辣椒四个品种的核型研究

本文对我国栽培辣椒Capsicum annuum L.的四个品种即汉川椒、华椒一号、牛角椒和二金条进行了核型分析,其染色体数目均为2n=2x=24,核型公式均为2n=24=20m+2sm+2st,但汉川椒和华椒一号具一对随体,牛角椒和二金条具两对随体。本文还对它们的进化关系进行了讨论。     

内葵杂3号染色体核型分析

对内蒙古地区的栽培品种内葵杂3号三交种和单交种了进行了核型分析。其结果为:内葵杂3号三交种和单交种的染色体数均为2n=34,各具一对随体染色体。三交种第2对染色体具随体且为近中部着丝粒染色体,其余为中部着丝粒染色体,染色体相对长度变异范围4.105%～7.703%,核型公式为2n=2x=34=32m+2sm(2sat),核型类型属于1A型;单交种均为中部着丝粒染色体,第4对染色体具随体,染色体相对长度变异范围3.661%～8.128%,其核型公式为:2n=2x=34=34m(2sat),核型类型属于1B型。     

韭菜三个品种的核型研究(摘要)

本文研究了我国不同地区韭菜三个品种(尸州韭、青岛韭、银川韭)的核型。结果表明:三个品种的核型均为同源四倍体,其核型公式为2n=4x=32=28m+4st(SAT),第1—7号为具中部着丝点染色体,第8号为近端着丝点染色体并带有随体,但其中有二个染色体带有明显的随体,另二个染色体所带随体较难以分辨。三个不同品种之间,染色体全组总的长度、染色体相对长度、最长和最短的变异范围、臂比范围都存在一些差异,但并不显著。本实验不同品种韭菜的核型研究结果与文献记载相符,不同者为第8对带随体染色体为具中部着丝点。而有的作者测定为近端着丝点染色体。此外,对于带随体染色体类型的不同与随体显现的程度进行了初步讨论。     

苜蓿属3种不同花色基因型的染色体核型分析

基于形态学的显著差异,对紫花苜蓿(Medicago sativa L.)、黄花苜蓿(Medicago falcata L.)和白花苜蓿(Alfalfa with Cream flower)进行染色体核型分析,结果表明,3种类型的苜蓿材料在染色体核型方面有显著差别,白花苜蓿和黄花苜蓿都是随体染色体,其中,黄花苜蓿有2条为端部着丝点染色体,其核型公式分别为:紫花苜蓿2n=4x=24m+8sm、黄花苜蓿2n=4x=24m+6sm+2T(SAT)、白花苜蓿2n=4x=24m+8sm(SAT)。紫花苜蓿与白花苜蓿的染色体具有89%的相似性,只是在紫花苜蓿7号染色体和白花苜蓿15号染色体存在随体有无的区别;黄花苜蓿染色体具有独特性,显著区别于紫花苜蓿和白花苜蓿,但从其19号染色体来看,参与了紫花苜蓿或白花苜蓿的构建;白花苜蓿15号随体染色体与黄花苜蓿25号随体染色体和紫花苜蓿7号染色体有高度的相似性,但也存在随体有无的区别。     

四川葱属一新种及其核型

本文分析了该新种的核型,其核型公式为K(2n)＝2x＝16=14m+2st(2SAT),具一对居间随体,有时该居间随体不明显。核型的不对称性为2A型。     

加拿大引进的二倍体燕麦种质的核型鉴定

采用常规压片法对砂燕麦、西班牙燕麦和短燕麦3个二倍体燕麦种进行了核型研究。结果表明:砂燕麦染色体核型公式为2n=2x=14=10m+4sm(2SAT),具近中部和中部着丝点染色体,第4对染色体组的短臂上有1对随体,核不对称系数为68.17%;西班牙燕麦染色体核型公式为2n=2x=14=10m+4sm(2SAT),具近中部和中部着丝点染色体,第7对染色体短臂上有1对随体,核不对称系数为59.31%;短燕麦染色体核型公式为2n=2x=14=6m+4sm+4st(2SAT),具近端部、近中部和中部着丝点染色体,第6对染色体组的短臂上有1对随体,核不对称系数为63.91%。虽然3个燕麦种的核型均为2A,但它们的染色体形态有明显不同,比较认为砂燕麦相对进化,短燕麦次之,西班牙燕麦较原始。本研究对燕麦种质资源的核型分析及进化地位研究具有参考价值。     

