Quantitative assessment of human chromosomal polymorphism with regard to paracentromeric heterochromatin

The measurement of C-segment length in chromosomes 1, 9 and 16 of 7 individuals was carried out. The regression analysis was employed to study a change of the C-segment sizes in the process of mitotic chromosome condensation. Typical values of C-segment length for chromosomes 1, 9 and 16 are about 1.4, 1.1 and 0.8mu respectively. Among 7 individuals there was no two which had identical size of C-segments for all three chromosomes studied. In six individuals heteromorphysm of C-segments was revealed. It was found that visually detected heteromorphysm may be expressed quantitatively as ratio length of C-segments in homologous chromosomes.     

Comparative study of methods for the quantitative assessment of the C-segment size of human chromosomes

The possibilities of comparison and reproducibility of results of estimation of the absolute dimensions of chromosomal C-segments measured by different methods have been studied. The data obtained indicate good comparability of the results obtained by all the methods in a definite range of chromosome condensation. All the methods demonstrated satisfactory reproducibility of the results on chromosomes 1 and 9. The errors of the quantitative estimation of chromosome 16 in the coupled cultures is discussed in view of the artefact nature of C-segment size variability.     

Variability of the C-segment sizes of chromosomes 1, 9, 16 and Y in the human chromosome set]

The investigation of chromosome polymorphism by quantitative methods is a rather hard task. The manual method for measuring C-segments of chromosomes 1, 9, 16 and Y in man is suggested, which is not difficult, being reasonably precise for the population research. Metaphases of the average level of chromosome condensation were taken for analysis. Only the C-segments were measured without measuring chromosomes. The negative chromosome image was 4000-fold magnified, compared to the chromosome natural size, and the boundaries of C-segments of each chromosome were five-fold dotted on a sheet of paper specially printed for this purpose. C-segments were measured by magnifying glass with 0.025 mcm scale unit. For every individuum, C-segments were measured in 5-7 cells only. The data are presented on the estimation of measurement errors and on individual (intercellular) and population (interindividual) variations of C-segments of chromosomes.     

The quantitative analysis of polymorphism on human chromosomes 1, 9, 16 and Y

Summary The generalized characteristic of the C-segment lengths on chromosomes 1, 9, 16, and Y is suggested for a study of population heterogeneity. For this purpose, the concept of the distance D is introduced, taking into account the individual C-segment lengths, the mean lengths and standard deviations of C-segment lengths in a group of subjects, as well as the coefficients of correlation of the C-segment lengths on the said chromosomes.It is demonstrated that distance D may be employed to study the relevance of the given subject to the group studied, the relation to the mean characteristics within the group, and selection of subjects' pairs with almost identical C-segment lengths on respective chromosomes.In the study of such problems as zygosity of twins, family analysis, etc., along with the absolute C-segment lengths, it is recommended to employ the relative C-segment lengths on chromosomes 1, 9, 16, and Y, calculated as a part of the sum total of their absolute lengths.     

C-polymorphism of chromosomes in men with azoospermia

Comparative evaluation of absolute C-segment lengths of chromosomes 1, 9, 16 and Y in 50 azoospermic males has revealed significant differences in chromosome 9 between 50 normal males. These results are considered as nonrandom in pathology of male gametogenesis.     

Differential condensation of human chromosomes 9 and Y

Some differences were observed in the mitotic condensation of regions composing human chromosomes 9 and Y: regions 9p, 9h and Y nf are characterized by an intense condensation by the end of the spiralization interval studied (the length of the repair chromosome 3 varying from 5.4 to 2.9 mkm). At the same time, the condensation of regions 9q-h (region 9q without heterochromatic block) is slowing in the initial spiralization interval (the length of chromosome 3 varying from 16.6 to 5.5 mkm). The Yf-block of Y-chromosome is condensing faster than nf-region. The condensation parameters of Q-heterochromatic blocks are most variable while the euchromatic regions are most stable. The dynamics of 9h and of f-block condensation are independent within one karyotype. Based on the data obtained we doubt the correctness of studies on linear dimensions of the constitutive heterochromatin blocks for the evaluation of its quantity in the karyotype. A possible association of differential mitotic condensation with the chromosome segregation disturbances is discussed.     

C-polymorphism of chromosomes 1, 9, 16 and Y in newborn infants of various gestational ages

Comparative evaluation of absolute C-segment lengths of chromosomes 1, 9, 16 and Y in new-born children of different gestational age has revealed no significant differences in their value between individuals with unfinished intrauterine development and those born in time.     

