Mutasynthetic Production and Antimicrobial Characterization of Darobactin Analogs

There is great need for therapeutics against multidrug-resistant, Gram-negative bacterial pathogens. Recently, darobactin A, a novel bicyclic heptapeptide that selectively kills Gram-negative bacteria by targeting the outer membrane protein BamA, was discovered. Its efficacy was proven in animal infection models of Escherichia coli, Klebsiella pneumoniae, and Pseudomonas aeruginosa, thus promoting darobactin A as a promising lead compound. Originally discovered from members of the nematode-symbiotic genus; Photorhabdus; , the biosynthetic gene cluster (BGC) encoding the synthesis of darobactin A can also be found in other members of the class; Gammaproteobacteria; . Therein, the precursor peptides DarB to -F, which differ in their core sequence from darobactin A, were identified; in silico; . Even though production of these analogs was not observed in the putative producer strains, we were able to generate them by mutasynthetic derivatization of a heterologous expression system. The analogs generated were isolated and tested for their bioactivity. The most potent compound, darobactin B, was used for cocrystallization with the target BamA, revealing a binding site identical to that of darobactin A. Despite its potency, darobactin B did not exhibit cytotoxicity, and it was slightly more active against Acinetobacter baumannii isolates than darobactin A. Furthermore, we evaluated the plasma protein binding of darobactin A and B, indicating their different pharmacokinetic properties. This is the first report on new members of this new antibiotic class, which is likely to expand to several promising therapeutic candidates.; IMPORTANCE; Therapeutic options to combat Gram-negative bacterial pathogens are dwindling with increasing antibiotic resistance. This study presents a proof of concept for the heterologous-expression approach to expand on the novel antibiotic class of darobactins and to generate analogs with different activities and pharmacokinetic properties. In combination with the structural data of the target BamA, this approach may contribute to structure-activity relationship (SAR) data to optimize inhibitors of this essential outer membrane protein of Gram-negative pathogens

Detergent Titration as an Efficient Method for NMR Resonance Assignments of Membrane Proteins in Lipid-Bilayer Nanodiscs

Lipid bilayer nanodiscs are an attractive tool to study membrane proteins in a detergent-free lipid-bilayer environment. In the case of NMR studies, a sequence-specific resonance assignment is required in order to gain structural and functional insights with atomic resolution. Although NMR backbone assignments of membrane proteins in detergents are available, they are largely absent for membrane proteins in nanodiscs due to unfavorable relaxation properties of the slowly tumbling membrane protein-nanodisc complex. The necessary residue-specific reassignment of resonances in nanodiscs is therefore extremely time and sample consuming and represents the fundamental bottleneck in the application of nanodiscs for NMR studies. Here we present an elegant and fast solution to the problem. We show that a resonance assignment in detergent micelles can be transferred to a spectrum recorded in nanodiscs via detergent titration. The procedure requires that lipid-detergent exchange kinetics are in the fast exchange regime in order to follow linear and nonlinear peak shift trajectories with increasing detergent concentration. We demonstrate the feasibility of the approach on the 148-residue membrane protein OmpX. The titration method is then applied to VDAC, a 19-stranded β-barrel with 283 residues, for which 67% of the detergent assignment could be transferred to the nanodisc spectrum. We furthermore show that this method also works for the largest currently assigned membrane protein, BamA with 398 residues. The method is applicable for backbone amide and side chain methyl groups and represents a time and cost-effective assignment method, for example, to investigate membrane protein allostery and drug binding in a more natural and detergent-free lipid bilayer

Computational identification of a systemic antibiotic for gram-negative bacteria

Discovery of antibiotics acting against Gram-negative species is uniquely challenging due to their restrictive penetration barrier. BamA, which inserts proteins into the outer membrane, is an attractive target due to its surface location. Darobactins produced by Photorhabdus, a nematode gut microbiome symbiont, target BamA. We reasoned that a computational search for genes only distantly related to the darobactin operon may lead to novel compounds. Following this clue, we identified dynobactin A, a novel peptide antibiotic from Photorhabdus australis containing two unlinked rings. Dynobactin is structurally unrelated to darobactins, but also targets BamA. Based on a BamA-dynobactin co-crystal structure and a BAM-complex-dynobactin cryo-EM structure, we show that dynobactin binds to the BamA lateral gate, uniquely protruding into its β-barrel lumen. Dynobactin showed efficacy in a mouse systemic Escherichia coli infection. This study demonstrates the utility of computational approaches to antibiotic discovery and suggests that dynobactin is a promising lead for drug development

Chimeric peptidomimetic antibiotics against Gram-negative bacteria

There is an urgent need for new antibiotics against Gram-negative pathogens that are resistant to carbapenem and third-generation cephalosporins, against which antibiotics of last resort have lost most of their efficacy. Here we describe a class of synthetic antibiotics inspired by scaffolds derived from natural products. These chimeric antibiotics contain a β-hairpin peptide macrocycle linked to the macrocycle found in the polymyxin and colistin family of natural products. They are bactericidal and have a mechanism of action that involves binding to both lipopolysaccharide and the main component (BamA) of the β-barrel folding complex (BAM) that is required for the folding and insertion of β-barrel proteins into the outer membrane of Gram-negative bacteria. Extensively optimized derivatives show potent activity against multidrug-resistant pathogens, including all of the Gram-negative members of the ESKAPE pathogens$^{1}$. These derivatives also show favourable drug properties and overcome colistin resistance, both in vitro and in vivo. The lead candidate is currently in preclinical toxicology studies that-if successful-will allow progress into clinical studies that have the potential to address life-threatening infections by the Gram-negative pathogens, and thus to resolve a considerable unmet medical need