Template activity and electron microscopic appearance of salt-extracted chromatin

The surface topography of human chromosomes and nuclei has been examined by light and electron microscopy at each stage during the ASG (G-) and BSG (C-) banding techniques. With both techniques a collapse of the chromosomal structure occurred during pre-treatment and subsequent staining with Giemsa resulted in the development of swollen regions at specific sites along the chromosomes. These swollen regions corresponded to the darkly staining bands observed in both techniques by conventional light microscopy. Removal of the dye resulted in a reversion to the collapsed state. A similar surface appearance was observed in both chromosomes and nuclei after each stage of the techniques.     

On the chemical basis of chromosome banding patterns.

A comparative study of the staining characteristics of four reagents for human chromosomes has been carried out. The four reagents are: (I) quinacrine mustard, as an alkylating agent, (II) the dihydroxy derivative of quinacrine mustard, (III) quinacrine, and (IV) 9-amino-6-chloro-2-methoxyacridine. The last reagent does not possess the amino substituted side chain even though it has the same intercalating nucleus. Comparison of the first three compounds in their staining and banding behavior suggested the initial step leading to banding may be the displacement of the nucleoprotein sites in hcromosomes. The Q and G banding could be blocked experimentally by treating the chromosome preparation with dimethylamine solution. This result may suggest that these sites have weaker basic proteins (nonhistone proteins?). The use of compound IV, which does not have the side chain in the molecule but does have the same intercalating chromophore, did not lead to banding and gives indirect support to this hypothesis. A combined use of compound IV and quinacrine may be useful for the determination of total DNA vs. banding DNA.     

On the Chemical Basis of Chromosome Banding Patterns

A comparative study of the staining characteristics of four reagents for human chromosomes has been carried out. The four reagents are: (I) quinacrine mustard, as an alkylating agent, (II) the dihydrory derivative of quinacrine mustard, (III) quinacrine, and (IV) 9-amino-6-chloro-2-methoryacridine. The last reagent does not possess the amino substituted side chain even though it has the same intercalating nucleus. Comparison of the first three compounds in their staining and banding behavior suggested the initial step leading to banding may be the displacement of the nucleoprotein sites in chromosomes. The Q and G banding could he blocked experimentally by treating the chromosome preparation with dimethylamine solution. This result may suggest that these sites have weaker basic proteins (nonhistone proteins?). The use of compound IV, which does not have the side chain in the molecuk but docs have the same intercalating chromophore, did not lead to handing and gives indirect support to this hypothesis. A combined use of compound IV and quinacrine may be useful for the determination of total DNA vs. banding DNA.     

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.     

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.     

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.     

The karyotype of the mouse

A denaturating and renaturating technique, applied to mouse chromosomes, makes visible characteristic banding patterns by which all elements of the karyotype can be individually distinguished. The Y chromosome as a whole appears darkly stained. The X chromosome comprises 6.33% of the homogametic haploid set. The banding pattern of the chromosomes is compared with that obtained by aid of the quinacrine dihydrochloride fluorescence technique. After its use a banding pattern results which is similar to, but less distinct than, that found after the renaturation procedure.     

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     

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.     

A new type of inversion of a human Y chromosome.

Using chromosome banding techniques, a phenotypically normal male was found to have an abnormal banding pattern of the Y chromosome. By the constitutive heterochromatin staining method, a darkly stained band was located on the short arm and the proximal region of the long arm. The quinacrine staining method also showed a similar abnormal banding pattern: a brightly fluorescing band was seen on the short arm and the proximal region of the long arm. By the conventional Giemsa staining method, however, no specific morphological abnormality was detected in the aberrant Y. On detailed karyotype analyses no recognizable abnormality of banding patterns of any other chromosome was found aside from the abnormal Y. The abnormality was determined to be a complex inversion of the Y chromosome, which is described as 46,X,inv(Y)(pter leads to p11::q11 leads to q12::cen::q12 leads to qter).     

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.     

Hoechst 33258 fluorescent staining of Drosophila chromosomes

Metaphase chromosomes of D. melanogaster, D. virilis and D. eopydei were sequentilly stained with quinacrine, 33258 Hoechst and Giemsa and photographed after each step. Hoechst stained chromosomes fluoresced much brighter and with different banding patterns than quinacrine stained ones. In contrast to mammalian chromosomes, Drosophia's quinacrine and Hoechst bright bands are all in centric heterochromatin and the banding patterns seem more taxonomically divergent than external morphological characteristics. Hoechst stained D. melanogaster chromosomes show unprecedented longitudinal differentiation by the heterochromatic regions; each arm of each autosome can be unambiguously identified and the Y shows eleven bright bands. The Hoechst stained Y can also be identified in polytene chromocenters. Centric alpha heterochromatin of each D. virilis autosome is composed of two blocks which can be differtiated by a combination of quinacrine and Hoechst staining. The distal block is always Q-H- while the proximal block is, for the various autosomes, either Q-H-, Q+H- or Q+H+. With these permutations of Hoechst and quinacrine staining, D. virilis autosomes can be unambiguously distinguished. The X and two autosomes have H+ heterochromatin which can easily be seen in polytene and interphase nuclei where it seems to aggregate and exclude H- heterochromatin. This affinity of fluorochrome similar heterochromatin was been seen in colcemide induced multiple somatic non-disjunctions where H+ chromosomes were distributed to one rosette and H- chromosomes were distributed to another. Knowing the base composition and base sequences of Drosophila satellites, we conclude that AT richness may be necessary but is certainly an insufficient requirement for quinacrine bright chromatin while GC richness may be a sufficient requirement for the absence of quinacrine or Hoechst brightness. Condensed euchromatin is almost as bright as Q+ heterochromatin. While chromatin condensation has little effect on Hoechst staining, it appears to be "the most important factor responsible for quinacrine brightness.' All existing data from D. virilis indicate that each fluorochrome distinct block of alpha heterochromatin may contain a single a single DNA molecule which is one heptanucleotide repeated two million times.     

