Banding isolated metaphase chromosomes by a sequential fluorescent G/Q technique

Summary G/Q-banding is a new, rapid, fluorescent technique for banding isolated chromosomes that incorporates characteristics of both G- and Q-banding. G-bands, while easily characterized, are often inconsistent when using isolated chromosomes, and Q-bands, while reliable, fade rapidly under UV exposure, making prolonged observation and photography difficult. G/Q-banding combines these techniques to sequentially utilize quinacrine staining over Giemsa banding to produce slow-fading fluorescent G/Q-bands. The background fluorescence in G/Q preparations fades quickly under continued UV exposure, while the chromosomes remain brightly banded and can be observed and photographed for at least five minutes. G/Q-banding was extended to whole cell chromosome spreads and produced results identical to those obtained with isolated chromosomes. Whole cell karyotypes indicate that G/Q-bands generally correspond to Q-bands. Advantages of G/Q-banding as a unique and universal technique over current double-staining procedures are discussed.     

Quinacrine fluorescence and Q-banding patterns of human chromosomes. I. Effects of varying factors.

Various factors involved in the production of "Q-bands" have been studied. It was found that a Zeiss standard WL fluorescent microscope required a shorter exposure time for photography as compared to a Zeiss photomicroscope. The minimal exposure time was obtained when the standard WL microscope was equipped with a UV light source containing a DC powered mercury burner and a concave mirror. Further, the pH and type of water used in the staining, washing and mounting of the slide were also important factors in producing clear and well differentiated "Q-bands". It also appears that the factors involved in the production of "Q-bands" effect the enhancement or quenching of fluorescence by poly d(A-T)-poly d(A-T) and salmon sperm DNA or poly dG-poly dC respectively. This preliminary report also suggests that DNA or polynucleotides with a specific base sequence may play an important role in Q-banding patterns on chromosomes.     

Localization of gamma-rays induced chromatid breaks using a three consecutive staining technique.

Three staining techniques (Giemsa, Q-banding and R-banding) are used consecutively to localize the breakage points in chromosomes of human lymphocytes, irradiated during G2-phase with gamma-rays, at doses ranging from 50 to 200 rad. The large majority, about 85% of the breaks, occurs at the interbands, between R- and Q-bands. The discrepancy of this result, with regard to previously reported ones, is attributed to the strong bias of analysis when only one staining technique is used.     

T antigen banding on chromosomes of simian virus 40 infected muntjac cells.

Chromosomes were prepared from mitotic munjac cells 48 to 72 h after infection with SV40 virus. When stained for SV40 T antigen by indirect immunofluorescence, all chromosomes within an infected cell were fluorescent, indicating the presence of T antigen. Furthermore, the chromosomes were not uniformly stained but appeared to have regions of high and low fluorescence intensity. A variety of controls showed that the banding patterns are specific and highly reproducible and may indeed reflect the binding sites of T antigen. The bright, fluorescent bands T antigen were found to correspond to bands visualized by trypsin-Giesma staining (G-bands) and also by quinacrine staining (Q-bands). Current knowledge of chromosome banding indicates that Q-bands reflect the distribution of AT-rich regions along the chromosome. From the DNA sequence of SV40, it is known that one of the T antigen binding sites contains AT-rich sequences; thus, T antigen banding might be due to the base-specific binding of T antigen to chromatin. In addition, these bands have been implicated as centers for chromosome condensation and units in control of DNA replication. While the functional significance of T antigen binding has yet to be determined, the SV40-muntjac system provides an unusual opportunity to study the interaction of a known regulatory protein with mammalian chromosomes.     

Specific Heterochromatic Banding of Metaphase Chromosomes Using Nuclear Yellow

The bis-benzimidazole compound nuclear yellow (NY) belongs to the same chemical family as the DNA binding fluorochromes Hoechst 33258 and Hoechst 33342. Spectroscopic studies of NY alone and in the presence of calf thymus DNA show high DNA binding affinity and behavior similar to the Hoechst fluorochromes above. Mitotic metaphase chromosomes from Balb/c mice stained with NY show C-banding and weak G/Q-banding, both of them disappearing after distamycin A (DA) or methyl green (MG) counterstaining. The same staining of human metaphase chromosomes from lymphocyte cultures, however, reveal only faint G/Q-banding (NY) and a characteristic DA-DAPI-like banding (NY-DA, NY-MG). Image analysis of NY stained human chromosomes, confirms that NY is suitable for studying polymorphisms affecting size in the pericentromeric hete-rochromatin of pairs 1, 9 and 16, and shows significant enhancement of NY fluorescence induced by DA in DA-DAPI heterochromatin. Our spectroscopic and cytological results show that NY, either alone or counterstained with DA or MG, can be used for DNA cytochemistry and chromosome banding. Possible mechanisms for the banding patterns induced by NY are discussed.     

