雅江点地梅（报春花科）3个居群的核型和倍性变化

首次报道了雅江点地梅（Androsace yargongensis)3个居群的染色体数目和核型,对倍性也进行研究。3个居群的染色体数目（2n),核型公式（KF）,染色体相长度组成（C．RL）,核型不对4称系数（As,K%)和核型类型（KT）分别为：野牛沟居群2n=40,KF=36m(1SAT) 2SM 2ST b,C,RL=2L 14M2 22M1 2S 2bS,As.K=54.75%,KT=2A;巴颜喀拉山居群2n=40,KF=36m 2sm 2st 1b,C.RL=4L 16M2 18M1 2S 1bS,As.K=56.31%,KT=2B;达坂山居群2n=60,KF=40m 14sm 6st,C.RL=4L 24M2 26M1 6S,As.K=59.56%,KT=2B。根据3个居群的染色体和核型不对称性与居群所在地的地理位置,认为雅江点地梅核型和倍性的演化与高海拔生态环境和寒冷、干旱的气候加剧有密切关系。     

广义烙铁头属三种烙铁头的核型及分类地位初步探讨

报道３种烙铁头蛇的核型。其中,烙铁头２ｎ＝３６＝１６Ｍ（１４Ｖ＋２ＳＶ／Ｖ）＋２０ｍ,ＺＷ型性决定,Ｚ为Ｖ型,Ｗ为ＳＩ／ＳＶ型,Ｚ明显大于Ｗ;菜花烙铁头２居群２ｎ＝３６＝１６Ｍ（１４Ｖ＋２ＳＩ）＋２０ｍ,ＺＷ型性决定,Ｚ为Ｖ型,Ｗ为ＳＩ型,Ｚ明显大于Ｗ;云南竹叶青２ｎ＝３６＝１６Ｍ（１２Ｖ／ＳＶ＋２ＳＶ／ＳＩ＋２ＳＩ）＋２ｍ,无异型性染本,对３种的核型及烙铁头属已知核型进行了比较分析,并对云南竹叶     

十种姜科植物的染色体数目研究

报道了姜科3属10种植物的染色体数目。(1)姜属5种:版纳姜2n=22,弯管姜2n=22,圆瓣姜2n=22,红球姜2n=22,紫色姜2n=22;(2)舞花姜属4种:舞花姜2n=24,毛舞花姜2n=48,双翅舞花姜2n=48,澜沧舞花姜2n=32;(3)凹唇姜属1种:白斑凹唇姜2n=36。其中弯管姜、圆瓣姜、紫色姜、澜沧舞花姜、白斑凹唇姜的染色体数目为首次报道。     

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.     

Karyotype Analysis in Lycoris longituba Y. Hsu et Fan

A karyotypic analysis of Lycoris longituba Y. Hsu et Fan was carried out. The voucher specimen, Z. G. Mao 10501, is preserved in the Herbarium of Hangchow Botanical Garden. The chromosome number in root tip cells of the species is found for the first time to be 16, among which 6 are large, V-shaped with submedian primary constrictions, and the other 10 are short, rod-shaped with terminal primary constrictions. Photomicrograph of the chromosome complement and idiogram are given in Fig. 1-3 respectively. The karyotype formula of the species is therefore 2n=16=6m+6t+4t (SAT) in the light of the chromosomal terminology defined by Levan and al.^[5] Based on the view stressed by Jones^[3] and Brandham^[4], successive fusion of the chromosomes should be taken as the essential mechanism for karyotype evolution and speciation in Lycoris. Reciprocal translocation, with the loss of one of the centromeres, might be the mechanism of origin for a V chromosome. It is, then, suggested that the decrease in chromosome number as a result of fusion of the rods with terminal or subterminal primaryconstrictions has taken place in the speciation of L. longituba.     

