Fabrice Rose

The supramolecular structure is decisive for the immunostimulatory properties of synthetic analogues of a mycobacterial lipid in vitro

Identification of new vaccine adjuvants with immunopotentiating properties commonly involves in vitro evaluations of candidate compounds for their ability to stimulate cells of the immune system. Subsequent elaborate experiments are then performed on only the positive candidates. Here we show how this strategy may miss good candidates due to context-dependent supramolecular characteristics of the candidate compounds, since both a specific molecular structure and the correct presentation of specific parts of the compounds are required for successful stimulation of the cells. Nevertheless, the supramolecular structure is rarely evaluated although changes in this structure may have a drastic impact on the presentation of the compounds to the cells. Synthetic analogues of the mycobacterial cell wall lipid monomycoloyl glycerol (MMG) possess immunopotentiating properties, but their biophysical characteristics are largely unresolved and the structural features determining their immunoactivating properties have been poorly explored. In the present study, we demonstrate that the immunostimulatory activity in vitro correlates with the supramolecular characteristics of the self-assembled MMG nanostructures. Thus, a series of MMG analogues displaying different stereochemistry in the hydrophobic moiety and the polar headgroup were designed and synthesized with different alkyl chain lengths. Stimulation of human monocyte-derived dendritic cells in vitro was clearly dependent on the stereochemistry of the hydrophobic part and on the alkyl chain length but not on the stereochemistry of the hydrophilic glycerol moiety. Small-angle X-ray scattering (SAXS) analysis showed that the immunoactivating analogues self-assembled into lamellar phases whereas the biologically inert analogues adopted inverse hexagonal phases. Langmuir monolayers confirmed that analogues with opposite lipid acid configurations displayed different packing modes. These data demonstrate that the biophysical properties and the lipid molecular structure are major determinants for the ability of the MMG analogues to activate antigen-presenting cells. Our findings emphasize the importance of investigating the biophysical and structural properties when assessing the effect of adjuvants in vitro.

Mechanism of Action of Lung Damage Caused by a Nanofilm Spray Product

Inhalation of waterproofing spray products has on several occasions caused lung damage, which in some cases was fatal. The present study aims to elucidate the mechanism of action of a nanofilm spray product, which has been shown to possess unusual toxic effects, including an extremely steep concentration-effect curve. The nanofilm product is intended for application on non-absorbing flooring materials and contains perfluorosiloxane as the active film-forming component. The toxicological effects and their underlying mechanisms of this product were studied using a mouse inhalation model, by in vitro techniques and by identification of the binding interaction. Inhalation of the aerosolized product gave rise to increased airway resistance in the mice, as evident from the decreased expiratory flow rate. The toxic effect of the waterproofing spray product included interaction with the pulmonary surfactants. More specifically, the active film-forming components in the spray product, perfluorinated siloxanes, inhibited the function of the lung surfactant due to non-covalent interaction with surfactant protein B, a component which is crucial for the stability and persistence of the lung surfactant film during respiration. The active film-forming component used in the present spray product is also found in several other products on the market. Hence, it may be expected that these products may have a toxicity similar to the waterproofing product studied here. Elucidation of the toxicological mechanism and identification of toxicological targets are important to perform rational and cost-effective toxicological studies. Thus, because the pulmonary surfactant system appears to be an important toxicological target for waterproofing spray products, study of surfactant inhibition could be included in toxicological assessment of this group of consumer products.

A strong adjuvant based on glycol-chitosan-coated lipid-polymer hybrid nanoparticles potentiates mucosal immune responses against the recombinant Chlamydia trachomatis fusion antigen CTH522

ABSTRACT Induction of mucosal immunity with vaccines is attractive for the immunological protection against pathogen entry directly at the site of infection. An example is infection with Chlamydia trachomatis (Ct), which is the most common sexually transmitted infection in the world, and there is an unmet medical need for an effective vaccine. A vaccine against Ct should elicit protective humoral and cell‐mediated immune (CMI) responses in the genital tract mucosa. We previously designed an antibody‐ and CMI‐inducing adjuvant based on poly(dl‐lactic‐co‐glycolic acid) (PLGA) nanoparticles modified with the cationic surfactant dimethyldioctadecylammonium bromide and the immunopotentiator trehalose‐6,6′‐dibehenate. Here we show that immunization with these lipid‐polymer hybrid nanoparticles (LPNs) coated with the mucoadhesive polymer chitosan enhances mucosal immune responses. Glycol chitosan (GC)‐modified LPNs were engineered using an oil‐in‐water single emulsion solvent evaporation method. The nanoparticle design was optimized in a highly systematic way by using a quality‐by‐design approach to define the optimal operating space and to gain maximal mechanistic information about the GC coating of the LPNs. Cryo‐transmission electron microscopy revealed a PLGA core coated with one or several concentric lipid bilayers. The GC coating of the surface was identified as a saturable, GC concentration‐dependent increase in particle size and a reduction of the zeta‐potential, and the coating layer could be compressed upon addition of salt. Increased antigen‐specific mucosal immune responses were induced in the lungs and the genital tract with the optimized GC‐coated LPN adjuvant upon nasal immunization of mice with the recombinant Ct fusion antigen CTH522. The mucosal responses were characterized by CTH522‐specific IgG/IgA antibodies, together with CTH522‐specific interferon &ggr;‐producing Th1 cells. This study demonstrates that mucosal administration of CTH522 adjuvanted with chitosan‐coated LPNs represents a promising strategy to modulate the magnitude of mucosal vaccine responses. Graphical abstract Figure. No caption available.

