裸蒴属的核型及三白草科四属间系统关系的探讨

本文首次报道三白草科裸蒴属中华裸蒴(Gymnotheca chinensis Decne)和白苞裸蒴(G. involucrata Pei)的染色体数目。两个种的体细胞染色体数均为2n=18,染色体基数为x=9。三白草科原始祖先的染色体基数假定为x=11,裸蒴属可能是经非整倍减少演变而来。裸蒴属间期核型属球状或棒状前染色体型。本文根据三白草科染色体研究的结果和现代地理分布格局,结合其他分枝学科的研究资料,对科下四属间的系统发育关系提出了初步假设。     

华南地区3种兔儿风属植物(菊科-帚菊木族)的细胞学研究

首次报道了华南地区兔儿风属(Ainsliaea DC.)(菊科-帚菊木族Asteraceae-Pertyeae)3种植物共4个居群的染色体数目和核型。其中长穗兔儿风(A.henryi Diels)的染色体数目为2n=24,核型公式为2n=16m+8sm;三脉兔儿风(A.trinervis Y.C.Tseng)的染色体数目为2n=26,核型公式为2n=16m+10sm;莲沱兔儿风(A.ramosa Hemsl.)2个居群的染色体数目均为2n=26,核型公式为2n=26=22m+4sm。所有居群的染色体由大到小逐渐变化,核型没有明显的二型性。这些结果表明兔儿风属植物确有x=12和x=13两个基数,其中x=13可能是该属的原始基数。     

黄根豆的核型分析

本文首次对单种属植物黄根豆(Chrysoirhiza adenotricha T.Chen)进行了核型分析,其核型公式为K(2n)=22=22m,并确认黄根豆属(Chrysorhiza)的染色体基数为X=11。     

四川当归属八种植物的核型及地理分布研究

本文首次报道四川八种当归属植物的染色体数目和核型。染色体基数x=11,除青海当归为四倍 体植物外,其余种类均为二倍体植物。金山当归 2n=22=20m+2sm;城口当归 2n=22=18m+2sm^sat+2sm;疏叶当归在不同地区有2种核型：2n=22=18m+4sm和 2n=22=16m+6sm;四川当归2n=22=16m+2sm^sat+4sm;茂汶当归2n=22=16m+6sm;青海当归 2n=4x=44=36m+8sm;当归2n= 22=14m+8sm;峨眉当归2n=22=10m+2sm+10st。除金山当归和 疏叶当归的部分居群核型为1A型外,其余种类均为2A型。根据核型的不对称性程度和外部形态分析 了各种类的演化水平,结合四川当归属植物的种类及地理分布,提出四川可能是当归属植物的原始中心和演化中心之一。     

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。     

葱属粗根组5种材料的核型研究

本文分析了葱属Allium粗根组Sect．Bromatorrhiza Ekberg五群材料的核型。多星韭Allium wallichii Kunth有两个类型：第一类型是二倍体,染色体组公式为AA,核型公式为K(2n)=2X=14=2m(SAT)+2m+10sm,属2A型;第二类型是同源四倍体,染色体组公式为AAAA, 核型公式为K(2n)＝4X＝28＝2m(SAT)+6m十20sm,属2A型。宽叶韭Allium hookeri Thwaites有三个类型： 第一类型是双基数同源异源三倍体,染色体组公式为AAB1,核型公式为 K(2n)＝2X+ x'＝22＝(12sm+2t)十(1m十45m+1st+2t), 属3A型; 第二类型也是双基数同源异源三倍体,能配对的两个染色体组染色体大小和形态与第一类型大体相似,不能配对的一个染色体组染色体大小和形态与第一类型有明显区别,其中至少有两条染色体发生了罗伯逊易位,出现一条很大的染色体和一条很小的染色体,染色体组公式为AAB2,核型公式为K(2n)=2x+x'＝22=(12sm+2t)+ (3m+1sm十2st+2t),属3A型;第三类型相当于第一类型染色体的自然加倍,是双基数同源异源六倍体,染色体组公式为AAAAB1B1,核型公式为K(2n)=4X十2x'＝44＝(24sm+4t)十(2m+ 8sm十2st+4t),属3A型。     

