黄牡丹八个居群的Giemsa C-带比较研究

应用ＢＳＧ方法对黄牡丹（Ｐａｅｏｎｉａ ｄｅｌａｖａｙｉ ｖａｒ．ｌｕｔｅａ）８个居群的Ｇｉｅｍｓａ Ｃ－带进行了比较研究。８个居群的所有染色体都在着丝点附近显示出了Ｃ－带,所有染色体的长臂上都没有显示Ｃ－带,而短臂上的Ｃ－带数量和位置在居群之间表现出了一定的差异。花甸凡居群手第二、第三、第四和第五对染色体显示端带;卓干山居群的第一、第三、第四和第五对染色体的短臂上没有显示Ｃ－带。在所研究的８个居     

Banding Human Chromosomes Using a Combined C-Banding-Fluorochrome Staining Technique

Slides pretreated for C-banding and stained with DAPI or CMA3 show different banding patterns in human metaphase chromosomes compared to those obtained with either standard Giemsa C-banding or fluorochrome staining alone. Human chromosomes show C-plus DA-DAPI banding after C-banding plus DAPI and enhanced R-banding after C-banding plus Chromomycin A3 staining. If C-banding preferentially removes certain classes of DNA and proteins from different chromosome domains, C-banding pre-treatment may cause a differential DNA extraction from G- and R-bands in human chromosomes, resulting in a preferential extraction of DNA included in G-bands. This hypothesis is partially supported by the selective cleavage and removal of DNA from R-bands of restriction endonuclease HaeIII with C-banding combined with DAPI or Chromomycin A3 staining. Structural factors relating to regional differences in DNA and/or proteins could also explain these results.     

萝卜蚜和豆蚜染色体C-带带型比较与分析

本研究利用C-带技术,显示出萝卜蚜和豆蚜的染色体C-带带型,并进行了初步分析。萝卜蚜与豆蚜的染色体在组型上只有第4对染色体稍有区别;在带型上两者有很明显的差异。萝卜蚜有2对散漫着丝粒染色体,豆蚜没有该种染色体。豆蚜的第4对染色体在端部缺少-C带带纹。萝卜蚜的第2对染色体与豆蚜的第2对染色体带型相似。根据萝卜蚜和豆蚜的C-带带型,讨论了二者在进化中的亲缘关系。     

C-banded karyotypes and polymorphisms in hexaploid oat accessions (Avena spp.) using Wright's stain.

A chromosome C-banding protocol using Wright's stain was employed to compare chromosomes in cultivars and wild accessions of several hexaploid oat taxa (Avena spp.). This technique permits the identification of each of the 21 somatic hexaploid oat chromosomes. Digital images of C-banded cells were captured on computer and used to construct karyotypes of several oat accessions. Polymorphisms for C-bands among oat cultivars and wild accessions are described. These banding polymorphisms can be used to trace introgression of chromosomes from wild sources and to provide physical markers on the genetic map for oat. Although C-banding permits the identification of likely C-genome chromosomes based on comparisons with C-banding patterns in diploid and tetraploid Avena species, the A and D genomes cannot be readily differentiated based on their banding patterns.     

Chromosome banding in Amphibia

Fixed metaphase chromosomes of several species of Amphibia were treated with various restriction endonucleases and subsequently stained with Giemsa. Metaphases of man and chicken were examined in parallel under the same experimental conditions for comparison. The restriction enzymes always induce subsets of the C-banding patterns present in the amphibian karyotypes. The heterochromatic regions can be either resistant or sensitive to the restriction enzyme. The modified C-banding patterns revealed by different restriction endonucleases in the karyotype of the same species can be either extremely dissimilar or almost completely congruent. Correspondingly, the action of the same restriction enzyme on the karyotypes of different species may vary greatly. There is only rarely a correlation between the type of C-banding patterns produced by different restriction endonucleases and their specific base pair recognition sequences. In contrast to mammalian and avian chromosomes, restriction enzymes induce no multiple G-banding patterns in amphibian chromosomes. This is attributed to the difference in organization of the DNA in the genomes of poikilothermic vertebrates. The possible mechanisms of restriction endonuclease banding and the various uses of this technique for amphibian chromosomes are discussed.     

