demecolcine and Monosomy

Small mutations, megabase deletions, and aneuploidy are involved in carcinogenesis and genetic defects, so it is important to be able to quantify these mutations and understand mechanisms of their creation. We have previously quantified a spectrum of mutations, including megabase deletions, in human chromosome 11, the sole human chromosome in a hamster-human hybrid cell line AL. S1- mutants have lost expression of a human cell surface antigen, S1, which is encoded by the M1C1 gene at 11p13 so that mutants can be detected via a complement-mediated cytotoxicity assay in which S1+ cells are killed and S1- cells survive. But loss of genes located on the tip of the short arm of 11 (11p15.5) is lethal to the AL hybrid, so that mutants that have lost the entire chromosome 11 die and escape detection. To circumvent this, we fused AL with Chinese hamster ovary (CHO) cells to produce a new hybrid, ALC, in which the requirement for maintaining 11p15.5 is relieved, allowing us to detect mutations events involving loss of 11p15.5. We evaluated the usefulness of this hybrid by conducting mutagenesis studies with colcemid, 137Cs gamma-radiation and UV 254 nm light. Colcemid induced 1000 more S1- mutants per unit dose in ALC than in AL; the increase for UV 254 nm light was only two-fold; and the increase for 137Cs gamma-rays was 12-fold. The increase in S1- mutant fraction in ALC cells treated with colcemid and 137Cs gamma-rays were largely due to chromosome loss and 11p deletions often containing a breakpoint within the centromeric region.

Topics: Animals; CHO Cells; Chromosome Deletion; Chromosomes, Human, Pair 11; Cricetinae; Demecolcine; Gamma Rays; Humans; Hybrid Cells; Monosomy; Mutagenicity Tests; Mutagens; Mutation; Ultraviolet Rays

In a previous publication we demonstrated that in cells of Vicia faba micronuclei derived from whole lagging chromosomes or chromatids may perform DNA synthesis and mitotic condensation in synchrony with main nuclei and be regained by main nuclei at the next mitosis, giving rise to trisomic cells together with diploids. This process was called 'mitotic indirect non-disjunction' (MIND). In the present work the occurrence of MIND was studied in human lymphocytes cultivated in vitro. Human lymphocytes were treated with low colcemid concentrations until fixation; BrUdR was supplied together with colcemid to distinguish the number of mitoses performed by the cells (M1, M2 and M3 cells). The frequencies of M1 ana-telophases with single lagging chromosomes/chromatids and of M2+ prophases with single micronuclei in synchronous motitic condensation with main nuclei were evaluated. On this basis the expected frequencies of both monosomic and trisomic M2 cells were calculated, according to the hypothesis of MIND. Their observed frequencies were very close to those expected. These results support the hypothesis of the occurrence of MIND in human lymphocytes.

Topics: Aneuploidy; Chromatids; Chromosomes, Human; Demecolcine; Female; Humans; In Vitro Techniques; Lymphocytes; Male; Micronuclei, Chromosome-Defective; Mitosis; Monosomy; Trisomy