伞形花科5种主要蔬菜作物的核型分析

采用卡宝染色压片法对伞形花科5种主要蔬菜作物进行了核型分析和比较.结果表明:芹菜的核型公式为K(2n)=2x=22=6m+2sm+8st+6t,染色体核型为"3B"型;芫荽的核型公式为K(2n)=2x=22=2m+2sm+18st,染色体核型为"3A"型;茴香的核型公式为K(2n)=2x=22=14m+6sm+2st,染色体核型为"2B"型;水芹的核型公式为K(2n)=2x=22=6m+6sm+10st,染色体核型为"3A"型;胡萝卜的核型公式为K(2n)=2x=18=6m+10sm+2st,染色体核型为"2A"型.并对他们的亲缘关系、遗传多样性进行了探讨.     

四十五种叶蝉的染色体研究（同翅目：叶蝉总科）

研究观察了45种中国雄性叶蝉的减数分裂,其中44种的核型为首次报道,染色体数目变化在2n=12～26之间,性别决定均为XO型。从叶蝉总科的组型图来看,该科染色体数目变化在2n=8～28之间,峰值为2n=18(16+XO),另外几种类型2n=16,20,22也有较高的出现频率。科内染色体数目的进化不具有明显的方向性,2n=22(20+XO)是该科的原始核型,易位导致的不均等互换可能是染色体数目进化的主要机制。从精子发生来看叶蝉总科与角蝉总科的关系较为密切,两者的共同特点是：①精母细胞体积较大,显著不同于沫蝉和蝉科;②减数分裂行为及精子变态过程相似;③染色体数目较少,染色体体积较大;④减数分裂前期具有典型的花束期,没有弥散期,因而不同于蜡蝉。但是由于叶蝉总科的染色体变异范围明显大于角蝉总科,而角蝉总科的核型相对较为保守,从核型上来说角蝉总科是比叶蝉总科较为原始的类群。     

桔梗的核型研究

本文观察和分析了桔梗的体细胞染色体,2n=18,核型公式为K(2n)=10m+8sm(2SAT),有较高的对称性,属“2A”型,在桔梗科中处于较为原始的地位。它与近缘属似有基数渐减的进化趋势。     

粗根韭的核型分化研究

对葱属粗根韭的3个地方居群的核型分析结果表明,3个居群的核型表现出很大的差异。西藏 达孜居群为2n=2x=20=4m+10sm+2t(2SAT)+4T;四川乡城居群为2n=2x=20=10sm+6t (2SAT)+4T;四川理县居群为2n=2x=20=6m+1Osm+2t(2SAT)+2T。虽然它们之间在核型上存 在差异,但除达孜居群的植株较矮小外,3个居群的植物在形态上却非常一致。理县居群的核型被认为 是原始类型,由它通过染色体结构变异,分别演化出更不对称的达孜居群和乡城居群。葱属中,目前只 发现4个种的染色体基数为10,除本种外其余3种分别是A．decipiens Fisch．;A．kujukense Vved．和 A．chelotum Wendelbo。根据这4个种的核型特征和分布格局,基数10可能有不同的起源,至少粗根韭 的起源与其余3种不同,而且起源最晚。粗根韭的核型特征及它与染色体基数为11的宽叶韭A．hook- eri Thwaites在核型上的相似性,表明它们很可能共同起源于基数为10但现已绝灭的祖先种。此外,还探讨了该祖先种的起源问题。     

吊兰染色体核型分析

对吊兰体细胞染色体计数,并进行核型分析。结果表明,吊兰染色体数目为2n=28;核型公式为2n=2x=28=4m+14sm+10st;染色体相对长度组成为2n=28=4L+14M2+10M1,属于3B型;全组染色体总长73.84μm,长臂总长为53.59μm;核型不对称系数为72.58%;染色体总体积为101.94μm³。     