Evaluation of phylogenetic relationships between five polyploid Aegilops L. species of the U-genome cluster by means of chromosomal analysis

Four tetraploid (Aegilops ovata, Ae. biuncialis, Ae. columnaris, and Ae. triaristata) and one hexaploid (Ae. recta) species of the U-genome cluster were studied using C-banding technique. All species displayed broad C-banding polymorphism and high frequency of chromosomal rearrangements. Chromosomal rearrangements were represented by paracentric inversions and intragenomic and intergenomic translocations. We found that the processes of intraspecific divergence of Ae. ovata, Ae. biuncialis, and Ae. columnaris were probably associated with introgression of genetic material from other species. The results obtained confirmed that tetraploid species Ae. ovata and Ae. biuncialis occurred as a result of hybridization of a diploid Ae. umbellulata with Ae. comosa and Ae. heldreichii, respectively. The dissimilarity of the C-banding patterns of several chromosomes of these tetraploid species and their ancestral diploid forms indicated that chromosomal aberrations might have taken place during their speciation. Significant differences of karyotype structure, total amount and distribution of C-heterochromatin found between Ae. columnaris and Ae. triaristata, on the one hand, and Ae. ovata and Ae. biuncialis, on the other, evidenced in favor of different origin of these groups of species. In turn, similarity of the C-banding patterns of Ae. columnaris and Ae. triaristata chromosomes suggested that they were derived from a common ancestor. A diploid species Ae. umbellulata was the U-genome donor of Ae. columnaris and Ae. triaristata; however, the donor of the second genome of these species was not determined. We assumed that these tetraploid species occurred as a result of introgressive hybridization. Similarity of the C-banding patterns of chromosomes of Ae. recta and its parental species Ae. triaristata and Ae. uniaristata indicated that the formation of the hexaploid form was not associated with large modifications of the parental genomes.     

Characterization of chromosomes and localization of the rDNA locus in the aye-aye (Daubentonia madagascariensis).

The karyotype of a prosimian primate, the aye-aye (Daubentonia madagascariensis), is described. Results from a variety of staining methods (Q-, R-, G-, and C-banding, distamycin A/DAPI and methyl-green/DAPI) are reported. Sites of methylation were visualized using antibodies against 5-methylcytosine. Digestion of aye-aye fixed metaphase chromosomes with the restriction endonuclease HaeIII produced G-banding. No other restriction enzymes tested produced clear G- or C-banding patterns. Ag-staining of the nucleolar organizer regions (NORs) revealed the location of rDNA sites on the short arms of the smallest pairs of acrocentric chromosomes, 13p and 14p.     

C-banding variation in the Moroccan oat species Avena agadiriana (2n=4x=28)

The C-banding technique was used to describe the chromosomes of a relatively recently-discovered Moroccan oat species, Avena agadiriana (2n=4x=28). A substantial amount of polymorphism for arm ratios and C-banding patterns was observed among five accessions of this species. However a common set of ten putatively homologous chromosomes was identifiable among the five accessions. The chromosomes of A. Agadiriana do not closely match those of any of the previously described diploid or tetraploid oat species in terms of their arm ratios and C-banding patterns. However, their overall C-banded appearance generally resembles the A/B/D groups of chromosomes of Avena species, rather than the more hetrochromatic C genomes. Implications of these findings in terms of chromosome evolution in the genus Avena are discussed.Contribution no. 95-490-J of the Kansas Agricultural Experiment Station, Kansas State University, Manhattan, KS, USA     

The role of chromosomal proteins in the C-banding of Allium cepa chromosomes.

