THE STRUCTURE OF MICROMYCETES COMPLEXES IN THE ECOTOPES OF SULFUR QUARRIES IN THE WESTERN REGION OF UKRAINE

Authors

DOI:

https://doi.org/10.33730/2310-4678.4.2022.275849

Keywords:

mycobiome structure, contaminated soils, species composition, biodiversity

Abstract

Species composition and structure of micromycetes in the soil samples of the Yavoriv and Podorozhnie sulfur quarries with different degree of sulfur contamination were studied. The monitoring points were selected based on the considerable variation of the level of sulfur pollution. Soil samples with comparatively insignificant excess of SO4 2– background concentration in soil solution were compared with those exceeding the concentration by 1.5–1.9 times (ecotope ZH1), by 4.0–4.6 times (ecotope E3), 48-50 times (ecotope T5), 40–44 times (ecotope T6), by 7.5–8.0 times (ecotope E7). It was established that the ecotopes with SO4 2– content in soil solution differing 1.5–1.9 times were characterized with the high comparison coefficient (V). It indicates exact similarity of microbiota of the studied ecotopes, which is typical for the studied area of the Podorozhnie sufur quarry. The Yavoriv sulfur quarry is characterized with low values of comparison coefficient (V) which was mostly demonstrated in the soils with excessive background concentration of SO4 2– in soil solution by 40–50 times. Species composition of micromycetes was defined, which were distinguished during 2011–2021 and classified as 76 species of 31 genera. Based on the calculation of even correlations between species of micromycetes in soils of the studied sulfur quarries and SO4 2– content in soil solution structural species were defined, which are interconnected with close correlation relations and form micromycetes complexes at the Podorozhnie and Yavoriv sulfur quarries, which indicates the spread of r- and L- strategists on the devastated areas.

Author Biographies

V. Oliferchuk, National Forestry University of Ukraine

Candidate of Biological Sciences, Associate Professor

І. Shukel, National Forestry University of Ukraine

Candidate of Agricultural Sciences, Associate Professor

References

Taras, U.M. (2013). Problemy rekultyvatsii sirchanoho karieru v zoni diialnosti Yavorivskoho derzhavnoho hirnycho-khimichnoho pidpryiemstva “Sirka” [The revegetation problems of sulphuric pit during activity of the Yavoriv state mines-chemical enterprise “Sirka”]. Naukovyi visnyk NLTU Ukrainy – Scientific bulletin of UNFU, 23 (2), 154–158 [in Ukrainian].

Bardas, A.V., Bohach, K.S. (2013). Vplyv hirnychykh robit na tekhnohenne ruinuvannia gruntovoho pokryvu ta ekolohichne vykorystannia zemelnykh resursiv [The impact of mining on man-made soil destruction and environmental use of land resources]. Ekonomichnyi prostir – Economic scope, 71, 277–286 [in Ukrainian].

Kachanovskyi, O. (2021). Klasyfikatsiia porushenykh zemel dlia reabilitatsii. [Classification of distributed lands for rehabilitation]. Tavriiskyi naukovyi visnyk. Seriia: Ekonomika – Taurida Scientific Herald. Series: Economics, 5, 90–96 [in Ukrainian].

Baliuk, S.A. (2012). Kontseptsiia rekultyvatsii zemel porushenykh za vidkrytoho ta pidzemnoho vydobutku korysnykh kopalyn [The concept of reclamation of lands disturbed by open and underground mining]. Natsionalnyi naukovyi tsentr “Instytut gruntoznavstva ta ahrokhimii imeni O.N. Sokolovskoho” [in Ukrainian].

Poesen, J. (2018). Soil erosion in the Anthropocene: Research needs. Earth Surface Processes and Landforms, 43, 64–84 [in English].

FAO (2021). The State of the World’s Land and Water Resources for Food and Agriculture — Systems at breaking point. Synthesis report 2021. Rome. DOI: https://doi.org/10.4060/cb7654en [in English].

FAO (2015). A/RES/70/1. Transforming our world: the 2030 Agenda for Sustainable Development, Agenda items 15 and 116 of UN Seventieth session. FAO, 21 October 2015. URL: https://sustainabledevelopment.un.org/post2015/transformingourworld. [in English].

Johnson, A.C., Jin, X., Nakada, N., Sumpter, J.P. (2020). Learning from the past and considering the future of chemicals in the environment. Science, 367, 384–387 [in English].

Baliuk, S., Medvediev, V., Vorotyntseva, L., Shymel, V. (2017). Suchasni problemy dehradatsii hruntiv i zakhody shchodo dosiahnennia neitralnoho yii rivnia [Problems of degradation of soils and measures on reaching its neutral level]. Visnyk ahrarnoi nauky – Bulletin of Agricultural Science, 8, 5–11 [in Ukrainian].

Demianiuk, O.S., Boiko, A.L. (2019). Zemlia potrebuie stratehichnoho analizu [Land demands strategic analysis]. Visnyk ahrarnoi nauky – Bulletin of Agricultural Science, 2, 82–85 [in Ukrainian].

