Possible mechanisms of the occurrence of chromosome restructurings. IV. Chromosome restructurings in spontaneous mutagenesis

An attempt was undertaken to modify the spontaneous mutation process by varying its conditions in somatic cells of different species and tissues. The rate of chromosome aberrations and their types were studied in anaphase and metaphase. Under normal conditions, chromosome breaks were only found to occur. Breakage of chromosomes occurs during interphase, and as a result, acentric fragments are located outside the equatorial plate during metaphase. This process of chromosome breakage leads to elimination of some genetic material, without concomitant exchanges, and therefore, it has been named "elimination" process. Spontaneous chromosome mutagenesis manifesting itself at cytogenetic level was concluded to be an elimination process directed to elimination of a portion of chromatin from chromosomes. When the conditions of spontaneous mutagenesis are altered, in particular, by cardiovascular diseases in man, by partial inhibition of DNA repair in mice and pea cells, by transformation of Chinese hamster cells, upon ageing of pea seeds-qualitative changes in the chromosomal aberrations are registered, connected with the appearance of chromosome exchanges and acentric fragments situated within the equatorial plate during metaphase. These two types of chromosome aberrations are proposed to be considered as new criteria of pathology. A system of processes was suggested to exist, preventing the appearance of aberrations during mitosis, and it is supposed to be one of the most significant homeostatic systems.     

Radiosensitivity of somatic cells and imaginal disks of male and female Drosohila]

Primary chromosome damages as well as the frequency of spontaneous and X-rays induced chromosome aberrations in Drosophila melanogaster males and females are studied. It is found using cytofluorimetric method that primary chromosome damages in ganglia cells of females and males are the same. In these cells as well as in cells of imaginal discs the frequency of induced chromosome aberrations, except gaps, is considerably higher for females. Ganglia cells of females and males of Drosophila are found not to differ from each other in their proliferation activity. The frequency of morphoses for both sexes is also the same. The assumption is made concerning the role of the non-identical repair in the increased mutability of female somatic cells, which is more intensive in this sex, as well as concerning more intensive identical repair in imaginal discs of females.     

Analysis of the Chromosome Aberrations Induced by X-Rays in Somatic Cells of DROSOPHILA MELANOGASTER

A technique has been perfected for enabling good microscope preparations to be obtained from the larval ganglia of Drosophila melanogaster. This system was then tested with X-rays and an extensive series of data was obtained on the chromosome aberrations induced in the various stages of the cell cycle.-The analysis of the results obtained offers the following points of interest: (1) There exists a difference in radio-sensitivity between the two sexes. The females constantly display a greater frequency of both chromosome and chromatid aberrations. They also display a greater frequency of spontaneous aberrations. (2) In both sexes the overall chromosome damage is greater in cells irradiated in stages G(2) and G(1). These two peaks of greater radiosensitivity are produced by a high frequency of terminal deletions and chromatid exchanges and by a high frequency of dicentrics, respectively. (3) The aberrations are not distributed at random among the various chromosomes. On the average, the Y chromosome is found to be more resistant and the breaks are preferentially localized in the pericentromeric heterochromatin of the X chromosome and of the autosomes. (4) Somatic pairing influences the frequency and type of the chromosome aberrations induced. In this system, such an arrangement of the chromosomes results in a high frequency of exchanges and dicentrics between homologous chromosomes and a low frequency of scorable translocations. Moreover, somatic pairing, probably by preventing the formation of looped regions in the interphase chromosomes, results in the almost total absence of intrachanges at both chromosome and chromatid level.     

Suppression of spontaneous and mitomycin C-induced chromosome aberrations in Fanconi's anemia by cell fusion with normal human fibroblasts

Summary The high rate of spontaneous and mitomycin C-induced chromosome aberrations in Fanconi's anemia fibroblasts is fully corrected after euploid somatic cell hybridization with normal human fibroblasts.     