硬枝黄蝉染色体计数与核型分析

以硬枝黄蝉Allamanda neriifolia幼胚为试验材料,对其体细胞染色体进行计数与核型分析。结果表明,硬枝黄蝉幼胚细胞含9对染色体,由中部或近中部着丝粒染色体构成。核型公式为2n=2x=6sm+12m。核型不对称系数为58.95%,核型分类属于2A型。     

美人蕉核型研究

对美人蕉体细胞染色体计数,并对其核型进行分析。结果表明,美人蕉的染色体数目为2n=18,核型公式为2n=2x=18m,属于"1A"型。     

绒毛白蜡的核型分析

应用根尖压片法对木樨科白蜡属绒毛白蜡(Fraxinus velutina)的染色体数目和核型进行了研究。结果表明:绒毛白蜡体细胞染色体数目为2n=22,核型公式为:K(2n)=22=20m+2 sm,属于"1A"类型。染色体相对长度组成为2n=22=4L+10M₂+8M₁。     

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+...     

The Studies on the Karyotypes and Cytogeography of Taxodium Rich.(Taxodiaceae)

The present paper deals with the karyotypic analysis of Taxodium ascendens Brongn. The somatic chromosomes in root-tip cells of the plant are found to be 2n =22, all with median and submedian constrictions. A character of the karyotype is that the chromosome 10 has a long kinetochore region (Plate 1:1). According to the terminology defined by Levan et al.^[18], the karyotype formula is k(2n)=22=20m+2sm, which is different to Huang et Hsu’s^[8] K(2n)=24=22m+2B(m). The karyotype belongs to “lA” of Stebbins’^[24] karyotypic symmetry and is generally regarded as a relatively primitive one. The species’ chromosome complement is 2n=22=2L+8M₂+12M₁ according to I.R.L.difined by Kuo et al.^[15] based on relative length. The lengths, arm ratios and types of chromosomes of the species are given in Table 1-I. The morphology of the chromosomes and the karyotype, are given in Plate 1:1. In the light of the works of Schlarbaum et al.^[21] and Mehra et al.^[17], K(2n)=22=20m (2SAT)+2sm and 2n=22=2L+6M₂+14M₁ are for T. distichum (L.) Rich. (see Table 1-II), K(2n)=20m+2sm and 2n=22=4L+4M₂+12M₁+2S for T. mucronatum Tenore (see Table 1-III, Plate 1:2), which belong to “lA” and “2A” respectively. The differences between three species in the ratio of the longest to the shortest chromosome, I.R.L. and the proportion of chromosomes with arm ratio >2 show that the karyotype of T. mucronatum is the most advanced and that of T. distichum the most primitive. The present author suggests that the sequence of evolutionary advance be T. distichum, T. ascendens, T. mucronatum. Based on the evidence from the karyotype analyses, ecology and geographical distribution (including fossil), the secondary center of genetic diversity (Fig. 1) and the probable evolu-tionary pattern (Fig. 2) of Taxodium are discussed.     

山东四种草本植物的核型研究

本文对山东４种草本植物进行了染色体研究。结果表明：阿尔泰狗哇花（Ｈｅｔｅｒｏｐａｐｐｕｓａｌ ｔａｉｃｕｓ（Ｗｉｌｄ）Ｎａｖｏｐｏｋｒ）的染色体数目为２ｎ＝３６,核型公式为Ｋ（２ｎ）＝３６＝３６ｍ,核型“１Ａ”型;求米草（Ｏｐｌｉｓｍｅｎｕｓｕｎｄｕｌａｔｉｆｏｌｉｕｓ（Ａｒｄｕｉｎｏ）ＲｏｅｍｅｔＳｃｈｕｌｔ）的染色体数目为２ｎ＝１２,核型公式为Ｋ（２ｎ）＝１２＝８ｍ＋４ｓｍ,核型“２Ａ”型;红秋葵（Ｈｉｂｉｓｃｕｓｃｏｃｉｎｅｕｓ（Ｍｅｄｉｃ）Ｗａｌｔ）的染色体数目为２ｎ＝３８,核型公式为Ｋ（２ｎ）＝３８＝１４ｍ＋２２ｓｍ＋２ｓｔ,核型“２Ｂ”型;蟋蟀草（Ｅｌｅｕｓｉｎｅｉｎｄｉｃａ（Ｌ）Ｇａｅｒｔｎ）的染色体数目为２ｎ＝１８,核型公式为ｋ（２ｎ）＝１８＝１６ｍ＋２ｓｍ,核型“２Ａ”型。     

