The Asian tiger mosquito Aedes albopictus (Scuse, 1895) was first detected on the Crimean Peninsula in 2019. Two female Ae. albopictus were captured in the city of Yalta (Kovalenko et al., 2020). In our study in 2020, we recorded the Asian tiger mosquito in two locations: in Sevastopol and in Yalta. In the following year, 2021, it was found that Ae. albopictus spread from Yalta to Alushta and appeared in Kerch. In total, we caught 440 mosquitoes of this species on the southern coast of Crimea. The complex ecological and molecular-genetic analysis of the invasive population on the Crimean Peninsula was carried out. Variability of the Folmer fragment of the coxI gene was determined. It was shown that the invasive population of Crimea contains two major mitochondrial haplotypes previously detected in the Krasnodar Territory. This allows us to conclude about the origin of the Crimean population from the population of Krasnodar Territory. We assume independent penetration of mosquitoes to Sevastopol, Yalta, and Kerch as a result of anthropogenic introduction. The obtained data indicate the formation of permanent populations of Ae. albopictus on the southern coast of Crimea.
2022. T. 127. Vyp. 5.
2022. T. 127. Vyp. 5.
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Invasion of the Asian Tiger Mosquito Aedes albopictus (Scuse, 1895) on the Crimean Peninsula
References
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Список литературы
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- Bega A.G., Moskaev A.V., Gordeev M.I. Ekologiya i rasprostranenie invazivnogo vida komarov Aedes albopictus (Skuse, 1895) na yuge Evropejskoj chasti Rossii // Rossijskij zhurnal biologicheskikh invazij. 2021. № 1. S. 27–38.
- Kovalenko I.S., Yakunin S.N., Abibulaev D.E., Vladychak V.V., Borodai N.V., Smelyanskii V.P., Fomina V.K., Zinich L.S., Tikhonov S.N. Obnaruzhenie Aedes (Stegomyia) albopictus (Skuse, 1895) v Krymu // Problemy osobo opasnykh infektsii. 2020. Vyp. 2. S. 135–137.
- Mokievskij V.O., Tsetlin A.B., Ignatov E.I i dr. Ekologicheskij atlas. Chernoe i Azovskoe morya. M., 2019. 464 s.
- Fedorova M.V., Shvets O.G., Mednyak I.M., Shaikevich E.V. Geneticheskij analiz populyatsii zavoznykh komarov Aedes (Stegomyia) albopictus (Skuse, 1895) (Diptera, Culicidae) v Krasnodarskom krae // Parazitologiya. 2019. T. 53, Vyp. 6. S. 518–528.
- Akıner M.M., Öztürk M., Başer A.B. Günay F, Hacıoğlu S, Brinkmann A., Emanet N., Özkul B.A., Nitsche A., Linton Y., Ergünay K. Arboviral screening of invasive Aedes species in northeastern Turkey: West Nile virus circulation and detection of in-sect-only viruses // PLoS Neglected Tropical Diseases. 2019. Vol. 13. N 5. e0007334.
- Henk Van den Berg W, Velayudhan R, Ejov M. Regional framework for surveillance and control of invasive mosquito vectors and re-emerging vector-borne diseases 2014–2020. Copenhagen, 2013. 26 p.
- Folmer O, Black M, Hoeh W, Lutz R, Vrijenhoek R. DNA primers for amplification of mitochondrial cytochrome c oxidase subu-nit I from diverse metazoan invertebrates. Mol Mar Biol Biotechnol. 1994. Vol. 3. P. 294–299.
- Kraemer M.U.G., Sinka M.E., Duda K.A., Mylne A.Q.N., Shearer F.M., Barker C.M., Moore C.G., Carvalho R.G., Coelho G.E., Bortel W.V., Hendrickx G., Schaffner F., Elyazar I.R.F., Teng H.J., Brady O.J., Messina J.P., Pigott D.M., Scott T.W., Smith D.L., Wint G.R.W., Golding N., Hay S.I. The Global Distribution of Arbovirus Vectors Aedes egypti and Ae. albopictus // Elife. 2015. Vol. 4. P. 1–18.
- Kumar S., Stecher G., and Tamura K. MEGA7: Molecular evolutionary genetics analysis version 7.0 for bigger datasets // Mol. Biol. Evol. 2016. Vol. 33. P. 1870–1874.