Infections caused by Staphylococcus aureus are closely linked to its ability to secure essential nutrients, including iron, which is extracted from the heme of human hemoglobin (Hb) through the iron-regulated surface determinant (Isd) system. The compound 4-[[2-[[5- (1H-indol-3-yl)-1,3,4-oxadiazol-2-yl]sulfanyl]acetyl]amino]benzoate (C35) was recently identified as a new potential antimicrobial agent for its ability to bind Hb and hamper its interaction with the staphylococcal hemophore IsdB in vitro. Here, we show that C35 inhibits S. aureus growth by specifically targeting the hemophore-driven iron acquisition system. Our findings confirm both the potential of C35 as a first-in-class protein-protein interaction inhibitor with antimicrobial activity, and the effectiveness of targeting hemophores as a strategy to inhibit S. aureus growth. To gain information for drug discovery purposes, the X-ray structure of Hb in the presence of the compound was solved. Unexpectedly, we discovered that, rather than the predicted binding pose, the molecule binds to tetrameric Hb in a cleft between the alpha subunits, stabilizing an R2 relaxed Hb conformation. This triggered further investigation of the effect of C35 on Hb functional properties, which showed a pronounced left-shift activity on oxygen binding curve (i.e., it strongly increases the Hb oxygen affinity). These results highlight C35 as a promising dual-acting compound with both antimicrobial activity and the ability to modulate Hb function through non-covalent stabilization of a high-affinity state.
Author SummaryStaphylococcus aureus is a dangerous bacterium that can cause severe infections in humans. To grow and survive it needs iron, which it steals from our red blood cells by taking it from hemoglobin, the protein that carries oxygen in the blood. In this study, we focused on a small molecule, called C35, that blocks the interaction between hemoglobin and a key bacterial protein involved in heme acquisition. We found that C35 strongly inhibits the growth of S. aureus when hemoglobin is the only available source of iron, showing a potential new method to starve the pathogen and consequently fight the infection. Surprisingly, we also found that C35 increases the affinity of hemoglobin for oxygen. This dual action makes C35 a unique molecule for future therapeutic development, with potential applications both as a new antimicrobial agent and in the treatment of diseases related to hemoglobin function.