Mechanisms of chromosomal aberration production I. Aberration induction by ultraviolet light

We have studied chromosomal aberration production in V-79 Chinese hamster tissue culture cells by UV light administered during the post-DNA-synthetic G₂ phase of the cell cycle. The treatment produced achromatic lesions and some chromatid deletions in the first post-irradiation mitosis, but no isochromatid deletions or chromatid exchange aberrations. In contrast, when G₂ UV-irradiated cells were examined in their second post-irradiation mitosis, there were significant yields of chromatid-type aberrations of all types, including isochromatid deletions and chromatid exchanges.

We have earlier reported²¹ that UV-irradiation during the pre-DNA-synthetic G₁ phase of the cell cycle induces only chromatid aberrations and also that most chromosomal aberration production by UV in G₁ can be photoreactivated in cells possessing the photoreactivating enzyme. We present here a model for chromosomal aberration production by UV. In the model all aberration production is enzymatically mediated, a consequence of the functioning of known molecular repair mechanisms. The important elements in the model are the following:

1. (1) The vertebrate chromosome is mononeme; i.e., contains but a single DNA double helix during the prereplication G₁ phase of the cell cycle.

2. (2) The UV-induced DNA lesion leading to the production of most aberrations is the cyclobutane dimer between adjacent pyrimidines in one polynucleotide strand.

3. (3) Single chain breaks appear at metaphase as achromatic lesions.

4. (4) Dimer removal sometimes leaves unrepaired single chain gaps, possibly as a result of incomplete excision repair.

5. (5) The single-stranded DNA opposite a single chain gap can be cleaved by a single-strand DNAase.

6. (6) Gaps are left in newly synthesized DNA polynucleotide chains opposite defective template chains (i.e., opposite dimers and chain breaks).

7. (7) Double-strand breaks present following local DNA replication may “spread” to the other chromatid by a recombinational process between template and new polynucleotide chains, one from each of the homologous double helices.

The model predicts the occurrence of isoachromatic lesions and of chromatid deletions paired (isolocus) with achromatic lesions. Though often not reported, both do, in fact, occur. In addition, the model accounts for the phenomenon of sister-chromatid exchange as a manifestation of a recombinational, or post-replication, repair mechanism. Finally, the model offers a simple interpretation of chromosomal aberration production by a variety of chemical agents.