西藏豆科植物区系的形成与分化

 Xizang (Tibet) is rich in Leguminosae flora, comprising 41 genera and 254 species so far known, exclusive of the commonly cultivated taxa (including 11 genera and 16 species). There are 4 endemic genera (with 8 species), 10 temperate genera (with 175 species) and 19 tropical genera (with 46 species) as well as the representatives of those genera whose distribution centers are in East Asia-North  America, Mediterranean and Central Asia.       1.  There are altogether 4 endemic genera of Leguminosae in this region. Accord- ing to their morphological characters, systematic position and geographical distribution, it would appear that Salweenia and Piptanthus are Tertiary paleo-endemics, while Straceya and Cochlianths are neo-endemics. Salweenia and Piptanthus may be some of more primitive members in the subfamily Papilionasae and their allies are largely distributed in the southern Hemisphere.  The other two genera might have been derived from the northern temperate genus Hedysarum and the East Asian-North American genus Apios respectively, because of their morphological resemblance. They probably came into existanc during the uplifting of the Himalayas.       2. An analysis of temperate genera       There are twelve temperate genera of Leguminosae in the region, of which the more important elements in composition of flora, is Astragalus, Oxytropis and Cara- gana.       Astragalus  is a  cosmopolitan  genus comprising 2000 species, with its center distribution in Central Asia. 250 species, are from China so far known, in alpine zone of Southwest and Northwest, with 70 species extending farther to the Himalayas and Xizang Plateau.       Among them, there are 7 species (10%) common to Central Asia, 12 species (15.7%) to Southwest China and 40 species (60%) are endemic, it indicates that the differentia- tion of the species of the genus in the region is very active, especially in the subgenus Pogonophace with beards in stigma. 27 species amounting to 78.5% of the total species of the subgenus, are distributed in this region.  The species in the region mainly occur in alpine zone between altitude of 3500—300 m. above sea-level. They have developed into a member of representative of arid and cold alpine regions.      The endemic species of Astragalus in Xizang might be formed by specialization of the alien and native elements. It will be proved by a series of horizontal and vertical vicarism of endemic species.  For example, Astragalus bomiensis and A. englerianus are horizontal and vertical vicarism species, the former being distributed in southeast part of Xizang and the latter in Yunnan; also A. arnoldii and A. chomutovii, the former being an endemic on Xizang Plateau and latter in Central Asia.      The genus Oxytropis comprises 300 species which are mainly distributed in the north temperate zone. About 100 species are from China so far known, with 40 species extending to Himalayas and Xizang Plateau.  The distribution, formation and differ- entiation of the genus in this region are resembled to Astragalus.  These two genera are usually growing together, composing the main accompanying elements of alpine mea- dow and steppe.      Caragana is an endemic genus in Eurasian temperate zone and one of constructive elements of alpine bush-wood. About 100 species are from China, with 16 species in Xi- zang. According to the elements of composition, 4 species are common to Inner Mon- golia and Kausu, 4 species to Southwest of China, the others are endemic. This not only indicates that the species of Caragana in Xizang is closely related to those species of above mentioned regions, but the differentiation of the genus in the region is obviously effected by the uplifting of Himalayas, thus leading to the formations of endemic species reaching up to 50%.      3. An Analysis of Tropical Genera      There are 19 tropical genera in the region. They concentrate in southeast of Xizang and southern flank of the Himalayas. All of them but Indigofera and Desmodium are represented by a few species, especially the endemic species. Thus, it can be seen that they are less differentiated than the temperate genera.      However, the genus Desmodium which extends from tropical southeast and northeast Asia to Mexio is more active in differentiation than the other genera. According to Oha- Shi,s system about the genus in 1973, the species of Desmodium distributed in Sino-Hima- laya region mostly belong to the subgenus Dollinera and subgenus Podocarpium.  The subgenus Dollinera concentrates in both Sino-Himalaya region and Indo-China with 14 species, of which 7 species are endemic in Sino-Himalaya.  They are closely related to species of Indo-China, southern Yunnan and Assam and shows tha tthey have close con- nections in origin and that the former might be derived from the latter.      Another subgenus extending from subtropical to temperate zone is Podocarpium. Five out of the total eight species belonging to the subgenus are distributed in Sino- Himalaya and three of them are endemic.      An investigation on interspecific evolutionary relationship and geographic distribu- tion of the subgenus shows that the primary center of differentiation of Podocarpium is in the Sino-Himalaya region.      Finally, our survey shows that owing to the uplifting of the Himalayas which has brought about complicated geographic and climatic situations, the favorable conditions have been provided not only for the formation of the species but also for the genus in cer-tain degree.     

