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     

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

The distribution of quinacrine and protein sulphur has been compared with that of DNA in euchromatic and heterochromatic regions of mouse chromosomes stained with the fluorescent dye quinacrine, using X-ray microanalysis. Heterochromatin tends to bind relatively more quinacrine than euchromatin, and contains a greater concentration of sulphur. Measurements of quinacrine fluorescence, when compared with quinacrine binding, show that the excitation of fluorescence is more efficient when the dye is bound to euchromatin than when it is bound to heterochromatin. Although this observation is consistent with the hypothesis that the dull quinacrine fluorescence of mouse centromeres is due to quenching by guanine residues, two other factors should also be considered: the lower absolute amount of dye bound to the centromeres, and a concentration-dependent quenching of fluorescence.     

Optical studies of complexes of quinacrine with DNA and chromatin: implications for the fluorescence of cytological chromosome preparations

The fluorescence and circular dichroism of quinacrine complexed with nucleic acids and chromatin were measured to estimate the relative magnitudes of factors influencing the fluorescence banding patterns of chromosomes stained with quinacrine or quinacrine mustard. DNA base composition can influence quinacrine fluorescence in at least two ways. The major effect, evident at low ratios of quinacrine to DNA, is a quenching of dye fluorescence, correlating with G-C composition. This may occur largely prior to relaxation of excited dye molecules. At higher dye/DNA saturations, which might exist in cytological chromosome preparations stained with high concentrations of quinacrine, energy transfer between dye molecules converts dyes bound near G-C base pairs into energy sinks. In contrast to its influence on quinacrine fluorescence, DNA base composition has very little effect on either quinacrine binding affinity or the circular dichroism of bound quinacrine molecules. The synthetic polynucleotides poly(dA-dT) and poly(dA)-poly(dT) have a similar effect on quinacrine fluorescence, but differ markedly in their affinity for quinacrine and in the circular dichroism changes associated with quinacrine binding. Quinacrine fluorescence intensity and lifetime are slightly less when bound to calf thymus chromatin than when bound to calf thymus DNA, and minor differences in circular dichroism between these complexes are observed. Chromosomal proteins probably affect the fluorescence of chromosomes stained with quinacrine, although this effect appears to be much less than that due to variations in DNA base composition. The fluorescence of cytological chromosome preparations may also be influenced by fixation effects and macroscopic variations in chromosome coiling.     

Staining of human metaphase chromosomes with fluorescent conjugates of polylysine

The interaction of polylysine and partially substituted dansyl, fluorescein, and quinacrine conjugates of polylysine with cytological preparations of human metaphase chromosomes has been studied by fluorescence microscopy. The fluorescence intensity along chromosomes stained with the dansyl and fluorescein conjugates exhibits little variation, suggesting that regions capable of binding these polycations are nearly evenly distributed. In contrast, the quinacrine derivatives of polylysine stain the chromosomes in a banded fluorescence pattern resembling that observed following quinacrine or quinacrine mustard treatment.     

Quantitative analysis of fluorescence profiles of chromosomes : Influence of DNA base composition on banding

Chromosome banding has been analysed in terms of DNA content and base composition distribution along five human chromosomes. Three intercalative dyes (quinacrine, proflavine and ethidium bromide) whose fluorescence quantum yield in the presence of DNAs of different base compositions has been determined, have been used to examine the influence of base composition on the chromosome patterns. Considering that the amount of DNA as determined by the Feulgen reaction is almost constant along the chromosome arms and assuming that base composition is the only factor influencing the fluorescence of these dyes, a distribution of the A-T base pair content along the chromosomes has been calculated from the fluorescence intensity profiles. From the ratio of the intensity profiles obtained with quinacrine and proflavine, patterns showing the variation of the DNA content and of the A-T base pair content could also be obtained independently. The validity of these different approaches is discussed.     

Mechanisms of quinacrine binding and fluorescence in nuclei and chromosomes

The mechanisms has been investigated whereby quinacrine binds to the DNA of nuclei and chromosomes in cytological preparations fixed in methanol-acetic acid. A variety of evidence is consistent with the idea that the quinacrine binds by intercalation. This is supported by a high value for the affinity of quinacrine for DNA, together with a saturation value of 0.2 quinacrine molecules/nucleotide; binding in the presence of strong salt solutions; and inhibition of fluorescence and banding by denaturation or depurination of DNA. At high quinacrine concentrations, weak binding of quinacrine to nuclei and chromosomes also occurs, but this is not relevant to the production of strong fluorescence or Q-banding patterns. A number of factors were tested which might have affected quinacrine fluorescence and banding. These included: pH; blocking protein amino groups by acetylation or benzoylation; introduction of hydrophobic groups by benzoylation; and dephosphorylation. All these treatments were without effect. However, comparison of the quinacrine fluorescence of human and onion nuclei, which differ substantially in the base composition of their DNA, shows that quinacrine fluorescence can be enhanced in cytological preparations by AT-rich DNA.     

