No influence of serotonin levels in foetal bovine sera on radiation-induced bystander effects and genomic instability.

PURPOSE: The aim of this study was to contribute to an inter-laboratory investigation within the Non-Targeted Effects of Ionising Radiation Integrated project (NOTE) (2006-2010) to investigate the role of serum serotonin concentration on radiation-induced bystander effects using our successful experimental design. Two sera of high and low serotonin levels were tested alongside standard serum used in our laboratory. MATERIALS AND METHODS: Primary Human Fibroblast 19 (HF19) cells were sham/irradiated with 0.5 Gy alpha-particles, in medium supplemented with serum of different levels of serotonin. Filtered medium was transferred to unirradiated HF19 bystander cells. Cells from irradiated and bystander populations were harvested for chromosomal analysis at early and delayed times post-irradiation/media transfer to assess initial damaging effects and induction of delayed chromosomal instability respectively. RESULTS: Chromosomal damage was elevated to significant levels (p = ≤ 0.005) above respective controls in both cell populations in all groups. Induction of delayed chromosomal instability was significantly observed in all groups at delayed time post irradiation/medium transfer. Furthermore, induction of bystander effects at early and delayed times was not significantly different between groups. CONCLUSIONS: No effect of serotonin on the induction of either bystander effects of genomic instability was observed using this experimental system.

Genomic instability after targeted irradiation of human lymphocytes: evidence for inter-individual differences under bystander conditions.

Environmental (222)radon exposure is a human health concern, and many studies demonstrate that very low doses of high LET alpha-particle irradiation initiate deleterious genetic consequences in both irradiated and non-irradiated bystander cells. One consequence, radiation-induced genomic instability (RIGI), is a hallmark of tumorigenesis and is often assessed by measuring delayed chromosomal aberrations. We utilised a technique that facilitates transient immobilization of primary lymphocytes for targeted microbeam irradiation and have reported that environmentally relevant doses, e.g. a single (3)He(2+) particle traversal to a single cell, are sufficient to induce RIGI. Herein we sought to determine differences in radiation response in lymphocytes isolated from five healthy male donors. Primary lymphocytes were irradiated with a single particle per cell nucleus. We found evidence for inter-individual variation in radiation response (RIGI, measured as delayed chromosome aberrations). Although this was not highly significant, it was possibly masked by high levels of intra-individual variation. While there are many studies showing a link between genetic predisposition and RIGI, there are few studies linking genetic background with bystander effects in normal human lymphocytes. In an attempt to investigate inter-individual variation in the induction of bystander effects, primary lymphocytes were irradiated with a single particle under conditions where fractions of the population were traversed. We showed a marked genotype-dependent bystander response in one donor after exposure to 15% of the population. The findings may also be regarded as a radiation-induced genotype-dependent bystander effect triggering an instability phenotype.

Tracking genomic instability within irradiated and bystander populations.

Over the past two decades, our understanding of radiation biology has undergone a fundamental shift in paradigms away from deterministic 'hit-effect' relationships and towards complex ongoing 'cellular responses'. These responses include now familiar, but still poorly understood, phenomena associated with radiation exposure such as genomic instability and bystander effects. Although these responses share some common features (e.g. they occur at high frequency following very low doses, are heterogeneous in their induction and are observed at time points far removed from the initial radiation exposure), the precise relationship between genomic instability and bystander effects remains to be elucidated. This review will provide a synthesis of the known, and proposed, interrelationships among irradiated and bystander cellular responses to radiation. It also discusses our current experimental approach for gaining a clearer understanding of the relationship between damage induction and long-term effects in both irradiated and bystander cells.