Structural modification of oxazolidinone antibiotics alters nascent peptide stalling preference and peptide trajectory through the ribosome.

The oxazolidinone antibiotic linezolid binds to the peptidyl transferase center of the ribosome, where it inhibits a subset of peptide bond formation events. This context-specificity of translation inhibition is dictated by the nature of the amino acid at the penultimate position of the nascent peptide. It remains unknown whether this is a general feature of oxazolidinones and whether it can be modulated by their structural alterations. Here, we show that the oxazolidinone tedizolid also inhibits translation in a context-specific manner, but with dramatically altered selectivity, favoring Ile, His, and Gln as the penultimate residues. Delpazolid, which shares the C5 hydroxymethyl moiety with tedizolid, shows a similar preference. Structural analysis of the ribosome with tedizolid and a stalled nascent peptide showed a compacted, helical conformation of the nascent chain induced by the drug. Our findings reveal that stalling preferences of oxazolidinones can be modulated by structural modifications within this antibiotic class.