C-banding and non-homologous associations in Gryllus argentinus

A comparative study of C-banded mitotic and meiotic chromosomes of Gryllus argentinus (Gryllidae) is reported. Improved cytological procedures were followed to establish karyotypes and to detect C-segments. Twenty-eight autosomes plus a sexual system XX, XO were found. Terminal C-heterochromatin in both arms and paracentric segments were detected in most of the chromosomes of the complement. Microdensitometric tracings confirmed the distribution of C-banded segments. Manifold connections through condensed terminal chromomeres were observed at pachytene occurring between two or more bivalents during meiosis. These heterologous associations involved the whole karyotype. End-to-end pachytene associations reacted intensely to the C-procedure. C-segments detected at diakinesis allowed the measurement of the centromere indices of bivalents which resulted in a more precise identification of given chromosome pairs. The relationship of the presence of terminal heterochromatin in mitotic chromosomes, the end-to-end associations through C-segments, the attachment of pachytene filaments to the nuclear membrane and their molecular implications is discussed.     

Chromosome condensation in mitosis and meiosis of rye (Secale cereale L.)

Structural investigation and morphometry of meiotic chromosomes by scanning electron microscopy (in comparison to light microscopy) of all stages of condensation of meiosis I + II show remarkable differences during chromosome condensation in mitosis and meiosis I of rye (Secale cereale) with respect to initiation, mode and degree of condensation. Mitotic chromosomes condense in a linear fashion, shorten in length and increase moderately in diameter. In contrast, in meiosis I, condensation of chromosomes in length and diameter is a sigmoidal process with a retardation in zygotene and pachytene and an acceleration from diplotene to diakinesis. The basic structural components of mitotic chromosomes of rye are "parallel fibers" and "chromomeres" which become highly compacted in metaphase. Although chromosome architecture in early prophase of meiosis seems similar to mitosis in principle, there is no equivalent stage during transition to metaphase I when chromosomes condense to a much higher degree and show a characteristic "smooth" surface. No indication was found for helical winding of chromosomes either in mitosis or in meiosis. Based on measurements, we propose a mechanism for chromosome dynamics in mitosis and meiosis, which involves three individual processes: (i) aggregation of chromatin subdomains into a chromosome filament, (ii) condensation in length, which involves a progressive increase in diameter and (iii) separation of chromatids.     

Shaping the metaphase chromosome: coordination of cohesion and condensation

Recent progress in our understanding of mitotic chromosome dynamics has been accelerated by the identification of two essential protein complexes, cohesin and condensin. Cohesin is required for holding sister chromatids (duplicated chromosomes) together from S phase until the metaphase-to-anaphase transition. Condensin is a central player in chromosome condensation, a process that initiates at the onset of mitosis. The main focus of this review is to discuss how the mitotic metaphase chromosome is assembled and shaped by a precise balance between the cohesion and condensation machineries. We argue that, in different eukaryotic organisms, the balance of cohesion and condensation is adjusted in such a way that the size and shape of the resulting chromosomes are best suited for their accurate segregation.     

Mechanisms of chromosome banding

Photo-oxidation of mitotic human chromosomes has been used in conjunction with anti-cytosine and anti-adenosine antibodies to produce R-banding. To elucidate the mechanism of this banding procedure we have examined the effect of photo-oxidation alone on chromosomes and nuclei. With short exposures to light in the presence of dilute methylene blue, C-band areas on chromosomes 1, 9, 16 and the terminal segment of the Y stain poorly. We call this phenomena reverse C-banding. After 18 h of exposure to light the chromosomes are swollen and show very little staining with quinacrine or Giemsa. Quantitative autoradiography shows that their DNA is almost completely extracted. Cytophotometric measurements also confirm that nuclear DNA is progressively extracted according to the length of exposure to light. When chromosomes are exposed to dilute methylene blue alone, without light, G-banded chromosomes result. We suggest the following explanation for these observations. In dilute methylene blue, C-band regions take up the greatest amount of dye and after short periods of photo-oxidation the DNA of these regions is preferentially destroyed resulting in reverse C-banding. Autoradiography in photo-oxidized chromosomes suggested that this preferential destruction of C-segments occurred in our experiments. With more prolonged exposure the DNA of the G-bands regions is preferentially destroyed and staining the remaining DNA with sensitive fluorescent labeled anti-C antibodies results in R-banding.     

Analysis of the inheritance of heterochromatic regions in human chromosomes 1, 9, 16 and Y

The inheritance of heterochromatic regions of chromosomes 1, 9, 16 and Y was studied in twelve families by means of measuring their C-segments. Maternal and paternal origin of chromosomes 1, 9 and 16 in the child was determined by two methods. The advantages and disadvantages of these methods and possibilities of their application are under discussion.     

