Cytogenetic markers for X chromosome in a karyotype of rainbow trout from Rutki strain (Poland)

Cytogenetic or molecular identification of sex chromosomes could help in breeding studies in producing monosex fish stocks, estimating success of androgenesis, gynogenesis, etc. Among fish species sex chromosomes are recognizable in only a few cases. Some populations of rainbow trout Oncorhynchus mykiss show morphologically differentiated sex chromosomes. A strain from Rutki, Poland, showed a heteromorphic pair of subtelocentric chromosome: presumably of the XY type in the male and XX in the female. Restriction endonuclease and DAPI banding resulted in a characteristic banding pattern enabling identification of the X chromosome.     

Homologous chromosomes characteristics by sequential banding procedures in rainbow trout Oncorhynchus mykiss

The development of high resolution methods of chromosome banding helped the finding of homologous chromosomes, detecting chromosomal abnormalities, and assigning the gene loci to particular chromosomes in mammals. Unfortunately, small and numerous fish chromosomes do not show GC rich and GC poor compartments, this preventing the establishment of G banding pattern. The combination of techniques enabling the identification of constitutive heterochromatin (C-banding), heterochromatin resistant to restriction endonucleas, NOR bearing chromosomes (AgNO3 banding), or AT rich regions on chromosomes (DAPI banding) in sequential staining provides a better characteristic of fish chromosomes. In this work sequentially DAPI, DdeI, AgNO3 stained chromosomes of rainbow trout resulted in the characteristic banding pattern of some homologous chromosomes. Procedure of FISH with telomere probe and DAPI as a counterstaining fluorochrome visualized simultaneous hybridization signals and DAPI banding. Possibility of detection both FISH and DAPI signals can help in procedures of gene mapping on chromosomes.     

Structural organization of chromosomes of the Indian muntjac (Muntiacus muntjak)

The identification, morphology, and banding pattern of the chromosomes of the Indian muntjac (Muntiacus muntjak) are described. A diagrammatic representation of the banding pattern as revealed by various techniques is presented following the nomenclature suggested by Paris Conference (1971) for human chromosomes. The Y2 chromosome and the neck of the X chromosome are late replicating based on observations made with the use of a bromodeoxuridine plus Giemsa technique. Most of the G-bands are early replicating, contrary to earlier findings based on autoradiography.     

Chromosome banding and compaction

Summary We have described a characteristic substructure of mitotic chromosomes, the chromosomal unit fibre, with lengths about five times the length of the corresponding metaphase chromosomes and a uniform diameter of 0.4 m. In order to study the relationship of chromosome banding to chromosome compaction, methods have been devised to obtain banding patterns on chromosomal unit fibres, similar to G-band patterns of intact mitotic chromosomes. The total number of bands plus interbands per haploid human karyotype is estimated at about 3000. The banding pattern of chromosomal unit fibres indicates a certain resemblance to the normal G-banding pattern of human chromosomes even if the details indicate a short-range random distribution.     

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.     

Toward a multicolor chromosome bar code for the entire human karyotype by fluorescence in situ hybridization

A colored banding pattern for human chromosomes is described that distinguishes each chromosome in a single fluorescence in situ hybridization with a set of subregional DNA probes. Alu/polymerase chain reaction products of various human/rodent somatic cell hybrids (fragment hybrids) were pooled into two probe sets that were labeled differentially and detected by red and green fluorescence. Chromosome regions hybridized by DNA present in both pools appeared yellow. The result was a multi-color set of 110 distinct signals per haploid chromosome set for the human karyotype. Each individual chromosome showed a unique sequence of signals, a result termed the “chromosome bar code”. The reproducibility of the hybridization pattern in various labeling and hybridization experiments was analyzed by computer densitometry. We have applied the chromosome bar code both in diagnostic cytogenetics and in genome studies. The approach allows the rapid identification of chromosomes and chromosome rearrangements. Although not yet showing the resolution of classical banding patterns, the present experiments demonstrate various applications in which the present multi-color bar code can significantly add to the spectrum of cytogenetic techniques. Received: 18 December 1996 / Accepted: 10 February 1997     

