A Dual Motif in the Hemagglutinin of H5N1 Goose/Guangdong-Like Highly Pathogenic Avian Influenza Virus Strains Is Conserved from Their Early Evolution and Increases both Membrane Fusion pH and Virulence

Wessels, Ute; Mostafa, Ahmed; Veits, Jutta; Hoffmann, Donata; Mamerow, Svenja; Stech, Olga; Hellert, Jan; Beer, Martin; Mettenleiter, Thomas C.; Stech, Jürgen

doi:10.1128/jvi.00778-18

Cited by 12 publications

(5 citation statements)

References 86 publications

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“…Both A(H5N1) sequences were assigned to clade 2.3.2.1c and carried the previously detected HA amino acid substitutions T108I (H5 numbering, the combination S107R-T108I has been associated with increased virulence in chickens and mice and increased pH of fusion) (Wessels et al, 2018), S133A (increased pseudovirus binding to α2-6 human-type receptors) (Yang et al, 2007) and S155N (associated with increased virus binding to α2-6 human-type receptors) (Wang et al, 2010), of which the latter is present in most viruses of this clade. Furthermore, they also carried D94N (associated with increased virus binding to α2-6) (Su et al, 2008), and one (A/Cambodia/i0125001G/2024, EPI_ISL_18823967) had N154D (associated with decreased virulence in mice) (Jin et al, 2019).…”

Section: A(h5n1)mentioning

confidence: 87%

Avian influenza overview December 2023–March 2024

Fusaro,

Gonzales,

Kuiken

et al. 2024

EFS2

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Between 2 December 2023 and 15 March 2024, highly pathogenic avian influenza (HPAI) A(H5) outbreaks were reported in domestic (227) and wild (414) birds across 26 countries in Europe. Compared to previous years, although still widespread, the overall number of HPAI virus detections in birds was significantly lower, among other reasons, possibly due to some level of flock immunity in previously affected wild bird species, resulting in reduced contamination of the environment, and a different composition of circulating A(H5N1) genotypes. Most HPAI outbreaks reported in poultry were primary outbreaks following the introduction of the virus by wild birds. Outside Europe, the majority of outbreaks in poultry were still clustered in North America, while the spread of A(H5) to more naïve wild bird populations on mainland Antarctica is of particular concern. For mammals, A(H5N5) was reported for the first time in Europe, while goat kids in the United States of America represented the first natural A(H5N1) infection in ruminants. Since the last report and as of 12 March 2024, five human avian influenza A(H5N1) infections, including one death, three of which were clade 2.3.2.1c viruses, have been reported by Cambodia. China has reported two human infections, including one fatal case, with avian influenza A(H5N6), four human infections with avian influenza A(H9N2) and one fatal case with co-infection of seasonal influenza A(H3N2) and avian influenza A(H10N5). The latter case was the first documented human infection with avian influenza A(H10N5). Human infections with avian influenza remain rare and no sustained human-to-human infection has been observed. The risk of infection with currently circulating avian H5 influenza viruses of clade 2.3.4.4b in Europe remains low for the general population in the EU/EEA. The risk of infection remains low to moderate for those occupationally or otherwise exposed to infected animals.

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Section: A(h5n1)mentioning

confidence: 87%

Avian influenza overview December 2023–March 2024

Fusaro,

Gonzales,

Kuiken

et al. 2024

EFS2

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“…The mutation analysis of the HA segment for the eight A(H5Nx) sequences revealed a previously reported profile (EFSA, ECDC and EURL, 2024) in which seven out of eight carried both T108I, which in combination with S107R has been associated with increased virulence in chickens and mice, and increased pH of fusion (Wessels et al, 2018), and S133A, which is linked to increased pseudovirus binding to α2-6 human-type receptors (Yang et al, 2007). Furthermore, all the A(H5Nx) viruses had a deletion at position 328 (a polybasic cleavage motif), which is seen in the vast majority of clade 2.3.2.1c, compared to A/Goose/Guangdong/1/96.…”

