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Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus laterosporus 301/İK3-2

Year 2023, Volume: 51 Issue: 3, 317 - 325, 16.07.2023
https://doi.org/10.15671/hjbc.1256836

Abstract

Siderophores are secondary metabolites released into the environment by various microorganisms, fungi, and plants to chelate iron from the surrounding environment. It is known that siderophores bind to other metals besides iron. Today, heavy metals, which are released as an undesirable result of industrial development, accumulate at high rates and pose a significant threat to biological living things. In this sense, remediation of heavy metal-contaminated sites is an urgent requirement. Siderophores are promising agents for the removal of heavy metals from natural habitats with the role of bioremediation.
In this study, the effect of heavy metals on the growth and siderophore production of Brevibacillus laterosporus was investigated. Maximum siderophore production was determined as 50 % at 48 h in the metal-free growth media. In addition, maximum siderophore production was determined for various heavy metals including 5 μM Hg2+, 0.5 mM Ni2+, 0.1 mM Co2+, and 2.5 μM Fe2+. Intracellular uptake of the mercury was also measured using optical emission spectroscopy and compared with siderophore production values of the B. laterosporus. The maximum biosorption of mercury was measured to be 40% in 5 μM Hg2+-containing media at 48 h of incubation. The results show that siderophore production is affected by uptake of various metals, and are usable for removing of heavy metals from environmental habitats.

References

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  • M.G.P. Page, The role of iron and siderophores in infection, and the development of siderophore antibiotics, Clin. Infect. Dis., 69 (2019) S529.
  • K.N. Raymond, B.E. Allred, A.K. Sia, Coordination chemistry of microbial iron transport, Acc. Chem. Res., 48 (2015) 2496–2505.
  • J. Kramer, Ö. Özkaya, R. Kümmerli, Bacterial siderophores in community and host interactions, Nat. Rev. Microbiol., 18 (2020) 152.
  • C. Meifang, N. Ryo, O. Tetsuya, M. Keisuke, Mercury removal and recovery by immobilized Bacillus megaterium MB1, Front. Chem. Sci. Eng., 6 (2012) 192–197.
  • C.M.H. Ferreira, A. Vilas-Boas, C.A. Sousa, H.M.V.M. Soares, E.V. Soares, Comparison of five bacterial strains producing siderophores with ability to chelate iron under alkaline conditions, AMB Expr., (2019) 9:78.
  • M. Heldal, S. Norland, O. Tumyr, X-ray microanalytic method for measurement of dry matter and elemental content of individual bacteria, Environ. Microbiol. 50 (1985) 1251–1257.
  • G.W. Bryan, Some aspects of heavy metal tolerance in aquatic organisms. In: A.P.M. Lockwood (Ed.), Effects of pollutants on aquatic organisms, Cambridge University Press., (1976) UK: 7-34.
  • M.J. Smith, J. N. Shoolery, B. Schwyn, I. Holden, J.B. Neilands, Rhizobactin, a structurally novel siderophore from Rhizobium meliloti, J. Am. Chem. Soc., 107 (1985) 1739-1743.
  • S.M. Payne, Detection, isolation, and characterization of siderophores, Meth. Enzymol., 235 (1994) 329–344.
  • S.M. Payne, Iron and virulence in the family Enterobacteriaceae, Crit. Rev. Microbiol., 16 (1988) 81–111.
  • L.E. Arnow, Colorimetric determination of the components of 3,4 dihydroxyphenylalaninetyrosine mixtures, J. Biol. Chem., 118 (1937) 531-537.
  • Z.T. Csaky, On the estimation of bound hydroxylamine in biological materials, Acta Chem. Scand., 2 (1948) 450-454.
  • E.I. Yılmaz, Metal tolerance and biosorption capacity of Bacillus circulans strain EB1, Res. Microbiol., 154 (2003) 409–415.
  • B.E. Kalinowski, L.J. Liermann, S. Givens, S.L. Brantley, Rates of bacteria-promoted solubilization of Fe from minerals: A review of problems and approaches, Chem. Geol., 169 (2000) 357–370.
  • A. Ranganathan, V.N. Shruthi, R. Thilagaraj, Heavy metal tolerance of Bacillus sp. isolated from lignite, Bachelor of technology thesis, (2008) SRM University.
  • A. Bagg, J.B. Neilands, Ferric uptake regulation protein acts as a repressor, employing iron (II) as a cofactor to bind the operator of an iron transport operon in Escherichia coli, Biochem., 26 (1987) 5471-5477.
  • D. Rachid, B. Ahmed, Effect of iron and growth inhibitors on siderophores production by Pseudomonas fluorescens, AJB, 4 (2005) 697–702.
  • B. Kräutler, Cobalt: B12 enzymes and coenzymes, EIBC, (2004) 1–26.
  • Y. Bi, D.L. Hesterberg, O.W. Duckworth, Siderophore-promoted dissolution of cobalt from hydroxide minerals, GCA, 74 (2010) 2915–2925.
  • K. Schauer, B. Gouget, M. Carrière, A. Labigne, H. De Reuse, Novel nickel transport mechanism across the bacterial outer membrane energized by the TonB/ExbB/ExbD machinery, Mol. Microbiol., 63 (2007) 1054–1068.
  • C.L. Washington-Hughes, G.T. Ford, A.D. Jones, M. Kimberly, F.W. Outten, Nickel exposure reduces enterobactin production in Escherichia coli, MicrobiologyOpen, 8 (2019) e00691.
  • M. Priyadarshanee, S. Chatterjee, S. Rath, H.R. Dash, S. Das, Cellular and genetic mechanism of bacterial mercury resistance and their role in biogeochemistry and bioremediation, J. Hazard Mater. 5;423 (2022) 126985.
Year 2023, Volume: 51 Issue: 3, 317 - 325, 16.07.2023
https://doi.org/10.15671/hjbc.1256836

