Details
Title
Some corrosive bacteria isolated from the technogenic soil ecosystem in Chernihiv city (Ukraine)Journal title
Studia QuaternariaYearbook
2021Volume
vol. 38Issue
No 2Affiliation
Tkachuk, Nataliia : Department of Biology, T.H. Shevchenko National University “Chernihiv Colehium”, Hetman Polubotok Str. 53, 14013, Chernihiv, Ukraine ; Zelena, Liubov : Department of Physiology of Industrial Microorganisms, Danylo Zabolotny Institute of Microbiology and Virology of the National Academy of Sciences of Ukraine, Acad. Zabolotny Str. 154, 03143 Kyiv, UkraineAuthors
Keywords
16S rRNA gene ; microbial induced corrosion ; phenotypic characteristicsDivisions of PAS
Nauki o ZiemiCoverage
101-108Publisher
Committee for Quaternary Research PAS ; Institute of Geological Sciences PASBibliography
Abdulina, D.R., Asaulenko, L.G., Purish, L.M., 2011. Dissemination of corrosive aggressive bacteria in soils of different biotopes (Rozpovsiudzhennia koroziino-ahresyvnykh bakterii u gruntakh riznykh biotopiv). Studia Biologica 5 (1), 11–16. (in Ukrainian).Agrawal, A., Vanbroekhoven, K., Lal, B., 2010. Diversity of culturable sulfidogenic bacteria in two oil-water separation tanks in the north-eastern oil fields of India. Anaerobe 16 (1), 12–18.
Ait-Langomazino, N., Sellier, R., Jonquet, G., Trescinski, M., 1991. Microbial degradation of bitumen. Experientia 6, 533–539.
AlAbbas, F.M., Williamson, Ch., Bhola, Sh.M., Spear, J.R., Olson, D.L., Mishra, B., Kakpovbia, A.E., 2013. Microbial Corrosion in Linepipe Steel Under the Influence of a Sulfate-Reducing Consortium Isolated from an Oil Field. Journal of Materials Engineering and Performance 22 (11), 3517–3529.
Amann, R.J., Stromley, J., Devereux, R., Key, R., Stahl, D.A., 1992. Molecular and microscopic identification of sulfate-reducing bacteria in multispecies biofilms. Applied and Environmental Microbiology 58, 614–623.
Andreyuk, E.I., Kozlova, I.A., Kopteva, Zh.P., Pilyashenko-Novokhatny, A.I., Zanina, V.V., Purish, L.M., 2002. Ferrosphere – formation zone corrosive community of microorganisms (Ferrosfera – zona formirovaniya korrozionno-aktivnogo soobschestva mikroorganizmov). Reports of the NAS of Ukraine 3, 157–161. (in Russian)
Andreyuk, K., Kozlova, I., Koptieva, Zh., Pilyashenko-Novokhatny, A., Zanina, V., Purish, L., 2005. Microbial Corrosion of Underground Structures, Naukova Dumka, Kyiv. (in Ukrainian with English summary).
Antonovskaya, N.S., Kozlova, I.A., Andreyuk, E.I., 1986. Thiobacillus thioparus – active agent in steel corrosion. Mikrobiologii Zhurnal 1, 36–41. (in Russian with English summary)
Aseeva, I.V., Babieva, I.P., Byzov, B.A., Goosev, V.S., Dobrovolskaya, T.G., Zvyagintsev, D.G., Zenova, G.M., Kozhevin, P.A., Kurakov, A.V., Lysak, L.V., Marfenina, O.E., Mirchink, T.G., Polyanskaya, L.M., Panikov, N.S., Skvortsova, I.N., Stepanov, A.L., Umarov, M.M., 1991. Methods of soil microbiology and biochemistry (Metodyi pochvennoy mikrobiologii i biohimii). In: Zvyagintsev, D.G. (Ed.), Moscow University Press, Moscow. (in Russian).
Bala, D.D., Chidambaram, D., 2014. Effect of anaerobic microbial corrosion on the surface film formed on steel. ECS Transactions 58 (41), 137–149.
