Identification of sex chromosomes in lake trout (Salvelinus namaycush)

In the male trout there is a difference in the quinacrine banding and C-banding patterns between the two homologs of the second largest chromosome pair. This chromosome is the only large submetacentric in the karyotype, making it easy to identify and suggesting that the sex chromosomes have become differentiated since the time of tetraploidization. In males one homolog has a medium-to-large quinacrine bright heterochromatic band on the end of the short arm, while the other lacks it completely. In females both homologs have medium-to-large quinacrine bright heterochromatic bands. Approximately half the progeny from every lake trout cross studied and half the eggs from every lake trout population examined were heteromorphic for a difference in this chromosome band. Results from sexed fish, reciprocal F1 hybrids between brook trout and lake trout, and gynogenetic haploids are all consistent with the interpretation that chromosome 2 is the sex chromosome. These results suggest that the addition of heterochromatin to the X can be the first step in the inhibition of crossing over between the X and Y chromosomes required for sex chromosome differentiation.     

Fluorescence analysis of late DNA replication in human metaphase chromosomes.

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

Q-bands in Lilium and their relationship to C-banded heterochromatin

In L. pardalinum, narrow bands of quinacrine fluorescence are distributed throughout the chromosomes. These vary in intensity from dull to bright, and their constant pattern allows all chromosomes to be recognized. Bright bands occur at some centromeres, and near all three nucleolar constrictions. In L. longiflorum, similar Q-bands occur along chromosomes, but they are less distinctive and their pattern does not closely match that of L. pardalinum. Also, L. longiflorum does not have bright regions at or near primary and secondary constrictions. Most Q-bands do not coincide with dark Giemsa C-bands, except for the bright nucleolar and centromeric regions in L. pardalinum. All C-banded heterochromatin stains identically after SSC pretreatment, dark with Giemsa and bright with quinacrine.— The many Q-bands of varying intensity, wide distribution and constant pattern, unrelated to C-bands, may be analogous to mammalian Q-bands. Such universality is expected if Q-bands area fundamental component of chromosome architecture.     

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.     

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.     

T antigen banding on chromosomes of simian virus 40 infected muntjac cells.

Chromosomes were prepared from mitotic munjac cells 48 to 72 h after infection with SV40 virus. When stained for SV40 T antigen by indirect immunofluorescence, all chromosomes within an infected cell were fluorescent, indicating the presence of T antigen. Furthermore, the chromosomes were not uniformly stained but appeared to have regions of high and low fluorescence intensity. A variety of controls showed that the banding patterns are specific and highly reproducible and may indeed reflect the binding sites of T antigen. The bright, fluorescent bands T antigen were found to correspond to bands visualized by trypsin-Giesma staining (G-bands) and also by quinacrine staining (Q-bands). Current knowledge of chromosome banding indicates that Q-bands reflect the distribution of AT-rich regions along the chromosome. From the DNA sequence of SV40, it is known that one of the T antigen binding sites contains AT-rich sequences; thus, T antigen banding might be due to the base-specific binding of T antigen to chromatin. In addition, these bands have been implicated as centers for chromosome condensation and units in control of DNA replication. While the functional significance of T antigen binding has yet to be determined, the SV40-muntjac system provides an unusual opportunity to study the interaction of a known regulatory protein with mammalian chromosomes.     

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     

Changes in the fluorescence patterns of translocated Y chromosome segments in Drosophila melanogaster

Fluorescence analysis after quinacrine staining in squashes of Varese wild stock male larval ganglia confirmed that the Y chromosome has four characteristic sections of bright fluorescence. In one Y/X and in one Y/III translocation the section of bright fluorescence on the short arm of the Y is no longer bright when translocated onto the terminal portion of the X and on the right arm of the III chromosome, respectively. Fluorescence analysis has also permitted the identification of a structurally abnormal Y chromosome in a cell line of Drosophila melanogaster established in vitro. The findings in the two translocations call for caution in the interpretation of structural rearrangements by fluorescence analysis.     

Chromosome banding homologies in three species of Aedes (Stegomyia)

The chromosome complements of the mosquitoes Aedes aegypti, Aedes mascarensis, and Aedes albopictus, belonging to the subgenus Stegomyia, gave a uniform response to the Q-, H-, and R-banding techniques. Of the three homomorphic chromosome pairs, only the shortest or sex pair (I) showed a consistent banding pattern. In the three species, a bright yellow intercalary band was present on one arm of both chromosomes of the sex pair after heat treatment and staining with acridine orange. The rest of the chromosome and the other two pairs fluoresced orange-red. The same intercalary region appeared completely dark with the fluorochromes quinacrine and Hoechst 33258, while the rest of the chromosomes fluoresced dull. The same banding pattern was present in males and females. Size variations of the Q- and H-negative and R-positive intercalary bands were observed within each species. The results are interpreted in terms of structural homology of the sex-determining chromosomes, which is retained within the subgenus.     

Feulgen hydrolysis and chromosome banding in Chilocorus (Coleoptera: Coccinellidae).

Prolonged Feulgen hydrolysis of chromosomes of Chilocorus orbus Csy. and C. stigma Say produces banding patterns that are the reverse of those revealed with quinacrine; brightly fluorescing regions are unstained, but nonfluorescent regions remain relatively darkly stained. This differential reactivity at hydrolysis times that otherwise yield intense Feulgen staining confirms the need for caution in the determination of DNA values with the Feulgen reaction in material with well-defined quinacrine bands. The coincidence of DNA-specific Feulgen bands with Q-, G-, and C-bands supports the view that, in Chilocorus at least, bands reflect differences in DNA composition along the chromosome.     

