Bioleaching Ability of Fungi Isolated from an Indonesian Sulfurous River Sediment

https://doi.org/10.22146/ijc.44810

Serafica Btari Christiyani Kusumaningrum(1), I Wayan Warmada(2), Wahyu Wilopo(3), Endah Retnaningrum(4*)

(1) Graduate Student of Biology Faculty, Universitas Gadjah Mada, Jl. Teknika Selatan, Sekip Utara, Yogyakarta 55281, Indonesia
(2) Department of Geological Engineering, Faculty of Engineering, Universitas Gadjah Mada, Jl. Grafika No. 2, Yogyakarta 55281, Indonesia
(3) Department of Geological Engineering, Faculty of Engineering, Universitas Gadjah Mada, Jl. Grafika No. 2, Yogyakarta 55281, Indonesia
(4) Faculty of Biology, Universitas Gadjah Mada, Jl. Teknika Selatan, Sekip Utara, Yogyakarta 55281, Indonesia
(*) Corresponding Author

Abstract


The unique characteristics of sulfurous river sediment located in Ungaran, Indonesia, are a reservoir of novel fungi with manganese bioleaching properties. Fungi are known to produce metabolic organic acids that have a potential for the industrial application of leaching metal from the ores. This application has high advantages, including low cost, low energy, and creates minimal environmental damage. Therefore, this research was performed to analyze the manganese bioleaching activities of two fungal isolates (KA2B2 and KB4B) from Indonesian sulfurous river sediment on pyrolusite and determine their phenotypic characters. These activities were investigated in terms of changes in fungal biomass, soluble manganese concentration, pH reduction, and organic acid production during 16 days of leaching. Soluble manganese concentrations were measured by atomic absorption spectrometry (AAS), whereas organic acid concentrations were analyzed by high-performance liquid chromatography (HPLC). According to bioleaching investigations, KA2B2 strain was more efficient than KB4B1 strain in extracting manganese from 0.02 g/cm3 pyrolusite. It also produced higher levels of organic acids, such as oxalic acid and citric acid, than KB4B1 strain, proving that strain of KA2B2 could be used to extract manganese from pyrolusite. Based on the phenotypic characters, both strains were identified as genus Penicillium.

Keywords


pyrolusite; soluble manganese; oxalic acid; citric acid

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References

[1] Fonti, V., Dell’anno, A., and Beolchini, F., 2016, Does bioleaching represent a biotechnological strategy for remediation of contaminated sediments?, Sci. Total Environ., 563-564, 302–319.

[2] Pathak, A., Morrison, L., and Healy, M.G., 2017, Catalytic potential of selected metal ions for bioleaching, and potential techno-economic and environmental issues: A critical review, Bioresour. Technol., 229, 211–221.

[3] Gu, T., Rastegar, S.O., Mousavi, S.M., Li, M., and Zhou, M., 2018, Advances in bioleaching for recovery of metals and bioremediation of fuel ash and sewage sludge, Bioresour. Technol., 261, 428–440.

[4] Retnaningrum, E., and Wilopo, W., 2019, Pyrolusite bioleaching by an indigenous Acidithiobacillus sp. KL3 isolated from an Indonesian sulfurous river sediment, Indones. J. Chem., 19 (3), 712–719.

[5] Vázquez-Campos, X., Kinsela, A.S., Waite, T.D., Collins, R.N., and Neilan, B.A., 2014, Fodinomyces uranophilus gen. nov. sp. nov. and Coniochaeta fodinicola sp. nov., two uranium mine-inhabiting Ascomycota fungi from northern Australia, Mycologia, 106 (6), 1073–1089.

[6] Ivarsson, M., Bengtson, S., and Neubeck, A., 2016, The igneous oceanic crust – Earth's largest fungal habitat?, Fungal. Ecol., 20, 249–255.

[7] Gadd, G.M., 2017, Fungi, rocks and minerals, Elements, 13 (3), 171–176.

[8] Ferreira, P.C., Pupin, B., and Rangel, D.E.N., 2018, Stress tolerance of soil fungal communities from native Atlantic forests, reforestations, and a sand mining degraded area, Fungal Biol., 122 (6), 400–409.

[9] Madrigal-Arias, J.E., Argumedo-Delira, R., Alarcón, A., Mendoza-López, M.R., García-Barradas, O., Cruz-Sánchez, J.S., Ferrera-Cerrato, R., and Jiménez-Fernández, M., 2015, Bioleaching of gold, copper and nickel from waste cellular phone PCBs and computer gold finger motherboards by two Aspergillus niger strains, Braz. J. Microbiol., 46 (3), 707–713.

[10] Kim, M.J., Seo, J.Y., Choi, Y.S., and Kim, G.H., 2016, Bioleaching of spent Zn-Mn or Ni-Cd batteries by Aspergillus species, Waste Manage., 51, 168–173.

[11] Bahaloo-Horeh, N., Mousavi, S.M., and Baniasadi, M., 2018, Use of adapted metal tolerant Aspergillus niger to enhance bioleaching efficiency of valuable metals from spent lithium-ion mobile phone batteries, J. Cleaner Prod., 197, 1546–1557.

[12] Li, Q., Csetenyi, L., Paton, G.I., and Gadd, G.M., 2015, CaCO3 and SrCO3 bioprecipitation by fungi isolated from calcareous soil, Environ. Microbiol., 17 (8), 3082–3097.

[13] Grum-Grzhimaylo, A.A., Georgieva, M.L., Bondarenko, S.A., Debets, A.J.M., and Bilanenko, E.N., 2016, On the diversity of fungi from soda soils, Fungal Divers., 76, 27–74.