A Study on Karyotypes of the Genus Lycoris

The genus Lycoris (Amaryllidaceae) consists of about 20 species, all of which are confined to temperate China, Japan and Korea. Cytological investigations, including a reexamination of the karyotypes of 14 taxa, measurements of relative nuclear DNA content, and meiotic configuration observations on some specific forms and interspecific hybrids, have been carried out by the present authors in order to re-evaluate the mode of karyotype evolution and the role of hybridization in the speciation of Lycoris. These have resulted in a new theory for explaining the karyotype evolution in the genus, which will be considered elsewhere. The present paper deals with observations on karyotypes of 11 species, 1 variety and 2 artificial hybrids. Results obtained through karyotype analysis, as shown by the data in Table 1, Plates I-VI and Figs. 1-2, reveal that: (1) the karyotypes of Lycoris rosea, L. radiata var. pumila, L. sprengeri, L. haywardii, L. caldwellii, L. squamigera and L. radiata are, on the whole, consistent with those reported by the previous authors^{[1,2,3,4,5,8,10,12]};(2) the I (rodshaped) chromosomes of L. chinensis and L. longituba are all T’s (telocentric) instead of t’s (acrocentric) or t(Sat)’s; (3) the three materials of L. aurea of different sources have shown a karyotypic differentiation: one with 2n=14=8m+6T, and the others with 2n=16=6m+10T: (4) both of the karyotypes of L. straminea and L. albiflora are 2n=19=3V+6I, inconsistent with 2n=16=6V+10I for the former and with 2n=17=5V+12I for the latter as reported by Inariyama (1953), Bose and Flory (1963) and Kurita (1987). The following aspects are worthwhile discussing: 1. The types of chromosomes. Karyotype analyses reveal the existence of three major chromosome types in Lycoris: (1) m (metacentric) chromosomes: (2) t (acrocentric) chromosomes, with short arms, (3) T (telocentric) chromosomes, sometimes with dot-like terminal centromeres. To distinghish t’s from T’s is of paramount importance for solving the problem of karyotype evolution in Lycoris. Bose (1963) pointed out that in the species with 2n=22, all I chromosomes were t’s, while in species with 2n=12-16, all I chromosomes were T’s. Our results of chromosome observations are consistent with Bose’s remarks. Some authorst^[3,6] have probably mistaken the dot-like terminal centromeres of T’s of L. longituba and L. chinensis as the short arms of t’s. 2. The significance of Robertsonian change in karyotype evolution. Although chromosome numbers and karyotypes are very variable in Lycoris, as shown in Table 1, the total number of arms of a chromosome complement of any species is always multiples of 11. Hence, it seems likely that Robertsonian changes have taken part in karyotype alteration, The genus has a series of basic chromosome numbers: 6, 7, 8 and 11. But which is the most primitive one? It is uncertain whether a successive decrease in chromosome numbers as a result of Robertsonian fusion or a gradual increase in chromosome numbers brought about by fission (fragmentation) has been the essential mechanism for karyotype evolution and speciation in Lycoris. These problems are of crucial importance and will be discussed in our subsequent papers. 3. The origin of polyploids. As evident from Table 1, there are two levels of ploidy differentiation in Lycoris: (1) di ploids with 2n=22 or the equivalent of 22, (2) triploids with 2n=33 or the equivalent of 33. The most common way of origination of triploids in plants is the hybridization of diploids with Tetraploids. But tetraploids have never been found in Lycoris. Thus, it is suggested that the triploids have originated from the combination of an unreduced gamete of a diploid with a normal gamete of another diploid. 4. The role of hybridization in speciation. Results of karyotype analyses show that hybridization has taken an important part in the speciation of Lycoris. Two types of hybrids have been found: (1) 2n=19= 3V+ 16I, L. straminea, L. albiflora and the two artificial hybrids L. sprengeri×L. chinensis and L. haywardii× L. chinensis all possess this karyotype. It could be seen from the above chromosome number and karyotype that this sort of karyotype is exactly half of the total sum of 2n=22I and 2n=16= 6V+10I. It is, therefore, quite evident that taxa possessing this karyotype are all diploid hybrids of 2n=22 and 2n=16, (2) 2n=27=6V+21I, L. caldwellii and L. squamigera possess this karyotype. It is reasonable to assume, too, that they are segmental allotriploids and have arisen from the combination of an unreduced diploid gamete of 2n=16 and a normal haploid gamete of 2n=22. The origin of the hybrid karyotype 2n=17=5V+12I reported by Inari- yama (1953) is similar to that of 2n=19, except that one of the parents possesses 2n=12= 10V+2I instead of 2n=16=6V+10I. The origin of the other hybrid karyotype 2n=30=3V+ 27I reported by Bose (1963) is similar to that of 2n=27, but the diploid gamete comes from taxa possessing 2n=22 instead of 2n=16.     

