lanka (Fig. 7). The members of Magnoliaceae are concentrated in Guangxi, Guangdong and Yunnan and radiate from there. The farther away from the centre, the less members we are able to find, but the more advanced they are in morphology. In this old geographical centre there are more primitive species, more endemics and more monotypic genera. Thus it is reasonable to assume that the region of Guangxi, Guangdong and Yunnan, China, is not only the centre of recent distribution, but also the chief survival centreof Magnoliaceae in the world.     

国产木兰科含笑亚族植物的叶结构及其分类学意义

为了探讨含笑亚族Micheliinae植物属间关系以及含笑属Michella属下等级的划分和一些种的分类学地位,利用放大镜和体视镜对国产含笑亚族植物3属共28个分类群的叶结构特征进行了观察与研究。结果表明：含笑属、合果木属Paramichelia和观光木属Tsoongiodendron植物的脉序类型、一级脉、二级脉及其间脉和三级脉等特征表现出较高的一致性,三属间无明显的划分界限;但是,盲脉及其分支、网眼的发育和大小、叶缘末级脉等叶结构特征存在种间差异。在含笑属中,树状盲脉首次被观察到。用UPGMA对所研究28个分类群、木兰属Magnolia两个亚属各2种和鹅掌楸Liriodendron chinense的叶结构特征和形态学特征共46个性状进行聚类分析。分析结果表明：（1）合果木Pbaillonii和观光木T.odorum与含笑属的种聚为一支,因此,支持将合果木属和观光木属归并入含笑属;（2）这些特征为含笑属内组的划分提供了分类学意义;（3）基于叶结构特征、形态学特征、地理分布、聚类分析,对含笑属内一些种类的分类地位进行了讨论。     

Sclerotesta morphology and its systematic implications in magnoliaceous seeds

Seeds of 101 species from 14 genera were observed using stereoscopic and scanning electron microscopy. Sclerotesta morphology is stable within the genera of Magnoliaceae. Two different morphological types are described according to features of the chalazal region, which have great value in classification and have been found only in Magnoliaceae. One is the pore type, characterized by being simple, observed in the relatively primitive taxa of this family, including Manglietia, Pachylarnax, Magnolia (19 species), Aromadendron, Talauma (eight species), Parakmeria (one species), Kmeria (one species), Elmerrillia and Liriodendron . The other one is the tube type, which is characterized by having a more complex structure consisting of a central hollow tube contained within a hole. This type was observed in relatively advanced taxa, including Manglietiastrum, Magnolia (15 species), Talauma (three species), Parakmeria (four species), Kmeria (one species), Alcimandra, Michelia, Paramichelia and Tsoongiodendron . Transitional types between these two were observed in some species of Magnolia . Chalazal region morphology, together with other useful sclerotesta characters, including seed size, shape, the raphal sinus and the external surface of the sclerotesta, may be used as diagnostic characteristics of genera, and even species in Magnoliaceae. A key to identify the different genera is supplied.  © 2003 The Linnean Society of London, Botanical Journal of the Linnean Society , 2003, 142 , 407–424.