New insights on how avian flu crosses the species barrier
A new publication sheds light on how a key avian influenza virus enzyme can mutate to allow the virus to replicate in mammals.
In recent years, public health measures, surveillance, and vaccination have helped bring about significant progress in reducing the impact of seasonal flu epidemics, caused by human influenza viruses A and B. However, a possible outbreak of avian influenza A (commonly known as “avian flu”) in mammals, including humans, poses a significant threat to public health.
The Cusack group at EMBL Grenoble studies the replication process of influenza viruses. A new study from this group sheds light on the different mutations that the avian influenza virus can undergo to be able to replicate in mammalian cells.
Some avian influenza strains can cause severe disease and mortality. Fortunately, significant biological differences between birds and mammals normally prevent avian influenza from spreading from birds to other species. To infect mammals, the avian influenza virus must mutate to overcome two main barriers: the ability to enter the cell and to replicate within that cell. To cause an epidemic or pandemic, it must also acquire the ability to be transmitted between humans.
However, sporadic contamination of wild and domestic mammals by avian flu is becoming increasingly common. Of particular concern is the recent unexpected infection of dairy cows in the U.S. by an avian H5N1 strain, which risks becoming endemic in cattle. This might facilitate adaptation to humans, and indeed, a few cases of transmission to humans have been reported, so far resulting in only mild symptoms.
At the heart of this process is the polymerase, an enzyme that orchestrates the virus’s replication inside host cells. This flexible protein can rearrange itself according to the different functions it performs during infection. These include transcription – copying the viral RNA into messenger RNA to make viral proteins – and replication – making copies of the viral RNA to package into new viruses.
Viral replication is a complex process to study because it involves two viral polymerases and a host cell protein – ANP32. Together, these three proteins form the replication complex, a molecular machine that carries out replication. ANP32 is known as a “chaperone,” meaning that it acts as a stabilizer for certain cellular proteins. It can do this thanks to a key structure – its long acidic tail. In 2015, it was discovered that ANP32 is critical for influenza virus replication, but its function was not fully understood.
The results of the new study, published in the journal Nature Communications, show that ANP32 acts as a bridge between the two viral polymerases – called replicase and encapsidase.
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