2 research outputs found
Borrelidin B: Isolation, Biological Activity, and Implications for Nitrile Biosynthesis
Borrelidin (<b>1</b>) is a
nitrile-containing bacterially
derived polyketide that is a potent inhibitor of bacterial and eukaryotic
threonyl-tRNA synthetases. We now report the discovery of borrelidin
B (<b>2</b>), a tetrahydro-borrelidin derivative containing
an aminomethyl group in place of the nitrile functionality in borrelidin.
The discovery of this new metabolite has implications for both the
biosynthesis of the nitrile group and the bioactivity of the borrelidin
compound class. Screening in the SToPS assay for tRNA synthetase inhibition
revealed that the nitrile moiety is essential for activity, while
profiling using our in-house image-based cytological profiling assay
demonstrated that <b>2</b> retains biological activity by causing
a mitotic stall, even in the absence of the nitrile motif
Charting the sequence-activity landscape of peptide inhibitors of translation termination
Apidaecin (Api), an unmodified 18-amino-acid-long proline-rich antibacterial peptide produced by bees, has been recently described as a specific inhibitor of translation termination. It invades the nascent peptide exit tunnel of the postrelease ribosome and traps the release factors preventing their recycling. Api binds in the exit tunnel in an extended conformation that matches the placement of a nascent polypeptide and establishes multiple contacts with ribosomal RNA (rRNA) and ribosomal proteins. Which of these interactions are critical for Api's activity is unknown. We addressed this problem by analyzing the activity of all possible single-amino-acid substitutions of the Api variants synthesized in the bacterial cell. By conditionally expressing the engineered api gene, we generated Api directly in the bacterial cytosol, thereby bypassing the need for importing the peptide from the medium. The endogenously expressed Api, as well as its N-terminally truncated mutants, retained the antibacterial properties and the mechanism of action of the native peptide. Taking advantage of the Api expression system and next-generation sequencing, we mapped in one experiment all the single-amino-acid substitutions that preserve or alleviate the on-target activity of the Api mutants. Analysis of the inactivating mutations made it possible to define the pharmacophore of Api involved in critical interactions with the ribosome, transfer RNA (tRNA), and release factors. We also identified the Api segment that tolerates a variety of amino acid substitutions; alterations in this segment could be used to improve the pharmacological properties of the antibacterial peptide