When chromosomes of Allium cepa are subjected to a C-banding procedure (incubation in saturated barium hydroxide followed by phosphate buffer at 60 degrees C for 1 h) and then treated with Giemsa stain, bands appear at the telomeres of all chromosomes. Microspectrophotometric measurements of Feulgen-DNA content, demonstrated that the C-banding procedure extracted DNA from the nuclei. Staining of banded chromosomes with several DNA-specific stains showed that this loss was differential, with the band DNA exhibiting more resistance to extraction than that of the rest of the chromosome. The C-banding procedure did not extract chromosomal proteins, however, and no difference in mass per unit length could be detected by Nomarski optics between band and interband regions. Several experiments demonstrated that chromosomal proteins play a significant role in C-banding. First, treatment of chromosomes with pronase before C-banding resulted in the elimination of differential staining with Giemsa. Furthermore, in preparations where the DNA was completely hydrolysed with hot TCA, the remaining chromosomal proteins were found to exhibit a differential affinity for Giemsa stain. Amido black staining demonstrated that total chromosomal protein was uniformly distributed after the hot TCA digestion, but the proteins localized in the telomeres had a greater affinity for the Giemsa stain than the bulk of the chromosomal proteins. When the TCA-digested chromosomes were subjected to the C-banding procedure before staining, the differential affinity of the telomeres for the Giemsa stain was lost. Thus, C-banding appears to be the result of a complex interaction between protein and DNA in which the greater resistance to extraction of the band DNA is necessary to stabilize and preserve chromatin protein which exhibits a differential affinity for Giemsa stain.     

Giemsa C-banded karyotypes of two subspecies ofHordeum brevisubulatum from China

C-banding patterns ofH. brevisubulatum subsp.brevisubulatum (2x) and subsp.turkestanicum (4x) had conspicuous telomeric C-bands in at least one chromosome arm with a minor difference in average band size between subspecies. Other conspicuous bands were few in number as in other taxa of the species complex. The C-banded area of the chromosomes was estimated to be 7 to 8 and 6 per cent, respectively. C-banding- and SAT-chromosome polymorphisms were observed in both subspecies. The latter and previous observations indicate that the number of SAT-chromosomes is a less reliable diagnostic character. Nucleolar organizer region polymorphisms were demonstrated through silver nitrate staining of nucleoli. C-banding patterns corroborated that tetra- and hexaploid cytotypes of subsp.turkestanicum form an autopolyploid series. Reliable identification ofH. brevisubulatum taxa based on cytological criteria should include the simultaneous use of C-banding patterns, and number and morphology of marker chromosomes.     

Chromosome evolution in the genus Poecilimon (Orthoptera, Tettigonioidea, Phaneropteridae)

Cytotaxonomic analysis of 20 species and subspecies of the genus Poecilimon using C-banding pattern, chiasma frequency, and morphometric characteristics of the chromosomes were described. Using a cladistic analysis the chromosome data provided a basis to produce a phylogenetic tree which was compared with a tree based on morphological characters and DNA sequence data. There are important differences in the grouping of data sets to species obtained on the basis of morphology/DNA analyses and that based on chromosomes. The explanation of the differences between C-banding patterns and taxonomic proximity is probably that the C-banding pattern changes quickly as the result of the high degree of variation of constitutive heterochromatin.     

Characterization of Hordeum chilense chromosomes by C-banding and in situ hybridization using highly repeated DNA probes.

C-banding patterns of Hordeum chilense and of Triticum aestivum 'Chinese Spring' - H. chilense disomic addition lines were analyzed and compared with in situ hybridization patterns using a biotin-labeled highly repetitive Triticum tauschii DNA sequence, pAs1, and a wheat 18S-26S rDNA probe. All seven H. chilense chromosomes pairs and the added H. chilense chromosomes present in the addition lines were identified by their characteristic C-banding pattern. Chromosome morphology and banding patterns were similar to those of the corresponding chromosomes present in the parent H. chilense accession. A C-banded karyotype of the added H. chilense chromosomes was constructed and chromosome lengths, arm ratios, and relative length, as compared with chromosome 3B, were determined. The probe pAs1 was found to hybridize to specific areas on telomeres and interstitial sites along the chromosomes, allowing the identification of all seven pairs of the H. chilense chromosomes. Comparison of the patterns of distribution of the hybridization sites of clone pAs1 in the T. tauschii and H. chilense chromosomes was carried out by in situ hybridization on somatic metaphase chromosomes of the HchHchDD amphiploid. In situ hybridization using the 18S-26S rDNA probe confirmed that the H. chilense chromosomes 5Hch and 6Hch were carrying nucleolus organizer regions. The results are discussed on the basis of phylogenetic relationships between D and Hch genomes.     

