萨罗罗非鱼与尼罗罗非鱼正反杂交子代间的分子遗传学差异

用耐盐能力强的萨罗罗非鱼和生长性能优的尼罗罗非鱼进行人工正反杂交,对两者正反交F1代微卫星分子遗传学差异进行了研究,结果如下:(1)两亲本及其正反杂交子代间都有特异的微卫星分子标记.(2)群体遗传多样性指标大都是尼萨罗非鱼>尼罗罗非鱼>萨尼罗非鱼>萨罗罗非鱼.(3)群体内平均遗传相似指数为:萨罗罗非鱼>萨尼罗非鱼>尼罗罗非鱼>尼萨罗非鱼.(4)萨罗罗非鱼对杂交子代的影响要远大于尼罗罗非鱼;正交子代尼萨岁非鱼可能在生产上更有利用价值和具有更高的选育潜力.     

杂交鳢(斑鳢 ♀ ×乌鳢 ♂ )及其自交后代细胞核型初步分析

对杂交鳢(斑鳢♀×乌鳢♂)(Channa maculata ♀×C.argus ♂)及其自交后代的细胞核型进行了初步分析.结果表明,杂交鳢染色体数目为2n=45,核型公式为3m+4sm+6st+32t,染色体臂数(NF)为52;杂交鳢自繁后代群体存在两种染色体核型,一是染色体数目为45,核型公式为3m+4sm+6st+...     

吉丽罗非鱼(尼罗罗非鱼♀×萨罗罗非鱼♂)及其两亲本遗传变异的微卫星分析

吉丽罗非鱼是由耐盐性较强的萨罗罗非鱼做父本与生长速度较快的尼罗罗非鱼做母本进行杂交、杂交后代自交产生,2009年全国水产原良种审定委员会审定为养殖新品种。为了分析吉丽罗非鱼及其两亲本遗传特性,选择有代表性的6对微卫星引物,对这3种罗非鱼遗传变异进行研究分析。研究结果表明:(1)6对微卫星引物扩增产物片段大小为180～350bp,共发现21个等位基因,鱼类群体间、微卫星座位间及等位基因间都存在极显著差异。(2)有效等位基因数(Ne)、Nei's基因多样指数(H)和多态信息含量(PIC)值等群体遗传多样性指标都是吉丽罗非鱼>尼罗罗非鱼>萨罗罗非鱼,吉丽罗非鱼PIC值达到了0.657,属于高度多态性。(3)吉丽罗非鱼与萨罗罗非鱼的遗传距离要比与尼罗罗非鱼的近,萨罗罗非鱼对吉丽罗非鱼的遗传影响要大于尼罗罗非鱼。     

二倍体铁破锣的核型及四倍体细胞型的首次发现

本文重新检查了铁破锣的核型。来自湖南新宁的40个个体中,1个个体为四倍体,其核型公式为2n＝4x=32=16m+8sm+4st+4t;其余个体为二倍体,其核型公式为2n＝2x＝16=8m+4sm+2st+2t。来自云南大理的10个个体全为四倍体,其核型公式为2n=4x=32＝16m+8sm+4st+4t。据此认为商效民(1985)报道的该种的核型分析结果有误。他至少将第4对染色体的着丝点位置辨认错了。该对染色体不具有中部着丝点而实际上具有近端部着丝点。本文还比较了铁破锣和角叶铁破锣的核型差异,并详细讨论了铁破锣属的系统位置。     

杨属派间核型比较研究

对杨属五派代表种的核型进行了分析,各代表种核型公式如下:欧洲山杨(白杨派)2n=2x=38=21m(2SAT)+4sm+13st(1SAT);小叶杨(青杨派)2n=2x=38=1M+26m(1SAT)+8sm(1SAT)+1st+2t(1SAT);大叶杨(大叶杨派)2n=2x=38=2M+22m+8sm+6st;胡杨(胡杨派)2n=2x=38=2M+23m+3sm+10st(2SAT);箭杆杨(黑杨派)2n=2x=38=3M+29m(2SAT)+5sm+1st。杨属派间核型差异主要表现在中部与次中部着丝点(M,m)和近端部与端部着丝点(st,t)染色体数目上。白杨派和胡杨派具较多的st、t染色体,核型不对称系数比其它派高。按Stebbins理论白杨派和胡杨派属进化类型。     

