Item request has been placed! ×
Item request cannot be made. ×
loading  Processing Request

Drivers Shaping Spillover of Aleutian Mink Disease Virus Introduced With American Mink Among Native Mustelids.

Item request has been placed! ×
Item request cannot be made. ×
loading   Processing Request
Read Online Read More Add to Saved list
  • Additional Information
    • Source:
      Publisher: Blackwell Verlag Country of Publication: Germany NLM ID: 101319538 Publication Model: eCollection Cited Medium: Internet ISSN: 1865-1682 (Electronic) Linking ISSN: 18651674 NLM ISO Abbreviation: Transbound Emerg Dis Subsets: MEDLINE
    • Publication Information:
      Original Publication: Berlin : Blackwell Verlag
    • Subject Terms:
      Aleutian Mink Disease Virus*/isolation & purification ; Aleutian Mink Disease*/epidemiology ; Aleutian Mink Disease*/virology ; Aleutian Mink Disease*/transmission ; Mink*/virology ; Introduced Species* ; Mustelidae*/virology; Animals ; Poland/epidemiology ; Seroepidemiologic Studies ; Antibodies, Viral/blood
    • Abstract:
      Competing Interests: The authors declare no conflicts of interest.
      Invasive alien species pose a major threat to ecosystems by outcompeting native species for resources, altering habitats, enabling potential genetic hybridisation and introducing pathogens into the environment. An understanding of the factors that determine virus transfer between invasive and native species is crucial to the mitigation of the negative impact of the pathogens introduced. This study presents a comprehensive analysis of factors influencing Aleutian mink disease virus (AMDV) infection in native mustelids in Poland, following its introduction by feral American mink. AMDV seroprevalence in American mink varied spatially from 0 in the central and southern regions to 0.8 in the northern regions. Antibodies to AMDV were detected in all six studied mustelids, including a novel finding in weasels. AMDV seroprevalence in other mustelids correlated positively with its occurrence in American mink, and reached 0.54 in areas with the highest mink AMDV seroprevalence. Furthermore, in native mustelids, more closely phylogenetically related to mink, AMDV seroprevalence was higher (0.68 in polecats and weasels) compared to more distantly related species (0.37 in badgers). Over the 27-year study period, AMDV seroprevalence in mustelids has increased from 0.04 to 0.60, despite a decline in seroprevalence in feral mink in subsequent years. These findings suggest that the spread of viral infections as a result of the introduction of invasive species could affect mustelid species and may intensify over time.
      (Copyright © 2025 Andrzej Zalewski et al. Transboundary and Emerging Diseases published by John Wiley & Sons Ltd.)
    • References:
      J Wildl Dis. 2016 Jan;52(1):22-32. (PMID: 26528576)
      J Virol. 1988 Aug;62(8):2903-15. (PMID: 2839709)
      J Wildl Dis. 2014 Jul;50(3):689-93. (PMID: 24807350)
      J Parasitol. 2011 Apr;97(2):357-60. (PMID: 21506875)
      Syst Biol. 2018 Jan 01;67(1):127-144. (PMID: 28472434)
      Sci Rep. 2023 Jun 9;13(1):9390. (PMID: 37296209)
      PLoS One. 2015 Oct 07;10(10):e0139852. (PMID: 26444280)
      Acta Vet Scand. 2013 Feb 08;55:10. (PMID: 23394546)
      Infect Immun. 1982 Apr;36(1):379-86. (PMID: 6176546)
      J Virol. 2015 Feb;89(3):1909-12. (PMID: 25410876)
      J Gen Virol. 2006 Aug;87(Pt 8):2115-2125. (PMID: 16847106)
      Infect Immun. 1983 Sep;41(3):1016-23. (PMID: 6193063)
      Transbound Emerg Dis. 2021 Jul;68(4):2556-2570. (PMID: 33197283)
      Biol Lett. 2016 Feb;12(2):20150623. (PMID: 26888913)
      PLoS One. 2011;6(7):e21693. (PMID: 21789177)
      Animals (Basel). 2022 Oct 05;12(19):. (PMID: 36230414)
      J Gen Virol. 2015 Jun;96(Pt 6):1423-1435. (PMID: 25667324)
      Nature. 2016 Aug 10;536(7615):143-5. (PMID: 27510207)
      Emerg Microbes Infect. 2017 May 10;6(5):e30. (PMID: 28487558)
      J Rheumatol. 1974 Mar;1(1):74-92. (PMID: 4376565)
      Infect Genet Evol. 2014 Jan;21:15-40. (PMID: 24161410)
      Vet Microbiol. 2009 Jan 13;133(3):229-38. (PMID: 18799272)
      Vet Microbiol. 2014 Jan 31;168(2-4):420-7. (PMID: 24389253)
      J Vet Diagn Invest. 2015 May;27(3):287-94. (PMID: 25862712)
      Vet Pathol. 2015 Nov;52(6):1250-3. (PMID: 25445322)
      Proc Biol Sci. 2015 Feb 22;282(1801):20142620. (PMID: 25567651)
      J Wildl Dis. 2004 Jul;40(3):394-402. (PMID: 15465705)
      Emerg Infect Dis. 2024 Mar;30(3):444-452. (PMID: 38407173)
      Trends Ecol Evol. 2005 May;20(5):238-44. (PMID: 16701375)
      Pathogens. 2020 Feb 15;9(2):. (PMID: 32075256)
      Infect Agents Dis. 1994 Dec;3(6):279-301. (PMID: 7889316)
      Funct Ecol. 2012 Dec;26(6):1275-1287. (PMID: 32313353)
      Science. 2001 May 11;292(5519):1102-5. (PMID: 11352064)
      Vet Rec. 2001 Oct 20;149(16):485-8. (PMID: 11700927)
      PLoS One. 2015 Mar 30;10(3):e0122194. (PMID: 25822750)
      Proc Biol Sci. 2003 Apr 22;270(1517):775-81. (PMID: 12737654)
      Science. 2010 Aug 6;329(5992):676-9. (PMID: 20689015)
      Sci Adv. 2015 Jun 19;1(5):e1400253. (PMID: 26601195)
      Science. 2004 Apr 9;304(5668):209-11. (PMID: 15073357)
      Proc Natl Acad Sci U S A. 2016 Oct 4;113(40):11261-11265. (PMID: 27638204)
      Virus Evol. 2021 Aug 28;7(2):veab075. (PMID: 34548930)
    • Accession Number:
      0 (Antibodies, Viral)
    • Publication Date:
      Date Created: 20250430 Date Completed: 20250430 Latest Revision: 20250501
    • Publication Date:
      20250501
    • Accession Number:
      PMC12017014
    • Accession Number:
      10.1155/tbed/3184679
    • Accession Number:
      40302756