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。     

七种药用植物的染色体研究

对山东７种药用植物的染色体进行了研究。结果表明：田旋花（ＣｏｎｖｏｌｖｕｌｕｓａｒｖｅｎｓｉｓＬ）的染色体数目为２ｎ＝７８;蜜柑草（ＰｈｙｌａｎｔｈｕｓｍａｔｓｕｍｕｒａｅＨａｖａｔａ）的染色体数目为ｎ＝８８;挂红灯（ＰｈｙｓａｌｉｓａｌｋｅｋｅｎｇｉＬｖａｒｆｒａｎｃｈｅｔｉ（Ｍａｓｔ）Ｍａｋｉｎｏ）的染色体数目为２ｎ＝２４,核型公式为Ｋ（２ｎ）＝２４＝２ｍ＋１８ｓｍ＋２ｓｔ＋２ｓｔ（ｓａｔ）,核型“２Ａ”型;无剌曼陀罗（ＤａｔｕｒａｓｔｒａｍｏｎｉｕｍＬｖａｒｉｎｅｒｍｉｓ（Ｊａｃｑ）ＳｃｈｉｎｚｅｔＴｈｅｌ）的染色体数目为２ｎ＝２４,核型公式为Ｋ（２ｎ）＝２４＝２０ｍ＋４ｓｍ,核型“１Ｂ”型;决明（ＣａｓｉａｔｏｒａＬ）的染色体数目为２ｎ＝２６,核型公式为Ｋ（２ｎ）＝２６＝２４ｍ＋２ｓｍ,核型“１Ａ”型;荔枝草（ＳａｌｖｉａｐｌｅｂｅｉａＲＢｒ）的染色体数目为２ｎ＝１６,核型公式为Ｋ（２ｎ）＝１６＝６ｍ＋１０ｓｍ,核型“２Ａ”型;车前（ＰｌａｎｔａｇｏａｓｉａｔｉｃａＬ）的染色体数目为２ｎ＝３６,核型公式为Ｋ（２ｎ）＝３６＝３２ｍ＋４ｓｍ,核型“１Ａ”型。     

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?     

甘肃紫斑牡丹品种与中原牡丹品种银带和Giemsa C带的研究

分别对甘肃紫斑牡丹品种和中原牡丹品种进行了核型,Ａｇｇｋｐｈｔ Ｇｉｅｎｓａ Ｃ带的研究。发现紫斑牡丹品种核型组成为２ ＝１０＝８ｍ＋２ｓｔ;中原牡丹品种核型组成为２ｎ＝１０＝６ｍ＋２ｓｍ＋２ｓｔ。ＧｉｅｍｓａＣ带带型显示,供试品种均能显示染色体端带,但天染色体端带的数目及分布位置上具品种特异性。     

贻贝(Mytilus edulis)核型及染色体带型分析

本文对贻贝染色体进行了核型分析,其结果为：２ｎ＝２８,１２ｍ＋１０ｓｍ＋６ｓｔ,ＮＦ＝５０,ＴＣＬ＝ １０３．９０μｍ,ＣＬ：２．７３５－４．７７４μｍ。第１、２、４、８、１１、１２对为中部着丝粒染色体（ｍ）;第６、９、１０、１３、１４对 为亚中部着丝粒染色体（ｓｍ）;第 ３、５、７对为亚端部着丝粒染色体（ｓｔ）。对贻贝染色体的Ｇ带、Ｃ带、银 染带进行了分析。银染结果表明,贻贝细胞中有四个银染核仁组织区（Ａｇ－ＮＯＲｓ）,分布在第 ３、５对染 色体长臂末端。     

华蟹甲草属和蟹甲草属4种植物的核型

４种植物的染色体间期均为复杂型,前期染色体为中间型。华蟹甲草两居群的染色体数目及核型为２ｎ＝６０＝４４ｍ＋１６ｓｍ（４ＳＡＴ）和２ｎ＝６０＝４２ｍ＋１８ｓｍ（２ＳＡＴ）。蟹甲草属３种：阔柄蟹甲草为２ｎ＝６０＝５０ｍ＋１０ｓｍ;蛛毛蟹甲草为２ｎ＝６０＝５０ｍ＋１０ｓｍ（２ＳＡＴ）;三角叶蟹甲草两居群分别为２ｎ＝６０＝４４ｍ＋１６ｓｍ（２ＳＡＴ）和２ｎ＝６０＝４４ｍ＋１６ｓｍ。核型均为２Ａ型,尽管华蟹     

