Reversible differential decondensation of unfixed Chinese hamster chromosomes induced by change in calcium ion concentration of the medium

Differential decondensation of isolated unfixed Chinese hamster metaphase chromosomes was obtained by decreasing the calcium ion concentration in the surrounding medium. A banded appearance of the swollen chromosomes could be observed either directly by phase contrast microscopy or after glutaraldehyde fixation and staining. There was a gradual transition from homogeneously dense to banded and finally to extensively decondensed chromosomes. The patterns induced at different stages were similar to those observed on fixed chromosomes after standard banding procedures (i.e., G-, C-, C_d–, Ag-NOR-staining). Chromosome decondensation could be reversed by the addition of calcium ions to the medium. Ca⁺⁺-dependent reversible differential chromosome decondensation was not observed if the chromosomes were previously treated with 0.35 M NaCl. Chromosome regions which had incorporated BrdU into their DNA were more resistant to a decrease in calcium ion concentration than BrdU non-substituted regions.     

Isolation of chromosome clusters from metaphase-arrested HeLa cells

We have developed a simplified approach for the isolation of metaphase chromosomes from HeLa cells. In this method, all the chromosomes from a cell remain together in a bundle which we call a metaphase chromosome cluster. Cells are arrested to 90–95% in metaphase, collected by centrifugation, extracted with non-ionic detergent in a low ionic strength buffer at neutral pH, and homogenised to strip away the cytoskeleton. The chromosome clusters which are released can then be isolated in a crude state by pelleting or they can be purified away from nearly all the interphase nuclei and cytoplasmic debris by banding in a Percoll^TM density gradient. — This procedure has the advantages that it is quick and easy, metaphase chromatin is recovered in high yield, and Ca⁺⁺ is not needed to stabilise the chromosomes. Although the method does not yield individual chromosomes, it is nevertheless very useful for both structural and biochemical studies of mitotic chromatin. The chromosome clusters also make possible biochemical and structural studies of what holds the different chromosomes together. Such information could be useful in improving chromosome isolation procedures and for understanding suprachromosomal organisation of the nucleus.     

Chromosome homology and heterochromatin in goat,sheep and ox studied by banding techniques

Peripheral blood lymphocyte metaphase chromosomes of three Bovoidean species have been studied using Quinacrine fluorescence and Giemsa banding techniques to give Q-, G-, and C-banding patterns. Q- and G-banding characteristics, coupled with chromosome length, enabled all of the chromosomes in each of the chromosome complements to be clearly distinguished, although some difficulties were encountered with the very smallest chromosomes. A comparison of G-banding patterns between the species revealed a remarkable degree of homology of banding patterns. Each of the 23 different acrocentric autosomes of the domestic sheep (2n=54) was represented by an identical chromosome in the goat (2n=60) and the arms of the 3 pairs of sheep metacentric autosomes were identical matches with the remaining 6 goat acrocentrics. A similar interspecies homology was evident for all but two of the autosomes in the ox (2n=60). This homology between sheep metacentric and goat acrocentric elements confirms a previously suggested Robertsonian variation. The close homology in G-banding patterns between these related species indicates that the banding patterns are evolutionarily conservative and may be a useful guide in assessing interspecific relationships. —The centromeric heterochromatin in the autosomes of the three species was found to show little or no Q-or G-staining, in contrast to the sex chromosomes. This lack of centromeric staining with the G-technique (ASG) contrasts markedly with results obtained with other mammalian species. However, with the C-banding technique these regions show a normal intense Giemsa stain and the C-bands in the sex chromosomes are inconspicuous. The amount of centromeric heterochromatin in the sheep metacentric chromosomes is considerable less than in the acrocentric autosomes or in a newly derived metacentric element discovered in a goat. It is suggested that the pale G-staining of the centromeric heterochromatin in these species might be related to the presence of G-Crich satellite DNA.     

