C- and G-bands of the opossum chromosomes: terminal sequences of DNA replication.

The sex chromosomes of the opossum, Didelphys virginiana, are the only elements that exhibit C-banding. In contrast, the sex chromosomes as well as the autosomes bear specific G-Bands. However, unlike other mammalian species different types of G-banding are observed if the chromosomes are pretreated with trypsin and SSC solution The SSC-pretreated chromosomes show discrete bands only when stained with Giemsa at certain pH values. An asynchronous pattern of terminal DNA replication is observed among the three C-banding regions of the X-chromosome. The inter- and intrapositive G-banding areas of the chromosomes are not always late in DNA replication in comparison to those negatively stained G-banding areas.     

Chromosomal rearrangements in rock wallabies, Petrogale (Marsupialia: Macropodidae). VI. Determination of the plesiomorphic karyotype: G-banding comparison of Thylogale with Petrogale persephone, P. xanthopus, and P. l. lateralis.

G-banding has demonstrated the presence of a conserved (2n = 22) chromosome complement in the macropod genus Thylogale and in some Petrogale species. This plesiomorphic karyotype consists of acrocentric chromosomes 1, 2, 5, 6, 8, 9, and 10; submetacentric chromosomes 3 and 4; and a metacentric chromosome 7. It should now be possible to relate the G-banding patterns of all other Petrogale species to this plesiomorphic complement and thereby determine the number and types of changes that have occurred during the course of chromosome evolution in Petrogale. It is hypothesised that this 2n = 22 complement is plesiomorphic for all macropodids.     

Chromosomal analysis of the pygmy chimpanzee (Pan paniscus) with a comparison to man.

The karyotype of Pan paniscus is reexamined by G-banding and examined for the first time by C-banding. In addition, examination of the chromosomes by the use of the fluorochromes adreamycine and 33258 Hoechst is undertaken. C-banding showed a surprising pattern with numerous terminal C-bands, as interstitial C-band, and several chromosomes lacking C-bands. Polymorphic conditions for C-bands are also identified involving several pairs. In a comparison to the chromosomes of man, G-banding revealed two pericentric inversions not previously observed. Only chromosome pairs No. 9,11,12 and the X are similar to man's by all techniques employed.     

Histones in cytological preparations

The presence of histones in fixed cytological preparations has been examined in order to investigate whether histones could be involved in G-banding. Up to 80% of the total cellular histones are removed by fixation. The remaining 20%, resistant to extraction by fixation, consist principly of histone fractions f1 and f2b. Dilute acid fails to remove quantitatively the histones that remain in cytological preparations after fixation. Trypsin treatment that results in banded patterns alters the presence of the remaining histones but heat treatment that results in banding fails to extract the remaining histones.     

Proteins in chromosome banding

Nuclei were isolated from Chinese hamster cells, treated with hypotonic KCl, fixed in acetic methanol, and either air-dried in glass tubes (in situ) or left in suspension (in vitro). These preparations were then exposed to a variety of G-banding treatments, including the 2 × SSC, urea, NaCl-urea, and trypsin methods. The proteins extracted into the treatment solution and those remaining in the nuclei were analyzed by SDS polyacrylamide gel electrophoresis. The three former treatments extracted specific subsets of the total nuclear nonhistone proteins into the treatment solution. Some of the extracted nonhistones were common to all treatments while others were unique to a particular treatment. Variable amounts and types of the histones were also extracted by these treatments, but significant quantities of all of these proteins still remained in the nuclei afterwards. The trypsin treatment appeared to degrade some of the nonhistones, while other non-histones, as well as the histones, were relatively resistant to trypsin digestion. Although there were a few differences in the residual proteins found in the nuclei after the various G-band treatments, the overall electrophoretic patterns of these proteins were generally similar. The results indicate that the G-banding techniques induce specific and reproducible changes in the proteins of isolated nuclei. If these banding treatments induce similar changes in the proteins of mitotic chromosomes, such alterations might be involved in mechanisms of chromosome banding.     

Multiplex-FISH for pre- and postnatal diagnostic applications.

