Identification of Copper Metabolism as a KRAS-specific Vulnerability in Colorectal Cancer

Download or read book Identification of Copper Metabolism as a KRAS-specific Vulnerability in Colorectal Cancer written by Neethi Nandagopal and published by . This book was released on 2020 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: KRAS is amongst the most frequently mutated genes driving human cancers, including ~ 45% of colorectal cancers (CRC). Despite intense efforts to curb its oncogenic potential, mutant KRAS is frequently associated with drug resistance and is extremely challenging to target therapeutically. Cell-surface proteins are often spatially dysregulated in cancers and are attractive therapeutic targets due to their easy accessibility. We performed RNA sequencing of mutant KRAS-expressing intestinal epithelial cells and observed that cells undergoing transformation exhibited dramatic changes in cell surface-coding genes. Therefore, our goal was to identify novel druggable targets expressed at the cell surface of mutant KRAS-transformed cells. Using a cutting-edge cell surface proteomics approach, we identified several differentially expressed proteins at the surface of KRAS-mutant cells compared to wild-type counterparts. We then performed a cell surface based CRISPR/Cas9 screen, which revealed that loss of the copper exporter Atp7a differentially affected the fitness of intestinal epithelial cells, depending on their KRAS status. Interestingly, we found that ATP7A was upregulated in KRAS-mutant cells compared to wild-type counterparts. ATP7A has a dual role in cells; while it is essential for maturation of copper (Cu)-dependent enzymes, ATP7A protects cells from excess Cu-induced toxicity (cuproptosis). In humans, ATP7A mutations result in disorders characterized by systemic deficiencies in Cu transport and levels. In animals and in tissue culture models, including intestinal epithelial cells, intracellular Cu levels are directly correlated with the post-transcriptional abundance of ATP7A. In line with this, we observed that KRAS-mutant CRC cells and tissues had relatively more intracellular Cu, and ATP7A-overexpression protected KRAS-mutant cells from cuproptosis, compared to wild-type counterparts. We also observed that in vivo growth of KRAS-mutant xenografts was reduced when mice were fed a Cu-deficient diet. Cu is utilized by several enzymes that regulate critical cellular functions including mitochondrial respiration, cell motility and proliferation. We show that KRAS-mutant cells were more sensitive to the Cu chelating drug ammonium tetrathiomolybdate (TTM), compared to wild-type cells. Moreover, TTM-treated KRAS-mutant cells displayed reduced activities of Cu-dependent MEK1/2 and mitochondrial electron transport chain enzyme, cytochrome c oxidase (CCO). We were surprised to find that the high-affinity CTR1 importer is downregulated in KRAS-mutant cells, and so we hypothesized that KRAS cells must uptake Cu through alternate means. In accordance with this, we found that macropinocytosis acts as a non-canonical Cu-supply route in KRAS-mutant cells. In vivo, treating cells with the macropinocytosis inhibitor EIPA, inhibited the expression of ATP7A and decreased bioavailable Cu in KRAS xenografts. In conclusion, our results show that KRAS-mutant cells increase Cu and ATP7A levels, likely to support tumorigenesis by elevating cuproenzymatic activity and parallelly dealing with cuproptosis. This study is relevant to cancer as tumor tissues and patients contain higher Cu levels than normal controls. Recent studies have highlighted a potential for repurposing the clinically available copper chelator TTM, which is used to treat Cu disorders. Our results demonstrate that copper bioavailability could be exploited to treat KRAS-mutated CRC with such inhibitors. Future work includes identification of combinatorial strategies that may be synthetic lethal to copper chelation.