A Novel Strategy for Development of Recombinant Antitoxin Therapeutics Tested in a Mouse Botulism Model

Jean Mukherjee,Patrick M Wright,Xiaochuan Feng,Karen Baldwin,Clinton E Leysath,Leonard A Smith,Daniela Bedenice,Charles B Shoemaker,Robert P Webb,Saul Tzipori,Kwasi Ofori,Jacqueline M Tremblay,Eric A Johnson

doi:10.1371/journal.pone.0029941

Abstract

Antitoxins are needed that can be produced economically with improved safety and shelf life compared to conventional antisera-based therapeutics. Here we report a practical strategy for development of simple antitoxin therapeutics with substantial advantages over currently available treatments. The therapeutic strategy employs a single recombinant ‘targeting agent’ that binds a toxin at two unique sites and a ‘clearing Ab’ that binds two epitopes present on each targeting agent. Co-administration of the targeting agent and the clearing Ab results in decoration of the toxin with up to four Abs to promote accelerated clearance. The therapeutic strategy was applied to two Botulinum neurotoxin (BoNT) serotypes and protected mice from lethality in two different intoxication models with an efficacy equivalent to conventional antitoxin serum. Targeting agents were a single recombinant protein consisting of a heterodimer of two camelid anti-BoNT heavy-chain-only Ab VH (VHH) binding domains and two E-tag epitopes. The clearing mAb was an anti-E-tag mAb. By comparing the in vivo efficacy of treatments that employed neutralizing vs. non-neutralizing agents or the presence vs. absence of clearing Ab permitted unprecedented insight into the roles of toxin neutralization and clearance in antitoxin efficacy. Surprisingly, when a post-intoxication treatment model was used, a toxin-neutralizing heterodimer agent fully protected mice from intoxication even in the absence of clearing Ab. Thus a single, easy-to-produce recombinant protein was as efficacious as polyclonal antiserum in a clinically-relevant mouse model of botulism. This strategy should have widespread application in antitoxin development and other therapies in which neutralization and/or accelerated clearance of a serum biomolecule can offer therapeutic benefit.

Highlights

The presence of toxins in circulation is the cause of a wide variety of human and animal illnesses
VHHs were obtained that bind to Botulinum neurotoxin (BoNT) serotype B (BoNT/B) holotoxin to permit efficacy testing on a second pathogenic serum protein
Competition ELISAs were used to identify the VHHs with the highest apparent affinity for unique epitopes on BoNT serotype A (BoNT/A) and BoNT/B leading to the selection of seven BoNT/A VHHs (Figure S1A) and four BoNT/B VHHs (Figure S1B)

Summary

Introduction

The presence of toxins in circulation is the cause of a wide variety of human and animal illnesses. Antitoxins are therapeutic agents that reduce further development of symptoms in patients that have been exposed to a toxin. Antitoxins are the antisera obtained from large animals that were immunized with inactivated toxin [1,2]. Some antitoxin therapies have been developed using one or more antitoxin mAbs [3,4,5,6]. Antisera and mAbs can be difficult to produce economically at scale, usually require long development times and often have problematic quality control, shelf-life and safety issues. New therapeutic strategies to develop and prepare antitoxins are needed

Methods

Results

Conclusion