Abstract (Project 1 - Oxford) Increasing the therapeutic window of radiotherapy may be achieved by using targeted therapies against cancer- associated pathways. The complement system is an innate immunity pathway, with emerging roles in cancer progression. No study has evaluated the effect of complement inhibition on both tumor and normal tissue radiation response. Here we show that targeting complement receptor C5aR1 improves radiation response in colorectal cancer models while reducing radiation-induced toxicity. Targeting C5aR1 increases IL-10 secretion, which attenuates NF-κB signaling and enhances apoptosis in tumor cells. IL-10-dependent apoptosis is observed both in vivo and in vitro suggesting a non-canonical stress-specific and likely immune-independent role for C5aR1 in regulating apoptosis. Importantly, we find that C5aR1 depletion results in decreased small intestinal histologic damage, crypt cell apoptosis and increased survival of mice following irradiation. In the small intestine, C5aR1 depletion results in increased IL-10 expression in both non-immune and immune cell populations. IL-10 signaling in CX3CR1+ macrophages is important for intestinal injury defense and C5aR1-/- mice have significantly higher levels of CX3CR1+ macrophages than WT mice. In response to irradiation, C5aR1 depletion does not attenuate NF-κB signaling but instead increases AKT activation correlating with decreased apoptosis occurring in an IL-10-depedent manner. Our data, therefore, indicate that genetically or pharmacologically targeting C5aR1 can improve radiation response in colorectal tumor models while reducing radiation-induced small bowel toxicity. Together, these findings suggest that inhibiting complement could be a promising approach to increasing the therapeutic window of radiotherapy. In this Project, we propose four specific aims to better understand the role of C5aR1 in radioprotection and radiosensitization. Aim 1 will determine the broad versus specific protection of normal epithelium (intestines, salivary glands, and lung epithelium) by C5aR1-/- mice in response fractionated and hypofractionated radiotherapy, in collaboration with Projects 2, 3, 4 and Core B. In Aim 2, we will investigate the mechanistic basis of radioprotection when C5aR1 is inhibited. Our preliminary data indicates that this is an IL-10 dependent mechanism and involves recruitment of CX3CR1+ macrophages that promote survival and angiogenesis. Aim 3 will determine how C5aR1 promotes tumor cell killing in combination with radiotherapy. The hypothesis based on our preliminary data is that C5aR1 inhibition increases IL-10 secretion, which attenuates NF-κB signaling, resulting in IL-10 dependent tumor cell killing both in cell culture and in animal models. Aim 4 will determine the effect of clinical grade C5aR1 inhibitors on radioprotecting intestine, salivary glands and lungs, and sensitizing colorectal tumors to radiotherapy. I intend to return to Stanford on a monthly or bim...