Ecological implications of anaerobic
nitrate turnover by isolate An-4 Aspergillus terreus is a common and globally occurring soil fungus that is also known from substrates as diverse as air, salterns, capybara droppings, lung of pocket mice, corn, cotton plants, milled rice, muesli, and wall paint [39]. The species has been reported from marine and associated habitats, such as mangroves and soft corals, and isolates from these habitats have been widely investigated for the production of bioactive compounds [40–42]. A. terreus has also been isolated from the hypersaline water of the Dead Sea [43, 44]. The species is an important human pathogen causing bronchopulmonary aspergillosis and disseminated infections [45]. Dissimilatory NO3 – reduction by human-associated microorganisms has been demonstrated [46, 47], but it is not known whether fungi are selleck chemicals involved. A. terreus is also of considerable biotechnological interest because it produces a wide diversity
of secondary metabolites that find pharmaceutical applications, biotechnologically Adriamycin clinical trial relevant compounds such as itaconic acid and itatartaric acid, as well as mycotoxins that are important for food safety ( [39] and references therein). The wide habitat spectrum of A. terreus might be significantly expanded by the ability for dissimilatory NO3 – reduction in the absence of O2. This fungus has the potential to survive hypoxic or anoxic conditions that prevail in aquatic sediments mostly just a few millimeters below the surface [48] or even
directly at the surface when O2 concentrations are low in the water column [12, 49]. In contrast, NO3 – originating from the water column and/or the nitrification layer at the sediment surface diffuses deeper into the sediment than O2 does [50]. In shallow sediments, NO3 –rich water is introduced into even deeper layers by mixing forces such as bioturbation, bioirrigation, and ripple movement [51, 52]. The sediment habitat in which A. terreus can thrive is further expanded by its NO3 – storage capability. The maximum intracellular NO3 – content of 8 μmol g-1 protein theoretically sustains dissimilatory NO3 – reduction without extracellular NO3 – supply for 2–4.5 days (calculated from rates measured in the 15N-labeling experiment). Survival and mTOR inhibitor growth beyond this time frame will depend on the ability of A. terreus to repeatedly access NO3 – in its natural sediment habitat, which is currently unknown. The dissimilatory NO3 – reduction activity of An-4 leads to the production and release of NH4 +, N2O, and NO2 -. Thus, unlike the denitrification and anammox activities of other microorganisms, the anaerobic NO3 – metabolism of An-4 cannot directly lead to fixed nitrogen removal. Since the major product of NO3 – reduction is NH4 +, An-4 merely converts one form of fixed nitrogen into another one.