Giemsa banding,quinacrine fluorescence and DNA-replication in chromosomes of cattle (Bos taurus)

Almost all the 30 chromosome pairs of cattle can be identified by their banding patterns made be visible by a Giemsa staining technique described previously. The banding pattern of the X chromosome shows striking similarities with the banding pattern of the human X chromosome. — The centromeric region of the acrocentric autosomes contains a highly condensed DNA. This DNA is removed by the Giemsa staining procedure as can be shown by interference microscopic studies. If the chromosomes are stained with quinacrine dihydrochloride these centromeric regions are only slightly fluorescent. — Autoradiographic studies with ³H-thymidine show that the DNA at the centromeric regions starts and finishes its replication later than in the other parts of the chromosomes.     

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.     

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.     

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     

Karyotype analysis and heterochromatin differentiation with Giemsa C-banding and fluorescent counterstaining inCephalanthera (Orchidaceae)

Detailed studies of the chromosomes of the three Austrian species of the genusCephalanthera showed them all to have basically similar karyotypes. BothC. damasonium (2n = 36) andC. longifolia (2n = 32) have three large and several classes of smaller chromosome pairs. The karyotype ofC. rubra (2n = 44) is composed of four large and several groups of smaller pairs. The heterochromatin in these species amounts to about 10% of total karyotype length. All the chromosomes have Giemsa-positive centromeres, but only a few have intercalary or terminal bands. Using differential fluorescent staining with DAPI/actinomycin D, quinacrine/actinomycin D (both A-T specific), and chromomycin A₃/distamycin A (G-C specific) three different types of major heterochromatic bands can be characterized in respect of their satellite DNA composition: highly A-T rich, slightly A-T rich, and very G-C rich. The chromosomes ofC. longifolia contain more A-T rich C-bands than those ofC. damasonium, while the latter's have more G-C rich heterochromatin. In both species several C-bands appear as secondary constrictions or gaps in the Feulgen-stained chromosomes, but most likely, in each species there is only one pair of chromosomes where the secondary constrictions function as nucleolus organizing regions. No major intraspecific variation could be observed except on one small chromosome pair ofC. longifolia which had a heteromorphic C-band in most individuals. Possible pathways of karyotype evolution involving polyploidy and Robertsonian events are discussed.     

Counterstain-enhanced chromosome banding

Summary Chromosome staining, in which at least one member of a pair or triplet of DNA binding dyes is fluoescent whereas the others act as counterstain, is reviewed. Appropriately chosen combinations of fluorescent dyes and counterstains can be employed to enhance general chromosome banding patterns, or to induce specific regional banding patterns. Some pairs of dyes which exhibit complementary DNA binding specificity, A-T/G-C or G-C/A-T, provide enhanced definition of positive or reverse banding patterns. Dye combinations of the type A-T/A-T, that include two DNA stains with similar specificity but non-identical binding modes, produce a specific pattern of brightly fluorescnet heterochromatic regions (DA-DAPI bands). In man, the method highlights the C bands of chromosomes 1, 9, 15, 16, and the Y. Certain dye triplets of the type G-C/A-T/A-T, which include two spectroscopically separated fluorescent stains with reciprocal DNA base pair binding specificites and a non-fluorescent A-T binding counterstain, can be used to highlight selectively, in the appropriate wavelength ranges, either R bands or DA-DAPI bands.Applications of these techniques in human cytogenetics are described. The potential of the new methodology for detecting and analysing specific chromosome bands is demonstrated. The mechanisms responsible for contrast enhancement and pattern induction are reviewed and their implications for chromosome structure are discussed as they relate to the banding phenomenon and to the DNA composition of chromosomes.     

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.     

Immunological visualization of 5-methylcytosine-rich regions in Indian Muntjac metaphase chromosomes

Regions rich in 5-methylcytosine were localized in male metaphase chromosomes of the Indian muntjac deer (Muntiakus muntjak). Chromosomes were ultraviolet irradiated and subsequently photooxidized in the presence of methylene blue to induce maximum DNA denaturation. Following treatment with anti 5-methylcytosine antibody (anti 5-MeC), regions of antibody binding were visualized by an immunofluorescence or immunopreoxidase staining procedure. All chromosomes showed some level of antibody binding along their length and at centromeric regions, with intense binding evident in the centromere of chromosome 3 and the elongated centromeric "neck" of chromosome 3-X. The Y chromosome displayed low levels of antibody binding. The banding pattern observed with anti 5-MeC is the reverse of that obtained by quinacrine staining.     

