Frontiers in Pharmacology (Mar 2024)

In vivo screening for toxicity-modulating drug interactions identifies antagonism that protects against ototoxicity in zebrafish

  • Ethan Bustad,
  • Emma Mudrock,
  • Elizabeth M. Nilles,
  • Andrea Mcquate,
  • Andrea Mcquate,
  • Andrea Mcquate,
  • Monica Bergado,
  • Alden Gu,
  • Louie Galitan,
  • Natalie Gleason,
  • Henry C. Ou,
  • Henry C. Ou,
  • David W. Raible,
  • David W. Raible,
  • David W. Raible,
  • Rafael E. Hernandez,
  • Rafael E. Hernandez,
  • Shuyi Ma,
  • Shuyi Ma,
  • Shuyi Ma,
  • Shuyi Ma

DOI
https://doi.org/10.3389/fphar.2024.1363545
Journal volume & issue
Vol. 15

Abstract

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Introduction: Ototoxicity is a debilitating side effect of over 150 medications with diverse mechanisms of action, many of which could be taken concurrently to treat multiple conditions. Approaches for preclinical evaluation of drug-drug interactions that might impact ototoxicity would facilitate design of safer multi-drug regimens and mitigate unsafe polypharmacy by flagging combinations that potentially cause adverse interactions for monitoring. They may also identify protective agents that antagonize ototoxic injury.Methods: To address this need, we have developed a novel workflow that we call Parallelized Evaluation of Protection and Injury for Toxicity Assessment (PEPITA), which empowers high-throughput, semi-automated quantification of ototoxicity and otoprotection in zebrafish larvae via microscopy. We used PEPITA and confocal microscopy to characterize in vivo the consequences of drug-drug interactions on ototoxic drug uptake and cellular damage of zebrafish lateral line hair cells.Results and discussion: By applying PEPITA to measure ototoxic drug interaction outcomes, we discovered antagonistic interactions between macrolide and aminoglycoside antibiotics that confer protection against aminoglycoside-induced damage to lateral line hair cells in zebrafish larvae. Co-administration of either azithromycin or erythromycin in zebrafish protected against damage from a broad panel of aminoglycosides, at least in part via inhibiting drug uptake into hair cells via a mechanism independent from hair cell mechanotransduction. Conversely, combining macrolides with aminoglycosides in bacterial inhibition assays does not show antagonism of antimicrobial efficacy. The proof-of-concept otoprotective antagonism suggests that combinatorial interventions can potentially be developed to protect against other forms of toxicity without hindering on-target drug efficacy.

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