C-band length variability and reproductive wastage

Summary The possible influence of total Y chromosome length and the C-band size variability of chromosomes 1, 9, 16, and Y, on reproductive wastage was investigated. One hundred couples with recurrent reproductive wastage and 106 control couples with at least two healthy children and no miscarriages were cytogenetically studied. Total Y chromosome length was evaluated as the Y/F index and the C-band size was analyzed quantitatively according to the linear measurement method of Baliek et al. (1977). The different degrees of mitotic contraction were corrected on the basis of the linear correlation found between heterochromatin and euchromatin length. Statistical comparison between results of Y chromosome from both samples demonstrated, in the test group, an increase in the mean value of the Y/F index, but the increase of Y C-band length did not reach significance. In addition mean values of C-band length on chromosomes 1, 9, and 16 in couples from the test group and especially those who had had two or more abortions, were lower than those in the controls. Among the latter the frequency of chromosomes included in the category of very large heterochromatin size is higher. However these length differences have been demonstrated only in specific subgroups, and in each one for a different chromosome. Our results indicated that Y chromosome length as well as C-band size variabilities are not directly related to reproductive wastage.     

Evidence of activity-specific, radial organization of mitotic chromosomes in Drosophila

The organization and the mechanisms of condensation of mitotic chromosomes remain unsolved despite many decades of efforts. The lack of resolution, tight compaction, and the absence of function-specific chromatin labels have been the key technical obstacles. The correlation between DNA sequence composition and its contribution to the chromosome-scale structure has been suggested before; it is unclear though if all DNA sequences equally participate in intra- or inter-chromatin or DNA-protein interactions that lead to formation of mitotic chromosomes and if their mitotic positions are reproduced radially. Using high-resolution fluorescence microscopy of live or minimally perturbed, fixed chromosomes in Drosophila embryonic cultures or tissues expressing MSL3-GFP fusion protein, we studied positioning of specific MSL3-binding sites. Actively transcribed, dosage compensated Drosophila genes are distributed along the euchromatic arm of the male X chromosome. Several novel features of mitotic chromosomes have been observed. MSL3-GFP is always found at the periphery of mitotic chromosomes, suggesting that active, dosage compensated genes are also found at the periphery of mitotic chromosomes. Furthermore, radial distribution of chromatin loci on mitotic chromosomes was found to be correlated with their functional activity as judged by core histone modifications. Histone modifications specific to active chromatin were found peripheral with respect to silent chromatin. MSL3-GFP-labeled chromatin loci become peripheral starting in late prophase. In early prophase, dosage compensated chromatin regions traverse the entire width of chromosomes. These findings suggest large-scale internal rearrangements within chromosomes during the prophase condensation step, arguing against consecutive coiling models. Our results suggest that the organization of mitotic chromosomes is reproducible not only longitudinally, as demonstrated by chromosome-specific banding patterns, but also radially. Specific MSL3-binding sites, the majority of which have been demonstrated earlier to be dosage compensated DNA sequences, located on the X chromosomes, and actively transcribed in interphase, are positioned at the periphery of mitotic chromosomes. This potentially describes a connection between the DNA/protein content of chromatin loci and their contribution to mitotic chromosome structure. Live high-resolution observations of consecutive condensation states in MSL3-GFP expressing cells could provide additional details regarding the condensation mechanisms.     

Disturbance in function and expression of condensin affects chromosome compaction in HeLa cells

Condensin, a major non-histone protein complex on chromosomes, is responsible for the formation of rod-shaped chromosome in mitosis. A heterodimer composed of SMC2 (structural maintenance of chromosomes) and SMC4 subunits constitutes the core part of condensin. Although extensive studies have been done in yeast, fruit fly and Xenopus to uncover the mechanisms and molecular nature of SMC proteins, little is known about the complex in mammalian cells. We have conducted a series of experiments to unveil the nature of condensin complex in human chromosome formation. The results show that overexpression of the C-terminal domain of SMC subunits disturbs chromosome condensation, leading to formation of swollen chromosomes, while knockdown of SMC subunits severely disturbs mitotic chromosome formation, resulting in chromatin bridges between daughter cells and multiple nuclei in single cells. The salt extraction assay indicates that a fraction of the condensin complex is bound to chromatin in interphase, but most of the condensin bind to chromatin at the onset of mitosis. Thus, disturbance in condensin function or expression affects chromosome condensation and influences mitotic progression.     