安徽石蒜属4种植物核型研究

本文分析了安徽境内石蒜属ＬｙｃｏｒｉｓＨｅｒｂ．４种植物的核型,并结合有关文献探讨它们的核型变异。结果表明,乳白石蒜Ｌ．ａｌｂｉｆｏｌｉａＫｏｉｄｚ．的核型为２ｎ＝１９＝３ｍ＋７ｓｔ＋４ｔ＋５Ｔ,属３Ｂ型;中国石蒜Ｌ．ｃｈｉｎｅｎｓｉｓＴｒａｕｂ．为２ｎ＝１６＝６ｍ＋１０Ｔ,属３Ｂ型;石蒜Ｌ．ｒａｄｉａｔａ（Ｌ’Ｈｅｒ．）Ｈｅｒｂ．为２ｎ＝２２＝４ｓｔ＋１８ｔ,属４Ａ型;换锦花Ｌ．ｓｐｒｅｎｇｅｒｉＣｏｍｅｓ．ｅｘＢａｋｅｒ．为２ｎ＝２２＝２ｓｔ＋２０ｔ,属４Ａ型。以上各种植物均未发现随体和次缢痕,通过核型比较,可见同种不同居群间在染色体数和核型结构上均存在较大的变异。     

Karyotype Analysis of 5 Species of Polygonatum Mill.

