QFH banding and DNA distribution in the macrochromosomes of the chicken Gallus domesticus

Chromosomes of Gallus domesticus were stained with rivanolum-SO2 (fluorescence Feulgen reaction) and by Hoechst 33258. Fluorescence photography was performed on a 35 mm film KN-3(KN-3) "Svema". The negatives were analyzed with the microdensitometer. The Feulgen (Fr--) and the Hoechst 3358 (H--) densitometric profiles of chromosomes showed light and dark segments along the metaphase chromosomes. The amount of DNA, as determined by the fluorescence Feulgen reaction, is not constant along the chromosome arms. Consequently, the base composition is not the only factor influencing the fluorescence of Hoechst 33258 along the chromosomes. The comparative analysis of densitometric profiles of the Hoechst 33258 and rivanolum-SO2 stained chromosomes shows that the Iq telomere band consists of GC-rich DNA (about 70% GC). The variation of DNA contents along the metaphase chromosome arms can be realized at both chromoneme and/or subchromoneme levels.     

A comparison of the effect of 5-bromodeoxyuridine substitution on 33258 Hoechst- and DAPI-fluorescence of isolated chromosomes by bivariate flow karyotyping

Application of the fluorescent DNA-intercalator propidium iodide for stabilization of the mitotic chromosome structure during isolation of chromosomes from V79 Chinese hamster cells and subsequent staining with the fluorochromes 33258 Hoechst or DAPI allowed bivariate flow karyotyping of isolated chromosomes. Fluorescence of 33258 Hoechst bound to isolated chromosomes containing 5-bromodeoxyuridine (BrdUrd) was quenched in comparison with the fluorescence of control chromosomes. Despite structural relationship and similarity of both absorption and fluorescence spectra of DAPI and 33258 Hoechst, reduction of fluorescence of DAPI-stained isolated chromosomes was not observed, by contrast with findings in conventional cytological metaphase preparations. It could be obtained, however, by preirradiation of the chromosomes with near-UV in the presence of DAPI. This led to a progressive destruction of the chromosomes. Destruction also occurred without BrdUrd, though at a slower rate. Preirradiation of chromosomes in the presence of 33258 Hoechst hardly affected the integrity of the chromosomes. Preirradiation of a 33258 Hoechst solution and its subsequent use as a stain resulted in a considerably decreased fluorescence of chromosomes. For DAPI this effect was small. Thus, whereas 33258 Hoechst itself is much more sensitive to near-UV irradiation than DAPI, DAPI bound to DNA in chromosomes renders the DNA much more sensitive to irradiation than 33258 Hoechst bound to DNA. Presumably, these differences can at least partly be reduced to the different molecular sizes of the dyes.     

A comparison of the effect of 5-bromodeoxyuridine substitution on 33258 Hoechst- and DAPI-fluorescence of isolated chromosomes by bivariate flow karyotyping

Summary Application of the fluorescent DNA-intercalator propidium iodide for stabilization of the mitotic chromosome structure during isolation of chromosomes from V79 Chinese hamster cells and subsequent staining with the fluorochromes 33258 Hoechst or DAPI allowed bivariate flow karyotyping of isolated chromosomes. Fluorescence of 33258 Hoechst bound to isolated chromosomes containing 5-bromodeoxyuridine (BrdUrd) was quenched in comparison with the fluorescence of control chromosomes. Despite structural relationship and similarity of both absorption and fluorescence spectra of DAPI and 33258 Hoechst, reduction of fluorescence of DAPI-stained isolated chromosomes was not observed, by contrast with findings in conventional cytological metaphase preparations. It could be obtained, however, by preirradiation of the chromosomes with near-UV in the presence of DAPI. This led to a progressive destruction of the chromosomes. Destruction also occurred without BrdUrd, though at a slower rate. Preirradiation of chromosomes in the presence of 33258 Hoechst hardly affected the integrity of the chromosomes. Preirradiation of a 33258 Hoechst solution and its subsequent use as a stain resulted in a considerably decreased fluorescence of chromosomes. For DAPI this effect was small. Thus, whereas 33258 Hoechst itself is much more sensitive to near-U.V irradiation than DAPI, DAPI bound to DNA in chromosomes renders the DNA much more sensitive to irradiation than 33258 Hoechst bound to DNA. Presumably, these differences can at least partly be reduced to the different molecular sizes of the dyes.In honour of Prof. P. van Duijn     

