Saturday, July 11, 2026

EM&I: Characterization of oseltamivir-resistant A(H5N1) clade 2.3.4.4b, genotype D1.1 variants identified in poultry farms of British Columbia, Canada

Abrupt Shift in H5N1 Genotypes in Wild Birds in US/Canada
Nature https://www.nature.com/articles/s41591-026-04300-1


#19,242

In the fall of 2024 - while we were watching the bovine B3.13 genotype spread in U.S. cattle - a new genotype (D1.1) of H5N1 appeared in Canada and the Pacific Northwest which very quickly became dominant in wild birds and swept eastward across the United States and Canada.

Since then, we've seen roughly 2 dozen confirmed human infections from this D1.1 genotype - several of them severe or fatal (see CDC Statement: First H5 Bird Flu Death Reported in United States) - along with studies suggesting it may better adapted to humans than B3.13 (see J.I.D.: Avian influenza virus A(H5N1) genotype D1.1 is better adapted to human nasal and airway organoids than genotype B3.13).

In early 2025  D1.1 was  detected in dairy cattle in two states (Nevada & Arizona), and later in Wisconsin, further raising concerns over its ability to infect mammals.

When it comes to treating H5N1 infection, Oseltamivir (aka `Tamiflu') remains the overwhelming drug of choice (see below), and makes up > 90% of our stockpiled influenza antiviral armamentarium. 


Previous reports on the incidence of oseltamivir resistance in H5N1 have been fairly reassuring (see 2023's Antiviral Research: Antiviral susceptibility of clade 2.3.4.4b HPAI H5N1 Viruses Isolated From Birds & Mammals in the United States, 2022), but we've seen how quickly that status quo can change. 

Which is why the surprise announcement in February of 2025 that Oseltamivir Resistant H5N1 (Genotype D1.1) had been found On 8 Canadian Poultry Farms in the fall of 2024, raised so many concerns.

In a report from Canada's CFIA and PHAC - the authors described the detection of a (previously) rare H275Y substitution in the neuraminidase (NA) protein of a number of genotype D1.1 isolates, one which is associated with strong resistance to the NA inhibitors oseltamivir and peramivir.

Normally, we only see this mutation appear in a small percentage (1%) of patients receiving antiviral treatment.  Because it is thought to exact a `fitness penalty' on influenza A viruses - limiting forward transmission -  H275Y in the `wild' is fairly rare. 

But over the past few years we've seen evidence of creeping oseltamivir resistance in seasonal H1N1 (FluView Week #20: EOY Review of Increased Detection of Oseltamivir Resistant H1N1 Viruses), along with growing concerns that oseltamivir monotherapy may no longer be the most effective treatment of H5N1.


All of which brings us to a new study, published in Emerging Microbes & Infections, which characterizes the oseltamivir resistant D1.1 viruses detected on 8 Canadian poultry farms in the fall of 2024.  

This is a lengthy, and at times technical, review.  I've posted the abstract and a few excerpts below, but many will want to read the report in its entirety.  I'll have a bit more after the break.

Characterization of oseltamivir-resistant A(H5N1) clade 2.3.4.4b, genotype D1.1 variants identified in poultry farms of British Columbia, Canada

Maxime CochinYacine AbedRobert VendramelliKatrina DionneCatherine BourassaGeneviève Laroche , show all
Article: 2686474 | Received 16 Feb 2026, Accepted 04 Jun 2026, Published online: 08 Jul 2026
 https://doi.org/10.1080/22221751.2026.2686474
ABSTRACT

Highly pathogenic avian influenza A(H5N1) viruses of clade 2.3.4.4b, genotype D1.1, are responsible for widespread outbreaks in poultry and continue to cause sporadic, sometimes severe, human infections. Herein, we characterized a wild-type (WT) influenza A(H5N1) D1.1 isolate (BC-H5N1-WT) and its H275Y neuraminidase (NA) variant (BC-H5N1-H275Y), both of which emerged on farms in British Columbia, Canada, during the fall 2024 outbreak.
In vitro analysis assessed replication kinetics in MDCK cells, with supernatants collected at different days post-infection (p.i.) and titrated by TCID50 and qRT-PCR. Neuraminidase inhibitor (NAI) susceptibility was determined by NA inhibition assays, whereas susceptibility to baloxavir acid (BXA) was evaluated by plaque reduction assay. In vivo virulence was evaluated in BALB/c mice infected with serial 10-fold dilutions of each virus to monitor weight loss and mortality. Viral titers in lungs, brain, nose, kidney, spleen, and heart were quantified at day 4 p.i. The BC-H5N1-WT virus was susceptible to the four antivirals tested, whereas BC-H5N1-H275Y displayed resistance to oseltamivir and peramivir but remained susceptible to zanamivir and BXA.
The BC-H5N1-WT exhibited significantly higher viral replication titers than BC-H5N1-H275Y at all tested time points and showed larger plaque sizes. In mice, BC-H5N1-WT was more virulent with LD50 values of 1.78 × 103 PFUs compared to 8.71 × 104 PFUs for BC-H5N1-H275Y, and produced higher viral titers in lungs and other organs. Despite the reduced fitness of the resistant H5N1 D1.1 variant, its emergence in the absence of viral selection pressure underscores the need for continued surveillance.

