DNA damage-related RNA expression to assess individual sensitivity to ionizing radiation

doi:10.1093/carcin/22.8.1179

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Carcinogenesis, Vol. 22, No. 8, 1179-1183, August 2001
© 2001 Oxford University Press

MOLECULAR EPIDEMIOLOGY AND CANCER PREVENTION

DNA damage-related RNA expression to assess individual sensitivity to ionizing radiation

Karine Bishay, Kathy Ory, Marie-Françoise Olivier, Jérôme Lebeau, Céline Levalois and Sylvie Chevillard^,1

CEA, DSV, DRR, 60–68 Avenue du Général Leclerc, BP6, 92265 Fontenay-aux-Roses Cedex, France

Predictive markers of intrinsic radiosensitivity in healthyindividuals are needed in monitoring their occupational or environmentalradiation exposure and may predict a patient's response to radiotherapy.Ionizing radiation can induce a large spectrum of DNA lesions,but under optimal DNA repair conditions, the principal residuallesions of importance are misrepaired double-strand breaks.The micronucleus (MN) assay represents a useful test in measuringradiosensitivity since it reflects non-repaired DNA breaks atthe time of cell division. Spontaneous and radiation-inducedMN vary greatly between individuals, and little is known aboutthe molecular mechanisms of this variability. DNA repair andapoptosis processes are involved in the cellular response toradiation-induced DNA damage, and variation in gene expressionrelated to these cellular pathways could be linked to individualradiosensitivity. In this study we analysed by real-time quantitativeRT–PCR the basal expression of 12 genes involved bothin DNA repair and apoptosis in a series of blood samples obtainedfrom 32 healthy male donors. Relationships between basal RNAexpressions and MN frequency and distribution per bi-nucleatedcell were studied after ex vivo irradiation of total blood samples.Our results indicate that the variability of mRNA gene expressionamong the 32 subjects appears to be of the same magnitude orhigher than that found for spontaneous or radiation-inducedMN frequency and that RAD51 gene expression is negatively correlatedwith radiation-induced MN frequency.

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