The present paper reports the chromosome numbers and karyotypes of five species in Polygonatum from Anhui of China. The materials used in this work are listed in Table 1, Photomicrographs of somatic metaphase and karyograms of the five species of Polygonatum in Plate 1, 2, 3, the idiograms in Fig. 1-11 and a comparison of the karyotype of them is provided in Table 2. The results are shown as follows: 1. Polygonatum odoratum (Mill.)Druce Two materials were examined. One from Mt. Huangshan, Anhui, has 2n= 16 = 10m (3sc)+ 6sm (Plate 1 :A, B). The idiogram is shown in Fig. 1. The chromosomes range in length from 2.85 to 8.85 μm, with the total length 48.63μm and the ratio of the longest to the shortest 3.11, The karyotype belong to Stebbins’(1971) 2B. The two chromosomes of the first pair have arm ratios 1.01 and 1.29 respectively, and The first pair has one chromosome carrying a satellite attached to the short arm, showing heterozyosity .The chromosome num ber of 2n= 16 in P. odoratum and its karyotype are reported for the first time. The other from Langyashan, Chu - xian, Anhui, is found to have 2n = 18 = 10m (Isc)+2sm+6st(2sc) (Plate 1: C, D). The idiogram is shown in Fig. 2. The chromosomes range in length from 2.43 to 8.29μm, with the total length 46.67µm and the ratio of the longest to the shortest 3.41. The karyotype is also of 2B. In a somatic chromosome complement the 2nd pair have one chromosome carrying a satellite attached to the long arm, showing heterozygosity. 2. Polygonatum filipes Merr. Two materials were examined. One from the Huangshan, Anhui is found to have two cytotypes: 2n= 16 and 2n=22. This paper reports one of them. The karyotype formula is 2n=22=8m+8sm(2sc)+6st(Plate 3: Q, R). The idiogram is shown in Fig. 3. The chromosomes range in length from 2.55- 5.85μm, with the total length 45.01 μm and the ratio of the longest to the shortest 2.29. The karyotype belongs to 3B. The other material from the Fangchang, Anhui, is shown to have four cytitypes: 2n= 14, 2n= 16, 2n=20 (Plate 3: W) and 2n=22. This paper reports two of them. Type I: the karytype formula is 2n=14=10m+4sm (Plate 3: S, T). The idiogram is shown in Fig. 5. The chromosomes range in length from 2.59 to 7.61μm, the total length 37.44μm and the ratio of the longest to the shortest is 2.94. the karyotype belongs to 2B. Type II :The karyotype formula is 2n=16=8m+4sm+4st (Plate 3: U, V). The idiogram is shown in Fig. 4. The chromosomes range in length from 2.65 to 8.21 μm, the total length 46.01 μm and the ratio of the longest to the shortest 3.10. The karyotype belongs to 2B. The chromosome numbers of 2n=20, 2n= 14 and 2n=22, and karyotype of 2n= 14 and 2n=22 in P. filipes are reported for the first time. 3. Polygonatum cytonema Hua Two materials were examined. One from the Langyashan, Chuxian, anhui, is found to have 2n = 18 = 8m (2sc)+ 6sm+ 4st (Plate 2: K, L). The idiogram is shown in Fig. 7. The chromosomes range in length from 3.41 to 9.21 μm, the total length 56.34μm and the ratio of the longest to the shortest is 2.70. The karyotype belongs to 2B. The other material from the Huangshan, Anhui, has two cytotypes: 2n=20 and 2n= 22. Type I: The karyotype formula is 2n= 20= 8m+ 6sm+ 6st (Plate 2: M, N). The idiogram is shown in Fig. 8. The chromosomes range in length from 1.75 to 5.03μm, with the total length 32. 91μm and the ratio of the longest to the shortest 2. 87. The karyotype is also of 2B. Type II: The karyotype formula is 2n=22=6m+ 8sm+4st+ 4t (Plate 2: O, P ). The idiogram is Shown in Fig. 10. The chromosomes range in length from 1.75 to 4.95 μm, with total length 35.05μm and the ratio of the longest to the shortest 2.83. The karyotype brlongs to 3B. 4. Polygonatum desoulayi kom. The material from Xuancheng, Anhui, is found to have karyotype 2n = 22 = 10m (2sc) + 6sm (lsc) + 6st ( Plate 2. I, J). The idiogram is shown in Fig. 6. The chromosomes range in length from 1.86 to 5.61μm, with the total length 41.98μm and the ratio of the longest to the shortest 3.02. The karyotype is also of 3B. The first pair has one chromosome carrying a satellite attached to the long arm, showing heterozygosity. The chromosome number and karyotype of Chinese material are reported for the first time. 5. Polygonatum verticillatum (L.) All. The material from the Langyashan, Chuxian, Anhui is found to have two cytotypes. Type 1: the karyotype formula is 2n = 18 = 2m+ 2sm+ 10st+ 2t+ 2T (Plate 1: G, H). The idiogram is shown in Fig.9. The chromosomes range in length from 1.86 to 4.03μm, with total length 28.28μm and the ratio of the longest to the shortest 2.17. The karyotype classification belongs to 3B. Type II: The karyotype formula is 2n=24=6m+4sm+12st+2T (Plate 1: E, F). The idiogram is shown in Fig. II. The chromosomes range in length from 2.01 to 5.03μm, with total length 41.36μm and the ratio of longest to shortest 2.50. The karyotype is also of 3B. The chromosome numbers and karyotypes of Chinese material are reported for the first time.