Didukh, Ya.P. (2012). Osnovy bioindykatsii [Basics of bioindication]. Kyiv: Naukova dumka [in Ukrainian].

Heger, T.J., Imfeld, G., Mitchell, E.A.D. (Eds.). (2012). Bioindication in Soil Ecosystems. European Journal of Soil Biology, 49, 1–118 [in English].

Demianiuk, O.S., Symochko, L.Yu., Tertychna, O.V. (2017). Suchasni metodychni pidkhody do otsiniuvannia ekolohichnoho stanu gruntu za aktyvnistiu mikrobiotsenozu [Modern methodical approaches to evaluaton the ecological condition of soil by microbial activity]. Pytannia bioindykatsii ta ekolohii — Problems of bioindication and ecology, 22 (1), 55–68 [in Ukrainian].

Musych, O.H., Parfeniuk, A.I., Landin, V.P., Demianiuk, O.S. (2018). Porushennia ekolohichnoi rivnovahy mikrobotsenozu na radiatsiino zabrudnenykh gruntakh Polissia Ukrainy [Violation of the ecological balance of microbocenosis on radiation-contaminated soils of Polissia of Ukraine]. Ahroekolohichnyi zhurnal – Agroecological journal, 3, 70–76 [in Ukrainian].

Iutinskaya, G.A., Ponomarenko, S.P., Andreyuk, Ye.I. (2010). Bioregulyatsiya mikrobno-rastitelnykh sistem: monografiya [Bioregulation of microbial-plant systems: monograph]. Kyiv: Nichlava [in Russian].

Paul, E.A. (2014). Soil microbiology, ecology and biochemistry. Academic press [in English].

Chandra, P., Varma, A., Tripathi, S., Prasad, R., (Eds.). (2019). Soil–microbes–plants: Interactions and ecological diversity. Plant Microbe Interface. Springer: Cham, Switzerland [in English].

Demianiuk, O., Symochko, L., Hosam, E.A.F. Bayoumi Hamuda, Symochko, V., Dmitrenko, O. (2019). Сarbon pool and biological activities of soils in different ecosystems. International Journal of Ecosystems and Ecology Science, 9 (1), 189–200 [in English].

Hofman, J., Bezchlebova, J., Dusek, L. (2003). Novel approach to monitoring of the soil biological quality. Environ. Int, 28 (88), 771–778 [in English].

Mirchink, T.G. (1984). Pochvennye griby kak komponenty biogeocenoza / Pochvennye organizmy kak komponenty biogeocenoza [Soil fungi as components of biogeocenosis / Soil organisms as components of biogeocenosis]. Moscow [in Russian].

Kaisermann, A., Maron, P., Beaumelle, L. et al. (2015). Fungal communities are more sensitive indicators to non-extreme soil moisture variations than bacterial communities. Applied Soil Ecology, 86, 158–164 [in English].

Devi, R., Kaur, T., Kour, D., Rana, K.L., Yadav, A., Yadav, A.N. (2020). Beneficial fungal communities from different habitats and their roles in plant growth promotion and soil health. Microbial Biosyst, 5, 21–47 [in English].

Marfenina, O.Ye. (2005). Antropogennaya ekologiya pochvennyh gribov [Anthropogenic ecology of soil fungi]. Moscow: Medicina dlya vseh [in Russian].

Bilay, V.I., Ellanskaya, I.A., Kirilenko, T.S. (1984). Mikromitsety pochv [Micromycetes of soils]. Kyiv: Naukova dumka [in Russian].

Zhdanova, N.N., Vasilevskaya, A.P. (1988). Melaninsoderzhashie griby v ekstremalnyh usloviyah [Melanincontaining fungi under extreme conditions]. Kyiv: Naukova dumka [in Russian].

Korinovska, O.M., Hryshko, V.M. (2011). Chutlyvist mikromitsetiv do vazhkykh metaliv [Sensitivity of micromycetes to heavy metals]. Visnyk Dnipropetrovskoho natsionalnoho universytetu. Biolohiia. Medytsyna — Bulletin of the Dnipropetrovsk National University. Biology. Medicine, 2 (2), 49–55 [in Ukrainian].

Hryshko, V.M., Korinovska, O.M., Bondarenko, A.M. (2012). Vydovyi sklad ta chyselnist mikromitsetiv u tekhnozemakh [Species composition and number of micromycetes in technozems]. Visnyk KhNAU — The Bulletin of Kharkiv National Agrarian University, 1(25), 70–77 [in Ukrainian].

Volkohon, V.V., Nadkernychna, O.V., Tokmakova, L.M. (2010). Eksperymentalna gruntova mikrobiolohiia: monohrafiia [Experimental soil microbiology: monograph]. Kyiv: Ahrarna nauka [in Ukrainian].

Bilay, V.I., Koval, E.Z. (1988). Aspergilly [Aspergillus]. Kyiv: Naukova dumka [in Russian].

Bilay, V.I. (1977). Fuzarii [Fusari]. Kyiv: Naukova dumka [in Russian].

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Published

2022-11-10

Issue

No. 4 (2022)

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Articles

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