木兰科分类系统的初步研究

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. mega- phylla, 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 primi- tive, 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, an- thers 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.     

论世界柳属植物的分布和起源

1.  The distribution of Salix species among the continents.  There are about 526 species of Salix in the world, most of which are distributed in the Northern Hemisphere with only a few species in the Southern Hemisphere.  In Asia, there are about 375 species, mak- ing up 71.29 percent of the total in the world, including 328 endemics; in Europe, about 114 species, 21.67 percent with 73 endemics; in North America, about 91 species, 17.3 percent with 71 endemics; in Africa, about 8 species, 1.5 percent, with 6 endemics.  Only one species occurs in South America.  Asia, Europe and North America have 8 species in common (excluding 4 cultivated species).  There are 34 common species between Asia and Europe, 14 both between Europe and North America and between Asia and North America, 2 between Asia and Africa. Acording to the Continental Drift Theory, the natural circumstances which promoted speciation and protected newly originated and old species were created by the orogenic movement of the Himalayas in the middle and late Tertiary.  Besides, the air temperature was a little higher in Asia than in Europe and North America (except its west part) and the dominant glaciers were mountainous in Asia during the glacial epoch in the Quaternary Period.  Then willows of Eu- rope moved southwards to Asia.  During the interglacial period they moved in opposite direc- tion.  Such a to-and-fro willow migration between Asia and Europe and between and North America occurred so often that it resulted in the diversity of willow species in Asia.  Those species of willows common among the continents belong to the Arctic flora.      2.  The multistaminal willows are of the primitive group in Salix.  Asia has 28 species of multistaminal willows, but Europe has only one which is also found in Asia.  These 28 species are divided into two groups, “northern type” and “southern type”, according to morphology of the ovary.  The boundary between the two forms in distribution is at 40°N.  The multistami- nal willows from south Asia, Africa and South America are very similar to each other and may have mutually communicated between these continents in the Middle or Late Cretaceous Period.  The southern type willows in south Asia are similar to the North American multista- minal willows but a few species.  The Asian southern type willows spreaded all over the conti- nents of Europe, Asia and North America through the communication between them before the Quaternany Period.   Nevertheless, it is possible that the willows growing in North America immigranted through the middle America from South America.  The Asian northern type mul- tistaminal willows may have originated during the ice period.      The multistaminal willows are more closed to populars in features of sexual organs.  They are more primitive than the willows with 1-3 stamens and the most primitive ones in the ge- nus.      3.  The center of origin and development of willows Based on the above discussion it is re- asonable to say that the region between 20°-40°N in East Asia is the center of the origin and differentiation of multistaminal willows.  It covers Southern and Southwestern China and nor- thern Indo-China Pennisula.     

