Abstract
ABSTRACT Penicillium ochrochloron was used in the past for the leaching of zinc from a zinc oxide containing filter dust via excreted organic acids. Organic acid excretion by P. ochrochloron was stimulated by the addition of an extracellular buffer (2-(N-Morpholino)ethanesulfonic acid, MES; or zinc oxide, ZnO: ZnO + 2 H+ → Zn2+ + H2O). It was tested if the buffer stimulated excretion of organic acid anions is due to the necessity of an anion efflux across the plasma membrane to maintain electroneutrality by balancing the excretion of protons by the H+-ATPase. This charge balance hypothesis was previously postulated for P. ochrochloron. Two strains of P. ochrochloron were studied, which differed in growth parameters and amount of excreted organic acids. From the results, it was concluded that charge balance at the plasma membrane is not the main reason for organic acid excretion in these two strains of P. ochrochloron. Furthermore, the phenomenon of reuptake of excreted organic acids in the presence of about 100 mM of glucose is confirmed. It is suggested that the equilibrium between extracellular and intracellular organic acid anions may be maintained passively by a facilitated diffusion transporter.
Highlights
Organic acid production by filamentous fungi is of high relevance within the field of fungal biotechnology (Magnuson and Lasure 2004; Sauer, Porro and Mattanovich 2008)
It was concluded that charge balance at the plasma membrane is not the main reason for organic acid excretion in these two strains of P. ochrochloron
P. ochrochloron CBS 123824, was identical to the strain used in that former study, as it was a frozen aliquot of the spore suspension from that time
Summary
Organic acid production by filamentous fungi is of high relevance within the field of fungal biotechnology (Magnuson and Lasure 2004; Sauer, Porro and Mattanovich 2008). In P. ochrochloron the excretion of citrate and other organic acids was stimulated by and depended on extracellular parameters such as buffers (zinc oxide (ZnO), 2-(NMorpholino)ethanesulfonic acid (MES), HEPES, phthalic acid; Received: 25 June 2019; Accepted: 3 March 2020 C FEMS 2020.
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