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。     

山东10种植物的核型分析

对山东１０ 种植物进行了核型分析。茴茴蒜（ Ｒａｎｕｎｃｕｌｕｓｃｈｉｎｅｎｓｉｓ Ｂｇｅ－） 染色体数目２ｎ ＝１６ , 核型公式Ｋ（２ｎ） ＝ ２ｘ ＝ １６ ＝ ２ Ｍ ＋ ２ｍ ＋ ２ｓｍ ＋ １０ｓｔ, “３Ａ”类型; 五脉地椒（ Ｔｈｙｍｕｓｑｕｉｎｑｕｅｃｏｓｔａｔｕｓ Ｃｅｌａｋ－） 染色体数目２ｎ＝ ２６ , 核型公式Ｋ （２ｎ） ＝ ２ｘ＝ ２６ ＝ ８ Ｍ ＋ １８ｍ , “１Ａ”类型; 蛇床（ Ｃｎｉｄｉｕｍ ｍｏｎｎｉｅｒｉ（Ｌ－） Ｃｕｓｓ－） 染色体数目２ｎ＝ ２０ , 核型公式Ｋ （２ｎ） ＝ ２ｘ＝ ２０ ＝ ２Ｍ＋ １６ｍ ＋ ２ｓｍ , “２Ｂ”类型; 波斯菊（ Ｃｏｓｍｏｓ ｂｉｐｉｎｎａｔｕｓ Ｃａｖ－） 染色体数目２ｎ ＝ ２４ , 核型公式Ｋ（２ｎ） ＝ ２ｘ ＝ ２４ ＝ １６ｍ ＋ ２ｍ （ｓａｔ） ＋ ６ｓｍ , “２Ａ”类型; 白车轴草（ Ｔｒｉｆｏｌｉｕｍ ｒｅｐｅｎｓ Ｌ－） 染色体数目２ｎ＝ ３２ , 核型公式Ｋ （２ｎ） ＝ ４ｘ ＝ ３２ ＝ ３２ｍ , “１Ａ”类型; 铁苋菜（ Ａｃａｌｙｐｈａ ａｕｓｔｒａｌｉｓ Ｌ－）染色体数目２ｎ ＝ ３２ , 核型公式Ｋ （２ｎ） ＝ ２ｘ＝ ３２ ＝ ３２ｍ , “１Ｂ”类型; 地构叶（ Ｓｐｅｒａｎｓｋｉａ ｔ?     

东方蓼的染色体核型分析

目的:对药用植物东方蓼的染色体数目、核型、体积等进行了研究。方法:采用常规制片方法,结合显微摄影对染色体的数目进行统计分析。结果:东方蓼体细胞染色体数目2n=22,相对长度组成2n=22=10M2+12M1;核型公式为K(2n)=2X=22=20m+2M;全体染色体总长19.16μm,长臂总长10.93μm,核型不对称系数(AS.K%)为57.00%,属于"1A"型,全体染色体总体积为20.30μm3。结论:东方蓼体细胞染色体的数目、核型、体积等清晰准确。     

Karyotype evolution by centromeric fission inZamia (Cycadales)

The chromosome numbers of several species ofZamia from Mexico are reported.Z. paucijuga, distributed from central Oaxaca to Nayarit, has been found to have 2n = 23, 25, 26, 27 and 28. 2n = 28 is the highest chromosome number yet found in the cycads. Karyotypes of this species differ principally in the number of telocentric and metacentric chromosomes present in each; 2n = 23, 25, 26, 27 and 28 were found to have 5, 3, 2, 1 and 0 metacentric and 8, 12, 14, 16 and 18 telocentric chromosomes, respectively.Z. fischeri has been found to be 2n = 16,Z. furfuracea andZ. loddigesii 2n = 18.Zamia paucijuga on the basis of morphological and ecological characteristics, is considered to be an advanced member of this genus. Chromosome and karyotype evolution inZ. paucijuga may have occurred by centromeric fission of metacentric chromosomes; the karyotypes ofZ. paucijuga are strongly asymmetrical, suggesting that they evolved recently.     

Observations of Chromosomes of Malus Species in China

Somatic chromosome numbers of 37 forms (representing 22 species) of apples in China were counted using wall-degradation and hypotonic method. Among the species investigated 3 categories of chromosome numbers, i.e. 2n=34, 51 and 68 are confirmed. The chromosome numbers of the following species are here first reported: Malus ombrophila 2n= 34, M. prattii 2n=34, M. melliana 2n=34, Zhaojiaohonghua (M. sp.) 2n=34, and M. asiatica var. 2n=68. Polyploids (including infraspecific polyploids) account for 41% of the total number of the species investigated. 51 is a predominant number. It is suggested that ploidy variation is an important pathway in apple evolution in China, and triploid may be considered as a suitable evolution grade. There are rich apple germplasm resources in China. The systematic studies of this genus are obviously essential.     

Occurrence of multiple sexual chromosomes (XX/XY1Y2 and Z1Z1Z2Z2/Z1Z2W1W2) in catfishes of the genus Ancistrus (Siluriformes: Loricariidae) from the Amazon basin

Loricariid catfishes show a predominance of homomorphism in sex chromosomes, but cases of simple and multiple systems were also found. Here we describe two cases of multiple sex chromosome systems in loricariids from Brazilian Amazonia. Males of Ancistrus sp.1 "Balbina" have a modal number of 2n = 39 chromosomes, fundamental number (FN) of 78, and karyotypic formula of 27 m + 10 sm + 2 st; females have 2n = 38 chromosomes, FN = 76, and 26 m + 10 sm + 2 st. Ancistrus sp.2 "Barcelos" has 2n = 52 chromosomes for both sexes, FN = 80 for males and FN = 79 for females. Karyotypic formula is 12 m + 12 sm + 4 st + 24a for males and 11 m + 12 sm + 4st + 25a for females. The two species show different arrangements of constitutive heterochromatin blocks, which are coincident with NORs and absent in sex chromosomes. We suggest a XX/XY(1)Y(2) mechanism for Ancistrus sp.1 "Balbina", and a Z(1)Z(1)Z(2)Z(2)/Z(1)Z(2)W(1)W(2) mechanism for Ancistrus sp.2 "Barcelos". The XX/XY(1)Y(2) mechanism here reported is the second known occurrence of this type of multiple sex chromosomes for Loricariidae and the third for Neotropical fishes; the mechanism Z(1)Z(1)Z(2)Z(2)/Z(1)Z(2)W(1)W(2) represents the first record among fishes. The presence of different sex chromosome systems in Ancistrus indicates a probable independent origin and suggests that the differentiation of sex chromosomes is evolutionarily recent among species in this genus.     

