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。     

Flow cytometric sorting of maize chromosome 9 from an oat-maize chromosome addition line

Large numbers of maize chromosome 9 can be collected with high purity by flow cytometric sorting of chromosomes isolated from a disomic maize chromosome addition line of oat. Metaphase chromosome suspensions were prepared from highly synchronized seedling root-tips of an oat-maize chromosome-9 addition line (OM9) and its parental oat and maize lines. Chromosomes were stained with propidium iodide for flow cytometric analysis and sorting. Flow-karyotypes of the oat-maize addition line showed an extra peak not present in the parental oat line. This peak is due to the presence of a maize chromosome-9 pair within the genome of OM9. Separation of maize chromosome 9 by flow cytometric sorting of a chromosome preparation from a normal maize line was not possible because of its size similarity (DNA content) to maize chromosomes 6, 7 and 8. However, it is possible to separate maize chromosome 9 from oat chromosomes and chromatids. An average of about 6×10³ chromosomes of maize chromosome 9 can be collected by flow-sorting from chromosomes isolated from 30 root tips (ten seedlings) of the oat-maize addition line. Purity of the maize chromosome 9, sorted from the oat-maize chromosome addition line, was estimated to be more than 90% based on genomic in situ hybridization analysis. Sorting of individual chromosomes provides valuable genomic tools for physical mapping, library construction, and gene isolation. Received: 28 February 2000 / Accepted: 14 July 2000     

Mapping of sister-chromatid exchanges in human chromosomes using G-banding and autoradiography.

Lumphocytes were pulse-labelled with [3H] thymidine. Following G-banding, the cells were autoradiographed and 46 in their third post-labelling division selected. The locations of 611 sister-chromatid exchanges (SCE's) which had occurred in the previous two cell cycles were recorded as label discontinuities along identified chromosomes. Between particular chromosomes, SCE frequency was proportional to chromosome length. SCE frequency distributions within particular chromosomes fitted Poisson expectations. There was no over-representation of exchanges in centromeric regions, or in the C-banded regions of chromosomes 1, 9 and 16. A trend of increased frequency of SCE in darkly G-banded regions and in relatively darkly banded chromosomes was evident. The apparent excess of SCE in dark G-bands could be considered to be a consequence of the more condensed state of the DNA in these regions in the interphase nucleus relative to the DNA in pale G-band regions. Such compaction could result in an enhanced probability of SCE and a reduced probability of gross inter- or intra-change involving these regions. In contrast, the more extended interphase state of the DNA in pale G-banded regions would allow non-homologous exchange and account for the preferred location of X-ray-induced exchange events to pale G-bands.     

Studies on G-bands and Macrocoils in Plant Chromosomes

Four different methods including trypsin urea, SDS and NaOH are presented for the in situ induction of G-bands and macrocoils on the chromosomes of Secale cereale, Hordeum vulgare and Vicia faba. The bands obtained were numerous and along the whole chromosome, the number of the G-bands was much interrelated with the condensation of chromosomes. The bands of homologous chromosomes in some cells were matchable. The G-banded chromosomes in late prophase have nearly reached high resolution level. When incubation periods were beyond critical time for G-banding, macrocoils were often revealed. Gyre number changed with chromosome condensation and the direction of coils has showed different patterns. Transformation of G-bands into macrocoils was first reported in plant chromosomes. Some chromosomes showing G-bands under light microscope appeared spiral patterns under scanning electron microscope. In this paper the relationship between G-bands and macrocoils in plant chromosomes is also discussed.     

Harlequin banding and localisation of sister-chromatid exchanges.

Harlequin banding (HB) was standardised on Indian muntjac chromosomes by superimposing harlequin staining or sister-chromatid differentiation and G-banding after incorporation of bromodeoxyuridine (BrdU) or cholorodeoxyuridine (CldU), and after treatment with BrdU plus mitomycin C (MMC). SCEs were localized on these chromosomes with the aid of the G-band map. There were more SCEs in G-bands than in R-bands in BrdU-incorporated chromosomes. CldU-incorporated chromosomes, however, did not show a preferential localization of SCEs in either G- or R-bands. When BrdU + MMC-induced SCEs were localized in harlequin-banded chromosomes, there was a significantly greater number of SCEs in R-bands; and there was a concomitant reduction in the frequency of SCEs in G-bands, as compared to the SCEs observed in this region after BrdU incorporation alone. Centromeric regions of chromosomes 1 and X had preferred sites for occurrence of SCEs in BrdU-incorporated chromosomes, the preferred sites being more in G-bands after BrdU and CldU incorporation and in R-bands after treatment of BrdU-incorporated chromosomes with MMC. Thus the formation of SCEs is not restricted by structure per se as defined by euchromatin or heterochromatin, but depends on the site of lesion production, type of lesion and repair pathway followed.     