        (SNIP)

In October 2024, several chicken farms in the province of BC, Canada, faced an outbreak of HPAIV. Whole genome sequencing confirmed that the virus was an H5N1 virus of the clade 2.3.4.4b [Citation7]. Phylogenetic analysis of the hemagglutinin (HA) and neuraminidase (NA) genes confirmed that the viruses involved were reassortant H5 viruses of clade 2.3.4.4b with an avian NA of N1 subtype from a North American wild bird lineage [Citation7].
Notably, this NA has a longer stalk compared to the truncated NA stalk of traditional HPAI H5N1 strains [Citation8]. Fully Eurasian 2.3.4.4b H5N1 viruses also possess this untruncated (long-stalk) NA, differing from the short-stalk NA common in most pre-2020 highly pathogenic H5N1 strains.
Interestingly, the NA gene from 8 of the 45 sampled poultry farms harboured the well-described H275Y (N1 numbering) substitution that confers high levels of resistance to oseltamivir (OSV) and peramivir (PER), which are influenza NA inhibitors (NAI).
Of note, there was no evidence of OSV or PER use in the related farms that could explain the presence of such H275Y mutants in these animals. Although old H1N1 viruses with the H275Y substitution were associated with a fitness loss [Citation9–11], more recent seasonal and pandemic H1N1 mutant viruses were more fit than the wild-type (WT) virus due to the presence of permissive NA mutations [Citation12–14].

       (SNIP)

It has been well described that the H275Y NA substitution can be selected under OSV pressure either clinically or in experimental in vitro/in vivo procedures. However, to the best of our knowledge, there was no use of OSV in poultry that could explain the emergence of the H275Y NA substitution in BC farms.
  • One possible explanation could be poultry exposure to antivirals in the environment (e.g. via contaminated water near human treatment centers) [Citation40]. 
  • Another possibility is cross-species contamination where the mutation would emerge in humans and spills back into poultry but the only human Canadian case with H5N1 infection so far was not infected by this mutant [Citation6].
  •  A more probable scenario seems to be that the H275Y substitution has emerged spontaneously as influenza viral replication involves an error-prone RNA-dependent RNA polymerase, with random mutations occurring frequently. Such mutation could potentially favour a more optimal balance between HA and NA in some viruses.
OSV is considered the preferred antiviral for the control of a potential influenza pandemic involving avian influenza viruses such as H5N1. Consequently, stockpiles of this compound have been established in several countries worldwide. This study and other observations suggest that it would be unwise not to consider alternatives in the event of the emergence of the H275Y substitution. 
 
This should include the consideration of other antivirals such as BXM, as well as combinations of antivirals with different mechanisms of action, i.e. ZAN (NAI) and BXM (polymerase inhibitor). Also, our findings confirm the need for extensive surveillance studies for influenza drug resistance not restricted to humans.

        (Continue . . . )
 

While the origin of this cluster of H275Y bearing H5N1 viruses remains unclear, the good news is these viruses (at least, back in 2024) showed diminished virulence (in BALB/c mice).

But as we saw with seasonal H1N1 in 2008, `fitness penalties' can be offset by permissive mutations elsewhere in the NA, which is why we follow reports like this one with interest.  

D1.1 isn't the only genotype of concern, and new genotypes will undoubtedly emerge in the future. Most will be evolutionary failures, but the success of B3.13 and D1.1 remind us there are exceptions. 

Even if widespread oseltamivir resistance doesn't emerge, our antiviral stockpile is limited, and we've previously seen problems getting them to patients during the first critical 48 hours of infection (see Sporadic Tamiflu (Oseltamivir) Shortages Reported In U.S. & Canada). 

Once again, our first line of defense will likely rely heavily on NPIs (non-pharmaceutical interventions), like face masks, hand washing, ventilation, staying home while sick, and avoiding crowds.

Which is why I'm recommending that people seriously consider now (see #Natlprep 2025: Personal Pandemic Preparedness) what they will do if another pandemic virus should embark on a new world tour.

Friday, July 10, 2026

Australia Confirms H5N1 in Local Seabird - Confirmed Detections (N=13)

Greater Crested Tern
Link  CC 4.0 Author mattf1996

#19,241

While long expected (see Australia : Biodiversity Council Webinar on HPAI H5 Avian Flu Threat), just three weeks ago Australia reported their first detection of HPAI H5N1 in a migratory bird (brown skua) in Western Australia.

Since then two other states (South Australia & NSW) have reported detections in migratory birds - with the nation's tally standing at 7 as of Monday, July 6th.

Overnight (here in the U.S.) Reuters has reported two new events of import - the first detection of H5N1 in a local seabird in SA, and testing of a dead seal in NSW -  although the most recent governmental summary report mentions neither of them.

