INFLUENCE OF VANADIUM ON THE GROWTH AND METABOLISM OF COPRINELLUS TRUNCORUM FUNGAL MYCELIUM

M. Žižić, M. Živić, Kristina Atlagić, M. Karaman, J. Zakrzewska
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Abstract

Fungi could absorb heavy metals, metalloids, or radionuclides, thus fungal species possess great potential in bioremediation. Since fungi absorb the vanadium, in the present study ability of Coprinellus truncorum mycelia for vanadate uptake and its intracellular metabolism were investigated. The submerged cultivated C. truncorum was exposed to a rising concentration of vanadate. 31P NMR spectroscopy was used to investigate phosphate metabolism of the mycelium, while the status of vanadium in the cell was followed by 51V NMR spectroscopy. The mycelium could grow, and overcome vanadate presence, up to the concentration of 1.6 mM in the submerged medium. 31P NMR measurements pointed out that vanadate induced changes in the concentration of the crucial metabolite containing phosphorus, particularly sugar phosphates. The major result of vanadate action is evinced through an appearance of a signal positioned at around 2.8 ppm, and an increased signal of hexose- phosphates. Using 51V NMR spectroscopy the presence of vanadate monomer in the mycelia of the fungal cell was confirmed.
钒对干菇真菌菌丝体生长和代谢的影响
真菌可以吸收重金属、类金属或放射性核素,因此真菌在生物修复方面具有很大的潜力。由于真菌对钒的吸收作用,本研究主要研究了干菇菌丝对钒酸盐的吸收能力及其在细胞内的代谢能力。潜水栽培的干茎暴露于浓度升高的钒酸盐中。采用31P核磁共振波谱法研究菌丝的磷酸盐代谢,51V核磁共振波谱法跟踪细胞内钒的状态。菌丝在浸没培养基中可以生长,并克服钒酸盐的存在,浓度可达1.6 mM。31P核磁共振测量指出,钒酸盐引起了含磷的关键代谢物浓度的变化,特别是糖磷酸盐。钒酸盐作用的主要结果通过定位在2.8 ppm左右的信号的出现和己糖-磷酸盐的信号增加来证明。利用51V核磁共振谱证实了该真菌菌丝中钒酸盐单体的存在。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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