Fluorescence analysis of late DNA replication in mouse metaphase chromosomes using BUdR and 33258 Hoechst

A late replicating X or Y chromosome can be detected by 33258 Hoechst staining and fluorescence microscopy in a large proportion of female or male mouse embryo cells, respectively, which have been cultured in medium containing 5-bromodeoxyuridine (BUdR) for part of one DNA synthesis period, The observed distribution of late replicating chromosome regions also includes centromeric heterochromatin and some quinacrine positive bands.     

Ectopic pairing of chromosome regions containing chemically similar DNA

Using genetically controlled stocks ofDrosophila melanogaster we have compared the frequency of ectopic pairing in a line showing intense quinacrine fluorescence at two sites (81F and 83E) on chromosome 3 with one showing such fluorescence at only one of these sites (81F). The frequency of ectopic pairing is an order of magnitude greater in cells from the line showing intense fluorescence in both regions than in the line showing it in only one. These data indicate that ectopic pairing is dependent upon properties of discrete chromosome regions as small as individual bands. Since A: T-rich chromatin is known to fluoresce intensely after quinacrine staining, these data further suggest that ectopic pairing is dependent on similarities of the DNA of the discrete chromosome regions involved.     

Chromosome analysis on 930 consecutive newborn children using quinacrine fluorescent banding technique

Summary Chromosome analysing using quinacrine fluorescence was performed on 930 consecutive newborn infants. The total incidence of major chromosome aberrations including numerical changes of the sex chromosomes, and structural changes of autosomes, was 0.54%. Incidences of XYY (0.4%) and XXY (0.2%) were relatively higher as compared to other studies. About 0.75% of the newborn infants were found to have a variable bright fluorescent band located on the proximal area of the short arm (p11) rather than on the proximal long arm (q11) of chromosome No. 3. Attempts were also made to record the variable fluorescent regions on 7 autosomes and the Y chromosome.     

Identification of several chromosome aberrations in man by the fluorescent method using quinacrine yprite]

The applications of the fluorescent staining of chromosomes with quinacrine mustard allowed to identify a dicentric Y-chromosome in two patients with defected external gynaetalies: a boy of 15 years old and a girl of 2 years old. Both the patients had mosaicism of sex chromosomes: 45, x/46, x dic (Y). The dicentric Y-chromosome, resembling chromosome, 16, had bright luminescence of the thelomeric regions characteristic of the normal Y-chromosome. Besides, a balanced autosomic translocation t (1, 14) (q 31, q 3) was found in the girl identified also with quinacrine mustard fluorescent staining.     

Hoechst 33258 banding of Drosophila nasutoides metaphase chromosomes

Hoechst 33258 banding of D. nasutoides metaphase chromosomes is described and compared with Q and C bands. The C band positive regions of the euchromatic autosomes, the X and the Y fluoresce brightly, as is typical of Drosophila and other species. The fluorescence pattern of the large heterochromatic chromosome is atypical, however. Contrary to the observations on other species, the C negative bands of the large heterochromatic chromosome are brightly fluorescent with both Hoechst 33258 and quinacrine. Based on differences in the various banding patterns, four classes of heterochromatin are described in the large heterochromatic chromosome and it is suggested that each class may correspond to an AT-rich DNA satellite.     

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.     

Stepwise accumulation of autoregulated enzyme activities during the cell cycle of the eucaryote Chlorella

Although the allocyclic X chromosome of the mouse frequently appears heteropycnotic, showing chromatid apposition, the feature is not necessarily consistent in conventionally stained metaphases. In contrast, the quinacrine mustard fluorescence and acetic saline Giemsa techniques unambiguously delineate the asynchronously replicating, allocyclic X in most metaphase spreads prepared from 6.5–7.5 days old female embryos, where the allocyclic X is characterized by bright fluorescence over the entire length with two faintly dark bands in the lower middle regions. The same X shows heavy staining by the ASG technique, resulting in less conspicuous banding pattern as compared with its isocyclic homologue. The above features are confirmed in adult bone marrow cells and primary fibroblast culture of the lung derived from the adult female as well as the 18-day-old embryo, though the frequency of cells with an identifiable allocyclic X decreases to some extent. Length measurement demonstrates that the allocyclic X is slightly shorter than the isocyclic one.     

Observations on specific giemsa staining of the Y and on selective oil destaining of the chromosomes.

The human Y chromosome can be differentially stained with Giemsa using simple procedures. This phenomenon is strikingly to that observed with quinacrine fluorescence. The specific Giemsa-Y stain may be selectively removed by the action of an oil. The same oil, under certain conditions, selectively removes Giemsa stain from all chromosomes, resulting in R- and T-banding patterns. These bands, which are obtained through subtraction of dye from Giemsa-stained chromosomes, allow slides to be further processed.     

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.     

Identification of sex chromosome molecular markers using RAPDs and fluorescent in situ hybridization in rainbow trout

The goal of this work is to identify molecular markers associated with the sex chromosomes in rainbow trout to study the mode of sex determination mechanisms in this species. Using the RAPD assay and bulked segregant analysis, two markers were identified that generated polymorphic bands amplifying preferentially in males of the Mount Lassen and Scottish strains of rainbow trout. Chromosomal localization using fluorescent in situ hybridization of a 900 bp probe developed from one of these markers revealed a brightly defined signal on a chromosome that could morphologically be classified as the Y chromosome. This revised version was published online in July 2006 with corrections to the Cover Date.