国产黄连属植物的染色体核型分析

中国黄连属6种1变种分属叶掌状三全裂和叶掌状五全裂2个类群,前者包括三角叶黄连、峨眉黄连、云南黄连、黄连和其变种短萼黄连;而分布于滇东南的五裂黄连和产于台湾的五叶黄连则归于后者。采用根尖压片法和卡宝品红染色法,对除五叶黄连外的中国黄连属5种1变种,以及日本黄连进行染色体核型比较分析,从细胞学角度为探讨中国黄连属植物的系统分类提供新的线索和证据。结果表明:(1)五裂黄连(2n=2x=18=2M+16m)、短萼黄连(2n=2x=18=8m+10sm)和日本黄连(2n=2x=18=12m+6sm)的染色体数目和核型均为首次报道。(2)7个材料的染色体基数均为9,除三角叶黄连为三倍体外,其余均为二倍体。(3)叶为掌状三全裂的二倍体种核型一致,为2A型,染色体类型以及不对称系数均很相似;叶为掌状五全裂的五裂黄连与五叶黄连的核型更接近,为1A型,核型特征的共性表明了这2个类群的自然属性。(4)三倍体三角叶黄连的不对称程度较高,核型为3A型,其染色体大小与峨眉黄连最接近。(5)根据核型不对称程度和染色体大小,结合地理分布,推测叶掌状五全裂种为本属的原始类群。     

Chromosome Studies of 10 Chinese Species of Adenophora Fisch.

This paper is a cytological part of biosystematic studies on Adenophora Fisch. in Heilongjiang, China. Chromosomal numbers and karyotypes of 10 spp. and 1 var. are reported. The results are summarized in Table 1. The chromosomal numbers and karyotypes of 6 spp. and 1 var. are first reported, including tetraploid species (2n=68) (A. pereskiifolia var. alternifolia, A. amurica and A. gmelinii). The basic number of chromosomes in the genus is mainly 17 (x=17), but that of A. trachelioides and A. remotiflora (2n=36) is 18 (x=18), an unique one in the genus. The karyotypes of all the species examined are relatively uniform, which means that they are derived from a common ancestral type. The chromosomes are smaller, varying between 2-4 μm. The majority of chromosomes are m and sm ones. And a pair of sat-chromosomes and a pair of st chromosomes are always present. The centromeric terminalization value of chromosomes is 57.5-61.9%, showing higher symmetry of karyotypes in the genus. The karyotype of A. tetraphylla (2n=34) is the most symmetrical among these species. Based on its morphological characters and distribution, the species may be considered as a relatively primitive member of the genus. The results show two revolutionary trends in karyotypes of the genus: number variation (including polyploidy and aneuploidy) and structural variation. The polyploidy is one of the principal patterns of speciation in the genus. Combined with the other characters, these species are taxonomically discussed, and two new taxa (A. amurica Fu et Liu and A. pereskiifolia ssp. alternifolia (Fuh ex Y. Z. Zhao) Fu et Liu) are confirmed. A. trachelioides and A. remotiflora (both 2n=36) with obvious petioles seems more advanced than the other species (2n 34).     

云南乌头属牛扁亚属的核形态研究

对云南乌头属牛扁亚属３种、１变种共９个居群的核形态进行了研究。其中弯短距乌头、粗花乌头和滇川乌头的染色体数目和核型为首次报道。所有种类的静止核和前期染色体形态基本相似,分别属于复杂中央染色微粒型和中国型;分裂中期染色体数目为２ｎ＝４ｘ＝３２,染色体类型通常为ｓｍ或ｍ,ｓｔ染色体少见,染色体从大到小逐渐过渡,核型的二型性不明显。结合有关资料,重点指出了乌头属不但在亚属之间,而且在牛扁亚属内也存在着较     

Karyomorphology of Incarvillea (Bignoniaceae) and its implications in distribution and taxonomy