Mechanisms of quinacrine binding and fluorescence in nuclei and chromosomes

Summary The mechanism has been investigated whereby quinacrine binds to the DNA of nuclei and chromosomes in cytological preparations fixed in methanol-acetic acid. A variety of evidence is consistent with the idea that the quinacrine binds by intercalation. This is supported by a high value for the affinity of quinacrine for DNA, together with a saturation value of 0.2 quinacrine molecules/nucleotide; binding in the presence of strong salt solutions; and inhibition of fluorescence and banding by denaturation or depurination of DNA. At high quinacrine concentrations, weak binding of quinacrine to nuclei and chromosomes also occurs, but this is not relevant to the production of strong fluorescence or Q-banding patterns.A number of factors were tested which might have affected quinacrine fluorescence and banding. These included: pH; blocking protein amino groups by acetylation or benzoylation; introduction of hydrophobic groups by benzoylation; and dephosphorylation. All these treatments were without effect. However, comparison of the quinacrine fluorescence of human and onion nuclei, which differ substantially in the base composition of their DNa, shows that quinacrine fluorescence can be enhanced in cytological preparations by AT-rich DNA.In honour of Prof. P. van Duijn     

Differences in the quinacrine staining of the chromosomes of a pair of sibling species: Drosophila melanogaster and Drosophila simulans

The patterns of intense fluorescence after staining with quinacrine dihydrochloride were studied in both the polytene chromosomes and mitotic chromosomes of a pair of sibling species, Drosophila melanogaster and D. simulans. Consistent differences between the two species were found in the pattern of fluorescence of both polytene and mitotic chromosomes. In addition, it was discovered that our stock of D. melanogaster (Oregon-R) is polymorphic at one autosomal position for the property of intense fluorescence after quinacrine staining. On the basis of these findings, the usefulness of quinacrine staining in the study of the cytogenetic structure of evolutionarily interesting populations is discussed.     

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.     

Quinacrine fluorescence staining of chromosomes and its relationship to DNA base composition

The quinacrine banding patterns of chromosomes of Dipodomys ordii and Mus musculus are described. Satellite and mainband DNA fractions from D. ordii and M. musculus were tested for their ability to quench or enhance the fluorescence of quinacrine dihydrochloride in solution. The relationship between the base composition of a particular DNA fraction, its effect on the fluorescence of quinacrine in solution and its location in chromosomes relative to the quinacrine banding pattern is discussed.     

Spectral luminescence studies of cells stained with acrichine derivatives

Excitation and fluorescence spectra are given of quinacrine derivative solutions, of buccal epithelium cell nuclei, of peripheral blood cells, and of isolated chromosomes treated with propyl-quinacrine mustard. It is confirmed that the differential cell treatment with quinacrine derivates may be observed in aqueous solutions only. Data obtained allow us to give some recommendations for employment of optimal filters and dichroic beam-splitters in the fluorescence microscopy of chromosomes treated with quinacrine derivatives.     

The action of ionizing radiation on DNA in the presence of quinacrine

It is shown by UV absorption and absolute fluorescence spectroscopy of solutions containing both DNA and quinacrine that the components experience mutual radio-protection due to scavenging of water radicals. From measurements at different ionic strengths it is inferred that quinacrine bound to DNA is more efficiently protected than the free compound. Furthermore, release of bound quinacrine from DNA is observed at higher doses.     

Optical studies of the interaction of 4′-6-diamidino-2-phenylindole with DNA and metaphase chromosomes

The optical absorption and fluorescence characteristics of 4-6-diamidino-2-phenylindole (DAPI) with DNA and chromosomes were studied. There is a decrease in extinction coefficient and shift in the absorption spectra to a higher wavelength when the dye binds to DNA. The fluorescence of DAPI is enhanced by both A-T and G-C base-pairs. The enhancement by A-T rich is significantly greater than by G-C rich DNA. The dye produces a localized bright fluorescence in centromeric regions of mouse chromosomes and the constrictions of human chromosomes 1 and 16; these regions are known to contain A-T rich DNA and show dull fluorescence when treated with quinacrine. This dye may be useful for identifying A-T rich region in chromosomes. The fluorescence of DAPI bound to polynucleotides or chromosomes is partially quenched by the introduction of BrdU. This suppression of dye fluorescence allows optical detection of sister chromatid exchanges and chromosome region containing DNA with an unequal distribution of thymidine between polynucleotide chains after BrdU incorporation.     

