Induced chromosomal aberrations in man

Factors Influencing the DNA Content of Radiation-induced Micronuclei

The distribution of the DNA content of radiation-induced micronuclei was analysed in several cell lines (Chinese hamster, Syrian hamster and mouse NIH-3T3 cells) by flow cytometry. Frequency and DNA content of micronuclei were measured simultaneously using fluorescence and forward scatter signals of micronuclei and nuclei in suspension stained with ethidium bromide. Computerized random breakage of chromosomes and random combination of fragments was performed to compare the measured micronucleus distributions in synchronized cells irradiated during G1-phase with calculated distributions. The measured DNA distribution of radiation-induced micronuclei was found to be influenced by several factors: (1) the DNA distribution and the centromeric index of the chromosomes in the various cell lines; (2) the cell cycle phase at time of micronucleus measurement due to DNA synthesis in micronuclei; (3) the presence of chromosome fragments in micronuclei; and (4) the presence of whole chromosomes in micronuclei. These factors were shown to be responsible for the previously found large radiation-induced micronuclei which could not be explained by the classic assumption only that radiation-induced micronuclei are mainly produced by single acentric fragments.

Chromosome abnormalities in human beings

Constitutional chromosomal abnormalities are an important cause of miscarriage, infertility, congenital anomalies and mental retardation in humans. Most human constitutional chromosomal imbalance results from aneuploidy, a condition that appears to be much more frequent in humans than in any other species studied. Chromosomal rearrangements and segmental deletions and duplications also occur in humans, but much less often. Although treatment of human somatic cells with some environmental agents produces chromosomal damage, no measurable increase in the frequency of constitutional chromosomal abnormalities has been unequivocally demonstrated among the children of parents exposed to any agent. Recent work has provided insight into a variety of mechanisms by which chromosomal abnormalities can arise during gametogenesis and early embryogenesis. Mechanisms have also been recognized that can correct or partially compensate for chromosomal imbalance, sometimes permitting survival of conceptuses that would otherwise be lost early in gestation. This improved understanding can be used to refine future studies of the cytogenetic effects of environmental exposures.

Liposomes induce chromosome aberrations in human cultured cells

The genotoxic effect of multilamellar lipid vesicles (MLV) was analysed on cultured heteroploid and diploid human cells. Dose-dependent reduction of cell survival and mitotic rate as well as induction of chromosome aberrations were observed. Chromatid and chromosome breaks and chromatid exchanges were found in 24-h culture after liposome treatment, whereas chromosome rearrangements were prevalent at 48 h. Neutral (PC/Chol) and positive (PC/SA) MLV showed a greater damage than negative (PS/PC; PS) MLV. Fibroblasts were the most sensitive cell type. In the case of PC/Chol MLV vesicles, control experiments with PC and Chol of controlled purity ruled out the possibility that the observed chromosome aberrations were caused by toxic oxidation products present in commercial preparations.

Measurement of levels of aneuploidy in mammalian cells using a modified hypotonic treatment

The use of a short hypotonic treatment can prevent scattering of chromosomes by retaining them within the cell membrane. This technique allows chromosomes to be counted accurately so that hypodiploidy can be assessed as well as hyperdiploidy. Levels of aneuploidy were measured following treatment of a low passage number Chinese hamster fibroblast cell line derived from liver (CH1-L) with colcemid, resulting in a dose-related increase in both aneuploidy and polyploidy. The system may be a valuable assay to extend the biological profile of environmental agents, particularly those that are carcinogenic but do not induce chromosome breakage.

Acute and long-term cytogenetic effects of treatment in childhood cancer: sister-chromatid exchanges and chromosome aberrations

The incidence of chromosomal aberrations in banded karyotypes and of sister-chromatid exchanges (SCEs) was determined in the lymphocytes of survivors of childhood cancer as 2 parameters which are pertinent in assessing the genetic damage induced by chemotherapy. The proportion of cells with chromosome breakage or structural rearrangement-type aberration was 1 cell in 67 in a control group of 8 untreated cancer patients and 2 parents of cancer patients, 1 cell in 8 in 12 patients currently on therapy, and 1 cell in 50 in 17 patients sampled 6 months to 35 years post-treatment. The range of mean SCE levels per cell was 4.5-6.5 in the untreated cancer patients, 4.0-9.6 in non-cancer controls, 3.3-33.7 in patients on therapy, and 4.6-9.7 in post-therapy survivors. Considerably variability was observed between individuals with both SCE and breakage assays but therapy-induced increases in SCEs were not necessarily correlated with increased levels of aberrations arising from chromosomal breakage.

Ethylene oxide: evidence of human chromosomal effects

Ethylene oxide is a known mutagen as indicated by short-term testing in vitro and in vivo. Occupational exposure can occur during ethylene oxide gas sterilization of materials for hospital and other use. To study the problem in a hospital sterilization facility where occupational exposure was suspected, epidemiologic, analytic and bioassay tools were employed. All persons whose work activities involved some aspect of the sterilization process were considered exposed to the gas. Within this group of symptomatic and asymptomatic individuals, chronic and incidental exposure was documented by clinical history. Sister chromatid exchanges were studied in lymphocytes cultured from exposed individuals as well as comparable controls. Four chronically exposed persons who reported upper respiratory and neurologic symptoms were studied in some detail. This group showed significantly increased sister chromatid exchange at three weeks and again at eight weeks after the last known exposure. Another group of eight persons with fewer complaints studied as late as the ninth week showed significantly increased exchanges. Incidental exposure may also increase sister chromatid exchange. The measured maximum concentration of ethylene oxide in the sterilizer room was 36 ppm (within standards set by the Occupational Safety and Health Administration).

Genetic alteration in the (Na+ + K+) ATPase transport system expressed in human lymphoblasts and their isolated plasma membranes

A series of ouabain-resistant human lymphoblastoid lines were shown to be genetically altered in the (Na+ + K+) ATPase transport system. The sensitivity to ouabain of Rb+ uptake in intact cells and (Na+ + K+) dependent ATP hydrolysis in purified plasma membrane vesicles was compared with measurement of ouabain binding to intact cells. Preliminary evidence for at least two categories of ouabain resistance was obtained.

Ouabain-resistant human lymphoblastoid lines altered in the (Na+ + K+)-dependent ATPase membrane transport system

Diploid human lymphoblastoid cells with altered response to ouabain inhibition of the (Na+ + K+)-dependent ATPase transport system, manifest both in whole cells and in purified plasma membrane vesicles, were selected for their resistance to 0.1 muM ouabain. Ouabain-resistant (OUA(R)) cells with normal growth at 50 times this dose were recovered at a frequency 1 X 10(-6). This frequency was increased 9-fold after exposure to ethyl methane sulphonate but was decreased by the frameshift mutagen ICR-191, under conditions where both increased the frequency of 8-azaguanine-resistant colonies. The ouabain resistance phenotype was stable after 200 population doublings in the absence of ouabain. OUA(R) clones show showed 30-50% of the wild type amount of 3H-ouabain bound per cell, with the same dissociation constant for ouabain, 0.1 muM at 0.5 mM K+, as observed in wild-type cells. Both the initial rate of uptake of 86Rb+ in OUA(R) cells and the (Na+ + K+)-dependent ATPase activity of OUA(R) plasma membranes showed decreased sensitivity to ouabain inhibition. However, growth and transport properties of OUA(R) cells in the absence of ouabain were unchanged compared with wild type cells.