1. Identifying the Cellular Target of Cordyheptapeptide A and Synthetic Derivatives
- Author
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Alexandra C Turmon, Matthew R. Naylor, R. Scott Lokey, Okimasa Okada, Hao-Yuan Wang, Walter M. Bray, Joshua Schwochert, Quinn Edmondson, Satoshi Ono, Jack Taunton, Victoria G. Klein, and Justin H Faris
- Subjects
Protein Synthesis Inhibitors ,chemistry.chemical_classification ,Molecular Structure ,Membrane permeability ,Chemistry ,Antineoplastic Agents ,General Medicine ,Peptides, Cyclic ,Biochemistry ,Article ,Cyclic peptide ,Elongation factor ,Structure-Activity Relationship ,Peptide Elongation Factor 1 ,Eukaryotic translation ,Cell culture ,Cell Line, Tumor ,Protein Biosynthesis ,Side chain ,Humans ,Molecular Medicine ,Cytotoxicity ,Solid-Phase Synthesis Techniques ,Intracellular - Abstract
Cordyheptapeptide A is a lipophilic cyclic peptide from the prized Cordyceps fungal genus that shows potent cytotoxicity in multiple cancer cell lines. To better understand the bioactivity and physicochemical properties of cordyheptapeptide A with the ultimate goal of identifying its cellular target, we developed a solid-phase synthesis of this multiply N-methylated cyclic heptapeptide which enabled rapid access to both side chain- and backbone-modified derivatives. Removal of one of the backbone amide N-methyl (N-Me) groups maintained bioactivity, while membrane permeability was also preserved due to the formation of a new intramolecular hydrogen bond in a low dielectric solvent. Based on its cytotoxicity profile in the NCI-60 cell line panel, as well as its phenotype in a microscopy-based cytological assay, we hypothesized that cordyheptapeptide was acting on cells as a protein synthesis inhibitor. Further studies revealed the molecular target of cordyheptapeptide A to be the eukaryotic translation elongation factor 1A (eEF1A), a target shared by other lipophilic cyclic peptide natural products. This work offers a strategy to study and improve cyclic peptide natural products while highlighting the ability of these lipophilic compounds to effectively inhibit intracellular disease targets.
- Published
- 2021
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