Isolation,fractionation and biochemical analysis of the metaphase chromosomes of Microtus agrestis

A method has been developed for isolating metaphase chromosomes from Microtus agrestis fibroblasts in relatively large quantities with recovery of about 50% of the chromosomes present in the metaphase cells. The method employs pressure homogenisation to release the chromosomes from the cells. The average chemical composition of the Microtus chromosome preparations is 24.6% DNA, 19.9% RNA and 55.5% protein. The isolated chromosomes were fractionated by sedimentation velocity in a density gradient into three size groups in one of which 75–80% of the chromosomes were the large sex-chromosomes. The relative composition of this fraction containing most of the heterochromatin of the cell was DNA: 100, RNA: 59, acid-soluble protein: 54, acid-insoluble protein: 178. — Disc electrophoresis studies revealed no significant difference in the histone patterns between the euchromatic and heterochromatic chromosomes of the three chromosome size-groups. Metaphase chromosomes appear to have a lower lysine-rich histone content than interphase nuclei.     

Responses of mammalian metaphase chromosomes to endonuclease digestion

Digestion of fixed metaphase chromosomes by endonucleases (micrococcal nuclease and DNase II) under optimal digestion conditions followed by Giemsa staining produces sharp banding patterns identical to G-bands. In ³H-thymidine labeled, synchronized metaphase cells of the chinese hamster (CHO line), the band induction is accompanied by the removal of DNA. The single strand specific nuclease S1 and DNase I do not produce such banding patterns.     

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.     

Interaction of anthracyclines with DNA and chromosomes

Daunomycin and adriamycin were previously found to produce Q-like banding patterns on chromosomes. The interaction of several anthracyclines with both natural and synthetic DNAs and chromosomes has been investigated in more detail. Daunomycin fluorescence is almost completely quenched by natural DNAs with varying base composition from 31 to 72% G-C and by the alternating polymer poly-d(G-C)·poly-d(G-C). In contrast, daunomycin fluorescence is quenched by only 50% when the dye interacts with synthetic A-T polymers. Thus, differential quenching of daunomycin fluorescence can account for the production of bright bands at contiguous A-T sequences along the chromosome. Slight differences in fluorescence quenching between the repeating and homopolymeric A-T duplex DNAs were observed which can be attributed to differences in affinity of daunomycin for these DNAs. The aminosugar moiety of daunomycin, daunosamine, increases the binding of daunomycin to DNA and also enhances chromosome banding. — Nogalamycin, which displays no differential quenching with the different DNAs in solution, also fails to produce bands on chromosomes. — These findings suggest that non-random nucleotide sequence arrangements along the chromosome are a basic determinant for dye interaction to produce the observed banding patterns. Specific banding procedures may determine the accessibility of these sites within the chromosomal DNA.     

Photometric determination of the DNA distribution in the 24 human chromosomes

From five normal individuals the DNA content and the DNA arm ratios of the 24 metaphase chromosomes were determined by means of scanning densitometry of photographic negatives of Feulgen-stained metaphase preparations. The results showed high reproducibility of the measuring procedure. The obtained DNA values for the 24 chromosomes showed general correspondence between the individuals. No differences between males and females were found. The DNA arm ratios showed somewhat higher inter-individual variability, especially for the acrocentric chromosomes. Our data are in agreement with other data published so far, which were obtained with somewhat different techniques, indicating that the DNA content of the individual human chromosomes in general is highly constant. Attempts were made to distinguish chromosomes by their DNA content and DNA ratio. It appears that classification of chromosomes using these parameters cannot compete with classification according to the banding patterns. Determination of the total DNA content and DNA distribution along the metaphase chromosomes may, however, provide a frame of reference for cytochemical methods directed towards the localization and quantification of molecular properties of the chromosome.     

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.     

The effect of chromosome banding techniques on the proteins of isolated chromosomes

Experiments were undertaken to determine the effect of various chromosome banding treatments on the histone and nonhistone proteins of isolated, fixed, air-dried metaphase chromosomes. Chromosome preparations were exposed to G-banding (SSC, urea, NaCl-urea, or trypsin), R-banding (Earle's balanced salt solution), and C-banding (NaOH or Ba(OH)₂) treatments, and the extracted and residual proteins were examined by SDS polyacrylamide gel electrophoresis. The results indicate that each of the banding treatments induce characteristic alterations in the chromosomal proteins. The residual proteins left in chromosomes after the diverse G-banding treatments were generally similar to one another, indicating that treatments inducing the same type of banding have similar effects on the chromosomal proteins. This was also true for the two different C-banding treatments. On the other hand, the residual protein patterns seen after the G-banding treatments were strikingly different from those seen after R-banding, which in turn differed from those seen after C-banding. The treatments inducing different types of banding therefore produce markedly different effects on the chromosomal proteins. These protein alterations may have an important influence on the induction of chromosome bands.     