中国种子植物特有属的数量分析

Chinese flora with many endemic elements is highly important in the world’s flora. According to recent statistics there are about 196 genera of spermatophytes, be- ing 6.5% of total Chinese genera.  These endemic genera comprising 377 species belong to 68 families, among which the Gesneriaceae (28 genera), Umbelliferae (13), Compo- sitae (13), Orchidaceae (12) and Labiatae (10) are predominant.  The tropical type containing 24 families and 80 genera is dominant. After it follows the temperate type with 23 families and 50 genera.  There are also 4 families endemic to China, i.e. Gin- kgoaceae, Bretschneideraceae, Eucommiaceae and Davidiaceae.  It shows that genera endemic to China are obviously related to the tropical and temperate flora in essence.      The endemic monotypic genera (139) and endemic obligotypic genera (48) combin- ed make up more than 95% of the total number of genera endemic to China.  Phylo- genetically more than half of them are ancient or primitive.  The life forms of all ende- mic genera are also diverse.  Herbs, especially perennial herbs, prevail with the propor- tion of about 62%, and trees and shrubs are the next, with 33%, and the rest are lianas.       Based upon the calculated number of genera endemic to China in each province and the similarity coefficents between any two provinces, some conclusions may be drawn as follows:       Yunnan and Sichuan Provinces combined are the distribution centre of genera en- demic to China and may be their original or  differentiation area,  because  numerous endemic genera, including various groups, exist in these two provinces.  The second is Guizhou where there are 62 endemic genera.  Others form a declining order, south China, central China and east China. But towards the north China endemic genera de- crease gradually, and the Qinling Range is an important distributional limit.       The largest simitarity coefficient, over 50%, appears between Shaanxi and Gansu probably because of the Qinling Range linking these two provinces.  But between any other two provinces it is less than 30% and it is generaly larger between two south pro- vinces than between two north provinces.       These characteristics mentioned above are correlated with topography and climate, and they may be resulted from the diversification in geography and climatic influence for a long time.     

东喜马拉雅南翼苔藓植物区系的特性及其来源

 In the south-east and south Xizang, in cluding Medog, Zayü some western separate valleys Yadong, Kama near Zentang in Dinggye, Boqu near Zham in Nyalam and Gyirong, a mild climate prevails because of the very high mountains and the very deep valleys.  According to our preliminary survey, 4/5 of the genera and 7/10 of the species, i.e. approximately representing all families and genera of the tropical and subtropical bryofliora of Xizang, are restricted to these localities below the altitude of 2,300 meters.  It almost agrees with the previous presumption that the Tsangpo gorge is the line of connection between two paleoeontinents—Laurasia and Gondwana.       Moreover, the bryoflora of these localities, besides the Indo-Malasian elements and East Asian elements as the main components, has at least about 40 genera in common with south America, Australia and Africa.  According to the historical phytogeogra- phical point of view, the distribution range of centain genera is formed through a period of long historical development.  The same is true for the area of different species, although they are found in widely separate areas right now, yet they might have once a continuous distribution in certain historical age. The Indian plate collided against the eastern part of Laurasia and afterwards the Australasian plate moved to the north.  All these might have dispersed the Gondwana elements as far as to the southeastern part of Xizang.      It is very interesting to note that of the 32 genera of bryophytes endemic to East Asia, 13 have recently been found in the southeast and south Xizang and also in the neighbouring regions, i.e. Yunnan, Sichuan, where there are many genera being in common with southeast and south Xizang and also highly concentrated in distribution. This may suggest that the Himalayas, being the highest and youngest mountain range, have changed the atmospheric circulation, and have created a new ecological condition between tropical and frigid zones, which have given the distribution of the newly form- ed genera a suitable circumstance to survive.  It may be presumed that the region covering counties Medog, Zayü, Yadong etc. in southeastern and southern parts of the Himalayas is a new center of distribution of bryophytes under the influence of the up-heaval of the Himalayas.     

