Sister chromatid exchanges and heterochromatin

Summary The inter- and intrachromosomal distribution patterns of SCEs obtained with or without mutagen treatment are reviewed and compared, with each other as to their relation to heterochromatin and with the distribution patterns of chromatid aberrations that occurred either spontaneously in chromosomes of repair-defective human syndromes or after treatment with the mutagens (BrdU, ethylalcohol, DMBA, TMBA, maleic hydrazide, MMS, MMC). The conclusions are: No general rule is detectable for nonrandom involvement of heterochromatin in spontaneous SCEs. Mutagen-induced SCEs show the same or very similar distribution patterns as the spontaneous ones and are in no case as preferentially located as chromatid aberrations (which involve mainly the junctions between eu- and heterochromatin or other special regions). Therefore, a specific mutagen sensitivity of heterochromatincontaining chromosome regions as observed for chromatid aberrations does not exist (or is less pronounced) for SCEs. This supports the inference that different mechanisms underlie the origins of the two phenomena.     

Sister chromatid exchanges in isolabeling

Isolabeling observed by autoradiography in sister chromatids at the second or later metaphases after incorporation of ³H-thymidine has sometimes been ascribed to an exchange between the multiple DNA duplexes in polynemic sister chromatids. An analysis reported here on the frequency and size of isolabeled regions in chromosomes of the rat kangaroo shows that all isolabeling can be accounted for by sister chromatid exchanges coupled with the image spread that can occur in tritium autoradiographs. Hence, in this case it becomes unnecessary to postulate binemy or polynemy to explain isolabeling.     

Sister chromatid exchanges in barley

Summary A mean frequency of 20.6 sister chromatid exchanges (SCEs) per cell has been observed in a reconstructed karyotype of Hordeum vulgare by application of the FPG technique after unifilar incorporation of BrdU into chromosomes. The involvement in SCEs of the 48 segments into which the chromosome set had been subdivided was, with a single deviation, length proportional and independent of the segment's heterochromatin content. Asymmetric bands, indicative of an uneven distribution of adenine and thymidine between the DNA strands in adenine (A)-thymidine (T) rich chromosome regions, could not be detected after incubation of the cells in BrdU for one cycle of DNA replication.     

Sister chromatid exchanges in Allium cepa

Differential staining of sister chromatids with Giemsa after BrdU incorporation into DNA was performed in Allium cepa L. chromosomes. A treatment solution containing 10^–7 M FdU, 10^–4 M BrdU and 10^–6 M Urd was found to ensure BrdU incorporation without affecting cell cycle duration. After several procedures before staining the slides with Giemsa had been tested, treatment with the fluorochrome compound 33258 Hoechst, exposure to UV light and heating at 55° C in 0.5×SSC, were found to be essential for good differentiation. The distribution of SCEs per chromosome agrees with the expected Poisson distribution. The mean value of SCEs per chromosome occurring when cells were exposed to the treatment solution for two consecutive rounds of replication (=5.5) was double the mean value observed when cells were exposed to the same treatment for only one round of replication (=2.8). SCEs were found to occur more frequently in those chromosome regions corresponding neither to C-bands nor to late replicating DNA-rich regions. Finally, the occurrence of SCEs involving less than the width of a chromatid is discussed.     

Sister chromatid exchanges in Vicia faba

Evolutionary loss of the Y chromosome has occurred in Climacia areolaris (Hagen) of the neuropteran family Sisyridae. The diploid set comprises 6 pairs of autosomes, plus 2 X chromosomes in the female and 1 X in the male. The Y is retained in Sisyra vicaria (Walker) of the same family: its chromosome number is 14 in both sexes including 2X chromosomes in the female and 1X plus Y in the male. Two alternative pathways for the segregation of the sex chromosomes-distance segregation and sex bivalent formation-co-exist in the latter species in a ratio of approximately 1 to 6; the possible phylogenetic significance of this feature is discussed.     

Sister chromatid exchanges in Tradescantia paludosa

A modified fluorescence-plus-Giemsa technique is described that allows differential staining of sister chromatids in root tip cells from cuttings of Tradescantia paludosa. With this staining technique, chromatids with both DNA strands unsubstituted are differentiated from chromatids containing 5-bromouracil in place of thymine in one of the strands of the DNA duplex. The baseline level of sister chromatid exchanges was shown to be dependent on the concentration of 5-bromodeoxyuridine in the treatment solution, the mean frequency being 43.5 sister chromatid exchanges per cell for the experimental protocol suggested.     