鱼类染色体的荧光显带研究

应用GC碱基特异性荧光染料色霉素A,辅以AT减基特异性荧光染料Hoechst33258,DAPI或喹吖因对鲤鱼,鲫鱼,大鳞副泥鳅和的有丝分裂染色体及黄鳝的有丝分裂和减数分裂染色体进行了荧光显带研究,结果发现,色霉素A3可以特异性地显示鱼类有丝分裂及减数分裂各个时期核仁组织区NORS的存在,Hoechst33258,DAPI或喹吖因则使这些区域（NORs)淡染,大鳞副泥鳞的染色体NORs 分布位置具有性别,根据实验结果,对有关鱼类染色体的荧光染色研究及其应用进行了讨论。     

Fluorescence analysis of late DNA replication in human metaphase chromosomes.

Thymidine incorporated as a terminal pulse into chromosomes otherwise substituted with 5-bromodeoxyuridine can be detected by associated bright 33258 Hoechst fluorescence. The location of metaphase chromosome regions identified by this method as last to complete DNA synthesis is consistent with the results of autoradiographic analyses with tritiated thymidine. The very late-replicating regions correspond to a subset of those which appear as bands after chromosomes are stained by quinacrine or modified Giemsa techniques. The high resolution of the 33258 Hoechst fluorescence pattern within individual cells is especially useful for revealing variations in the order of terminal replication. Both homolog asynchrony and fluctuations in the distribution of bright 33258 Hoechst fluorescence within chromosomes from different cells are apparent and localized to individual bands. The results are consistent with the possibility that these bands constitute units of chromosome replication as well as structure.     

Use of DNA fluorochromes for studying meiosis in the woody species Thryptomene calycina.

The fluorescent DNA probes DAPI and Hoechst 33258 produce superior images to the traditional acetocarmine stain of the small chromosomes of the woody shrub Thryptomene calycina at all stages of microsporocyte meiosis and microspore mitosis. Hoechst 33258 was slightly superior to DAPI because of reduced background fluorescence. Binding with the DNA-specific probes required a fixative containing chloroform to remove autofluorescent materials, a pretreatment with acetic acid and a pH of least 6 during treatment. The nucleoli did not fluoresce after treatment with DAPI or Hoechst 33258. Superior resolution of chromosomes after treatment with the fluorochromes enabled easy determination of the haploid number at metaphase I, metaphase II and at metaphase of the microspore mitosis.     

Use of DNA Fluorochromes for Studying Meiosis in the Woody Species Thryptomene Calycina

The fluorescent DNA probes DAPI and Hoechst 33258 produce superior images to the traditional acetocarmine stain of the small chromosomes of the woody shrub Thryptomene calycina at all stages of microsporocyte meiosis and microspore mitosis. Hoechst 33258 was slightly superior to DAPI because of reduced background fluorescence. Binding with the DNA-specific probes required a fixative containing chloroform to remove autofluorescent materials, a pretreatment with acetic acid and a pH of least 6 during treatment. The nucleoli did not fluoresce after treatment with DAPI or Hoechst 33258. Superior resolution of chromosomes after treatment with the fluorochromes enabled easy determination of the haploid number at metaphase I, metaphase II and at metaphase of the microspore mitosis.     

Mechanism of differential staining of BUdR-substituted Vicia faba chromosomes.

Chromosomes of the broad bean Vicia faba were isolated and air-dried on slides after incorporation of BUdR into DNA (BUdR substitution) for two rounds of replication. Then the preparations were embedded in a buffer solution containing trypsin as well as fluorescence dye (acridine orange or Hoechst 33258). We observed chromosomes with a fluorescence microscope at various times after embedding. After about 15 min one sister chromatid of some of the metaphase chromosomes showed enhanced darkening and disintegration within 1–4 min (melting effect) during observation. We suppose that fragmentation of BUdR-substituted DNA by the acridine orange-visible light system in acridine orange staining and by irradiation with wavelengths around the transition from UV to visible light in Hoechst 33258 staining is responsible for this phenomenon. The disintegration of one sister chromatid in BUdR-substituted chromosomes can also be produced by UV irradiation during trypsin treatment when fluorescence dyes are not present.     

