Aminoacyl-tRNA synthetases, the essential enzyme family for protein translation, are attractive targets for developing antibacterial, antifungal, and antiparasitic agents and for treating other human diseases. The antimalarial natural product cladosporin was discovered recently as a novel lysyl-tRNA synthetase (LysRS) specific inhibitor. Here, we report a thorough analysis of cladosporin derivatives using chemical synthesis, biophysical, and biochemical experiments. A series of isocoumarin derivatives with only one nonhydrogen atom/bond change per compound was synthesized. These changes include replacements of methyltetrahydropyran moiety by methylcyclohexane or cyclohexane, lactone by lactam, hydroxyl groups by methoxyl groups, and dismission of the chiral center at C3 with a Δ 3,4 double bond. We evaluated these compounds by thermal shift assays and enzymatic experiments and further studied their molecular recognition by the Plasmodium falciparum LysRS through total five high-resolution crystal structures. Our results showed that the methyltetrahydropyran moiety of cladosporin could be replaced by a more stable methylcyclohexane without reducing binding ability. Removing the methyl group from the methylcyclohexane moiety slightly decreased the interaction with LysRS. Besides, the replacement with a lactam group or a conjugated Δ 3,4 double bond within the scaffold could be two more options to optimize the compound. Lastly, the two phenolic hydroxyl groups were critical for the compounds to bind LysRS. The detailed analyses at atomic resolution in this study provide a foundation for the further development of new antibiotics from cladosporin derivatives.
Aminoacyl-tRNA synthetases are attractive targets for the development of antibacterial, antifungal, antiparasitic agents and for the treatment of other human diseases. Lysyl-tRNA synthetase (LysRS) from this family has been validated as a promising target for the development of antimalarial drugs. Here, we developed a high-throughput compatible assay and screened 1215 bioactive compounds to identify Plasmodium falciparum cytoplasmic LysRS (PfLysRS) inhibitor. ASP3026, an anaplastic lymphoma kinase inhibitor that was used in clinical trials for the treatment of B-cell lymphoma and solid tumors, was identified as a novel PfLysRS inhibitor. ASP3026 suppresses the enzymatic activity of PfLysRS at nanomolar potency, which is >380-fold more effective than inhibition of the human counterpart. In addition, the compound suppressed blood-stage P. falciparum growth. To understand the molecular mechanism of inhibition by ASP3026, we further solved the cocrystal structure of PfLysRS-ASP3026 at a resolution of 2.49 Å, providing clues for further optimization of the compound. Finally, primary structure-activity relationship analyses indicated that the inhibition of PfLysRS by ASP3026 is highly structure specific. This work not only provides a new chemical scaffold with good druggability for antimalarial development but also highlights the potential for repurposing kinase-inhibiting drugs to tRNA synthetase inhibitors to treat human diseases.
Aminoacyl-tRNA synthetases (AARSs), a family of essential protein synthesis enzymes, are attractive targets for drug development. Although several different types of AARS inhibitors have been identified, AARS covalent inhibitors have not been reported. Here we present five unusual crystal structures showing that threonyl-tRNA synthetase (ThrRS) is covalently inhibited by a natural product, obafluorin (OB). The residue forming a covalent bond with OB is a tyrosine in ThrRS active center, which is not commonly modified by covalent inhibitors. The two hydroxyl groups on the o-diphenol moiety of OB form two coordination bonds with the conserved zinc ion in the active center of ThrRS. Therefore, the β-lactone structure of OB can undergo ester exchange reaction with the phenolic group of the adjacent tyrosine to form a covalent bond between the compound and the enzyme, and allow its nitrobenzene structure to occupy the binding site of tRNA. In addition, when this tyrosine was replaced by a lysine or even a weakly nucleophilic arginine, similar bonds could also be formed. Our report of the mechanism of a class of AARS covalent inhibitor targeting multiple amino acid residues could facilitate approaches to drug discovery for cancer and infectious diseases.
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