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。     

五种珍珠菜的核型研究

本文对５种珍珠菜亚属植物进行了染色体数目及核型研究。其中瓣珍珠菜２ｎ＝２４＝１２ｍ＋８ｓｍ＋４ｓｔ（２ＳＡＴ）、黑腺珍珠菜２ｎ＝２２＝２ｍ＋４ｓｍ＋６ｓｔ＋１０ｔ、泽珍珠菜２ｎ＝２４＝１４ｍ＋６ｓｍ（２ＳＡＴ）＋４ｓｔ和小叶珍珠菜２ｎ＝４８＝３４ｍ＋１０ｓｍ＋４ｓｔ的染色体数目及核型为首次报道。中国九江产的红根草核型２ｎ＝２４＝２０ｍ＋４ｓｍ（２ＳＡＴ）与日本产的核型２ｎ＝２４＝１８ｍ（１ＳＡＴ）     

滇牡丹复合群的GiemsaC—带比较研究

应用ＢＳＧ方法对滇牡丹复合群５个类群的ＧｉｅｍｓａＧ－带进行了比较研究。在５个类群的根尖体细胞有丝分中期观察到１０条染色体,其核型基本一致,均为Ｋ＝２ｎ＝１０＝６ｍ＋２ｓｍ＋２ｓｔ。各类群的１０条染色体都在着丝点附近显示出了ＧｉｅｍｓａＣ－带,所有染色体的长臂上都没有显示出ＧｉｅｍｓａＣ－带,。而短臂上的ＧｉｅｍｓａＣ－带的数量和位置在娄各之间表现了一定的差异。除了滇牡丹第一地同源染色体中只有一条     

吉林省产5种百合的核型研究

报道了吉林省产５种百合科植物的染色体数目和核型：①毛百合Ｌｉｌｉｕｍ ｄａｕｒｉｃｕｍ Ｋｅｒ．－Ｇｅｗ１．２ｎ＝２４＝２ｍ（２ＳＡＴ）＋２ｓｍ（２ＳＡＴ）＋８ｓｔ（２ＳＡＴ）＋１２ｔ（２ＳＡＴ）;②有斑百合Ｌ．ｃｏｎｃｏｌｏｒ Ｓａｌｉｓｂ．ｖａｒ．ｂｕｓｃｈｉａｎｕｍ（Ｌｏｄｄ．）Ｂａｋｅｒ ２ｎ＝２４＝２ｍ（２ＳＡＴ）＋４ｓｍ（４ＳＡＴ）＋６ｓｔ（２ＳＡＴ）＋１２ｔ;③兰州百合Ｌ．ｄａｖｉｄ     

鼠颚毛厉螨染色体组型及其C-带、G-带的研究(蜱螨亚纲:厉螨科)

本文首次报道了厉螨科鼠颚毛厉螨 Tricholaelaps myonyssognathus 染色体组型及其C-带、G-带的研究。结果表明其为单二倍体性决定系统(n=6,2n=12),雄性体细胞具有6条染色体,雌性体细胞具有12条染色体。所有染色体均为单着丝粒,其着丝粒位置分别为中部(1和2号)、亚中部(3号)、亚端部(4号)及端点(5和6号)。C-带为着丝粒带。G-带的有35条深带。     

玉米染色体G-带ASG法显带的研究

两个自交系的根尖染邑体经ASG法处理显出了G-带。王米G-带沿整个染色体长轴分布,是一些密切邻近的多重带纹。无论有丝分裂的晚前期、早中期或中期染色体都有这类带纹。每一对同源染色体的两成员G-带带型基本相似,不同染色体或同一染色体的不同区域带纹具有一定的差异。ASG处理前用α-溴萘或放线菌素D预处理都可显出G-带。本文讨论了玉米G-带与哺乳动物G-带的相似点以及用ASG法进行玉米G-带显带应注意的技术问题。     

大麦G—显带核型的研究

本文报道了 ASG 法处理的三个栽培大麦(Hordeum Vulgare)品种 G-带的核型研究。结果表明无论是早中期或中期染色体都显示出了密切邻近的、多重的 G-带带纹。在有丝分裂过程中染色体愈浓缩带纹数目愈少。同源染色体之间带纹分布的位置、染色深浅以及带纹数目都基本一致,可以较为准确地进行配对。同一分裂时期不同染色体的 G-带带纹各具一定的特点,可以作为鉴别的标记。讨论了显带技术和中期染色体的 G-带等问题。     

Studies on G-Banding Karyotype in Barley (Hordeum vulgare)

G-banding karyotypes of three cultivars in barley were analyzed. Multiple closely adjacent G-bands were able to be observed in each early metaphase or metaphase chromosome treatted by an ASG method. The more concentrated the chromosome, the less was the number of G-bands during mitosis. The position of band distribution, staining degree and band numbers between homologous chromosomes were basically identical. Chromosome pairing for karyotype analysis could be carried out more accurately. G-banding patterns of different chromosome pairs were not the same, they could be used as the markers to distinguish one from another chromosome pair. During the same mitotic stage the banding patterns including number, relative position and staining degree of the bands between different cultivars were basically the same, but they had differences in the size and staining degree of some bands near centromeres. G-banding technique and G-banding of metaphase chromosomes were discussed.     