The action of ultraviolet light on the patterns of banding induced by restriction endonucleases in human chromosomes

The irradiation of metaphase spreads of human cells with ultraviolet (UV) light blocked the chromosome banding induced by Alu I, Mbo I, Dde I, Hinf I, Hae III, and Rsa I restriction endonucleases. At 13 J/m² there was moderate inhibition of the nuclease action, which was detected as an increase in the stain intensity of chromosomes (Alu I, Mbo I, Dde I, Rsa I) or as a change in the banding pattern (Hinf I, Hae III). At 70–300 J/m² the UV-induced blockage was complete; the chromosomes showed no banding, and stain intensity was similar to that of control slides incubated with buffer. — BrdU substitution and the irradiation of BrdU-substituted chromosomes with 313 nm light at 1800–15000 J/m² did not block the action of restriction nucleases. On the other hand, UV irradiation of BrdU-substituted chromosomes inhibited the action of restriction enzymes at the same fluences that blocked the nuclease action in unsubstituted chromosomes. The data indicate that DNA-protein crosslinkage is the factor inhibiting DNA extraction and chromosome banding.     

High resolution G-banded chromosomes of the mouse

High resolution G-banded mouse chromosomes were prepared using an actinomycin D and acridine orange pretreatment protocol, resulting in late prophase mouse chromosomes which reveal over twice the number of bands as compared with mid metaphase. These elongated chromosomes, described here in detail and used to construct a precise schematic representation of the late prophase banding patterns, should be generally useful in high resolution mouse chromosome analysis.     

Morphological and biochemical effects of endonucleases on isolated mammalian chromosomes in vitro

Endonuclease digestion of isolated and unfixed mammalian metaphase chromosomes in vitro was examined as a means to study the higher-order regional organization of chromosomes related to banding patterns and the mechanisms of endonuclease-induced banding. Isolated mouse LM cell chromosomes, digested with the restriction enzymes AluI, HaeIII, EcoRI, BstNI, AvaII, or Sau96I, demonstrated reproducible G- and/or C-banding at the cytological level depending on the enzyme and digestion conditions. At the molecular level, specific DNA alterations were induced that correlated with the banding patterns produced. The results indicate that: (1) chromatin extraction is intimately involved in the mechanism of endonuclease induced chromosome banding. (2) The extracted DNA fragments are variable in size, ranging from 200 bp to more than 4 kb in length. (3) For HaeIII, there appears to be variation in the rate of restriction site cleavage in G- and R-bands; HaeIII sites appear to be more rapidly cleaved in R-bands than in G-bands. (4) AluI and HaeIII ultimately produce banding patterns that reflect regional differences in the distribution of restriction sites along the chromosome. (5) BstNI restriction sites in the satellite DNA of constitutive heterochromatin are not cleaved intrachromosomally, probably reflecting an inaccessibility of the BstNI sites to enzyme due to the condensed nature of this chromatin or specific DNA-protein interactions. This implies that some enzymes may induce banding related to regional differences in the accessibility of restriction sites along the chromosome. (6) Several specific nonhistone protein differences were noted in the extracted and residual chromatin following an AluI digestion. Of these, some nonhistones were primarily detected in the extracted chromatin while others were apparently resistant to extraction and located principally in the residual chromatin. (7) The chromatin in constitutive heterochromatin is transiently resistant to cleavage by micrococcal nuclease.     

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.     

Automatic detection and localization of sister chromatid exchanges.

Sister chromatids of human metaphase chromsomes from cells which have replicated twice in medium containing 5-bromodeoxyuridine exhibit unequal fluorescence when stained with the dye 33258 Hoechst. Sister chromatid exchanges occurring in these chromosomes are apparent as interchanges of brightly and dully fluorescing chromatids. A technique for detecting such exchanges by computer analysis of chromsome images has been developed and found to campare favorably with manual methods. The exchanges have been localized in the context of quinacrine banding patterns.     