A-T rich sequences in vertebrate DNA

Partially denatured DNAs from mouse, cow, and chicken were visualized in the electron microscope by the basic protein film technique and the size and distribution of the denatured regions characterized. A-T rich sequences visualized at 15% denaturation average about 1500 bases in length for all three species and are arranged quite non-randomly in the genome. This arrangement is such that 30–50% of the entire genome contains no A-T rich DNA, and another 20% is composed about one-half of A-T rich sequences and one-half of other sequences. Comparison with DNA denaturation profiles indicates that for each organism these sequences are from 25–35% G+C and that there is very little if any DNA more A-T rich than these. Estimates from published studies of fluorescence enhancement of quinacrine bound to A-T rich DNAs suggest that the observed non-random organization of A-T rich sequences is sufficient to account for Q banding of metaphase chromosomes.     

The organization of DNA in the mitotic and polytene chromosomes of Sciara coprophila

The organization of DNA in the mitotic metaphase and polytene chromosomes of the fungus gnat, Sciara coprophila, has been studied using base-specific DNA ligands, including anti-nucleoside antibodies. The DNA of metaphase and polytene chromosomes reacts with AT-specific probes (quinacrine, DAPI, Hoechst 33258 and anti-adenosine) and to a somewhat lesser extent with GC-specific probes (mithramycin, chromomycin A₃ and anticytidine). In virtually every band of the polytene chromosomes chromomycin A₃ fluorescence is almost totally quenched by counterstaining with the AT-specific ligand methyl green. This indicates that GC base pairs in most bands are closely interspersed with AT base pairs. The only exceptions are band IV-8A3 and the nucleolus organizer on the X. In contrast, quinacrine and DAPI fluorescence in every band is only slightly quenched by counterstaining with the GC-specific ligand actinomycin D. Thus, each band contains a moderate proportion of AT-rich DNA sequences with few interspersed GC base pairs. — The C-bands in mitotic and polytene chromosomes can be visualized by Giemsa staining after differential extraction of DNA and those in polytene chromosomes by the use of base-specific fluorochromes or antibodies without prior extraction of DNA. C-bands are located in the centromeric region of every chromosome, and the telomeric region of some. The C-bands in the polytene chromosomes contain AT-rich DNA sequences without closely interspered GC base pairs and lack relatively GC-rich sequences. However, one C-band in the centromeric region of chromosome IV contains relatively GC-rich sequences with closely interspersed AT base pairs. — C-bands make up less than 1% of polytene chromosomes compared to nearly 20% of mitotic metaphase chromosomes. The C-bands in polytene chromosomes are detectable with AT-specific or GC-specific probes while those in metaphase chromosomes are not. Thus, during polytenization there is selective replication of highly AT-rich and relatively GC-rich sequences and underreplication of the remainder of the DNA sequences in the constitutive heterochromatin.     

Binding of anti-nucleoside antibodies reveals different classes of DNA in the chromosomes of the kangaroo rat (Dipodomys ordii)

The binding of highly purified anti-nucleoside antibodies to fixed metaphase chromosomes of the kangaroo rat (Dipodomys ordii) revealed the presence of different classes of DNA in different regions of the chromosomes. To permit antibody binding, the chromosomal DNA was first made single-stranded by either ultraviolet irradiation, which denatures some classes of AT-rich DNA, or photo-oxidation, which denatures GC-rich DNA. The antibody binding patterns obtained matched the location of the different classes of satellite DNA in kangaroo rat chromosomes. After either denaturation method, anti-5-methylcytidine (anti-M) bound intensely only to the centromeric heterochromatic regions which are known to contain the GC rich, highly methylated HS-β satellite DNA of this species. The basic repeating unit of the HS-β sequence is 5′-ACACAGCGGG-3′ 3′-TGTGTCGCCC-5′ [4]. The binding of anti-M after UV irradiation is permitted by the production of pyrmidine (CC and TC) dimers in the right-hand portion of this repeating sequence, supporting the idea that the 5-methylcytosine residues are in this portion. After photo-oxidation, anti-cytidine (anti-C) and anti-adenosine (anti-A) also showed intense binding to the centromeric heterochromatin. In addition, these antibodies showed moderately intense binding to non-centromeric heterochromatic regions, which contain the relatively GC-rich HS-α and MS satellite DNAs. After UV irradiation, anti-A binding produced a banding pattern identical to the quinacrine (Q-band) pattern, with bright chromosome arms and very dull centromeric heterochromatic regions, while anti-C showed moderate binding in the centromeric regions and fairly even but weak binding elsewhere.The results have clarified the way in which anti-nucleoside antibodies react with chromosomal DNA. The reactivity of anti-A, anti-C and anti-M with the partially denatured HS-β satellite DNA supports the idea that antibody binding requires denaturation of a sequence perhaps no more than 5 base pairs long. In addition, it appears that it is not necessary to have more than one identical base in a row to permit antibody binding.     

