Assessment of anthropogenic invasion of microfungi in Arctic ecosystems (exemplified by Spitsbergen archipelago)

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Abstract

Introduction. The aim of this work was to study the mycobiota of anthropogenic materials, soil and air in the settlement Barentsburg (Spitsbergen archipelago), to assess the spread of invasive species and to identify potentially pathogenic microfungi.

Material and methods. The material for the study was collected in the period of research work of the Russian expedition of the AARI (2017-2018) in the area of the settlement Barentsburg (located at 78° N, 14° E). Isolation and identification of microfungi were carried out using standard microbiological methods according to cultural and morphological characteristics and sequencing in the ITS1 and ITS2 regions.

Results. As a result of the research, a high level of microbiological colonization of anthropogenic substrates has been established, the places of accumulation of potentially pathogenic microorganisms were found out. 24 species of microfungi were identified from anthropogenic materials, 46 and 43 species from aeromycota and the soils of the observed territory. The genus Penicillium (12 species) prevailed by the number of species, followed by Cladosporium, Aspergillus, Cadophora (3 species each). For disturbed ecosystems the following peculiarities have been established: 1) a change in the structure of microfungi complexes and increase in the CFU number of microfungi at aeromycota and soil, 2) aeromycota formation occurs partly due to introduced species, 3) a clear dominance of dark-colored fungi on anthropogenic materials, 4) among the introduced microfungi a significant proportion were destructors of the materials as well as potentially human pathogens; 5) introduced species are able to adapt to arctic conditions.

Conclusion. On the example of the village of Barentsburg (arch. Svalbard) it is shown that anthropogenic impact leads to changes in the main characteristics of microscopic fungi complexes in the Arctic territories.

About the authors

Irina Yu. Kirtsideli

Botanical Institute of the Russian Academy of Sciences

Author for correspondence.
Email: microfungi@mail.ru
ORCID iD: 0000-0002-4736-2485

MD, Ph.D., DSci., leading researcher of the Mycology department of V.L. Komarov Botanical Institute of the Russian Academy of Science, St. Petersburg, 197376, Russian Federation.

e-mail: microfungi@mail.ru

Russian Federation

D. Yu. Vlasov

Botanical Institute of the Russian Academy of Sciences; Saint-Petersburg State University

