Pathogenic antibiotic resistant bacteria pose one of the most important health challenges of the 21st century. The overuse and abuse of antibiotics coupled with the natural evolutionary processes of bacteria has led to this crisis. Only incremental advances in antibiotic development have occurred over the last 30 years. Novel classes of molecules, such as engineered antibodies, antibiotic enhancers, siderophore conjugates, engineered phages, photo-switchable antibiotics, and genome editing facilitated by the CRISPR/Cas system, are providing new avenues to facilitate the development of antimicrobial therapies. The informatics revolution is transforming research and development efforts to discover novel antibiotics. The explosion of nanotechnology and micro-engineering is driving the invention of antimicrobial materials, enabling the cultivation of “uncultivable” microbes and creating specific and rapid diagnostic technologies. Finally, a revival in the ecological aspects of microbial disease management, the growth of prebiotics, and integrated management based on the “One Health” model, provide additional avenues to manage this health crisis. These, and future scientific and technological developments, must be coupled and aligned with sound policy and public awareness to address the risks posed by rising antibiotic resistance.
Rapamycin-induced protein heterodimerization of FKBP12 and FRB is one of the most commonly employed switches to conditionally control biological processes. We developed an optically activated rapamycin dimer that does not induce FKBP12-FRB dimerization until exposed to light, and applied it to control kinase, protease, and recombinase function.
The Androgen Receptor (AR) remains the leading target of advanced prostate cancer therapies. Thiosalicylamide analogs have previously been shown to act in cells as acyltransfer catalysts that are capable of transferring cellular acetate, presumably from acetyl-CoA, to HIV NCp7. Here we explore if the cellular acetyl-transfer activity of thiosalicylamides can be redirected to other cellular targets guided by ligands for AR. We constructed conjugates of thiosalicylamides and the AR-binding small molecule tolfenamic acid, which binds the BF-3 site of AR, proximal to the coactivator “FXXLF” binding surface. The thiosalicylamide-tolfenamic acid conjugate, YZ03, but not the separate thiosalicylamide plus tolfenamic acid, significantly enhanced acetylation of endogenous AR in CWR22Rv1 cells. Further analysis confirms that Lys720, a residue critical to FXXLF coactivator peptide binding, is a site of acyl-YZ03 acetylation. Under acyl-transfer conditions, YZ03 significantly enhances the ability of BF-3 site binding ligands to inhibit AR-coactivator peptide association. These data suggest that biomimetic acyltransferases can enhance protein-protein interaction inhibitors through covalent modification of critical interfacial residues.
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