Frequencies and types of exchange aberrations induced by X-rays and neutrons in Chinese hamster splenocytes detected by FISH using chromosome-specific DNA libraries

PURPOSE: To estimate the frequencies of radiation- (low and high LET) induced chromosome aberrations in Chinese hamster splenocytes by two-colour fluorescence in situ hybridization using DNA painting probes specific for chromosomes 2, 3, 8, X and Y and to determine (1) the ratio of radiation-induced translocations and dicentrics; (2) the spectrum of exchange aberrations induced by X-rays and neutrons; and (3) the relative involvement of the different chromosomes in the formation of aberrations. MATERIALS AND METHODS: Isolated splenocytes from the Chinese hamster were irradiated in vitro with different doses of 200 kV X-rays (0.75, 1.5, 3.0 Gy) and 1 MeV fast neutrons (0.25, 0.5, 1.0 Gy). Conventional analysis of chromosome aberrations was carried out in Giemsa-stained preparations. Chromosome aberrations involving chromosomes 2, 3, 8, X and Y were analysed in first division metaphases using two-colour FISH. RESULTS: The results indicate that when all types of translocations are taken into account both X-rays and neutrons induce more translocations than dicentrics, the ratio between the two types of exchanges being 1.4 and 1.8 respectively. The ratio of 'apparently simple' reciprocal translocations and reciprocal complete dicentrics was close to 1 for both types of radiation. The RBE of neutrons for induction of exchanges was found to be between 5 and 8. Neutron irradiation was more efficient at inducing insertions. Among the chromosomes studied, an increased involvement was observed for chromosome 8 in dicentrics and translocations than that expected on the basis of its chromosome length. The high content of interstitial telomeric sequences in chromosome 8 may be responsible for the observed sensitivity of this chromosome. CONCLUSIONS: The results obtained in this study indicate that: (1) more translocations are found than dicentrics; (2) heterogeneity exists among Chinese hamster chromosomes for involvement in radiation-induced exchanges; (3) the spectrum and distribution of exchange aberrations are different between X-rays and neutrons; and (4) the relative frequencies of insertions could be used as a 'fingerprint' for exposure to high LET radiation.     

Persistence of radiation-induced translocations in human peripheral blood determined by chromosome painting

We have investigated the persistence of translocations and other types of chromosome damage with time using human peripheral blood acutely exposed in vitro to 137Cs gamma rays at doses ranging from 0.5 to 4 Gy. Freshly drawn blood from one donor was irradiated and metaphase chromosomes were prepared 2 to 7 days after exposure. Chromosomes 1, 2 and 4 were painted red-orange and chromosomes 3, 5 and 6 were painted green by fluorescence in situ hybridization (FISH) using "semi-directly" labeled whole-chromosome painting probes. This type of labeling combines direct and indirect labeling and showed significant advantages over both these other methods. All types of structural chromosome aberrations were classified by the Protocol for Aberration Identification and Nomenclature Terminology (PAINT) system. The yields of dicentric chromosomes, acentric fragments and ring chromosomes diminished with time as expected. Translocations exhibited greater persistence but showed a clear and statistically significant reduction in frequency at all doses. The mathematical model suggested that the translocation frequencies would reach a plateau of approximately 4, 15, 51, 106 and 179 translocations per 100 cell equivalents after irradiation with 0.5, 1, 2, 3 and 4 Gy, respectively. When translocations were classified by the conventional system, an analysis of the distribution of translocations and dicentrics per cell indicated that both types of exchanges were Poisson-distributed 48 h postirradiation. However, cells bearing translocations have a higher possibility of having dicentrics than cells without translocations. These findings suggest that dicentrics may contribute to a decline of translocation frequencies with time, and that some translocations are not completely persistent. The results obtained here using human blood exposed in vitro may influence the use of translocations as a retrospective biodosimeter of exposure to ionizing radiation in humans.     