Chromosomal banding patterns and karyotype evolution in three pig kidney cell strains (PK15, F and RP)

Some of the techniques used to obtain banding patterns in human karyotype are adapted here to three pig kidney cell strains (PK15, F and RP). These strains were established respectively in 1955, 1962 and 1969. The banding techniques used are: controlled heating, ASG technique, alkaline treatment and proteolytic digestion with trypsin or pronase. Knowing the specific banding of the pig karyotype, it has been possible to study the chromosomal rearrangements observed in the heteroploid cell strains. If the strain is old, the rearrangements are more numerous. However, they are the same as the ones usually described: in the three strains, one of the two chromosomes of each pair is retained unchanged as judged by its banding. The other chromosome is either present, lost or modified. It may constitute part of a marker chromosome.     

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。     

Cytological mapping of human chromosomes: results obtained with Quinacrine fluorescence and the Acetic-Saline-Giemsa techniques

The similarities and differences between the banding patterns obtained in human chromosomes with the Quinacrine fluorescence and the Acetic-Saline-Giemsa (ASG) techniques are described. The use of these techniques to identify each chromosome pair in the human karyotype is discussed, as also is the use of the methods to identify aberrant chromosomes and to map points of exchange in translocations and inversions. A number of examples are used to illustrate the resolution permitted by these new methods. Seven polymorphic regions on normal chromosomes are described, which include four identified by fluorescence on chromosomes 3,4, 13, and 22. The secondary constrictions on chromosomes 1, 9, and 16, which had previously been observed in conventionally stained preparations from favourable material, are particularly clear in all cells treated with the Giemsa techniques. The new methods make it possible to detect small differences in size between the heterochromatic blocks at these regions in homologous chromosomes. The benefit to human genetics of studying the familial segregation of both structurally rearranged and normal, but polymorphic chromosomes, where the chromosomes or parts of chromosomes can be unambiguously identified is stressed.     

Chromosome homology and heterochromatin in goat,sheep and ox studied by banding techniques

Peripheral blood lymphocyte metaphase chromosomes of three Bovoidean species have been studied using Quinacrine fluorescence and Giemsa banding techniques to give Q-, G-, and C-banding patterns. Q- and G-banding characteristics, coupled with chromosome length, enabled all of the chromosomes in each of the chromosome complements to be clearly distinguished, although some difficulties were encountered with the very smallest chromosomes. A comparison of G-banding patterns between the species revealed a remarkable degree of homology of banding patterns. Each of the 23 different acrocentric autosomes of the domestic sheep (2n=54) was represented by an identical chromosome in the goat (2n=60) and the arms of the 3 pairs of sheep metacentric autosomes were identical matches with the remaining 6 goat acrocentrics. A similar interspecies homology was evident for all but two of the autosomes in the ox (2n=60). This homology between sheep metacentric and goat acrocentric elements confirms a previously suggested Robertsonian variation. The close homology in G-banding patterns between these related species indicates that the banding patterns are evolutionarily conservative and may be a useful guide in assessing interspecific relationships. —The centromeric heterochromatin in the autosomes of the three species was found to show little or no Q-or G-staining, in contrast to the sex chromosomes. This lack of centromeric staining with the G-technique (ASG) contrasts markedly with results obtained with other mammalian species. However, with the C-banding technique these regions show a normal intense Giemsa stain and the C-bands in the sex chromosomes are inconspicuous. The amount of centromeric heterochromatin in the sheep metacentric chromosomes is considerable less than in the acrocentric autosomes or in a newly derived metacentric element discovered in a goat. It is suggested that the pale G-staining of the centromeric heterochromatin in these species might be related to the presence of G-Crich satellite DNA.     

浙江大罗山七倍体薤白的发现及其成因分析

该试验对浙江大罗山一个薤白种群的13个个体进行了染色体计数和核型分析,并对探讨七倍体薤白的可能形成机制进行了讨论。结果表明:(1)大罗山薤白种群为混倍种群,其中3个个体为七倍体,染色体组型是2n=7x=46m(2SAT)+10sm(2SAT),核型为2B型;10个个体为四倍体,染色体组型是2n=4x=26m(1SAT)+6sm(1SAT),核型为2B型。薤白种群的混倍性和七倍体均为首次报道。(2)对七倍体薤白的成因分析认为,七倍体是通过三倍体和四倍体未减数配子结合产生;随体染色体数目并不与植株的倍性相对应,而且并不都是出现于同源染色体上;薤白种内倍性增大与其物种进化的趋势一致,即倍性越大,种群越进化。