Functional characterization of Val60, a key residue involved in the membrane-oligomerization of fragaceatoxin C, an actinoporin from Actinia fragacea

AbstractActinoporins are pore-forming toxins produced by different sea anemones that self-assemble within the membranes of their target cells and compromise their function as a permeability barrier. The recently published three-dimensional structures of two oligomeric complexes formed by fragaceatoxin C point to Val60 as a key residue involved in the oligomerization of the functional pore.To gain insight into the mechanism of toxin oligomerization, different point mutations have been introduced at this position. Functional characterization of the muteins suggests that Val60 represents a hot-spot where the introduction of mutations hinders protein assembly and reduces the overall affinity for membranes

Functional Delineation of a Protein–Membrane Interaction Hotspot Site on the HIV-1 Neutralizing Antibody 10E8

Antibody engagement with the membrane-proximal external region (MPER) of the envelope glycoprotein (Env) of HIV-1 constitutes a distinctive molecular recognition phenomenon, the full appreciation of which is crucial for understanding the mechanisms that underlie the broad neutralization of the virus. Recognition of the HIV-1 Env antigen seems to depend on two specific features developed by antibodies with MPER specificity: (i) a large cavity at the antigen-binding site that holds the epitope amphipathic helix; and (ii) a membrane-accommodating Fab surface that engages with viral phospholipids. Thus, besides the main Fab–peptide interaction, molecular recognition of MPER depends on semi-specific (electrostatic and hydrophobic) interactions with membranes and, reportedly, on specific binding to the phospholipid head groups. Here, based on available cryo-EM structures of Fab–Env complexes of the anti-MPER antibody 10E8, we sought to delineate the functional antibody–membrane interface using as the defining criterion the neutralization potency and binding affinity improvements induced by Arg substitutions. This rational, Arg-based mutagenesis strategy revealed the position-dependent contribution of electrostatic interactions upon inclusion of Arg-s at the CDR1, CDR2 or FR3 of the Fab light chain. Moreover, the contribution of the most effective Arg-s increased the potency enhancement induced by inclusion of a hydrophobic-at-interface Phe at position 100c of the heavy chain CDR3. In combination, the potency and affinity improvements by Arg residues delineated a protein–membrane interaction site, whose surface and position support a possible mechanism of action for 10E8-induced neutralization. Functional delineation of membrane-interacting patches could open new lines of research to optimize antibodies of therapeutic interest that target integral membrane epitopes.This study was supported by the Spanish MCIN (Grants PID2021-126014OB-I00 MCIN/AEI/FEDER, UE to JLN and BA; and PID2021-122212OA-I00 MCIN/AEI/FEDER, UE to ER), Basque Government (Grant: IT1449-22) and JSPS KAKENHI 20H03228 (to J.M.M.C.)

Molecular recognition of a membrane-anchored HIV-1 pan-neutralizing epitope.

Antibodies against the carboxy-terminal section of the membrane-proximal external region (C-MPER) of the HIV-1 envelope glycoprotein (Env) are considered as nearly pan-neutralizing. Development of vaccines capable of producing analogous broadly neutralizing antibodies requires deep understanding of the mechanism that underlies C-MPER recognition in membranes. Here, we use the archetypic 10E8 antibody and a variety of biophysical techniques including single-molecule approaches to study the molecular recognition of C-MPER in membrane mimetics. In contrast to the assumption that an interfacial MPER helix embodies the entire C-MPER epitope recognized by 10E8, our data indicate that transmembrane domain (TMD) residues contribute to binding affinity and specificity. Moreover, anchoring to membrane the helical C-MPER epitope through the TMD augments antibody binding affinity and relieves the effects exerted by the interfacial MPER helix on the mechanical stability of the lipid bilayer. These observations support that addition of TMD residues may result in more efficient and stable anti-MPER vaccines.This study was supported by MCIN/AEI/10.13039/501100011033 - “ERDF A way of making Europe” (Grant PID2021-126014OB-I00 to J.L.N. and B.A.), MCIN/AEI/10.13039/501100011033 (Grant PID2020-112821GB-I00 to M.A.J.), Basque Government (Grant: IT1449-22 to J.L.N. and B.A.) and Kiban-B grant 20H03228 from JSPS to J.M.M.C. L.R.-M. acknowledges funding from the Agence National de la Recherche (ANR), as part of the ‘Investments d′Avenir’ Program (I-SITE ULNE/ANR-16-IDEX-0004 ULNE). This project has received funding from the European Union’s Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement No. 895819 (to C.V.). Work at Pompeu Fabra University was supported by the María de Maeztu network of Units of Excellence of the Spanish Ministry of Science and Innovation. Technical assistance from Miguel García-Porras is greatly acknowledged. The NMR experiments were performed in the “Manuel Rico” NMR laboratory, LMR, CSIC, a node of the Spanish Large-Scale National Facility ICTS R-LRB

