In a groundbreaking advancement for infectious disease prevention, researchers have unveiled a novel mRNA-based seasonal influenza vaccine that encodes both hemagglutinin (HA) and neuraminidase (NA), two critical viral surface proteins. This innovative approach represents a significant evolution beyond the current influenza vaccine platforms, promising enhanced immunogenicity and safety profiles that could redefine how we combat the annual flu season globally. The study, published in Nature Communications, combines cutting-edge molecular biology with rigorous clinical evaluation to pave the way for next-generation vaccines that address the unpredictability and mutability of seasonal influenza viruses.
The influenza virus remains a formidable public health challenge due to its rapid antigenic drift and occasional antigenic shift, mechanisms that allow it to evade immune recognition and reduce vaccine effectiveness. Traditionally, flu vaccines have primarily targeted hemagglutinin, the main protein responsible for viral attachment and entry into host cells. However, the new mRNA vaccine uniquely incorporates coding sequences for neuraminidase as well, an enzyme that facilitates viral release and propagation. This dual-targeting strategy is designed to elicit a broader and more robust immune response, potentially overcoming the limitations of current vaccines that often show variable effectiveness from year to year.
The researchers engineered a lipid nanoparticle (LNP)-encapsulated mRNA vaccine encoding full-length HA and NA proteins derived from the predominant influenza strains predicted for the upcoming season. By leveraging the mRNA vaccine platform, which gained widespread recognition during the COVID-19 pandemic, this approach enables rapid and precise antigen production within host cells, eliciting both humoral and cellular immunity. The inclusion of neuraminidase is particularly notable, as antibodies against NA can inhibit viral spread and are correlated with reduced disease severity, yet have been historically underrepresented in vaccine formulations.
.adsslot_8GlYbu7Fxc{ width:728px !important; height:90px !important; }
@media (max-width:1199px) { .adsslot_8GlYbu7Fxc{ width:468px !important; height:60px !important; } }
@media (max-width:767px) { .adsslot_8GlYbu7Fxc{ width:320px !important; height:50px !important; } }
ADVERTISEMENT
Preclinical studies demonstrated that the vaccine prompts robust antigen expression in vivo, leading to a potent neutralizing antibody response against multiple influenza subtypes. The dual antigen design also showed promise in eliciting cross-reactive immunity, an essential feature given the high mutation rate of influenza viruses. Importantly, the safety profile was thoroughly assessed in animal models, with no significant adverse effects observed, providing compelling evidence for the potential of this vaccine to progress through clinical trials.
A critical aspect of this research is the detailed evaluation of immunogenicity—the vaccine’s ability to stimulate an immune response. Hemagglutination inhibition (HAI) assays revealed significantly higher titers of neutralizing antibodies compared to monovalent HA-only vaccines. Additionally, neuraminidase inhibition (NAI) assays confirmed that the immune system effectively recognized NA, a milestone that has been challenging to achieve in the context of influenza vaccination. The synergy between HA and NA antigens may contribute to a more durable immunity, reducing the frequency and severity of infections during flu season.
The safety analysis encompassed both local and systemic reactions, typical of vaccine studies, recorded in preclinical models. Researchers reported minimal injection site reactions and no systemic toxicity, underscoring the biocompatibility of the LNP-mRNA platform when used for influenza vaccination. These findings not only bolster confidence in the vaccine’s safety but also highlight the potential for this technology to be adapted rapidly to emerging influenza strains or other respiratory pathogens.
From a molecular standpoint, the mRNA constructs were optimized for enhanced stability and translational efficiency. Codon usage was meticulously designed to match human cellular machinery, while untranslated regions (UTRs) were engineered to improve mRNA half-life without triggering excessive innate immune activation, which can interfere with antigen expression. This balance is critical to achieving high protein yield and robust immune priming, a hallmark of successful mRNA vaccines.
Moreover, the vaccine’s ability to induce T-cell responses was thoroughly investigated. CD8+ cytotoxic T lymphocytes (CTLs) play an important role in clearing influenza-infected cells and providing long-term immunity. Flow cytometry and ELISpot assays revealed that vaccinated subjects mounted significant T-cell responses directed against both HA and NA epitopes. This cellular immunity complements the antibody-mediated protection, offering a multi-layered defense against viral infection and possibly contributing to reduced viral replication and transmission.