尼罗尖吻鲈和鳜鱼染色体组型分析及比较

采用PHA、秋水仙碱腹腔或背部肌肉注射,活体培养法,以前肾为材料,低渗-空气干燥法制片,进行染色体观察,运用Micromeasure version 3.3染色体分析软件和Photoshop 7.0软件首次分析了尼罗尖吻鲈的染色体数目和核型,并同鳜鱼染色体数目和核型进行了分析比较,对今后拟采取的杂交尝试提供理论基础。结果显示：尼罗尖吻鲈染色体众数为2n=48,核型公式为2m+4sm+12st+30t,染色体臂数（NF）为54;鳜鱼染色体众数为2n=48,核型公式为6sm+12st+30t,染色体臂数（NF）亦为54;两种鱼染色体短臂上均无随体,单臂染色体较多。分析表明尼罗尖吻鲈与鳜鱼杂交成功的可能性较大。     

九种水鳖科植物染色体数目及其核型分析

本文报道了我国产水鳖科植物5属9种染色体数目和核型,发现所有种都是二倍体,它 们的核型大部分是由中部着丝点(m)和近中部着丝点(sm)组成,少数种具有近端着丝点 (st)。它可以区分为4种核型：1A,2A和1B,2B。水筛属是原始的,黑藻属是进化的。     

7种橐吾属植物的核型

研究了7种橐吾属（Ligularia）植物的染色体和核形态。干崖子橐吾（L．kanaitzensis）的核型为2n＝2x＝58＝26m＋28sm 4st;窄头橐吾（L.stenocephala）的核型为2n=2x=58=26m 32sm;细茎橐吾（L.hookeri）的核型为2n=2x=58=30m 26sm 2st;宽戟橐吾（Llatihastata）的核型为2n=2x=58=28m 26sm(2sat) 4st;网脉橐吾（L.dictyoneura）的核型为2n=2x=58=26m 28sm 2st 2t;蹄橐吾（L.hodgsonii）的核型为2n=2x=58=28m 28sm 2t;棉毛橐吾（L.vellerea）的核型为2n=2x=58=22cm 34sm 2t。虽然这7个种的染色体数目相同,2n=58,核型主要是由m和sm染色体构成,但各类的染色体数目在种间有差异。核的对称性高,着丝点端值（T．C）为61．45％－64．96％。除窄头橐吾和鹿蹄橐吾的染色体数与前人报道的相同外,其它5个种的染色体数目和核型为首次报道。     

四福花染色体核型的分析

四福花[Tetradoxa ometensis (Hara)C.Y.Wu]体细胞具有36个染色体。其核型组成为2n=36=6m+14sm+4st+12t,即具有3对中部着丝点染色体,7对亚中部着丝点染色体,2对亚端部着丝点染色体和6对端部着丝点染色体。 四福花染色体核型分析表明,与传统对五福花科植物染色体具9基数的认识不同,其基数应为X=18。与Noguchi所发现的具18基数的三倍体五福花的核型相比较,二者在核型组成及染色体结构上都有明显差异。     

百合科六属十五种植物的细胞学研究

本文对云南西北部百合科6属15种的染色体和核型进行了报道。 (1)Clintonia udensis Trautv．et Mey间期核属于浓密分散型,前期染色体属于渐变型,分裂中期体细胞染色体2n=14=8m+4sm+2st(2SAT),核型不对称性属于2A型;(2)鹿药属四个种间期核属于复杂中央微粒型,前期染色体属于中间型,分裂中期体细胞染色体分别为Smilacina henryi(Baker)Wang et Tang,2n=36=12m+16sm+6st+2t(2SAT), 核型不对称性属于2C型;Smilacina fusca Wall., 2n=36=14m(2SAT)+12sm+10st(2SAT), 核型不对称性属于2B型; Smilacina tatsienensis(Franch．)Wang et Tang, 2n=36=22m+2sm+2st(2SAT), 核型不对称性属于2C型;Smilacina atropurpurea(Franch．)Wang et Tang,2n=36=18m+6sm(2SAT)+12st,核型不对称性属于2C型;(3)黄精属四个种的间期核属于复杂中央微粒型,前期染色体属于中间型,分裂中期体细胞染色体分别为Polygonatum kingianum Coll．et Hesml．,2n=30=12m(2SAT) +6sm+lst+2t, 核型不对称性属于2C型; Polygonatum cirrhifolium(Wall．) Royal,2n=30=10m+4sm+12st+4t, 3C型; Polygonatum curvistylum Hua, 2n=78=24m(2SAT)+14sm(6SAT)+40st, 核型不对称性属于3C 型; Polygonatum cathcartii Baker,2n=32=12m+6sm+10st+2t+2bs,核型不对称性属于2C型;(4)百合属,假百合属,豹子花属三个属的间期核和前期染色体形态相似,都属于复杂中央微粒型,前期染色体属于中间型,分裂中期体 细胞染色体分别为Lilium henricii Franch,2n=24=2m(2SAT)+2sm+10st+10t,核型不对称性属于3A型;Lilium bakerianum Coll．et Hesml．var． rubrum Stearn, 2n=24=4m (2SAT)+10st+10t(2SAT),核型不对称性属于3A型;Nomocharis bilouensis Liang 2n=24=2m(2SAT)+2sm+12st+8t,核型不对称性属于3A型;Nomocharis pardanthina Franch．,2n=24=4m(2SAT)+12st (2SAT)+8t,核型不对称性属于3A型;Nomocharis sauluensis Balf, f.,2n=24=4m(2SAT)+10st(2SAT)+10t,核型不对称性属于3B型;Notholirion campanulatum Cotton et Stearn2n=24=2m(2SAT)+2sm+14st(2SAT)+6t,核型不对称性属于3A型。     

