Immunity protein release from a cell‐bound nuclease colicin complex requires global conformational rearrangement

Mireille Vankemmelbeke,Nicholas G Housden,Richard James,Christopher N Penfold,Colin Kleanthous

doi:10.1002/mbo3.122

Mireille Vankemmelbeke, Nicholas G Housden + Show 3 more

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https://doi.org/10.1002/mbo3.122

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Journal: MicrobiologyOpen	Publication Date: Aug 28, 2013
Citations: 24	License type: CC BY 3.0

Affiliation: University of Oxford, University of Nottingham

Abstract

Nuclease colicins bind their target receptor BtuB in the outer membrane of sensitive Escherichia coli cells in the form of a high-affinity complex with their cognate immunity proteins. The release of the immunity protein from the colicin complex is a prerequisite for cell entry of the colicin and occurs via a process that is still relatively poorly understood. We have previously shown that an energy input in the form of the cytoplasmic membrane proton motive force is required to promote immunity protein (Im9) release from the colicin E9/Im9 complex and colicin cell entry. We report here that engineering rigidity in the structured part of the colicin translocation domain via the introduction of disulfide bonds prevents immunity protein release from the colicin complex. Reduction of the disulfide bond by the addition of DTT leads to immunity protein release and resumption of activity. Similarly, the introduction of a disulfide bond in the DNase domain previously shown to abolish channel formation in planar bilayers also prevented immunity protein release. Importantly, all disulfide bonds, in the translocation as well as the DNase domain, also abolished the biological activity of the Im9-free colicin E9, the reduction of which led to a resumption of activity. Our results show, for the first time, that conformational flexibility in the structured translocation and DNase domains of a nuclease colicin is essential for immunity protein release, providing further evidence for the hypothesis that global structural rearrangement of the colicin molecule is required for disassembly of this high-affinity toxin-immunity protein complex prior to outer membrane translocation.

Highlights

Nuclease colicins are Escherichia coli bacteriocins which have to traverse two membranes in order to gain access to their site of action, the cytoplasm
We decided to investigate these ambiguities by introducing conformational constraint in the structured T domain (STD) of the colicin E9 (colE9) through disulfide bond engineering and analyzing their effect on Im9 release during outer membrane (OM) translocation and on colicin biological activity
We suggest that a conformational rearrangement requiring a cellular energy input and initiated via the recruitment of the Tol system by the colicin intrinsically unstructured T domain (IUTD) is propagated along the STD (IL1 and IL3), R domain (BH29), and DNase domain (KM1) culminating in the release of the immunity protein

Summary

Introduction

Nuclease colicins are Escherichia coli bacteriocins which have to traverse two membranes in order to gain access to their site of action, the cytoplasm. They bind sensitive cells via the vitamin B12 receptor BtuB receptor in the outer membrane (OM) and much progress has been made to unravel the events leading to OM translocation of their cytotoxic domains (Cascales et al 2007; Kleanthous 2010; Jakes and Cramer 2012). In common with most colicins, the DNase-type colicin E9 (colE9) consists of three functional domains.

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Conclusion