Bano, A.Sh., Qazі, J.I., 2011. Soil Buried Mild Steel Corrosion by Bacillus cereus-SNB4 and its Inhibition by Bacillus thuringiensis- SN8. Pakistan Journal of Zoology 43 (3), 555–562.
Bergey’s Manual of Systematic Bacteriology, 2005. Second Edition, Volume 2, The Proteobacteria, Part C. The Alpha-, Beta-, Delta-, and Epsilonproteobacteria.Brenner, D.J., Krieg, N.R., Staley, J.T. et al., Springer, New York.
Bergey’s Manual of Systematic Bacteriology, 2009. Second edition, Volume 3, The Firmicutes. De Vos, P., Garrity, G.M., Jones, D., Krieg, N.R., Ludwig, W., Rainey, F.A., Schleifer, K.-H., Whitman, W.B. Springer, New York.
Bergey’s Manual of Systematic Bacteriology, 2012. Second edition, Volume 5, The Actinobacteria, Part A. Goodfellow, M., Kämpfer, P., Busse, H.-J., Trujillo, M.E., Suzuki, K.-I., Ludwig, W., Whitman, W.B. Springer, New York.
Beech, I.B., Gaylarde, Ch.C., 1999. Recent advances in the study of biocorrosion: an overview. Revista de Microbiologia 30 (3), 117– 190.
Bermont-Bouis, D., Janvier, M., Grimont, P.A., Dupont, I., Vallaeys, T., 2007. Both sulfate-reducing bacteria and Enterobacteriaceae take part in marine biocorrosion of carbon steel. Journal of Applied Microbiology 102, 161–168.
Bleich, R., Watrous, J.D., Dorrestein, P.C., Bowers, A.A., Shank, E.A., 2015. Thiopeptide antibiotics stimulate biofilm formation in Bacillus subtilis. Proceedings of the National Academy of Sciences (PNAS) 112 (10), 3086–3091.
Bolton, N., Critchley, M., Fabien, R., Cromar, N., Fallowfield, H., 2010. Microbially influenced corrosion of galvanized steel pipes in aerobic water systems. Journal of Applied Microbiology 109, 239–247.
Bragadeeswaran,S., Jeevapriya, R., Prabhu, K., Sophia Rani, S., Priyadharsini, S., Balasubramanian, T., 2011. Exopolysaccharide production by Bacillus cereus GU812900, a fouling marine bacterium. African Journal of Microbiology Research 5 (24), 4124–4132.
Capão, A., Moreira-Filho, P., Garcia, M., Bitati, S., Luciano Procópio, L., 2020. Marine bacterial community analysis on 316L stainless steel coupons by Illumina MiSeq sequencing. Biotechnology Letters 42, 1431–1448.
Costerton, J.W., Lewandowski, Z., Caldwell, D.E., Korber, D.R., Lappin- Scott, H.M. Microbial Biofilms, 1995. Annual Review of Microbiology 49, 711–745.
Du, J., Li, S., Liu, J., Yu, M., 2014. Corrosion behavior of steel Q235 co-influenced by Thiobacillus thiooxidans and Bacillus. Beijing Hangkong Hangtian Daxue Xuebao. Journal of Beijing University of Aeronautics and Astronautics 40 (1), 31–38.
Duque, Z., Ibars, J.R., Sarró, M.I., Moreno, D.A., 2011. Comparison of sulphide corrosivity of sulphate- and non-sulphate-reducing prokaryotes isolated from oilfield injection water. Materials and Corrosion 62 (9999), 1–7.
Engel, K., Ford, S.E., Coyotzi, S., McKelvie, J., Diomidis, N., Slater, G., Neufeld, J.D., 2019. Stability of Microbial Community Profiles Profiles Associated with Compacted Bentonite from the Grimsel Underground Research Laboratory. mSphere 4 (6) e00601-19. https://doi.org/10.1128/mSphere.00601-19
Giovannoni, S.J., Britschgi, T.B., Moyer, C.L., Field, K.G., 1990. Genetic diversity in Sargasso Sea bacterioplankton. Nature, 345, 60–63.