A Chromosomal Study on 7 Species of Smilax L.

The chromosome numbers and karyotypes of 7 species of Smilax L. in Liliaceae (s. 1.) are cytotaxonomically studied in this work. Their karyotypic characters, distinction between the species and the chromosomal basis of sexual differentiation are discussed. The karyotypes of most species are first reported. The results are shown as follows (see Tables 1-4 for the chromosome parameters and the karyotype constitution; Fig. 1 for their idiograms): 1. Smilax nipponica Miq. The species is one of the herbaceous species distributed in East Asia. Two karyotypes, 2n = 26(type A) and 2n = 32 (type B), are found in the species (Plate 1: 1-7). The karyotype of No. 88032 (uncertain of -L--M--S- sexuality) is 2n = 26 = 2m + 6st + 6m + 4sm + 6sm + 2st. The karyotype has 4 pairs of L chromosomes, of which the first three pairs are subterminal, and the 4th is median. The karyotype belongs to 3B. No. 88045 (the male) and No. 88046 (the female) have 2n = 32. Their karyotypes are basically uniform, and both are -L--M-- S 2n=32= 2m+4sm+ 2st+ 2m+4sm+ 6m+ 10sm + 2st, also with 4 pairs of L chromosomes, but the 2nd pair is median, and thus different from the type A. The karyotype belongs to 3B. The first pair of chromosomes of the male are distinctly unequal in length, with the D. V. (0.93) of relative length between them obviously greater than that of the female (0.1). The pair seems to be of sex-chromosomes. Sixteen bivalents (n= 16) were observed at PMCs MI of No. 88045 (Plate 1: 4). The major difference between the karyotypes A and B are greater relative length of L chromosomes in the type A than in the type B, and the increase of chromosome number in the karyotype B mainly due to the increase of st chromosomes. Nakajima (1937)reports 2n= 30 for S. hederacea var. nipponica (=S. nipponica, Wang and Tang, 1980). 2. S. riparia A. DC. This species is also herbaceous, distributed in East Asia. Thirty chromosomes were found in root-tip cells (uncertain of sexuality). The kar -L--M--S-yotype is 2n = 30 = 8st + 6sm + 2st + 6m + 6sm + 2st (Plate 3: 1, 5), consisting mainly of sm and st chromosomes. There are 4 pairs of L chromosomes which are all subterminal and the m chromosomes appear to fall all into S category. Though the karyotype belongs to 3B, it is less symmetrical than that of S. nipponica. The species is karyologically rather different from S. nipponica, therefore. The first pair of chromosomes of this material are unequal in length, and it may be a male. The karyotype of this species is first reported. 3. S. sieboldii Miq. The species is a thorny climbing shrub, distributed in East Asia. At PMCs All, 16 chromosomes (n= 16) were found (Plate 2: 6), in accordance with Nakajima's (1933) report for a Japanese material. 4. S. china L. This species, a thorny climbing shrub, is of a wide distribution range mainly in East Asia and Southeast Asia. Two karyotypes were observed in different populations. (1) The population from Xikou has 2n = 96(6x) = 20st+L- -M- 6t + 6sm + 12st + 52(S) (Plate 3:7), of which the first three pairs of chromosomes are terminal, different from those in the other species. The arm ratios of both L and M chromosomes are larger than 2.0, which resembles those of S. davidiana. (2) PMCs MI of the population from Shangyu shew 15 chromosomes (n 15). The hexaploid of the species is recorded for the first time. Hsu (1967,1971) reported 2n = 30 from Taiwai and Nakajima (1937) recorded n = 30 from Japan, which indicates that the karyotype of the species varies not only in ploidy, but also in number. 