植物染色体G-带的初步研究

本文首次报道了川百台(Lilium davidii)、华山松(Pinus armardii)和七叶一枝花(Paris polyphylla)等植物染色体G-带研究结果。本试验的G-带与以往的C-带不同,C-带每条染色体上一般只有1-4条带,多分布在着丝点附近,而G-带则多达几十条,分布在整条染色体上,带纹清晰,前期染色体带呈颗粒状,中期染色体呈明显的带状,与哺乳动物染色体G-带很相似。G-带的数目取决于染色体浓缩的程度。前期染色体带纹数目是中期的三倍,接近人类高分辨带水平。对G-带带纹采用了自动光谱分析,波峰数值与带纹相符。作者同时介绍了胰酶法在植物染色体G-带中的应用。认为此方法既适合动物亦适用于植物。但植物G-带显示的关键可能不在胰酶法本身,而在合适的分裂时期及染色体处理技术。     

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.     

Electron microscopy of G-banded human mitotic chromosomes

Trypsin-treated human metaphase chromosomes stained with Giemsa and uranyl acetate showed clear, reproducible band structures under the transmission electron microscope (TEM). The banding pattern observed with TEM corresponded very closely to the G-band pattern visualized by light microscopy. The TEM images were used for karyotype analyses. Trypsin-treated chromosomes stained with uranyl acetate alone also showed clear G-bands under TEM. Shadow casting in addition to uranyl acetate staining revealed more structural detail of the chromosomes. Chromosome fibers, 200 Å–300 Å in diameter, were observed in the interband regions. Most chromosomes showed the major G-bands under the higher TEM magnification wit0out any trypsin treatment.     

The occurrence of G-bands in the mitotic chromosomes of the amphibian Xenopus muelleri

The mitotic chromosomes from cultured cells of Xenopus muelleri were G-banded with trypsin and/or with trypsin/urea. These amphibian chromosomes were not found to be more highly contracted at metaphase than those of mammals or reptiles and trypsin G-banding was more easily induced than in the case of most reptilian chromosomes. The organization of vertebrate chromosomes into distinct early replicating (R-bands) and late replicating (G-bands) replicon clusters may be characteristic of eucaryotes in general.     

The ultrastructure of G- and C-banded chromosomes

A method of visualizing chromosome bands by electron microscopy has been used to investigate the fine structural organization of G- and C-banded chromosomes. The following information has been obtained:

1. 1. G-bands, produced by trypsinization, were electron dense regions of highly packed chromatin fibres separated by regions in which the chromatin fibres were much less densely packed (interbands).

2. 2. Several degrees of chromatin dispersion were apparent in trypsinized chromosomes. Such dispersion was not a prerequisite for the initial visualization of G-bands, however the progressive pattern of dispersion indicated that the bands were relatively more resistant to dispersion than the interbands.

3. 3. After fixation and trypsinization, individual chromatin fibres measured 250 Å in diameter and appeared morphologically similar to control chromatin fibres seen by whole mount electron microscopy.

4. 4. In trypsinized chromosome complements, the chromosomes often appeared to be interconnected to one another by chromatin fibres. The evidence indicates that these interchromosomal fibres are artefacts produced by the overlapping of dispersed chromatin fibres.

5. 5. When the same metaphase chromosome was observed by both light and electron microscopy, some of the light microscopic G-bands were represented by two or more ultrastructural bands. The number of bands seen in metaphase chromosomes by electron microscopy appears to approach the increased number of bands generally seen in prometaphase chromosomes by light microscopy.

6. 6. C-banding methods (NaOH treatment or overtrypsinization) resulted in the extraction of variable amounts of chromatin from the non C-band regions of the chromosomes, however the constitutive heterochromatin remained highly condensed and resistant to extraction. This result supports the hypothesis that the mechanism of C-banding involves the selective loss of non C-band chromatin.

     

High resolution bands in maize chromosomes by G-banding methods

Summary It was demonstrated that G-bands are unequivocally present in plant chromosomes, in contrast to what had been formerly believed by plant cytologists. Maize chromosomes prepared by an enzymatic maceration method and treated with trypsin or SDS showed clear G-bands spreading along the chromosomes. The most critical point during the G-banding procedures was the post-fixation with glutaraldehyde solution. Banding patterns were processed by using the chromosome image analyzing system and a clearer image was obtained. Gbanding technique and the image manipulation method described here can be applied to many plant species, and would contribute new information in the field of plant cytology and genetics.     