[14] Boldt-Burisch, K., and Naeth, M.A., 2017, Early colonization of root associated fungal communities on reclamation substrates at a diamond mine in the Canadian Sub-Arctic, Appl. Soil Ecol., 110, 118–126.

[15] Xu, H.B., Tsukuda, M., Takahara, Y., Sato, T., Gu, J.D., and Katayama, Y., 2018, Lithoautotrophical oxidation of elemental sulfur by fungi including Fusarium solani isolated from sandstone Angkor temples, Int. Biodeterior. Biodegrad., 126, 95–102.

[16] Gholipour, S., Mehrkesh, P., Azin, E., Nouri, H., Rouhollahi, A.A., and Moghimi, H., 2018, Biological treatment of toxic refinery spent sulfidic caustic at low dilution by sulfur-oxidizing fungi, J. Environ. Chem. Eng., 6 (2), 2762–2767.

[17] Şener, B., Aksoy, D.Ö., Çelik, P.A., Toptaş, Y., Koca, S., Koca, H., and Çabuk, A., 2018, Fungal treatment of lignites with higher ash and sulphur contents using drum type reactor, Hydrometallurgy, 182, 64–74.

[18] Sutcliffe, B., Chariton, A.A., Harford, A.J., Hose, G.C., Greenfield, P., Midgley, D.J., and Paulsen, I.T., 2018, Diverse fungal lineages in subtropical ponds are altered by sediment-bound copper, Fungal Ecol., 34, 28–42.

[19] Mehta, K.D., Das, C., Kumar, R., Pandey, B.D., and Mehrotra, S.P., 2010, Effect of mechano-chemical activation on bioleaching of Indian Ocean nodules by a fungus, Miner. Eng., 23 (15), 1207–1212.

[20] Chiang, Y.W., Santos, R.M., Monballiu, A., Ghyselbrecht, K., Martens, J.A., Mattos, M.L.T., Van Gerven, T., and Meesschaert, B., 2013, Effects of bioleaching on the chemical, mineralogical and morphological properties of natural and waste-derived alkaline materials, Miner. Eng., 48, 116–125.

[21] Khayatian, G., Moradi, M., and Hassanpoor, S., 2018, MnO2/3MgO nanocomposite for preconcentration and determination of trace copper and lead in food and water by flame atomic absorption spectrometry, J. Anal Chem., 73, 470–478.

[22] Vilanova, L., Viñas, I., Torres, R., Usall, J., Buron-Moles, G., and Teixidó, N., 2014, Acidification of apple and orange hosts by Penicillium digitatum and Penicillium expansum, Int. J. Food Microbiol., 178, 39–49.

[23] Gillot, G., Jany, J.L., Poirier, E., Maillard, M.B., Debaets, S., Thierry, A., Coton, E., and Coton, M., 2017, Functional diversity within the Penicillium roqueforti species, Int. J. Food Microbiol., 241, 141–150.

[24] Pitt, J.I., and Hocking, A.D., 2009, Fungi and Food Spoilage, Springer, Boston, MA.

[25] Visagie, C.M., Houbraken, J., Frisvad, J.C., Hong, S.B., Klaassen, C.H.W., Perrone, G., Seifert, K.A., Varga, J., Yaguchi, T., and Samson, R.A., 2014, Identification and nomenclature of the genus Penicillium, Stud. Mycol., 78, 343–371.

[26] Golmohammadzadeh, R., Faraji, F., and Rashchi, F., 2018, Recovery of lithium and cobalt from spent lithium ion batteries (LIBs) using organic acids as leaching reagents: A review, Resour. Conserv. Recycl., 136, 418–435.

[27] Qu, Y., Lian, B., Mo, B., and Liu, C., 2013, Bioleaching of heavy metals from red mud using Aspergillus niger, Hydrometallurgy, 136, 71–77.

[28] Xu, T.J., Ramanathan, T., and Ting, Y.P., 2014, Bioleaching of incineration fly ash by Aspergillus niger – precipitation of metallic salt crystals and morphological alteration of the fungus, Biotechnol. Rep., 3, 8–14.

[29] Mohanty, S., Ghosh, S., Nayak, S., and Das, A.P., 2017, Bioleaching of manganese by Aspergillus sp. isolated from mining deposits, Chemosphere, 172, 302–309.

[30] Panda, S.K., Mishra, S.S., Kayitesi, E., and Ray, R.C., 2016, Microbial-processing of fruit and vegetable wastes for production of vital enzymes and organic acids: Biotechnology and scopes, Environ. Res., 146, 161–172.

[31] Liu, J., Li, J., Shin, H., Liu, L., Du, G., and Chen, J., 2017, Protein and metabolic engineering for the production of organic acids, Bioresour. Technol., 239, 412–421.

[32] Yang, L., Lübeck, M., and Lübeck, P.S., 2017, Aspergillus as a versatile cell factory for organic acid production, Fungal Biol. Rev., 31 (1), 33–49.

[33] Xia, M.C., Bao, P., Liu, A.J., Zhang, S.S., Peng, T.J., Shen, L., Yu, R.L., Wu, X.L., Li, J.K., Liu, Y.D., Chen, M., Qiu, G.Z., and Zeng, W.M., 2018, Isolation and identification of Penicillium chrysogenum strain Y5 and its copper extraction characterization from waste printed circuit boards, J. Biosci. Bioeng., 126 (1), 78–87.



DOI: https://doi.org/10.22146/ijc.44810

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