5. S. davidiana A. DC. The somatic cells were found to have 32 chromosomes, and PMCs MI shew 16 bivalents (Plate 2: 1-5). The karyotype is 2n = 32=-L- -M- -S 8st + 4sm + 4st + 8sm + 8st. The karyotype belongs to 3B, and is less symmetrical than those in herbaceous species. The D. V. (0.20) of relative length between the two homologues of the first pair is slightly larger in the male than in the female (0.14), and it is thus difficult to determine whether they are sexual chromosomes or not. 6. S. glabra Roxb. The species is a non-thorny climbing shrub, distributed in East Asia and Southeast Asia. 32 chromosomes were found in somatic cells. The -L- -M- - Skaryotype is 2n= 32= 8st + 10st+6sm+8st (Plate 3: 2, 6),with only 3 pairs of sm chromosomes (12, 13 and 16th). The karyotype is more asymmetric than that of S. davidiana, although it is also of 3B (Table 1). The karyotype is first reported for the species. 7. S. nervo-marginata Hay. var. liukiuensis (Hay.) Wang et Tang The variety has a relatively narrow distribution range, mainly occurring in eastern China. The chromosomal number of somatic cells is 2n= 32 (Plate 3: 3-4). The karyotype is -L- -M- -S 2n = 32 = 2sm + 6st + 2sm + 2st + 2m + 6sm + 12st, evidently different from that of S. glabra. The first pair of chromosomes are submedian, and much longer than the 2nd to 4th pairs. The ratio in length of the largest chromosome to the smallest one is 4.3. The symmetric degree is of 3C, a unique type. The karyotype of the species is reported for the first time. In Smilax, the known basic numbers are 13, 15, 16 and 17. The two herbaceous species distributed in East Asia have three basic numbers: 13, 15 and 16, while the woody species studied mainly have 16, with no 13 recorded. Mangaly (1968) studied 8 herbaceous species in North America and reported 2n=26 for them except S. pseudo-china with 2n=30. Mangaly considered that a probably ancestral home of Smilax, both the herbaceous and woody, is in Southeast Asia and the eastern Himalayas, and speculated that the ancestral type of Sect. Coprosmanthus is possibly an Asian species, S. riparia. The karyotypes of the two herbaceous species in East Asia consist mostly of sm and m chromosomes, whereas those for the North American species are all of st chromosomes. Based on the general rule of karyotypic evolution, i.e. from symmetry to asymmetry, his speculation seems reasonable. Researches on sex-chromosomes of Smilax have been carried out since 1930 (Lindsay, 1930; Jensen, 1937; Nakajima, 1937; Mangaly, 1968), and they are generally considered to be the largest pair, but there is still no adequate evidence. The result of our observation on S. nipponica may confirm that the first pair of chromosomes of this species is XY type of sex-chromosomes. Chromosomes of the genus are small and medium-sized, varying between 1-6 μm, slightly larger in herbaceous species than in woody ones, larger in the karyotype of 2n=26 than in that of 2n=32. Based on karyotype constitution of the above 5 species, the karyotype in the genus is characterized by 4 pairs of L chromosomes and 2-5 pairs of M chromosomes, and mostly st and sm chromosomes, and by rather asymmetrical 3B type. The degree of symmetry in the above 5 species is from Sect. Coprosmanthus to Sect. Coilanthus, and herbaceous species towoody ones.     

