Radiation quality and mutagenesis in human lymphoblastoid cells.

An interesting problem associated with studying the effects of low doses of high atomic number and energy (HZE) particles, as found in space, is that not all cells will necessarily be similarly traversed during exposure, a scenario that greatly complicates the measurement of end points that require time to develop, gene-locus mutation being a perfect example. The standard protocol for measuring mutations at the heterozygous thymidine kinase locus in human lymphoblastoid cells involves waiting three days after treatment for newly induced mutants to fully express, at which time cells are then plated in the presence of the selective agent, and mutants are counted three weeks later. This approach is acceptable as long as all cells are uniformly affected, as is the case with low-linear energy transfer (LET) ionizing radiation.

Genetic susceptibility: radiation effects relevant to space travel.

Genetic variation in the capacity to repair radiation damage is an important factor influencing both cellular and tissue radiosensitivity variation among individuals as well as dose rate effects associated with such damage. This paper consists of two parts. The first part reviews some of the available data relating to genetic components governing such variability among individuals in susceptibility to radiation damage relevant for radiation protection and discusses the possibility and extent to which these may also apply for space radiations.

Radiation leukemogenesis in mice: loss of PU.1 on chromosome 2 in CBA and C57BL/6 mice after irradiation with 1 GeV/nucleon 56Fe ions, X rays or gamma rays. Part I. Experimental observations.

Since deletion of the PU.1 gene on chromosome 2 is a crucial acute myeloid leukemia (AML) initiating step in the mouse model, we quantified PU.1 deleted cells in the bone marrow of gamma-, X- and 56Fe-ion-irradiated mice at various times postirradiation.

Radiation sensitivity of primary fibroblasts from hereditary retinoblastoma family members and some apparently normal controls: colony formation ability during continuous low-dose-rate gamma irradiation.

We previously described an enhanced sensitivity for cell killing and G(1)-phase cell cycle arrest after acute gamma irradiation in primary fibroblast strains derived from 14 hereditary-type retinoblastoma family members (both affected RB1(+/-) probands and unaffected RB1(+/+) parents) as well as distinctive gene expression profiles in unirradiated cultures by microarray analyses. In the present study, we measured the colony formation ability of these cells after exposure to continuous low-dose-rate (0.5-8.

Cytotoxicity of cigarette smoke condensate is not due to DNA double strand breaks: Comparative studies using radiosensitive mutant and wild-type CHO cells.

Purpose: To determine whether cigarette smoke condensate (CSC) without metabolic activation induces direct DNA double strand breaks (DSB) in the G1 phase of various radiosensitive mutants of CHO cells and whether these breaks display collateral hypersensitivity to CSC with respect to cell killing.

Materials & Methods: We treated the G1-phase cultures of wild-type and DNA repair deficient mutants of CHO cells with various concentrations of CSC and examined the cell survival by colony formation assay and the induction of DNA double strand breaks by constant field gel electrophoresis as well as the phophorylated histone H2-A variant X (gamma-H2AX) assay.

Results: Gel analysis and gamma-H2AX focus assay showed significantly fewer, but still detectable levels of DSB per cell after CSC treatment compared to ionizing radiation (IR) exposures, even when equitoxic radiation exposures were delivered at a low dose rate over the same 8-hour exposure used for CSC treatments.