Evidence for significant heritability of apoptotic and cell cycle responses to ionising radiation.

Genetic factors are likely to affect individual cancer risk, but few quantitative estimates of heritability are available. Public health radiation protection policies do not in general take this potentially important source of variation in risk into account. Two surrogate cellular assays that relate to cancer susceptibility have been developed to gain an insight into the role of genetics in determining individual variation in radiosensitivity. These flow cytometric assays for apoptosis induction and cell cycle delay following radiation are sufficiently sensitive to distinguish lymphocytes from a healthy donor population from those of a sample of obligate carriers of ATM mutations (P = 0.01 and P = 0.02, respectively). Analysis of 54 unselected twin pairs (38 dizygotic, 16 monozygotic) indicated much greater intrapair correlation in response in monozygotic than in dizygotic pairs. Structural equation modelling indicated that models including unique environmental factors only fitted the data less well than those incorporating two or more of additive genetic factors, common environmental factors and unique environmental factors. A model incorporating additive genetic factors and unique environmental factors yielded estimates of heritability for the two traits of 68% (95% CI 40-82%, cell cycle) and 59% (95% CI 22-79%, apoptosis). Thus, these data suggest that genetic factors contribute significantly to human variation in these two measures of radiosensitivity that relate to cancer susceptibility.

Interaction of human SUV3 RNA/DNA helicase with BLM helicase; loss of the SUV3 gene results in mouse embryonic lethality.

The SUV3 gene is present in all eukaryotes and encodes an RNA/DNA helicase which operates both in mitochondria and cell nuclei. To assess its function in mammals we generated a mouse mutant strain in which the 3' part of the SUV3 gene is disrupted. The mutated allele is a hypomorph transmitted from one generation to another at a frequency about 35% lower than expected while mice homozygous for the mutation die in utero before midgestation. Using ELISA binding assays we show that human SUV3 protein interacts with human WRN and BLM helicases. The binding to BLM protein was 10-fold stronger (with a K(d) of 0.5nM) than to WRN protein (K(d) of 5nM). Silencing of the SUV3 gene in the human cell line HeLa resulted in elevation of homologous recombination as measured by the frequency of sister chromatid exchange during mitotic cell division. These results indicate that the SUV3 protein is required in mammalian development and in somatic cells participates in genome maintenance through interaction with other genome fidelity housekeepers.