番茄五个品种的核型研究（摘要）

本文研究了番茄五个不同品种(武昌大红、加拿大、佛特、荷兰五号、青北早)的核型。1.番茄的核型公式如下: (1) 武昌大红。2n=24=2M+8m+12sm+2st (2) 加拿大。2n=24=4M+8m+12sm (3) 佛特。2n=24=2M+8m+10sm+4st (4) 荷兰五号2n=24=2M+14m+8sm (5) 青北早2n=24=4M+8m+12sm 2、五个品种中都具有一对随体染色体,但位于那一对染色体上也有相同和相异。“武昌大红”与“佛特”的随体在第9对上。“加拿大”在第7对上。“荷兰五号”及“青北早”位于第4对染色体上,并发现“武昌大红”、“加拿大”品种的随体,在同一品种也出现随体大小的差异。3、在各个品种中,染色体的全长、相对长度、臂比都存在着一些差异。4、对于番茄染色体的随体的大小及其在染色体对数的位置,染色体的形态结构,核形与番茄起源的关系进行了初步讨论。     

四种草本花卉的染色体核型分析北大核心CSCD

采用常规制片方法对4种草本花卉的染色体数目、核型等进行了研究。结果分别为石竹(Diranthus chinensis)染色体数2n=14,核型公式为K(2n)=14=12 m+2 sm,其核型为"1A";裂叶花葵(Lavatera trimestrisLinn.)染色体数2n=14,核型公式为K(2n)=14=6 m+8 sm,核型为"2A";观赏椒(Capsicum frutescans)染色体数2n=24,核型公式K(2n)=24=24 m,核型为"1B";凤仙(Impatiens balsamina)染色体数2n=14,核型公式为K(2n)=2x=14=10 m+4 sm,核型为"1B"。此4种植物的染色体核型均为首次报道,可为花卉的良种选育和分类提供必不可少的依据。     

三尖杉科的核形态学研究

4种三尖杉科植物的核形态结构的研究结果如下:它们的间期核均为复杂染色中心型,分裂前期 染色体属于中间型,体细胞分裂中期染色体的核型为:(1)三尖杉Cephalotaxus fortuni Hook．F.,K2n= 24=21m+1M+2sm(2SAT),核型不对称性属于2A型,着丝点端化值(T.C.％)为53．99;(2)高山三尖 杉C.alpina(Li)L.K.Fu,K2n=24=19m+3M+2sm(2SAT),核型不对称性属于2A型,T.C.％值为 53.93;(3)海南粗榧(西双版纳粗榧)C.mannii Hook.f., K2n=24=22m(1SAT)+2sm(2SAT),核型不 对称性属于2A型,T.C.％值为54.47;(4)篦子三尖杉C.oliveri Mast.,K2n＝24＝22m+2sm(2SAT), 核型不对称性属于2B型,T.C.％值为53.53。4种三尖杉的染色体结构都是1～22号染色体为m染色 体,23和24号染色体为sm染色体并具随体,其随体较大而稳定。它们的核形态结构较为相似,从核型 参数上看似乎三尖杉和高山三尖杉的亲缘关系最近,种间的中期染色体结构也有一些细微差异。除三尖杉C．fortunei仅有染色体数目的报道外,这4个种的核形态研究为首次报道。     