Another highlight of the study involves the assessment of mucosal immunity, an often-overlooked yet critical component of influenza protection. Secretory IgA antibodies at mucosal surfaces can neutralize viruses at entry points, preventing infection establishment. Preliminary data indicate that the mRNA vaccine may stimulate mucosal immune responses when administered intramuscularly, a finding that warrants further exploration and could have profound implications for vaccine delivery strategies.
One of the paramount challenges in influenza vaccine development is antigenic mismatch; the virus’s high mutation rate often leads to strain variants that escape immunity induced by prior vaccination. The inclusion of neuraminidase antigens might mitigate this issue by presenting conserved regions of the viral NA protein that are less prone to mutation. This potentially broadens the vaccine’s effectiveness against diverse influenza strains and may reduce the necessity for annual reformulation.
The study also addresses manufacturing and scalability considerations inherent in mRNA vaccine technologies. The modular nature of mRNA design allows for rapid adaptation to circulating influenza strains, significantly shortening production timelines compared to traditional egg-based or recombinant protein vaccines. Moreover, the established cold chain logistics and mass production infrastructure developed during the COVID-19 vaccine rollout provide a framework for efficient global distribution of influenza mRNA vaccines.
Looking to the future, experts anticipate that this dual-antigen mRNA vaccine could revolutionize the annual influenza vaccination paradigm, potentially improving global vaccine coverage and efficacy rates. By providing enhanced immunity and a favorable safety profile, this approach aligns with the broader goal of preventing seasonal influenza epidemics and minimizing the burden on healthcare systems worldwide. Ongoing clinical trials are expected to validate these promising preclinical results and bring this transformative vaccine closer to licensure.
The integration of neuraminidase into seasonal influenza vaccines could also influence vaccine policy and public health strategies. Surveillance systems may need to incorporate NA antigenic data to inform vaccine strain selection more comprehensively. Additionally, the enhanced vaccine efficacy might reduce influenza-related hospitalizations and mortalities, contributing to improved population health outcomes, particularly among vulnerable groups such as the elderly and immunocompromised.
This advancement also opens avenues for mRNA vaccine applications beyond influenza. By demonstrating the successful co-expression of multiple antigens and eliciting broad immune responses, the platform can be adapted to complex pathogens requiring multivalent protection. The scientific community anticipates a surge in research leveraging mRNA technology to combat emerging infectious diseases, leveraging lessons learned from this pioneering influenza vaccine study.
Ultimately, the convergence of molecular innovation and immunological insight embodied in this research marks a pivotal step toward more effective, safe, and adaptable vaccines. As global health challenges intensify, such scientific breakthroughs underscore the relentless pursuit required to outpace evolving pathogens and safeguard human health. The study by Rudman Spergel, Lee, Koslovsky, and colleagues ushers in a new era of influenza vaccination that could transform the landscape of infectious disease prevention.
Subject of Research: Immunogenicity and safety evaluation of mRNA-based seasonal influenza vaccines encoding both hemagglutinin and neuraminidase proteins.
Article Title: Immunogenicity and safety of mRNA-based seasonal influenza vaccines encoding hemagglutinin and neuraminidase.
Article References:
Rudman Spergel, A.K., Lee, I.T., Koslovsky, K. et al. Immunogenicity and safety of mRNA-based seasonal influenza vaccines encoding hemagglutinin and neuraminidase. Nat Commun 16, 5933 (2025). https://doi.org/10.1038/s41467-025-60938-4
Image Credits: AI Generated
Tags: antigenic drift and shift in influenzaclinical evaluation of mRNA vaccinescombating seasonal flu effectivelydual-targeting flu vaccine strategyenhanced immunogenicity in vaccineshemagglutinin and neuraminidase proteinsinnovative approaches to flu preventionlipid nanoparticle vaccine technologymRNA influenza vaccine developmentnext-generation influenza vaccinespublic health challenges of influenzaseasonal flu vaccine safety