Sister chromatid exchanges in protein-energy malnutrition

Summary The frequency of sister chromatid exchanges in children suffering from severe protein-energy malnutrition was investigated by the fluorescent-plus-Giemsa method. Children suffering from kwashiorkor had significantly higher mean SCEs per circulating lymphocyte than did normal children. A small but statistically significant decrease in these levels was observed following nutritional rehabilitation.     

Sister chromatid exchanges in Vicia faba

The relationship between chromosomal aberrations and sister chromatid exchanges (SCE's) after treatment of Vicia faba root tips with thiotepa, caffeine and 8-ethoxycaffeine (EOC) was studied by using a modified fluorescent plus Giemsa (EPG) technique. At concentrations which had little effect on the frequency of chromosomal aberrations, thiotepa strongly increased the frequency of SCE's, provided that the chromosomes were allowed to replicate between treatment and fixation. Frequently, the size of the exchanged material was smaller than the diameter of the chromatid. Post-treatments with caffeine of roots previously exposed to thiotepa strongly increased the frequency of aberrations, but had little effect on the frequency of SCE's. In contrast to thiotepa, EOC caused only a slight increase in the frequency of SCE's even at concentrations which produced a high frequency of chromosomal aberrations. Thus, there was not a close correlation between SCE's and chromosomal aberrations. Single-strand exchanges between the DNA double helices in sister chromatids were not detected.     

Sister chromatid exchanges in cultured peripheral lymphocytes from twins

Summary Sister chromatid exchange points (SCE points) on individual chromosomes were studied in cultured lymphocytes from 11 monozygotic (MZ) and nine dizygotic (DZ) same-sexed pairs by means of sequential Q-banding and BUdR-Giemsa techniques. No statistically significant variation between unrelated individuals with respect to SCE points on specific chromosomes was found. Intrapair differences in the number of SCE points on specific chromosomes were not significantly smaller between MZ twin partners as compared with DZ partners. The results suggest that genetic factors do not play any major role in the frequency and distribution of SCE in normal subjects.     

Sister chromatid exchanges and chromatid interchanges in bloom's syndrome.

A comparison is made between the incidences of sister chromatid exchanges (SCE) per chromosome and group of chromosomes and breakage, visible at metaphase like open gaps, breaks, and breaks involved in chromatid interchange formation (CI) in Bloom's syndrome. It can be shown that the two levels of breakage SCE and CI are not correlated as to the locations. The discussion deals with possible interpretations of preferential breakage and reunion at certain homologous chromosomes and the difficulties today to understand SCEs.     

Comparative effectiveness in the induction of sister chromatid exchanges and chromosome aberrations

The dose curves for 5 chemicals were studied to compare the efficiency of induction of SCEs and chromosomal aberrations by "polycentric" mutagens. The number of SCEs was found to increase linearly with the dose while that of chromosomal aberrations--nonlinearly. The efficiency of SCEs induction by these mutagens was found to be 25-50 times as high as in the induction of chromosomal aberrations. Division of alkylating mutagens into "monocentric" and "polycentric" is shown to be useful. It reflects their different efficiency in damaging one or simultaneously two DNA strands. The correlation between SCEs and formation of aberrations of the chromatid type is stated.     

Sister chromatid exchanges in balanced translocation carriers and in patients with unbalanced karyotypes

Summary Sister chromatid exchanges (SCEs) were studied in peripheral human leukocytes from 16 patients with balanced translocations or with unbalanced karyotypes, and from 4 controls. No difference was seen between these two groups of people in the mean number of SCEs per cell, or in the total number of SCEs observed for each pair of autosomes involved in the translocations studied. With this last number no difference from the expected number of SCEs, if one supposes that SCEs follow a random distribution, was seen.     

Sister chromatid exchanges in leukocytes of patients with cancer of cervix uteri

Summary The frequency of sister chromatid exchange (SCE) was investigated in 13 women with cervical cancer together with 11 control women. The SCE frequencies were found to be 10.05±2.35 and 6.95±1.53 in cancer cases and controls, respectively. The SCE values of cancer cases deviate significantly from that of controls. The SCE in chromosome groups E, F, and G was found to be more in comparison to controls (P<0.001). This preliminary study indicates the possibility of using SCE as a preclinical marker.     