Email: noemail@neicon.ru
ORCID iD: 0000-0002-0455-1462
Russian Federation

M. S. Zelenskaya

Saint-Petersburg State University

Email: noemail@neicon.ru
ORCID iD: 0000-0003-3588-8583
Russian Federation

V. A. Iliushin

Botanical Institute of the Russian Academy of Sciences

Email: noemail@neicon.ru
ORCID iD: 0000-0003-1031-7661
Russian Federation

Yu. K. Novozhilov

Botanical Institute of the Russian Academy of Sciences

Email: noemail@neicon.ru
ORCID iD: 0000-0001-8875-2263
Russian Federation

I. V. Churkina

North-Western Almazov Federal Medical Research Center of the Russian Federation

Email: noemail@neicon.ru
ORCID iD: 0000-0002-9259-7152
Russian Federation

E. P. Barantsevich

North-Western Almazov Federal Medical Research Center of the Russian Federation

Email: noemail@neicon.ru
ORCID iD: 0000-0002-4800-3345
Russian Federation

References

  1. AMAP Arctic pollution 2006. Oslo: Arctic Monitoring and Assessment Programme; 2006.
  2. Christensen J.H., Hewitson B., Busuioc A., Chen A., Gao X., Held I. et al. Regional climate projections. In: Solomon S. et al (eds). Climate change 2007. The physical science basis. Contribution of Working Group I to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press; 2007: 849–940.
  3. Henry H.A.L. Climate change and soil freezing dynamics: historical trends and projected changes. Climatic Change. 2008; 87: 421–34.
  4. Marfenina O.E. Antropogenic changes in complexes of microfungi in soils [Antropogennoye izmeneniye kompleksov mikroskopicheskikh gribov v pochvakh]. Diss. Moscow; 1999. (in Russian)
  5. Fisk A.C., DeWit M., Wayland Z., Kuzyk N., Burgess R., Letcher B. et al. An assessment of the toxicological significance of anthropogenic contaminants in Canadian Arctic wildlife. Sci Total Environ. 2005: 351–93.
  6. Anda E.E., Nieboer E., Dudarev A.A., Sandanger T.M., Odland J.O. Intra- and intercompartmental associations between levels of organochlorines in maternal plasma, cord plasma and breast milk, and lead and cadmium in whole blood, for indigenous peoples of Chukotka. J Environ Monit. 2007; 9: 884–93.
  7. Nost T.H., Vestergren R., Berg V., Nieboer E., Odland J.O., Sandanger T.M. Repeated measurements of per- and polyfl uoroalkyl substances (PFASs) from 1979 to 2007 in males from northern Norway: Assessing time trends, compound correlations and relations to age/birth cohort. Environ Int. 2014; 67: 43–53.
  8. Zachinyaeva A.V., Lebedeva E.V. Micromycetes of polluted soils of the North-West region of Russia and their role in the pathogenesis of allergic forms of mycoses. Mikologiya i fitopatologiya. 2003; 37 (5): 69–74. (in Russian)
  9. Zalar P., Gunde-Cimerman N. Cold-Adapted Yeasts in Arctic Habitats. In: Buzzini P., Margesin R., eds. Cold-adapted yeasts. Berlin, Heidelberg: Springer; 2014: 49–74.
  10. Connell L.B., Rodriguez R.R., Redman R.S., Dalluge J.J. Cold-Adapted Yeasts in Antarctic Deserts. In: Buzzini P., Margesin R. (eds). Cold-adapted Yeasts. Berlin, Heidelberg: Springer; 2014: 76–98.
  11. Selbmann L., De Hoog G.S., Zucconi L., Isola D., Onofri S. Black yeasts in cold habitats. In: Buzzini P., Margesin R. (eds) Cold-adapted Yeasts. Berlin, Heidelberg: Springer; 2014: 173–90.
  12. Hassan N., Rafiq M., Hayat M., Shah A.A., Hasan F. Psychrophilic and psychrotrophic fungi: a comprehensive review. Rev Environ Sci Bio. 2016; 15 (2): 147–72.
  13. Kirtsideli I.Yu., Vlasov D.Yu., Novozhilov Yu.K., Abakumov E.V., Barantsevich E.P. Assessment of Anthropogenic Influence on Antarctic Mycobiota in Areas of Russian Polar Stations. Contemp Probl Ecol. 2018; 11 (5): 449–57.
  14. Hisdal V. Svalbard nature and history. Oslo: Norwegian Polar Institute; 1998. 123 p.
  15. Zvyagintsev D.G. Methods of soil microbiology and biochemistry [Metody pochvennoy mikrobiologii i biokhimii]. Moscow: MSU; 1991. 304 p. (in Russian)
  16. Pestova N.E., Barantsevich E.P., Ribkova N.S., Kozlova N.S., Barantsevich N.E. Study of effectiveness of sequeness of fragement of 16S RRNA gene in idenrification of microorganisms. Profilakticheskaya i klinicheskaya meditsina. 2011; 4 (41): 54–5. (in Russian)