The DNA-based structure of human chromosome 5 in interphase

In contrast to those of metaphase chromosomes, the shape, length, and architecture of human interphase chromosomes are not well understood. This is mainly due to technical problems in the visualization of interphase chromosomes in total and of their substructures. We analyzed the structure of chromosomes in interphase nuclei through use of high-resolution multicolor banding (MCB), which paints the total shape of chromosomes and creates a DNA-mediated, chromosome-region-specific, pseudocolored banding pattern at high resolution. A microdissection-derived human chromosome 5-specific MCB probe mixture was hybridized to human lymphocyte interphase nuclei harvested for routine chromosome analysis, as well as to interphase nuclei from HeLa cells arrested at different phases of the cell cycle. The length of the axis of interphase chromosome 5 was determined, and the shape and MCB pattern were compared with those of metaphase chromosomes. We show that, in lymphocytes, the length of the axis of interphase chromosome 5 is comparable to that of a metaphase chromosome at 600-band resolution. Consequently, the concept of chromosome condensation during mitosis has to be reassessed. In addition, chromosome 5 in interphase is not as straight as metaphase chromosomes, being bent and/or folded. The shape and banding pattern of interphase chromosome 5 of lymphocytes and HeLa cells are similar to those of the corresponding metaphase chromosomes at all stages of the cell cycle. The MCB pattern also allows the detection and characterization of chromosome aberrations. This may be of fundamental importance in establishing chromosome analyses in nondividing cells.     

The pattern of restriction enzyme-induced banding in the chromosomes of chimpanzee,gorilla, and orangutan and its evolutionary significance

Summary The pattern of banding induced by five restriction enzymes in the chromosome complement of chimpanzee, gorilla, and orangutan is described and compared with that of humans. The G banding pattern induced by Hae III was the only feature common to the four species. Although hominid species show almost complete chromosomal homology, the restriction enzyme C banding pattern differed among the species studied. Hinf I did not induce banding in chimpanzee chromosomes, and Rsa I did not elicit banding in chimpanzee and orangutan chromosomes. Equivalent amounts of similar satellite DNA fractions located in homologous chromosomes from different species or in nonhomologous chromosomes from the same species showed different banding patterns with identical restriction enzymes. The great variability in frequency of restriction sites observed between homologous chromosome regions may have resulted from the divergence of primordial sequences changing the frequency of restriction sites for each species and for each chromosomal pair. A total of 30 patterns of banding were found informative for analysis of the hominid geneaalogical tree. Using the principle of maximum parsimony, our data support a branching order in which the chimpanzee is more closely related to the gorilla than to the human.     

Computer assisted karyotype analysis of Pyrrhopappus carolinianus

With the help of Computer Aided Karyotyping procedures, Ag-NOR staining and C-banding techniques, the karyotype of Pyrrhopappus carolinianus (Asteraceae, Lactuceae) has been studied. The species has 2n=12 chromosomes. Silver staining reveals that the two shortest pairs of chromosomes possess NOR's. On the basis of chromosome length and centromere position, only the longest chromosome pair and the satellite chromosomes can be identified. Two types of C-banding can be obtained, dependent on the temperature of the hydrochloric acid hydrolysis of the root tips. Hydrolysis at 60°C results exclusively in centromeric bands, whereas a treatment at room temperature reveals a pattern of intercalary bands. A computer assisted analysis of the intercalary banding pattern resulted in the construction of schematic representation of the average C-banding pattern. This banding pattern allows an easy identification of each of the chromosome pairs.     

Rapid physical mapping of cloned DNA on banded mouse chromosomes by fluorescence in situ hybridization.