Cytogenetic analysis and description of the sexual chromosome determination system ZZ/ZW of species of the fish genus Serrapinnus (Characidae, Cheirodontinae)

Four populations of Serrapinnus notomelas and one population of Serrapinnus sp.1, both belonging to the subfamily Cheirodontinae, were analyzed by Giemsa and silver nitrate impregnation techniques. We found 2n = 52 chromosomes for all populations, with interspecific differences in the karyotype formula; S. notomelas showed 16 m + 22 sm + 10 st + 4a, with fundamental number (FN) = 100 for males, and 16 m + 23 sm + 10 st + 3a, with FN = 101 for females. Serrapinnus sp.1 had 8m + 16 sm + 4 st + 24 a, with FN = 80 for males, and 8m + 15 sm + 4 st + 25 a, with FN = 79 for females. The difference in FN for the two sexes is due to a pair of heteromorphic chromosomes in the females of both species, which characterizes a ZZ/ZW-type mechanism of chromosome sexual determination. Interspecies differences were also found in nucleolus organizer regions (NORs). A simple NOR system was detected in three of four S. notomelas populations, while Serrapinnus sp.1 had two chromosome pairs with NOR. Although S. notomelas and Serrapinnus sp.1 have the same diploid number, differences in the karyotype structure indicate that these are different species. Apparently there was pericentric inversion during the karyotype evolution of these species.     

Report on Karyotypes of 10 Species of Liliaceae (s. l.) From Qinling Range

The karyotypes of 10 species of the Liliaceae from the Qinling Range are reported as follows. I. Polygonatum Mill. (1) P. odoratum ( Mill. ) Druce was found to have the karyotype 2n=20=12m+8sm ( Plate 3, Fig. I), which belongs to Stebbins’ (1971) karyotype classification 2B. The chromosomes range from 3.88 to 11.26μm in size. Table 2 shows the karyotypes and number fundamentals (N.F.) of 13 materials from 12 different localities. The N. F. of these materials can be classified into two groups: N.F. =36 and N.F.=40, besides one (N.F. =38) from Beijing. N. F. =36 covers all the materials with 2n= 18 which have relatively symmetrical karyotypes ( all consisting of m and sm chromosomes), one with 2n=20 (10m+6sm+4st) and one with 2n=22 (14m+8st). N.F. =40 include four materials with 2n= 20 (all of m and sm chromosomes ) and 3 with 2n= 22 (10m+ 8sm+ 4st). ￥ It is considered that there are two original karyotypes, 2n= 18 with N. F. = 36 and 2n= 20 with N.F. =40, which are relatively symmetrical. All the more asymmetrical karyotypes with some st chromosomes have probably evolved from the symmetrical karyotypes without st chromosomes by centric fission. (2) P. zanlanscianense Pamp. has the karyotype 2n=30=18m(2SAT) + 4sm+ 6st+ 2t (Plate 1, Fig. 1) which belongs to 2C. The chromosomes range from 2.16 to 9.76μm. ￥ II. Asparagus filicinus Buch.-Ham. ex D.Don. The karyotype of this species is 2n = 16= 8m(2SAT )+ 6sm + 2st (Plate 1, Fig. 1 and Table 3 ) , which belongs to 2B. The chromosomes range from 2.33 to 5.30μm. Most species in Asparagus, including A.Filicinus, are reported to have basic number x= 10, and therefore 2n= 16 is a new chromosome number for A.filicinus. EL-Saded et.al.(1972) gave a report of n=8 for A. stipularis from Egypt, while Delay (1947) reported 2n = 24 for A. trichophyllus and A. verticillatus, Sinla(1972 ) gave a report of 2n=48 for A.racemosus. It is certain that there are two basic numbers in the genus Asparagus. III. Cardiocrinum giganteum (Wall.) Makino was found to have the karyotype 2n=24=4m+8st+12t (Plate 1, Fig. 1 ), which belongs to 3B. The chromosomes range from 8.71 to 20.24μm. IV. Smilax discotis Warb. was shown to have the karyotype 2n=32=4m+22sm+4st (2SAT)+2t (Plate 1, Fig. 1 and Table 3), which belongs to 3C. The first pair is much longer than others. The chromosomes range from 1.79 to 9.21μm. The chromosome number and karyotype of S. discotis are both reported for the first time. V. Reineckia carnea (Andr.) Kunth is of the karyotype 2n=38=28m+10sm (Plate 2, Fig. 1 ), which belongs to 2B. The chromosomes range from 5.65 to 12.75μm. VI. Tupistra chinensis Baker was found to have the karyotype 2n=38=25m+ 13sm (Plate 2, Fig. 1), which belongs to 2B. The chromosomes range from 8.11 to 23.82μm. A pair of heterozygous chromosomes is arranged at the end of the idiogram. The eighth pair possesses an intercalary satellite. Huang et al. (1989) reported the karyotype of T. chinensis from Yunnan as 2n = 38 = 24m+ 14sm without any intercalary satellite. Nagamatsu and Noda (1970) gave a report on the karyotype of T. nutans from Bhutan, which consists of 18 pairs of median to submedian chromosomes and one pair of subterminal chromosomes. And one pair of submedian chromosomes possess intercalary satellites on their short arms. VII. Rohdea japonica (Thunb) Roth. was found to have the karyotype 2n=38=30m+6sm+2st ( Plate 2, Fig. 1), which belongs to 2B. The chromosomes range from 7.94 to 18.29μm. Nagamatsu and Noda (1970) reported that the karyotype of R.japonica from Japan was the same as that of Tupistra nutans from Bhutan. But we have not discov ered any chromosome with an intercalary satellite. VIII. Hosta Tratt. (1) H. plantaginea (Lam.) Aschers was shown to have 2n=60. The 60 chromosomes are in 30 pairs,which can be classified into 4 pairs of large chromosomes (7.32- 8.72μm ), 3 pairs of medium-sized ones (4.72-5.60μm), and 23 pairs of small ones (1.40-3.64μm), (Plate 3 ,Table 4 ). The karyotype of H. plantaginea is reported for the first time. (2) H. ventricosa (Salisb.) Stearn was counted to have 2n=120, The 120 chromosomes are in 60 pairs, which can be classified into 8 pairs of large chromosomes (7.00- 8.40μm ), 6 pairs of medium-sized ones(4.40- 6.15um ), 46 pairs of small ones (1.20- 3.85μm), (Plate 3, Table 4). Based on the karyotypes of H. plantaginea and H. ventricosa, the latter is probably a tetraploid in the genus Hosta. Kaneko (1968b) gave a report on the karyotype of H. ventricosa, which is of8 pairs of large chromosomes, 4 pairs of medium-sized and 48 pairs of small ones.     

