(PQ9)A redox-mediated mechanism of chemotherapy-induced cognitive impairment
Bondada, Subbarao    Butterfield, David Allan    St Clair, Daret K.   
University of Kentucky, Lexington, KY, United States

This application addresses the Provocative Question 9: What are the molecular and/or cellular mechanisms that underlie the development of cancer therapy-induced severe adverse sequelae? focusing on Chemotherapy-induced cognitive impairments (CICI). CICI is now a recognized toxicity syndrome that includes loss of executive function (confusion; memory issues), inability to multitask, and impaired intellectual reasoning. While CICI caused by central nervous system (CNS)-directed therapies (such as radiation and intrathecal chemotherapy) is readily understood, the mechanisms underlying a critical and shared toxicity of chemotherapy that occurs after systemic cancer treatment with drugs that did not direct at the brain, are unclear. The number of patients at risk for CICI from systemic therapy far exceeds the number of patients exposed to CNS therapy, but little is known about the mechanisms mediating the effect of systemic therapy on CICI, and there is no clear vision of how to prevent this condition. We have previously shown that generation of reactive oxygen species (ROS) by cytotoxic chemotherapeutic drugs is an essential mediator of brain injury even though the drug itself did not get into the brain. It is also imperative to note that anticancer medications, designed specifically to target cancer cells with specialized features, such as the family of Bcl2 inhibitors, also generate ROS. However, the effect of targeted therapy on CICI has never been addressed, and, consequently, their mechanisms of action are entirely unknown. The goal of this proposal is to test the overall hypothesis that therapy-induced ROS production in the target tissues leads to increased circulating TNF? through extracellular vesicles (EVs)-mediated reactions, and this pro-inflammatory cytokine crosses the blood brain barrier to elicit mitochondrial dysfunction and consequent neuronal injury leading to CICI. The following specific aims are designed to test the ROS hypothesis, gain an understanding of the EVs-mediated mechanisms, and test the proof-of-concept in an experimental cancer therapy setting using two prototype chemotherapy agents (Doxorubicin and Venetoclax) that represent standard cytotoxic and experimental targeted drugs in a lymphoma model.
Aim 1 will investigate the fundamental role of TNF? in therapy-induced neuronal injury to gain insights into mechanisms of CICI in the brain and demonstrate efficacy of chemotherapy in the presence of redox-active antioxidants.
Aim 2 will determine the mechanistic links between circulating extracellular vesicles and therapy-induced CICI.
Aim 3 will define the cell(s) of origin of TNF? produced during chemotherapy that leads to cognitive impairment.
These aims will be accomplished in vitro and in vivo using state-of-the-art technologies, including magnetic resonance spectroscopy, redox proteomics, unique animal models, and novel mitochondria targeting anti-oxidant, MnP, to ameliorate CICI without reducing the efficacy of the anti-cancer drugs. The results from this project will lay important groundwork for future clinical trials to improve the quality of lives of cancer patients exposed to cytotoxic or targeted therapies.

Public Health Relevance

Chemotherapy-induced cognitive impairment (CICI) is a serious threat to the quality of life. This project is designed to identify practice-changing therapy by establishing a new paradigm, which recognizes that ROS is the initiator of CICI, caused by both cytotoxic and targeted drugs. Results from these studies will lead to very concrete information potentially offering a specific course of action to develop effective clinical approaches specifically designed to prevent CICI without reducing chemotherapeutic efficacy.