Binding of quinacrine to the human Y chromosome

Human chromosome spreads were stained with 3H-quinacrine and their fluorescence observed. The exact location of specific spreads on each slide was noted and photographs taken. Autoradiographs were then prepared so that the quinacrine fluorescence of any specific chromosome could be compared directly with the distribution of grains over the same chromosome on the autoradiograph. The Y chromosome fluoresced much more intensely than any of the other chromosomes, but there were no more grains over the Y chromosome than over the other chromosomes. Therefore the enhanced fluorescence of the human Y chromosome is not due to an increased binding of quinacrine.     

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。     

Quinacrine: Spectroscopic properties and interactions with polynucleotides

The acridine dye quinacrine and its interactions with calf thymus DNA, poly(dA-dT) · poly (dA-dT), and poly (dG-dC) · poly(dG-dC) were studied by light absorption, linear dichroism, and fluorescence spectroscopy. The transition moments of quinacrine give rise to absorption bands polarized along the short axis (400–480-nm band), and the long axis (345-nm and 290-nm bands) of the molecule, respectively. Linear dichroism studies show that quinacrine intercalates into calf thymus DNA as well as into the polynucleotides, displaying fairly homogeneous binding to poly (dA-dT) · poly (dA-dT), but more than one type of intercalation site for calf thymus DNA and poly (dG-dC) · poly(dG-dC). Fluorescence spectroscopy shows that for free quinacrine the pK = 8.1 between the mono- and diprotonated states also remains unchanged in the excited state. Quinacrine bound to calf thymus DNA and polynucleotides exhibits light absorption typical for the intercalated diprotonated form. The fluorescence enhancement of quinacrine bound to poly (dA-dT) · poly(dA-dT) may be due to shielding from water interactions involving transient H-bond formation. The fluorescence quenching in poly(dG-dC) · poly(dG-dC) may be due to excited state electron transfer from guanine to quinacrine. © 1993 John Wiley & Sons, Inc.     

Energy-linked protonation of quinacrine in beef heart submitochondrial membranes.

1. The absorption spectrum of quinacrine in aqueous solution, in the visible region, changes with the pH of the medium in the pH range from 6.0 to 9.0 with an isosbestic point at 353 nm. This indicates that the monoprotonated (quinacrine - H+) and the diprotonated (quinacrine - 2H+) forms of quinacrine at equilibrium in this pH range have a 1 to 1 stoichiometry. 2. The monoprotonated and the dipronated forms to quinacrine exhibit similar fluorescence emission spectra, but distinctive fluorescence excitation spectra. 3. The relative fluorescence quantum yields of quinacrine in aqueous media of various pH values are estimated. The relative fluorescence quantum yield of quinacrine at pH 9.0 is more than 3 fold of that at pH 6.0. 4. The fluorescence excitation and emission spectra, as well as the relative fluorescence quantum yield of quinacrine associated with non-energized submitochondrial membranes, are similar to those of quinacrine alone. 5. Analyses of the absorption spectra, the fluorescence excitation spectra and the relative fluorescence quantum yield indicate that the energy-linked fluorescence decrease of quinacrine associated with the energized submitochondrial membranes results from the protonation of quinacrine - H+ to form quinacrine - 2H+. 6. Quantitative data are provided indicating that the maximal efficiency of protonation of quinacrine - H+ to form quinacrine - 2H+ depends on the concentration of H+ in the membranes generated through energy coupling, and the concentration of quinacrine - H+ initially present in the reaction medium. Under optimal conditions virtually complete conversion of quinacrine - H+ into quinacrine - 2H+ is observed. 7. The fluorescence intensity of quinacrine, either alone or associated with non-energized submitochondrial membranes, decreases with increasing temperature. When quinacrine is associated with the energized membranes, however, its fluorescence intensity increases slightly with increasing temperature. This unusual fluorescence behavior towards temperature, together with the fact that under optimal conditions virtually all the quinacrine molecules associated with the energized membranes are in the diprotonated form, further substantiate our earlier conclusion that the diprotonated quinacrine molecules are tightly bound to the energized membranes in a fashion which does not permit ready equilibration with the external medium.     

