Serological evidence of antibodies to Flaviviridae in wild birds in Portugal

Filipa Loureiro, Luís Cardoso, Ana C. Matos, Cristina Pintado, Filipe Silva, Mariana Ferreira, Ricardo Brandão, Carolina Lopes, Ana Patrícia Lopes, João Rodrigo Mesquita, Manuela Matos, Ana Cláudia Coelho

Animal Diseases ›› 2024, Vol. 4 ›› Issue (1) : 35.

Animal Diseases ›› 2024, Vol. 4 ›› Issue (1) : 35. DOI: 10.1186/s44149-024-00136-9
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Serological evidence of antibodies to Flaviviridae in wild birds in Portugal

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Emerging infectious diseases are a major threat to biodiversity and an important public health issue. Flaviviruses are the cause of several emerging vector-borne zoonotic arboviruses whose distribution is currently increasing in Europe. The evidence that West Nile virus (WNV) circulates in resident and migratory species has implications for both animal and public health and should therefore be studied in depth. USUTU (USUV), Bagaza (BAGV) and tick-borne encephalitis virus (TBEV) are other viruses that are beginning to spread more widely. An integrated surveillance program, namely in birds, is essential for reducing the risk of infection in human populations within the One Health principles. In the present study, wild birds admitted to wildlife rehabilitation centers in Portugal were sampled. Two hundred eight blood samples were assayed serologically for antibodies to flaviviruses by using a commercial ELISA kit. An overall seroprevalence of 19.6% (95% confidence interval [CI]: 13.7–26.7%) was observed. Antibodies against flaviviruses were detected in 13 (35.1%) different species of wild birds. Accipitriformes (26.7%; 95% CI: 18.5–36.2%) and Strigiformes (26.7%; 95% CI: 14.6–42.0%) were the orders with the highest seroprevalence rates recorded. There were no statistically significant differences (p = 0.725) between the geographical regions (NUTS II) studied, but a statistically significant difference (p = 0.017) was found between sex (male: 34.4%; female: 4.8%). A higher seroprevalence was detected in adults (32.1%) than in juvenile birds (9.3%) (p = 0.014), and age was considered a risk factor for flavivirus infection in wild birds (odds ratio 1.4; 95% CI: 0.5–4.0). More epidemiological studies are needed in Portugal since the actual spread of the genus Flavivirus throughout the country is unknown.

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Filipa Loureiro, Luís Cardoso, Ana C. Matos, Cristina Pintado, Filipe Silva, Mariana Ferreira, Ricardo Brandão, Carolina Lopes, Ana Patrícia Lopes, João Rodrigo Mesquita, Manuela Matos, Ana Cláudia Coelho. Serological evidence of antibodies to Flaviviridae in wild birds in Portugal. Animal Diseases, 2024, 4(1): 35 https://doi.org/10.1186/s44149-024-00136-9

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[]
AgueroM, Fernandez-PineroJ, BuitragoD, SanchezA, ElizaldeM, San MiguelE, VillalbaR, LlorenteF, Jimenez-ClaveroMA. Bagaza virus in partridges and pheasants, Spain, 2010. Emerging Infectious Diseases, 2011, 17(8): 1498-1501
CrossRef Google scholar
[]
AlbaA, AllepuzA, NappS, SolerM, SelgaI, ArandaC, CasalJ, PagesN, HayesEB, BusquetsN. Ecological surveillance for West Nile in Catalonia (Spain), learning from a five-year period of follow-up. Zoonoses and Public Health, 2014, 61(3): 181-191
CrossRef Google scholar
[]
AngeloniG, BertolaM, LazzaroE, MoriniM, MasiG, SinigagliaA, TrevisanM, GossnerCM, HaussigJM, BakonyiT, CapelliG, BarzonL. Epidemiology, surveillance and diagnosis of Usutu virus infection in the EU/EEA, 2012 to 2021. Euro Surveillance, 2023, 28(33): 2200929
CrossRef Google scholar
[]
BarrosSC, RamosF, FagulhaT, DuarteM, HenriquesM, LuísT, FevereiroM. Serological evidence of West Nile virus circulation in Portugal. Veterinary Microbiology, 2011, 152(3–4): 407-410
CrossRef Google scholar
[]
BeckC, Jimenez-ClaveroMA, LeblondA, DurandB, NowotnyN, Leparc-GoffartI, ZientaraS, JourdainE, LecollinetS. Flaviviruses in Europe: Complex circulation patterns and their consequences for the diagnosis and control of West Nile disease. International Journal of Environmental Research Public Health, 2013, 10(11): 6049-6083
CrossRef Google scholar
[]
Beck, C., S. Lowenski, B. Durand, C. Bahuon, S. Zientara, and S. Lecollinet. 2017. Improved reliability of serological tools for the diagnosis of West Nile fever in horses within Europe. PLoS Neglected Tropical Diseases 11 (9): e0005936. https://doi.org/10.1371/journal.pntd.0005936.
