Vaccination is the most effective measure at preventing influenza virus infections. However, current seasonal influenza vaccines are only protective against closely matched circulating strains. Even with extensive monitoring and annual reformulation our efforts remain one step behind the rapidly evolving virus, often resulting in mismatches and low vaccine effectiveness. Fortunately, many next-generation influenza vaccines are currently in development, utilizing an array of innovative techniques to shorten production time and increase the breadth of protection. This review summarizes the production methods of current vaccines, recent advances that have been made in influenza vaccine research, and highlights potential challenges that are yet to be overcome. Special emphasis is put on the potential role of glycoengineering in influenza vaccine development, and the advantages of removing the glycan shield on influenza surface antigens to increase vaccine immunogenicity. The potential for future development of these novel influenza vaccine candidates is discussed from an industry perspective.
Summary The influenza virus hemagglutinin (HA) and coronavirus spike (S) protein mediate virus entry. HA and S proteins are heavily glycosylated, making them potential targets for carbohydrate binding agents such as lectins. Here, we show that the lectin FRIL, isolated from hyacinth beans ( Lablab purpureus ), has anti-influenza and anti-SARS-CoV-2 activity. FRIL can neutralize 11 representative human and avian influenza strains at low nanomolar concentrations, and intranasal administration of FRIL is protective against lethal H1N1 infection in mice. FRIL binds preferentially to complex-type N-glycans and neutralizes viruses that possess complex-type N-glycans on their envelopes. As a homotetramer, FRIL is capable of aggregating influenza particles through multivalent binding and trapping influenza virions in cytoplasmic late endosomes, preventing their nuclear entry. Remarkably, FRIL also effectively neutralizes SARS-CoV-2, preventing viral protein production and cytopathic effect in host cells. These findings suggest a potential application of FRIL for the prevention and/or treatment of influenza and COVID-19.
A major challenge to end the pandemic caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is to develop a broadly protective vaccine that elicits long-term immunity. As the key immunogen, the viral surface spike (S) protein is frequently mutated, and conserved epitopes are shielded by glycans. Here, we revealed that S protein glycosylation has site-differential effects on viral infectivity. We found that S protein generated by lung epithelial cells has glycoforms associated with increased infectivity. Compared to the fully glycosylated S protein, immunization of S protein with N-glycans trimmed to the mono-GlcNAc-decorated state (S MG ) elicited stronger immune responses and better protection for human angiotensin converting enzyme 2 (hACE2) transgenic mice against variants of concern (VOCs). In addition, a broadly neutralizing monoclonal antibody was identified from S MG immunized mice that could neutralize wild type (WT) SARS-CoV-2 and VOCs with sub-picomolar potency. Together, these results demonstrate that removal of glycan shields to better expose the conserved sequences has the potential to be an effective and simple approach for developing a broadly protective SARS-CoV-2 vaccine.
Coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has resulted in more than 167 million confirmed cases and over 3 million deaths so far. This global pandemic has led to great efforts directed toward the study of this virus and its infection mechanism as well as development of effective means to control this devastating infectious disease. Like many other viral surface proteins, the trimeric SARS-CoV-2 spike (S) protein is heavily glycosylated with 22 N- and 2 O-glycosites per monomer which are likely to influence S protein folding and evade host immune response. More than one million S protein sequences with over 1,000 sites of mutation in its 1,273 amino acids have been reported to the GISAID database, including the highly transmissible variant strains found in the UK and South Africa. This high frequency of transmission and mutation is a major challenge in the development of broadly protective vaccines to control the pandemic. We have studied the impact of glycosylation on receptor-ligand interaction through evaluation of ACE2 and S protein expressed in different cell lines. Of different S protein glycoforms, the one expressed from lung epithelial cells, the primary cells for infection, has more complex-type glycans and higher binding avidity to the receptor as compared with the S protein from HEK293T cells which have more high-mannose or hybrid-type glycoforms. We also found that most of the S protein glycosites are highly conserved and the glycosites at positions 801 and 1194 are essential for viral entry. In addition, the RBD of S1 and the HR regions of S2 contain most of highly conserved sequences, and removal of each glycosite on pseudotyped SARS-CoV-2 virus for evaluation of the impact on structure and function provides insights into the design of broadly protective vaccines. In an effort to develop such universal vaccines, we found that mice immunized with monoglycosylated S protein (Smg) elicited better antibody responses capable of neutralizing not only the wild type but also the variants from the UK and South Africa than those with the fully-glycosylated S protein (Sfg), and strikingly, Smg vaccination provides better survival for hACE2 transgenic mice when challenged with lethal dose of SARS-CoV-2. Moreover, using single B cell technology, we isolated a monoclonal antibody from Smg immunized mice which was also able to neutralize the wild type and variants, suggesting that removal of unnecessary glycans from S protein to better expose the highly conserved sequences is an effective approach to developing broadly protective vaccines against SARS-CoV-2 and variants.
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