OIL DEGRADATION BY BACTERIA ISOLATED FROM BOTTOM SEDIMENTS OF THE KARA SEA SHELF AND THE BAIKAL LAKE

The activity of microorganisms isolated from the bottom sediments of the Kara Sea shelf and Lake Baikal in the process of oil degradation was evaluated in a model experiment. Under low temperature (+10°С) and mineralization from 0 to 30 g/L (sodium chloride) the reduced conversion of n-alkanes in the cultivation of bacteria from the Kara Sea (less than 30%) and higher activity of Baikal microorganisms community (conversion up to 95%) were revealed. The response of bacterial communities to the change in the mineralization of the medium is selective: nonsignificant result of the influence on n-alkanes degradation in the cultivation of the Kara Sea strains, and a sharp acceleration of conversion of the oil alkane fraction in the cultivation of Baikal microorganisms under 7,0 to 15 g/L of sodium chloride in the medium. The effect of synergism during oil degradation under conditions of co-cultivation of the strains from Lake Baikal and the Kara Sea is inappreciable.

oil-oxidizing microorganisms, the Kara Sea, the Baikal Lake, n-alkanes, oil

1. Atlas Bajkala [Atlas of the Baikal Lake] / Pod red. G.I. Galaziya. Moskva: Sibirskoe otdelenie AN SSSR, Mezhvedomstvennyj sovet programmy «Sibir», Federal’naya sluzhba geodezii i kartografii, 1993. 160 с. (in Russian).

2. Atlas R.M. Effects of hydrocarbons on microorganisms and biodegradation in Arctic ecosystems in Petroleum Effects in the Arctic Environment / Ed. F.R. Engelhardt. UK, London: Elsevier, 1985. P. 63–99.

3. Gorshkov A.G., Marinayte I.I., Zemskaya T.I., Khodzher T.V. Sovremennyj uroven’ nefteproduktov v vode ozera Bajkal i ego pritokov [Actual concentrations of oil products in water of the Baikal Lake and its tributaries] // Himiya v interesah ustojchivogo razvitiya. 2010. V. 18. P. 711–718 (in Russian).

4. Gramberg I.S. Arkticheskij shel’f – budushchee neftegazovoj promyshlennosti Rossii [The Arctic shelf as a future of the oil and gas industry of Russia] / I.S. Gramberg, O.I. Suprunenko // Arktika na poroge tret’ego tysyacheletiya (resursnyj potencial i problemy ehkologii). SPb.: Nauka, 2000. P. 133–144 (in Russian).

5. Gramberg I.S., Sorokov D.S., Suprunenko O.I. Neftegazovye resursy Rossijskogo shel’fa [Oil and gas resources of the Russian shelf] // Prospect and protection of mineral resources. 1993. № 8. P. 8–11 (in Russian).

6. Haines J.R., Kadkhodayan M., Mocsny D.J., Jones C.A., Islam M., Venosa A.D. Effect of salinity, oil type, and incubation temperature on oil degradation. International symposium on in situ and on-site bioreclamation. USA: San Diego, 1993. P. 75–83.

7. Harris R.F. Effect of water potential on microbial growth and activity / Eds J.F. Parr, W.R. Gardner, L.F. Elliott. Madison: Soil Science Society of America, 1981. P. 23–95.

8. Hirsch R., Bezdek R., Wendling R. Peaking of world oil production and its mitigation // American Institute of Chemical Engineers Journal. 2006. V. 52. № 1. P. 1–7.

9. Kontorovich A.E., Kashirtsev V.A., Moskvin V.I., Burshtein L.M., Zemskaya T.I., Kostyreva E.A., Kalmychkov G.V., Khlystov O.M. Neftegazonosnost otlozhenij ozera Bajkal [Petroleum potential of the Baikal Lake] // Russian Geol. Geophys. 2007. V. 48. P. 1046–1053 (in Russian).

10. Lane D. J.16S/23S rRNA sequencing. Wiley: New York, 1991. P. 115–175.

11. Liu J., Bacosa H.P., Liu Z. Potential environmental factors affecting oil-degrading bacterial populations in deep and surface waters of the Northern Gulf of Mexico // Front. Microbiol. 2017. V. 7. 2131 р.

12. Mamaeva E.V., Galach’yants Y.P., Khabudaev K.V., Petrova D.P., Pogodaeva T.V., Khodzher T.B., Zemskaya T.I. Metagenomnyj analiz mikrobialnyh soobschestv donnyh osadkov shelfa Karskogo moray i Enisejskogo zaliva [Metagenomic analysis of microbial communities of bottom sediments of the Kara Sea Shelf and the Yenisei Bay] // Microbiology. 2016. V. 85. № 2. P. 187–198 (in Russian).

