Differential mechanisms for calcium-dependent protein/membrane association as evidenced from SPR-binding studies on supported biomimetic membranes

International audienceIn this work, two different types of supported biomimetic membranes were designed to study the membrane binding properties of two different proteins that both interact with cellular membranes in a calcium-dependent manner. The first one, neurocalcin, is a member of a subfamilly of EF-hand calcium-binding proteins that exhibit a calcium-myristoyl switch. The second protein is a bacterial toxin, the adenylate cyclase produced by Bordetella pertussis, the causative agent of whooping cough. The biomimetic membranes constructed in this study were either hybrid bilayer membranes or polymer-tethered membranes. Hemimembrane formation was obtained in two steps: a monolayer of 1-octadecanethiol or octadecyl-trichlorosilane was self-assembled on top of the gold or glass surface, respectively, and then the egg-phosphatidyl choline (PC) vesicle fused on the hydrophobic alkyl layer. Polymer-tethered membranes on solid support were obtained using N-hydroxysuccinimide (NHS)-terminated-poly(ethyleneglycol) (PEG)-phospholipids as anchoring molecules. Egg-PC/1,2-distearoyl-sn-glycero-3-phospho-ethanolamine-poly(ethyleneglycol)-N-hydroxy-succinimide (DSPE-PEG-NHS) mixture liposomes were injected on the top of an amine grafted surface (cysteamine-coated gold or silanized glass); vesicles were linked to the surface and disrupted, leading to the formation of a bilayer. The biomimetic membrane constructions were followed by surface plasmon spectroscopy, while membrane fluidity and continuity were observed by fluorescence microscopy. Protein/membrane binding properties were determined by resonance surface plasmon measurements. The tethered bilayer, designed here, is very versatile as it can be adapted easily to different types of support. The results demonstrate the potentialities of such polymer-tethered artificial membranes for the study of proteins that insert into biological membranes such as toxins and/or integral membrane proteins

Delivery of the HIV-1 Tat protein to dendritic cells by the CyaA vector induces specific Th1 responses and high affinity neutralizing antibodies in non human primates.

This article demonstrate the usefulness of primate models such as african green monkeys for relevant preclinical work on vaccinesInternational audienceThe human immunodeficiency virus type 1 (HIV-1) Tat is a key protein playing a major role in the infectivity of the virus. Thus, HIV-Tat based vaccines have been proposed as an attractive option to treat AIDS. Recently, we have shown that the recombinant detoxified adenylate cyclase (CyaA) from Bordetella pertussis carrying HIV-Tat (CyaA-E5-Tat), targets dendritic cells (DCs) and induces specific Th1 polarized and neutralizing antibody responses in mice. To further explore the potentialities of this prototype vaccine for human use, we analyzed the CyaA-E5-Tat induced antibody responses in non-human primates and established the biological characteristics of these antibodies. African Green Monkeys (AGM) were immunized with CyaA-E5-Tat in the presence or in the absence of alum adjuvant. First, we showed that the anti-CyaA antibodies induced by such immunization does not interfere with the binding of CyaA-E5-Tat to its receptor at the DC surface, the alphaMbeta2 integrin. Monkeys immunized with CyaA-E5-Tat, with or without alum, produced anti-Tat antibodies that mainly recognized the N-terminal domain of the Tat protein. Importantly, all sera obtained after three immunizations displayed the capacity to bind to Tat and neutralize its transactivating function in vitro. Finally, in the absence of alum, CyaA-E5-Tat, induced Th1 Tat specific T cell responses. These findings reveal that CyaA-E5-Tat is efficiently delivered in non-human primates and had a significant impact on the generation of neutralizing anti-Tat antibodies. These observations are, thus, encouraging for the use of the CyaA vector in human and also suggest that CyaA-E5-Tat might be a useful tool to decipher the biological characteristic of such antibodies