This Collaborative VA Merit Application (CMA) leverages expertise of accomplished researchers who formed a VA Colorectal Cancer (CRC) Cell-Genomics Consortium (VA4C) in May 2017. Cancer stem cells (CSCs) are critical mediators of carcinogenesis and induce cancer relapse resulting in poor outcomes. Glycosaminoglycans (GAGs), linear polysaccharides, that play a critical role in regulation of several hallmarks of cancer, engage various cell surface receptor targets, especially on CSCs. Yet, their biological potential in cancer has not been realized. Based on our highly intriguing recent observations that G2.2, a non-saccharide glycosaminoglycan mimetic (NSGM) of a natural GAG, selectively inhibits CSCs through an oppositely-directed mechanism involving growth factors, we propose that G2.2 is a novel, selective inhibitor of human CSCs. We hypothesize that unique NSGMs can selectively and potently inhibit colorectal CSC growth through a novel mechanism of antipodal pleiotropicity with respect to activation of growth factors. We propose three aims. We will test the efficacy of G2.2 in 50 well characterized CSCs enriched primary human colorectal spheroids/tumoroids as well as normal intestinal organoids, examine comprehensive CSC phenotype (self- renewal, migration, invasion, and chemotherapy resistance), and determine pharmacokinetic profile of the most promising NSGMs (Aim 1).
In Aim 2, we will determine molecular mechanism of G2.2 (and analogs). We will determine how antipodal pleiotropic effects arise, e.g., activation of fibroblast growth factor receptor (FGFRs) and inhibition of insulin-like growth factor 1 receptor (IGF1R), and alter pp38/pERK signaling ratio, which contributes to the CSC phenotype. Finally, in Aim 3, we will determine therapeutic utility of NSGMs in vivo by examining efficacy (specifically on CSCs) and toxicity (effect on normal stem cells) in advanced in vivo models of patient-derived xenografts (PDXs) or HT29 orthotopic xenografts either alone or in combination with chemotherapy (5-fluorouracil & oxaliplatin). The proposed studies will be greatly enhanced by collaborative merit process. Specifically, our collaboration with Drs. Mohapatra (Subhra)(Tampa), Raufman (Baltimore) Pisegna (Greater LA) within our cluster of Cancer Stem Cells in Pathology and Treatment of CRCs (CSCPT), as well as other VA4C collaborators including Mohapatra/Kelly (Tampa/Durham), and Dr. Bouvet (San Diego) will allow ? a) testing of NSGMs in novel tumoroid models for independent validation (Aim 1); b) decipher predictive biomarkers for NSGM effect through correlation of effect with muti-omics studies; and c) testing of NSGMs in novel animal models such as PDXs and distal colon orthotopic xenografts in Aim 3. Similarly, our expertise and knowledge gained through the proposal will be shared with Drs. Mohapatra and Raufman (CSC assays e.g. comprehensive analyses of CSC markers. CSC selectivity etc.), We will also assist other VA4C investigators in collecting blood, serum and tissue samples. The proposed studies are expected to help decipher novel CSCs signaling and develop unique GAG mimetics as prototypic agents for clinical use.
Glycosaminoglycans (GAGs) are ubiquitous in nature and play important role in cancer. They have been found to regulate critical properties of cancer stem cells (CSCs), which are responsible for cancer recurrence and mortality. We have discovered that a non-sugar mimetic called G2.2 and its analogs selectively inhibit CSCs. We propose to generate more effective analogs of G2.2 with improved drug-like properties, and study their molecular mechanisms of action to decipher CSC biology, especially glycobiology, and develop novel anti-cancer therapies that address the issues of remission and/or cure.