Endonuclease banding of isolated mammalian metaphase chromosomes

Evidence is presented that endonuclease digestion of isolated, unfixed chromosomes results in the production of banding patterns similar to those produced by digestion of fixed, air-dried chromosomes. Mouse L cell chromosomes were isolated under acidic or relatively neutral pH conditions, exposed in situ (as wet mounts on glass slides) or in vitro (in suspension) to micrococcal nuclease, Alu I or Eco RI, treated with a buffered salt solution, and stained with Giemsa. After any of these endonuclease treatments in situ, the centromeric regions of the chromosomes were intensely stained, characteristic of the C-banding observed in fixed chromosomes exposed to the same treatments. Although the fixed chromosomes were morphologically well-preserved after endonuclease digestion, the morphology of chromosomes digested in situ was variable, ranging from normal to swollen to highly distorted chromosomes. In the latter, the endonucleases induced dispersion of non-C-band chromatin; however, C-bands were still apparent as condensed, differentially-stained regions. Exposure of isolated chromosomes to Alu I in vitro also resulted in well-defined C-banding and led to the extraction of about 70% of the chromosomal DNA. From these results, the mechanism of endonuclease-induced C-banding appears to involve the dispersion and extraction of digested chromatin.     

DNA probes for identifying chromosomes 5, 6, and 7 of Schistosoma mansoni

Schistosoma mansoni has a genome of 270 Mb contained on 8 pairs of chromosomes. C-banding has been a useful technique in identifying the 7 autosomal and sex chromosomes. However, even with C-banding, S. mansoni chromosomes 5, 6, and 7 are difficult to discriminate from each other, because of their small sizes, morphological similarity, and poor banding patterns. We have identified probes that specifically paint chromosomes 5, 6, and 7 of S. mansoni with the use of chromosome microdissection and the degenerate oligonucleotide-primed polymerase chain reaction (DOP-PCR). Exact chromosome identification is required for accurate chromosome mapping of genomic clones and genetic elements, which is an essential component of the schistosome genome project.     

C-banded karyotypes of two Silene species with heteromorphic sex chromosomes.

Mitotic metaphase chromosomes of Silene latifolia (white campion) and Silene dioica (red campion) were studied and no substantial differences between the conventional karyotypes of these two species were detected. The classification of chromosomes into three distinct groups proposed for S. latifolia by Ciupercescu and colleagues was considered and discussed. Additionally, a new small satellite on the shorter arm of homobrachial chromosome 5 was found. Giemsa C-banded chromosomes of the two analysed species show many fixed and polymorphic heterochromatic bands, mainly distally and centromerically located. Our C-banding studies provided an opportunity to better characterize the sex chromosomes and some autosome types, and to detect differences between the two Silene karyotypes. It was shown that S. latifolia possesses a larger amount of polymorphic heterochromatin, especially of the centromeric type. The two Silene sex chromosomes are easily distinguishable not only by length or DNA amount differences but also by their Giemsa C-banding patterns. All Y chromosomes invariably show only one distally located band, and no other fixed or polymorphic bands on this chromosome were observed in either species. The X chromosomes possess two terminally located fixed bands, and some S. latifolia X chromosomes also have an extra-centric segment of variable length. The heterochromatin amount and distribution revealed by our Giemsa C-banding studies provide a clue to the problem of sex chromosome and karyotype evolution in these two closely related dioecious Silene species.     

