Micronuclei and sister chromatid exchanges induced by capsaicin in human lymphocytes

Escherichia coli has provided an important model system for understanding the molecular basis for genetic instabilities associated with repeated DNA. Changes in triplet repeat length during growth following transformation in E. coli have been used as a measure of repeat instability. However, very little is known about the molecular and biological changes that may occur on transformation. Since only a small proportion of viable cells become competent, uncertainty exists regarding the nature of these transformed cells. To establish whether the process of transformation can be inherently mutagenic for certain DNA sequences, we used a genetic assay in E. coli to compare the frequency of genetic instabilities associated with transformation with those occurring in plasmid maintained in E. coli. Our results indicate that, for certain DNA sequences, bacterial transformation can be highly mutagenic. The deletion frequency of a 106 bp perfect inverted repeat is increased by as much as a factor of 2 x 10(5) following transformation. The high frequency of instability was not observed when cells stably harboring plasmid were rendered competent. Thus, the process of transformation was required to observe the instability. Instabilities of (CAG).(CTG) repeats are also dramatically elevated upon transformation. The magnitude of the instability is dependent on the nature and length of the repeat. Differences in the methylation status of plasmid used for transformation and the methylation and restriction/modification systems present in the bacterial strain used must also be considered in repeat instability measurements. Moreover, different E. coli genetic backgrounds show different levels of instability during transformation.     

Induction of sister chromatid exchanges in human cells by fluorescent light.

The Brd-U differential staining technique was utilized to examine the induction of sister-chromatid exchanges (SCE) by fluorescent ligt in human fetal lung fibroblasts (IMR-90). Exposure of these cells in media to fluorescent light resulted in an increase in SCE frequencies from a background level of 8.5 SCE/cell to 20.5 SCE/cell. Cellular replication kinetics were also inhibited by fluorescent light exposure. Exposure of cells to fluorescent light in phosphate buffered saline (PBS) resulted in a two-fold increase in SCE levels and incresed inhibition of cell replication, indicating that culture media may have a protective effect. Determinations of SCE frequencies with blocking filters indicated that the fluorescent light wavelengths responsible for SCE induction were in the near-ultraviolet spectrum between 300 and 390 nm. Culturing cell sin media that had been exposed to fluorescent light resulted in a significant increase in SCE levels, 14.5 ± 1.5 vs. 7.5 ± 0.65, demonstrating the contribution of media photoproducts to SCE induction. The role of media photoproducts was further reinforced by finding a significant decline in fluorescent light induced SCE in cells cultured in medium deficient in three known photosensitizers (phenol red, tetracycline and riboflavin) for 2–3 weeks prior to exposure.Since SCE have been shown to be a sensitive indicator of DNA damage, these results indicate that fluorescent light can induce genetic damage in human cells. These findings are also of importance to investigators culturing cells in laboratories with fluorescent illumination.     

UV-light induced sister chromatid exchanges in xeroderma pigmentosum lymphocytes

Summary Cultured lymphocytes from 9 patients with clinically different types of xeroderma pigmentosum were exposed to ultraviolet light at 24 h. An increased rate of sister chromatid exchanges was observed in 6 patients (128–148% increase in three, 34–51% in three), but not in three patients with deSanctis-Cacchione syndrome (xeroderma pigmentosum with mental defect), compared to simultaneously cultured controls. A positive result could be useful as preliminary cytogenetic diagnostic test. The results are interpreted as an expression of UV-light induced chromosomal instability due to impaired DNA repair.     

Rate of sister chromatid exchanges in Bloom syndrome fibroblasts reduced by co-cultivation with normal fibroblasts.

Six strains of Bloom syndrome (BlS) fibroblasts responded to co-cultivation with normal fibroblasts at a 1:2 ratio by a reduced rate of sister chromatid exchanges (SCE's) from a mean of 67.5 (range = 59--78) to 28.4 (range = 21--35). The response was dose-dependent in one strain tested at 1:2, 1:1, and 2:1 ratios. In addition, quadriradial exchange figures and other signs of increased chromosomal instability were not found in BlS cells following co-cultivation with control cells. Control cells did not respond to BlS cells and maintained a normal rate of SCEs. Culture medium conditioned for 48 hrs by normal fibroblasts could also reduce the rate of SCEs in BlS fibroblasts, but less than in co-cultivation. We suggest that the reduced rate of SCEs and the lack of chromosomal instability in BlS cells following co-cultivation represent a corrective effect that is related to the basic defect and not dependent on cell-to-cell contact.     

