Litcius/Paper detail

Iron Or Zinc Bioaccumulated In Mycelial Biomass Of Edible Basidiomycetes

Suzana Harue Umeo, Maria Graciela Iecher Faria, Douglas Cardoso Dragunski, Juliana Silveira do Valle, Nelson Barros Colauto, Giani Andréa Linde

2020Anais da Academia Brasileira de Ciências17 citationsDOIOpen Access PDF

Abstract

Iron and zinc bioaccumulation in mycelial biomass of different medicinal basidiomycetes was evaluated in order to produce metal-enriched mycelial biomass as an alternative functional food from non-animal sources and based on biotechnology processes. Pleurotus ostreatus strain U2-9, U2-11, U6-8, and U6-9, Pleurotus eryngii strain U8-11, Schizophyllum commune strain U6-7, and Lentinula edodes strain U6-11 and U6-12 were grown in malt extract agar with or without addition of 50 mg/L iron or 7.5 mg/L zinc. The mycelial biomass was separated and iron and zinc concentrations were determined in a flame atomic absorption spectrophotometer. Basidiomycete strains presented different growth rates with the presence of iron and zinc; there was no dependence between the metal bioaccumulation and the fungal growth. The fungi presented greater capacity to bioaccumulate iron than zinc. P. ostreatus (U2-9) has greater iron bioaccumulation (3197.7 mg/kg) while P. ostreatus (U6-8) greater zinc bioaccumulation (440.4 mg/kg) in mycelial biomass. P. ostreatus (U2-9), P. ostreatus (U2-11), and S. commune (U6-7) had the highest metal translocation rates from the culture medium to mycelial biomass. The mycelial biomass enriched with iron or zinc is an alternative to a new functional food from non-animal sources.

Topics & Concepts

Pleurotus ostreatusBioaccumulationMyceliumZincFood scienceChemistryBotanyBiomass (ecology)Environmental chemistryBiologyMushroomAgronomyOrganic chemistryFungal Biology and ApplicationsMycorrhizal Fungi and Plant InteractionsPhytochemistry and Bioactivity Studies