An analysis of the technical variables in the production of C bands

Numerous combinations, concentrations, pH's and durations of HCl, NaOH and SSC treatments were tested for the purpose of developing an improved C banding technique for human metaphase chromosomes. Methods of slide preparation, as they affect C banding were also evaluated. — HCl and SSC treatment used separately, for all times and concentrations tested, gave no C banding. All treatment sequences which included an NaOH exposure gave at least some C banding, but also gave considerable swelling and distortion. Surprisingly, the best results were obtained from heat-dried preparations exposed to 0.2 N HCl at 25° C for 15 minutes, no NaOH and subsequently incubated in 2xSSC, pH=7.0 at 62–65° C for 18–24 hours. This technique is now being used routinely, following a G banding technique for homologue identification, to monitor C band variation in human chromosomes. — The pH of the 2xSSC incubation solution was found to be important. Slides treated as above with HCl, but with 2xSSC, pH=6.0 gave only G banding; HCl and 2xSSC, pH=8.0 gave C banding, but considerable chromosome swelling and poor uptake of stain. — Air- or ignition-dried preparations, with the HCl and 2xSSC treatment appeared undertreated and gave a mixture of G and C banding. A brief (30 second) exposure to 0.07 N NaOH between the HCl and 2xSSC steps is recommended. These results are in support of DNA-protein interaction and/or loss rather than denaturation-renaturation as a likely mechanism for C band production.     

The late replication banding patterns of chromosomes are highly conserved in the genera Rana,Hyla, and Bufo (Amphibia: Anura)

Late replication banding and C-banding analyses were performed on the metaphase chromosomes of six species and one subspecies of Palearctic water frogs, genus Rana. Although C-banding patterns showed interspecific or intersubspecific variation, late replication banding patterns of all 13 chromosome pairs of these species were homologous. Minor differences of banding patterns were observed only in chromosomes 2, 7 and 13. Close comparison of the late replication banding patterns with those of three non-water frog species of Rana, and one each of Hyla and Bufo, provided important information on interspecific and intergeneric variability. In the Rana species, the banding patterns of all 13 pairs were homologous except for those some regions of 8 pairs. In one species each of Hyla and Bufo that was examined, the six large chromosome pairs (Nos. 1-6) showed banding homologies. Furthermore, among the Rana, Hyla and Bufo species the four large chromosome pairs (Nos. 1-3, 5 of Rana and Hyla, and Nos. 1, 3–5 of Bufo) shared banding homologies. These results show that the large chromosomes have been highly conserved in the evolutionary history of the three genera.     

Spreading and staining of human metaphase chromosomes on aminoalkylsilane-treated glass slides

Summary The properties of aminoalkylsilane-treated glass slides for the preparation of metaphase spreads and their staining quality have been studied and compared with those of slides which had only been cleaned in ethanol/ether. The parameters investigated were: (1) the average area of metaphases from cultures of blood from both healthy donors and haematology patients; (2) the influence of the positively charged coating on the quality of quinacrine- and Giemsa-banding patterns; (3) non-specific background staining for these banding methods; (4) the number of metaphases as compared to the number of interphase cell nuclei per area of preparation; and (5) the Feulgen-staining intensities of chromosomes and chicken erythrocyte nuclei.The quality of metaphase preparations and the differential staining of chromosomes is better on aminoalkysilane-treated glass slides than that of preparations on routinely cleaned normal microscope slides. In the preparations on aminoalkylsilance-treated slides, the distribution of the cells over the glass surface is more homogeneous; and no influence could be detected on the relative frequency of metaphases as compared to the number of non-divided cell nuclei; the average area per metaphase is increased by about 10% and consequently the number of overlapping chromosomes is decreased.Preparations on aminoalkylsilane-treated glass, after Q-, G- and DAPI-banding procedures, always showed less binding of the staining compounds to the glass slide (a cleaner background) than those on routinely cleaned microscope glass slides. The Feulgen-pararosaniline staining intensities of human metaphase chromosomes and chicken erythrocyte nuclei are the same on aminoalkylsilane-treated slides and on routinely cleaned glass slides. Furthermore, the reproducibility and constancy of quinacrine banding was improved by development of an equilibrium staining method which does not require a washing procedure. The medium, containing 0.002% quinacrine, allows optimal staining results to be obtained for microphotography purposes within 30 min of staining (for visual inspection at least 90 min is required) and is used as the embedding medium.In combination with aminoalkylsilane-treated glass slides, this procedure leads to a clean background and reproducible banding patterns of excellent quality, the results being better and more constant than those of methods described before.