Asymmetric decondensation of the L cell heterochromatin by Hoechst 33258

A benzimidazole derivative, Hoechst 33258 can induce decondensation of constitutive heterochromatin in the mouse derived L cell chromosomes when the compound is given in sufficiently high concentration (40 micrograms/ml) to the L cell culture. Hoechst 33258 at low concentration (1 micrograms/ml, 16 h) cannot produce this effect on L cell chromosomes. Bromodeoxyuridine (BUdR) incorporation for one cell cycle simultaneous with the Hoechst 33258 treatment at low concentration could decondense heterochromatin segments in metaphase chromosomes. The heterochromatin decondensation, however, was asymmetric; it was observed only on one chromatid and the other of a chromosome remained in condensed state. The observation of asymmetric decondensation of heterochromatin by Hoechst 33258 after BUdR incorporation for one cell cycle, the association of A-T rich satellite DNA to mouse heterochromatin, and available data on the specific binding of Hoechst 33258 to A-T base pairs of DNA and on the higher affinity of the compound to BUdR substituted DNA than to ordinary DNA implied that the binding of Hoechst 33258 molecules to A-T rich satellite DNA is the cause of heterochromatin decondensation.     

Identification of inverted duplicated #15 chromosomes using bivariate flow cytometric analysis

A dual laser FACS IV cell sorter has been used to obtain bivariate flow histograms of human metaphase chromosomes stained with the DNA-specific dyes, 33258 Hoechst and chromomycin A3. Approximately twenty distinct chromosomal fluorescence populations can be resolved using this double staining technique and the flow cytometer which has been modified only by the substitution of a specially designed air-spaced achromat for the standard focusing lens. Metaphase chromosomes from two different cell lines bearing inverted duplicated #15 autosomes have been subjected to bivariate chromosome analysis. In both cases, the inverted duplicated #15 chromosomes have been identified in the bivariate flow histogram. This identification was supported by experiments in which doubly stained chromosomes were counterstained with either netropsin or distamycin A, resulting in a relative increase in the 33258 Hoechst fluorescence intensity of the structurally abnormal #15 chromosomes, compared with the other chromosomes, as predicted by cytological studies. The possibility of identifying and separating small abnormal autosomes using commercially available instrumentation should facilitate the use of recombinant DNA techniques for the construction of libraries which are highly enriched for DNA sequences from limited autosomal subregions important in the study of chromosomal abnormalities such as deletions, translocations and inversion duplications.     

Pairs of fluorescent dyes as probes of DNA and chromosomes.

If two fluorescent dyes with different binding or fluorescence specificities are used simultaneously to stain DNA or chromosomes, the ratio of their fluorescent signals can provide information about base composition or base analogue substitution. Energy transfer between such dye pairs, possible if the fluorescence spectrum of one overlaps the absorption spectrum of the other, can modify observed fluorescence. Microfluorometric measurements were used to document the occurrence of energy transfer between quinacrine or 33258 Hoechst as energy donor and ethidium or 7-aminoactinomycin D as acceptor when used jointly to stain cytologic preparations of human metaphase chromosomes. Use of 7-aminoactinomycin D, a dye with G-C binding specificity, as energy acceptor permitted the identification of human chromosome regions presumptively enriched for clusters of A-T base pairs, based on the resistance of A-T specific fluorescence, from quinacrine or 33258 Hoechst, to energy transfer dependent quenching. The results provide information about basic structural features of metaphase chromosomes, and the associated methodology may prove useful in accentuating specific fluorescent polymorphic chromosome regions.     

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.     

Chromosome condensation and Hoechst 33258 fluorescence in meiotic chromosomes of the grasshopper Spathosternum prasiniferum (Walker)

Patterns of Hoechst 33258 fluorescence have been studied in grasshopper chromosomes. At metaphase of mitotic as well as meiotic divisions — when chromosomes were maximally compact — all the chromosomes fluoresced brightly but no differentially fluorescing regions were detected. However, when all the chromosomes, except the X, were highly extended at pachytene and diplotene stages a distinct differential fluorescence was observed: only the centromeres of the autosomal bivalents fluoresced brightly whereas the entire X univalent showed bright fluorescence. Restriction of differentially bright fluorescence to the more condensed regions of chromosomes suggests a modulatory role for chromosome condensation in the production of Hoechst fluorescence. This suggestion was further strengthened by the substantial quenching of fluorescence caused by removal of chromosomal proteins following treatment with H₂SO₄. Similarly, post-C-band-treatment staining with Hoechst also led to quenching, though now the centromeres of the chromosomes, including the X, retained their differential fluorescence. It is proposed, therefore, that in grasshopper chromosomes, H-fluorescence is modulated by chromosome condensation brought about by differential ratios of DNA/protein at different chromosome regions and at different division stages.     