The karyomorphology of 11 species of the genus Incarvillea Juss. is reported. The chromosome numbers of all species studied are 2 n  = 22. The interphase nuclei and prophase chromosomes were found to be of the simple chromocentre type and the interstitial type, respectively. The asymmetry of the karyotype of I. arguta (two populations) in subgenus Amphicome is type 2A. The karyotypes of Incarvillea s inensis var. sinensis , I.  s inensis var. przewalskii, and I. olgae in subgenus Incarvillea are of asymmetry type 3A. The remaining nine species and one variety in subgenus Pteroscleris are also of asymmetry 3A. Data on three species and one variety studied are first reports. This study indicates that karyotype variation at the diploid level appears to be the predominant feature of chromosome evolution in the genus Incarvillea . According to this study of karyomorphology, morphological characteristics and geographical distribution, it seems that the three subgenera should be regarded as three independent genera. The geography of the genus is discussed.  © 2004 The Linnean Society of London, Botanical Journal of the Linnean Society , 2004, 144 , 113–121.     

云南大叶茶细胞学研究

本文采用去壁低渗法研究了云南大叶茶的染色体核型,间期核形态和多核现象。结果表明大多数染色体是中部着丝粒染色体,5对是近中部着丝粒染色体,第7和12对染色体中各有1条具随体染色体。根据Levan等的分类原则,其核型为2n=20m+8sm+2sm(SAT),属于Stebbins核型分类的“2A”型,同时亦发现有“2B”型的核型。云南大叶茶间期核型为浓密分散型和复杂染色中央微粒型两种;并首次发现茶树中的多核现象,在所观察的1250个细胞中有6个是具双核细胞(占0.48％),有2个是具三核细胞占(0.16％)。另外,本文还对部份山茶属植物的核型进行了讨论。从核型上可以看出:(1)山茶属植物在进化上属于较原始的种系;(2)山茶属植物核型的进化基本符合Stebbins提出的植物界核型进化的规律,即对称—→不对称;(3)山茶属植物的核型在一定范围内变异甚大,这种变异没有一定的规律性。这些观点与张宏达提出的山茶属植物的分类系统基本吻合。带随体的染色体数目在山茶属植物核型的进化上没有什么明显的变化规律。     

Systematic position of Nannoglottis Maxim. s.l. (Asteraceae): karyomorphological data

This paper describes for the first time the karyomorphology of 4 populations of 2 species of Nannoglottis Maxim. s. l. The two species both show the resting nuclei of the complex chromocenter type and the mitotic prophase chromosomes of the interstitial type. The karyotype formula of N. gynura is 2n = 18 = 14m + 2sm + 2st(SAT) in two populations while that of N. carpesioides is 2n = 18 = 14m + 2sm(2SAT) + 2st in two populations. The two species under study represent two sections of Nannoglottis s. l. N. gynura, the only species of sect. Stenolepis, is considered as the most primitive member of the genus. Accordingly, the basic chromosome number of the genus might be x＝9. Karyomorphological data indicate that Nannoglottis should be placed in the tribe Astereaerather than in the Inuleae and the Senecioneae.     

Karyomorphology of four species in Ancylostemon,Briggsiopsis and Lysionotus (Gesneriaceae)

Reported in the present paper are chromosome numbers and karyotypes of three genera of the Gesneriaceae, i.e. Ancylostemon Craib. , Briggsiopsis (Franch.) K. Y. Pan and Lysionotus D. Don. The former two genera are endemic to China. The karyotype of Ancylostemon aureus (Franch.) Burtt is formulated as 2n = 34 = 20m(1sat) + 14sm, with the same chromosome number as its allied species A. convexus Craib. This species is characterized by the interphase nucleus of complex chromocenter type and the proximal type of chromosomes in the mitotic prophase. The chromosome number of the monospecific genus Briggsiopsis is 2n = 34, the same as the lowest chromosome number reported in Briggsia. The karyotype of Briggsiopsis, which is formulated as 2n = 25m + 6sm + 3st, also seems to be primitive among the species of the two genera. Briggsiopsis is characterized by the interphase nucleus of simple-complex chromocenter type and the interstitial-gradient type of chromosomes in the mitotic prophase. The chromosome number of Lysionotus carnosus Hemsl. is the lowest reported in this genus. Its karyotype is formulated as 2n= 30 = 21m + 5sm + 3st + lt. Lysionotus serratus var. pterocaulis, with the karyotype being formulated as 2n= 32 = 2lm + 10sm + lt, has the same chromosome number as var. serratus. These two species show a remarkable differentiation of karyotypes and are characterized by the interphase nuclei of simple-complex chromocenter type and the gradient type of chromosomes in the mitotic prophase. _ .     