Abstract

References

  • B. Khasheii, P. Mahmoodi, A. Mohammadzadeh, Siderophores: Importance in bacterial pathogenesis and applications in medicine and industry, Microbiol. Res., 250 (2001) 126790.
  • M.G.P. Page, The role of iron and siderophores in infection, and the development of siderophore antibiotics, Clin. Infect. Dis., 69 (2019) S529.
  • K.N. Raymond, B.E. Allred, A.K. Sia, Coordination chemistry of microbial iron transport, Acc. Chem. Res., 48 (2015) 2496–2505.
  • J. Kramer, Ö. Özkaya, R. Kümmerli, Bacterial siderophores in community and host interactions, Nat. Rev. Microbiol., 18 (2020) 152.
  • C. Meifang, N. Ryo, O. Tetsuya, M. Keisuke, Mercury removal and recovery by immobilized Bacillus megaterium MB1, Front. Chem. Sci. Eng., 6 (2012) 192–197.
  • C.M.H. Ferreira, A. Vilas-Boas, C.A. Sousa, H.M.V.M. Soares, E.V. Soares, Comparison of five bacterial strains producing siderophores with ability to chelate iron under alkaline conditions, AMB Expr., (2019) 9:78.
  • M. Heldal, S. Norland, O. Tumyr, X-ray microanalytic method for measurement of dry matter and elemental content of individual bacteria, Environ. Microbiol. 50 (1985) 1251–1257.
  • G.W. Bryan, Some aspects of heavy metal tolerance in aquatic organisms. In: A.P.M. Lockwood (Ed.), Effects of pollutants on aquatic organisms, Cambridge University Press., (1976) UK: 7-34.
  • M.J. Smith, J. N. Shoolery, B. Schwyn, I. Holden, J.B. Neilands, Rhizobactin, a structurally novel siderophore from Rhizobium meliloti, J. Am. Chem. Soc., 107 (1985) 1739-1743.
  • S.M. Payne, Detection, isolation, and characterization of siderophores, Meth. Enzymol., 235 (1994) 329–344.
  • S.M. Payne, Iron and virulence in the family Enterobacteriaceae, Crit. Rev. Microbiol., 16 (1988) 81–111.
  • L.E. Arnow, Colorimetric determination of the components of 3,4 dihydroxyphenylalaninetyrosine mixtures, J. Biol. Chem., 118 (1937) 531-537.
  • Z.T. Csaky, On the estimation of bound hydroxylamine in biological materials, Acta Chem. Scand., 2 (1948) 450-454.
  • E.I. Yılmaz, Metal tolerance and biosorption capacity of Bacillus circulans strain EB1, Res. Microbiol., 154 (2003) 409–415.
  • B.E. Kalinowski, L.J. Liermann, S. Givens, S.L. Brantley, Rates of bacteria-promoted solubilization of Fe from minerals: A review of problems and approaches, Chem. Geol., 169 (2000) 357–370.
  • A. Ranganathan, V.N. Shruthi, R. Thilagaraj, Heavy metal tolerance of Bacillus sp. isolated from lignite, Bachelor of technology thesis, (2008) SRM University.
  • A. Bagg, J.B. Neilands, Ferric uptake regulation protein acts as a repressor, employing iron (II) as a cofactor to bind the operator of an iron transport operon in Escherichia coli, Biochem., 26 (1987) 5471-5477.
  • D. Rachid, B. Ahmed, Effect of iron and growth inhibitors on siderophores production by Pseudomonas fluorescens, AJB, 4 (2005) 697–702.
  • B. Kräutler, Cobalt: B12 enzymes and coenzymes, EIBC, (2004) 1–26.
  • Y. Bi, D.L. Hesterberg, O.W. Duckworth, Siderophore-promoted dissolution of cobalt from hydroxide minerals, GCA, 74 (2010) 2915–2925.
  • K. Schauer, B. Gouget, M. Carrière, A. Labigne, H. De Reuse, Novel nickel transport mechanism across the bacterial outer membrane energized by the TonB/ExbB/ExbD machinery, Mol. Microbiol., 63 (2007) 1054–1068.
  • C.L. Washington-Hughes, G.T. Ford, A.D. Jones, M. Kimberly, F.W. Outten, Nickel exposure reduces enterobactin production in Escherichia coli, MicrobiologyOpen, 8 (2019) e00691.
  • M. Priyadarshanee, S. Chatterjee, S. Rath, H.R. Dash, S. Das, Cellular and genetic mechanism of bacterial mercury resistance and their role in biogeochemistry and bioremediation, J. Hazard Mater. 5;423 (2022) 126985.
There are 23 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Fatma İnci Özdemir 0000-0003-0818-103X