High resolution chromosome analysis: one and two parameter flow cytometry

Isolated mammalian chromosomes have been quantitatively classified by high resolution flow cytometry. Chinese hamster chromosomes stained with 33258 Hoechst and excited in the UV showed a fluorescence distribution in which the 14 types of Chinese hamster chromosomes were resolved into 16 groups seen as distinct peaks in the distributions. Chinese hamster chromosomes were also stained with both 33258 Hoechst (HO) and chromomycin A3 (CA3); the two dye contents were measured by selective excitation in the UV and at 458 nm in a dual beam flow cytometer. The resulting two parameter distribution (HO versus CA3) showed 10 chromosome groups¹. Human strain LLL 761 chromosomes stained with HO and excited in the UV showed a fluorescence distribution in which the 23 types of human chromosomes were resolved into 12 groups. Human chromosomes stained with both HO and CA3 and measured in the dual beam flow cytometer produced two parameter fluorescence distributions which showed 20 groups. The chromosomes associated with each group were determined by quinacrine banding analysis of sorted chromosomes and by DNA cytophotometry of preidentified metaphase chromosomes. The relative HO and CA3 stain content and frequency of occurrence of chromosomes in each group were determined from the fluorescence distributions and compared to the results from DNA cytophotometry. The chromosome to chromosome variations in HO and CA3 staining are attributed to variations in chromosomal base composition.     

Molecular basis of chromosome banding

The effects of mouse satellite, main band and total DNA on the fluorescence intensity of quinacrine and of the bibenzimidazole derivative Hoechst 33258 were tested in solution. No significant differences were noticed between the double-stranded DNAs in spite of the 5% difference in AT-content between satellite and main band DNA. Single-stranded DNAs enhanced the fluorescence intensity of Hoechst 33258 far less than double-stranded DNAs. Having been denaturated and then reassociated the DNA fractions were intermediate in their enhancing effects on the fluorescence intensity of Hoechst 33258, the differences presumably being due to different degrees of reassociation. The effect of denatured and subsequently reassociated satellite DNA on the fluorescence intensity of quinacrine was similar to that of the native DNAs. Main band and total DNA quenched the fluorescence intensity of quinacrine more after denaturation-reassociation than it did when native. In the discussion the results are related to known cytological data.     

The use of base pair specific DNA binding agents as affinity labels for the study of mammalian chromosomes

The fluorochromes Hoechst 33258 and olivomycin are base pair specific DNA binding agents. The fluorescence enhancement of Hoechst 33258 and olivomycin in the presence of DNA can be directly related to the A-T and G-C content of the interacting DNA respectively. Cytological observations of metaphase chromosomes treated with these two compounds suggest that the fluorescent banding patterns produced are the reverse of one another. —Non-fluorescent base pair specific DNA binding agents have been used as counterstains in chromosome preparations to enhance the contrast of the banding patterns produced by the base specific fluorochromes. The non-fluorescent G-C specific antibiotic actinomycin-D enhanced the resolution of fluorescent bands produced by the A-T specific fluorochrome Hoechst 33258. Similarly the non-fluorescent A-T specific antibiotic netropsin was found to enhance resolution of the bands produced by the G-C specific fluorochrome olivomycin. Netropsin was also found to increase the differential fluorescent enhancement of complexes of olivomycin with DNAs of various base composition in solution. These findings suggest that counterstaining agents act through a base sequence dependent inhibition of subsequent binding by base pair specific fluorochromes.—The base specific DNA binding agents have been used to differentiate different types of constitutive heterochromatin in mammalian species, and to facilitate chromosome identification in somatic cell hybrids.     