Physics and technology of cardiovascular MR imaging

PURPOSE: Analysis of chromosomal aberrations by fluorescence in situ hybridization using a combination of chromosome painting and telomere detection in order to get more insight into: (a) the extent of incompleteness of exchanges and (b) the frequencies of interstitial fragments. MATERIALS AND METHODS: Isolated mouse splenocytes were exposed in vitro to X-rays at a dose of 2 Gy. Aberrations involving chromosomes 2 and 3 were analysed by FISH using simultaneous chromosome painting and telomere detection. RESULTS: At 2 Gy, about 10% of apparently simple exchanges are incomplete. A striking observation was the high induction of interstitial fragments, with frequencies nearly as high as that of dicentrics. Assuming, that both ends of all interstitial fragments have rejoined with each other (to form acentric rings), it can be estimated that over 92% of reactive ends of detectable breakpoints have rejoined illegitimately. Overall, equal frequencies of translocation types t(Ab) and t(Ba) (according to the PAINT nomenclature) were observed. Also, the ratios between reciprocal forms of translocations and dicentrics were close to 1 for both the chromosomes studied. CONCLUSIONS: These studies have shown that many of the frequently observed 'one-way' exchanges using painting probes, are in fact reciprocal exchanges with one participating lesion so close to the telomere that no distal signal can be detected. Frequencies of true incomplete exchanges were found to be low. Intrachanges, here detected as interstitial fragments, were observed frequently.     

Kinetics of the formation of chromosome aberrations in X-irradiated human lymphocytes, using PCC and FISH

In order to study the initial frequencies and define kinetics of the formation of chromosomal exchanges in X-irradiated human lymphocytes, the premature chromosome condensation (PCC) technique was employed in combination with fluorescence in situ hybridization (FISH) with a composite probe for human chromosome 8 and a pan-centromeric probe for the whole genome. Human lymphocytes were X-irradiated (0.5, 1, 2, 3, 4 and 6 Gy), fused with mitotic Chinese hamster ovary (CHO) cells immediately or 1, 3, 6, 12 and 18 h after irradiation. Immediately after irradiation chromosomal breaks, dicentrics and translocations showed a linear dose-response. Unrejoined chromosome breaks were the most frequent types of aberrations (about 85%) observed. About 15% of total aberrations were chromosome exchanges of 65% of these were translocations and 35% were dicentrics. The chromosomal exchanges initially observed were mostly incomplete, with no complex exchanges at doses of 1 and 2 Gy, at higher doses (3-6 Gy) complex exchanges were observed and their frequencies increased with increasing post incubation time. Following different recovery times, repair kinetics of breaks for different doses of irradiation was studied. The shapes of the curves obtained for breaks as well as chromosome exchanges were linear-quadratic. The linear yield component, alpha, is formed entirely in the fast process that can be manifested in the early plateau, while component beta developed slowly in the subsequent hours. The kinetics of breaks rejoining was exponential, almost 50% of breaks rejoined after 1 h and at 18 h about 20% of breaks remained. At low doses of 1 and 2 Gy most of the exchanges were formed immediately and at higher doses, the frequency of exchanges increased with kinetics similar to that observed for the rejoining of breaks. However, the kinetics was different for different doses of irradiation. The frequency of dicentrics increased at doses above 2 Gy following 3 h recovery time, but for the translocations effect was pronounced even at 1 h recovery time. The frequency of incomplete exchanges (i.e., terminal translocations) decreased with post irradiation time and at 18 h was 30-40% less than the frequency obtained immediately after irradiation. The increase in the total translocations as a function of time between irradiation and fusion was due to a rapid increase in complete exchanges (i.e., reciprocal translocations). The frequency of ring chromosomes immediately after irradiation, also increased linearly, however, it was 3-5 times lower than dicentrics and remained almost constant in number for different doses and at different post-irradiation times.     

Paternally inherited chromosomal structural aberrations detected in mouse first-cleavage zygote metaphases by multicolour fluorescence in situ hybridization painting

We describe a fluorescence in situ hybridization (FISH) procedure for assessing zygotic risk of paternal exposure to endogenous or exogenous agents. The procedure employs multicolour FISH with chromosome-specific DNA painting probes plus DAPI staining for detecting both balanced and unbalanced chromosomal aberrations in mouse first-cleavage (1-Cl) zygote metaphases. Four composite probes specific for chromosomes 1, 2, 3 or X, each labelled with biotin, plus a composite probe specific for chromosome Y labelled with digoxigenin, were used. We applied this method to evaluate the effects of paternal exposure to acrylamide, a model germ cell clastogen. First-cleavage zygote metaphases, collected from untreated females mated to males whose sperm or late spermatids were treated with acrylamide, were scored for the induction of structural aberrations using both chromosome painting (PAINT analysis) and DAPI analysis. Structural chromosomal aberrations were observed in the sperm-derived, but not in the egg-derived, pronuclei. While 59.4% of the zygotes had structural aberrations by DAPI analysis, 94.1% of the same zygotes had structural aberrations by PAINT analysis (P < 0.001), illustrating the increased sensitivity for detecting translocations and insertions obtained by adding chromosome painting. These findings show that FISH painting of mouse 1-Cl zygotes when used in conjunction with DAPI analysis is a powerful model for investigating the cytogenetic defects transmitted from father to offspring.     

