Credit NIAID
#18,403
Although we spend a good deal of time looking at the risks from novel influenza viruses, seasonal flu kills hundreds of thousands every year around the globe. Even with somewhere near a billion people getting the flu vaccine every year (which is only moderately effective), that leaves a lot of people at risk of serious illness or death.
Influenza antivirals have been around for nearly 50 years (Amantadine was approved in the US in 1976), while oseltamivir (aka Tamiflu) was approved in 1999, and Baloxavir in 2018.
But very much like we see with antibiotics and bacteria, antivirals are susceptible to resistance developing over time in targeted viruses. By the end of 2005 our oldest class of flu antivirals - M2 ion channel blockers (e.g. Amantadine, Rimantadine) - had become largely ineffective against seasonal H3N2, and in early 2006 were no longer recommended for use.
Luckily we had oseltamivir -- an NAI (neuraminidase inhibitor) - to fall back on. It was, however, far more expensive and difficult to produce in quantity. While occasional instances of Oseltamivir resistance (1%) were reported prior to 2007, in nearly every case, it developed after a person was placed on the drug (i.e. `spontaneous mutations’).Studies suggested that these resistant strains suffered a `fitness penalty', and were therefore unlikely to spread from human-to-human.An optimistic view that lasted just over 2 years, as by 2008 seasonal H1N1 picked up `permissive mutations' (Cite) that enabled resistant seasonal H1N1 viruses to spread rapidly around the globe. By the end of 2008, the CDC was forced to issue major new guidance for the use of antivirals (see CIDRAP article With H1N1 resistance, CDC changes advice on flu drugs).
This resistance was due primarily to the acquisition of an H275Y mutation, and had seasonal H1N1 not been supplanted by a (still NAI susceptible) pandemic swine H1N1 virus in the spring of 2009, oseltamivir might still be off the table.
We've been watching ever since 2009 for any signs that the replacement pH1N1 virus has been gaining resistance to oseltamivir, but for the most part, the news has been pretty good. And in 2018 a new (albeit more expensive) class of antivirals (Baloxavir) was added to our armamentarium.
Eurosurveillance: An outbreak of A(H1N1)pdm09 Exhibiting Cross-resistance to Oseltamivir & Peramivir in an Elementary School in Japan, Sept 2024
Viruses: Increase of Synergistic Secondary Antiviral Mutations in the Evolution of A(H1N1)pdm09 Influenza Virus Neuraminidases
EID Journal: Multicountry Spread of Influenza A(H1N1)pdm09 Viruses with Reduced Oseltamivir Inhibition, May 2023–February 2024
Eurosurveillance: A community Cluster of Influenza A(H3N2) Virus infection with Reduced Susceptibility to Baloxavir - Japan 2023
EID Journal: H-2-H Transmission Of A(H3N2) with Reduced Susceptibility to Baloxavir, Japan
This week we have a new dispatch, published in the CDC's EID Journal, that describes another instance of Baloxavir resistance in Japan (where the drug is mostly widely used). While only one case is reported, it was in a child who had not been treated with the antiviral, and it was due to a previously unassociated mutation.
I've posted the link, abstract, and some excerpts, but many will want to read the full dispatch. I'll have a bit more after the break.
Dispatch
Influenza A(H1N1)pdm09 Virus with Reduced Susceptibility to Baloxavir, Japan, 2024
Emi Takashita, Hiroko Morita, Shiho Nagata, Seiichiro Fujisaki, Hideka Miura, Tatsuya Ikeda, Kenichi Komabayashi, Mika Sasaki, Yohei Matoba, Tomoko Takahashi, Naomi Ogawa, Katsumi Mizuta, Sueshi Ito, Noriko Kishida, Kazuya Nakamura, Masayuki Shirakura, Shinji Watanabe, and Hideki Hasegawa
Abstract
Influenza A(H1N1)pdm09 virus carrying an I38N substitution was detected in an untreated teenager in Japan. The I38N mutant virus exhibited reduced susceptibility to baloxavir but remained susceptible to neuraminidase inhibitors and showed reduced growth capability. Monitoring antiviral drug susceptibility of influenza viruses is necessary to aid public health planning and clinical recommendations.
(SNIP)
The PA I38T substitution is the most frequent substitution and has the greatest effect on baloxavir susceptibility (5). Influenza A(H1N1)pdm09 (pH1N1) and A(H3N2) viruses with the PA I38T substitution isolated from baloxavir-treated patients show similar replication fitness and pathogenicity to wild-type isolates tested in hamsters and efficiently transmit between ferrets by respiratory droplets (6).