It is also worth noting that some of the granular reporting featured in earlier  announcements (exact locations, dates of recovery, suspected cases under investigation, etc.) have recently been replaced by briefer summaries. 

 First, the latest official update. 

June 2026 H5 bird flu detection

As of 8.30pm AEST, 10 July 2026, Australia has 13 confirmed detections of H5 bird flu in wild birds.

There are seven confirmed in Western Australia (WA), five in South Australia (SA) and one in New South Wales (NSW).

There is no evidence of any mass mortality. There is no evidence of infection in poultry or the wider agriculture industry.

The risk to human health remains low.

Australia is well prepared to respond quickly.

If you notice sick or dead birds or other animals, you should not touch them or get too close. Record your location and report it to the 24-hour Emergency Animal Disease Hotline on 1800 675 888.

More information is available in the update below.

While a bit terse, we get some additional detail - including confirmation of the detection in a local seabird - in the following report from Australia's Chief Veterinary Officer: 

H5 bird flu testing updates 

10 July 2026

Attributable to the Australian Chief Veterinary Officer, Dr Beth Cookson:

Testing at CSIRO’s Australian Centre for Disease Preparedness has confirmed four additional detections of H5 high pathogenicity avian influenza (bird flu).

This includes a detection in a greater crested tern, found near Robe, South Australia. This is the first detection of H5 bird flu in an Australian wild non-migratory seabird.

CSIRO’s ACDP has confirmed two additional positive cases in wild migratory seabirds from South Australia. The petrels were found in Port Vincent, Yorke Peninsula and Emu Bay, Kangaroo Island.

CSIRO’s ACDP has also confirmed another positive result in a previously reported suspect petrel from Mullaloo Beach, Perth in Western Australia. Testing remains underway for a further suspect case from a petrel at Horrocks Beach in the Shire of Northampton.

There have now been 12 confirmed or presumed positive detections of H5 bird flu in Australia.

There remains no evidence of any mass mortality events, and there are no detections in poultry or in our agricultural production system.

The risk to human health remains low. 

And lastly we get the following update from Western Australia's Department of Primary Industries and Regional Developmentwhere roughly 100 of  > 1,400 wildlife-related reports have thus far been investigated, producing 7 positive results.

H5 bird flu confirmed on northern WA beaches
Media release

Western Australia has now recorded seven confirmed (or presumed positive) cases of H5 bird flu in individual wild migratory seabirds.

Last updated: 10 July 2026

Western Australia has now recorded seven confirmed (or presumed positive) cases of H5 bird flu in individual wild migratory seabirds.

Testing at CSIRO’s Australian Centre for Disease Preparedness today confirmed the virus in the previously reported suspect positive dead petrel at Mullaloo Beach on the north Perth metropolitan coast.

Another dead petrel previously reported at Horrocks Beach near Northampton was classified as presumed positive with further testing unable to definitively determine H5 bird flu virus through viral sequencing.

It is considered highly likely this bird was infected with H5 bird flu based on the H5 test results, species involved, coastal location and the broader epidemiological picture.

WA is responding to both cases with heightened surveillance in the coastal areas.

Nationally, there have been 13 confirmed or presumed positive results of H5 bird flu in Australia.

This includes 12 wild migratory seabirds, and one confirmed detection announced today in a greater crested tern found near Robe in South Australia. This is the first confirmed detection in an Australian non-migratory seabird.

Importantly, at this time, there is no evidence of any large-scale deaths in wildlife, nor any evidence of infection in poultry or in our agricultural production system

The seven confirmed detections in WA are isolated occurrences and dispersed along a significant length of coastline from east of Esperance to Northampton.

Coastal communities are encouraged to report sick or dead wildlife to the Emergency Animal Disease (EAD) Hotline for assessment.

There has been more than 1400 wildlife-related reports from WA to the hotline since the first confirmed case on 19 June. Of these reports, 228 have been prioritised for further investigation.

To date, a total of 93 negative test results has been recorded across the State.

Each report is carefully reviewed and assessed based on factors such as the species involved, the number of animals affected, the location and the likelihood of disease risk.

Not every report will result in birds being tested or collected, but every report does help inform the understanding of the disease and what is happening in the environment.

People are reminded to avoid handing the animals, record their observations by photo or video and report to the EAD hotline on 1800 675 888.


Based on the previous report of July 6th, the number of wildlife hotline reports has increased by roughly 400 in the past 4 days, while the number of samples tested in WA have risen from 70 to roughly 100. 

Given that 7% of the first 100 tests from WA have come back positive, it is probably safe to say that we are only seeing the tip of the iceberg.

Stay tuned. 

Thursday, July 09, 2026

EFSA: An LPAI H9N2 Mystery



#19,240

A little over a week ago the EFSA published their quarterly avian flu review - which in addition to documenting the last 3 months of Europe's extraordinary 2025-2026 avian flu season - announced the surprise finding of an older, Middle-Eastern/African clade of LPAI H9N2 circulating in Hungary's poultry. 