Dose-response curve for chromosome translocations measured in human lymphocytes exposed to 60Co gamma rays

Chromosome painting was employed to measure frequencies of reciprocal translocations in human lymphocytes induced by 60Co gamma rays, with emphasis on low doses. Translocations and dicentrics were distinguished by use of a pan-centromeric probe. A total of 41,151 metaphases were analyzed at doses below 0.2 Gy. The linear "take-off" slope of the linear-quadratic dose-response curve for translocations, i.e., the alpha coefficient, was measured to be 0.023 +/- 0.005 translocations per cell per Gy. This alpha coefficient is more precise than previously measured. Because the alpha coefficient is the dominant contributor to the translocation frequency induced by low-level exposures, the results presented here will substantially reduce uncertainties in biodosimetry estimates obtained for stable translocations.     

Preoperative testing before carotid endarterectomy: a survey of vascular surgeons'' attitudes

In this article, we address the issue of persistence of chromosome exchanges following acute in vitro exposure of rat peripheral blood to 137Cs. Irradiation occurred 24 hr after culture initiation, and metaphase chromosomes were prepared 2, 3, 4, and 5 days later. Chromosomes 1, 2, and 4 were painted in unique colors and scored for structural aberrations. Dicentric chromosomes and acentric fragments diminished rapidly with time, as expected. Translocations exhibited greater persistence, but still showed a reduction in frequency, reaching a plateau of approximately 65 and 55% of their initial values, 4 days after exposure to 1 and 2 Gy, respectively. An exponentially declining model was fit to the combined dicentric, acentric fragment, and translocation frequencies, which showed that all three aberration types declined at equivalent rates. The frequencies of dicentrics and fragments declined to a plateau of zero, while translocations reached a plateau at frequencies significantly greater than zero. The decline in translocations with time is inconsistent with prevailing theoretical expectations, but is consistent with a model where some translocations are fully stable (persistent) and some are unstable (not persistent) through cell division. These results may have implications for radiation biodosimetry in humans.     

Response of mosquitoes (Diptera: Culicidae) to carbon dioxide and octenol in Egypt

The radioprotective effect of the leaf extract of Ocimum sanctum (OE) in combination with WR-2721 (WR) was investigated on mouse bone marrow. Adult Swiss mice were injected intraperitoneally (i.p.) with OE (10 mg/kg on 5 consecutive days), or 100-400 mg/kg WR (single dose) or combination of the two or double-distilled water (DDW) and whole-body exposed to 4.5 Gy gamma-irradiation (RT). Metaphase plates were prepared from femur bone marrow on days 1, 2, 7 and 14 post-treatment and chromosomal aberrations were scored. The maximum number of aberrant cells was observed at 24 h after irradiation in all the groups. However, pretreatment with OE or WR individually resulted in a significant decrease in aberrant cells as well as different types of aberrations. The combination of the two further enhanced this effect; resulting in a 2-fold increase in the protection factor (PF = 6.68) compared to 400 mg/kg WR alone. The percent aberrant cells decreased linear-quadratically with WR dose when given individually, while in the OE + WR pretreatment animals the values showed a linear dose response. Combination of OE with WR doses above 200 mg/kg completely eliminated rings, polyploidy and pulverization of chromosomes. Percent aberrant cells decreased with time in all groups, though the values remained higher than normal even on day 14 in the RT alone as well as those treated with single agent + RT. WR doses above 200 mg/kg before RT resulted in significantly higher frequency of aberrant cells compared to RT and OE + RT groups on day 14, suggesting delayed WR toxicity; but combination of OE with WR brought down these values to normal level, indicating that OE combination, in addition to enhancing WR protection, may also act as a detoxifier. The protective effect of OE and WR is also reflected in the enhancement of bone marrow CFU survival. Both OE and WR possessed significant free radical scavenging activity in vitro. The combination of the two further enhanced this effect, suggesting that the enhanced free radical scavenging activity by combining the two protectors results in the higher bone marrow cell protection. The significant elevation in chromosome protection obtained by combining OE with WR, with reduction in the latter's toxicity at higher doses, suggests that the combination may have promise for radioprotection in humans.     

