Kevin Plattner

and 5 more

Background: IgE antibodies are involved in type-1 hypersensitivity. Cross-linking IgE bound to the high-affinity IgE receptor, FceRI on effector cells with an allergen can cause anaphylaxis. Recent studies have shown that IgE glycosylation significantly impacts the ability of IgE to bind to its high-affinity receptor FceRI and exert effector functions 1,2. We have recently shown that immunization of mice with IgE in complex with an allergen leads to a protective, glycan-dependent anti-IgE response 3. However, to what extent the glycans on IgE determine the induction of those antibodies and how they facilitate serum clearance is unclear. We investigated the role of glycan-specific IgG anti-IgE autoantibodies in regulating serum IgE levels and preventing systemic anaphylaxis by passive immunization. Methods: Mice were immunized using glycosylated or deglycosylated IgE-allergen-immune complexes (ICs) to induce anti-IgE IgG antibodies. The anti-IgE IgG antibodies were purified and used for passive immunization. Results: Glycosylated IgE-ICs induced a significantly higher anti-IgE IgG response and more IgG secreting plasma cells than deglycosylated IgE-ICs. Passive immunization of IgE sensitized mice with purified anti-IgE IgG increased the clearance of IgE and prevented systemic anaphylaxis upon allergen challenge. Anti-IgE IgG purified from the serum of mice immunized with deglycosylated IgE-ICs, led to a significantly reduced elimination and protection, confirming that the IgE glycans themselves are the primary drivers of the protectivity induced by the IgE-immune complexes. Conclusion: IgE glycosylation is essential for a robust anti-IgE IgG response and might be an important regulator of serum IgE level.

Mona Mohsen

and 27 more

SARS-CoV-2 caused one of the most devastating pandemics in the recent history of mankind. Due to various countermeasures, including lock-downs, wearing masks and increased hygiene, the virus has been controlled in some parts of the world. More recently, the availability of vaccines, based on RNA or Adenoviruses, have greatly added to our ability to keep the virus at bay, again in some parts of the world only. While available vaccines are effective, it would be desirable to also have more classical vaccines at hand for the future. Key feature of vaccines for long-term control of SARS-CoV-2 would be inexpensive production at large scale, ability to make multiple booster injections and long-term stability at +4 oC. Here we describe such a vaccine candidate, consisting of the SARS-CoV-2 receptor binding motif grafted genetically onto the surface of the immunologically optimized cucumber mosaic virus, called CuMV TT-RBM. Using bacterial fermenter production and continuous flow centrifugation, the productivity of the production process is estimated to be >2.5 million doses per 1000 liter fermenter run and the vaccine candidate is stable for at least 14 months at 4°C. We further demonstrate that the candidate vaccine is highly immunogenic in mice and rabbits and induces more high avidity antibodies compared to convalescent human sera and antibodies induced are more cross-reactive to mutant RBDs for variants of concern (VoC). Furthermore, antibody responses are neutralizing and long-lived. This, the here presented VLP-based vaccine may be a good candidate for use as conventional vaccine in the long-term.