Despite being clearly zoonotic - LPAI H9N2 is considered a `non-reportable' disease in poultry or wild birds by WOAH (see Terrestrial Animal Code). As a result, there are huge gaps in surveillance and reporting around the world. 

At the same time we've seen a growing number of studies - mostly out of Asia - warning of its growing adaptation to mammalian hosts (see EM&I: Enhanced Replication of a Contemporary Avian Influenza A H9N2 Virus in Human Respiratory Organoids).

Our own CDC lists two lineages (A(H9N2) G1 and A(H9N2) Y280) as having at least some pandemic potential, and several candidate vaccines have been developed.

In terms of risk of emergence, the H9N2
Y280 lineage is ranked higher than H5N1

While there is still much to be learned about them, over the past couple of months we've seen 2 new lineages of LPAI H9N2 described in the literature.

EM&I: A new clade of H9N2 avian influenza virus circulating in Laos

Preprint: Outbreak of H9N2 Avian Influenza Viruses in Lesser Rhea in Peru, June-July 2025

Where H9N2 is endemic (Asia, Africa, the Middle East) attempts at controlling the virus with vaccines have been largely unsuccessful (see J. Virus Erad.: Ineffective Control Of LPAI H9N2 By Inactivated Poultry Vaccines - China).

While most human cases have been reported out of China (see below), this year Europe saw its first (imported) human infection with H9N2 in Italy (see WHO DON: Avian Influenza A(H9N2) - Italy (Ex Senegal))

Reports of LPAI H9N2 in European poultry have been rare, but in this latest report the EFSA describes an outbreak in 7 premises in Hungary.

Apart from these HPAI A(H5N1) outbreaks, Hungary reported the detection of A(H9N2) clade G5.5 virus back in April in 7 establishments keeping chickens (broilers), all of which were located in a single geographical area within one settlement. Increased mortality in one establishment initially raised suspicions of HPAI, however, the birds tested negative for HPAI A(H5) and A(H7) viruses

Tests for infectious bronchitis virus returned positive and pathological examinations revealed tracheitis, presenting with a clinical picture typical of a co-infection (Belkasmi et al., 2020; Regragui et al., 2025). This prompted testing for A(H9N2) virus.

As this specific clade had originally been restricted to countries outside the EU, such as those in the Middle East (Fusaro et al., 2024), poultry workers were interviewed about their travel history; however, no plausible link could be established. 

The source of introduction therefore remained unknown at the time of reporting. All affected establishments were stamped out, cleaned, and disinfected. After 2-3 weeks following repopulation, the birds will be tested again for A(H9N2) virus. Waterfowl flocks present in the affected county were tested for A(H9) virus prior to movement, but all these tests returned negative. 

The report goes on to describe the LPAI H9N2 virus:

Low pathogenic avian influenza A(H9N2) clade G5.5 (CDC, online-a) was identified in two genetically characterised samples collected from commercial poultry establishments in Hungary in April 2026. This clade is circulating in domestic birds in some countries in Africa, the Middle East and West Asia, and has previously never been detected in birds in the EU/EEA. 

Avian influenza A(H9N2) viruses belonging to clade G5.5 have also been reported in sporadic human cases, including Oman and Senegal in 2019, Ghana in 2024, and Italy in March 2026 in a patient who returned from West Africa (Pariani et al., 2026). 

The viruses that are most closely related to the Hungarian strains are A(H9N2) viruses of the same clade that had been circulating in the Middle East one or two decades ago. The long branches and time separating the Hungarian viruses from their progenitors suggest a significant gap of data, making it impossible to determine their origin.

Similarly to the majority of the A(H9N2) viruses of lineages G and B, they possess the HA-Q226L mutation (H3 numbering), which is associated with preferential binding to human-like α2-6-linked sialic acid (SA α2-6) receptors. 


The only recent reports of Clade G5.5 appear to have come from Oman, Senegal, and Ghana, although we are hindered by a general lack of testing, surveillance and reporting.

How it ended up in Hungary - some 4,000km from these locations - is a genuine mystery.  While migratory birds, imported exotic birds, or even human carriage are possible, there is scant evidence to support any conclusion. 

LPAI H9N2 may not be our biggest pandemic threat, but it is far from benign. The fact that H9 has successfully flown under the radar - only to turn up unexpectedly in central Europe - suggests we may want to consider expanding our testing and reporting systems beyond H5 and H7 viruses.  

Wednesday, July 08, 2026

Viruses: First Ecuadorian Pediatric Case of Multisystem and Neurological Involvement Associated with Influenza A—H5N1 Virus—Case Report

 

#19,239

In January of 2023 Ecuador reported its first (and as far as we know, only) human infection with H5N1; in a 9-year-old girl with reported contact with backyard poultry. 

The initial report included no details on when she was infected, her symptoms, or her current condition.
 
But the following day PAHO published a report stating : The patient is currently hospitalized in a pediatric intensive care unit, in isolation and with antiviral and supportive treatment.