Mitotic stability of yeast chromosomes: a colony color assay that measures nondisjunction and chromosome loss

A colony color assay that measures chromosome stability is described and is used to study several parameters affecting the mitotic maintenance of yeast chromosomes, including ARS function, CEN function, and chromosome size. A cloned ochre-suppressing form of a tRNA gene, SUP11, serves as a marker on natural and in vitro-constructed chromosomes. In diploid strains homozygous for an ochre mutation in ade2, cells carrying no copies of the SUP11 gene are red, those carrying one copy are pink, and those carrying two or more copies are white. Thus, the degree of red sectoring in colonies reflects the frequency of mitotic chromosome loss. The assay also distinguishes between chromosome loss (1:0 segregation) and nondisjunction (2:0 segregation). The most dramatic effect on improving mitotic stability is caused by increasing chromosome size. Circular chromosomes increase in stability through a size range up to approximately 100 kb, but do not continue to be stabilized above this value. However, linear chromosomes continue to increase in mitotic stability throughout the size range tested (up to 137 kb). It is possible that the mitotic stability of linear chromosomes is proportional to chromosome length, up to a plateau value that has not yet been reached in our synthetic constructions.     

Deacetylation and methylation at histone H3 lysine 9 (H3K9) coordinate chromosome condensation during cell cycle progression

Interphasic chromatin condenses into the chromosomes in order to facilitate the correct segregation of genetic information. It has been previously reported that the phosphorylation and methylation of the N-terminal tail of histone H3 are responsible for chromosome condensation. In this study, we demonstrate that the deacetylation and methylation of histone H3 lysine 9 (H3K9) are required for proper chromosome condensation. We confirmed that H3K9ac levels were reduced, whereas H3K9me3 levels were increased in mitotic cells, via immunofluorescence and Western blot analysis. Nocodazole treatment induced G2/M arrest but co-treatment with TSA, an HDAC inhibitor, delayed cell cycle progression. However, the HMTase inhibitor, AdoX, had no effect on nocodazole-induced G2/M arrest, thereby indicating that sequential modifications of H3K9 are required for proper chromosome condensation. The expression of SUV39H1 and SETDB1, H3K9me3-responsible HMTases, are specifically increased along with H3K9me3 in nocodazole-arrested buoyant cells, which suggests that the increased expression of those proteins is an important step in chromosome condensation. H3K9me3 was highly concentrated in the vertical chromosomal axis during prophase and prometaphase. Collectively, the results of this study indicate that sequential modifications at H3K9 are associated with correct chromosome condensation, and that H3K9me3 may be relevant to the condensation of chromosome length.     

Heterochromatic regions of human chromosomes 1, 9, 16 and Y and the phenotype

The relationship between variability of the heterochromatic regions of chromosomes 1, 9, 16, Y and the anthropometric characteristics (the height, the biacromial diameter and weight) was studied in two groups of children; 70 children had embryopathies of unknown etiology and 40 children had the Down syndrome. The positive statistically significant correlation of the C-segments lengths of chromosomes 1, 9, 16, their sum included, and above characteristics was found. The correlation coefficients of Y-chromosome were non-significant. The problems of functional role of the structural heterochromatin and its influence on viability and physical development of the organism are discussed.     

Distinct roles of the Drosophila ninaC kinase and myosin domains revealed by systematic mutagenesis

We have investigated the role of topoisomerase II (topo II) in mitotic chromosome assembly and organization in vitro using Xenopus egg extracts. When sperm chromatin was incubated with mitotic extracts, the highly compact chromatin rapidly swelled and concomitantly underwent local condensation. Further incubation induced the formation of entangled thin chromatin fibers that eventually resolved into highly condensed individual chromosomes. This in vitro system made it possible to manipulate mitotic chromosomes in their assembly condition without any isolation or stabilization steps. Two complementary approaches, immunodepletion and antibody blocking, demonstrated that topo II activity is required for chromosome assembly and condensation. Once condensation was completed, however, blocking of topo II activity had little effect on the chromosome morphology. Immunofluorescent studies showed that topo II was uniformly distributed throughout the condensed chromosomes and was not restricted to the chromosomal axis. Surprisingly, all detectable topo II molecules were easily extracted from the chromosomes under mild conditions where the shape of chromosomes was well preserved. Our results show that topo II is essential for mitotic chromosome assembly, but does not play a scaffolding role in the structural maintenance of chromosomes assembled in vitro. We also present evidence that changes of DNA topology affect the distribution of topo II in mitotic chromosomes in our system.     

Application of ethidium bromide for high-resolution banding analysis of chromosomes from human malignant cells

Ethidium bromide was added to cultured human leukemic bone marrow and solid tumor cells to evaluate its inhibitory effect on mitotic chromosome condensation and its possible application to high-resolution banding analysis. In most experiments ethidium bromide treatment resulted in a high proportion of mitotic cells having elongated chromosomes, without remarkable reduction in either the mitotic index or quality of metaphase chromosomes. Optimal effect on chromosome length was obtained by adding 10 micrograms/ml of ethidium bromide during the final 2 hr of culture. Because of the simplicity and reproducibility of the technique involved, ethidium bromide can be used routinely to extend the length of chromosomes for fine-banding analysis of malignant cells.