Herro, H.M., Port, R.D., 1993. The Nalco guide to cooling water system failure analysis, 1st ed., McGraw-Hill, New York, pp. 420.
Horn, J., Carrrillo, C., Dias, V., 2003. Comparison of the Microbial Community Composition at Yucca Mountain and Laboratory Test Nuclear Repository Environments. CORROSION ⁄2003 (San Diego, CA, March 16–20, 2003), Paper No. 03556. NACE International, Houston.
Ilhan-Sungur, Е., Ozuolmez, D., Çotuk, A., Cansever, N., Muyzer, G., 2017. Isolation of a sulfide-producing bacterial consortium from coolingtower water: Evaluation of corrosive effects on galvanized steel. Anaerobe 43, 27–34.
James, G.A., Beaudette, L., Costerton, J.W., 1995. Interspecies bacterial interactions in biofilm. The Journal of Industrial Microbiology and Biotechnology 15 (4), 237–262.
Jan-Roblero, J., Romero, J.M., Amaya, M., Le Borgne, S., 2004. Phylogenetic characterization of a corrosive consortium isolated from a sour gas pipeline. Applied Microbiology and Biotechnology 64, 862–867.
Jayaraman, A., Earthman, J.C., Wood, T.K., 1997. Corrosion inhibition by aerobic biofilms on SAE 1018 steel. Applied Microbiology and Biotechnology 47, 62–68.
Lane, D.G., 1991. Nucleic acids techniques in bacterial systematic. In: Stackebrandt, E., Goodfellow, M. (Eds), Nucleic Acid Techniques in Bacterial Systematic, John Wiley and Sons, New York, 115–175.
Lewandowski, Z., 2000. Structure and Function of Biofilms. In: Evans, L.V. (Ed.) Biofilms: Recent Advances in Their Study and Control, 1–17, Harwood Academic Publishers.
Li, X., Duan, J., Xiao, H., Li, Y., Liu, H., Guan, F., Zhai, X., 2017. Analysis of Bacterial Community Composition of Corroded Steel Immersed in Sanya and Xiamen Seawaters in China via Method of Illumina MiSeq Sequencing. Frontiers in microbiology 8, 1737.
Lopez, M.A., Serna, F.J.Z., Jan-Roblero, J., Romero, J.M., Hernandez- Rodriguez, C., 2006. Phylogenetic analysis of a biofilm bacterial population in a water pipeline in the Gulf of Mexico. FEMS Microbiology Ecology 58, 145–154.
Lovley, D.R., Phillips, E.J.P., 1988. Novel mode of microbial energy metabolism: organic carbon oxidation coupled to dissimilatory reduction of iron or manganes, Applied and Environmental Microbiology 54 (6), 1472–1480.
Magot, M., Ravot, G., Campaignolle, X., Ollivier, B., Patel, B.K., Fardeau, M.L., Thomas, P., Crolet, J.L., Garcia, J.L., 1997. Dethiosulfovibrio peptidovorans gen. Nov., sp. Nov., a new anaerobic, slightly halophilic, thiosulfate-reducing bacterium from corroding offshore oil wells. International Journal of Systematic and Evolutionary Microbiology 47, 818–824.
Methods of general bacteriology: in three volumes (Metodyi obschey mikrobiologii), 1984. Gerhardt, F. et al. (Ed.), 3, Mir, Moscow. (in Russian).
Monroy, O.A.R., Gayosso, M.J.H., Ordaz, N.R., Olivares, G.Z., Ramírez, C.J., 2011. Corrosion of API XL 52 steel in presence of Clostridium celerecrescens. Materials and Corrosion 62 (9), 878–883.
Neria-Gonzalez, I., Wang, E.T., Ramirez, F., Romero, J.M., Hernandez- Rodriguez, C., 2006. Characterization of bacterial community associated to biofilms of corroded oil pipelines from the southeast of Mexico. Anaerobe 12, 122–133.