[]
BergmannF, FischerD, FischerL, MaischH, RischT, DreyerS, SadeghiB, GeelhaarD, GrundL, MerzS, GroschupMH, ZieglerU. Vaccination of zoo birds against West Nile virus - a field study. Vaccines (Basel), 2023, 11(3): 652
CrossRef Google scholar
[]
Birdlife International. 2015. European red list of birds. Luxembourg: Office for Official Publications of the European Communities. https://doi.org/10.2779/975810.
[]
Bravo-BarrigaD, Aguilera-SepúlvedaP, Guerrero-CarvajalF, LlorenteF, ReinaD, Pérez-MartínJE, Jiménez-ClaveroMA, FronteraE. West Nile and Usutu virus infections in wild birds admitted to rehabilitation centers in Extremadura, western Spain, 2017–2019. Veterinary Microbiology, 2021, 255: 109020
CrossRef Google scholar
[]
BuschMP, KleinmanSH, ToblerLH, KamelHT, NorrisPJ, WalshI, MatudJL, PrinceHE, LanciottiRS, WrightDJ, LinnenJM, CagliotiAS. Virus and antibody dynamics in acute West Nile virus infection. Journal of Infectious Diseases, 2008, 198(7): 984-993
CrossRef Google scholar
[]
CalisherCH, KarabatsosN, DalrympleJM, ShopeRE, PorterfieldJS, WestawayEG, BrandtWE. Antigenic relationships between flaviviruses as determined by cross-neutralization tests with polyclonal antisera. Journal of General Virology, 1989, 70(Pt 1): 37-43
CrossRef Google scholar
[]
Casades-MartíL, Cuadrado-MatíasR, Peralbo-MorenoA, Baz-FloresS, FierroY, Ruiz-FonsF. Insights into the spatiotemporal dynamics of West Nile virus transmission in emerging scenarios. One Health, 2023, 16: 100557
CrossRef Google scholar
[]
CavalleriJV, Korbacska-KutasiO, LeblondA, PaillotR, PusterlaN, SteinmannE, TomlinsonJ. European College of Equine Internal Medicine consensus statement on equine flaviviridae infections in Europe. Journal of Veterinary Internal Medicine, 2022, 36(6): 1858-1871
CrossRef Google scholar
[]
Centers for Disease Control and Prevention. http://www.cdc.gov/westnile/index.html. Accessed 25 Feb 2024.
[]
ChevalierV, LecollinetS, DurandB. West Nile virus in Europe: A comparison of surveillance system designs in a changing epidemiological context. Vector-Borne Zoonotic Diseases, 2011, 11(8): 1085-1091
CrossRef Google scholar
[]
Costa, A. 2021. Serological surveillance of West Nile virus and molecular diagnostic of West Nile virus, Usutu virus, avian Influenza and Newcastle disease virus in wild birds of Portugal. Lisbon: Master Thesis, University of Lisbon – Faculty of Veterinary Medicine.
[]
CsankT, DrzewniokováP, KorytárĽ, MajorP, GyuraneczM, PistlJ, BakonyiT. Serosurvey of flavivirus infection in horses and birds in Slovakia. Vector Borne Zoonotic Diseases, 2018, 18(4): 206-213
CrossRef Google scholar
[]
CvjetkovićIH, RadovanovJ, KovačevićG, TurkulovV, PatićA. Diagnostic value of urine qRT-PCR for the diagnosis of West Nile virus neuroinvasive disease. Diagnostic Microbiology and Infectious Disease, 2023, 107(1): 115920
CrossRef Google scholar
[]
DaepCA, Muñoz-JordánJL, EugeninEA. Flaviviruses, an expanding threat in public health: Focus on dengue, West Nile, and Japanese encephalitis virus. Journal of Neurovirology, 2014, 20(6): 539-560
CrossRef Google scholar
[]
ErdélyiK, UrsuK, FerencziE, SzerediL, RátzF, SkáreJ, BakonyiT. Clinical and pathologic features of lineage 2 West Nile virus infections in birds of prey in Hungary. Vector Borne Zoonotic Diseases, 2007, 7(2): 181-188
CrossRef Google scholar
[]
European Centre for Disease Prevention and Control. https://www.ecdc.europa.eu/en/west-nile-virus-infection. Accessed 13 Mar 2024.