植物染色体高分辨G-带技术研究

本文对植物染色体高分辨 G-带技术进行了比较系统的研究,并首次运用改良的尿素法在野生一粒小麦、玉米、蚕豆、吊兰、川百合等多种植物上诱导出 G-带,带纹清晰,数目多,分布在染色体全长上。前期染色体带呈颗粒状,中期染色体呈明显带状,与哺乳动物染色体 G-带很相似。G-带的数目取决于染色体浓缩程度,中期染色体一条深带到晚前期可显示出2.67条亚带。作者同时比较了胰酶法与尿素法的显带效果。认为两种方法显示的带纹基本相同,尿素法比胰酶法作用温和,显带时间长达数分钟,易于掌握,重复性高,具有更高的应用价值。     

Differential decondensation of mitotic chromosomes during hypotonic treatment of living cells as a possible cause of G-banding: an ultrastructural study

The chromosomal ultrastructure of Chinese hamster cells treated with 0.075 M KCl — a solution ordinarily used for making preparations of spread chromosomes — was studied. The hypotonic treatment was shown to result in differential decondensation of chromosomes which consists in the uneven distribution of deoxyribonucleoprotein (DNP) fibrils along chromatids. Fixation of cells with methanol acetic acid causes an abrupt restructuring of chromosomes. However, the DNP preserves its uneven distribution along chromatids. As seen on ultra-thin sections of marker nucleolus organizer chromosomes, the densely packed regions may correspond to G-bands detected in the selfsame chromosomes by standard methods of differential staining. The results suggest that the capacity of chromosomes for differential staining is based on the different resistance of G- and R-bands to the decondensing action of hypotonic solutions on living cells.     

家猪减数分裂粗线期二价体与有丝分裂中期染色体的比较研究

以性成熟公猪睾丸和外周血为材料,采用长低渗、高氯仿卡诺固定液固定和外周血细胞培养制备减数分裂粗线期二价体和有丝分裂中期染色体,通过对二价体和有丝分裂中期染色体分裂指数和长度的比较研究,发现二价体的分裂指数和长度分别是有丝分裂中期染色体的5倍和3．42倍（1．87～5．98）;同时以12号染色体为例,比较了二价体上的染色粒结构带与有丝分裂中期染色体G－带,表明染色粒结构带比中期染色体G－带纹丰富,而与早中期G－带带织吻合。     

Fluorescent staining of L cell centromeres and chromocenters with 1-dimethylaminonaphthalene-5-sulfonyl chloride and G-bandings

Fluorescent staining patterns of L cell chromosomes with 1-dimethylaminonaphthalene-5-sulfonyl chloride (dansyl chloride) were studied. Ordinary air-dried L cell metaphase chromosomes exhibited relatively uniform and bright yellowish green fluorescence by dansyl-staining under the fluorescence microscope. However, after the chromosome preparations were treated with 10 mM NaCl for 24 h at 4 °C, which produced distinctive G-bands with Giemsa-staining, the centromeric regions and several interstitial regions of some particular chromosomes were clearly fluorescent but other regions showed only dull fluorescence. After the treatment of chromosome slides with cupric sulfite reagent, which converts sulfhydryls and disulfides to thiosulfates chromosomes showed clear G-bands which were indistinguishable from those after 10 mM NaCl treatment. By dansyl-staining, however, the cupric sulfite-treated chromosomes exhibited very faint fluorescence on their contour alone, and neither centromeric regions nor some interstitial regions of marker chromosomes had distinctly bright fluorescence.Although Giemsa-staining disclosed dark chromocenters in approx. 75% of interphase nuclei irrespective of pretreatments, dansyl-staining revealed bright chromocenters in approx. 60% of interphase nuclei in control slides, in about 40% of nuclei in 10 mM NaCl-treated slides, and in only about 30% of nuclei in cupric sulfite-treated preparations.These observations indicated that in the air-dried chromosome preparations, the distribution of protein over the metaphase chromosome is relatively uniform along its length, and that G-bands in the chromosome and Giemsa-staining of chromocenters in interphase nuclei are not significantly affected by apparent loss of protein from the preparations. It was also suggested that particular protein may be associated with the centromeric regions of L cell chromosomes. Some technical details of dansyl fluorochroming and the significance of the observations were discussed.     

