High-throughput cell-based assays for the preclinical development of DsbA inhibitors as antivirulence therapeutics

Abstract

AbstractAntibiotics are failing fast, and the development pipeline is alarmingly dry. New drug research and development is being urged by world health officials, with new antibacterials against multidrug-resistant Gram-negative pathogens as the highest priority. Antivirulence drugs, which are inhibitors of bacterial pathogenicity factors, are a class of promising antibacterials, however, their development is often stifled by lack of standardised preclinical testing akin to what guides antibiotic development. The lack of established target-specific microbiological assays amenable to high-throughput, often means that cell-based testing of virulence inhibitors is absent from the discovery (hit-to-lead) phase, only to be employed at later-stages of lead optimization. Here, we address this by establishing a pipeline of bacterial cell-based assays developed for the identification and early preclinical evaluation of DsbA inhibitors. Inhibitors of DsbA block bacterial oxidative protein folding and were previously identified by biophysical and biochemical assays. Here we use existing Escherichia coli DsbA inhibitors and uropathogenic E. coli (UPEC) as a model pathogen, to demonstrate that a combination of a cell-based AssT sulfotransferase assay and the UPEC motility assay, modified for a higher throughput format, can provide a robust and target-specific platform for the evaluation of DsbA inhibitors. Our pipeline could also be used in fragment and compound screening for the identification of new DsbA inhibitor classes or hits with a broad spectrum of activity. In conclusion, the establishment of accurate, high-throughput microbiological assays for antivirulence drug identification and early preclinical development, is a significant first step towards their translation into effective therapeutics.ImportanceThe safety net of last resort antibiotics is quickly vanishing as bacteria become increasingly resistant to most available drugs. If no action is taken, we will likely enter a post-antibiotic era, where common infections and minor injuries are once again lethal. The paucity in new antibiotic discovery of the past decades has compounded the problem of increasing antibiotic resistance, to the point that it now constitutes a global health crisis that demands global action. There is currently an urgent need for new antibacterial drugs with new targets and modes of action. To address this, research and development efforts into antivirulence drugs, such as DsbA inhibitors, have been ramping up globally. However, the development of microbiological assays as tools for effectively identifying and evaluating antivirulence drugs is lagging behind. Here, we present a high-throughput cell-based screening and evaluation pipeline, which could significantly advance development of DsbA inhibitor as antivirulence therapeutics.