The influence of a substrate including extracellular matrix proteins on karyotypic variability in two cell lines of Indian muntjac skin fibroblasts

The influence of cell-culture conditions on numerical and structural karyotypic variability has been investigated in two Indian muntjac skin fibroblast “markerless” cell lines, M and MT. The cells were cultivated on a substrate consisting of extracellular matrix proteins (ECMs) synthesized by human mesenchymal stem cells (SC5-MSC). The character of cell distribution for the chromosome number of the cell line M changed after cultivation for 1 and 4 days as compared to control cells, which were cultured on a hydrophilic surface without ECM coating. These changes involve a significant decrease in frequency of cells with the modal numbers of chromosomes and an increase in frequency of cells with lower chromosome numbers. Many new types of additional structural variants of the karyotype (SVK) appear. The MT cell line, differing from M line in the number of homologous chromosomes, exhibited a character of cell distribution similar to that of the M line for the chromosome number for only 1 day after cultivation on the ECM substrate, but not after 4 days under the same culture conditions, when no difference from the control cells was observed. Further cultivation of MT cells for 8 days did not change the character of cell distribution for the chromosome number relative to the control variant. The observed alterations seem to be due to disturbances in the correct chromosome-segregation process, which were caused by an abrupt shift in the cell-culture conditions. Analysis of the structural karyotypic variability revealed a significant increase in frequency of chromosomal aberrations in the M cell line for 1 and 4 days in culture on the ECM substrate as compared to the control cells. The frequency of dicentric chromosomes (telomeric associations) was increased and constituted more than 50% of all chromosome aberrations. No increase in frequency of chromosome aberrations was observed for MT cells cultured under the same conditions. It can be suggested that the differing by the karyotypic structure, but the genetically identical cell lines have different response to the substrate. In contrast to the M line, in the MT line, a fast normalization of numerical karyotypic characteristics and no enhancement of structural karyotypic variability takes place. This provides a possibility to cultivate an MT cell on the given protein substrate while maintaining a balanced karyotypic structure characteristic of MT cell line.     

Radiosensitivity of chromosomes in lymphocytes from Down's syndrome patients

A study was made of the yield of chromosome aberrations in gamma-irradiated G0 peripheral blood lymphocytes from 6 patients with different forms of Down's syndrome. The doses used were from 0.25 to 3.0 Gy. Seven healthy donors of different age made the control group. There was a significant increase in the yield of chromosome exchanges in lymphocytes from all the patients as compared to control. The spontaneous level of chromosome aberrations and the frequency of radiation-induced fragments did not differ from the control values. The yield of exchanges in diploid and trisomic cells from patients with the mosaic form of Down's syndrome did not change significantly as the time of cultivation was raised. The origin of DNA repair defects leading to the increased chromosome radiosensitivity in Down's syndrome is discussed.     

The rate of sister chromatid exchanges parallel to spontaneous chromosome breakage in Fanconi's anemia and to trenimon-induced aberrations in human lymphocytes and fibroblasts.

The incidence of structural chromosome aberrations and the rate of sister chromatid exchanges (SCE) was investigated in lymphocyte cultures from a patient with typical Fanconi's anemia and his parents. The rate of SCEs was found to be normal. In experiments with the alkylating agent Trenimon the SCE rates proved to be a sensitive indicator for the induction of structural aberrations: in presence of an induced aberration rate half as high as the spontaneous rate in the Fanconi's anemia case, the rate of SCEs was found to be quintupled. Dose-effect relationships for the induction of SCE rates by Trenimon were studied over a wide dose range in lymphocyte and fibroblast cultures. The results reflect the same difference in sensitivity earlier observed in the induction of structural chromosome aberrations, fibroblasts being far more sensitive.     

Radiosensitive mutants of Drosophila. VI. The effect of ultraviolet rays and methylmethane sulfonate on the viability and incidence of chromosome aberrations in the somatic cells of mutant mus(2)201G1

The mus(2)201G1 mutation determining high sensitivity to UV-rays and methyl methansulfonate (MMS) has been studied. The larvae of Drosophila of different age were treated with UV-rays and MMS. Lethality of organisms during the larvae and the pupa stages of the development, as well as the frequency of spontaneous and induced chromosome aberrations were registered. The mus(2)201G1 mutation was shown to determine high lethality of Drosophila during larvae and pupa stages as well as a high frequency of spontaneous and induced chromosome aberrations. The conclusion was made that chromosome aberrations are not the single reason for the death of the mutant flies after mutagenic treatment and that the function of the mus(2)201G1 gene is necessary for divided and undivided cells.     

Relative ranking of culture media based on proliferation kinetics and spontaneous chromosomal aberrations in PHA-responsive human peripheral blood lymphocytes.