Non-uniform distribution of sister chromatid exchanges in human lymphocytes

To test whether sister chromatid exchange (SCE) scores on human chromosomes have a uniform distribution, simulated SCE scores were generated and compared with observed scores using log-linear models. The analysis was performed at the level of the chromosome groups. Using this method we first tested whether the number of SCEs was distributed uniformly, i.e. proportional to the relative length of the chromosomes. Refinements of this hypothesis were made by considering a variable region around a first SCE to be inert for other SCEs and by making the occurrence of an SCE on a chromosome dependent on the occurrence of another SCE on the same chromosome. In further analyses it was tested whether the number of SCEs was proportional to the number of G bands on a chromosome, or to the DNA content of the chromosomes. None of the tested hypotheses fitted the observed data, establishing the non-uniform distribution of these events.     

Ultrasonic induction of sister chromatid exchanges in human lymphocytes

Summary We analyzed sister chromatid exchange (SCE) frequencies as an indicator of DNA damage induced in human lymphocytes by real-time ultrasound. A range of exposure times and intensities was tested in a series of blind, randomized, in vitro experiments under spatial and sonographic conditions simulating exposure of a gravid abdomen and uterus. Our studies showed small but consistent effects of ultrasound on SCE frequencies, for each experiment. Differences between matched control and exposed means were significantly different from zero. X ² tests for homogeneity indicated no significant differences among either the means or the total distributions of the controls, nor among each of the separate dose levels. Consequently, experiments were pooled, and X ² analysis indicated significant differences both among distributions and among means of SCE frequencies for controls versus exposed cells (P(0.001). The pooled control mean was also significantly different from each of the pooled dose means. Correcting for multiple comparisons gave identical results for the paired comparisons of means except for the 20-min level which was borderline (0.025P(0.01). We conclude that the well-established value of clinical ultrasonography warrants its continued use; however, minimizing the numbers and lengths of exposure per patient would seem prudent, pending further information on clinical implications of our results.Supported in part by NIH-HD82855 and HD 11021 and a National Foundation Summer Science Research Grant for Medical Students, 8-80-22     

Enhancement of X-ray-induced sister chromatid exchanges in hypoxic cells

In these studies we have used wild-type Chinese hamster ovary cells (AA8) and a mutant cell line (UV-41) deficient in excision repair to compare sister chromatid exchange (SCE) induction after X irradiation under oxic and hypoxic conditions. X irradiation of AA8 cells under oxic conditions induced only a slight increase in SCEs, whereas at each dose tested a significantly greater number of SCEs were induced in hypoxic cells. When AA8 cells were X-irradiated and the addition of bromodeoxyuridine (BrdU) was delayed for 20 h to allow DNA lesions to be repaired, the levels of SCEs detected in both oxic and hypoxic cells returned to background levels. X irradiation of UV-41 cells also induced only a slight increase of SCEs in oxic cells, whereas a significant number of SCEs were induced in hypoxic cells. However, in contrast to results with AA8 cells, when hypoxic UV-41 cells were X-irradiated and the addition of BrdU was delayed for 20 h, the number of SCEs remained significantly above background levels. In combination with previous alkaline elution data, these results are consistent with the possibility that DNA-protein crosslinks are responsible for the SCEs induced by X irradiation of hypoxic cells. Irrespective of the mechanism(s) involved, the data presented suggest that the SCE assay may potentially aid in the detection of hypoxic tumor cells.     

beta-Carotene reduces sister chromatid exchanges induced by chemical carcinogens in mouse mammary cells in organ culture

Present studies in the mammary epithelial cell transformation model in organ culture showed that presence of beta-carotene during the 24 hr treatment (initiation stage) of the glands with the carcinogens, 7,12-dimethylbenz[a]anthracene (DMBA), N-nitrosodiethylamine (DENA) and N-methylnitrosourea (MNU), caused a highly significant (P less than 0.001-0.01) reduction of SCE induced by the same carcinogens. In contrast, 4-hydroxyphenyl retinamide (4-HPR) which is known to act at the promotional stage of carcinogenesis did not show any significant reduction of SCE. Thus findings suggest that beta-carotene can modify the DNA damaging effect of the carcinogens and thereby may also prevent the initiation of the carcinogenic process.     

Dose dependence of sister chromatid exchanges in human lymphocytes induced by in vitro α-particle irradiation

Exposure of human G₀ lymphocytes to high-LET particles under different conditions has been seen, unlike low-LET radiations, to be substantially effective in the induction of sister chromatid exchanges (SCE). However, whereas for fast neutrons a linear dose response of SCE has been determined, there is no sign of a dose-response relationship for α-particles. A likely reason for this lack of dose dependence may be the irradiation procedure. Therefore, a technique developed in our laboratory to ensure uniformity of irradiation with α-particles was used in the present study. Monolayers of 3 h-stimulated lymphocytes were exposed with α-particles from ²⁴¹Am. Underdispersion was found for the cell-to-cell variance of the number of SCE. The dose response of SCE was linear, with a yield of 3.4 SCE per cell and per Gray. Received: 26 April 1996 / Accepted in revised form: 24 July 1996     

