Abstract
Manganese biomineralization is a widespread process among bacteria and fungi. To date, there is no conclusive experimental evidence for how and if this process impacts microbial fitness in the environment. Here, we show how a model organism for manganese oxidation is growth inhibited by nitrite, and that this inhibition is mitigated in the presence of manganese. We show that such manganese-mediated mitigation of nitrite inhibition is dependent on the culture inoculum size, and that manganese oxide (MnOX) forms granular precipitates in the culture, rather than sheaths around individual cells. We provide evidence that MnOX protection involves both its ability to catalyze nitrite oxidation into (nontoxic) nitrate under physiological conditions and its potential role in influencing processes involving reactive oxygen species (ROS). Taken together, these results demonstrate improved microbial fitness through MnOX deposition in an ecological setting, i.e., mitigation of nitrite toxicity, and point to a key role of MnOX in handling stresses arising from ROS.IMPORTANCE We present here a direct fitness benefit (i.e., growth advantage) for manganese oxide biomineralization activity in Roseobacter sp. strain AzwK-3b, a model organism used to study this process. We find that strain AzwK-3b in a laboratory culture experiment is growth inhibited by nitrite in manganese-free cultures, while the inhibition is considerably relieved by manganese supplementation and manganese oxide (MnOX) formation. We show that biogenic MnOX interacts directly with nitrite and possibly with reactive oxygen species and find that its beneficial effects are established through formation of dispersed MnOX granules in a manner dependent on the population size. These experiments raise the possibility that manganese biomineralization could confer protection against nitrite toxicity to a population of cells. They open up new avenues of interrogating this process in other species and provide possible routes to their biotechnological applications, including in metal recovery, biomaterials production, and synthetic community engineering.
Highlights
Manganese biomineralization is a widespread process among bacteria and fungi
Through systematic analysis of medium composition, we have created a minimal defined medium that supports AzwK-3b growth (Table 1) and that has revealed the requirement for five specific vitamin supplements for growth
Manganese biomineralization into manganese oxide (MnOX) is widespread among bacteria, but there is no clarity about its possible functional roles
Summary
Manganese biomineralization is a widespread process among bacteria and fungi. To date, there is no conclusive experimental evidence for how and if this process impacts microbial fitness in the environment. It has been suggested that certain fungi employ ligand-stabilized MnIII to oxidize recalcitrant litter [16], but these studies were not performed with single (defined) carbon/energy sources The latter hypothesis regarding the protective potential of MnOX remains unproven to date for metal toxicity [2, 7]. Strain AzwK-3b’s cellular and excreted proteome is shown to be different when grown in the presence or absence of Mn, while it is notable that the heme peroxidase described above was not found to be differentially expressed [28] It is currently not clear how and if the metabolically costly process of extracellular Mn oxidation benefits individual cells and how it could have been maintained over evolutionary time scales
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