[]
European Centre for Disease Prevention and Control. 2022. Tick-borne encephalitis. In ECDC. Annual epidemiological report for 2020. Stockholm: ECDC.
[]
Farooq, Z., H. Sjödin, J. C. Semenza, Y. Tozan, M. O. Sewe, J. Wallin, and J. Rocklöv. 2023. European projections of West Nile virus transmission under climate change scenarios. One Health 16:100509. https://doi.org/10.1016/j.onehlt.2023.100509.
[]
FilipeAR, PintoMR. Survey for antibodies to arboviruses in serum of animals from southern Portugal. The American Journal of Tropical Medicine and Hygiene, 1969, 18(3): 423-426
CrossRef Google scholar
[]
Fontoura-Gonçalves, C., F. Llorente, E. Pérez-Ramírez, M. Á. Jiménez-Clavero, J. B. Costa, G. de Mello, D. Gonçalves, P. C. Alves, U. Höfle, and J. Queirós. 2024. Dynamics of Bagaza, West Nile, and Usutu viruses in Portugal revealed by long-term serological surveillance in red-legged partridges, 2018-2022. 485 bioRxiv 2024.08.02.606292 [Preprint] [cited 2024-08-11]. https://doi.org/10.1101/2024.08.02.606292.
[]
García-BocanegraI, FrancoJJ, LeónCI, Barbero-MoyanoJ, García-MiñaMV, Fernández-MoleraV, GómezMB, Cano-TerrizaD, GonzálvezM. High exposure of West Nile virus in equid and wild bird populations in Spain following the epidemic outbreak in 2020. Transboundary and Emerging Diseases, 2022, 69(6): 3624-3636
CrossRef Google scholar
[]
García-CarrascoJM, MuñozAR, OliveroJ, SeguraM, García-BocanegraI, RealR. West Nile virus in the Iberian Peninsula: Using equine cases to identify high-risk areas for humans. Euro Surveillance, 2023, 28(40): 2200844
CrossRef Google scholar
[]
GeraldesMA, CunhaMV, GodinhoC, LimaRF, GiovanettiM. The historical ecological background of West Nile virus in Portugal provides One Health opportunities into the future, 2023
CrossRef Google scholar
[]
GiesenC, HerradorZ, Fernandez-MartinezB, FiguerolaJ, GangosoL, VazquezA, Gómez-BarrosoD. A systematic review of environmental factors related to WNV circulation in European and Mediterranean countries. One Health, 2023, 16: 100478
CrossRef Google scholar
[]
GriffithsPR. Sex identification in birds. Seminars in Avian and Exotic Pet Medicine, 2000, 9(1): 14-26
CrossRef Google scholar
[]
HabarugiraG, SuenWW, Hobson-PetersJ, HallRA, Bielefeldt-OhmannH. West Nile virus: An update on pathobiology, epidemiology, diagnostics, control and “One Health” implications. Pathogens, 2020, 9(7): 589
CrossRef Google scholar
[]
HöfleU, BlancoJM, CrespoE, NaranjoV, Jiménez-ClaveroMA, SanchezA, de la FuenteJ, GortazarC. West Nile virus in the endangered Spanish imperial eagle. Veterinary Microbiology, 2008, 129(1–2): 171-178
CrossRef Google scholar
[]
Hosmer, D. W., and S. Lemeshow. 2000. Applied logistic regression. 2nd edition. New York: Wiley. https://doi.org/10.1002/0471722146.
[]
HubálekZ. An annotated checklist of pathogenic microorganisms associated with migratory birds. Journal of Wildlife Diseases, 2004, 40(4): 639-59
CrossRef Google scholar
[]
Ip, H. S., A. J. Van Wettere, L. McFarlane, V. Shearn-Bochsler, S. L. Dickson, J. Baker, G. Hatch, K. Cavender, R. Long, and B. Bodenstein. 2014. West Nile virus transmission in winter: the 2013 Great Salt Lake bald eagle and eared grebes mortality event. PLoS Currents 6. https://doi.org/10.1371/currents.outbreaks.b0f031fc8db2a827d9da0f30f0766871.
