Structure of the Diphtheria Toxin at Acidic pH: Implications for the Conformational Switching of the Translocation Domain

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license.Diphtheria toxin, an exotoxin secreted by Corynebacterium that causes disease in humans by inhibiting protein synthesis, enters the cell via receptor-mediated endocytosis. The subsequent endosomal acidification triggers a series of conformational changes, resulting in the refolding and membrane insertion of the translocation (T-)domain and ultimately leading to the translocation of the catalytic domain into the cytoplasm. Here, we use X-ray crystallography along with circular dichroism and fluorescence spectroscopy to gain insight into the mechanism of the early stages of pH-dependent conformational transition. For the first time, we present the high-resolution structure of the diphtheria toxin at a mildly acidic pH (5–6) and compare it to the structure at neutral pH (7). We demonstrate that neither catalytic nor receptor-binding domains change their structure upon this acidification, while the T-domain undergoes a conformational change that results in the unfolding of the TH2–3 helices. Surprisingly, the TH1 helix maintains its conformation in the crystal of the full-length toxin even at pH 5. This contrasts with the evidence from the new and previously published data, obtained by spectroscopic measurements and molecular dynamics computer simulations, which indicate the refolding of TH1 upon the acidification of the isolated T-domain. The overall results imply that the membrane interactions of the T-domain are critical in ensuring the proper conformational changes required for the preparation of the diphtheria toxin for the cellular entry.National Institute of General Medical Sciences (P30 GM110761)Department of Energy, Office of Science, Office of Basic Energy Sciences, under contract no. DE-AC02-06CH1135

Refining Protein Penetration into the Lipid Bilayer Using Fluorescence Quenching and Molecular Dynamics Simulations: The Case of Diphtheria Toxin Translocation Domain

Dynamic disorder of the lipid bilayer presents a challenge for establishing structure-function relationships in membranous systems. The resulting structural heterogeneity is especially evident for peripheral and spontaneously inserting membrane proteins, which are not constrained by the well-defined transmembrane topology and exert their action in the context of intimate interaction with lipids. Here, we propose a concerted approach combining depth-dependent fluorescence quenching with Molecular Dynamics simulation to decipher dynamic interactions of membrane proteins with the lipid bilayers. We apply this approach to characterize membrane-mediated action of the diphtheria toxin translocation domain. First, we use a combination of the steady-state and time-resolved fluorescence spectroscopy to characterize bilayer penetration of the NBD probe selectively attached to different sites of the protein into membranes containing lipid-attached nitroxyl quenching groups. The constructed quenching profiles are analyzed with the Distribution Analysis methodology allowing for accurate determination of transverse distribution of the probe. The results obtained for 12 NBD-labeled single-Cys mutants are consistent with the so-called Open-Channel topology model. The experimentally determined quenching profiles for labeling sites corresponding to L350, N373, and P378 were used as initial constraints for positioning TH8-9 hairpin into the lipid bilayer for Molecular Dynamics simulation. Finally, we used alchemical free energy calculations to characterize protonation of E362 in soluble translocation domain and membrane-inserted conformation of its TH8-9 fragment. Our results indicate that membrane partitioning of the neutral E362 is more favorable energetically (by ~ 6 kcal/mol), but causes stronger perturbation of the bilayer, than the charged E362

Hydrogenated and fluorinated surfactants derived from Tris (hydroxymethyl)-acrylamidomethane allow the purification of a highly active yeast F1-F0 ATP-synthase with an enhanced stability

Loss of stability and integrity of large membrane protein complexes as well as their aggregation in a non-lipidic environment are the major bottlenecks to their structural studies. We have tested C12H25-S-poly-Tris-(hydroxymethyl)acrylamidomethane (H12-TAC) among many other detergents for extracting the yeast F1F0 ATP-synthase. H12-TAC was found to be a very efficient detergent for removing the enzyme from mitochondrial membranes without altering its sensitivity towards specific ATP-synthase inhibitors. This extracted enzyme was then solubilized by either dodecyl maltoside (DDM), H12-TAC or fluorinated surfactants such as C2H5-C6F12-C2H4-S-poly-Tris-(hydroxymethyl)acrylamidomethane (H2F6-TAC) or C6F13-C2H4-S-poly-Tris-(hydroxymethyl)acrylamidomethane (F6-TAC), two surfactants exhibiting a comparable polar head to H12-TAC but bearing a fluorinated hydrophobic tail. Preparations from enzymes purified in the presence of H12-TAC were found to be more adapted for AFM imaging than ATP-synthase purified with DDM. Keeping H12-TAC during the Ni-NTA IMAC purification step or replacing it by DDM at low concentrations did not however allow preserving enzyme activity, while fluorinated surfactants H2F6-TAC and F6-TAC were found to enhance enzyme stability and integrity as indicated by sensitivity towards inhibitors. ATPase specific activity was higher with F6-TAC than with H2F6-TAC. When enzymes were mixed with egg phosphatidylcholine, ATP-synthases purified in the presence of H2F6-TAC or F6-TAC were more stable upon time than the DDM purified enzyme. Furthermore, in the presence of lipids, an activation of ATP-synthases was observed that was transitory for enzymes purified with DDM, but lasted for weeks for ATP-synthases isolated in the presence of molecules with Tris polyalcoholic moieties. Relipidated enzymes prepared with fluorinated surfactants remained highly sensitive towards inhibitors, even after 6 weeks