The long and the short of avian W chromosomes: no evidence for gradual W shortening

The well-established view of the evolution of sex chromosome dimorphism is of a gradual genetic and morphological degeneration of the hemizygous chromosome. Yet, no large-scale comparative analysis exists to support this view. Here, we analysed karyotypes of 200 bird species to test whether the supposed directional changes occur in bird sex chromosomes. We found no support for the view that W chromosomes gradually become smaller over evolutionary time. On the contrary, the length of the W chromosome can fluctuate over short time scales, probably involving both shortening and elongation of non-coding regions. Recent discoveries of near-identical palindromes and neo-sex chromosomes in birds may also contribute to the observed variation. Further studies are now needed to investigate how chromosome morphology relates to its gene content, and whether the changes in size were driven by selection.     

The Application of Sequence Analysis of rDNA Fragment to the Systematic Study of the Subfamily Cyrtandroideae (Gesneriaceae)

A molecular phylogeny of the subfamily Cyrtandroideae represented by five genera of four tribes was constructed using sequence analysis of the internal transcribed spacers (ITS) and partial 5.8 S rRNA gene (3’end) of nuclear ribosomal DNA. Direct PCR sequencing method was used in the study. The sequences of ITS-1 in the five species range from 234 bp to 258 bp in size and those of ITS-2 from 218 bp to 246 bp. The ITS-1 (258 bp) and ITS-2 (218 bp) of Whytockia bijieensis differ greatly from those of the other species in size, sequence and G + C content, and therefore the tribe Klugieae represented by W. bijieensis may have diverged from the ancestor of the subfamily Cyrtandroideae at a very early time. In PAUP analysis, W. bijieensis was used as the functional outgroup, and only one most parsimonious Fitch tree was obtained through exhaustive search. The tree has 353 steps, with CI = 0. 932 and RI = 0. 529. In the tree, Chirita crassifolia is basal to a monophyletic group comprising Cyrtandra umbellifera, Briggisia longipes and Anna mollifolia, and the monophyletic group is strongly supported by the bootstrap value (97). The tribes Trichosporeae and Cyrtandreae represented respectively by Anna mollifolia and Cyrtandra urnbellifera both evolved from the tribe Didymorcarpeae, which can explain why many intermediate taxa exist among the three tribes. According to this, the present authors suggest that the tribe Trichosporeae and the tribe Cyrtandreae be merged with the tribeDidymocarpeae.     

中国独活属的核型研究

本文首次报道了我国独活属10种(含1变种)的核型,其中8种的染色体数目亦为首次报道。研究表明它们的染色体数目均为2n＝2x＝22,为二倍体,其核型为中部着丝点和亚中部着丝点染色体组成,仅具1A和2A两种类型。有4种具随体染色体,在部分H．vicinum植株中发现有1条B染色体,在H．millefolium var．longilobum中同时存在2n＝22和2n＝24的非整倍体．不同种的染色体形态不同,为分类研究提供了细胞学依据。 本文在核型分析基础上讨论了该属分类群的划分、种间亲缘关系及演化,并结合我国毗邻地区该属细胞学资料和地理分布规律,提出我国西南部的横断山区是独活属的频度中心和多样性中心。     