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.     

Characterization of Drosophila heterochromatin

The C- and N-banding patterns of D. melanogaster, D. simulans, D. virilis, D. texana, D. ezoana and D. hydei were studied in comparison with quinacrine and Hoechst banding patterns. In all these Drosophila species the C bands correspond to the heterochromatin as revealed by the positive heteropycnosis in the prometaphase chromosomes. The N bands have the following characteristics: 1) they are always localized on the heterochromatin and generally do not correspond to the C bands; 2) they do not correspond to the nucleolar organizing regions; 3) they are inversely correlated with fluorescence, i.e., they correspond to regions which are scarcely, if at all, fluorescent after Hoechst 33258 or quinacrine staining; 4) they are localized both on regions containing AT rich satellite DNA and on those containing GC rich satellite DNA.     

A third common allele in the transferrin system,Tf C3 , detected by isoelectric focusing

Summary The fluorochrome Hoechst 33258 which binds preferentially to A-T base pairs, drastically inhibits the condensation of A-T-rich centromeric heterochromatin regions in mouse cell lines. The condensation of all other regions of these chromosomes is also inhibited to some extent. The human Y chromosome contains a large heterochromatic region, which is also rich in A-T base pairs. This chromosome is not affected by Hoechst 33258 in human leukocyte cell cultures. On the other hand, condensation of the multiple copies of human Y chromosome in the mouse-human cell hybrid RH-28Y-23 is inhibited and the chromosomes appear distorted in Hoechst 33258-treated cells.     

Differences in DNA composition along mammalian metaphase chromosomes

Denaturation of chromosomal DNA in situ can be achieved without disruption of chromosomal morphology by heating slides at 25–90° C in 10–95% formamide in SSC. The extent of denaturation is proportional to formamide concentration and temperature. Reassociation of denatured DNA is prevented with formaldehyde. — The DNA in the paracentromeric constrictions in human chromosomes 1, 9 and 16 denatures earlier than in any other regions, as shown by the red colour with acridine orange. When the temperature or formamide concentration is raised a red and green banding pattern emerges in which regions known to stain brightly with quinacrine mustard are red whereas other regions are green. The last regions to turn red are the short arms of some acrocentric chromosomes. Since A+T-rich DNA denatures before G+C-rich DNA, it is inferred that QM-bright areas are rich in A+T. Similar results are obtained with mouse and Microtus agrestis cells. — Reassociation of chromosomal DNA denatured by heat and formamide occurs if no formaldehyde is used. In human cells, kinetic studies on reassociation indicate that the highest degree of repetition is in the DNA of the distal half of the Y chromosome. Next in degree of repetition are the paracentromeric constrictions, the short arm regions of some of the acrocentric chromosomes, and all the centromeric regions. Highly repetitious DNA is found in all mouse centromeric regions except that of the Y chromosome. Constitutively heterochromatic segments of X and Y and the autosomal centromeric regions of Microtus agrestis also contain repetitious DNA. — It is proposed that differential base content and susceptibility to denaturation of DNA contribute to or at least accompany Q-, G- and R-banding. The degree of C-banding is related to repetitious DNA. The human Y chromosomal DNA is probably A+T-rich and exceptionally repetitious, exhibiting spontaneous reassociation under many experimental conditions.     