Multicolor spectral karyotyping identifies new recurring breakpoints and translocations in multiple myeloma

Karyotypic information on multiple myeloma (MM) is less extensive than that on other myeloid or lymphoid malignancies due to low mitotic activity of plasma cells. An add(14)(q32) marker chromosome has been reported to be the most frequent recurring abnormality in clonally abnormal cases; in approximately one third of the latter cases, this marker has been identified as a der(14)t(11;14)(q13;q32) chromosome. To map chromosomal breakpoints, characterize the add(14)(q32) marker chromosomes, and to identify other recurring translocations in MM, we used spectral karyotyping (SKY) to analyze a panel of nine bone marrow (BM) biopsy samples from eight patients and 10 tumor cell lines derived from MM patients. SKY involves hybridization of 24 fluorescently labeled chromosome painting probes to metaphase spreads in such a manner that simultaneous visualization of each of the chromosomes in a different color is accomplished. By this method, it was possible to define all chromosomal rearrangements and identify all of the clonal marker chromosomes in tumor cells. By detailed mapping of breakpoints of rearrangement, it was also possible to identify several novel recurring sites of breakage that map to the chromosomal bands 3q27, 17q24-25, and 20q11. The partner chromosomes in translocations that generated the add (14)(q32) marker chromosomes were identified in all cases in which they were detected by G-banding (one biopsy and six cell lines). In addition, two new translocations involving band 14q32, ie, t(12;14)(q24;q32) and t(14;20)(q32;q11) have also been identified. These studies demonstrate the power of SKY in resolving the full spectrum of chromosome abnormalities in tumors.     

Comparative studies of the mitogenic effects of epidermal growth factor and transforming growth factor-alpha and the expression of various growth factors in neoplastic and non-neoplastic prostatic cell lines

Murine acute myeloid leukemia is characterized by chromosome 2 aberrations, and genesis of the marker chromosome 2 by radiation is suspected to be an initiating event of radiation leukemogenesis. A detailed analysis of the type and frequency of chromosome 2 aberrations in murine bone marrow cells at an early stage after irradiation is provided here. A total of 40 male C3H/He mice was exposed to 137Cs gamma-ray at a dose of 1, 2 or 3 Gy, and sacrificed 24 hours after irradiation. Metaphase samples prepared from bone marrow cells were Q-banded for karyotyping or painted with DNA probes specific to chromosome 2. In 5 mice analyzed by karyotyping, one mouse showed high frequency of the marker aberrations as well as other chromosome 2 aberrations. Chromosome painting analysis for the rest of the mice also detected 3 animals showing significantly high frequencies of chromosome 2 aberrations. Dose-dependence of the frequencies was observed even among those mice that tended to be sensitive. The results indicated that there was a subgroup of mice carrying hypersensitive chromosome 2. The subgroup could be leukemia-sensitive if radiation-induced chromosome aberrations are responsible for an early change in myeloid leukemogenesis.     

Application of chromosome painting to clastogenicity testing in vitro

To maximise sensitivity, protocols for testing chemicals in chromosomal aberration assays in vitro are designed so that cells are sampled when the peak frequency of aberrations might be expected to occur. They are not designed to measure the frequency of aberrations in cells which survive. Only chromosomal aberrations which are heritable, however, can have any relevance to human health, but the detection of those aberrations most likely to be tolerated (inversions, reciprocal translocations) is notoriously difficult with conventional light microscopy. Current protocol design is justified by arguing that the presence of structural aberrations of any type at early times after treatment indicates a risk that a proportion of aberrations will persist and be maintained in the population. Chromosome painting allows reciprocal exchanges to be relatively easily measured and permits the validity of these assumptions to be tested. To date, the kinetics of induction and dose-response relationships of reciprocal translocations induced by chemicals have been little investigated. We compared the frequency of chromosome-type aberrations in human lymphocytes following treatment with two powerful clastogens, streptonigrin and Trenimon, using conventional staining techniques and chromosome painting. The results show that although reciprocal translocations can be shown to arise and persist in treated populations of human lymphocytes for several days following treatment, their frequency is very low, even at concentrations where large amounts of chromosomal damage are induced, indicating that, at present, the value of using chromosome painting as an adjunct to traditional clastogenicity testing is limited.     

