Can neural signals override cellular decisions in the presence of DNA damage?

Cells within an organism are in constant crosstalk with their surrounding environment. Short and long-range signals influence cellular behavior associated with division, differentiation, and death. This crosstalk among cells underlies tissue renewal to guarantee faithful replacement of old or damaged cells over many years. Renewing tissues also offer recurrent opportunities for DNA damage and cellular transformation that tend to occur with aging. Most cells with extensive DNA damage have limited options such as halting cell cycle to repair DNA, undergo senescence, or programmed cell death. However, in some cases cells carrying toxic forms of DNA damage survive and proliferate. The underlying factors driving survival and proliferation of cells with DNA damage remain unknown. Here we discuss potential roles the nervous system may play in influencing the fate of cells with DNA damage. We present a brief survey highlighting the implications the nervous system has in regeneration, regulation of stem cells, modulation of the immune system, and its contribution to cancer progression. Finally, we propose the use of planarian flatworms as a convenient model organism to molecularly dissect the influence of neural signals over cellular fate regulation in the presence of DNA damage.