[]
Jurado-TarifaE, NappS, LecollinetS, ArenasA, BeckC, Cerdà-CuéllarM, Fernández-MorenteM, García-BocanegraI. Monitoring of West Nile virus, Usutu virus and Meaban virus in waterfowl used as decoys and wild raptors in southern Spain. Comparative Immunology, Microbiology and Infectious Diseases, 2016, 49: 58-64
CrossRef Google scholar
[]
KaaijkP, LuytjesW. Are we prepared for emerging flaviviruses in Europe? Challenges for vaccination. Human Vaccines and Immunotherapeutics, 2018, 14(2): 337-344
CrossRef Google scholar
[]
KunoG. Serodiagnosis of flaviviral infections and vaccinations in humans. Advances in Virus Research, 2003, 61: 3-65
CrossRef Google scholar
[]
LaDeauSL, KilpatrickAM, MarraPP. West Nile virus emergence and large-scale declines of North American bird populations. Nature, 2007, 447(7145): 710-713
CrossRef Google scholar
[]
LinkeS, NiedrigM, KaiserA, EllerbrokH, MüllerK, MüllerT, ConrathsFJ, MühleRU, SchmidtD, KöppenU, BairleinF, BertholdP, PauliG. Serologic evidence of West Nile virus infections in wild birds captured in Germany. American Journal of Tropical Medicine and Hygiene, 2007, 77(2): 358-364
CrossRef Google scholar
[]
Llorente, F., A. García-Irazábal, E. Pérez-Ramírez, C. Cano-Gómez, M. Sarasa, A. Vázquez, and M. Á. Jiménez-Clavero. 2019. Influence of flavivirus co-circulation in serological diagnostics and surveillance: A model of study using West Nile, Usutu and Bagaza viruses. Transboundary and Emerging Diseases 66 (5): 2100–2106. https://doi.org/10.1111/tbed.13262.
[]
LopezG, Jimenez-ClaveroMA, TejedorCG, SoriguerR, FiguerolaJ. Prevalence of West Nile virus neutralizing antibodies in Spain is related to the behavior of migratory birds. Vector-Borne Zoonotic Diseases, 2008, 8(5): 615-621
CrossRef Google scholar
[]
LourençoJ, BarrosSC, Zé-ZéL, DamineliDSC, GiovanettiM, OsórioHC, AmaroF, HenriquesAM, RamosF, LuísT, DuarteMD, FagulhaT, AlvesMJ, ObolskiU. West Nile virus transmission potential in Portugal. Communications Biology, 2022, 5(1): 6
CrossRef Google scholar
[]
Ludwig, A., M. Bigras-Poulin, P. Michel, and D. Bélanger. 2010. Risk factors associated with West Nile virus mortality in American Crow populations in Southern Quebec. Journal of Wildlife Diseases 46 (1): 195–208. https://doi.org/10.7589/0090-3558-46.1.195.
[]
LustigY, SoferD, BucrisED, MendelsonE. Surveillance and diagnosis of West Nile virus in the face of Flavivirus cross-reactivity. Frontiers in Microbiology, 2018, 9: 2421
CrossRef Google scholar
[]
MackenzieJS, GublerDJ, PetersenLR. Emerging flaviviruses: The spread and resurgence of Japanese encephalitis, West Nile and dengue viruses. Nature Medicine, 2004, 10(12 Suppl): S98-109
CrossRef Google scholar
[]
Malik, Y. S., A. A. P. Milton, S. Ghatak, and S. Ghosh. 2021. Migratory birds and public health risks. In Role of Birds in Transmitting Zoonotic Pathogens, Livestock Diseases and Management, 15–24. Singapore: Springer. https://doi.org/10.1007/978-981-16-4554-9.
[]
MarzalA, FerragutiM, MurielJ, MagallanesS, OrtizJA, García-LongoriaL, Bravo-BarrigaD, Guerrero-CarvajalF, Aguilera-SepúlvedaP, LlorenteF, de LopeF, Jiménez-Clavero, FronteraE. Circulation of zoonotic flaviviruses in wild passerine birds in Western Spain. Veterinary Microbiology, 2022, 268: 109399
CrossRef Google scholar
[]
MichelF, FischerD, EidenM, FastC, ReuschelM, MüllerK, RinderM, UrbaniakS, BrandesF, SchwehnR, LühkenR, GroschupMH, ZieglerU. West Nile virus and Usutu virus monitoring of wild birds in Germany. International Journal of Environmental Research and Public Health, 2018, 15(1): 171
CrossRef Google scholar
[]
NewtonI. Molt and plumage. Ringing & Migration, 2009, 24: 220-226
CrossRef Google scholar
[]
PallariCT, EfstathiouA, MoysiM, PapanikolasN, ChristodoulouV, MazerisA, KoliouM, KirschelANG. Evidence of West Nile virus seropositivity in wild birds on the island of Cyprus. Comparative Immunology, Microbiology and Infectious Diseases, 2021, 74: 101592