We have monitored baloxavir susceptibility of seasonal influenza viruses in Japan since the 2017–18 season and reported human-to-human transmission of PA I38T mutant H3N2 viruses in children <10 years of age (7,8).
Researchers detected a PA I38N substitution in a pH1N1 virus isolated from a patient during a phase 3 clinical trial of baloxavir. That substitution conferred a 24-fold reduction in baloxavir susceptibility in recombinant A/WSN/33(H1N1) and a 10-fold reduction in recombinant A/Victoria/3/75(H3N2) and reduced growth capability in both viruses (3,9). However, its effect on pH1N1 virus has not been reported.
During our 2023–24 surveillance, we detected a PA I38N mutant pH1N1 virus in a 14-year-old patient not treated with baloxavir. Here, we report the in vitro characterization of the PA I38N mutant pH1N1 virus.
Conclusions
In this study, we showed that the PA I38N mutant pH1N1 virus had reduced susceptibility to baloxavir but remained susceptible to NA inhibitors. Our results indicate that the PA I38N substitution in the pH1N1 virus contributed to a reduction in baloxavir susceptibility, but the reduction in susceptibility was less than that caused by the PA I38T substitution (3,9).
PA I38 is highly conserved in influenza A and B viruses (1). During October 2023–March 2024, medical institutions that serve ≈3.7 million persons in Japan received baloxavir to use for antiviral treatment. The PA I38N substitution may negatively affect the growth capability of the virus in vitro; however, our findings suggest possible transmission of the PA I38N mutant pH1N1 virus from another host harboring the mutant virus, which may have emerged under the selective pressure of baloxavir or as a result of a rare spontaneous mutation.
In Japan, influenza activity was low throughout the COVID-19 pandemic; the first influenza outbreak occurred in the 2022–23 season (13). The influenza outbreak in the 2023–24 season was larger than that of 2022–23 (Figure 1). Influenza pH1N1 virus activity peaked in November 2023 and then declined.
The PA I38N mutant pH1N1 virus in this study was detected in March 2024. By March, the pH1N1 outbreak was almost over, and no regional spread of the PA I38N mutant pH1N1 virus was observed.
We reported a community cluster of influenza A(H3N2) viruses with reduced susceptibility to baloxavir caused by a PA E199G substitution in Japan in February–March 2023 (13). In addition, researchers reported widespread community clusters of pH1N1 viruses with cross-resistance to oseltamivir and peramivir in Australia and Japan (14,15). Monitoring of antiviral drug susceptibility of influenza viruses is necessary to aid public health planning and clinical recommendations for antiviral drug use.
Dr. Takashita is a virologist with the National Institute of Infectious Diseases, Tokyo, Japan. Her research interests include antiviral drug susceptibilities of influenza viruses.
While a loss of one (or both) of our main classes of antivirals would be a disaster for seasonal flu, it could have even greater impact during a pandemic. For most people, a novel flu vaccine would only be available 6 months or more into an outbreak (see Referral: SCI AM - A Bird Flu Vaccine Might Come Too Late to Save Us from H5N1).
Although we've not seen any reports of H275Y in D1.1 samples collected in the United States, last November the CDC did report finding a far-less impactful mutation (NA-S247N) in 3 poultry workers from Washington State, which they stated may slightly reduce the virus's susceptibility to antivirals.Just over 2 weeks ago, St. Jude Researchers warned Current Antivirals Likely Less Effective Against Severe Infection Caused by Bird Flu in Cows’ Milk, and 6 weeks ago we learned from Emerg. Microbes & Inf: Oseltamivir Resistant H5N1 (Genotype D1.1) found On 8 Canadian Poultry Farms.
Although I remain hopeful our antiviral stockpiles (mostly oseltamivir) can help `take the edge off' the opening months of the next pandemic, it is by no means assured.
To be most effective, antivirals ideally need to be given early (< 48 hours) into an infection. Stockpiles are finite, and even during moderately severe seasonal flu epidemics we've seen difficulties in rapidly dispensing these drugs (see 2022's CDC HAN #0482: Prioritizing Antiviral Treatment of Influenza in the Setting of Reduced Availability of Oseltamivir).
Any way you cut it, our first line of defense will - once again - rely heavily on NPIs (non-pharmaceutical interventions), like face masks, hand washing, ventilation, staying home while sick, and avoiding crowds.