鄂西神农架地区的植被和植物区系

 Shennungia is generally known as “The highest mountain in Central China”. It is situated at latitude 31°342'N., longitude 110°35'E. in western Hupeh.       The area explored is deeply cut in all sides by five V-shaped valleys, giving the landscape a steep topography.  Its summit is about 3105 meters above the sea level, and the relative altitude is from 1000-2000 meters.      The climate of the region is warm temperate.  The differences of humidity-warmth condition between the eastern and the western flanks are quite marked.      In western Hupeh and the adjacent area of Szechuan the rugged topography still preserves some tracts of natural forests at higher elevations.  Our vegetational survey is confined to localities above 1500 meters. The collection of plant samples of the flora is extended to the whole mountain from the foothill to the peak.  The present article deals with only a part of the results of our survey.      1.  The vertical vegetation belts of Mt. Shennungia and relationships with other regions:  The vegetation belts on the eastern and the western flanks of the mountain are shown in diagram 2 and 3.  The comparison of the vertical vegetation zones of the Mt. Shennungia with those of the Yülungshan in N. W. Yunnan and the eastern Himalaya to the west and with those of Hwangshan and Central Japan to the east is shown in table 4, It shows that the plant communities of the Mt. Shennungia are of temperate nature, and they are more closely related to those of Hwangshan in S. Anhwei and of Central Japan than to the eastern Himalaya.      2.  Floristic composition: The generic ranges of flowering plant are relatively distinct and stable. Various distributional patterns of genera are analysized.      1)  Statistics of the genera in various distributional patterns: The total number of genera of flowering plants in this region are 762, belonging to the following four categories. A) tropical genera 239 (31.3%), B)  temperate  genera  416 (54.7%),  C) endemic genera 47 (6%), and D) comsmopolitan genera 61 (8%).       2)  Endemic genera:  An examination of the composition of the flora in western Hupeh reveals that 47 endemic Chinese genera occur in this mountain of which 24 are monotypic genera, 20 oligotypic and 2 multitypic as shown in Table 4. The arborescent genera are nearly all deciduous. They are of temperate nature.       3)  Temperate genera:  There are 416  genera in  wastern Hupeh.  They  are subdivides into the following three groups according to their distributional patterns: A)  The north temperate genera: There are 159 genera belonging to 62 families in western Hupeh. B)  Eastern Asian genera:  There are 117 genera belonging to 69 families in western Hupeh.  Among them 22 are common to the western Szechuan, adjacent regions of Yunnan and the Eastern Himalaya.  The remaining 95 genera are commom to both eastern China and Japan. C) The Eastern Asian-eastern North- American genera:  Of the total 762 genera known in western Hupeh, 64 are disjunc- tively distributed in both eastern Asia and eastern North-America.       4)  The tropical genera: Of the 762 genera of the flowering plant of western Hupeh, 239 (31%) are of tropical nature.       Finally, our survey shows:  1. Many of the primitive temperate genera and ende- mic relicts concentrate in western Hupeh and the adjacent region of Szechuan indica- ting that it might be one of refuges of tertiary flora. Moreover, it might also be one of the most important regions of differentiation, development and distribution of tem- perature flora. 2.  The vegetation of this region is not only of temperate nature, but also of a transitional nature. 3.  According to an analysis of the flora and a compari- son of the vertical distribution of the vegetation of Yülungshan and Eastern Himalaya to the west with Hwangshan and Central Japan to the east, the floristic affinity of western Hupeh is more closely related to eastern China and Central Japan rather than to the Eastern Himalaya, and phytogeographically this region is intermediate between the Sino-Himalayan and the Sino-Japanese patterns.  However, the problem of phyto- geography of western Hupeh and the adjacent region of Szechuan is a complicated one requiring further study.       

中国清风藤科的初步研究

 This paper is a preliminary study on the Sabiaceae in aspects of its morphology, taxonomy and geography.  We propose that the Sabioideae and Meliosmoideae as two new subfamilies of Sabiaceae according to the external morphology, flower structure and geographical distribution of these two genera respectively.       This paper follows the taxonomic concepts of Luetha Chen on Sabia and C. F. van Beusekom on Meliosma.  We agree with them for their classification of these two genera above the specific rank.  As to the revision work of Sabia by van de Water and C. F. van Beusekom’s work on Meliosma we disagree  for their unduly broad specific concepts.  We rather treat the species of these two genera according to their habitats in regions on a relatively narrower sense.  The genus Sabia of China are classified into 2 tribes, with 16 species, 5 subspecies and 2 varieties in which 4 sub- species and l variety are as new combinations, the genus of Meliosma in China are classified into 2 subgenera with 29 species, and 7 varieties of which 4 varieties are new combinations.       After examining the affinity of the species of Sabia and Meliosma in China and its neighboring nations such as Burma, Japan and Bhutan, we found that their migra- tion initiated from China, as the primitive species of these two genera occured in northeast and central part of Yunnan, sou theast of Sichuan, north of Guizhou and west of Hubei, the region may probably be the main origin of these two genera.      As shown in tables 1 & 2, the localities where the species of these two genera den- sely populate they are from Yunnan, Guangxi, and Guangdong coinciding with the concepts of C. F. van Beusekom and van de Water about the distribution of exotic species of these two genera, it may reasonable be pointed out that the center of distri- bution of these two genera is Yunnan, Guangxi, Guangdong and nieghboring nations, upper Burma and northern Vietnam.  Futhermore, it may be seen that starting from this center the number of species become less and less as they proceed far and far awaybut become more advance in evolution.     