Immunological and physical evaluation of the multistage tuberculosis subunit vaccine candidate H56/CAF01 formulated as a spray-dried powder

Liquid vaccine dosage forms have limited stability and require refrigeration during their manufacture, distribution and storage. In contrast, solid vaccine dosage forms, produced by for example spray drying, offer improved storage stability and reduced dependence on cold-chain facilities. This is advantageous for mass immunization campaigns for global public health threats, e.g., tuberculosis (TB), and offers cheaper vaccine distribution. The multistage subunit vaccine antigen H56, which is a fusion protein of the Mycobacterium tuberculosis (Mtb) antigens Ag85B, ESAT-6, and Rv2660, has been shown to confer protective efficacy against active TB before and after Mtb exposure in preclinical models, and it is currently undergoing clinical phase 2a testing. In several studies, including a recent study comparing multiple clinically relevant vaccine adjuvants, the T helper type 1 (Th1)/Th17-inducing adjuvant CAF01 was the most efficacious adjuvant for H56 to stimulate protective immunity against Mtb. With the long-term goal of designing a thermostable and self-administrable dry powder vaccine based on H56 and CAF01 for inhalation, we compared H56 spray-dried with CAF01 with the non-spray-dried H56/CAF01 vaccine with respect to their ability to induce systemic Th1, Th17 and humoral responses after subcutaneous immunization. Here we show that spray drying of the H56/CAF01 vaccine results in preserved antigenic epitope recognition and adjuvant activity of CAF01, and the spray-dried, reconstituted vaccine induces antigen-specific Th1, Th17 and humoral immune responses, which are comparable to those stimulated by the non-spray-dried H56/CAF01 vaccine. In addition, the spray-dried and reconstituted H56/CAF01 vaccine promotes similar polyfunctional CD4+ T-cell responses as the non-spray-dried vaccine. Thus, our study provides proof-of-concept that spray drying of the subunit vaccine H56/CAF01 preserves vaccine-induced humoral and cell-mediated immune responses. These results support our ongoing efforts to develop a thermostable, dry powder-based TB vaccine.

Temperature-Induced Self-Assembly of the Group B Streptococcus (GBS) Fusion Antigen GBS-NN

Group B Streptococcus (GBS) is a leading cause of serious bacterial neonatal infections worldwide, which provides an unmet medical need for a globally effective vaccine. The recombinant GBS fusion antigen GBS-NN contains the N-terminal regions of the GBS Rib and Alpha C proteins. It shows promising immunogenicity eliciting protective immunity in mice and encouraging results in early human clinical trials. Understanding the physical stability of GBS-NN containing conformational B-cell epitopes is crucial to ensure optimal vaccine stability, efficacy, and safety. We initially discovered that GBS-NN is prone to form higher-order structures at elevated temperatures. We therefore investigated the self-assembly behavior of GBS-NN and characterized the higher-order conformational structures as a function of temperature. In the native state, GBS-NN exists as a monomer and has a secondary structure containing α-helix and β-sheet. Langmuir studies demonstrated that the native protein is highly surface-active and forms a monolayer film at the air-water interface because of its amphipathic properties. The conformational stability of GBS-NN was measured as a function of temperature. GBS-NN has an unusual thermal behavior with a phase transition of approximately 61 °C, which is not accompanied by any major changes in the secondary structure. However, the antigen showed irreversible self-assembly as a function of temperature into higher-order structures with a hydrodynamic diameter of approximately 100 nm. Cryo-transmission electron microscopy analyses demonstrated that these self-assemblies consist of vesicular, ring-like structures with a hollow aqueous interior. Therefore, GBS-NN is a physically stable monomeric protein but is prone to temperature-induced self-assembly above 61 °C.

Unusual Self-Assembly of the Recombinant Chlamydia trachomatis Major Outer Membrane Protein–Based Fusion Antigen CTH522 Into Protein Nanoparticles

Sexually transmitted Chlamydia trachomatis infects more than 100 million people annually, and untreated chlamydia infections can cause severe complications. Therefore, there is an urgent need for a chlamydia vaccine. The Ctrachomatis major outer membrane protein (MOMP) is highly immunogenic but is a challenging vaccine candidate by being an integral membrane protein, and the immunogenicity depends on a correctly folded structure. We investigated the biophysical properties of the recombinant MOMP-based fusion antigen CTH522, which is tested in early human clinical trials. It consists of a truncated and cysteine-free version of MOMP fused to 4 variable domains from serovars D-G. In the native state, CTH522 did not exist as a monomer but showed an unusual self-assembly into nanoparticles with a negative zeta potential. In contrast to the β-barrel structure of MOMP, native CTH522 contained no well-defined secondary structural elements, and no thermal transitions were measurable. Chemical unfolding resulted in monomers that upon removal of the denaturant self-assembled into higher order structures, comparable to the structure of the native protein. The conformation of CTH522 in nanoparticles is thus not entirely random and contains structural elements stabilized via denaturant-disruptable hydrophobic interactions. In conclusion, CTH522 has an unusual quaternary structure of supramolecular self-assemblies.