For >3 decades, Giemsa banding of metaphase chromosomes has been the standard karyotypic analysis for pre- and postnatal diagnostic applications. However, marker chromosomes or structural abnormalities are often encountered that cannot be deciphered by G-banding alone. Here we describe the use of multiplex-FISH (M-FISH), which allows the visualization of the 22 human autosomes and the 2 sex chromosomes, in 24 different colors. By M-FISH, the euchromatin in marker chromosomes could be readily identified. In cases of structural abnormalities, M-FISH identified translocations and insertions or demonstrated that the rearranged chromosome did not contain DNA material from another chromosome. In these cases, deleted or duplicated regions were discerned either by chromosome-specific multicolor bar codes or by comparative genomic hybridization. In addition, M-FISH was able to identify cryptic abnormalities in patients with a normal G-karyotype. In summary, M-FISH is a reliable tool for diagnostic applications, and results can be obtained in 相似文献   

Configurational changes in chromatids from helical to banded structures

Induction of configurational changes in the helical chromatids of air dried chromosomes was used to explore the mechanism of G-banding. From the water-Giemsa stained metaphase spreads of Chinese hamster cells, chromosomes having clearly helical chromatids were selected and photographed. Then the chromosomes were decolorized, treated with trypsin, and restained with saline-Giemsa (1 x SSC). Such procedures were repeatedly carried out upon the same chromosomes. Subsequent examination of the chromosomes showed that configurational changes from a helical structure to a banded structure had occurred. Some chromosomes revealed a variety of transitional changes between these two configurations. During the repeated G-banding treatments, the distances between bands along the same chromatids changed each time. The results obtained seem to indicate that the G-banding results from locally induced compaction of chromosomal materials along the chromatids.     

Why plant chromosomes do not show G-bands

Summary Giemsa techniques have refused to reveal G-banding patterns in plant chromosomes. Whatever has been differentially stained so far in plant chromosomes by various techniques represents constitutive heterochromatin (redefined in this paper). Patterns of this type must not be confused with the G-banding patterns of higher vertebrates which reveal an additional chromosome segmentation beyond that due to constitutive heterochromatin. The absence of G-bands in plants is explained as follows: 1) Plant chromosomes in metaphase contain much more DNA than G-banding vertebrate chromosomes of comparable length. At such a high degree of contraction vertebrate chromosomes too would not show G-bands, simply for optical reasons. 2) The striking correspondence of pachytene chromomeres and mitotic G-bands in higher vertebrates suggests that pachytene chromomeres are G-band equivalents, and that this may also be the case in plants. G-banded vertebrate chromosomes are on the average only 2.3 times shorter in mitosis than in pachytene; the chromomeric pattern therefore still can be shown. In contrast, plant chromosomes are approximately 10 times shorter at mitotic metaphase; their pachytene-like arrangement of chromomeres is therefore no longer demonstrable.     

东北虎和华南虎染色体比较研究

采用外周血淋巴细胞培养技术,首次研究了东北虎核型、G-带,C-带和Ag-NOR以及华南虎的G-带,C-带,并就其结果进行了比较分析。结果表明:两种虎在染色体数目、G-带、C-带带型和Ag-NORs特征上,均没有明显差异。     

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。     

Karyotypic characterization of Iheringichthys labrosus (Pisces, Pimelodidae): C-, G- and restriction endonuclease banding

Various chromosomal banding techniques were utilized on the catfish, Iheringichthys labrosus, taken from the Capivara Reservoir. C-banding regions were evidenced in telomeric regions of most of the chromosomes. The B microchromosome appeared totally heterochromatic. The restriction endonuclease AluI produced a banding pattern similar to C-banding in some chromosomes; the B microchromosome, when present, was not digested by this enzyme and remained stained. G-banding was conspicuous in almost all the chromosomes, with the centromeres showing negative G-banding. When the restriction endonuclease BamHI was used, most of the telomeres remained intact, while some centromeres were weakly digested. The B chromosome was also not digested by this enzyme. The first pair of chromosomes showed a pattern of longitudinal bands, both with G-banding and BamHI; this was more evident with G-banding. This banding pattern can be considered a chromosomal marker for this population of I. labrosus.     

The karyotype of the golden monkey (Rhinopithecus r. roxellanae)

In this paper, the karyotype and G-banding pattern of the chromosomes of cultured peripheral blood lymphocytes in R. r. roxellanae were investigated. The chromosome number of this species is 44 in both sexes. In R. r. roxellanae, as in other monkeys, sex is determined by specific sex chromosomes, i.e. the male is XY and the female is XX. The 21 pairs of autosomes consist of 7 pairs of metacentric chromoomes, 13 pairs of submetacentric chromosomes and one acrocentric pair. Chromosome measurements were made from highly enlarged photographic prints. They included the relative length, arm ratio and centromere index of each chromosome. Both chromosomal and chromatid aberrations were observed. They were 0·67 and 2%, respectively. Finally, G-banding pattern analysis of chromosomes of R. r. roxellanae were carried out. The results show that each homologous pair has its own special banding pattern, so that each of them is easily recognizable. Idiograms of chromosome complements with the Giemsa banding pattern are constructed.     