毛茛科鸭跖花属的核形态研究

研究了毛茛科鸭(足石)花属Oxygraphis Bunge 3种植物的核形态。其间期核均为复杂中央染色微粒型,前期染色体为中间型,染色体基数为x=8。脱萼鸭（足石）花O.delavayi的染色体明显大于鸭(足石)花O.glacialis和细叶鸭(足石)花O.tenuifolia的染色体。结果支持鸭（足石）花属是毛茛科毛茛亚族subtrib.Ranunculinae的一个自然成员以及脱萼鸭跖花可能是该属的原始种的观点。     

Karyomorphology of the genus Oxygraphis Bunge (Ranunculaceae)

Three species of the genus Oxygraphis Bunge (Ranunculaceae) were karyomorphologically studied. The interphase nuclei of complex chromocenter type, prophase chromosomes of interstitial type and basic chromosome number of x = 8 were common to all the three species examined, but the chromosomes of O. delavayi were markedly larger than those of O. glacialis and of O. tenuifolia. The results support the viewpoints that Oxygraphis is a natural member of the subtribe Ranunculinae Spach, tribe Ranunculeae DC. in the subfamily Ranunculoideae and that O. dela-vayi might be the primitive species of this genus.     

六种云杉的核型分析

对６种（含１变种）云杉属植物的染色体数目及形态特征进行了分析研究。研究树种均为我国特有种,其中４种在本文中首次报道。分析材料全部取自各树种中心产区的原始林内。其核型公式：鳞皮云杉（Ｐ．ｒｅｔｒｏｆｌｅｘａ）Ｋ（２ｎ）＝２４＝２２ｍ＋２ｓｍ;云极（Ｐ．ａｓｐｅｒａｔａ）Ｋ（２ｎ）＝２４＝２０ｍ＋４ｓｍ;青插（Ｐ．ｗｉｌｓｏｎｉｉ）Ｋ（２ｎ）＝２４＝２０ｍ＋４ｓｍ＋１Ｂ;紫果云极（Ｐ．ｐｕｒｐｕｒｅａ     

鹿科动物的染色体组型及其进化

染色体是遗传物质的主要携带者。在动植物进化过程中,染色体在数量和结构上的变化,无疑对物种形成起重要的作用。染色体的变化往往引起基因的重新排列和遗传物质的增加或丢失。染色体在结构和数量上的差异还往往造成两个本来很相近的群体间的生殖隔离而形成新种。染色体组型和染色体的带型都代表着种的特性,它为不同动物在分类研究和确定其在进化过程中的位置提供了一个新的和重要的标准。可是,染色体的结构既是稳定的,同时又是可变的。染色体组型的改变是以染色体组的结构特点为基础     

The discovery of triploid Lycoris sprengeri Comes ex Baker from Anhui,China

Lycoris sprengeri Comes ex Baker is endemic to China. Reported in the present paper are the chromosomes number and karyotypes for two wild populations of the species from Anhui. ( 1 )Caishi population has a karyotype 2n=33=9st+21t+3T. The length of chromosomes ranges from 5.58～9.15μm. The karyotype belongs to Stebbin’s (1971) “4A”. (2)Longyashan populations have two karyotypes. The karyotype formula of the type I is 2n=22=8st+14t, with chromosomes ranging from 6.88～9.15μm. The karyotype belongs to “4A”. The karyotype formula of the type Ⅱ is 2n＝22＝1m+1sm+14st+6t, with chromosomes ranging from 7.20～15.80μm. The karyotype belongs to “3B”. The triploid type of L. sprengeri was discovered in Anhui for the first time. The karyotype 2n=22 =1m+1sm+14st+6t in diploid type of this species is here reported for the first time.The Robertsonian change plays a key role in karyotype evolution of Lycoris.     