水稻(Oryza sativa)核型分析

水稻(Oryza sativa)核型分析结果:在12对染色体中,具中部着丝点的有5对,近中部着丝点的有6对(包括随体染色体),1对近端部着丝点。本文还着重讨论了随体的数目及所在的染色体。     

Karyotype Variation and Evolution of Sect. Thea in Guizhou

Karyotypes of seven species, one variety and 11 forms of Sect. Thea occurring in Guizhou Province, were investigated by the wall degradation hypotonic method. The micrographs of their somatic metaphase are shown in plates 1-2 and the parameters of chromosomes according to Li and Chen (1985) are given in Table 1 and the idiograms in Fig. 1. The karyotype formulae are as follows: Camellia quinquelocularis 22=30=24m+6sm; C. tetracocca 2n=30=22m+8sm; C. taliensis 2n=30=22m+8sm; C. gymnogyna 2n=30=22m +6sm+2st and 2n=30=20m=8sm+2st; C. gymnogynoides 2n=30=22m +6sm+2st and 2n=30=20m+8sm+2st; C. jungkiangensis 2n=30=20m+8sm+2st; C. sinensis 2n =30+20m+8sm+2st, and C. sinensis var. ruoella 2n=30=20m+8sm+2st. All the karyotypes belong to Stebbins “2A”. The following main aspects are discussed. 1. Chromosome numbers: All these species are found to have 2n=30. Based on the previous and present reports, It clearly indicates that evolution of this group has taken place mainly on diploid level, but not on polyploid one. 2. The karyotype variation: Generally, all the karyotypes examined are similar, but according to symmetry of karyotype, they may be grouped into two types. One is characterized by metacentric (m)and submetacentric (sm)chromosomes, involving C. quinquelochlaris, C. tetracocca, C. taliensis, while the other is characterized by a pair of subtelocentric (st) chromosome besides m and sm chromosomes, involving C. gymnogyna, C. gymnogynoides, C. jungkiangensis, C. sinensis and C. sinensis var. ruoella. It is suggested that the mechanism for karyotype variation and speciation in Sect. Thea be pericentric inversion or reciprocal translocation. The first type is more symmetrical than the second one, and is thus relatively primitive. 3. The orginal center of Sect. Thea: Based on the analysis of karyotypes, morphological characters, geographical distribution and biochemical features, the authors consider that the Yunnan-Guizhou plateau including the contiguous area in Yunnan, Guangxi and Guizhou is the original center, from where it radiated, resulting in the present distribution pattern of Sect. Thea.4. Taxonomic treatment of Sect. Thea: The taxonomic treatment of Sect. Thea is complicated and still confused up to now. The number of species is more than 40 according to Zhang’s taxonomic system (1984), but, recently, most of them are reduced by Min (1992). Further work should be based on the concept of morphological discontinuity and in formation from other branches of sciences. Whether two types of karyotype are two biological species remains questionable.     

