Golian Marcel, Hegedűsová Alžbeta, Mezeyová Ivana, Chlebová Zuzana, Hegedűs Ondrej, Urminská Dana, Vollmannová Alena, Chlebo Peter
Institute of Horticulture, Faculty of Horticulture and Landscape Engineering, Slovak University of Agriculture in Nitra, Tr. A. Hlinku 2, 949 76 Nitra, Slovakia.
AgroBioTech Reseach Centre, Slovak University of Agriculture in Nitra, Tr. A. Hlinku 2, 949 76 Nitra, Slovakia.
Foods. 2021 Dec 29;11(1):76. doi: 10.3390/foods11010076.
The species is a commercially, gastronomically, and biotechnologically important fungus. Its strain variability has been little researched. The study provides an evaluation of 59 oyster mushroom production strains in terms of the ability to accumulate selected metals in the cap and stipe. The fruiting bodies were grown under identical model conditions on straw substrate. Metal concentrations (ET-AAS) in dry fruiting bodies ranged in values 1.7-22.4 mg kg for Al, 2.6-9.7 mg kg Ba, 199-4560 mg kg Ca, 1.7-12.0 mg kg Cu, 12-120 mg kg Fe, 16,000-49,500 mg kg K, 876-2400 mg kg Mg, 0.39-11.0 mg kg Mn, 46-920 mg kg Na and 11-920 mg kg for Zn. More Cu, Fe, K, Mg, Mn, Zn accumulated in the cap, while in the stipe Ba was amassed. No significant difference was found between Al, Ca and Na between the accumulation in the cap and the stipe. Furthermore, the dependence of metal uptake from the substrate depending on the fortification of the substrate was confirmed. Statistically significant ( < 0.05) synergistic relationships were shown in pairs Al and Ba, Al and Fe, Ba and Na, Ba and Ca, Ca and Na, Cu and Fe, Fe and Mn, Fe and Zn, K and Mg, K and Mn, K and Zn, Mg and Mn, Mg and Na, Mg and Zn and Mn and Zn in the substrate without the addition of sodium selenate to the substrate. Altered relationships were observed after the application of sodium selenate to the substrate, synergism of Se and Ni, Se and Co and Se and Hg, Cu and Mn, Cu and Fe, Zn and Co, Zn and Ni, Zn and Hg, Mn and Fe, Mn and Cr, Co and Ni, Co and Hg, Ni and Hg, Pb and Cd. The findings of the study may help in the selection of production strains with hypercumulative properties for a particular metal and subsequent use in the addition of fortified fruiting bodies (e.g., with Zn). Based on the study the strains less sensitive to the accumulation of hazardous metals is possible to select for large-scale production, which is important from the perspective of food safety.
该物种是一种在商业、美食和生物技术方面都很重要的真菌。其菌株变异性研究较少。本研究评估了59种平菇生产菌株在菌盖和菌柄中积累特定金属的能力。子实体在相同的模型条件下于秸秆基质上生长。干子实体中的金属浓度(电热原子吸收光谱法):铝为1.7 - 22.4毫克/千克,钡为2.6 - 9.7毫克/千克,钙为199 - 4560毫克/千克,铜为1.7 - 12.0毫克/千克,铁为12 - 120毫克/千克,钾为16000 - 49500毫克/千克,镁为876 - 2400毫克/千克,锰为0.39 - 11.0毫克/千克,钠为46 - 920毫克/千克,锌为11 - 920毫克/千克。菌盖中积累的铜、铁、钾、镁、锰、锌更多,而菌柄中积累的是钡。菌盖和菌柄中铝、钙和钠的积累没有显著差异。此外,还证实了从基质中吸收金属对基质强化的依赖性。在未向基质中添加亚硒酸钠的情况下,基质中铝和钡、铝和铁、钡和钠、钡和钙、钙和钠、铜和铁、铁和锰、铁和锌、钾和镁、钾和锰、钾和锌、镁和锰、镁和钠、镁和锌以及锰和锌之间呈现出具有统计学意义(<0.05)的协同关系。向基质中添加亚硒酸钠后观察到关系发生了变化,硒与镍、硒与钴以及硒与汞、铜与锰、铜与铁、锌与钴、锌与镍、锌与汞、锰与铁、锰与铬、钴与镍、钴与汞、镍与汞、铅与镉之间呈现协同作用。该研究结果可能有助于选择对特定金属具有超积累特性的生产菌株,并随后用于添加强化子实体(如含锌的子实体)。基于该研究,可以选择对有害金属积累不太敏感的菌株用于大规模生产,这从食品安全的角度来看很重要。
