Conventional (i.e. genotoxic) anticancer drugs cause numerous side effects on normal tissue. These adverse effects are dose-limiting and severely impact the quality of life of cancer patients. Pharmacological inhibition of adverse tissue damage would be preferential in order to widen the therapeutic window of combined radio-chemotherapy and, in consequence, enable more efficient and better tolerable therapy of malignant diseases. Own preliminary data demonstrate that HMG-CoA reductase inhibitors (i.e. statins), which are believed to have pleiotropic cholesterol-independent effects by targeting Rac/Rho-signaling, mitigate adverse cytotoxic and genotoxic as well as inflammatory and pro-fibrotic responses of non-malignant cells in vitro and selected tissues in preclinical in vivo models following treatment with widely used anticancer drugs (e.g. doxorubicin, cisplatin) and irradiation (IR). Bearing in mind the multiple protective effects of statins and Rac-specific small-molecule inhibitors against different types of genotoxic drugs and towards different types of tissues/cell types, we hypothesize that these drugs interfere with superior molecular mechanisms involved in the pathophysiology of acute and chronic normal tissue damage resulting from anticancer therapeutics. The results of additional pharmacological studies provide cumulative evidence that the Ras-homologous GTPase Rac1 might be of particular relevance in this context. However, genetic evidence for this hypothesis is still missing. Yet, genetic data are essentially required to motivate novel clinical drug development. Therefore, the submitted proposal aims to verify Rac1 as promising target for the prevention of anticancer therapy-induced adverse tissue responses by employing a genetic rac1 knock-out mouse model. To this end, we intend to accomplish an inducible genetic deletion of the rac1 gene using the Rac1flox/flox/Mx1-Cre mouse model, which is already available to the applicant. Employing this poly-I:C inducible model system, rac1 can be extensively deleted in multiple cell types. Afterwards, comparative analyses using Rac1 proficient and Rac1 deficient animals will be performed to elucidate the impact of Rac1 on (i) the toxic effects of doxorubicin on the heart, (ii) the nephrotoxic effects of cisplatin and (iii) the toxic effects caused by fractionated irradiation of the lung. The working hypothesis is that Rac1-regulated signaling pathways are required for both acute and chronic normal tissue damage induced by anticancer therapeutics. In other words, we speculate that Rac1 deficiency is organoprotective in the context of anticancer therapy employing conventional drugs and irradiation. The project aims to validate Rac1 as therapeutic target for a tissue-overspanning prevention of multiple adverse effects of radio-chemotherapy.

DFG Programme Research Grants