Specific Heterochromatic Banding of Metaphase Chromosomes Using Nuclear Yellow

The bis-benzimidazole compound nuclear yellow (NY) belongs to the same chemical family as the DNA binding fluorochromes Hoechst 33258 and Hoechst 33342. Spectroscopic studies of NY alone and in the presence of calf thymus DNA show high DNA binding affinity and behavior similar to the Hoechst fluorochromes above. Mitotic metaphase chromosomes from Balb/c mice stained with NY show C-banding and weak G/Q-banding, both of them disappearing after distamycin A (DA) or methyl green (MG) counterstaining. The same staining of human metaphase chromosomes from lymphocyte cultures, however, reveal only faint G/Q-banding (NY) and a characteristic DA-DAPI-like banding (NY-DA, NY-MG). Image analysis of NY stained human chromosomes, confirms that NY is suitable for studying polymorphisms affecting size in the pericentromeric hete-rochromatin of pairs 1, 9 and 16, and shows significant enhancement of NY fluorescence induced by DA in DA-DAPI heterochromatin. Our spectroscopic and cytological results show that NY, either alone or counterstained with DA or MG, can be used for DNA cytochemistry and chromosome banding. Possible mechanisms for the banding patterns induced by NY are discussed.     

Application of laser scanning cytometry to the analysis of chromosomal aberrations induced by benzo[a]pyrene in CHO-WBLT cells

BACKGROUND: A recently developed laser scanning cytometry technique was applied to cytometric studies to detect rapidly stable chromosomal aberrations induced by a carcinogen in a Chinese hamster fibroblast cell line, CHO-WBLT. METHODS: Individual chromosomes were collected from metaphase cells by a syringe technique and spread on slides. The DNA content of each chromosome stained with propidium iodide was measured with a laser scanning cytometer (LSC). A characteristic DNA histogram, designated as the "laser scanning karyotype (LSK)," was obtained from about 20,000 chromosomes of CHO-WBLT cells. Each chromosome was confirmed morphologically under the microscope by using a "re-location" system built into the LSC. RESULTS: A total of 21 chromosomes, including marker chromosomes specific to the cell line, were assigned to 10 major peaks in the LSK, which was analogous to the karyotype demonstrated with the classical Q-banding technique. In contrast, clonal sublines isolated after exposure to the carcinogen benzo[a]pyrene showed LSKs different from those found in untreated control cells, and seven of 20 clones were found to be abnormal, with a small number of chromosomal translocations and/or deletions, which were confirmed by Q-banding. CONCLUSIONS: The laser scanning cytometry technique was employed to detect stable chromosomal aberrations in CHO-WBLT cells after treatment with benzo[a]pyrene. The results obtained with this technique were comparable to those obtained by Q-banding; therefore, this method may be useful for rapid primary screening to detect stable, abnormal karyotypes induced by environmental chemicals and/or radiation.     

Q- and C-bands in the metaphase chromosomes of Drosophila nasutoides

The large heterochromatic chromosome of Drosophila nasutoides reveals distinctive C- and Q-bands. The regions which are negative in C-banding appear positive in Q-banding. The isochromosomic nature of this chromosome and the locality of the satellite DNAs in this chromosome are discussed with respect to these banding patterns.     

Simultaneous observation of quinacrine bands and silver grains on radiolabeled metaphase chromosomes

A procedure is described for quinacrine banding of radiolabeled metaphase chromosomes for autoradiography. The chromosomes can be labeled either in vivo or by in situ hybridization. The banding procedure involves treating the slides with RNase and formamide and staining in quinacrine. The slides are then processed for autoradiography. After development of the photoemulsion, the chromosomes can be karyotyped with UV light by their fluorescent banding patterns and the silver grains overlaying the chromosomes can be demonstrated by the addition of tungsten light. It is possible by careful manipulation of the visible light to simultaneously observe both fluorescent bands and silver grains. This technique should significantly increase the accuracy of chromosome identification after autoradiography and decrease the time and effort required for such analysis.     

Clearly differentiated and stable chromosome bands produced by a spermine bis-acridine, a bifunctional intercalating analogue of quinacrine

Characteristic fluorescent banding patterns on human metaphase chromosomes are produced by treating chromosome preparations directly with a spermine bis-acridine fluorochrome (CMA)₂S. The clearly differentiated bands are similar to those produced by quinacrine (Q-banding), but show enhanced definition between bright and dull regions as compared with the banding patterns obtained by the quinacrine technique. In addition, the bands on chromosomes produced by (CMA)₂S show insignificant fluorescence fading over extended periods of excitation. Solution interactions between DNA and (CMA)₂S showed a greater fluorescence differential between fluorescence enhancement by the alternating polymers poly d(A-T) · poly d(A-T) and fluorescence quenching by the polynucleotide poly d(G-C) · poly d(G-C) for this fluorochrome than was observed for quinacrine. The increased definition in Q-type bands produced by the spermine bis-intercalating derivative and the lack of fluorescence fading make this fluorochrome an excellent one for routine clinical cytogenetic analysis.     

