Influenza: Our Old Fickle Foe

This yearmarks the 100-year anniversary of the devastating influenza pandemic of 1918, which killed an estimated 20-40 million people globally. Given the ever-evolving nature of the virus, it is not surprising that we now find ourselves in themidst of yet another particularly brutal flu season that has taken our immune systems and healthcare infrastructure off guard yet again. The H3N2 strain of influenza A virus, which is typically associated with more severe illness and higher mortality, has dominated both hemispheres this year. However, influenza type B viruses are also wreaking havoc this season. Although we have learned much about influenza virus biology in 100 years, it is hard not to feel frustrated that we don’t have a more effective, andmore broadly-protective, “universal” vaccine. The current egg-based inactivated vaccine approach for protecting the population against seasonal influenza hasn’t changed much at all since the 1940s. Each year, the World Health Organization makes a recommendation on which strains to include in a given year’s vaccine formulation. However—due to the virus’s high mutation rate and variable transmission patterns—in some years, these best estimates unfortunately result in an immunological mismatch against the predominantly circulating strain (s). The goal of a universal vaccine, therefore, is to induce a broadly protective immune response to unchanging component(s) of the virus that are conserved across viral strains, and that are not susceptible to seasonal antigenic drift. Several approaches are underway toward this end. Researchers at UCLA, for example, have shown recently in Science that by systematically knocking out multiple virulence sites on the virus they were able to produce an attenuated virus that was highly-susceptible to interferon, but that was viable enough to induce a potent immune response capable of providing protection against heterologous viruses. This approach, if successful in humans, should have the benefit of not only providing cross-protection against ever-evolving seasonal strains but also the live nature of the virus will make it suitable for convenient nasal spray administration. Researchers have also been trying for years to make a vaccine that will induce broadly neutralizing antibodies directed against the unvarying stem (stalk) of the viral surface hemagglutinin protein, yet challenges with immunogenicity have delayed getting this approach into human clinical trials. Another approach directed targeting the viral nucleoprotein and matrix 1 proteins has been shown to be safe in humans, and is just nowmoving into a two-year phase II trial.We eagerly await the results of this first-ever humanuniversal influenza vaccine trial.