A week later the WHO published a far more detailed report which stated:

The case is a nine-year-old girl, with no known comorbidities, from Bolívar Province, Ecuador. She developed symptoms of conjunctival pruritus and coryza on 25 December 2022. On 27 December, she was brought to a local health center for medical evaluation and treatment. On 30 December, due to the persistent symptoms including nausea, vomiting and constipation, she was admitted to a general hospital where empirical treatment for meningitis was started with antibiotics and antipyretics. On 3 January 2023, she was transferred to a pediatric hospital in critical condition where she was admitted to the intensive care unit (ICU) with septic shock and was treated with antivirals and mechanical ventilation due to pneumonia.

 Eight months later a report appeared in Travel Medicine which stated:

The patient was a 9-year-old girl without co-morbidities from Bolivar Province, who was admitted to a hospital due to severe flu symptoms in 30 December 2022. She was transferred to the ICU of a paediatric hospital on 3 January 2023 due to complications with septic shock and pneumonia. She received complex support antiviral treatment, including oseltamivir, managing to improve her critical condition; She continued in interdisciplinary management with favorable progress and was finally discharged from the hospital.

I mention these prior reports because today we have a new case report - published in the journal Viruses - which paints a far different picture of this patient's course of illness; one which had much more neurological involvement than previously acknowledged. 

Other than a vague mention that `empirical treatment for meningitis was started' during hospitalization in the WHO report, there was little to suggest this case presented as anything other than severe flu symptoms & pneumonia leading to septic shock. 

 Whereas, today's report states:

The clinical course was characterized by an atypical initial presentation of bilateral periorbital edema and headache, progressing to acute encephalitis, cerebral ischemia, flaccid tetraplegia, central diabetes insipidus, and refractory septic shock. 

They also indicate that respiratory symptoms were minimal upon admission, instead citing `progressive neurological symptoms'which prompted urgent medical evaluation

Those early reports become problematic because clinicians require timely information on the full range of symptoms and/or presentation of novel flu infection, if they are to consider them in their differential.  

First, I've posted some brief excerpts from the case report, but the paper is very much worth reading in its entirety. After the break we'll look back at some other recent reports of severe neurological involvement from H5N1 infection. 

First Ecuadorian Pediatric Case of Multisystem and Neurological Involvement Associated with Influenza A—H5N1 Virus—Case Report
Frances Fuenmayor 1,*, Santiago Chávez 2, María de los Ángeles Costta 1, Mateo Carvajal 3, Denisse Benítez 3,Rommel Guevara 3, Erika Muñoz 3, Paúl Cárdenas 3,Marisol Carrillo 4 … Melanie Orellana 2
Viruses 2026, 18(7), 749;
https://doi.org/10.3390/v18070749


Abstract

Influenza A (H5N1) is a highly pathogenic zoonotic virus with a human fatality rate of approximately 60%. Pediatric cases and associated neurological manifestations remain poorly documented in Latin America. This report describes the first confirmed Ecuadorian pediatric case of H5N1-associated encephalitis and multisystem organ failure in a previously healthy 9-year-old female following direct contact with infected poultry.

The clinical course was characterized by an atypical initial presentation of bilateral periorbital edema and headache, progressing to acute encephalitis, cerebral ischemia, flaccid tetraplegia, central diabetes insipidus, and refractory septic shock.

Diagnostic confirmation was achieved via nasopharyngeal RT-PCR, with additional RT-PCR and sequencing performed on cerebrospinal fluid, which identified conserved influenza A M1/M2 gene fragments, while laboratory markers—including marked elevations in IL-6, ferritin, and CRP—indicated a severe hyperinflammatory state.

Management involved an intensive multidisciplinary approach utilizing oseltamivir, intravenous immunoglobulin, modulated-dose corticosteroids, desmopressin, and mechanical ventilation. Despite a severe clinical course, the patient achieved a favorable recovery, with a Glasgow Coma Scale score of 15/15 at discharge and only partial residual paresis and left hypoacusia as sequelae. This landmark case provides rare evidence of H5N1 neuroinvasion in a pediatric patient and demonstrates that timely detection combined with aggressive immunotherapy and antiviral treatment can improve survival.

Furthermore, it underscores the critical necessity for strengthened regional molecular surveillance and clinical training to recognize atypical presentations of emerging zoonoses in Latin America, especially in cases involving contact with sick poultry.

        (SNIP) 

(SNIP)

This case underscores the severity of multisystemic involvement in influenza A H5N1 in pediatric patients, as well as the importance of a structured follow-up protocol for managing neurological and metabolic sequelae. Our findings highlight the need for active surveillance in children exposed to avian-influenza risk factors and for protocols covering early identification, continuous monitoring, and rehabilitation after resolution of the acute illness. Given the magnitude of these clinical implications, primary prevention through zoonotic control remains a fundamental pillar for reducing the incidence of new cases.

(Continue . . . )

Although the `classic' presentation of H5N1 infection has been severe flu symptoms and fever leading to pneumonia, we've seen a number of atypical presentations over the years.   