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.     

三裂叶豚草和普通豚草的染色体核型研究

本文对产自中国东北地区和南昌市的三裂叶豚草和普通豚草进行了染色体观察与核型分析,两种豚草的染色体数目分别为２ｎ＝２４和２ｎ＝３６,与前人的报导一致,染色体核型未见到报导。     

三种食肉目动物的核型分析

本文报道了产于我国华北地区的艾鼬、貉和果子狸的核型。其中艾鼬2n=36。组型由20条双臂染色体、14条单臂染色体和一对性染色体组成。貉2n=65,它与wuster等报道过的貉的2n=42的核型表现出同种动物核型间的多态现象。果子狸2n=44,其c带带型中具有一对带有较大异染色质的中部着丝点染色体。     

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。     

M chromosome of the wild silkworm, Bombyx mandarina (n = 27), corresponds to two chromosomes in the domesticated silkworm, Bombyx mori (n = 28).

Chromosomes of Bombyx mori (n = 28) and of Bombyx mandarina (n = 27) were studied cytogenetically to resolve the origin of the large M chromosome in the Japaneses type of B. mandarina. In the F1 progeny from the reciprocal cross between B. mandarina and B. mori, the mitotic chromosome number was 2n = 55, and a chromosome configuration of 26 bivalents plus 1 trivalent was observed at metaphase I of germ cells. The trivalent chromosome consisted of the M chromosome from B. mandarina and two chromosomes from B. mori. When males of B. mori were mated to the F1 females, nuclei with two types of chromosome number (2n = 55 and 2n = 56) and two sets of chromosome pairs (26 bivalents plus 1 trivalent versus 28 bivalents) were observed in the metaphase I stage. Linkage analysis showed that the 14th chromosome of B. mori was involved in these two types of chromosome segregation. This result indicates that the M chromosome in B. mandarina arose from a fusion between a chromosome corresponding to the 14th linkage group and another, yet unidentified linkage group.     

三种榉属植物染色体数目及核型分析

报道了我国3种榉属(Zelkova)植物核型。结果如下:大叶榉(Z.schneideriana Hand.-Mazz.)2n=2x=28=14m 14sm;光叶榉(Z.serrata(Thunb.)Makino)的核型公式为2n=2x=28=26m 2sm,1、2、3对染色体的短臂上有次缢痕存在;大果榉(Z.sinica Schneid)的核型公式为2n=2x=28=20m 8sm。     

国产姜科植物的染色体计数(5)

<正> 本文继续对7属15种国产姜科植物作染色体计数观察,其中10种是染色体计数的新纪录(表、图)。通过对黄花大苞姜(Caulokaempferia coenobialis)和大苞姜(C.yunnanensis)以及凹唇姜(Bosenbevgia rotunda)和心叶凹唇姜(B.fallax)的染色体观察,确定了大苞姜属(Caulokaempferia)和凹唇姜属(Bosenbergia)的染色体基数分别为12和9。     

Studies on Chromosome Numbers and Anatomy of Young Branches of Calligonum of Xinjiang in Relation to the Evolution of Some Species of the Genus

There are more than 20 species of Calligonum in China, of which 17 are known from Xinjiang. They are divided into four sections. This paper aims to study the evolutionary relations of some species of Calligonum in Xinjiang. The chromosome numbers of 13 species and the anatomic structures of young branch of 8 species have been examined. Among 13 species, the, basic chromosome number x=9.9 species are diploids. 4 species are tetraploids. The evolutionary relations of these plants are arranged as follows: Section Calligonum (Fisch. et Mey.) Borszcz. 1. C. junceum (Fisch. et Mey.) Litv. Section Pterococcus (Pall.) Borszcz. 2. C. leucocladum (Schrenk) Bge. 3. C. aphyllum (Pall.) Gürke. 4. C. rubicundum Bge. Section Calligonum ,. 5. C. cordatum Eug. Kor. 6. C. densum Borszcz. 7. C. klementzii A. Los. Section Medusa Sosk et Alexandra 8. C. mongolicum Turcz. 9. C. pumilum A. Los. 10. C. ebi-nuricum Ivanova 11. C. arborescens Litv. 12. C. caput-medusae Schrenk 13.C. roborovskii A. Los.