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Joint detection of microsatellites and flanking sequences – SNPSTR markers for Athene noctua to fight illegal wildlife trade

AutorInnen: 
Mozer, A., Consul, A., Misof, B., Jäger, R., Olek, K., Astrin, J. J.
Erscheinungsjahr: 
2024
Vollständiger Titel: 
Joint detection of microsatellites and flanking sequences – SNPSTR markers for Athene noctua to fight illegal wildlife trade
Publiziert in: 
Forensic Science International: Animals and Environments
Publikationstyp: 
Zeitschriftenaufsatz
DOI Name: 
https://doi.org/10.1016/j.fsiae.2024.100084
Bibliographische Angaben: 
Joint detection of microsatellites and flanking sequences – SNPSTR markers for Athene noctua to fight illegal wildlife trade, Forensic Science International: Animals and Environments,Volume 5,2024, 100084, ISSN 2666-9374, https://doi.org/10.1016/j.fsiae.2024.100084. (https://www.sciencedirect.com/science/article/pii/S2666937424000040)
Abstract: 

Trade of wild-caught animals is illegal for many taxa and in many countries. Common regulatory procedures involve documentation and marking techniques. However, these procedures are subject to fraud and thus should be complemented by routine genetic testing in order to authenticate the captive-bred origin of animals intended for trade. A suitable class of genetic markers are SNPSTRs that combine a short tandem repeat (STR) and single nucleotide polymorphisms (SNPs) within one amplicon. This combined marker type can be used for genetic identification and for parentage analyses and in addition, provides insight into haplotype history. As a proof of principle, this study establishes a set of 20 SNPSTR markers for Athene noctua, one of the most trafficked owls in CITES Appendix II. These markers can be coamplified in a single multiplex reaction. Based on population data, the percentage of observed and expected heterozygosities of the markers ranged from 0.400 to 1.000 and 0.545 to 0.850, respectively. A combined probability of identity of 5.3 * 10−23 was achieved with the whole set, and combined parentage exclusion probabilities reached over 99.99%, even if the genotype of one parent was missing. A direct comparison of an owl family and an unrelated owl demonstrated the applicability of the SNPSTR set in parentage testing. The established SNPSTR set thus proved to be highly useful for identifying individuals and analysing parentage to determine wild or captive origin. We propose to implement SNPSTR-based routine certification in wildlife trade as a way to reveal animal laundering and misdeclaration of wild-caught animals.