Identification of complex chromosome rearrangements in the gibbon by fluorescent in situ hybridization (FISH) of a human chromosome 2q specific microlibrary, yeast artificial chromosomes, and reciprocal chromosome painting

Chromosome painting has revealed that the human chromosome homologs in lesser apes are often fragmented and translocated to a number of different hylobatid chromosomes. We investigated the fragmented human chromosome 2 homologs in gibbons to illustrate a new strategy in mapping regional and band-specific chromosomal homologies between species. Previous research showed that the DNA library specific to human chromosome 2 paints parts of four gibbon (lar species group) chromosomes (viz., 1, 10, 12, and 16) and yields five distinct hybridization signals (including two on gibbon chromosome 16). However, the exact segments of human chromosome 2 that were translocated to the various gibbon chromosomes could not be distinguished. To determine the origin of the human chromosome 2 signals, we hybridized a microlibrary for the long arm of human chromosome 2, as well as YACs specific for most of the major bands on this chromosome, to metaphases of the gibbon. For reciprocal chromosome painting, we hybridized flow-sorted gibbon chromosome probes to human chromosome 2. Each method added additional insights that helped clarify the shuffling of human chromosome 2 material in the highly reorganized gibbon genome. There was an excellent correspondence between these complementary techniques. YAC 958d2 identified the breakpoint between human chromosome 2 material present on gibbon chromosomes 10 and 16. The reciprocal chromosome painting permitted a more complete and regional assignment of homology between segments on various gibbon chromosomes to human chromosome 2. The results show that a combination of reciprocal chromosome painting, subregional microlibraries, and band-specific probes (such as YACs) can be used to identify homologies between species and to rapidly construct detailed comparative chromosome maps, especially when the karyotypes are highly rearranged.     

Identification of X-ray-induced complex chromosome exchanges using fluorescence in situ hybridization: a comparison at two doses

Complex chromosome exchanges are defined as interactions between three or more breaks, in two or more chromosomes. In this study, a sequential hybridisation technique was developed to visualize a given chromosome pair: green (chromosomes 1, 5 and 7), all centromeres red and the remaining chromosomes blue. Primary human fibroblasts were irradiated in G1 with 4 and 6 Gy 250-kV X-rays. After 4 Gy, a total of 387 simple aberrations (defined as translocations or dicentrics with fragments) and 116 complex aberrations were identified. After 6 Gy these aberrations numbered 225 and 110 respectively. Using a break-rejoin scheme, which describes interactions between breaks within a complex as independent events we modelled the complex 'mix' present after 4 Gy. At 6 Gy the same model could be used for chromosomes 5 and 7, but chromosome 1 frequencies could only be explained if we biased the interactions, such that two-breaks-in-one-chromosome events occur predominantly in chromosome 1. From these predicted interactions we also calculated the number of apparently simple exchanges that are actually complex derived. These accounted for 20% of those observed after 4 Gy and 33% after 6 Gy. Therefore, with this FISH assay, an estimated 35 and 54% of all exchanges are derived from complexes after 4 and 6 Gy respectively.     

Chromosomal rearrangements detected by FISH and G-banding

Fluorescence in situ hybridization (FISH) using chromosome-specific DNA libraries as painting probes, locus-specific unique sequence (cosmid) probes, and Y-specific repetitive sequences was applied in the analysis of eighteen cases of chromosomal rearrangements of undetermined nature. FISH clarified the origin of the extra or translocated chromosome segments in seventeen patients, one with 2q+, two with 4q+, one each with 6p+, 7p+, 9q+, 10p+, 11q+ and 12p+, two with 13q+, and one each with 15q+, 17p+, 18p+, 20p+, 21p+ and Yq+, as well as the nature of a de novo supernumerary chromosome marker in a previously reported case. By G-banding and molecular cytogenetic studies of the family members, six cases were determined to have unbalanced translocations inherited from the carrier parent. The extra translocated genetic material may cause specific trisomic syndromes, including partial 6p21.3-p23, 9q32-q34.3, 13q32-q34, 15q24-q26, and 17p11.2-p13 trisomies in those patients. A translocated 21q segment on 12p was shown by a painting probe in a patient with Down features. A patient with cat cry syndrome resulting from a loss of the terminal segment of the short arm of chromosome 5 was confirmed by a cosmid probe showing de novo reciprocal translocation between chromosomes 5 and 18:t(5;18) (p13.3;p11.31). With FISH, the extra material on the rearranged chromosome could also be identified as duplicated or translocated. The FISH technique thus provides a method for the analysis of extra structurally abnormal chromosomes (especially in de novo cases), recognizable syndromes (contiguous gene syndromes) caused by translocated deletion from parental balanced chromosome rearrangements, and supernumerary marker chromosomes. FISH subsequent to G-banding is also of great help in the confirmation of preliminary abnormal G-banded karyotypes after a modified destaining procedure. In conclusion, the combination of G-banding and FISH is very useful in the accurate diagnosis of chromosomal rearrangements.     