Sister chromatid exchanges in patients with precancerous and cancerous lesions of cervix uteri

Summary The frequency of sister chromatid exchanges (SCEs) was studied in leucocytes from 46 patients with cervical carcinoma, 89 precancerous lesions, and 43 age-matched control women. The frequency of SCEs was found to be 10.15 ±2.49 in cancer, 8.83±2.15 in precancerous lesions, and 7.55±2.24 in controls. The analyses of SCE data revealed a highly significant (P<0.001) increase in precancerous and cancerous lesions compared to controls. The intra-chromosomal distribution of SCEs revealed a random increase in various chromosomal groups in patients with cancer and dysplasia compared to controls. The mean SCE level among various groups of precancerous lesions according to severity of pathological condition did not show significant differences. However, 70.8% of dysplasia cases revealed SCE levels higher than the average in controls. The increased frequencies of SCEs in the majority of cancer patients and a few, precancerous lesions indicate that individuals with high SCE levels may be at a high risk of developing cancer. Thus the usefulness of SCE levels as a preclinical marker to identify the high risk group of dysplasias needs to be ascertained by follow-up studies; these are in progress.     

Sister chromatid exchanges in betel and tobacco chewers

The incidence of sister-chromatid exchange (SCE) was investigated in the lymphocyte chromosomes of betel and tobacco chewers. Betel chewers and betel-with-tobacco chewers showed higher yields of SCE than normal controls. Higher frequencies of SCE were also observed in individuals who chewed more than 10 betel leaves, or betel leaves-with-tobacco, per day, compared to people who chewed less than 10 betel leaves, or betel leaves-with-tobacco, per day, respectively. Subjects who had chewed betel leaves and betel leaves + tobacco for more than 10 years showed an elevated frequency of SCE.     

Ultraviolet light and mitomycin C induced sister-chromatid exchanges in fibroblasts from patients with retinoblastoma

Ultraviolet light and mitomycin C (MMC) induced sister-chromatid exchanges (SCEs) were investigated in 6 diploid fibroblast strains derived from 3 patients with deletion 13 and retinoblastoma, one patient with a hereditary form of retinoblastoma, one patient with trisomy 13, and one normal control. Two fibroblast strains with del(13)(q14q22) showed a significant increase in SCEs compared to the control after UV and MMC treatments. In contrast, cell strains with del(13)(q12q14) and trisomy 13 did not show increased SCEs. The frequency of SCEs in fibroblasts from a patient with autosomal dominant retinoblastomas (no deletions) was significantly increased by UV, but not by MMC. The results suggest that cell strains with different deletions of chromosome 13 have different SCE responses to UV and MMC inductions. The cells with del(13)(q14q22) may have a DNA-repair defect.     

Sister chromatid exchanges in lymphocytes of nuclear medicine physicians

OBJECTIVE: The aim of this study was to assess whether occupational exposure to chronic, low doses of Iodine 131 (I-131) and Technetium 99m (Tc-99m) may lead to genotoxicity. Medical personnel occupied in nuclear medicine departments are occupationally exposed to low doses of I-131 and Tc-99m. The determination of the frequency of sister chromatid exchanges (SCEs) and of cells with a high frequency of SCEs (HFC) is considered to be a sensitive indicator for detecting genotoxic potential of mutagenic and carcinogenic agents. Therefore, we examined peripheral lymphocytes from nuclear medicine physicians for the presence of both SCE and HFC. METHODS: Sixteen exposed nuclear medicine physicians (non-smokers) were compared to 16 physicians (non-smokers) who had not been exposed to chemical or physical mutagens in their usual working environment at the same hospital. RESULTS: A statistically significant difference was found between SCE frequencies and HFC percentages measured in lymphocytes from the exposed and control groups. CONCLUSIONS: The present observation on the effect of chronic low doses of I-131 and Tc-99m indicates the possibility of genotoxic implications of this type of occupational exposure. Hence, the personnel who work in nuclear medicine departments should carefully apply the radiation protection procedures and should minimize, as low as possible, radiation exposure to avoid possible genotoxic effects.