Bahadır Aydın 0009-0005-2108-0403

Ahmet Tülek 0000-0003-1079-7837

Early Pub Date July 16, 2023
Publication Date July 16, 2023
Acceptance Date June 8, 2023
Published in Issue Year 2023 Volume: 51 Issue: 3

Cite

APA Özdemir, F. İ., Aydın, B., & Tülek, A. (2023). Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus laterosporus 301/İK3-2. Hacettepe Journal of Biology and Chemistry, 51(3), 317-325. https://doi.org/10.15671/hjbc.1256836
AMA Özdemir Fİ, Aydın B, Tülek A. Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus laterosporus 301/İK3-2. HJBC. July 2023;51(3):317-325. doi:10.15671/hjbc.1256836
Chicago Özdemir, Fatma İnci, Bahadır Aydın, and Ahmet Tülek. “Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus Laterosporus 301/İK3-2”. Hacettepe Journal of Biology and Chemistry 51, no. 3 (July 2023): 317-25. https://doi.org/10.15671/hjbc.1256836.
EndNote Özdemir Fİ, Aydın B, Tülek A (July 1, 2023) Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus laterosporus 301/İK3-2. Hacettepe Journal of Biology and Chemistry 51 3 317–325.
IEEE F. İ. Özdemir, B. Aydın, and A. Tülek, “Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus laterosporus 301/İK3-2”, HJBC, vol. 51, no. 3, pp. 317–325, 2023, doi: 10.15671/hjbc.1256836.
ISNAD Özdemir, Fatma İnci et al. “Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus Laterosporus 301/İK3-2”. Hacettepe Journal of Biology and Chemistry 51/3 (July 2023), 317-325. https://doi.org/10.15671/hjbc.1256836.
JAMA Özdemir Fİ, Aydın B, Tülek A. Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus laterosporus 301/İK3-2. HJBC. 2023;51:317–325.
MLA Özdemir, Fatma İnci et al. “Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus Laterosporus 301/İK3-2”. Hacettepe Journal of Biology and Chemistry, vol. 51, no. 3, 2023, pp. 317-25, doi:10.15671/hjbc.1256836.
Vancouver Özdemir Fİ, Aydın B, Tülek A. Investigation of the Siderophore Production and Associated Heavy Metal Accumulation Potential of Brevibacillus laterosporus 301/İK3-2. HJBC. 2023;51(3):317-25.

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