DIPI and DAPI: Fluorescence banding with only negligible fading

Summary DIPI and DAPI produce distinct fluorescent bands in human chromosomes similar to quinacrine banding patterns. Additionally, the AT rich secondary constrictions in the chromosomes Nos. 1, 9 and 16 are brightly fluorescent. On the other hand the brilliantly fluorescent regions after staining with quinacrine mustard in the chromosomes Nos. 3 and 4, satellites and some other regions in the acrocentric chromosomes are less striking. The distal part of the Y, however, is clearly discernible. Thus DIPI and DAPI seem to be strictly AT specific fluorochromes like Hoechst 33258.In interphase nuclei the Y chromosome can be identified. However, quinacrines are superior for Y-body analysis in buccal, hair cell and sperm smears.BrdU labeled chromatids show reduced fluorescence intensity. The difference, however, is less apparent than after staining with Hoechst 33 258.DAPI and especially DIPI are highly resistant to UV-irradiation; there is almost no fading within 30 min when using DIPI. Moreover, fluorescence intensity is stronger than in quinacrines. When photographing, exposure times may be reduced to about one quarter compared to quinacrine mustard.     

Specific fluorescent bands on chromosomes produced by acridine orange after prestaining with base specific non-fluorescent DNA ligands

Metaphase chromosomes stained with acridine orange exhibit uniform yellow-green fluorescence. Chromosome preparations treated with the non-fluorescent A-T specific antibiotic distamycin A prior to acridine orange staining exhibit longitudinal fluorescent banding patterns similar to those produced by a number of fluorescent R-band techniques. Similarly, chromosome preparations treated with the non-fluorescent G-C specific antibiotic actinomycin D followed by acridine orange staining exhibit Hoechst-type banding patterns. Interactions of various ligand-DNA combinations in solution indicate that the base pair specific antibiotics induce banding patterns by selectively altering acridine orange binding sites in chromosomal regions rich in the particular base pair for which the antibiotic exhibits specificity.     

Effect of Hoechst 33258 on Chinese hamster chromosomes

Cells of the Chinese hamster strain C-125 were treated for different time intervals with H 33258, a bibenzimidazole derivative. The same compound was used to stain fixed cells of the same strain. — H 33258 induced in cells in culture specific areas of reduced spiralization on the metaphase chromosomes of some cells. These probably correspond to DNA segments rich in A-T bases interspersed along the chromosomes. Probably H 33258 acts during S period of cell cycle. — The banding obtained by staining with H 33258 is similar to that induced by quinacrine dihydrochloride but shows a better resolution.     

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.     

The structural organization of mouse metaphase chromosomes

The binding of highly purified anti-nucleoside antibodies to mouse (Mus musculus) metaphase chromosomes was studied by an immunofluorescence technique. The chromosomal DNA was denatured by one of two selective denaturation procedures because these antibodies reacted with single stranded but not native DNA. After ultraviolet irradiation (UV), which produced single stranded regions primarily in AT rich DNA, the binding of antiadenosine (anti-A) produced a pattern of fluorescent bands similar to that produced by quinacrine (Q-bands). Additional foci of bright fluorescence were observed at the centrometric (C-band) regions, which are known to contain AT rich satellite DNA. After photooxidation, which produced single stranded regions in GC rich DNA, the binding of anti-A produced a fluorescent banding pattern similar to the R-banding pattern seen after thermal denaturation and staining with coriphosphine O. After photooxidation, R-band patterns were also obtained with anti-cytidine (anti-C) and anti-5-methylcytidine (anti-M). After either UV irradiation or photooxidation, anti-M, but not anti-C, showed intense binding to the C-band regions of mouse chromosomes. — These findings led to the following conclusions: (1) Antibody banding patterns reflect the presence of a class of AT rich, GC poor DNA in chromosome regions which show bright quinacrine fluorescence and in the regions that contain the AT rich satellite DNA. (2) The alternate, quinacrine dull regions contain a relatively GC rich class of DNA which appears to be more highly methylated than the AT rich DNA in the Q-bright bands, but not the AT rich satellite DNA in the Q-dull C-bands. (3) 5-Methylcytosine residues occur in a sequence of mouse satellite DNA that contains both adjacent pyrimidines and guanine residues. The basic repeating unit of mouse satellite DNA is known to contain the sequence 5-GAAAAATGA-3 (Biro et al., 1975). Therefore, assuming the antibodies used could detect single bases in denatured DNA, the methylated sequence in mouse satellite DNA