暖地杓兰——与碗兰属有密切关系的新种

Cypripedium subtropicum S.  C. Chen et K. Y. Lang is a phytogeography- cally significant new species with its habit, inflorescence and column very similar to those of Selenipedilum of tropical America.  It is found in Mêdog of southeastern Xi- zang, China.  Its slender leafy stem bears at the summit a many-flowered raceme, am- ounting to 1.5 m in height. Although its ovary is unilocular—this is the reason why we place it in Cypripedium, the column characters resemble those of Selenipedilum. For example, the staminode is rather small and its long stalk is very similar in texture and color to the filament of the fertile stamens. Obviously, it is a primitive new species re- lated to Selenipedilum based on the similarities mentioned above.       In the subfamily Cypripedioideae, as generally recognized, Selenipedilum is  the most primitive genus, from which or whose allies Cypripedium is derived.  Of phyto- geographical significance is the fact that Selenipedilum occurs in Central America and northern South America, while a cypripedium akin to it is discontinuously distributed in subtropical Asia.  This suggests that Selenipedilum or Selenipedilum-like  form be once continually distributed in North America and eastern Asia when the climate there was warmer, as it is in the subtropics today.  The floristic relationship between Central America and subtropical Asia appears to be closer than expected, as shown by the dis- tribution patterns of Tropidia, Erythrodes, etc.  Based on the occurrence of all six sec- tions and particularly the most primitive form in eastern Asia, Cypripedium seems to be of Asian, rather than Central American, origin.  Selenipedilum possesses some very primitive characters, such as trilocular ovary, vanilla-scented fruit, seed with sclerotic testa, simple column and more or less suffrutescent habit.  The latter is considered by Dahlgren & Clifford (1982) to be one of ancestral characters of monocotyledons, which is now very rare not only in Orchidaceae but also in all monocotyledons.  It is indeed necessary to make further investigations on Selenipedilum and also the new species pub-lished here, as well as a detailed comparison between them.     

中国列当属的分类及与近缘属的关系

The morphological characters in the genus Orobanche were evaluated from the taxonomic point of view.  The author finds that the plants of this genus are relatively similar to each other in respect to characters of vegetative organs, fruits and seeds.  But the differences in the floral structures can be served as a basis for delimitating infrageneric taxa.   The seed coat of 18 species and pollen grains of  6 species were also examined under scanning electron microscope (SEM). They seem to have little significance for distinguishing species.       The result supports G. Beck’s (1930) division of the genus Orobanche into 4 sections, of which 2 occur in China, based on the characters of the inflorescence, bracteoles and calyx. The author considers that some characters, such as anther hairy or not, upper lip of corolla entire or not, lower lip longer or shorter than the upper one, the state of corolla-tube inflec-  tion and the hair type of filaments and plants, are important in distinguishing Chinese species.  A key to the species of Orobanche in China is given.       This genus consists of about 100 species, and is mostly confined to Eurasia, with over 60  species found in Caucasus and Middle Asia of USSR, where may be the mordern  distribu-  tional  centre.        Orobanche L. in China is represented by 23 species, 3 varieties and l forma. As shown in  Table 1, most species (12 species) are found in Xinjiang, which clearly shows a close floristic  relationship between this region and Middle Asia of USSR.  6 species are endemic to China,  of which 4 are confined to the Hengduan Mountains  (Yangtze-Mekong-Salwin divide).        The relationships between this genus and related ones of Orobanchaceae are also discussed.  The author holds the following opinions: the genus Phelypaea Desf. should be considered as a   member of Orobanche L. Sect. Gymnocaulis G. Beck,  the monotypic genus,   Necranthus A.   Gilli endemic to Turkey, is allied with Orobanche L. Sect.  Orobanche, the monotypic genus,   Platypholis Maxim, endemic to Bonin Is. of Japan, is far from Orobanche L. in relation and   should be regarded as a separate genus.        The 11 OTU’s, including all the sections of Orobanche L. and 7 genera of Orobanchaceae,   and 15 morphological characters were used in the  numerical  taxonomic treatment  to  test  the   above-mentioned  suggestions.   After standardization of characters, the correlation matrices were   computerized.  The correlation matrices were made to test the various clustering methods.   At    last the UPGMA clustering method was chosen and its result is shown in a phenogram.  The   result of numerical analysis is basically in accordance with the suggestions.     