Proliferation kinetics and spontaneous yield of chromosomal aberrations phytohemagglutinin (PHA)-responsive peripheral blood lymphocytes were studied from blood samples collected from 45 individuals in 4 different synthetic media. Except for a significant difference for Eagle's MEM and RPMI 1640, the other media did not show difference for the yield of chromatid or chromosome type of aberrations. Differences were however noticed in the proliferation kinetics (mitotic and proliferative rate indices) of cells among the media used. The study indicated that (i) the intrinsic properties of media which influence proliferation rate and yield of chromosomal aberrations are independent of each other as higher proportion of first division cells do not correspond with higher frequency of chromosomal aberrations, (ii) the amount of free-radical scavengers present in the medium, apart from the genetic make-up of the individuals, may contribute to the spontaneous yield of chromosomal aberrations and (iii) RPMI 1640 medium, which showed higher transformation and faster cycling rate for the lymphocytes, may be considered as medium of choice for analysing two main cytogenetic end-points, chromosomal aberrations and sister chromatid exchanges (SCEs).     

Relationship between environmental pollution and genetic monitoring of human populations

The basis of genetic monitoring is the knowledge of laws of the spontaneous mutation process. These laws are determined for human chromosome and genome mutations by cytogenetic examination of newborns, infants with congenital defects, and the material of spontaneous abortions. Confidence intervals and all the necessary sample sizes were calculated when registering the mutagenic effects of different intensity in the general population as well as to the groups of closer contact with mutagens. Such calculations were made for controlling the spontaneous mutation process in lymphocytes of human peripheral blood on the basis of registering chromosome aberrations.     

The effect of immobilized fibronectin on karyotypic variability in the skin fibroblast cell subline of indian muntjac

The numerical and structural karyotypic variability has been investigated in the Indian muntjac skin fibroblast cell subline MT on cultivating cells on the fibronectin-coated surface. In cell subline MT, cultivated on the fibronectin-coated surface for 1 and 2 days, the character of cell distribution for the chromosome number did not change. In 3, 4 and 8 days, the character of cell distribution for the chromosome number changed. These changes involve a significant decrease in frequency of cells with modal numbers of chromosomes, and an increase in frequency of cells with lower chromosome numbers. Many new additional structural variants of the karyotype (SVK) appear. The observed alterations seem to be due to both disturbances of mitotic apparatus and selection of SVK, which are more advantageous to changed culture conditions of the cell population. Detachment of cells from the fibronectin-coated surface, followed by a 1 day cultivation on a hydrophilic surface, commonly used for routine cell cultivation, does not restore the control cell distribution for the chromosome number, but cultivation in these conditions for 5 days restore control distribution. The frequency of chromosomal aberrations on cultivation on the fibronectin-coated surface for 3 and 4 days significantly increases, mainly at the expence of dicentrics (telomeric association). On prolongating the time of cultivation up to 8 days on the fibronectin-coated surface the frequency of chromosomal aberrations approaches the control value. Structural instability of chromosomes at cultivation on the fibronectin-coated surface demonstrates nonspecific reaction of "markerless" cell lines to unfavourable factors of the environment. We discuss possible reasons of differences in the character of karyotypic variability in cell lines of the Indian muntjac skin fibroblasts on cultivating on laminin and fibronectin.     

Classification of spontaneous genotyping cell adaptation

Dependence of spontaneous frequency of chromosome aberrations in the lymphocytes of peripheral human blood on biological age are presented. Obtained results allow one to consider the cytogenetic effects in inter-relation with biological age as indexes of adaptational possibilities of the organism. There are four periods of genotypic cell adaptation from newborn up to 100 years old distinguishing in the average frequency of chromosome aberrations and the number of aberrant cells, their distribution and spectrum as well.     

Report on the Eleventh International Workshop on the Identification of Transcribed Sequences 2001. November 9-11, 2001. Washington, DC, USA

