Copper ion sorption ability of Alternaria alternata (Fr.) Keissl. and Fusarium oxysporum Schltdl. micromycetes

Our analysis of metabolic and ecological features of fungi indicates a high bioremediation potential of fungal mycelium. The relevance of the problems solved in this work is conditioned by insufficiently studied mechanisms and conditions of micromycetal activity on heavy metal detoxication. The effect of copper on the development of two micromycete species, namely, melanised Alternaria alternata (Fr.) Keissl., 1912 and hyaline  Fusarium oxysporum Schltdl., 1824 cultivated on Czapek agar (with 2 or 3% sucrose) was compared;  the ability of mycelium to sorb copper cations when grown in a liquid culture with 0, 0.05, 0.1, 0.25, and 0.5 mg Cu²⁺ / L was evaluated. F. oxysporum had noticeable advantages in terms of  growth rate, tolerance, conidia production on medium with Cu2+. The effective concentration of copper (EC₅₀), indicating the resistance of the fungus, increased for  F. oxysporum by 1.5 times with increasing sucrose content in the medium. The melanised culture of  A. alternata  was superior to  F. oxysporum in terms of sorption capacity. The percentage of Cu²⁺ extraction by fungal mycelium from the medium reached 40% in the case of  F. oxysporum and twice as much in the case of  A. alternata . The vast majority of copper was sorbed by the cell walls of hyphae and washed away by water. A small amount (a maximum of 0.16 µg Cu²⁺ /g dry mycelium of  A. alternate ) penetrated inside the mycelial cells. F. oxysporum, which had no intracellular protective melanins, accumulated Cu²⁺ (2 to 14 times) less. The results show that the mechanisms of resistance to Cu²⁺ and sorption are different in the studied species: in Fusarium they are  determined mainly by the barrier functions of hyphae cell walls, while in Alternaria melanin plays a significant role in protection against Cu toxic action.

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