Fluorometric properties of the bibenzimidazole derivative hoechst 33258, a fluorescent probe specific for AT concentration in chromosomal DNA

A new fluorescent probe of chromosomal DNA structure in situ, the bibenzimidazole derivative Hoechst 33258, shows enhanced fluorescence with both AT- and GC-rich DNA; however, enhancement by AT-rich DNA is greater than enhancement with GC-rich DNA. When this compound is used as a probe, it produces localized fluorescence which can be correlated with AT concentration in specific chromosome regions. By the use of 33258, Hilwig and Gropp (1972) were able to demonstrate the relatively AT-rich DNA present in centric regions of mouse chromosomes; these regions do not fluoresce brightly when treated with quinacrine because of the presence of guanine residues which are spaced with high periodicity and which therefore efficiently quench quinacrine fluorescence. The data obtained in this study with DNA polymers of defined structure or composition, as test model compounds, suggest that 33258 is a useful cytochemical reagent for generally identifying all types of AT-rich regions in chromosomes, including those which are not demonstrable with quinacrine.     

Identification of human chromosomes by DNA-binding fluorescent agents

The distribution of DNA along metaphase chromosomes that are not excessively contracted can be visualized in the fluorescence microscope with the aid of fluorescent DNA-binding agents. Additional, characteristic details in the fluorescence patterns are obtained with fluorochromes that bind preferentially to certain chromosomal regions. The highly fluorescent alkylating agent quinacrine mustard (QM) effects discrete, fluorescent labeling of both plant and mammalian metaphase chromosomes, presumably by selective binding to guanine residues in DNA, and is also capable of intercalation in the DNA double helix. Chromosome regions fluorescing particularly strongly with QM have been demonstrated in human metaphase chromosomes 3, 13–15 and Y.A convenient measuring technique has been developed for the rapid and accurate recording of fluorescence patterns in human metaphase chromosomes. These photoelectric recordings of the fluorescence patterns contain far greater detail than can be seen by the human eye.The fluorescence patterns described are based on measurements of about 1,000 human metaphase chromosomes. This new technique of determining fluorescence patterns in human chromosomes should be particularly valuable for the identification of chromosomes 4–5 and the individual types in the 6–12 group. Individual, typical patterns also occur within the groups 13–15, 17–18, and 21–22.     

Characterization of Drosophila heterochromatin

A number of preliminary experiments have shown that the fluorescence pattern of Hoechst 33258, as opposed to that of quinacrine, varies with the concentration of dye. The metaphase chromosomes of D. melanogaster, D. simulans, D. virilis, D. texana, D. hydei and D. ezoana have therefore been stained with two concentrations of H 33258 (0.05 and 0.5 mug/ml in phosphate buffer at pH 7) and with a single concentration of quinacrine (0.5% in absolute alcohol). The three fluorescence patterns so obtained were shown to be somewhat different in some of the species and the coincide in others. All three stainings gave an excellent longitudinal differentiation of heterochromatin while euchromatin fluoresced homogeneously. Living ganglion cells of the six species mentioned above were treated with quinacrine and H 33258. Quinacrine induced a generalized lengthening and swelling of the chromosomes and H 33258 the decondensation of specific heterochromatic regions. A correlation of the base composition of the satellite DNAs contained in the heterochromatin of the species studied with the relative fluorescence and decondensation patterns showed that: 1) the extremely fluorochrome bright areas and those decondensed are present only in species containing AT rich satellite DNA; 2) the opposite is not true since some AT-rich satellite DNAs are neither fluorochrome bright nor decondensed; 3) there is no good correspondence between Hoechst bright areas and the decondensed ones. AT richness therefore appears to be a necessary but not sufficient condition both for bright fluorescence and decondensation. Some cytological evidence suggests that similarly AT rich satellite DNAs respond differently in fluorescence and decondensation because they are bound to different chromosomal proteins. A combination of the results of fluorescence and decondensation revealed at least 14 types of heterochromatin; 4-7 of which are simultaneously present in the same species. Since closely related species (i.e. D. melanogaster and D. simulans; D. virilis and D. texana) show marked differences in the heterochromatic types they contain, it can be suggested that within the genus Drosophila qualitative variations of heterochromatin have played an important role in speciation.