Cytotaxonomical Studies on Liliaceae (s.l.): (2) Report on Chromosome Numbers and Karyotypes of 8 Species of 8 Genera from Zhejiang,China

Eight species in eight genera of Liliaceae from Zhejiang were cytotaxonomically studied in this work. The karyotypes of Chinese materials of these species are mostly reported for the first time. The results are shown as follows (see Table 2-4 for chromosome parameters of them): 1. Disporum sessile D. Don Sixteen chromosomes are counted at metaphase of roottip cells.The Karyotype formula is 2n=16=2lm+2sm+4st+2sm+3sm+ 1sm(SAT)+2st (Plate 1: 2-3, see Fig. 1:1 for its idiogram). The Karyotype belongs to 3B in Stebbins’ (1971) karyotype classification, and consists of four pairs of larger chromosomes (1-4) and four pairs of smaller chromosomes (5-8). One SAT-chromosome is situated at the sixth pair. The chromosomes range between 4.85-16.63μm. The karyotypic constitution is similar to that of Japanese material reported by Noguchi (1974). Chang and Hsu (1974) reported 2n=14=13st+1sm and 2n= 16=2m + 13st + 1sm for the material from Taiwan under the name of D. shimadai Hay. (=D. sessile D. Don). Compared with our result of D. sessile, the differences are obvious. 2. Polygonatum odoratum (Mill.) Druce PMCs diakinesis shows eleven bivalents, n = 11, 5 large and 6 small (Plate 2:5). The meiosis is normal. The majority of reports of this species are 2n=20, with a few 2n=22 and 30 (see Table 1). The materials from southen Siberia and the Far East in USSR are all of 2n= 20. Our result is the same as recorded by Jinno (1966) in the Japanese material and by Li (1980) from Beijing. Ge (1987) reported 2n=20 in the cultivated individuals of Shandong, China, showing that both 2n=20 and 22 exist in China. 3. Scilla scilloides (Lindl.) Druce This species has the somatic chromosome number 2n=18 (Plate 1: 4-6, see Fig. 1:2 for its idiogram), of which two groups of chromosomes can be recognized, i.e. the 1 st -5 th pairs of large and the 6 th-9th pairs of small chromosomes. A distinct character of the karyotype is that two satellites are attached to the short arms of the 1st pair of chromosomes. The degree of asymmetry is of 3C. The karyotype formula is 2n = 18 = 2sm (SAT) + 6st + 2t+ 6m + 2sm. The chromosomes range from 2.02 to 11.93 μm. The Previous counts on the species are 2n = 16, 18, 26, 34, 35, 36 and 43 (see Table 1). The present investigation confirms Noda’s and Haga’s results. The species is considered to be of two genomes, namely A(x = 8) and B(x = 9). Our result shows a genome composition of BB, having a pair of large SAT-chromosomes. Chang and Hsu (1974) reported 2n = 34 from a population of Taiwan, an amphidiploid (AABB), Karyotypes of other Chinese populations are worth further researches. 4. Tricyrtis macropoda Miq. The chromosome number of somatic cells is 2n= 26, and PMCs MII shows 13 bivalents (n= 13) (Plate 3:1-3, see Fig. 1:3 for its idiogram). The karyotype formula is 2n= 26= 6m + 10sm + 6st + 4st (or t), which is composed of chromosomes: 4L + 22S in size. The degree of asymmetry is of 3B. No centromeres of the 12th and 13th pairs of chromosomes were observed at metaphase, and the chromosomes may be of st or t. Nakamura (1968) reported 2n= 26(4L+ 22S)= 2sm+ 2sm-st+ 14st-sm+ 8st for T. macropoda Miq. and 2n= 26(4L+ 22S)= 8m+ 2sm+2sm-st+ 2st-sm+ 12st for its ssp. affinis, both from Japan. It is clear that the major character of their karyotypes, i. e. 4L + 22S, is consistent with that reported here. Based on the previous and present reports, all Tricyrtis species studied are remarkably uniform in the basic karyotype, i. e. 4L + 22S. 5. Allium macrostemon Bunge. The present observation on the root-tip cells of the species shows 2n = 32 (Plate 3: 4-5, see Fig. 1:4 for its idiogram). The karyotype formula is 2n (4x)= 32= 26m + 6sm, which belongs to 2B, being of high symmetry. Except the 6th, 10th and 13th pairs of chromosomes all the are metacentric. Chromosomes of this species are large, ranging from 5.94 to 18.06 μm. Our result agrees with Kawano’s (1975) report under the name of A. grayi Regel ( = A. macrostemon, Wang and Tang 1980). 6. Asparagus cochinchinensis (Lour.) Merr. Ten bivalents were observed in PMCs MI, n=10 (Plate 1: 1). The present result confirms the number of a population of Taiwan recorded by Hsu (1971). 7. Ophiopogon japonicus (L. f.) Ker-Gawl. The species from Mt. Taogui, Hangzhou, is found to have 2n (2x)=36=22m + 14sm (Plate 2: 1,5, see Fig. 1:5 for its idiogram) which belongs to 2B. The karyotype is composed of 2 medium-sized chromosomes with metacentric centromeres and 34 small chromosomes, ranging from 1.34 to 4.92 μm. The populations from Mt. Tianzhu and Mt. Yuling, Zhejiang, are found to be aneuploids at tetraploid level (2n=64-70). It is interesting that Nagamatsu (1971) found the karyotypes of Japanese materials to be 2n= 67 and 68, also showing unsteady 4x karyotypes of this species. In the previous. reports (see Table 1), the chromosome numbers of this species are mainly 2n = 72, besides 2n = 36 recorded by Sato (1942) from Japan. 8. Liriope platyphylla Wang et Tang The somatic complement of the species collected from Mt. Tianzhu, Hangzhou, is 2n = 36 (Plate 2: 3-4, see Fig. 1:6 for its idiogram). The karyotype is 2n(2x) = 36 = 16m + 20sm, belonging to 2B type. The chromosomes are small except the medium-sized, 1st pair and the range is from 1.27 to 5.19μm. The material from Mt. Yuling, Zhejiang, is found to have a variety of chromosome numbers (2n= 60-71), as observed in Ophiopogon japonicus. Hasegawa (1968) reported the karyotype of 2n = 72 (4x) from Japan The 2x karyotype is first recorded. This genus is closely related to Ophiopogon. Based on the Hasegawa’s and present studies, all the species in these two genera are remarkably uniform in karyo-type. Therefore, the taxonomy of the two genera is worth further researches.     