Focal accumulation of aromaticity at the CDRH3 loop mitigates 4E10 polyreactivity without altering its HIV neutralization profile

Broadly neutralizing antibodies (bnAbs) against HIV-1 are frequently associated with the presence of autoreactivity/polyreactivity, a property that can limit their use as therapeutic agents. The bnAb 4E10, targeting the conserved Membrane proximal external region (MPER) of HIV-1, displays almost pan-neutralizing activity across globally circulating HIV-1 strains but exhibits nonspecific off-target interactions with lipid membranes. The hydrophobic apex of the third complementarity-determining region of the heavy chain (CDRH3) loop, which is essential for viral neutralization, critically contributes to this detrimental effect. Here, we have replaced the aromatic/hydrophobic residues from the apex of the CDRH3 of 4E10 with a single aromatic molecule through chemical modification to generate a variant that preserves the neutralization potency and breadth of 4E10 but with reduced autoreactivity. Collectively, our study suggests that the localized accumulation of aromaticity by chemical modification provides a pathway to ameliorate the adverse effects triggered by the CDRH3 of anti-HIV-1 MPER bnAbs.This study was supported by the following Grants: European Commission (790012 SI H2020-MSCA-IF-2017) (E.R.); US NIAID, NIH grant R01 AI143563 (M.B. Z.); James B. Pendleton Charitable Trust (M.B.Z.); JSPS grant 20H03228 (J. M.M.C.); Spanish MCIU (RTI2018-095624-B-C21; MCIU/AEI/FEDER, UE) (J.L.N.), Basque Government (IT1196-19) (J.L.N.). C.E. acknowledges funding from Medical Research Council (grant number MC_UU_12010/unit programs G0902418 and MC_UU_12025), Wolfson Foundation, Deutsche Forschungsgemeinschaft (Excellence Cluster Balance of the Microverse, Collaborative Research Center 1278 Polytarget), Leibniz Association (Leibniz Campus Infectooptics), Wellcome Institutional Strategic Support Fund, Oxford internal funds (EPA Cephalosporin Fund and John Fell Fund), and support from the Micron Oxford Advanced Bioimaging Unit (Wellcome Trust funding 107457/Z/15/Z). This work was also supported by the Platform Project for Supporting Drug Discovery and Life Science Research [Basis for Supporting Innovative Drug Discovery and Life Science Research (BINDS)] from AMED (JP21am0101091). S.I. received a predoctoral fellowship from the BasqueGovernment. P.C. would like to acknowledge the University of the Basque Country (DOCREC18/01), the Basque Government (POS_2018_1_0066) and the European Commission (H2020-MSCA-IF-2019-ST project 892232 FILM-HIV) for funding his position. This research was also supported by the CIFAR Azrieli Global Scholar program (J-P.J.), the Ontario Early Researcher Awards program (J-P.J.), and the Canada Research Chairs program (J-P.J.). Part of the biophysical data presented in this manuscript were collected at the Hospital for Sick Children Structural & Biophysical Core facility supported by the Canada Foundation for Innovation and Ontario Research Fund

Affinity for the Interface Underpins Potency of Antibodies Operating In Membrane Environments