Analytical evaluation of the new Prostatus PSA Free/Total assay for prostate-specific antigen as part of a screening study for prostate cancer

A second Philadelphia (Ph) chromosome is one of the most common nonrandom secondary chromosome changes in leukemias with 9;22 translocations. It has been suggested, and observed in two studies of masked t(9;22), that the second Ph chromosome is an exact duplication of the entire derivative chromosome 22. In a cytogenetic study of bone marrow cells from an acute myelogenous leukemia patient, a cell line carrying two different Ph chromosomes evidenced by a chromosome 22 centromeric heteromorphism was found. From this observation arose the question whether the second der(22) was a true Ph chromosome or whether it was a deleted chromosome derived from the normal chromosome 22 that did not contain the bcr-abl rearrangement. A fluorescent in situ hybridization (FISH) study with the t(9;22) probe revealed two bcr-abl positive signals on 60 of 100 interphase nuclei. The second Ph could have resulted from a mitotic crossing over; or, analogously to late-appearing Philadelphia chromosomes, it may be derived from a new chromatid translocation between the chromosomes 9 and 22 not involved in the initial t(9;22).     

Hypermutability of mouse chromosome 2 during the development of x-ray-induced murine myeloid leukemia

In an effort to identify the precise role of a deletion at regions D-E of mouse chromosome 2 [del2(D-E)] during the development of radiation-induced myeloid leukemia, we conducted a serial sacrifice study in which metaphase chromosomes were examined by the G-banding technique. Such metaphase cells were collected from x-irradiated mice during the period of transformation of some of the normal hematopoietic cells to the fully developed leukemic phenotype. A group of 250 CBA/Ca male mice (10-12 weeks old) were exposed to a single dose of 2 Gy of 250-kilovolt-peak x-rays; 42 age-matched male mice served as controls. Groups of randomly selected mice were sacrificed at 20 hr, 1 week, and then at intervals of 3 months up to 24 months after x-irradiation. Slides for cytogenetic, hematological, and histological examination were prepared for each animal at each sacrifice time. An expansion of cells with lesions on one copy of chromosome 2 was evident in 20-25% of treated mice at each sacrifice time. The majority of such lesions were translocations at 2F or 2H, strongly suggesting hypermutability of these sites on mouse chromosome 2. No lesions were found in control mice. The finding leads to the possibility that genomic lesions close to 2D and 2E are aberrants associated with radiation leukemogenesis, whereas a single clone of cells with a del2(D-E) may lead directly to overt leukemia. The data also indicate that leukemic transformation arises from the cumulative effects of multiple genetic events on chromosome 2, reinforcing the thesis that multiple steps of mutation occur in the pathogenesis of cancer.     

Chromosome painting: a useful art

Chromosome 'painting' refers to the hybridization of fluorescently labeled chromosome-specific, composite probe pools to cytological preparations. Chromosome painting allows the visualization of individual chromosomes in metaphase or interphase cells and the identification of both numerical and structural chromosomal aberrations in human pathology with high sensitivity and specificity. In addition to human chromosome-specific probe pools, painting probes have become available for an increasing range of different species. They can be applied to cross-species comparisons as well as to the study of chromosomal rearrangements in animal models of human diseases. The simultaneous hybridization of multiple chromosome painting probes, each tagged with a specific fluorochrome or fluorochrome combination, has resulted in the differential color display of human (and mouse) chromosomes, i.e. color karyotyping. In this review, we will summarize recent developments of multicolor chromosome painting, describe applications in basic chromosome research and cytogenetic diagnostics, and discuss limitations and future directions.     