13. McGenity T.J. Halophilic hydrocarbon degraders / Ed. K.N. Timmis. Berlin: Springer-Verlag, 2010. P. 1939–1951.

14. McMillen S.J., Requejo A.G., Young G.N., Davis P.S., Cook P.D., Kerr J.M., Gray N.R. Bioremediation potential of crude oil spilled on soil / Eds. R.E. Hinchee, C.M. Vogel, F.J. Brockman. San Diego: Battelle Press, 1995. P. 91–99.

15. Michel J., Hayes M.O. Weathering patterns of oil residues eight years after the Exxon Valdez oil spill // Mar. Poll. Bull. 1999. V. 38. № 10. P. 855–863.

16. Pavlova O.N., Lomakina A.V., Gorshkov A.G., Suslova M.Y., Likhoshvai A.V., Zemskaya T.I. Mikrobnye soobschestva i ih sposobnost okislyat n-alkany v rajone razgruzki gazoneftesoderzhaschih fluidov v Srednem Baikale (mys Gorevoj Utes) [Microbial communities and their ability to oxidize n-alkanes in the area of release of gas- and oil-containing fluids in mid-Baikal (Cape Gorevoi Utes)] // Biol. Bull. 2012. V. 39. № 5. P. 458–463 (in Russian).

17. Pavlova O.N., Zemskaya T.I., Gorshkov A.G., Kostornova T.Y., Parfenova V.V. Sravnitelnaya harakteristika mikrobnyh soobschestv dvuh rajonov estestvennyh nefteproyavlenij ozera Baikal [Comparative characterization of microbial communities in two regions of natural oil seepage in the Baikal Lake] // Biol. Bull. 2008a. V. 35. № 3. P. 287–293 (in Russian).

18. Pavlova O.N., Zemskaya T.I., Gorshkov A.G., Parfenova V.V., Suslova M.Y., Khlystov O.M. Issledovanie mikrobnogo soobschestva ozera Baikal v rajone estestvennyh nefteproyavlenij [Study on the Lake Baikal microbial community in the areas of the natural oil seeps] // Appl. Biochem. Microbiol. 2008b. V. 44. № 3. P. 287–291 (in Russian).

19. Piccolo L.L., Pasquale C.D., Fodale R., Puglia A.M., Quatrini P. Involvement of an alkane hydroxylase system of Gordonia sp. Strain SoCg in degradation of solidn-alkanes // Appl. Environ. Microbiol. 2011. V. 77. № 4. P. 1204–1213.

20. Pogodaeva T.V. Zemskaya T.I., Golobokova L.P., Khlystov O.M., Minami H., Sakagami H. Osobennosti himicheskogo sostava porovyh vod donnyh otlozhenij razlichnyh rajonov ozera Baikal [Specific features of the chemical composition of pore waters of bottom sediments in different Baikal basins] // Russ. Geol. Geophys. 2007. V. 48. P. 886–900 (in Russian).

21. Rike A.G., Bшrresen M., Instanes A. Response of cold-adapted microbial populations in a permafrost profile to hydrocarbon contaminants // Polar Record. 2001. V. 37. № 202. Р. 239–248.

22. Rochelle P.A. DNA extraction for 16S rRNA gene analysis to determine genetic diversity in deep sediment communities // FEMS Microbiol. Lett. 1992. V. 100. P. 59–66.

23. Rojo F. Degradation of alkanes by bacteria // Environ. Microbiol. 2009. V. 11. № 10. P. 2477–2490.

24. Sambrook J., Fritsch E.F., Maniatis T. Molecular Cloning. New York: Cold Spring Harbor, 1989. 545 p.

25. Sei K., Mori K., Kohno T., Maki H. Development and application of PCR primers for monitoring alkane-degrading bacteria in seawater microcosm during crude oil degradation process // Journal of Chemical Engineering of Japan. 2003. V. 36. № 10. P. 1185–1193.

26. Smits T.H.M., Balada S.B., Witholt B., van Beilen J.B. Functional analysis of alkane hydroxylases from gram-negative and gram-positive bacteria // J. Bacteriol. 2002. V. 184. P. 1733–1742.

27. van Beilen J.B., Funhoff E.G. Alkane hydroxylses involved in microbial alkane degradation // Appl. Microbiol. Biotechnol. 2007. V. 74. № 1. P. 13–21.

28. Walworth J., Braddock J.F., Woolard C. Nutrient and temperature interactions in bioremediation of cryic soils // Cold Regions Science and Technology. 2001. V. 32. № 2–3. P. 85–91.

29. Whyte L.G., Goalen B., Hawari J., Labbe D., Greer C.W., Nahir M. Bioremediation treatability assessment of hydrocarboncontaminated soils from Eureka, Nunavut // Cold Reg. Sci. Technol. 2001. V. 32. P. 121–132.