Q- and C-bands in the metaphase chromosomes of Drosophila nasutoides

The large heterochromatic chromosome of Drosophila nasutoides reveals distinctive C- and Q-bands. The regions which are negative in C-banding appear positive in Q-banding. The isochromosomic nature of this chromosome and the locality of the satellite DNAs in this chromosome are discussed with respect to these banding patterns.     

G-banding of human sperm chromosomes

Summary G-banded human sperm chromosomes are routinely obtained in our laboratory using a modification of the method described by Martin et al. (1982). The study of banded sperm chromosomes is essential for the genetic counseling of male carriers of balanced chromosome rearrangements.     

A simple method to sequentially reveal Q- and C-bands on the same metaphase chromosomes

The Q-C staining procedure, i.e., to treat QM stained preparations with a modified ASG method, conveniently provides Q? and C? (instead of the expected G?) bands on the same metaphase chromosomes. This procedure is especially useful for karyological study of heteroploid cells and interspecific cell hybrids in which extensive chromosomal rearrangements and complex karyotypic compositions are present. A few examples of karyological interest are reported. C-bands, which are either Q+ or Q?, can be divided into two to three subsegments in human chromosomes 1, 9, and 16. These subsegments are connected by a Q?/C?element. Interstitial C-bands could have originated mostly from a C-band without the kinetochore or with the“non-functional” kinetochore.“Double Minutes” are of two kinds, Q+/C+ and Q?/C+. Mechanism for the production of C-bands by the Q-C procedure is briefly discussed.     

Quantitative studies on the arrangement of human metaphase chromosomes

Summary The association pattern was studied in 2715 mitoses of 90 meningiomas with different numbers of acrocentric chromosomes. In cells with monosomy 22, a significant increase of mitoses with associations was observed in comparison to cells with a normal karyotype. The number of associating acrocentric chromosomes was highly significantly increased. This surplus was not only caused by a highly significant increase of associating G chromosomes but also of D chromosomes. The loss of further acrocentric chromosomes had no significant influence on the number of mitoses with associations or the number of associating chromosomes. Based on the well-known correlations between the nucleolus organization and the association pattern, the results seem to indicate a compensation mechanism among the nucleoles organizing regions (NOR's) which keeps the supply of nucleolar material constant and simultaneously causes a higher association tendency between the remaining acrocentric chromosomes. The increase of associations in the 22 monosomic cells was interpreted as a overcompensation after the loss of only one NOR.     

Quantitative studies on the arrangement of human metaphase chromosomes

Summary The association pattern was studied in 1182 mitoses of 21 patients with trisomy 13 and in a control group. In addition, 173 trisomic mitoses were compared with the same number of diploid mitoses in a case of mosaicism.The number of mitoses with associations was no higher in the trisomic cells than in cells with normal karyotypes. Some differences were observed in the frequency of associations per cell and of the types of associations in the patient group and in the trisomic cells of the mosaic case. The number of associations in which more than two acrocentric chromosomes were involved was unexpectedly low in the cells with a supernumerary chromosome 13.The result are interpreted as suggesting the existence of a compensatory mechanism activated by the additional acrocentric chromosome.Parts of this work are included in the doctoral (MD) thesis of DM     

Proteome analysis of human metaphase chromosomes

DNA is packaged as chromatin in the interphase nucleus. During mitosis, chromatin fibers are highly condensed to form metaphase chromosomes, which ensure equal segregation of replicated chromosomal DNA into the daughter cells. Despite >1 century of research on metaphase chromosomes, information regarding the higher order structure of metaphase chromosomes is limited, and it is still not clear which proteins are involved in further folding of the chromatin fiber into metaphase chromosomes. To obtain a global view of the chromosomal proteins, we performed proteome analyses on three types of isolated human metaphase chromosomes. We first show the results from comparative proteome analyses of two types of isolated human metaphase chromosomes that have been frequently used in biochemical and morphological analyses. 209 proteins were quantitatively identified and classified into six groups on the basis of their known interphase localization. Furthermore, a list of 107 proteins was obtained from the proteome analyses of highly purified metaphase chromosomes, the majority of which are essential for chromosome structure and function. Based on the information obtained on these proteins and on their localizations during mitosis as assessed by immunostaining, we present a four-layer model of metaphase chromosomes. According to this model, the chromosomal proteins have been newly classified into each of four groups: chromosome coating proteins, chromosome peripheral proteins, chromosome structural proteins, and chromosome fibrous proteins. This analysis represents the first compositional view of human metaphase chromosomes and provides a protein framework for future research on this topic.     

Banding and spiralization of human metaphase chromosomes

Summary A new technique is described which produces spiralization of human metaphase chromosomes. The important feature is heat followed by trypsin treatment. By varying conditions, it is possible to produce bands, spirals and intermediate stages. This provides a new approach to the understanding of banding and chromosome structure.     

Occurrence of G-banding in metaphase chromosomes of Encarsia berlesei (Hymenoptera: Aphelinidae).

Well-defined G-bands were obtained on somatic metaphase chromosomes of Encarsia berlesei using trypsin and warm 2x SCC in sequence. The G-banded pattern allowed rapid identification of all five metacentric chromosomes, which appeared uniformly lighted when stained with DAPI fluorochrome dye. It is stressed that ageing affects G-banding in this insect species; in fact, good banded chromosomes were obtained on 1-month air-stored chromosomes. Evidence for asynchronous condensation on the chromosomes of this species is also provided.     