CrossRef Google scholar
[]
ParkashV, WoodsK, KafetzopoulouL, OsborneJ, AaronsE, CartwrightK. West Nile virus infection in travelers returning to United Kingdom from South Africa. Emerging Infectious Diseases, 2019, 25(2): 367-369
CrossRef Google scholar
[]
PaternosterG, TomassoneL, TambaM, ChiariM, LavazzaA, PiazziM, FavrettoAR, BalduzziG, PautassoA, VoglerBR. The degree of One Health implementation in the West Nile Virus integrated surveillance in Northern Italy, 2016. Frontiers in Public Health, 2017, 5(236): 1-10
CrossRef Google scholar
[]
PiersonTC, DiamondMS. The continued threat of emerging flaviviruses. Nature Microbiology, 2020, 5(6): 796-812
CrossRef Google scholar
[]
QueirósJ, BarrosSC, Sánchez-CanoA, HenriquesAM, FagulhaT, Dos SantosFA, DuarteMD, Fontoura-GonçalvesC, GonçalvesD, RodriguesM, CabreraTC, de MeraIGF, GortazarC, HöfleU, AlvesPC. Bagaza virus in wild birds, Portugal, 2021. Emerging Infectious Diseases, 2022, 28(7): 1504-1506
CrossRef Google scholar
[]
RizzoliA, Jimenez-ClaveroMA, BarzonL, CordioliP, FiguerolaJ, KorakaP, MartinaB, MorenoA, NowotnyN, PardigonN, SandersN, UlbertS, TenorioA. The challenge of West Nile virus in Europe: Knowledge gaps and research priorities. Euro Surveillance, 2015, 20(20): 21135
CrossRef Google scholar
[]
ScaramozzinoP, CarvelliA, BruniG, CappielloG, CensiF, MaglianoA, MannaG, RicciI, RombolàP, RomitiF, RosoneF, SalaMG, SciclunaMT, VaglioS, LiberatoCD. West Nile and Usutu viruses cocirculation in central Italy: Outcomes of the 2018 integrated surveillance. Parasites & Vectors, 2021, 14(1): 243
CrossRef Google scholar
[]
SimoninY. Circulation of West Nile virus and Usutu virus in Europe: Overview and challenges. Viruses, 2024, 16(4): 599
CrossRef Google scholar
[]
TodoricD, VrbovaL, MitriME, GasmiS, StewartA, ConnorsS, ZhengH, BourgeoisAC, DrebotM, ParéJ, ZimmerM, BuckP. An overview of the national West Nile Virus surveillance system in Canada: A One Health approach. Canada Communicable Disease Report, 2022, 48(5): 181-187
CrossRef Google scholar
[]
Verbeek, N. A. M. and C. Caffrey. 2002. American crow (Corvus brachyrhynchos): Account Nb647. In The birds of North America, eds. A. Poole and E. Gill. Philadelphia: Academy of Natural Sciences and Washington, D.C.: American Ornithologists’ Union. https://doi.org/10.2173/bna.647.
[]
WeingartlHM, DrebotMA, HubálekZ, HalouzkaJ, AndonovaM, DibernardoA, Cottam-BirtC, LarenceJ, MarszalP. Comparison of assays for the detection of West Nile virus antibodies in chicken serum. Canadian Journal of Veterinary Research, 2003, 67(2): 128-132
[]
WeissenböckH, HubálekZ, BakonyiT, NowotnyN. Zoonotic mosquito-borne flaviviruses: Worldwide presence of agents with proven pathogenicity and potential candidates of future emerging diseases. Veterinary Microbiology, 2010, 140(3–4): 271-280
CrossRef Google scholar
[]
World Health Organization. 2020. https://www.who.int/news-room/fact-sheets/detail/vector-borne-diseases. Accessed 23 June 2024.
[]
ZannoliS, SambriV. West Nile virus and Usutu virus cocirculation in Europe: Epidemiology and implications. Microorganisms, 2019, 7(7): 184
CrossRef Google scholar
[]
ZieglerU, BergmannF, FischerD, MüllerK, HolickiCM, SadeghiB, SiegM, KellerM, SchwehnR, ReuschelM, FischerL, KroneO, RinderM, SchütteK, SchmidtV, EidenM, FastC, GüntherA, GlobigA, ConrathsFJ, StaubachC, BrandesF, LierzM, KorbelR, VahlenkampTW, GroschupMH. Spread of West Nile virus and Usutu virus in the German bird population, 2019–2020. Microorganisms, 2022, 10(4): 807
CrossRef Google scholar
[]
ZuberogoitiaI, ZabalaJ, MartínezJE. Molt in birds of prey: A review of current knowledge and future challenges for research. Ardeola, 2018, 65(2): 183-207
CrossRef Google scholar
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