Physical mapping of DNA clones by nonisotopic in situ hybridization has greatly facilitated the human genome mapping effort. Here we combine a variety of in situ hybridization techniques that make the physical mapping of DNA clones to mouse chromosomes much easier. Hybridization of probes containing the mouse long interspersed repetitive element to metaphase chromosomes produces a Giemsa-like banding pattern which can be used to identify individual Mus musculus, Mus spretus, and Mus castaneus chromosomes. The DNA binding fluorophore, DAPI, gives quinacrine-like bands that can complement the hybridization banding data. Simultaneous hybridization of a differentially labeled clone of interest with the banding probe allows the assignment of a mouse clone to a specific cytogenetic band. These methods were validated by first mapping four known genes, Cpa, Ly-2, Cck, and Igh-6, on banded chromosomes. Twenty-seven additional clones, including twenty anonymous cosmids, were then mapped in a similar fashion. Known marker clones and fractional length measurements can also provide information about chromosome assignment and clone order without the necessity of recognizing banding patterns. Clones hybridizing to each murine chromosome have been identified, thus providing a panel of marker probes to assist in chromosome identification.     

Trypsin G- and C-banding for interchange analysis and sex identification in the chicken

The trypsin banding methods were applied to feather pulp and embryonic material of the chicken. Two contrasting types of chromosomal banding patterns were obtained by varying the duration of trypsin treatment. A short time treatment shows a G-banding pattern which has characteristic and distinctive bands along the chromosome arms. Prolonging the trypsin treatment causes the G-banding pattern to disappear, and only the centromeres and the W chromosome remained heterochromatic which is characteristic of the C-banding pattern. The application of the G-banding pattern analysis was used to identify regions of chromosomes involved in rearrangements. The simplified trypsin technique which produces the C-banding pattern makes it relatively easy to identify the W sex-chromosome and determine sex in avian species.     

Structure of human chromosomes visualized at the electron microscopic level

A newly developed technique allows cytological (light microscope level) chromosome preparations to be examined at the electron microscopic level. Ultrathin (50 nm) sections of highly condensed Hela cell metaphase chromosomes show the characteristic mitotic chromosome morphology. In addition a fibrous network (presumably chromosome fibers) can be seen within them. Fibers appear to be gathered at foci along each chromatid. Treatment of chromosomes with trypsin in a trypsin/G-banding procedure reduces the amount of staining material at the electron microscopic level and results in more prominent foci. Thicker (100 nm) sections of less condensed chromosomes prepared from human lymphocytes display a banding pattern similar to G-banding, even without pretreatment with proteases.     

Fluram induces species-dependent C and G bands in mammalian chromosomes, revealing heterogeneous distribution of chromosomal proteins

Fluram (Fluorescamine; 4-phenylspiro(furan-2(3H),1'-phthalan)-3,3'-dione) is a fluorogenic reagent, which permits the detection of primary amines by forming highly fluorescent pyrrolinone derivatives. This reagent has been used on methanol-acetic acid fixed metaphase chromosomes of mouse and man and proved to be very effective in differentiating chromosome regions in both genomes. Mouse centromeric heterochromatin is highly reactive, showing intense fluorescence in all centromeric regions, whereas human chromosomes show no fluorescence in such regions. In addition, a G-like banding pattern is also obtained in both types of chromosomes. The differential reactivity of each chromosome region showed by this method demonstrates a heterogeneous distribution of chromosome proteins, resulting in a chromosome banding pattern, which is in this case species dependent.     

A photographic representation of the variability in the G-banded structure of the chromosomes in the mouse karyotype

Analysis of the mouse chromosomes is becoming increasingly important in many fields of genetic research. It is generally considered that the mouse chromosomes are more difficult to analyse than, for example, human chromosomes which has often led to their misidentification. This article presents a guide to the correct identification of trypsin-Giemsa banded chromosomes from the mouse. The variability in the G-banded structure of each chromosome is presented pictorially together with some suggestions for their unequivocal identification. Since many of the mouse chromosomes have similar banding patterns, those chromosomes which are more frequently misidentified have been compared and contrasted. Finally a summary of the main features for the identification of each chromosome is presented.     

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.     