Quantitative studies on the arrangement of human metaphase chromosomes

Summary The spatial relationships between the homologous pairs of chromosomes in the normal human colcemid-treated metaphase plate were tested by two different mathematical approaches: (a) determination of the distances between the centromeres of the homologous chromosomes compared to the mean distance of all centromeres of the mitosis in question; (b) measuring the distances of the different chromosomes from the center of the mitosis.The following results were obtained: (1) The arrangement of human metaphase chromosomes does not follow a normal distribution; the distribution is narrower and taller, probably due to an impairment of free chromosome spreading by the cell membrane. We believe that only in membraneless mitotic cells should the chromosome-spread correspond to a normal distribution under the same preparation conditions. (2) There is a positive correlation between decreasing chromosome size and decreasing mean distance between homologous chromosomes. (3) A close positive correlation exists between increasing chromosome size and increasing distance to the barycenter of the mitosis. (4) There is also a close positive correlation between the distance of homologous chromosome pairs and their distance from the center of the mitosis, i.e., with increasing distance from the center of the mitosis, the distance between the homologous partners increases. (5) The following statistically significant deviations from these rules could be established: (a) The large acrocentric chromosomes are closer associated, as one would expect from their size, probably due to their participation in the nucleolus organization; (b) in the female cell one of the two X chromosomes has an extremely peripheral localization; the X chromosomes are furthest apart of all pairs of homologous chromosomes; (c) the chromosome pairs 6 and 8 are relatively close together in spite of their peripheral position, suggesting a truc close association of the homologus partners; (d) the chromosome pair 18 has a more peripheral position than expected, and a relatively large mean distance between the homologous partners; (e) the chromosome pair 1 has a much more central position and a closer association than is expected from its size.     

Quantitative studies on the arrangment of human metaphase chromosomes

Summary The pattern of association of acrocentric chromosomes was examined in ten and five carriers of a 15/21 and a 13/14 Robertsonian translocation, respectively, and was compared with that of the same numbers of relatives with normal karyotypes. In the carriers of 15/21 translocation, the number of large associations (involving more than two acrocentrics) and the association frequencies for individual acrocentric chromosomes, were significantly higher than in the control group. The mean number of associations of the single homologs of the translocation chromosomes was much higher than that of the other acrocentrics. In the carriers of 13/14 translocations, only the association frequency for chromosome 13 was higher than in the normal relatives. The uninvolved chromosomes homologous to those involved in translocations showed an insignificant increase in associations in comparison with the other acrocentrics. These results suggest that some mechanism within the cells compensates for the effect of missing acrocentrics or of acrocentrics lacking NORs on the number of associations. The possible relations of this phenomenon to the activity of the nucleolus organizing regions are discussed.     

Isolation of specific human metaphase chromosomes

The human karyotype can be subdivided into seven fractions containing specific chromosomes to provide material for recombinant DNA research. The isolated metaphase chromosomes are sorted according to size by velocity zonal centrifugation, and specific chromosome groups are further purified by electrostatic deflection in a flow microfluorometer. Rapid improvements in technology should soon provide preparations of single chromosomes.     

Semiconductor nanocrystal probes for human metaphase chromosomes

To improve signal stability and quantitation, an optically stable, novel class of fluorophore for hybridization analysis of human metaphase chromosomes is demonstrated. Detection of hybridization sites in situ was based on fluorescence from streptavidin-linked inorganic crystals of cadmium selenide [(CdSe)ZnS]. Fluorescence of nanocrystal fluorophores was significantly brighter and more photostable than organic fluorophores Texas Red and fluorescein. Thus, semiconductor nanocrystal fluorophores offer a more stable and quantitative mode of fluorescence in situ hybridization (FISH) for research and clinical applications.     

Chromatin organization and restriction endonuclease activity on human metaphase chromosomes

Human metaphase chromosomes were treated with HaeIII, HindIII, EcoRI, and AluI restriction endonucleases and subsequently stained with either Giemsa or ethidium bromide. The results obtained seemed to suggest that the structural organization of specific chromosome regions can play a primary role in determining the cytological effect after digestion with specific restriction endonucleases.     

Distribution of human chromosomes on the metaphase plate using banding techniques

Summary This study deals with the problem of distribution of the 46 centromeres on the human metaphase plate after treatment with colchicine and hypotonic shock.The location of the centromeres was recorded for 400 metaphases in which the chromosomes were identified by bands.A quantitative analysis of chromosome distribution ascertains the absence of proximities between homologous chromosomes. The already known ones between acrocentric chromosomes are found at a very high level. The nature and intensity of these proximities vary from one sample to another as is the case between heterologues.A three-dimensional graphic technique is proposed to summarize all of the interchromosome proximities.     

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.     

DNA catenation maintains structure of human metaphase chromosomes

Mitotic chromosome structure is pivotal to cell division but difficult to observe in fine detail using conventional methods. DNA catenation has been implicated in both sister chromatid cohesion and chromosome condensation, but has never been observed directly. We have used a lab-on-a-chip microfluidic device and fluorescence microscopy, coupled with a simple image analysis pipeline, to digest chromosomal proteins and examine the structure of the remaining DNA, which maintains the canonical ‘X’ shape. By directly staining DNA, we observe that DNA catenation between sister chromatids (separated by fluid flow) is composed of distinct fibres of DNA concentrated at the centromeres. Disrupting the catenation of the chromosomes with Topoisomerase IIα significantly alters overall chromosome shape, suggesting that DNA catenation must be simultaneously maintained for correct chromosome condensation, and destroyed to complete sister chromatid disjunction. In addition to demonstrating the value of microfluidics as a tool for examining chromosome structure, these results lend support to certain models of DNA catenation organization and regulation: in particular, we conclude from our observation of centromere-concentrated catenation that spindle forces could play a driving role in decatenation and that Topoisomerase IIα is differentially regulated at the centromeres, perhaps in conjunction with cohesin.