https://www.selleckchem.com/products/AdipoRon.html An intriguing challenge of drug discovery is targeting pathogenic mutant proteins that differ from their wild-type counterparts by only a single amino acid. In particular, pathogenic cysteine mutations afford promising opportunities for mutant-specific drug discovery, due to the unique reactivity of cysteine's sulfhydryl-containing side chain. Here we describe the first directed discovery effort targeting a pathogenic cysteine mutant of a protein tyrosine phosphatase (PTP), namely Y279C Src-homology-2-containing PTP 2 (SHP2), which has been causatively linked to the developmental disorder Noonan syndrome with multiple lentigines (NSML). Through a screen of commercially available compounds that contain cysteine-reactive functional groups, we have discovered a small-molecule inhibitor of Y279C SHP2 (compound 99; IC50 ≈ 6 μM) that has no appreciable effect on the phosphatase activity of wild-type SHP2 or that of other homologous PTPs (IC50 ≫ 100 μM). Compound 99 exerts its specific inhibitory effect through irreversible engagement of Y279C SHP2's pathogenic cysteine residue in a manner that is time-dependent, is substrate-independent, and persists in the context of a complex proteome. To the best of our knowledge, 99 is the first specific ligand of a disease-causing PTP mutant to be identified. This study therefore provides both a starting point for the development of NSML-directed therapeutic agents and a precedent for the identification of mutant-specific inhibitors of other pathogenic PTP mutants.Resistance to the last-line polymyxins is increasingly reported in multidrug-resistant Gram-negative pathogens, including Acinetobacter baumannii, which develops resistance via either lipid A modification (e.g., with phosphoethanolamine [pEtN]) or even lipopolysaccharide (LPS) loss in the outer membrane (OM). Considering these two different mechanisms, quantitative membrane lipidomics data were utilized to develop three OM