Argininosuccinate Synthase 1 is a Metabolic Regulator of Colorectal

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Letter

ASS1 is a Metabolic Regulator of Colorectal Cancer Pathogenicity Leslie A. Bateman, Wan-Min Ku, Martin J Heslin, Carlo M Contreras, Christine F. Skibola, and Daniel K. Nomura ACS Chem. Biol., Just Accepted Manuscript • DOI: 10.1021/acschembio.6b01158 • Publication Date (Web): 23 Feb 2017 Downloaded from http://pubs.acs.org on February 24, 2017

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Manuscript in preparation for ACS Chemical Biology

ASS1 is a Metabolic Regulator of Colorectal Cancer Pathogenicity

Leslie A. Bateman1, Wan-Min Ku, Martin J. Heslin2, Carlo M. Contreras2, Christine F. Skibola2, *, and Daniel K. Nomura1, * 1

Departments of Chemistry, Molecular and Cell Biology, and Nutritional Sciences and Toxicology, University of California, Berkeley, Berkeley, CA 94720 2

The University of Alabama at Birmingham, Birmingham, AL 35233

*Correspondence to [email protected] and [email protected]

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Abstract Like many cancer types, colorectal cancers have dysregulated metabolism that promotes their pathogenic features. In this study, we used the activity-based protein profiling chemoproteomic platform to profile cysteine-reactive metabolic enzymes that are upregulated in primary human colorectal tumors. We identified argininosuccinate synthase 1 (ASS1) as an upregulated target in primary human colorectal tumors and show that pharmacological inhibition or genetic ablation of ASS1 impairs colorectal cancer colorectal pathogenicity. Using metabolomic profiling, we show that ASS1 inhibition leads to reductions in the levels of oncogenic metabolite fumarate, leading to impairments in glycolytic metabolism that supports colorectal cancer cell pathogenicity. We show here that ASS1 inhibitors may represent a novel therapeutic approach for attenuating colorectal cancer through compromising critical metabolic and metabolite signaling pathways and demonstrate the utility of coupling chemoproteomic and metabolomic strategies to map novel metabolic regulators of cancer.

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Results and Discussion Cancer cells show dysregulated metabolism that underlies nearly every aspect of cancer pathogenicity. Among various cancers, nearly 50,000 people are expected to die from colorectal cancers with ~135,000 new estimated cases in 2016 making colorectal cancer the second most lethal cancer type, and thus new therapeutic targets need to be discovered to reduce this mortality rate associated with colorectal cancers. Here, we used a chemoproteomic strategy called activity-based protein profiling (ABPP) to map dysregulated metabolic enzyme targets that are important in colorectal cancer. ABPP uses reactivity-based chemical probes to map proteome-wide reactive, ligandable, and functional sites directly in complex proteomes 1–3. This strategy can be used to identify dysregulated protein targets in cancer, as well as sites of probe labeling which can potentially constitute ligandable sites or a binding pocket where smallmolecule ligands may bind 4,5. These reactive and ligandable sites of probe modification may in-turn be pharmacologically interrogated using various strategies such as covalent ligand discovery methods 4. Here, we used a broad cysteine-reactive iodoacetamide-alkyne (IAyne) probe to map dysregulated protein targets in primary human colorectal tumors compared to their matched normal colorectal tissue counterparts (Fig. 1A; Table S1) 5,6. We labeled colorectal tumor and normal colorectal tissue proteomes with the cysteine-reactive iodoacetamide-alkyne (IAyne) probe followed by conjugation of a biotin handle by copper-catalyzed azide-alkyne cycloaddition (CuAAC), avidin-enrichment, and proteomic profiling (Fig. 1A, B; Table S1). We profiled cysteine-reactivity in this study due to its functional importance in many types of metabolic enzymes, including the role of cysteine in enzyme catalysis, redox regulation, allosteric modulation, and metal binding 7. Proteomic analysis of probe-enriched protein targets yielded 555 total proteins. We then

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filtered these proteins for metabolic enzymes that were significantly heightened (p2-fold) in primary colorectal tumors compared to matched normal tissue counterparts, resulting in 10 lead metabolic enzyme candidates for further study. These targets included NNMT, IMPDH2, NT5C2, GMPS, FASN, NME1, COMT, GART, GPX2, and ASS1 (Fig. 1B). Due to limited amounts of tumor tissue, we could not perform detailed studies to quantitatively elucidate probe modification sites of cysteines labeled by IAyne on individual tumors and normal tissues. Instead, we performed isotopic tandem orthogonal proteolysis-enabled ABPP (isoTOP-ABPP) studies on pooled colorectal tumor tissue to quantitatively map cysteine reactivity in primary human colorectal tumors. We labeled pooled colorectal tumors with 100 µM versus 10 µM of IAyne, followed by appendage of an isotopically heavy (100 µM) or light (10 µM) biotin-azide analytical handle that bears a TEV protease cleavage site. Upon combining high versus low probe-treated proteomes in 1:1 ratio, we then enriched probe-modified tryptic peptides and analyzed heavy to light peptide ratios by quantitative proteomic methods (Fig. 1C; Table S1). In total, we identified 443 probe-modified tryptic peptides from primary human colorectal tumors. Those peptides that show stoichiometric IAyne labeling resulting in heavy to light ratios of ~10 are not considered hyper-reactive. In contrast, those probe-modified peptides that show heavy to light isotopic ratios of 2-fold over no-probe control). Shown on the right are just the metabolic enzymes enriched by IAyne. (B) Dysregulated metabolic enzyme targets. Metabolic enzyme targets from Fig. 1A that were significantly (p