Nnabuk Eddy Okon, 2010. Fermentation product of Streptomyces griseus (albomycin) as a green inhibitor for the corrosion of zinc in H2SO4. Green Chemistry: Letters and Reviews 3 (4), 307–314.
Nuňez, M., 2007. Prevention of metal corrosion: new research. Nova Science Publishers, Inc., New York, pp. 310.
Okabe ,S., Odagiri, M., Ito, T., Satoh, H., 2007. Succession of sulfur- oxidizing bacteria in the microbial community on corroding concrete in sewer systems. Applied and Environmental Microbiology 73, 971–980.
Oliveira, V.M., Lopes-Oliveira, P.F., Passarini, M.R.Z., Menezes, C.B.A., Oliveira, W.R.C., Rocha, A.J., Sette, L.D., 2011. Molecular analysis of microbial diversity in corrosion samples from energy transmission towers. Biofouling 27 (4), 435–447.
Pacheco da Rosa, J., Korenblum, E., Franco-Cirigliano, M.N., Abreu, F., Lins, U., Soares, R.M.A., Macrae, A., Seldin, L., Coelho, R.R.R., 2013. Streptomyces lunalinharesii Strain 235 Shows the Potential to Inhibit Bacteria Involved in Biocorrosion Processes. Hindawi Publishing Corporation BioMed Research International, Article ID 309769.
Pacheco da Rosa, J., Tiburcio, S.R.G., Marques, J.M., Seldin, L., Coelho, R.R.R., 2016. Streptomyces lunalinharesii 235 prevents the formation of a sulfate-reducing bacterial biofilm. Brazilian journal of microbiology 47, 603–609.
Pavissich, J.P., Vargas, I.T., Gonzalez, B., Pasten, P.A., Pizarro, G.E., 2010. Culture dependent and independent analyses of bacterial communities involved in copper plumbing corrosion. Journal of Applied Microbiology 109, 771–782.
Pope, D.H., Duquette, D.J., Johannes, A.H., Wayner, P.C., 1984. Microbially influenced corrosion of industrial alloys. Materials Performance 23 (4), 14–15.
Pilyashenko-Novokhatny, A.I., 2000. Possible distribution of functions between the components of corrosion-hazardous aggregates of microorganisms in the general process of microbially induced corrosion (Mozhlyvyi rozpodil funktsii mizh skladovymy koroziinonebezpechnymy sukupnostiamy mikroorhanizmiv v zahalnomu protsesi mikrobno indukovanoi koroziii). Materials IV International. Conference-exhibitions “Problems of corrosion and anticorrosion. Protection of materials” (Corrosion-200). G.V. Karpenko Physical-Mechanical Institute of the National Academy of Sciences of Ukraine, Lviv. 564–567. (in Ukrainian)
Plohinskij, N.A., 1970. Biometrics (Biometriya). Izdatel’stvo Moskovskogo universiteta, Moskva. (in Russian)
Purish, L.M., Asaulenko, L.G., 2007. Dynamics of succession changes in sulfidogenic microbial association under conditions of biofilm formation on the surface of steel. Mikrobiologii Zhurnal 69 (6), 19‑25. (in Ukrainian with English summary)
Purish, L.M., Asaulenko, L.G., Ostapchuk, A.M., 2009. Features of development of mono- and associative cultures of sulfate-reducing bacteria and formation of exopolymer complex. Mikrobiologii Zhurnal 71 (2), 20–26. (in Ukrainian with English summary)
Qiu, Y.-Y., Guo, J.-H., Zhang, L., Chen, G.-H., Jiang, F., 2017. A highrate sulfidogenic process based on elemental sulfur reduction: cost-effectiveness evaluation and microbial community analysis. Biochemical Engineering Journal 128, 26–32.