A comparison of the fluorescent karyotypes of the chimpanzee (Pan troglodytes) and man

Individual chimpanzee chromosomes have been identified by their characteristic banding revealed by quinacrine fluorescent staining. A fluorescent karyotype of this species was set up to be compared with the standard human fluorescent karyotype. It was found that chromosomes 1, 3, 11, 12, 14 and X-chromosome of the chimpanzee appear to have banding patterns similar to the equivalent human chromosomes. Chromosomes 6, 7, 8, 10 and 13 also had a fluorescent pattern corresponding to the human chromosomes of the same number, particularly in the long arm. Remarkable variation in intensity and/or size of fluorescent regions was frequently found in the short arm of satellited acrocentric chromosomes 13, 14, 15, 22 and 23. Variations occurred between homologues and between individuals. Such variable fluorescence in a specific chromosomal region of an individual animal is a reproducible characteristic. Unlike its human counterpart, the distal segment in the long arm of the chimp's Y-chromosome is not brightly fluorescent. An earlier report is thus confirmed.     

Banding pattern analysis of human chromosomes by use of a urea treatment technique

A new technique to reveal the banding pattern of human chromosomes is described. Slides prepared by the routine air drying technique were treated with urea-Sörensen buffer solution for ten minutes at pH 6.8 at 37° C. Individual pairs of all human chromosomes exhibited a characteristic banding pattern by this technique, and by its use the karyotypes were analysed. With the exception of some minor differences the banding patterns obtained by the present technique appeared to be identical with those obtained by the Giemsa staining and quinacrine fluorescence methods carried out by previous workers.Contribution No. 877 from the National Institute of Genetics, Japan. Supported by grant-in-aid No. 92332 from the Ministry of Education of Japan.     

Fluorimetric measurements and chromatin condensation patterns of nuclei from 3T3 cells throughout G1

Using two cytological methods based on nuclear morphology, quinacrine dihydrochloride (QDH) staining and premature chromosome condensation (PCC), it has been possible to identify cell cyle positions within G1 of growing and arrested 3T3 cells. The fluorescent intensity of QDH-stained interphase cells appears to decrease as the cells pass from mitosis to S phase. Likewise, the length and thickness of prematurely condensed chromatids can be related to the cells' position within the G1 period. Data are presented that deal with three interrelated topics: (1) We determined by fluorometric measurements of nuclei from 3T3 cells that the visual observation of the decrease in QDH fluorescence during G1 reflects an actual decrease in total fluorescence and not a dispersion of the fluorescent chromatin in a larger nuclear area. (2) We correlated the results obtained by QDH staining with those of PCC on the same cell samples blocked in G1 by different conditions. Serum-starved and contact-inhibited cell nuclei had the highest intensity, hydroxyurea-treated ones had the lowest intensity, while that of isoleucine-deprived cells was in between. The same relative order of G1 positions was obtained based on PCC morphology. Thus, both methods monitor the state of chromatin condensation and can be used to identify cell cycle position within G1.(3) We showed with both methods that the states of chromatin resulting from the various G1 blocking conditions differ from each other.     

Fine characterization of turbellarian chromosomes I. Giemsa and quinacrine banding in Dugesia polychroa (O. Schmidt)

Giemsa and quinacrine banding was routinely produced in metaphase spreads of the freshwater triclad Dugesia polychroa. The techniques reported here may help eliminate the problems in chromosome banding which have prevented the application of differential chromosome banding in karyological studies of this taxon. More detailed karyological and phylogenetic comparisons with other species now seems possible.     

How, when and why proteins collapse: the relation to folding

Unfolded proteins under strongly denaturing conditions are highly expanded. However, when the conditions are more close to native, an unfolded protein may collapse to a compact globular structure distinct from the folded state. This transition is akin to the coil-globule transition of homopolymers. Single-molecule FRET experiments have been particularly conducive in revealing the collapsed state under conditions of coexistence with the folded state. The collapse can be even more readily observed in natively unfolded proteins. Time-resolved studies, using FRET and small-angle scattering, have shown that the collapse transition is a very fast event, probably occurring on the submicrosecond time scale. The forces driving collapse are likely to involve both hydrophobic and backbone interactions. The loss of configurational entropy during collapse makes the unfolded state less stable compared to the folded state, thus facilitating folding.     

Bandign isolated metaphase chromosomes by a sequential flurescent G/Q technique.

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

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.     

Q Band Chromosomal Polymorphisms in Lake Trout (SALVELINUS NAMAYCUSH)

Q banding of chromosome preparations from lake trout revealed the presence of heteromorphic quinacrine bright bands on several chromosomes. All of the metacentric chromosome pairs can be distinguished on the basis of number, position and intensity of the quinacrine bright bands and chromosome size. These bands appear to represent heterochromatin, since they are darkly staining with the C band technique. Since all of the fish examined had consistent heteromorphisms at several of the quinacrine bright bands, these chromosome markers should be useful in genetic comparisons between different trout stocks and populations.