滇蜀豹子花核型及其变异研究

本文详细报道了滇蜀豹子花的核型,发现居群中存在两种细胞型,即A型和B型。A型参考核型为2n = 24＝2m(2SAT)+2sm+8st(4SAT)+12t(2SAT),其第3号两条同源染色体长臂均无居间随体：B型参考核型为2n=24＝2m(2SAT)+2sm+8st(2SAT)+12t(3SAT)+0—1b,其第3号一条同源染色体长臂紧靠着丝点处有一大而明显的居间随体,而另一条同源染色体则无,构成明显的3号染色体的结构杂合性。统计表明,居群中二者的比例近似为1A;2B。研究还发现了大量的体细胞染色体结构变异核型,表明滇蜀豹子花核型尚未趋于稳定,还处于强烈分化之中,高频率的体细胞染色体结构变异是其种内分化不可忽视的一种进化要素。     

中国荞麦栽培品种的核型比较分析

通过对我国栽培的10个甜荞（Fagopyrun esculentum)品种和7个苦荞（F.tatricum)品种根尖染色体数目观察和核型比较分析,结果表明：甜荞和苦荞染色体数目都是由16条染色体构成的,2n=2x=16。甜荞有2对随体,而苦荞有1对随体,它们的核型公式分别为12m 4m(SAT)、12m 2sm 2sm(SAT);种内各品种在染色体相对长度、染色体长度比、随体染色体数目和形态等方面差异较小,但在种间的差异明显。     

玉米8个栽培亚种（类型）的核型和C—带带型的比较研究

本文首次报道了玉米8个亚种、2个亚型和2个杂交品种的核型和Giemsa C-带带型。所有材料的根尖细胞染色体数目均为2n=20。主要由中部和亚中部着丝点染色体组成。第6染色体短臂均具随体,但大小不同。所有材料均显示有亚端带和端带,在第6染色体的短臂上显示有NOR或/和随体带。C-带的分布、总数目和总长度各不相同。其总带数变异于6至18之间,C-带总长度为5.65—11.40％之间。在核型中,具中部着丝点的染色体数目及C-带总数,罕见栽培或原始的类型通常多于广泛栽培的类型。此外,有关核型和C-帝的变异和进化也进行了简略的讨论。     

3个彩色马蹄莲引进品种的核型分析

利用普通压片法对3个引进彩色马蹄莲(Zantedeschia hybrid)品种的染色体数与核型进行了分析。结果表明:所试验品种染色体数均为2n=32。染色体形态比较一致,多是由中部(m)以及近中部(sm)着丝粒染色体组成。其中,‘Allure’为2n=2x=32=14m(2SAT)+2sm,‘Cupdio’的核型公式为2n=2x=32=14m+2sm,Odessa的核型公式为2x=32=1M+15m(1SAT)。3个品种核型不对称系数分别为56.72%,56.25%和56.38%,核型分类显示其均为1A型。     

广东四个墨兰品种的核型研究

研究了广东四个墨兰品种金嘴墨兰、银边墨兰、企剑黑墨和企剑白墨的染色体数目和核型。结果表明,企剑黑墨和企剑白墨的染色体数目为2n=40,为二倍体,核型公式分别为：2n=2x=40=30m＋10sm和2n=2x=40=2M＋36m＋2st;金嘴墨兰和银边睾兰的染色体数目为2n=41,为非整倍体。4个墨兰品种的染色体结构主要由中部着丝粒染色体组成,除银边墨兰为1B型外,其它均为2B型。     

黄精属细胞分类学研究Ⅱ.四川金佛山地区黄精属植物核型

本文对四川金佛山地区4种黄精属植物的核型进行了研究,其结果为:滇黄精:2n=26=6m+12sm(2SAT)+8st(2SAT);距药黄精:2n=26=10m+4sm+12st;垂叶黄精:2n=30=14m(2SAT)+4sm+10st+2t、2n=28=14m+6sm+6st+2t;湖北黄精:2n=30=12m+8sm+10st、2n=28=6m+10sm+10st+2t、2n=22=2m+12sm 8st。通过与其它地区黄精属植物染色体数目与形态的比较,发现本地区所有种类的染色体数目普遍偏高,无论在染色体基数或染色体形态上都比较接近喜马拉雅山地区分布的种类。从实验结果进一步看出了黄精属的染色体变异是相当明显的,并主要表现为非整倍性变异;在有些情况下,染色体数目与结构的变异能与某些形态学特征相联系。     

Karyotypes and Giemsa C-banding patterns of Zebrina pendula, Z. purpusii and Setcreasea purpurea, compared with those of Tradescantia ohiensis.