Many recent cases - particularly from genotype B3.13 - have been mild, often with conjunctivitis and minor respiratory symptoms.  Some are even asymptomatic.  

But avian H5N1 also has a history of causing severe neurological manifestations both in humans, and in other avian and mammalian hosts.

Since 2022 we've seen a steady stream of reports of spillover of avian H5N1 into mammalian hosts, with many exhibiting severe (often fatal) neurological manifestations. A few of many recent blogs include:




While severe neurological involvement from human H5Nx infection remains relatively rare:

In 2022 (see Clinical Features of the First Critical Case of Acute Encephalitis Caused by Avian Influenza A (H5N6) Virus), we reviewed the first known case of neuroinfluenza in an H5N6 patient; a 6-year-old girl who was admitted to a hospital with mild pneumonia - but severe encephalitis - in January of that year.

That was followed 15 months ago (April 2025) by a preliminary report on a neuroinvasive infection in an 8-y.o. girl (see Vietnam: Ho Chi Minh DOH Reports A Rare H5N1 Encephalitis Case In a Child), which reported:

As noted by infectious experts, this is a rare case in which the A/H5N1 avian influenza virus damages the central nervous system and does not attack the respiratory tract.

We followed up on that case last May in OFID: Central Nervous System Involvement by Novel Clade 2.3.2.1e H5N1 Avian Influenza Virus in a Paediatric Patient, where the authors warned:

Testing for IAV and  A(H5N1) virus should be considered in patients presenting with CNS infection with a history of exposure (e.g. dead poultry). Clinicians should be aware of meningoencephalitis associated with A(H5N1) infection in the absence of respiratory symptoms.

A reminder that while it can sometimes be mild, H5N1 isn't your father's influenza. 

Tuesday, July 07, 2026

J. Virology: Receptor profiling and growth assessment of influenza A virus in porcine mammary and non-mammary tissues and derived cells

 


#19,238

Until 28 months ago conventional wisdom held that cattle, sheep, goats and other mammalian livestock were not susceptible to HPAI H5Nx infection (see A Brief History Of Influenza A In Cattle/Ruminants). 

Isolated spillovers weren't impossible, but had never been confirmed outside of the lab, and thought highly unlikely.

All that changed abruptly in the spring of 2024 when we saw goats die from H5N1 in Minnesota, followed by a multi-state outbreak of H5N1 in dairy cattle. Since then more than 1,150 U.S. cattle herds in 20 states have been affected, and we've seen sporadic reports from the UK, Europe, and Asia

At first, the assumption was that only the B3.13 `Bovine' genotype of H5N1 could infect cattle, but in early 2025 genotype D1.1 was discovered in dairy cows in 3 states, and the European and Asia spillovers were from different genotypes as well. 

While we've seen evidence that cattle and other ruminants could serve as mixing vessels for avian influenza, the bigger concern has always been HPAI spillovers into pigs, which have a history of generating pandemic viruses. 

Although detections in swine have been limited, we've seen scattered evidence that H5N1 can infect pigs, albeit often asymptomatically. A few past reports include:
In May of 2023, in Netherlands: Zoonoses Experts Council (DB-Z) Risk Assessment & Warning of Swine As `Mixing Vessels' For Avian Flu, we looked at growing concerns in Europe that avian H5N1 could increase its pandemic threat by spreading (and evolving) in farmed swine.

Followed only days later by a report out of Italy confirming an H5N1 spillover event at a `mixed species' farm (poultry & swine), and the subsequent seroconversion of the majority of the pigs tested on that farm (see Study: Seroconversion of a Swine Herd in a Free-Range Rural Multi-Species Farm against HPAI H5N1 2.3.4.4b Clade Virus).

In late 2024, we saw two pigs infected with a new, recently emerged genotype (D1.2) in Oregon (see USDA Confirms 2nd Pig on Oregon Farm Tested Positive for H5N1).

And last fall, in Transboundary & Emerg Inf: Serological Evidence of HPAI (H5N1) in Invasive Wild Pigs in Western Canada, we looked at a study which found (limited) serological evidence of HPAI H5 infection in wild pigs in western Canada.

While the number of wild pigs in Canada is a matter of some debate, in the United States, estimates run in 6-9 million range, mostly clustered  across the Southern tier of states (see APHIS Map below).

Whether commercial or wild, swine are considered problematic when it comes to the spread and evolution of novel flu viruses. But how well adapted `bovine' strains of HPAI H5 might be to pigs is unknown. 

The lack of reports of HPAI H5 in pigs is comforting, but surveillance and testing for the virus in the United States is quite limited.

According to the USDA, as of Sept.1, 2025 there were 74.5 million hogs and pigs on U.S. farms, and according to their last published Influenza A Virus in Swine Surveillance report (Q4), in they tested 977 samples in 2025.

The USDA further notes:

Due to the voluntary nature of this surveillance, the information in this report cannot be used to determine regional and/or national incidence, prevalence, or other epidemiological measures, but it may help identify IAV-S trends.
The $64 question remains; are pigs - like cattle - more susceptible the newer HPAI viruses currently circulating in the United States? 

