DNA damage accumulation during fractionated low-dose radiation compromises hippocampal neurogenesis - Genome Dynamics in Neuroscience and Aging

Zoe Schmal ¹ Anna Isermann ¹ Daniela Hladik ² Christine Von Toerne ³ Soile Tapio ² Claudia Ruebe ¹

¹Department of Radiation Oncology, Saarland University, Homburg/Saar, Germany
²Institute of Radiation Biology, Helmholtz Zentrum Muenchen, German Research Center for Environmental Health GmbH, Neuherberg, Germany
³Research Unit Protein Science, Helmholtz Zentrum Muenchen, German Research Center for Environmental Health GmbH, Neuherberg, Germany

Background and Purpose: High-precision radiotherapy is an effective treatment modality for tumors. Intensity-modulated radiotherapy techniques permit close shaping of high doses to tumors, however healthy organs outside the target volume are repeatedly exposed to low-dose radiation (LDR). The inherent vulnerability of hippocampal neurogenesis is likely the determining factor in radiation-induced neurocognitive dysfunctions. Using preclinical in-vivo models with daily LDR we attempted to precisely define the pathophysiology of radiation-induced neurotoxicity.

Material and Methods: Genetically-defined mouse strains with varying DNA repair capacities were exposed to fractionated LDR (5x/10x/15x/20x0.1Gy) and dentate gyri from juvenile and adult mice were analyzed 72hours after last exposure and 1, 3, 6 months after 20x0.1Gy. To examine the impact of LDR on neurogenesis, persistent DNA damage was assessed by quantifying 53BP1-foci within hippocampal neurons. Moreover, subpopulations of neuronal stem/progenitor cells were quantified and dendritic arborization of developing neurons were assessed. To unravel molecular mechanisms involved in radiation-induced neurotoxicity, hippocampi were analyzed using mass spectrometry-based proteomics and affected signaling networks were validated by immunoblotting.

Results: Radiation-induced DNA damage accumulation leads to progressive decline of hippocampal neurogenesis with decreased numbers of stem/progenitor cells and reduced complexities of dendritic architectures, clearly more pronounced in repair-deficient mice. Proteome analysis revealed substantial changes in neurotrophic signaling, with strong suppression directly after LDR and compensatory upregulation later on to promote functional recovery.

Conclusion: Hippocampal neurogenesis is highly sensitive to repetitive LDR. Even low doses affect signaling networks within the neurogenic niche and interrupt the dynamic process of generation and maturation of neuronal stem/progenitor cells.