青藏高原:从热带动植物乐土到冰期动物群摇篮

在我国藏北渐新世地层中发现了攀鲈和鲃类新属种,其现生近缘类型都生活在亚洲和非洲的热带地区。这不仅在鱼类的系统发育和动物地理上具有重要意义,并且表明青藏高原腹地在距今26 Ma前仍然为温暖湿润的低地,伴生的棕榈、菖蒲等植物化石也指示同样的环境,说明当时由印度洋来的暖湿气流至少可以深入到藏北地区。自那时起,高原内部的地理特征与自然环境经历了巨大的变化。青藏高原在中新世持续隆升,至上新世达到现代高度,形成冰冻圈环境。在札达盆地的上新世沉积中发现了披毛犀、雪豹、北极狐和盘羊的祖先类型,显示适应严寒环境的第四纪冰期动物群起源于青藏高原,由此提出和进一步完善了寒冷适应性动物起源与扩散的"走出西藏"理论。     

獐牙菜属植物的起源, 散布和分布区形成

本文根据植物类群的系统发育和地理分布统一的原理，讨论了獐牙菜属植物的起源、散布和分 布区的形成。獐牙菜属包括11组16系154种，间断分布在亚洲、欧洲、北美洲和非洲。中国西南部- 喜马拉雅地区汇集了大多数种类、不同演化水平的类群以及形形色色的特有类群，成为该属的多样化 中心和多度中心。该属的原始类群和外类群也集中分布在中国西南山地，极有可能是该属的起源地。该 属的分布区类型中出现了各式的间断分布，根据有该属植物分布的大陆间及大陆与岛屿间分离和连接 的时间推测，该属的起源时间至少不会晚于晚白垩纪，也许更早，可追溯到中白垩纪。通过分类群间亲 缘关系和现代分布分析，显示出该属植物从起源地向周围和一定方向散布，形成了三个主要散布途径。在散布过程中植物本身也发生演化和就地特化，形成新的类群。     

青藏高原和喜马拉雅地区锦鸡儿属植物的地理分布

锦鸡儿属Caragana是一个典型的温带亚洲分布属。本属在青藏高原和喜马拉雅约有24种1变种，约占整个属的1／3。这些种类几乎全部处于演化高级阶段，且既有叶轴宿存类群，也有假掌状叶类群。反映出种的分化很活跃，在横断山地区形成本属的分布中心、分化中心。本区内绝大多数种类是特有分布。替代现象主要受气候、植被变化作用，沿横断山和喜马拉雅分布的长齿系Ser. Bracteolatae Kom．是一个典型的替代分布类群。锦鸡儿属植物生态适应性很强，可在其生长的灌丛中形成优势种。 寒化和旱化现象十分突出，它们有一系列森林种、草原种和荒漠种及相关的形态变异。用锦鸡儿属植物进行青藏高原和喜马拉雅区域内的分布区关系分析及最小生成树MST和特有性简约性分析(PAE)，表明横断山地区特别是其北部是本属植物的一个地理结点。以此沿横断山向北部唐古特和西部藏东南适应性辐射。横断山和西喜马拉雅联系微弱，看不出植物长距离扩散的踪迹，大多是由于生态因子限制而产生的隔离。虽然本区不可能是锦鸡儿属的起源地，然而，通过本区与邻近地区的地理联系，可推测它们在我国适应性辐射方向是从东北向西南。结合豆科蝶形花亚科其它属化石记录及其分布区局限在温带亚洲等现象，认为锦鸡儿植物是一组特化、晚近衍生的类群，起源于北方东西伯利亚晚第三纪中新世后期至上新世。     