While it doesn't completely answer the question, today's study tested the infectivity and replication of 4 different influenza viruses (Bovine H5N1, LPAI H5N1, Swine H1N2, and Human H1N1) across an array of porcine cell lines (primary nasal turbinate, trachea, lung and mammary gland epithelial cells).

They report that porcine mammary epithelial cells contain both SA-α2,3 avian‑type  and SA-α2,6 human‑type receptor cells and can support replication of bovine H5N1 B3.13 to relatively high titers, suggesting lactating pigs are a plausible host for this genotype.

The caveat being, this study was done in vitro using tissues and cells from a  single porcine donor, tested against a limited array of (4) viruses. While it shows that pig udder cells can be infected, it's a long way from proving that infections are common in the field. 

That said, these results suggest that - given what we've already seen with cattle - we might be better served by escalating the surveillance and testing of swine - and increasing biosecurity on pig farms - before it becomes a bigger issue. 

Due to its length and technical details, I've only posted the abstract and a few excerpts.  Follow the link to read it in its entirety.

Receptor profiling and growth assessment of influenza A virus in porcine mammary and non-mammary tissues and derived cells
Ulises Barron-Castillo , Nathalie Berube1, Cynthia L. Swan1, M. Afzal Javed1, Lauren Aubrey1, Jill Trann1,2, Makenzie Gidych1, Sauhard Shrivastava1,2, Kaushal Baid1, Arinjay Banerjee ,2, Yan Zhou 
Received 17 April 2026 Accepted 8 June 2026 Published 6 July 2026
Address correspondence to Yan Zhou, yan.zhou@usask.ca.
Copyright © 2026 Barron-Castillo et al. This is an open-access article distributed under the terms of the Creative Commons Attribution 4.0 International license.
 
Highly pathogenic avian influenza (HPAI) virus clade 2.3.4.4b genotype B3.13 infected the mammary gland of dairy cattle; the new tissue tropism and host heightened concern about its ability to cross species barriers with zoonotic potential. Pigs play a key role in influenza A virus (IAV) adaptation, serving as a “mixing vessel” for the emergence of reassortants. The susceptibility of porcine mammary gland to HPAI infection remains unexplored.
In this study, we profiled IAV receptors in porcine mammary gland as well as respiratory tract tissues. Additionally, we evaluated the binding capacity of IAVs to these tissues. Furthermore, we isolated primary cells from porcine mammary gland and respiratory tract, and immortalized them. We examined the growth potential of IAV isolates from bovine, avian, swine, and human on these cells.
We showed that porcine mammary gland displays both SA-α2,3 and SA-α2,6, and that IAVs bind to mammary gland tissues with variable affinities. While bovine H5N1 virus replicates efficiently in mammary gland and respiratory tract cells, replication of other IAVs in mammary epithelial cells is moderate but is efficient in respiratory cells.
These findings suggest that porcine mammary gland could support the infection by HPAI 2.3.4.4b genotype B3.13.
(SNIP)
Pigs are known as mixing vessels for IAVs due to the presence of both SA-α2,3 and SA-α2,6 receptors in their respiratory tract, allowing co-infection by avian, human, and swine IAV strains (13, 14). The expression of both receptors facilitates viral reassortment, enabling the emergence of novel viruses with pandemic potential, such as the 2009 H1N1, a quadruple-reassortant strain (15).
Given the recent evidence of HPAI H5N1 replication in bovine mammary gland tissue, it is important to assess whether the porcine mammary gland could similarly support influenza viral infection. This will provide insights into whether it serves as a potential site for viral adaptation and reassortment. Meanwhile, it is also equally important to assess the potential replication of bovine H5N1 in porcine respiratory tract in comparison to other IAV strains.
Here, we characterized IAV receptors on porcine mammary gland and respiratory tract tissues. Additionally, we tested the binding capacity of IAV to these tissues. Furthermore, we isolated primary cells from both porcine mammary gland and respiratory tract tissues and immortalized them. The growth potential of a panel of IAV isolates from bovine, swine, human, and avian sources was examined in these cells.
We report that porcine mammary gland expresses both SA-α2,3 and SA-α2,6 receptors, and IAVs bind to mammary gland tissues with variable levels. HPAI H5N1 bovine isolate replicates efficiently in epithelial cells derived from the mammary gland and respiratory tract. In contrast, non-HPAI isolates exhibited moderate replication in mammary gland cells but efficient replication in respiratory tract cells. These findings suggest that porcine mammary gland tissues could support infection by HPAI H5N1 clade 2.3.4.4b genotype B3.13. 

        (Continue . . . )

 

Monday, July 06, 2026

PNAS (Referral): Genomic and structural evidence of SARS-CoV-2 and MERS-CoV in migratory birds

 
Tundra Swans Flyovers, Craig Strobeck, Public Domain,
https://www.fws.gov/media/tundra-swans-flyovers

#19,237

We've a surprising report to look at this morning in PNAS (most of which is behind a paywall) which describes the first detection of Betacoronaviruses (COVID & MERS-COV) in migratory birds in China. 