Use of fluorescent sequence-specific polyamides to discriminate human chromosomes by microscopy and flow cytometry

In this paper, we demonstrate the use of synthetic polyamide probes to fluorescently label heterochromatic regions on human chromosomes for discrimination in cytogenetic preparations and by flow cytometry. Polyamides bind to the minor groove of DNA in a sequence-specific manner. Unlike conventional sequence-specific DNA or RNA probes, polyamides can recognize their target sequence without the need to subject chromosomes to harsh denaturing conditions. For this study, we designed and synthesized a polyamide to target the TTCCA-motif repeated in the heterochromatic regions of chromosome 9, Y and 1. We demonstrate that the fluorescently labeled polyamide binds to its target sequence in both conventional cytogenetic preparations of metaphase chromosomes and suspended chromosomes without denaturation. Chromosomes 9 and Y can be discriminated and purified by flow sorting on the basis of polyamide binding and Hoechst 33258 staining. We generate chromosome 9- and Y-specific ‘paints’ from the sorted fractions. We demonstrate the utility of this technology by characterizing the sequence of an olfactory receptor gene that is duplicated on multiple chromosomes. By separating chromosome 9 from chromosomes 10–12 on the basis of polyamide fluorescence, we determine and differentiate the haplotypes of the highly similar copies of this gene on chromosomes 9 and 11.     

In situ factors affecting stability of the DNA helix in interphase nuclei and metaphase chromosomes

The data from earlier cytochemical studies, in which the metachromatic fluorochrome acridine orange (AO) was used to differentially stain single vs double-stranded DNA, suggested that DNA in situ in intact metaphase chromosomes or in condensed chromatin of G0 cells is more sensitive to denaturation, induced by heat or acid, than DNA in decondensed chromatin of interphase nuclei. Present studies show that, indeed, DNA in permeabilized metaphase cells, in contrast to cells in interphase, when exposed to buffers of low pH (1.5-2.8) becomes digestible with the single-strand-specific S1 or mung bean nucleases. A variety of extraction procedures and enzymatic treatments provided evidence that the presence of histones, HMG proteins, and S-S bonds in chromatin, as well as phosphorylation or poly(ADP)ribosylation of chromatin proteins, can be excluded as a factor responsible for the differential sensitivity of metaphase vs interphase DNA to denaturation. Cell treatment with NaCl at a concentration of 1.2 N and above abolished the difference between interphase and mitotic cells, rendering DNA in mitotic cells less sensitive to denaturation; such treatment also resulted in decondensation of chromatin visible by microscopy. The present data indicate that structural proteins extractable with greater than or equal to 1.2 N NaCl may be involved in anchoring DNA to the nuclear matrix or chromosome scaffold and may be responsible for maintaining a high degree of chromatin compaction in situ, such as that observed in metaphase chromosomes or in G0 cells. Following dissociation of histones, the high spatial density of the charged DNA polymer may induce topological strain on the double helix, thus decreasing its local stability; this can be detected by metachromatic staining of DNA with AO or digestion with single-strand-specific nucleases.     

Different effects of 33258 Hoechst and DAPI in fluorescent staining of sister chromatids differentially substituted with bromodeoxyuridine

Summary After substitution with 5-bromodeoxyuridine (BrdUrd) for two rounds of replication, chromosomes in cytological preparations stained with 33258 Hoechst show upon epiluminescence an immediate differential sister chromatid fluorescence. When stained with DAPI, however, which has a structural resemblance to part of the 33258 Hoechst molecule, such a differential pattern of fluorescence was only induced after some delay. Upon restaining with the same dye the differential fluorescence appeared instantly. In preparations double stained with ethidium bromide and 33258 Hoechst the induction of a differential staining of sister chromatids with 33258 Hoechst was not accompanied by a differential staining with ethidium bromide. Once a differential staining was obtained with DAPI in preparations double stained with ethidium bromide and DAPI, the ethidium bromide pattern also appeared to be differential upon subsequent observation. No differentiation could be obtained with ethidium bromide alone. The observations described in the case of 33258 Hoechst staining are in agreement with a molecular quenching by BrdUrd without gross structural consequences for the DNA. In the case of DAPI staining, however, there occurs a differential photolysis of BrdUrd-substituted DNA. Besides the nature, most likely the size, of the fluorochrome molecules themselves, the state of the fixed chromatin appeared also to play a role in determining the mechanism of the sister chromatid differentiation: after prolonged incubation in buffer, BrdUrd-containing chromosomes stained with 33258 Hoechst showed a differential staining evidently caused by photolysis, indicating that they had become more susceptible to light.