The contribution of membrane interfacial interactions to recognition of membrane-embedded antigens by antibodies is currently unclear. This report demonstrates the optimization of this type of antibodies via chemical modification of regions near the membrane but not directly involved in the recognition of the epitope. Using the HIV-1 antibody 10E8 as a model, linear and polycyclic synthetic aromatic compounds are introduced at selected sites. Molecular dynamics simulations predict the favorable interactions of these synthetic compounds with the viral lipid membrane, where the epitope of the HIV-1 glycoprotein Env is located. Chemical modification of 10E8 with aromatic acetamides facilitates the productive and specific recognition of the native antigen, partially buried in the crowded environment of the viral membrane, resulting in a dramatic increase of its capacity to block viral infection. These observations support the harnessing of interfacial affinity through site-selective chemical modification to optimize the function of antibodies that target membrane-proximal epitopes.We are grateful to Professor Ueda (Kyushu University) for valuable advice. C.D. acknowledges RES (Red Espanola de Supercomputacio ' n) for providing computational resources. S.I. received a pre-doctoral fellowship from the Basque Government. P.C. acknowledges a research associate contract from the University of the Basque Country (DOCREC18/01) and a postdoctoral fellowship from the Basque Government (POS_2018_1_0066).This study was supported by the following grants: European Commission (790012 SI H2020MSCA-IF-2017 to E.R., J.-P.J., and J.L.N.); US NIAID (NIH) (R01 AI143563 to M.B.Z.); James B. Pendleton Charitable Trust (to M.B.Z.); Grant-in-Aid for Scientific Research on Innovative Areas "Chemistry for Multimolecular Crowding Biosystems, JSPS KAKENHI (JP17H06349 to A.O.); JSPS KAKENHI (15K06962 and 20H03228 to J.M.M.C.); Spanish MINECO (BIO2015-64421R and MINECO/AEI/FEDER, UE to J.L.N.); Spanish MCIU (RTI2018-095624B-C21 and MCIU/AEI/FEDER, UE to J.L.N.); and the Basque Government (IT1196-19) (to J.L.N.). C.E. acknowledges funding from Medical Research Council (MC_UU_12010/unit programs G0902418 and MC_UU_12025), Wolfson Foundation, Deutsche Forschungsgemeinschaft (Research unit 1905, Excellence Cluster Balance of the Microverse, Collaborative Research Centre 1278 Polytarget), Wellcome Institutional Strategic Support Fund, Oxford internal funds (EPA Cephalosporin Fund and John Fell Fund), and support from the Micron Oxford Advanced Bioimaging Unit (Wellcome Trust funding 107457/Z/15/Z). This research was undertaken, in part, thanks to funding from the CIFAR Azrieli Global Scholar program (to J.-P.J.) and the Canada Research Chairs program (950-231604 to J.-P.J.). This work was also supported by the Platform Project for Supporting Drug Discovery and Life Science Research (Basis for Supporting Innovative Drug Discovery and Life Science Research [BINDS] from AMED JP19am0101091)

Identification of a membrane-bound prepore species clarifies the lytic mechanism of actinoporins

International audiencePore-forming toxins (PFT) are cytolytic proteins belonging to the molecular warfare apparatus of living organisms. The assembly of the functional transmembrane pore requires several intermediate steps ranging from a water-soluble monomeric species to the multimeric ensemble inserted in the cell membrane. The non-lytic oligomeric intermediate known as prepore plays an essential role in the mechanism of insertion of the class of β-PFT. However, in the class of α-PFT like the actinoporins produced by sea anemones, evidence of membrane-bound prepores is still lacking. We have employed single-particle cryo-electron microscopy (cryo-EM) and atomic force microscopy (AFM) to identify, for the first time, a prepore species of the actinoporin fragaceatoxin C (FraC) bound to lipid vesicles. The size of the prepore coincides that of the functional pore, except for the transmembrane region, which is absent in the prepore. Biochemical assays indicated that, in the prepore species, the N-terminus is not inserted in the bilayer but exposed to the aqueous solution. Our study reveals the structure of the prepore complex in actinoporins, and highlights the role of structural intermediates for the formation of cytolytic pores by an α-PFT