Resolving ambiguities in the karyotype of domestic sheep (Ovis aries)

The unambiguous identification of ovine chromsomes has become essential for the mapping of the sheep genome, which predominantly consists of telocentric chromosomes of gradually decreasing size. Nucleolus organizer regions (NORs) and Robertsonian fusions have been used here as the cytological and morphological markers, respectively, to define the banding pattern of eight paris of sheep telocentric chromosomes that have an ambiguous identification status. Five Robertsonian chromosomes involving most of the ambiguous chromosomes as well as normal prometaphase chromosomes were stained sequentially and separately by QFQ, GTG, and Ag-NOR methodologies. The prometaphase banding patterns of the ambiguous chromosomes 4, 6, 8, 9, 21, 24, 25 and 26 are represented schematically. For providing an accurate image of the banding pattern, a system of shading has been employed to show the relative intensity of bands in a given chromosome. The results presented here will facilitate the regional mapping of the sheep genome, extend the information on cytogenetic homology with other bovids, and substantially accelerate the comparative mapping studies in Bovidae.     

The use of subchromosome-length unique band sequences in the analysis of prophase chromosomes.

Using human prophase chromosome ideograms at the 850-band stage, we previously demonstrated that the 24 prophase ideograms can be divided into a set of 94 unique band sequences, each having a recognizable banding pattern distinct from other nonhomologous chromosome portions. Using actual prophase mitotic cells in this study, we analyzed the p arm of chromosome 11 and of chromosomes 16-22 and characterized a similar set of unique band sequences on actual chromosomes. This set of unique band sequences, a statistical comparison scheme, and image-processing techniques outlined in the present report can be used to identify and distinguish banding patterns of these chromosomes and to determine band pattern abnormalities.     

Unidirectional loss of human chromosomes in rat-human hybrids

Karyological analysis of 25 rat-human hybrid cell clones shows that only the human chromosomes are lost from the hybrids. Giemsa banding staining of the chromosomes of these hybrids allowed the identification of each human chromosome present in the hybrid cells.     

Giemsa banding patterns in chronic lymphocytic leukaemia.

The banding patterns of chromosomes from 20 patients with chronic lymphocytic leukaemia (C.L.L.) have been analyzed. 97 of 100 metaphases examined had a normal banding pattern. The 3 remaining metaphases, all from one patient had bands similar to those seen after aging. It is concluded that the chromosomes in C.L.L. have normal banding patterns. The majority of cytogenetic studies in chronic lymphocytic leukaemia have reported normal chromosomes (Fitzgerald and Adams 1965; Oppenheim et al., 1965; Lawler et al., 1968). An inherited abnormality of G group chromosome (No. 22) has been reported in a family, three members of whom developed C.L.L. (Fitzgerald and Hamer, 1969), but further investigations of cases of familial leukaemia failed to reveal a similar abnormality (Fitzgerald et. al., 1966). The development of new techniques which allow the positive identification of individual chromosomes (Caspersson et al., 1969; Dutrillaux and Lejeune, 1971; Sumner et al., 1971; Seabright, 1971), has revolutionised human cutogenetics and revealed additional information regarding chromosome abnormalities and leukaemia (Rowley, 1973; Lobb et al., 1972; Milligan and Garson, 1974). The purpose of this investigation was to determine whether the chromosomes in C.L.L. have normal banding patterns.     

The banding pattern of the salivary gland chromosomes of Drosophila hydei

The banding pattern of the salivary gland chromosomes of D. hydei was investigated in the electron microscope. We compared the banding pattern of squashed chromosomes with non-squashed preparations and observed that the fixation and squash procedure we used does not introduce artificial changes in the banding pattern of the chromosome. An electron microscopic map was made of the banding pattern of the distal half of the second salivary gland chromosome. On the basis of the number of bands in this part of the second chromosome we calculated a total of about 3700 bands for the whole set of polytene chromosomes of D. hydei. Our data indicate a similar number of bands in the salivary gland chromosomes of evolutionary remote Drosophila species like D. hydei and D. melanogaster.