Glioblastoma multiforme (GBM) is characterized by intratumoral heterogeneity as to both histomorphology and genetic changes, displaying a wide variety of numerical chromosome aberrations the most common of which are monosomy 10 and trisomy 7. Moreover, GBM in vitro are known to have variable karyotypes within a given tumor cell culture leading to rapid karyotype evolution through a high incidence of secondary numerical chromosome aberrations. The aim of our study was to investigate to what extent this mitotic instability of glioblastoma cells is also present in vivo. We assessed the spatial distribution patterns of numerical chromosome aberrations in vivo in a series of 24 GBM using two-color in situ hybridization for chromosomes 7/10, 8/17, and 12/18 on consecutive 6-microm paraffin-embedded tissue slides. The chromosome aberration patterns were compared with the histomorphology of the investigated tumor assessed from a consecutive HE-stained section, and with the in vitro karyotype of cell cultures established from the tumors. All investigated chromosomes showed mitotic instability, i.e., numerical aberrations within significant amounts of tumor cells in a scattered distribution through the tumor tissue. As to chromosomes 10 and 17, only monosomy occurred, as to chromosome 7 only trisomy/polysomy, apparently as a result of selection in favor of the respective aberration. Conversely, chromosomes 8, 12, and 18 displayed scattered patterns of monosomy as well as trisomy within a given tumor reflecting a high mitotic error rate without selective effects. The karyotypes of the tumor cell cultures showed less variability of numerical aberrations apparently due to clonal adaptation to in vitro conditions. We conclude that glioblastoma cells in vivo are characterized by an extensive tendency to mitotic errors. The resulting clonal diversity of chromosomally aberrant cells may be an important biological constituent of the well-known ability of glioblastomas to preserve viable tumor cell clones under adaptive stress in vivo, in clinical terms to rapidly recur after antitumoral therapy including radio- or chemotherapy.     

An improved procedure for the cultivation and in situ chromosome preparation of monolayer cell cultures

A method for the cultivation of monolayer cell cultures on microslides in quadruple culture dishes together with a simple procedure for in situ chromosome preparation are described. The cells fixed to the slide can be stained according to standard procedures and analysed microscopically. The method is simple, rapid and reliable and provides many advantages especially for cytogenetic diagnostics with fibroblasts and amniotic fluid cells. It simplifies the performance of cytogenetic mutagenicity testing with primary cultures and permanent cell lines, e.g. the analysis of chromosome aberrations, sister chromatid exchanges (SCEs) and induced aneuploidy, as well as large-scale cytogenetic experiments.     

Results of a cytogenetic study of children from radionuclide-contaminated goiter endemic zone of the Rivno region of Ukraine

Under the conventional cytogenetical examination of 6 different children groups (with and without non-stohastic thyroid pathology, exposed and nonexposed to the iodine isotopes in 1986) from the goiter endemic zone of Ukraine which belongs to the territory contaminated by 137Cs radionuclides, the identical to the spontaneous level of somatic chromosome mutagenesis of the last decade in all observed groups with the tendency to increasing of stable aberrations in some persons had been established.     

Tissue-specific placental mosaicism for autosomal trisomies in spontaneous human abortuses: mechanisms of formation and phenotypic effects]

The frequencies of autosomal trisomies in extraembryonic human tissues were estimated in the cases of different abnormalities of prenatal development, from the confined placental mosaicism (CPM) with either relatively normal embryogenesis or restricted intrauterine growth to spontaneous abortion. A tissue-specific compartmentalization was found to be characteristic of cell lines with trisomies for individual autosomes. Analysis of various phenotypical effects of chromosomal aberrations associated with mosaicism is necessarily required to understand the mechanisms and factors responsible for tissue chromosomal mosaicism. Based on analysis of the cell karyotype during prenatal diagnosing of chromosome aberrations in tissues of both extraembryonic and embryonic origin, in 1996, Wolstenholme proposed a model of CPM for individual chromosomes. According to the model, the distribution of cell lines with autosomal trisomies between extraembryonic tissues depends on the ratio between meiotic and mitotic mutations early in embryonic development. However, the model cannot be used to study tissue chromosomal mosaicism in spontaneous abortions, because little information is available on cell karyotype in embryonic tissues themselves after intrauterine fetal death. In this work, a model of tissue-specific chromosomal mosaicism was suggested based on the data on cell karyotype determined in extraembryonic tissues alone, which can be helpful in evaluating the contribution of tissue chromosomal differences into the etiology of early intrauterine death. Along with the experimental evidence, comparative analysis of the two models indicated that the meiotic chromosome nondisjunction plays the major role in trisomy formation and the resultant spontaneous arrest of embryonic development. Other factors responsible for tissue-specific distribution of chromosomal aberrations are also discussed. These are differences in cell proliferative activity, as well as changes in compartmentalization and migration of cells with abnormal karyotypes.     