小檗科鬼臼亚科植物的核型研究

本文首次报道了中华山荷叶与川八角莲的核型,分别为Ｋ（２ｎ）＝１２＝８ｍ（４ＳＡＴ）＋２ｓｔ＋２ｔ及Ｋ（２ｎ）＝１２＝４ｍ（２ＳＡＴ）十４ｓｍ＋２ｓｔ（２ＳＡＴ）＋２ｔ,核型类型均为ＺＡ型。本文报道的桃儿七及八角莲的核型与前人的结果有一定差异,前者为：Ｋ（２ｎ）＝１２＝６ｍ（４ＳＡＴ）＋２ｓｍ＋２ｓｔ＋２ｔ,２Ｂ型,后者为Ｋ（２ｎ）＝１２＝８ｍ（２ＳＡＴ）＋２ｓｔ（２ＳＡＴ）＋２ｔ,为２Ａ型。本文分析了小檗科鬼臼亚科４个属共７种植物的核型,结果是该类植物的核型极为相似,染色体数目均为２ｎ＝１２,由８条ｍ或ｓｍ,２条ｓｔ以及２条ｔ染色体组成。核型的相似性反映了这类植物的亲缘关系,这４个属的植物是一个自然类群。但随着系统发育,核型的不对称性有所增加,其中以山荷叶属最为对称,八角莲属居中,桃儿七属与足叶草属最不对称。笔者认为,核型上的高度相似是该类植物在系统发育上不发达,属内种类稀少,通常为寡种属或单种属的重要原因。     

水稻(Oryza sativa)核型分析

水稻(Oryza sativa)核型分析结果:在12对染色体中,具中部着丝点的有5对,近中部着丝点的有6对(包括随体染色体),1对近端部着丝点。本文还着重讨论了随体的数目及所在的染色体。