Coronaviruses are divided into 4 distinct genera: 
  • Alphacoronaviruses
  • Betacoronaviruses (i.e. SARS-CoV, MERS-CoV, etc.)
  • Gammacoronaviruses
  • and Deltacoronaviruses 
Alphacoronaviruses & Betacoronaviruses primarily infect mammals, while birds are mostly affected by Gammacoronaviruses, such as infectious bronchitis virus (AIBV) and occasionally by Deltacoronaviruses.

We've seen a few crossovers - particularly with Deltacoronaviruses - which have been detected mostly in birds and but occasionally in mammals (see Discovery of seven novel Mammalian and avian coronaviruses in the genus deltacoronavirus . . . . ). 

Numerous studies have tried (and failed) to infect birds with Betacoronaviruses, including: 

All of which has led researchers to long assume that birds aren't susceptible to either SARS-CoV-2 or MERS-CoV.  But today's report calls that into question.

In brief, George F. Gao et al. report finding:
  • Three nearly full‑length SARS‑CoV‑2 genomes (2 Beta-like & 1 Gamma-like VOCs) in the feces of Tundra Swans collected in Jiangxi Province in 2021.
  • They also report a ~70% complete MERS‑CoV genome was recovered from a Bar‑headed goose in Tibet in 2022. 
  • While the original Wuhan Strain of SARS-COV-2 was unable to infect Swans (via tsACE2 receptors), some later variants appear to have acquired the ability to do so
Since I don't have access to the full report, I'll simply refer my readers to the link and abstract below.  I'll have a brief postscript after the break. 

Genomic and structural evidence of SARS-CoV-2 and MERS-CoV in migratory birds

Jian Cao, Sheng Liu, Chao Su, +4 , and George F. Gao gaof@im.ac.cn
Contributed by George F. Gao; received January 10, 2024; accepted May 15, 2026; reviewed by Jie Cui, Yi Guan, and Lin-Fa Wang
June 29, 2026 123 (27) e2400023123
https://doi.org/10.1073/pnas.2400023123

Copyright © 2026 the Author(s). Published by PNAS. This article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).

Abstract

Migratory birds are the natural reservoir of influenza A virus (IAV), but their role as a carrier of SARS-CoV-2 remains unclear. Here, we report the identification of three almost full-length viral genome sequences of SARS-CoV-2 variants of concern (VOCs) in Tundra swans.

These sequences are named hCoV-19/Tundra swan/Jiangxi/IMCAS_M1/2021 (IMCAS_M1), hCoV-19/Tundra swan/Jiangxi /IMCAS_M2/2021 (IMCAS_M2), and hCoV-19/Tundra swan/Jiangxi/IMCAS_M3/2021 (IMCAS_M3). IMCAS_M1 and IMCAS_M3 have the same mutations as the Beta VOC (K417N, E484K, and N501Y) in the receptor-binding domain (RBD) of the viral spike (S) protein, whereas IMCAS_M2 shares the same mutations as the Gamma VOC (K417T, E484K, and N501Y) in the RBD with all three showing their distinct mutations in the genomes.

Virus receptor angiotensin-converting enzyme 2 (ACE2) proteins from both Tundra swan (tsACE2) and Black swan (bsACE2) can bind to the RBDs of all three viruses and the Alpha VOC, but not to RBD of the prototype (PT) virus. The polar contacts and hydrophobic interactions revealed by cryo-electron microscopy (cryo-EM) structures of the RBD–ACE2 complex, play key roles in virus–receptor engagement.

Furthermore, HeLa cells expressing bsACE2 and tsACE2 proteins could be transduced by pseudotyped SARS-CoV-2 variants (Alpha, Beta, and Gamma) but not PT SARS-CoV-2.

In addition, we obtained one partial genome of MERS-CoV named Bar-headed goose/Tibet/IMCAS_M4/2022 (IMCAS_M4) with 20,180 bp (~70.0% coverage). Our findings highlight the importance of migratory birds as potential carrier of both SARS-CoV-2 and MERS-CoV, thereby posing potential threat to public health.

For years, the role of migratory birds in the spread of avian flu was bitterly contested, with many scientists insisting that birds were simply incapable of flying long distances while carrying the H5 virus (see 2011's Study: The Role Of Migratory Birds In Spreading Bird Flu).

Despite abundant evidence, it wasn't until the second half of the last decade that the role of migratory birds in spreading avian flu was generally accepted (see Migratory Birds & The Spread Of Highly Pathogenic Avian Flu).

While it isn't clear how important migratory birds might be in the spread of Betacoronaviruses, this study suggests we can no longer ignore their potential as carriers of SARS-CoV-2, MERS-CoV, and possibly other coronaviruses. 

A humbling reminder that anything we say with relative certainty about avian flu, novel coronaviruses - or any other infectious disease - today, is subject to future revision as these pathogens evolve and our knowledge base expands.