C-banding analysis of eight species ofKengyilia (Poaceae: Triticeae)

To characterize chromosomes and the interspecific relationships within the genus Kengyilia, 8 species were used for Giemsa C-banding analysis. Results indicated that the species differed in C-banding patterns. K. gobicola, K. alatavica and K. batalinii had distinct centromeric bands and no banded chromosomes, while K. hirsuta, K. longiglumis, K. melanthera, K. rigidula and K. thoroldiana had more abundant and diagnostic C-bands with interstitial and terminal bands.     

A high-resolution karyotype of cucumber (Cucumis sativus L. 'Winter Long') revealed by C-banding, pachytene analysis, and RAPD-aided fluorescence in situ hybridization.

Using molecular cytogenetic DNA markers, C-banding, pachytene analysis, and fluorescence in situ hybridization (FISH), a high-resolution karyotype was established in the cucumber. C-banding showed distinct hetero chromatic bands on the pericentromeric, telomeric, and intercalary regions of the chromosomes. The C-banding patterns were also consistent with the morphology of 4'-6-diamino-2-phenylindole dihydrochloride (DAPI)-stained pachytene chromosomes. Two repetitive DNA fragments, CsRP1 and CsRP2, were obtained by PCR and localized on the mitotic metaphase and meiotic pachytene chromosomes. CsRP1 was detected on the pericentromeric heterochromatic regions of all chromosomes, except chromosome 1. CsRP2 was detected on 5 (chromosomes 1, 2, 3, 4, and 7) of 7 chromosomes. All homologous chromosome pairs could be distinguished by FISH using 2 RAPD markers. This is the first report on molecular karyotyping of mitotic and meiotic spreads of cucumber.     

Cytogenetic characterization of the Zebra Mussel Dreissena polymorpha (Pallas) from Miedwie Lake, Poland

Cytogenetic characterization of D. polymorpha was carried out using banding techniques such as C-banding, fluorochrome CMA3 and silver nitrate treatment. The diploid chromosome number of both investigated D. polymorpha forms (typical and albinotic) was the same 2n = 32 (NF = 56). The karyotype consisted of 5 pairs of metacentric, 7 pairs of submetacentric and four pairs of subtelo-acrocentric chromosomes. Ag-NORs were located in the telomeric position on the largest subtelo-acrocentric chromosome pair. C banding patterns indicate many sites of constitutive heterochromatin mainly located in the telomeric regions and interstitially in some chromosomes. CMA3-sites were observed in almost all chromosomes; apart from the Ag-NORs sites, they were located terminally on the chromosome arms and interstitially on three chromosome pairs. Sixteen chromosomes could be counted at the diakinesis stage of meiosis. No differences in banding chromosome patterns were found neither between both analyzed forms of D. polymorpha nor between males and females.     

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。     

Recent chromosome diversification in the evolutionary radiation of the freshwater fish family Curimatidae (Characiformes)

Neotropical Curimatidae fishes include 97 species in eight genera. Basic cytogenetic studies show a karyotype of 2 n = 54 chromosomes in most species. Karyotype divergence of the nucleolus organizing regions between species has been reported, and these regions appear to be good cytotaxonomic markers. In the present work, karyotype, heterochromatin and Ag-NOR variability in 13 species were investigated to analyse the chromosome diversification in view of the biogeographic history of this group. Only Cyphocharax platanus showed a karyotype with 2 n = 58 chromosomes. Ag-NOR and C-banding patterns were quite divergent among the species studied. All species whose C-bands were analysed had heterochromatic blocks associated with the nucleolus organizing regions. Species with multiple Ag-NORs also showed an increase in NOR-associated heterochromatic blocks. C-banding showed considerable differentiation among species, revealing a pronounced chromosome diversification in this group. Karyotypic variability corroborates the hypothesis that these fishes in Amazon region show various discrete patterns of species endemism. Chromosome diversification in curimatids has a recent origin and appears to be accompanying the post-Andean speciation responsible for the diversity of species in the family.