  17. Hoch H.C., Galvani C.D., Szarowski D.H., Turner J.N. Two new fluorescent dyes applicable for visualization of fungal cell walls. Mycologia. 2005; 97 (3): 580–8.
  18. Polyanskaya L.M., Zvyagintsev D.G. The content and composition of microbial biomass as an index of the ecological status of soil. Eurasian J Soil Sci. 2005; 38 (6): 625–33.
  19. Kirtsideli I. Yu., Vlasov D.Yu., Abakumov E.V., Barantsevich E.P., Novozhilov Ju.K., Krylenkov V.A. et al. Airborne fungi in arctic settlement Tiksi (Russian Arctic, coast of the Laptev Sea). Czech polar Rep. 2017; 7 (2): 300–10.
  20. Kirtsideli I.Yu., Vlasov D.Yu., Krylenkov V.A., Sokolov V.T. Aeromikota in locations of the Russian Arctic stations in the water areas of the White, Barents and Kara Seas. Mikologiya i fitopatologiya. 2011; 45 (3): 228–39. (in Russian)
  21. Kirtsideli I.Yu., Vlasov D.Yu., Krylenkov V.A., Rolle N.N., Barantsevich E.P., Sokolov V.T. Comparative Study of Airborne Fungi at Arctic Stations Near Water Area of the Northern Sea Route. Ekologiya cheloveka [Human Ecology]. 2018; 4: 16–21. (in Russian)
  22. Kirtsideli I.Yu. Soil micromycetes from arctic tundras of Kara sea Taymir coast. Mikologiya i fitopatologiya. 1999; 33 (1): 19–24. (in Russian)
  23. Korneykova M.V., Evdokimova G.A. Microbiota of the ground air layers in natural and industrial zones of the Kola arctic. J Environ Sci Health A Tox Hazard Subst Environ Eng. 2018; 53 (3): 271–7.
  24. Singh S.M., Singh S.K., Yadav L.S., Singh P.N., Ravindra R. Filamentous soil fungi from Ny-Ålesund, Spitsbergen, and screening for extracellular enzymes. Arctic. 2012; 65 (1): 45–55.
  25. Kurek E., Korniłowicz-Kowalska T., Słomka A., Melke J. Characteristics of soil filamentous fungi communities isolated from various micro relief forms in the high Arctic tundra (Bellsund region, Spitsbergen). Pol Polar Res. 2007; 28: 57–73.
  26. Matveeva N.V., Zanokha L.L., Afonina O.M., Potemkin A.D., Patova E.N., Davydov D.A. et al. Plants and fungi of the polar deserts of the Northern Hemisphere [Rasteniya i griby polyarnykh pustyn’ Severnogo polushariya]. Komarov Botanical Institute RAS. Saint-Petersburg: Marafon; 2015. (in Russian)
  27. Pang K.L., Chiang M.W., Vrijmoed L.L.P. Havispora longyearbyenensis gen. et sp. nov.: An arctic marine fungus from Svalbard, Norway. Mycologia. 2008; 100: 291–5.
  28. Zhang T., Wang N.F., Liu H.Y., Zhang Y.Q., Yu L.Y. Soil pH is a Key Determinant of Soil Fungal Community Composition in the Ny-Ålesund Region, Svalbard (High Arctic). Front Microbiol. 2016; 7: 227. https://doi.org/10.3389/fmicb.2016.00227
  29. Zhu R., Chen Q., Ding W., Xu H. Impact of seabird activityon nitrous oxide and methan efluxes from High Arctic tundra in Svalbard, Norway. J Geophys Res. 2012; 117: G04015. https://doi.org/10.1029/2012JG002130
  30. Ali S.H., Alias S.A., Siang H.Y., Smykla J., Pang K.L., Guo S.Y. Studies on diversity of soil microbfungi in the Hornsundarea. Spitsbergen. Pol Polar Res. 2013; 34: 39–54. https://doi.org/10.2478/popore-2013-0006
  31. Cox F., Newsham K.K., Bol R., Dungait J.A., Robinson C.H. Not poles apart: Antarctic soil fungal communities show similarities to those of the distant Arctic. Ecol Lett. 2016; 19 (5): 528–36.
  32. Kochkina G.A., Ivanushkina N.E., Ozerskaya S.M. Structure of mycobiota of permafrost. Mikologiya segodnya. 2011; 2: 178–84. (in Russian)
  33. Ozerskaya S., Kochkina G., Ivanushkina N., Gilichinsky D.A. Fungi in permafrost. In: Margesin R., ed. Permafrost soils. Springer; 2009: 85–95.
  34. Buzzini P., Branda E., Goretti M., Turchetti B. Psychrophilic yeasts from worldwide glacial habitats: diversity, daptation strategies and biotechnological potential. FEMS Microbiol Ecol. 2012; 82 (2): 217–41.
  35. Sanitary rules SP 1.3.2322-08 «Security work with microorganisms of III–IV pathogenicity groups (hazard) and agents of parasitic infections»; 2008. (in Russian)

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Copyright (c) 2024 Kirtsideli I.Y., Vlasov D.Y., Zelenskaya M.S., Iliushin V.A., Novozhilov Y.K., Churkina I.V., Barantsevich E.P.


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