Induction of structural chromosome aberrations and sister chromatid exchanges in human lymphocytes in vitro by aristolochic acid

The medicinal use of Aristolochia clematitis has been known for some time. The main active agent of this medicinal plant is aristolochic acid, a nitrophenanthrenecarbonic acid. Very recently, however, the Federal Health Office withdrew the licence for all drugs containing aristolochic acid, because of the well-founded suspicion that aristolochic acid may be a very potent carcinogen. We investigated the induction of structural chromosome aberrations and sister chromatid exchanges (SCEs) by aristolochic acid in human lymphocytes in vitro. Cells were treated with the agent tested throughout culture time and during the G0 phase of the cell cycle. We tested concentrations over a range of 1 to 20 micrograms/ml. Both treatment conditions resulted in an increased aberration frequency. The induction of gaps and breaks as well as the induction of SCEs showed a dose-dependent increase. The number of SCEs per metaphase was enhanced by a factor of 2 to 3. If conventional cytogenetic methods had been applied in time, one would have recognized the mutagenic risk of aristolochic acid earlier.     

Suppression of the frequencies of sister chromatid exchanges in Bloom's syndrome fibroblasts by co-cultivation with Chinese hamster cells

Summary The effect of co-cultivation of Bloom's syndrome fibroblasts with Chinese hamster ovary cells (CHO) on the incidence of sister chromatid exchanges (SCEs) was studied. The results show that suppression of the frequency of SCEs in Bloom's syndrome cells occurs only if cell to cell contact is present with CHO cells, without any effect on the SCE frequency in the latter.It is suggested that possible genetic heterogeneity between different Bloom's syndrome patients can be studied using the method of co-cultivation.     

Sister chromatid exchanges in human cells and Chinese hamster cells: Evidence that the rate of sister chromatid exchanges is a function of ploidy

The frequency of sister chromatid exchanges (SCE) in the chromosomes of the diploidy and polyploidy of Chinese hamster cells and human cells has been studied using BUdR-DAPI (bromodeoxyuridine, 4′-6-diamidino-2-phenylindol) fluorescence. The rate of SCEs per cell under constant control conditions is in proportion to the ploidy levels. In addition, the frequency of SCEs observed in a given human chromosome (nos. 1) is also directly proportional to the number of such chromosomes presented in the cells. The mean of SCEs in human chromosome numbers 1 is very similar (0.46–0.48) for diploid, triploid, and tetraploid cells. The results suggest that the rate of SCEs is a function of cellular ploidy levels.     

Increased rates of sister chromatid exchanges induced by the herbicide 2,4-D

The potential for genetic damage from widely used hormonic herbicides, such as 2,4-dichlorophenoxyacetic acid (2,4-D), continues to be of serious concern. The mutagenic effect as reflected by the rates of sister chromatid exchanges (SCE) was determined in cultured human lymphocytes. Data were based on the analysis of 50 cells for the control and each of the three treatments. A 50 micrograms/ml dosage caused a highly significant increase in SCE. Dosages of 100 and 250 micrograms/ml elevated the rate of SCE, but not significantly. Since 2,4-D biodegrades rapidly in soil and water, its continued use is not in serious question until safer compounds are available. However, the results of this study suggest that the danger of genetic damage from direct exposure to commercial samples of 2,4-D should not be ignored.     

Reduced frequencies of Mitomycin-C induced sister chromatid exchanges in AKR Mice

Summary The frequencies of base-line and Mitomycin-C (MMC) induced sister chromatid exchanges (SCE) were surveyed in four inbred strains of mice. In contrast to the C57B1/6J, CBA/J, and A/J strains where frequencies of SCE increased linearly with increasing dose of MMC, levels of SCE were significantly lower in AKR/J mice at high MMC concentrations. At a dose of 5 mg/kg MMC, chromosomal aberrations were more frequent in bone marrow cells of AKR/J mice than in C57B1/6J mice. These observations suggest an altered response to DNA damage in the AKR mouse strain.     

DNA-protein cross-links induced by nickel compounds in intact cultured mammalian cells

The carcinogenic activity of crystalline NiS has been attributed to phagocytosis and intracellular dissolution of the particles to yield Ni2+ which is thought to enter the nucleus and damage DNA. In this study the extent and type of DNA damage in Chinese hamster ovary CHO cells treated with various nickel compounds was assessed by alkaline elution. Both insoluble (crystalline NiS) and soluble (NiCl2) nickel compounds induced single strand breaks and DNA protein cross-links. The single strand breaks were repaired relatively quickly but the DNA-protein cross-links were present and still accumulating 24 h after exposure to nickel. Single strand breakage occurred at both non-cytotoxic and cytotoxic concentrations of nickel, however, DNA-protein cross-linking was absent when cells were exposed to toxic nickel levels. The concentration of nickel that induced DNA-protein cross-linking correlated with those metal concentrations that reversibly inhibited cellular replication.