It has been proposed that the genera Zebrina and Setcreasea of the family Commelinaceae should be united and reunited, respectively, with the genus Tradescantia, mainly based on morphological studies. In the present study, karyotypes and Giemsa C-banding patterns in the root-tip cells of three Zebrina and two Setcreasea clones were analyzed, and were compared with those of a triploid Tradescantia clone. Z. pendula and Z. purpusii (both 2n = 24) were found to have similar karyotypes (4 M + 6 ST + 14 T; M = meta-, ST = subtelo-, T = telocentric chromosomes), while Z. pendula cv Quadricolor (2n = 23) had a unique karyotype (6 M + 5 ST + 11 T + 1 SA; SA = short acrocentric chromosome). The only clear difference between Z. pendula and Z. purpusii was that one and two subtelocentric chromosomes, respectively, had satellites at the short arms. Two clones of S. purpurea (2n = 24) had karyotypes (8 M + 8 M' + 8 SM; M' = nearly meta-, SM = submetacentric chromosomes) similar to each other. T. ohiensis (2n = 18) had a symmetric karyotype (9 M + 9 SM) consisting of larger chromosomes than S. purpurea. Many clear Giemsa C-bands were detected, in addition to centromeric bands in all chromosomes of all clones. Z. pendula and Z. purpusii commonly had single clear interstitial bands in eight telocentric chromosomes each, but they also had unique telomeric and other interstitial bands, respectively. Z. pendula cv Quadricolor had a unique banding pattern, i.e., satellite bands in the unique short chromosome, telomeric bands at the long arms of all metacentric chromosomes, and single interstitial bands in six telocentric chromosomes. Two clones of S. purpurea had telomeric bands at many chromosome arms and satellite bands in two nearly metacentric and one submetacentric chromosomes, but some differences were found between them. On the other hand, all the chromosomes of T. ohiensis had telomeric bands at both arms, and three submetacentric chromosomes had satellite bands. These result prove structural differentiation of chromosomes occurred among the clones, especially in Zebrina, and show that S. purpurea is relatively close to T. ohiensis, while Zebrina is obviously distant from the other two genera. Therefore, there remains a question cytologically at least for uniting Zebrina with Tradescantia.     

黄精属细胞分类学研究——Ⅱ.四川金佛山地区黄精属植物核型

本文对四川金佛山地区4种黄精属植物的核型进行了研究,其结果为:滇黄精:2n=26=6m+12sm(2SAT)+8st(2SAT);距药黄精:2n=26=10m+4sm+12st;垂叶黄精:2n=30=14m(2SAT)+4sm+10st+2t、2n=28=14m+6sm+6st+2t;湖北黄精:2n=30=12m+8sm+10st、2n=28=6m+10sm+10st+2t、2n=22=2m+12sm 8st。通过与其它地区黄精属植物染色体数目与形态的比较,发现本地区所有种类的染色体数目普遍偏高,无论在染色体基数或染色体形态上都比较接近喜马拉雅山地区分布的种类。从实验结果进一步看出了黄精属的染色体变异是相当明显的,并主要表现为非整倍性变异;在有些情况下,染色体数目与结构的变异能与某些形态学特征相联系。     

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.     

牡丹染色体的Ag-NORs和Giemsa C带的研究

本文首次报道了紫斑牡丹和栽培牡丹5个重要品种的Ag-NORs和Giemsa C带带型。所有材料的核型组成均为2n=2x=10=6m+2sm+2st。多数材料具6个Ag-NORs,但在染色体上的分布位点不同。C带的差别主要表现在第1、2、3对染色体上。以上两种核学特征,具有品种的特异性。分带所显示的端(T)带和Ag-NORs的数目及分布基本一致。牡丹染色体的端带,本质上是N带;常规染色所显示的所谓随体,实际上是瑞部核仁组成区(NORs)。此外,对牡丹的细胞学研究技术进行了讨论。