Coibamide A (CbA) is a marine natural product with potent antiproliferative activity against human cancer cells and a unique selectivity profile. Despite promising antitumor activity, the mechanism of cytotoxicity and specific cellular target of CbA remain unknown. Here, we develop an optimized synthetic CbA photoaffinity probe (photo-CbA) and use it to demonstrate that CbA directly targets the Sec61α subunit of the Sec61 protein translocon. CbA binding to Sec61 results in broad substrate-nonselective inhibition of ER protein import and potent cytotoxicity against specific cancer cell lines. CbA targets a lumenal cavity of Sec61 that is partially shared with known Sec61 inhibitors, yet profiling against resistance conferring Sec61α mutations identified from human HCT116 cells suggests a distinct binding mode for CbA. Specifically, despite conferring strong resistance to all previously known Sec61 inhibitors, the Sec61α mutant R66I remains sensitive to CbA. A further unbiased screen for Sec61α resistance mutations identified the CbA-resistant mutation S71P, which confirms nonidentical binding sites for CbA and apratoxin A and supports the susceptibility of the Sec61 plug region for channel inhibition. Remarkably, CbA, apratoxin A, and ipomoeassin F do not display comparable patterns of potency and selectivity in the NCI60 panel of human cancer cell lines. Our work connecting CbA activity with selective prevention of secretory and membrane protein biogenesis by inhibition of Sec61 opens up possibilities for developing new Sec61 inhibitors with improved drug-like properties that are based on the coibamide pharmacophore.
The mandelalides are complex macrolactone natural products with distinct macrocycle motifs and a bioactivity profile that is heavily influenced by compound glycosylation. Mandelalides A and B are direct inhibitors of mitochondrial ATP synthase (complex V) and therefore more toxic to mammalian cells with an oxidative metabolic phenotype. To provide further insight into the pharmacology of the mandelalides, we studied the AMP-activated protein kinase (AMPK) energy stress pathway and report that mandelalide A is an indirect activator of AMPK. Wild-type mouse embryonic fibroblasts (MEFs) and representative human non-small cell lung cancer (NSCLC) cells showed statistically significant increases in phospho-AMPK (Thr172) and phospho-ACC (Ser79) in response to mandelalide A. Mandelalide L, which also harbors an A-type macrocycle, induced similar increases in phospho-AMPK (Thr172) and phospho-ACC (Ser79) in U87-MG glioblastoma cells. In contrast, MEFs co-treated with an AMPK inhibitor (dorsomorphin), AMPKα-null MEFs, or NSCLC cells lacking liver kinase B1 (LKB1) lacked this activity. Mandelalide A was significantly more cytotoxic to AMPKα-null MEFs than wild-type cells, suggesting that AMPK activation serves as a protective response to mandelalide-induced depletion of cellular ATP. However, LKB1 status alone was not predictive of the antiproliferative effects of mandelalide A against NSCLC cells. When EGFR status was considered, erlotinib and mandelalide A showed strong cytotoxic synergy in combination against erlotinib-resistant 11-18 NSCLC cells but not against erlotinib-sensitive PC-9 cells. Finally, prolonged exposures rendered mandelalide A, a potent and efficacious cytotoxin, against a panel of human glioblastoma cell types regardless of the underlying metabolic phenotype of the cell. These results add biological relevance to the mandelalide series and provide the basis for their further pre-clinical evaluation as ATP synthase inhibitors and secondary activators of AMPK.
The genome of entomopathogenic fungus Tolypocladium inflatum Gams encodes 43 putative biosynthetic gene clusters for specialized metabolites, although genotype−phenotype linkages have been reported only for the cyclosporins and fumonisins. T. inflatum was cultured in defined minimal media, supplemented with or without one of nine different amino acids. Acquisition of LC-MS/MS data for molecular networking and manual analysis facilitated annotation of putative known and unknown metabolites. These data led us to target a family of peptaibols and guided the isolation and purification of tolypocladamide H (1), which showed modest antibacterial activity and toxicity to mammalian cells at micromolar concentrations. HRMS/MS, NMR, and advanced Marfey's analysis were used to assign the structure of 1 as a peptaibol containing 4-[(E)-2-butenyl]-4-methyl-L-threonine (Bmt), a hallmark structural motif of the cyclosporins. LC-MS detection of homologous tolypocladamide metabolites and phylogenomic analyses of peptaibol biosynthetic genes in other cultured Tolypocladium species allowed assignment of a putative tolypocladamide nonribosomal peptide synthetase gene.
Coibamide A is a cyclopeptide natural product with potent antiproliferative activity against cultured human cancer cells and subcutaneous U87-MG glioblastoma tumors in mice. We have recently determined that coibamide A binds to the Sec61 translocon channel at a site that is close, but not identical, to the binding site of the peptide/polyketide natural product apratoxin A. As the majority of secreted proteins in mammalian cells are trafficked through the conventional secretory pathway via the Sec61 translocon, this raised the possibility that coibamide A and apratoxin A block import and secretion of different Sec61 client proteins. In the present study, we analyzed and compared the secretome of human U87-MG glioblastoma cells in the presence and absence of both marine natural products. U87-MG glioblastoma cells were treated with coibamide A (5 nM), apratoxin A (5 nM), or vehicle for 24 h. The growth media was then replaced with serum-free media for a further 24 h. Tryptic proteomic samples were generated from cell-free conditioned media and analyzed on a LC-coupled Orbitrap Fusion mass spectrometer. The high-resolution Orbitrap mass analyzer was used to both identify precursor ions for tandem mass (MS2) analysis in the ion trap mass analyzer and to quantitate those ions (MS1). Secreted proteins were identified from peptide–spectrum matches to the human protein database using a decoy database to assign an FDR and quantified from their MS1 ion intensities. Comparison of mass spectrometric data against the human secretome database revealed 175 proteins in the U87-MG cell secretome that were identified with high confidence. Differences between coibamide A and apratoxin A treatment were not significant, however both Sec61 inhibitors induced significant suppression of the U87-MG secretome relative to vehicle-treated cells. Treatment with coibamide A or apratoxin A resulted in the reduction of 75% of quantifiable secretome (131 proteins). Of the remaining 44 proteins, 34 are directed to intracellular organelles or contain a motif associated with retention in the endoplasmic reticulum and 10 were not suppressed with treatment but were hypothesized to be Sec61 clients. Malignant glioblastoma cells secrete proteins into the extracellular space and use complex intercellular signaling mechanisms for a survival advantage. Our results indicate that broad-acting inhibitors of Sec61-dependent co-translational translocation block the progression of a significant percentage of the U87-MG glioblastoma cell secretome including several proteins that have previously been detected as biomarkers in the cerebrospinal fluid, blood, or urine of brain tumor patients. Taken together, our work illustrates the feasibility of inducing a reversible suppression of numerous (undrugged) extracellular signals by targeting Sec61-dependent protein biogenesis in the secretory pathway with drug-like molecules. Citation Format: Daphne R. Mattos, Jeffrey D. Serrill, Philip R. Gafken, Kerry L. McPhail, Walter K. Vogel, Jane E. Ishmael. Cyanobacterial natural product Sec61α inhibitors induce broad suppression of the glioma cell secretome [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3916.
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