On the Genus Ceterachopsis (J. Sm.) Ching

eterachopsis was proposed by the senior author as an independent genus of the family Aspleniaceae in 1940 with 2 species. Since then much study on its morphology, anatomy, gametophyte and palynology has been carried out by Nayar, Bir, Chandra & Nayar and Chang et al., and they are of the opinion that the genus like Ceterach, is a comparatively primitive element in the family Aspleniaceae. The queer zigzag patern of cutting of lanceolate fronds appears extraordinary in the family Aspleniaceae, and also suggests its antiquity in evolution. So far only 3 species (C. dalhousiae, C. paucivenosa and C. magnifica) are recognized, the former from W. Himalayas, also known from Africa, while the latter two from W. S. China (Yunnan). However, in the past forty years the Chinese botanists have discovered 2 more species as new in N. W. Yunnan, thus bringing the total known species of the genus up to 5. The present paper is a brief summary on the genus Ceterachopsis, which will be published in detail in the Flora Sinica vol. 4. Pteridologists are also divided in their views regarding the generic status of Ceterachopsis with 5 well-defined species in Yunnan and the East Himalayas. We prefer to mintain it as a genus separate from Asplenium on account of its distinct morphological features. It is to be hoped that more species may come to light in the mountainsin N. W. Yunnan through further exploration now under way.     

Karyology of the genus Faberia (Cichorieae–Asteraceae) and its systematic implications

Faberia Hemsl., a small genus of six species in the tribe Cichorieae, Asteraceae, has been karyologically investigated for the first time. All four studied species were revealed to have the somatic chromosome number 2n = 34, and thus the basic number of the genus was assumed to be x = 17. This rather high basic number has been previously reported very rarely in the tribe, occurring otherwise only in Warionia Benth. & Coss., a monospecific genus endemic to northwestern Africa, and in the American species of Lactuca L. The chromosome morphology was very similar among the four species, with the majority being median centromeric (m) and a few submedian centromeric (sm). In all the karyotypes the chromosomes were medium‐sized (6.33–1.61 μm), and showed a steady gradation in length from the longest to the shortest, with no evidence of bimodality. Our results strongly support the recognition of Faberia as an independent genus and the inclusion of Faberiopsis Shih & Y. L. Chen in Faberia.     

类叶升麻具有毛茛科中最对称和最原始的核型吗?

根据以前的报道,类叶升麻 Actaea asiatica Hara具有10条大型的中部着丝点染色体和6条较大 的近中部着丝点染色体,其核型在毛茛科中显得最为对称和原始,而类叶升麻属的其他种类具有10条 大型的中部着丝点染色体、4条较大的近中部着丝点染色体和两条没有短臂的染色体。在毛茛科中,同 一属的染色体形态通常十分相似,因此上述类叶升麻的核型分析结果十分可疑。本文重新检查子该种 的染色体。结果表明其核型与该属其他种类的核型没有明显区别。与升麻属其他4属,即 Beesia, Anemonopsis,Souliea,Cimicifuga相比,类叶升麻及该属其他种类都具有两条没有短臂的T染色体,因 此类叶升麻属 Actaea L．的核型不对称性程度在升麻族中显得最高,其核型在该族中也可能最为进化, 这两条T染色体可以作为类叶升麻属的细胞学标志,据此可以将该属与升麻族其他4属区别开来。     

Chromosome evolution in the genus Mikania (Compositae)

Karyotypic analysis of ten species of the genus Mikania was carried out using Feulgen staining. Species belonging to the following sections were analyzed: Section Thyrsigerae containing M. additicia (2n = 34), M. hemisphaerica, M. lanuginosa, and M. punctata (2n = 36), and Mikania sericea (2n = 42), which adds a new basic chromosome number (x = 21) to the genus and to the tribe Eupatorieae; Section Corymbosae with M. hastato-cordata (2n = 34) and M. involucrata and M. microptera with 2n = 36 chromosomes; Section Spicato-Racemosae with M. sessilifolia, with 2n = 108 chromosomes. One unidentified species with 2n = 34 chromosomes was also analyzed. All the species studied show one large pair of chromosomes with a secondary constriction in the middle region of the long arm. The morphology of this chromosome suggests that it can be considered as a cytological marker for the genus. Because of the distinctive inflorescence types found in the genus Mikania and the high frequency of species with x = 18, a correlation between morphological and chromosomal evolution is discussed. The present study suggests that the basic original chromosome number for the genus is x = 18, from which the others (x = 17, 19, 20, 21) have been derived by aneuploidy to form the observed aneuploid series.