Polycyclic aromatic hydrocarbons degradation by marine-derived basidiomycetes: optimization of the degradation process

ABSTRACT Pyrene and benzo[a]pyrene (BaP) are high molecular weight polycyclic aromatic hydrocarbons (PAHs) recalcitrant to microbial attack. Although studies related to the microbial degradation of PAHs have been carried out in the last decades, little is known about degradation of these environmental pollutants by fungi from marine origin. Therefore, this study aimed to select one PAHs degrader among three marine-derived basidiomycete fungi and to study its pyrene detoxification/degradation. Marasmiellus sp. CBMAI 1062 showed higher levels of pyrene and BaP degradation and was subjected to studies related to pyrene degradation optimization using experimental design, acute toxicity, organic carbon removal (TOC), and metabolite evaluation. The experimental design resulted in an efficient pyrene degradation, reducing the experiment time while the PAH concentration applied in the assays was increased. The selected fungus was able to degrade almost 100% of pyrene (0.08 mg mL-1) after 48 h of incubation under saline condition, without generating toxic compounds and with a TOC reduction of 17%. Intermediate metabolites of pyrene degradation were identified, suggesting that the fungus degraded the compound via the cytochrome P450 system and epoxide hydrolases. These results highlight the relevance of marine-derived fungi in the field of PAH bioremediation, adding value to the blue biotechnology.

Effect of Ca(2+)-channel blockers, Ca(2+)-ionophore and increased pyrene excimer formation on the microsomal glucose-6-phosphatase.

The dependence of microsomal glucose-6-phosphatase (G-6-Pase) activity on Ca2+ as well as the membrane lipid microviscosity was studied by the effect of Ca(2+)-channel blockers (namely verapamil and nifedipine), Ca(2+)-ionophore, A23187 and pyrene excimer formation. Channel blockers depressed the G-6-Pase and Ca(2+)-ATPase while the ionophore increased these activities. Dimethyl sulfoxide, a known membrane surface active agent showed no change. Ca(2+)-uptake into the membrane has expectedly been lowered by the channel blockers while the ionophores facilitated the ion flux. Excimer formation of the fluorescent probe, pyrene as an indicator of increased membrane fluidity, and microviscosity calculated from there on, showed that Ca(2+)- and lipid microenvironment in the membrane significantly influenced the activity of G-6-Pase. Membrane lipid composition such as phospholipid/cholesterol molar ratio which also indicates an increased membrane fluidity is markedly increased with the ionophore but decreased with the channel blockers, while protein/phospholipid ratio remained unchanged. Microsomal G-6-Pase is a multicomponent multifunctional protein. It is argued that Ca2+ may play the role of an obligatory cofactor not only for the hydrolysis of G-6-P (catalytic part of the enzyme) but also involved in the regulation of substrate and product transport in or out of the endoplasmic reticulum lumen.