Abstract
The ExoU type III secretion enzyme is a potent phospholipase A2 secreted by the Gram-negative opportunistic pathogen, Pseudomonas aeruginosa Activation of phospholipase activity is induced by protein-protein interactions with ubiquitin in the cytosol of a targeted eukaryotic cell, leading to destruction of host cell membranes. Previous work in our laboratory suggested that conformational changes within a C-terminal domain of the toxin might be involved in the activation mechanism. In this study, we use site-directed spin-labeling electron paramagnetic resonance spectroscopy to investigate conformational changes in a C-terminal four-helical bundle region of ExoU as it interacts with lipid substrates and ubiquitin, and to examine the localization of this domain with respect to the lipid bilayer. In the absence of ubiquitin or substrate liposomes, the overall structure of the C-terminal domain is in good agreement with crystallographic models derived from ExoU in complex with its chaperone, SpcU. Significant conformational changes are observed throughout the domain in the presence of ubiquitin and liposomes combined that are not observed with either liposomes or ubiquitin alone. In the presence of ubiquitin, two interhelical loops of the C-terminal four-helix bundle appear to penetrate the membrane bilayer, stabilizing ExoU-membrane association. Thus, ubiquitin and the substrate lipid bilayer act synergistically to induce a conformational rearrangement in the C-terminal domain of ExoU.
Highlights
A wide variety of bacterial pathogens express effector proteins that influence or modify the host environment in a way that facilitates their survival and dissemination
The Gram-negative opportunistic pathogen Pseudomonas aeruginosa synthesizes four effector proteins that are injected into host cells via the T3SS[2,3,4,5], of which ExoU is the most strongly correlated with virulence and negative clinical outcome [6, 7]
Diubiquitin was chosen for this study as it has been shown that ubiquitin polymers of several linkage types have a greatly enhanced ability to bind and activate ExoU as compared with monomeric forms [8]
Summary
A wide variety of bacterial pathogens express effector proteins that influence or modify the host environment in a way that facilitates their survival and dissemination. The catalytic domain of ExoU exhibits structural similarity to the patatin group of plant phospholipases, as well as to eukaryotic phospholipases [9]. Unlike their eukaryotic counterparts, activation by ubiquitin appears to be a property of many bacterial patatin-like proteins [10]. Two X-ray crystal structures of ExoU in complex with its cognate chaperone, SpcU, have been solved [13, 14] These structures are in excellent agreement and reveal ExoU to be a multi-domain protein containing a chaperone-binding domain, a catalytic domain, a bridging domain, and a C-terminal four-helix bundle domain. Cooperative Substrate-Cofactor Interactions of ExoU bundle domains do not appear to have close sequence or structural equivalents in either the patatins or the eukaryotic phospholipases
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