C- and Q-chromatin of the experimentally condensed human interphase chromosomes]

Condensed interphase chromosomes of the cultured human lymphocytes obtained by the fusion of interphase and metaphase cells were studied using C- and Q-bands techniques. The appearance and localization of the constitutive heterochromatin blocks on condensed chromosomes at G1-period were the same as on the metaphase ones. These characters were used for a group and individual identification of some chromosomes condensed at G1-period and for a study of the association of the constitutive heterochromatin blocks in the interphase nuclei. The fluorescent analysis of the chromosomes condensed at G1-period detected some bright fluorescent blocks of the constitutive heterochromatin.     

Chromosome regions containing DNAs of known base composition,specifically evidenced by 2,7-di-t-butyl proflavine

After staining by a new proflavine derivative (2,7-di-t-butyl proflavine, DBP), which specifically binds to the A-T base pairs of DNA by an external process, the constrictions of the human chromosomes 1, 16 and to a lesser extent 9 and the centromeric regions of the chromosomes (except the Y) of Mus musculus are brightly fluorescent. These chromosome regions are known to contain repetitive DNAs rich in A-T. On the contrary, the centromeric regions of the autosomes of Bos taurus, which contain a G-C rich DNA, are faintly fluorescent. The arms of the chromosomes of the three species display a banding similar to, but fainter than, the Q-banding. These results are discussed in correlation with physico-chemical studies on the binding and fluorescence processes of the dye bound to DNA and to nucleohistone. The staining properties of DBP are compared to those of quinacrine, quinacrine mustard and proflavine, three intercalative dyes which are also supposed to reveal the A-T base pairs along the chromosomes, but are faintly fluorescent on the human and murine A-T rich regions. This comparison leads us to discuss the mechanisms responsible for the chromosomal banding in relation to DNA base composition and repetitiveness, protein distribution and packing of the chromatin fibers, along the chromosomes.     

Traitements discontinus par le BrdU et coloration par l'acridine orange: obtention de marquages R,Q et intermëdiaires

Discontinued treatments with BudR at different periods of the cellular cycle produce various chromosome banding after staining with acridine orange. In particular, it is possible to observe R- or Q- or an intermediary banding, simply by varying the time of incorporation of BudR. This implies that the amount of AT or GC bases present locally in DNA is not directly responsible for the banding observed. Furthermore it appears that a precise correlation exists between replication and R- or Q-banding: the DNA located at each group of bands replicates either early (R-bands) or late (Q-bands). But these timings overlap towards the middle of phase S: if the treatment is given at that time, it is possible to observe aspects intermediary between Q and R.     

Detection of structural chromosome aberrations in immunophenotyped mitoses.

The recently developed MAC (morphology-antibody-chromosome) method allows simultaneous immunophenotype and karyotype analysis in the same cell. To date, application of this new method has been hampered by the poor quality of chromosome banding. In this paper, we describe a modified simultaneous immunofluorescence and Q-banding technique, as well as a new combination of immunohistochemical and fluorescent R-banding methods. By further modifying the MAC method, we were able not only to achieve unequivocal results with weakly expressed antigens but also to improve the quality of the banding techniques, so that even structural chromosome abnormalities were well defined.     

Fluorescence Banding in Several Species of Plant

Chromosomal fluorescence banding in Haynaldia villosa (2n=14),Zea mays (2n=20) and Secale cereale (2n=14) have been studied. Stained with Hoe-chst 33258, all three species show chromosomal banding clearly and brightly, but withquinacrine. 2HCl only the staining of H. villosa chromosomes are satisfactory. While thequinacrine fluorescence banding of maize and Secale is not clearer and quench morequickly. The positions of the Ho-banding are basically identical with the Q-banding. A comparison has been made between the fluorescence banding and the C-banding in great detail. The results show that the two barding patterns are about the same, but there are also some differences ,between them. We have also discussed the reason of the similarities and the differences between Ho-banding, Q-banding and C-banding in chromosomes of same species.     

Location of the mouse complement factor H gene (cfh) by FISH analysis and replication R-banding.