The role of trypsin in the pre-treatment of chromosomes for giemsa banding

Summary The role of trypsin in the elicitation of G-banding on human chromosomes was studied in two separate laboratories. Enzyme activity and ability of trypsin to chelate calcium were manipulated by dilution of the treatment solution, and by inhibition with diisopropylphosphofluoridate, diphenylcarbamyl chloride, or soybean trypsin inhibitor. In all cases, chromosomes were affected in proportion to the enzyme activity of the treatment solution rather than the ability of the solution to bind calcium. It is concluded that calcium chelation is not sufficient to explain G-banding by trypsin, but that proteolytic activity is required.     

Changes in elemental composition of human chromosomes during a G-banding (ASG) and a C-banding (BSG) procedure.

Human chromosomes fixed in methanol-acetic acid have been examined by X-ray microanalysis, before, during and after a G-banding and a C-banding procedure. Phosphorus (representing mainly DNA), sulphur and calcium are the most prominent elements in untreated chromosomes. In the G-banding procedure, the calcium is lost during 2 x SSC treatment. In the C-banding procedure, calcium is lost in the preliminary HCl treatment. During the following barium hydroxide treatment a large amount of barium becomes attached to the chromosomes, but is lost again during the subsequent 2 x SSC treatment. In both banding techniques Giemsa staining produces large peaks for sulphur (thiazine dyes) and bromine (eosin), showing that both types of dyes are involved in the staining. Reduction in the phosphorus peak during these procedures may be partly due to extraction of DNA and other chromosomal components, but could also be due to absorption of phosphorus X-rays by heavy elements (barium and bromine).     

粳稻三体的染色体G—显带鉴定

采用有丝分裂染色体的G-显带技术,对供试的6个三体的额外染色体进行了鉴定。结果表明:A型、B型、C型、D型、E型和H型三体的额外染色体分别为K5、K6、K12、K7、K8和K10。用不同的分裂时期的细胞所鉴定出的结果完全一致。与过去所用的三体鉴定的方法相比较,利用G-显带技术鉴定三体的方法具有准确性高,稳定性和重复性好以及简便易行的优点。     

The G-banded prophase chromosomes of man.

Using a simple G-banding technique developed in our laboratory, analysis of late prophases enables the visualization of approximately 1000 bands in the haploid set of human chromosomes. These bands have been classified according to the recommendations of the Paris Conference. The increased resolution offered by this technique is likely to be useful in the study of the structure and molecular organization of chromosomes and in identifying minute chromosome defects in birth defects and neoplasia.     

Q-, C-, and G-banding patterns in the germ-line and somatic chromosomes of Miastor sp. (Diptera: cecidomyidae)

Q-, C-, and G-banding patterns are described for the germ-line and somatic chromosomes of Miastor sp. The chromosome number in the germ line is 36, which is 3 less than that previously reported for the same cultured line 18 years ago. There are 8 chromosome groups: 8 large acrocentrics, 11 large and medium submetacentrics, 4 medium metacentrics, 4 medium subtelocentrics, 6 medium telocentrics, one medium acrocentric, one small submetacentric, and one small telocentric. All 8 large acrocentrics have a Q-band and an interstitial C-band in the short arm, suggesting that these chromosomes are at least partially homologous (or homeologous) and that the germ line originally was polyploid. Only one other germ-line chromosome, the small submetacentric, has a Q-band and an interstitial C-band. In somatic cells there are 8 chromosomes, 28 chromosomes having been eliminated during early cleavage. Three of the four pairs of somatic chromosomes are heteromorphic, despite the indications of a polyploid origin of the germ-line chromosomes and despite the presence of somatic pairing. Furthermore, there is a great deal of restriction on which chromosomes are retained in somatic cells, and it may be that the same 8 chromosomes are retained by all embryos. The G-banding pattern is not as clear as the other two banding patterns. The findings are discussed in relation to observations in other cecidomyids, and a model for the evolution of the chromosome system of Miastor is presented.     

Protein-depleted chromosomes

Protein-depleted isolated Chinese hamster chromosomes have been obtained by different protein extraction procedures and examined by electron microscopy and SDS-polyacrylamide gel electrophoresis. Salt-resistant centromeric and telomeric structures are visible in protein-depleted chromosomes and the protein-depleted chromosomes appear to have a regular, longitudinal pattern in critical point dried preparations. The scaffold-like structure of protein-depleted chromosomes is highly affected by the ionic strength and composition of the extraction medium and by the spreading conditions. Nucleosomal histones of isolated chromosomes proved to be more sensitive to the sodium chloride treatment than histones of isolated chromatin. A small, but constant quantity of core histones was detected in 2 M salt extracted chromosomes and H3 and H4 histones of isolated chromosomes appeared to be resistant to the sodium deoxycholate treatment.