Infectivity and transmissibility of an avian H3N1 influenza virus in pigs

Molecular and ecological determinants of mammalian adaptability in avian influenza virus

The avian influenza virus (AIV) primarily affects birds and poses an increasing concern due to its growing adaptability to other hosts, heightening zoonotic risks. The adaptability is a key factor in AIV to infect multiple non-avian species, including humans, companion animals, aquatic mammals, carnivores, and other mammals. The virus is evolving through genetic mutations and reassortments, leading to the emergence of AIV strains with enhanced virulence and adaptability in mammals. This highlights the critical need to understand the genetic factors of AIV, including mutations in polymerase proteins, surface antigens, and other regulatory proteins, as well as the dynamics of AIV-host interactions and environmental factors such as temperature, humidity, water salinity, and pH that govern the cross-species adaptability of the virus. This review provides comprehensive insights into the molecular/genetic changes AIV undergoes to adapt in mammalian hosts including bovines, swine, equines, canines, and felines. The adaptive mutations in viral polymerase proteins, such as PB2-E627K, and receptor specificity shift facilitate the virus adaptability in mammals. Since AIVs interact with specific receptors on host cells, therefore the type and distribution of receptors are crucial in determining the host range of the virus and its adaptability by facilitating attachment and entry of the virus. This review examines sialic acid receptor distribution and binding patterns in various mammalian hosts, emphasizing how the presence and structure of specific receptors influence viral interaction, adaptation, and transmission. The review concludes that the differential distribution and expression of SA receptors are vital in the mammalian adaptability and tissue tropism of viral strains. Notably, during the adaptation to mammals, AIVs show a shift in preference from α-2,3 to α-2,6 receptors. This review further emphasizes the role of ecological determinants in the adaptation of viruses to mammalian hosts. Low temperatures, high humidity, and neutral to slightly acidic pH levels enhance virus stability, facilitating its persistence in the environment and spread among susceptible hosts. Overall, AIV remains a global health threat, necessitating coordinated efforts in research, surveillance, and public health strategies.

Early-warning signals and the role of H9N2 in the spillover of avian influenza viruses

BACKGROUND

The spillover of avian influenza viruses (AIVs) presents a significant global public health threat, leading to unpredictable and recurring pandemics. Current pandemic assessment tools suffer from deficiencies in terms of timeliness, capability for automation, and ability to generate risk estimates for multiple subtypes in the absence of documented human cases.

METHODS

To address these challenges, we created an integrated database encompassing global AIV-related data from 1981 to 2022. This database enabled us to estimate the rapid expansion of spatial range and host diversity for specific AIV subtypes, alongside their increasing prevalence in hosts that have close contact with humans. These factors were used as early-warning signals for potential AIV spillover. We analyzed spillover patterns of AIVs using machine learning models, spatial Durbin models, and phylogenetic analysis.

FINDINGS

Our results indicate a high potential for future spillover by subtypes H3N1, H4N6, H5N2, H5N3, H6N2, and H11N9. Additionally, we identified a significant risk for re-emergence by subtypes H5N1, H5N6, H5N8, and H9N2. Furthermore, our analysis highlighted 12 key strains of H9N2 as internal genetic donors for human adaptation in AIVs, demonstrating the crucial role of H9N2 in facilitating AIV spillover.

CONCLUSIONS

These findings provide a foundation for rapidly identifying high-risk subtypes, thus optimizing resource allocation in vaccine manufacture. They also underscore the potential significance of reducing the prevalence of H9N2 as a complementary strategy to mitigate chances of AIV spillovers.

FUNDING

National Key Research and Development Program of China.

A systematic review of influenza virus in water environments across human, poultry, and wild bird habitats

Influenza, a highly contagious acute respiratory disease, remains a major global health concern. This study aimed to comprehensively assess the prevalence of influenza virus in different aquatic environments. Using 43 articles from four databases, we thoroughly examined water matrices from wastewater treatment plants (WTPs) and other human environments, as well as poultry habitats and areas frequented by migratory wild birds. In WTP influents (10 studies), positivity rates for influenza A ranged from 0.0 % to 97.6 %. For influenza B (8 studies), most studies reported no positivity, except for three studies reporting detection in 0.8 %, 5.6 %, and 46.9 % of samples. Within poultry habitats (13 studies), the prevalence of influenza A ranged from 4.3 % to 76.4 %, while in environments frequented by migratory wild birds (11 studies), it ranged from 0.4 % to 69.8 %. Geographically, the studies were distributed as follows: 39.5 % from the Americas, 18.6 % from Europe, 2.3 % from South-East Asia and 39.5 % from the Western Pacific. Several influenza A subtypes were found in water matrices, including avian influenza (H3N6, H3N8, H4N1, H4N2, H4N6, H4N8, H5N1, H5N8, H6N2, H6N6, H7N9, H0N8, and H11N9) and seasonal human influenza (H1N1 and H3N2). The existing literature indicates a crucial requirement for more extensive future research on this topic. Specifically, it emphasizes the need for method harmonization and delves into areas deserving of in-depth research, such as water matrices pertaining to pig farming and prevalence studies in low-income countries.