利用胚胎和幼孢子体进行蕨类细胞学研究

以蕨类植物胚胎和幼孢子体根为实验材料,以根尖和孢子母细胞为对照,进行细胞学观察方法的比较研究.结果显示:(1)野外材料的根尖仅在春季分裂期约1个月时间内存在分裂相,根尖个体数目较少(每植株根尖数目＜20条),根尖细胞内含有较坚硬的黏性物质,利用单株根尖进行压片,成功率低于40％;而从野外采回培养时根尖生长极为缓慢且较难成活,因而影响实验效果.(2)野外材料的孢子母细胞仅在孢子囊形成期约1周时间内存在分裂相,因此极大地限制了细胞学观察研究.(3)以胚胎和幼孢子体根为材料进行实验,单位面积(d=15cm培养皿)内幼孢子体根尖或胚胎的数量多于300个,分裂期细胞比例高,且细胞间基本不含黏性物质,进行细胞学研究时较少受到季节和实验时间的限制;利用单株根尖或胚胎进行压片,成功率高于80％.因此,利用蕨类植物的胚胎和幼孢子体根进行细胞学研究能有效地提高蕨类植物细胞学观察实验的成功率.     

The mechanism of C- and G-banding of chromosomes

A series of biochemical, staining and electron microscopy techniques were utilized to investigate the mechanisms of C- and G-banding. These led to the following conclusions.

1. 1. The treatment of fixed chromosomes with 0.07 N NaOH for 30 to 180 sec removes from 16 to 81% of the DNA from the chromosomes.

2. 2. On average, the complete C-band technique removes 60% of the DNA.

3. 3. This DNA is preferentially extracted from the non-C-band regions.

4. 4. In marked contrast to this, all G-band techniques (except 1) removed less than 9% of the chromosomal DNA.

5. 5. Most of the G-band techniques, including those using trypsin, remove very little protein from the chromosomes.

6. 6. Feulgen staining indicated that neither C- nor G-banding can be explained on the basis of different amounts of DNA along the length of the chromatid.

7. 7. Treatment of chromosomes with alkali or prolonged treatment with trypsin tends to destroy G-bands, while C-bands remain.

8. 8. The combined use of acridine orange and Giemsa staining indicate that, (a) repetitious DNA in situ renatures in seconds while non-repetitious DNA renatures in minutes; (b) Neither C- nor G-banding depends upon the differential renaturation of DNA for its effect.

9. 9. G-banding is more delicate and relatively mild conditions allow staining of both C- and G-bands. To obtain only C-bands the chromosome must be treated more harshly to disrupt or destroy the G-bands.

10. 10. DNA-non histone protein interactions probably play an important role in the production of both C- and G-banding.

     

Visualization of R-bands in human metaphase chromosomes by the restriction endonuclease MseI

Human metaphase chromosomes were treated with the restriction endonuclease MseI, which cuts DNA at TTAA sequences. This enzyme preferentially cuts and extracts DNA from G-bands and thus is the first restriction endonuclease allowing direct R-band visualization. Specific patterns ranging from R+C-like to C-like banding can be induced, depending on the concentration of the enzyme. At intermediate concentrations, only a subset of R-bands are produced, corresponding to GC-rich bands that are especially resistant to heat denaturation (so-called T-bands). These results suggest that compositional differences between chromosomal regions determine the different rates of cleavage by MseI, not only between R- and G-bands but also among different R-bands.     

Cytogenetic characteristics of the cell line BHK-21 (C-13) and three of its clones

Cell clones (C-9, C-24, C-36) of the cell line BHK-21 (C-13) were obtained and characterized. Compared to the original line, cells of these clones are larger in size, display an increased content of nuclear DNA and have more chromosomes. The G-bands were obtained by Giemsa staining following mild trypsin treatment. Marker chromosomes were determined in the original cell line BHK-21 (C-13) and in its large-cell clones. All the clones obtained are polyploid.     

Cell cycle parameters and accumulation of metaphase cells in maize suspension cultures

Cell cycle parameters of maize (Zea maysL cv Black Mexican Sweet) suspension cultures and root meristem cells were determined by pulse labelling with [³H]thymidine ([³H]TdR). Total cell cycle time for the suspension cultures was 27 h; 3 h in G1, 14 h in S, 6 h in G2, 2.2 h in prophase, 1 h in metaphase, 0.1 h in anaphase, and 0.7 h in telophase. Cell cycle durations in root meristem cells of Black Mexican Sweet (BMS) corn with and without B chromosomes in vivo were 20.0 h and 18.3h, respectively. Chemical and physical methods were used successfully to accumulate mitoses in the suspension cultures; compared to the untreated control, the mitotic index of the treated cultures was increased from 4 to 23% and the frequency of metaphase cells increased dramatically from 3 to 19%.