东亚植物区系的一些分布式样和迁移路线

本文根据毛茛科等科的一些植物的地理分布划分出由西到东方向的7种分布式样和由西南到东 北方向的8种分布式样，并列出了属于每种式样的植物。根据这些分布式样和对一些植物的地理分布 和亲缘关系的分析，看出了自我国西南部分别向东、向西和向东北诸方向伸展出的三条迁移路线：(1)由 西南部向东，在北部沿秦岭和大别山(秦岭-大别山走廊)，在中部沿武陵山、幕阜山等山脉，在南部沿南 岭(南岭走廊)到达华东沿海地区、台湾或进一步到达日本和邻近地区；(2)从西南部向西达喜马拉雅山 区(喜马拉雅走廊)；(3)从横断山区向东北方向经秦岭、黄土高原东部、阴山、长白山和小兴安岭，到达西 伯利亚及相邻地区；这条迁移路线可称为中国西南－东北走廊，在第四纪冰期中曾是一些植物从西伯利 亚或我国东北到我国西南部之间的往返通道。此外，还根据半蒴苣苔和吊石苣苔的地理分布，根据光萼 唇柱苣苔和芒毛苣苔的分布，根据斑叶唇柱苣苔、齿叶吊石苣苔、华丽芒毛苣苔、显苞芒毛苣苔、毛线柱 苣苔、光叶楼梯草、多序楼梯草、华南楼梯草、细齿崖爬藤和长蓖木兰的地理分布，根据山豆根属、山桂花 属、盾片蛇菰、滇黔楼梯草、微柱麻和单蓖麻的地理分布，以及根据檬果樟属的地理分布，分别区分出下 列迁移路线：(1)从云南东南和广西西部向东北分布到华东和日本的一条迁移路线；(2)由云贵高原南部 向东沿南岭走廊达台湾的一条迁移路线；(3)由云贵高原南部和中南半岛北部向西沿云南高原的南缘和 西缘达我国西藏东南部或印度东北部，最后沿喜马拉雅走廊达尼泊尔的迁移路线；(4)由云南高原南部 和中南半岛北部向南经马来半岛到苏门答腊和爪哇岛，以及向东南经婆罗洲到菲律宾的二条迁移路 线。根据对一些植物的分析，以及上述诸迁移路线的辐射状分布格局，并根据有关古植物学的研究(被 子植物可能起源于赤道地区；北半球和南半球的温带植物区系是在中白垩纪分化出来的)，以及李惠林、 ВУЛЪВ和吴征镒等学者对我国植物区系的起源、性质等方面的重要论断，作者推测云贵高原和四川一带 可能是在中白垩纪，被子植物在赤道地区起源后向北半球扩展到达上述地区形成的一个重要发展中心，在这里发生了强烈的演化辐射，上述的诸条迁移路线就是这个辐射出现后的产物。     

中国柳属植物地理分布的研究

本文研究了中国产柳属植物的分布，并探讨了该属的起源与演化问题。  我国产柳     属植物255种，约占全世界总数的46％，隶属于37个组，几乎包括了该属所有的进化类型。     因此，中国是世界柳属植物种数最多、类型最丰富的地区。青藏高原的出现，是形成这一分布     特点的重要原因。我国柳属植物主要分布在西北、东北和西南地区。西北地区是中亚分布区     的一部分; 东北地区是东北亚分布区的一部分; 它们又都有一些中欧-西伯利亚和北极-高山成     分。青藏高原与其他分布区间的联系很少，是柳属又一个重要的分布中心。作为泛北极植物 区系的典型属之一的柳属，可能起源于东南亚热带山区。