A technique for replication R- and G-banding of mouse lymphocyte chromosomes was developed, and the replication R-banding pattern was analyzed. Optimal banding patterns were obtained with thymidine- and BrdU-treatment of lymphocytes in the same cell cycle. This produced replication R-band patterns that were the complete reverse of the G-band patterns on all chromosomes. Replication R-banding methods can be used in conjunction with nonisotopic, fluorescence in situ hybridization (FISH) to localize cloned probes to specific chromosomal bands on mouse chromosomes. with these methods the mouse complement factor H gene (cfh) was localized to the terminal portion of the F region of Chromosome 1. Q-banding patterns were also obtained by the replication R-banding method and may be useful for rapid identification of each chromosome.     

Evolution of differential chromosome banding]

Specific chromosome banding patterns in different eukaryotic taxons are reviewed. In all eukaryotes, chromosomes are composed of alternating bands, each differing from the adjacent material by the molecular composition and structural characteristics. In minute chromosomes of fungi and Protozoa, these bands are represented by kinetochores (Kt- (Cd-)bands), nucleolus organizers (N-bands), and telomeres as well as the euchromatin. In genomes of most fungi and protists, long clusters of tandem repeats and, consequently, C-bands were not revealed but they are likely to be found out in species with chromosomes visible under a light microscope, which are several tens of million bp in size. Chromosomes of Metazoa are usually larger. Even in Cnidaria, they contain C-bands, which are replicated late in the S phase. In Deuterostomia, chromosome euchromatin regions differ by replication time: bands replicating at the first half of the S phase alternate with bands replicating at the second half of the S phase. Longitudinal differentiation in the replication pattern of euchromatic regions is observed in all classes of Vertebrata beginning with the bony fish although the time when it developed in Deuterostomia is unknown. Apparently, the evolution of early and late replicating subdomains in Vertebrata euchromatin promoted fast accumulation of differences in the molecular composition of nucleoproteid complexes characteristic of early and late replicating bands. As a result, the more contrasting G/R and Q-banding patterns of chromosomes developed especially in Eutheria. The evolution of Protostomia and Plantae followed another path. An increase in chromosome size was not accompanied by the appearance of wide RBE and RBL euchromatin bands. The G/R-like banding within the interstitial chromosome regions observed in some representatives of Invertebrates and higher plants arose independently in different phylogenetic lineages. This banding pattern seems to be closer to that of C-banding than to the typical G/R-banding of the mammalian chromosomes.     

The distribution of quinacrine on chromosomes as determined by X-ray microanalysis

The distribution of quinacrine in relation to Q-banding on CHO chromosomes has been investigated using X-ray microanalysis. Technical problems involved in this type of experiment were studied in detail. It was necessary to use a solution of quinacrine acetate in acetic acid to ensure that the only chlorine detectable in quinacrine-stained chromosomes was in the quinacrine molecule. Electron irradiation during analysis rapidly destroys quinacrine fluorescence, but the chlorine is not lost from the chromosomes, and there are several reasons for supposing that a reliable distribution of quinacrine on the chromosome can be obtained by the method. — Small variations along the chromosome in the amounts of chlorine (representing quinacrine) and of phosphorus (mainly DNA) occur. The distribution patterns for chlorine and phosphorus show a good resemblance to each other for each homologous chromosome; quinacrine fluorescence patterns (Q-bands) do not resemble chlorine distribution patterns, however. The results of this study therefore support the view that Q-bands result from the differential quenching of fluorescence along chromosomes to which the quinacrine is essentially uniformly bound, and do not reflect differential binding of quinacrine along the chromosome.With an Appendix by A. D. Carothers and D. Rutovitz     

Rapid identification of chromosomes carrying silver-stained nucleolus-organizing regions

Summary The use of a combination of transmitted light and epiluminescence after silver and fluorescent staining of chromosome preparations makes it possible to achieve simultaneous visualization of silver-stained NORs and fluorescent chromosomes. This technique permits exact localization of silver precipitates on normal and BrdU-substituted chromosomes. After previous silver impregnation, fluorescent staining by actinomycin-daunomycin-DAPI was used to induce a banding pattern that enables identification of specific chromosomes while observing silver-stained NORs at the same time. Application of this method to Down's syndrome patient revealed a 21/21 Robertsonian translocation with NORs eliminated.     

小熊猫染色体异染色质的显示

以培养的小熊猫外周淋巴细胞为实验材料,结合Ｃ－显带技术及ＣＭＡ３／ＤＡ／ＤＡＰＩ三竽荧光杂色的方法,对小熊猫的染色体组型、Ｃ－带带型及ＣＭＡ３／ＤＡ／ＤＡＰＩ荧光带带型进行了研究,发现：（１）经Ｃ－显带技术处理,可在小熊猫染色体上呈现出一种极为独特的Ｃ－带带型。在多数染色体上可见到丰富的插入Ｃ－带及端粒Ｃ－带。而着丝区仅显示弱阳性Ｃ－带;（２）除着丝粒区外,ＣＭＡ３诱导的大多数强荧光带纹与Ｃ－阳性