Section: Hpai A(h5nx)mentioning

confidence: 62%

Avian influenza overview March–June 2024

Alexakis,

Fusaro,

Kuiken

et al. 2024

EFS2

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Between 16 March and 14 June 2024, 42 highly pathogenic avian influenza (HPAI) A(H5) virus detections were reported in domestic (15) and wild (27) birds across 13 countries in Europe. Although the overall number of detections in Europe has not been this low since the 2019–2020 epidemiological year, HPAI viruses continue to circulate at a very low level. Most detections in poultry were due to indirect contact with wild birds, but there was also secondary spread. Outside Europe, the HPAI situation intensified particularly in the USA, where a new A(H5N1) virus genotype (B3.13) has been identified in >130 dairy herds in 12 states. Infection in cattle appears to be centred on the udder, with milk from infected animals showing high viral loads and representing a new vehicle of transmission. Apart from cattle, HPAI viruses were identified in two other mammal species (alpaca and walrus) for the first time. Between 13 March and 20 June 2024, 14 new human cases with avian influenza virus infection were reported from Vietnam (one A(H5N1), one A(H9N2)), Australia (with travel history to India, one A(H5N1)), USA (three A(H5N1)), China (two A(H5N6), three A(H9N2), one A(H10N3)), India (one A(H9N2)), and Mexico (one fatal A(H5N2) case). The latter case was the first laboratory‐confirmed human infection with avian influenza virus subtype A(H5N2). Most of the human cases had reported exposure to poultry, live poultry markets, or dairy cattle prior to avian influenza virus detection or onset of illness. Human infections with avian influenza viruses remain rare and no human‐to‐human transmission has been observed. The risk of infection with currently circulating avian A(H5) influenza viruses of clade 2.3.4.4b in Europe remains low for the general public in the EU/EEA. The risk of infection remains low‐to‐moderate for those occupationally or otherwise exposed to infected animals or contaminated environments.

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“…Bioinformatics analysis identified many mutations that would increase virulence in mice, such as R114 and I115 (H3 numbering) of the HA gene (Wessels et al, 2018); D30, M43, and A215 of the M1 gene (Fan et al, 2009;Nao et al, 2015); S42, E55, E66 (SX1/2020, Y173/2020, and Y175/2020), M106, and F138 (except SX1/2020, Y173/2020, and Y175/2020) of the NS1 gene (Jiao et al, 2008;Ayllon et al, 2014;Li et al, 2018); the NS1 C-terminal ESEV motif of the PDZ domain at position aa227-230 (Jackson et al, 2008;Soubies et al, 2010;Zielecki et al, 2010); combination of V89, D309, K339, G477, V495, E627, and T676 of the PB2 gene (Li et al, 2009); V3 (except NQ1/2021) and G622 of the PB1 gene (Feng et al, 2016;Elgendy et al, 2017); and D383 of the PA gene (Song et al, 2015;Suttie et al, 2019).…”

Section: Molecular and Phylogenetic Analysismentioning

confidence: 99%

Comparative Antigenicity and Pathogenicity of Two Distinct Genotypes of Highly Pathogenic Avian Influenza Viruses (H5N8) From Wild Birds in China, 2020–2021

et al. 2022

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To date, there have been three epidemic waves of H5N8 avian influenza worldwide. The current third epidemic wave began in October 2020 and has expanded to at least 46 countries. Active and passive surveillance were conducted to monitor H5N8 viruses from wild birds in China. Genetic analysis of 10 H5N8 viruses isolated from wild birds identified two different genotypes. Animal challenge experiments indicated that the H5N8 isolates are highly pathogenic in chickens, mildly pathogenic in ducks, while pathogenicity varied in BALB/c mice. Moreover, there were significant differences in antigenicity as compared to Re-11 vaccine strain and vaccinated chickens were not completely protected against challenge with the high dose of H5N8 virus. With the use of the new matched vaccine and increased poultry immune density, surveillance should be intensified to monitor the emergence of mutant strains and potential worldwide spread via wild birds.

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A Dual Motif in the Hemagglutinin of H5N1 Goose/Guangdong-Like Highly Pathogenic Avian Influenza Virus Strains Is Conserved from Their Early Evolution and Increases both Membrane Fusion pH and Virulence

Cited by 12 publications

References 86 publications

Avian influenza overview December 2023–March 2024

Avian influenza overview December 2023–March 2024

Avian influenza overview March–June 2024

Comparative Antigenicity and Pathogenicity of Two Distinct Genotypes of Highly Pathogenic Avian Influenza Viruses (H5N8) From Wild Birds in China, 2020–2021

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