Litcius/Paper detail

The C. difficile toxin B membrane translocation machinery is an evolutionarily conserved protein delivery apparatus

Kathleen E. Orrell, Michael J. Mansfield, Andrew C. Doxey, Roman A. Melnyk

2020Nature Communications34 citationsDOIOpen Access PDF

Abstract

Large Clostridial Toxins (LCTs) are a family of six homologous protein toxins that are implicated in severe disease. LCTs infiltrate host cells using a translocation domain (LCT-T) that contains both cell-surface receptor binding sites and a membrane translocation apparatus. Despite much effort, LCT translocation remains poorly understood. Here we report the identification of 1104 LCT-T homologs, with 769 proteins from bacteria outside of clostridia. Sequences are widely distributed in pathogenic and host-associated species, in a variety of contexts and architectures. Consistent with these homologs being functional toxins, we show that a distant LCT-T homolog from Serratia marcescens acts as a pH-dependent translocase to deliver its effector into host cells. Based on evolutionary footprinting of LCT-T homologs, we further define an evolutionarily conserved translocase region that we show is an autonomous translocase capable of delivering heterologous cargo into host cells. Our work uncovers a broad class of translocating toxins and provides insights into LCT translocation.

Topics & Concepts

TranslocaseBiologyChromosomal translocationConserved sequenceClostridium difficile toxin BEffectorTransport proteinCell biologyGeneticsPeptide sequenceGeneClostridium difficile toxin AClostridium difficileAntibioticsClostridium difficile and Clostridium perfringens researchToxin Mechanisms and ImmunotoxinsStreptococcal Infections and Treatments