Tissue-Specific Placental Mosaicism for Autosomal Trisomies in Human Spontaneous Abortuses: Mechanisms of Formation and Phenotypical Effects

The frequencies of autosomal trisomies in extraembryonic human tissues were estimated in the cases of different abnormalities of prenatal development, from the confined placental mosaicism (CPM) with either relatively normal embryogenesis or restricted intrauterine growth to spontaneous abortion. A tissue-specific compartmentalization was found to be characteristic of cell lines with trisomies for individual autosomes. Analysis of various phenotypical effects of chromosomal aberrations associated with mosaicism is necessarily required to understand the mechanisms and factors responsible for tissue chromosomal mosaicism. Based on analysis of the cell karyotype during prenatal diagnosing of chromosome aberrations in tissues of both extraembryonic and embryonic origin, in 1996, Wolstenholme proposed a model of CPM for individual chromosomes. According to the model, the distribution of cell lines with autosomal trisomies between extraembryonic tissues depends on the ratio between meiotic and mitotic mutations early in embryonic development. However, the model cannot be used to study tissue chromosomal mosaicism in spontaneous abortions, because little information is available on cell karyotype in embryonic tissues themselves after intrauterine fetal death. In this work, a model of tissue-specific chromosomal mosaicism was suggested based on the data on cell karyotype determined in extraembryonic tissues alone, which can be helpful in evaluating the contribution of tissue chromosomal differences into the etiology of early intrauterine death. Along with the experimental evidence, comparative analysis of the two models indicated that the meiotic chromosome nondisjunction plays the major role in trisomy formation and the resultant spontaneous arrest of embryonic development. Other factors responsible for tissue-specific distribution of chromosomal aberrations are also discussed. These are differences in cell proliferative activity, as well as changes in compartmentalization and migration of cells with abnormal karyotypes.     

The killifish Nothobranchius rachowi,a new animal in genetic toxicology

Nothobranchius rachowi, a tropical fish that belongs to the family of the Cyprinodontidae, is introduced as a new animal for genetic toxicological studies. The karyotype of N. rachowi consists of 16 large chromosomes. This species can be used for studies on chromosomal aberrations as well as for observations on sisterchromatid exchanges (SCEs). Exposure to 120 mg ethyl methanesulphonate per litre water induced 0.66 SCEs per chromosome, whereas the spontaneous frequency amounted to 0.10 SCEs per chromosome. A comparative study with Umbra pygmaea indicated that the sensitivity for this kind of mutagen is the same in both species. After exposure of N. rachowi to 50 mg cyclophosphamide per litre of water, 0.35 SCEs per chromosome were induced, showing that promutagens could be detected. It is postulated that N. rachowi can be used for screening both pure compounds and surface water for genotoxic potential. An advantage of N. rachowi over Umbra spp. is that the former species is more likely to breed under laboratory conditions.     

Melanin decreases clastogenic effects of ionizing radiation in human and mouse somatic cells and modifies the radioadaptive response

Melanin’s influence on the chromosome aberration frequency induced by radiation in human lymphocytes and mouse bone marrow cells has been studied. We revealed earlier that melanin significantly decreases the frequencies of different radiation-induced mutations in animal germ cells. Melanin protection in somatic cells has been found to be less effective. The melanin effect in somatic cells depends on radiation dose: the lower the damage level, the better the melanin protection. In order to determine the influence of melanin at low radiation doses, the adaptive response was investigated in mouse bone marrow cells in vivo. The level of chromosome aberrations in these cells after fractionated irradiation of 0.2 Gy+1.5 Gy with a 4-h interval was about half that after a single dose of 1.7 Gy. If melanin was injected prior to irradiation, the aberration level decreased by a factor of about two in both cases. This observed result may be due to the potential radioprotective effect of melanin and to the absence of any adaptive response, whereas in the case of melanin application between the priming and challenge doses, the combined effect of the adaptive response as well as melanin protection resulted in a 4-fold decrease of chromosome aberrations. These results allow us to draw the following conclusions: adaptive response can be prevented by a radioprotector such as melanin, and melanin is capable of completely removing low-dose radiation effects. Received: 2 December 1998 / Accepted in revised form: 15 September 1999     

Manifestations of ageing at the cytogenetic level

The effects of ageing in humans appear to be a combination of influence of genetically programmed phenomena and exogenous environmental factors, and take place at the cellular level (senescence), rather than at the level of the organism. There are many processes, which occur in somatic cells as a consequence of DNA replication (accumulation of DNA errors or mutations that outstrip repair processes, telomere shortening, deregulation of apoptosis, etc.) and which drive replicative senescence in human cells. DNA errors are considered to be critical primary lesions in the formation of chromosomal aberrations. It can be concluded that the chromosome aberrations are biomarkers of ageing in human cells. Studies of human metaphases, interphase nuclei and micronuclei showed the increase in loss of chromosomes and the increase in frequency of stable chromosome aberrations as a function of age.