Long-term effects of ionizing radiation on gene expression in a zebrafish model.

Long-term effects of ionizing radiation on gene expression in a zebrafish model.

Blog Article

Understanding how initial radiation injury translates into long-term effects is an important problem in radiation biology.Here, we define a set of changes in the transcription profile that are associated with the long-term response weboost splitter to radiation exposure.The study was performed in vivo using zebrafish, an established radiobiological model organism.To study the long-term response, 24 hour post-fertilization embryos were exposed to 0.

1 Gy (low dose) or 1.0 Gy (moderate dose) of whole-body gamma radiation and allowed to develop for 16 weeks.Liver mRNA profiles were then analyzed using the Affymetrix microarray platform, with validation by quantitative PCR.As a basis for comparison, 16-week old adults were exposed at the same doses and analyzed after 4 hours.

Statistical analysis was performed in a way to minimize the effects of multiple comparisons.The responses to these two treatment regimes differed greatly: 360 probe sets were associated primarily with the long-term response, whereas a different 2062 probe sets were associated primarily with the response when adults of the same age were irradiated 4 hours before exposure.Surprisingly, a ten-fold difference in radiation dose (0.1 versus 1.

0 Gy) had little effect.Analysis at the gene and pathway level indicated that the long-term response includes the induction of cytokine and inflammatory regulators and transcription and growth factors.The acute read more response includes the induction of p53 target genes and modulation of the hypoxia-induced transcription factor-C/EBP axis.Results help define genes and pathways affected in the long-term, low and moderate dose radiation response and differentiate them from those affected in an acute response in the same tissue.