Rajasekar, A., Ting, Y.-P., 2010. Microbial Corrosion of Aluminum 2024 Aeronautical Alloy by Hydrocarbon Degrading Bacteria Bacillus cereus ACE4 and Serratia marcescens ACE2. Industrial & Engineering Chemistry Research 49, 6054–6061.
Romanenko, V.I., Kuznetsov, S.I., 1974. Ecology of microorganisms of fresh reservoirs (Ekologiya mikroorganizmov presnyih vodoemov), Nauka, Leningrad. (in Russian).
Salgar-Chaparro, S.J., Darwin, A., Kaksonen, A.H., Machuca, L.L., 2020. Carbon steel corrosion by bacteria from failed seal rings at an offshore facility. Scientific reports 10 (1), 12287. https://doi.org/10.1038/s41598-020-69292-5
Salgar-Chaparro, S.J., Silva-Plata, B.A., 2008. Caracterizacion de la comunidad microbiana residente en aguas de produccion de tres campos de explotacion petrolera, con especial enfasis en grupos asociados a procesos corrosivos. Proyecto. Universidad Industrial de Santander. (in Spanish with English summary)
Satoh, H., Odagiri, M., Ito, T., Okabe, S., 2009. Microbial community structures and in situ sulfate-reducing and sulfur-oxidizing activities in biofilms developed on mortor specimens in a corroded sewer system. Water Research 43, 4729–4739.
Stahl, D.A., Lane, D.I., Olsen, G.L., Pace, N.R., 1984. Analysis of hydrothermal vent-associated symbionts by ribosomal RNA sequences. Science, 224, 409–411.
Su, H., Mi, Sh., Peng, X., Han, Y., 2019. The mutual influence between corrosion and the surrounding soil microbial communities of buried petroleum pipelines. RSC Advances 9, 18930–18940.
Tamura, K., Stecher, G., Peterson, D., Filipski, A., Kumar, S., 2013. MEGA6: Molecular Evolutionary Genetics Analysis version 6.0. Molecular Biology and Evolution 30 (12), 2725–2729.
Tkachuk, N., Zelena, L., Mazur, P., Lukash, O., 2020. Genotypic, physiological and biochemical features of Desulfovibrio strains in a sulfidogenic microbial community isolated from the soil of ferrosphere. Ecological questions 31 (2), 79–88.
Tkachuk, N.V., Zelena, L.B., Parmynska, V.S., Yanchenko, V.O., Demchenko, A.M., 2017. Identification of heterotrophic soil ferrosphere bacteria and their sensitivity to the pesticide linuron, Mikrobiologii Zhurnal 9 (4), 75–87. (in Ukrainian with English summary).
Vaschenko, I.M., Lange, K.P., Merkulov, M.P., 1982. Workshop on the basics of rural farming (Praktikum po osnovam selskogo hazyaystva), Prosveschenie, Moskva. (in Russian).
Vincke, E., Boon, N., Verstraete, W., 2001. Analysis of the microbial communities on corroded concrete sewer pipes – a case. Applied Microbiology and Biotechnology 57, 776–785.
Wang, Y.S., Liu, L., Fu, Q., Sun, J., An, Z.Y., Ding, R., Li, Y., Zhao, X.D., 2020. Effect of Bacillus subtilis on corrosion behavior of 10MnNiCrCu steel in marine environment. Scientific Reports 10, 5744. http://dx.doi.org/10.1038/s41598-020-62809-y
Zhu, X., Lubeck, J., Kilbane II J.J., 2003. Characterization of microbial communities in gas industry pipelines. Applied and Environmental Microbiology 69, 5354–5363.
Date
2021.12.05Type
ArticleIdentifier
DOI: 10.24425/sq.2021.136826Abstracting & Indexing
Studia Quaternaria is indexed in the following database:Arianta
Bibliography and Index of Geology - GeoRef
Celdes
CNPIEC
EBSCO
EBSCO Discovery Service
Google Scholar
J-Gate
Naviga (Softweco)
Primo Central (ExLibris)
Summon (Serials Solutions/ProQuest)
TDOne (TDNet)
WorldCat (OCLC)