Determination of the radiation sensitivity of the stromal cells in the murine long-term bone marrow culture by measuring the induction and rejoining of interphase chromosome breaks

PURPOSE: To determine the radiosensitivity of bone marrow stromal cells, the rate of interphase chromosome breakage and rejoining of stromal cells in the murine long term bone marrow culture and of human skin fibroblasts were compared. METHODS AND MATERIALS: The cells were irradiated with doses up to 6 Gy and repair times up to 6 hr were investigated. After induction of premature chromosome condensation by fusing the cells with mitotic HeLa cells, the number of interphase chromosome fragments was counted. RESULTS: The number of radiation induced breaks was found to be not significantly different for both cell types with 6.16 +/- 0.26 breaks per Gray for the fibroblasts and 5.96 +/- 0.20 breaks per Gray for the stromal cells. A significant difference was observed in the repair rate. The fibroblasts rejoined 39.6% of the breaks induced initially during the first hour after irradiation and 5.6 +/- 1.84 breaks remained unrejoined after 6 hr, while the stromal cells were able to rejoin 63.2% in 1 hr and had 2.05 +/- 0.07 breaks unrejoined after 6 hr. CONCLUSION: If the well substantiated assumption is made, that the capacity to repair DNA double strand breaks or interphase chromosome breaks is correlated with the cellular radiosensitivity, this finding indicate, that murine bone marrow stromal cells are more radioresistant than human skin fibroblasts.     

Analysis of on- and off-resonance magnetization transfer techniques

PURPOSE: To quantitatively assess all gamma-ray induced chromosomal changes confined to one human chromosome using fluorescence microscopy and in situ hybridization with a fluorescently labeled human chromosome specific nucleic acid probe. METHODS AND MATERIALS: Synchronized human-hamster hybrid cells containing human chromosome 11 were obtained by a modified mitotic shake-off procedure. G1 phase cells (> 95%) were irradiated with 137Cs gamma rays (0, 0.5, 1.0, 1.5, 2.0, 4.0, 6.0, 8.0, and 10.0 Gy) at a dose rate of 1.1 Gy/min and mitotic cells collected 16-20 h later; chromosomal spreads were prepared, denatured, and hybridized with a fluorescein-tagged nucleic acid probe against total human DNA. Chromosomes were examined by fluorescence microscopy and all categories of change involving the human chromosome 11 as target, recorded. RESULTS: Overall, of the 3104 human-hamster hybrid cells examined, 82.1% were euploid, of which 88.6% contained one copy of human chromosome 11, 6.2% contained two copies, and 5.2% contained 0 copies. This is compatible with mitotic nondisjunction in a small fraction of cells. Of the remaining 17.9% of cells, 85.2% were tetraploid cells with two copies of human chromosome 11. For all aberrations involving human chromosome 11 there was a linear relationship between yield and absorbed dose of 0.1 aberrations per chromosome per Gy. The yield of dicentrics, translocations, and terminal deletions that involve one lesion on the human chromosome was linear, while the yield of interstitial deletions that arise from two interacting lesions on the human chromosome was curvilinear. The frequencies of dicentrics and translocations were about equal, while there was a high (40-60%) incidence of incomplete exchanges between human and hamster chromosomes. CONCLUSIONS: Fluorescent in situ hybridization (FISH) procedures allow for the efficient detection of a broad range of induced changes in target chromosomes. Symmetrical exchanges induced in G1 (translocations) were readily scored and found to equate with the complementary asymmetrical exchanges (dicentrics). That is, nonlethal stable changes, which might be of concern in carcinogenic processes, complement lethal, unstable changes. Interstitial deletions that may contribute to the loss of antioncogenes as well as to lethality are also readily detected with enhanced levels detected at higher doses. The high level of induced terminal deletions and of incomplete dicentrics and translocations indicate a partial failure of interaction between lesions induced in human and hamster DNA, and suggest that such interspecies interactions lack the fidelity of intraspecies DNA lesion interactions. This suggests caution in the use of such model systems as indicators of human cell responsiveness.     

Citrinin-induced chromosomal abnormalities in the bone marrow cells of Mus musculus

Oral administration of various doses of citrinin (5 to 20 ppm) to young weanling mice for 8 weeks induced both gross as well as individual types of abnormalities and breakages in the chromosomes of bone marrow cells. The rate of such abnormalities was 5.5% in the controls and 36.0% in the treated variants. Hypoploidy, stickiness and clumping of chromosomes were some of the gross types of abnormalities. Structural chromosomal changes observed were chromosome/chromatid breaks, gaps, acentric fragments, metacentric chromosomes and ring formations.