Comparative transcriptomic analysis of Stenotrophomonas sp. MNB17 revealed mechanisms of manganese tolerance at different concentrations and the role of histidine biosynthesis in manganese removal

Bacteria possess protective mechanisms against excess Mn(II) to reduce its toxicity. Stenotrophomonas sp. MNB17 showed high Mn(II) removal capacity (92.24-99.16 %) by forming Mn-precipitates (MnCO3 and Mn-oxides), whose Mn-oxides content increased with increasing Mn(II) concentrations (10-50 mM). Compared with 0 mM Mn(II)-stressed cells, transcriptomic analysis identified genes with the same transcriptional trends in 10 mM and 50 mM Mn(II)-stressed cells, including genes involved in metal transport, cell envelope homeostasis, and histi-dine biosynthesis, as well as genes with different transcriptional trends, such as those involved in oxidative stress response, glyoxylate cycle, electron transport, and protein metabolism. The upregulation of histidine biosyn-thesis and oxidative stress responses were the most prominent features of these metabolisms under Mn(II) stress. We confirmed that the increased level of reactive oxygen species was one of the reasons for the increased Mn-oxides formation at high Mn(II) concentrations. Metabolite analysis indicated that the enhanced histidine biosynthesis rather than the tricarboxylic acid cycle resulted in an elevated level of alpha-ketoglutarate, which helped eliminate reactive oxygen species. Consistent with these results, the exogenous addition of histidine significantly reduced the production of reactive oxygen species and Mn-oxides and enhanced the removal of Mn(II) as MnCO3. This study is the first to correlate histidine biosynthesis, reactive oxygen species, and Mn-oxides formation at high Mn(II) concentrations, providing novel insights into the molecular regulatory mechanisms associated with Mn(II) removal in bacteria.

Automated summary

This study investigates the mechanism of Mn(II) removal by bacteria and identifies the upregulation of histidine biosynthesis and oxidative stress response as important features. The increased level of reactive oxygen species is found to contribute to the formation of Mn-oxides. The addition of histidine enhances Mn(II) removal. These findings provide novel insights into the molecular regulatory mechanisms associated with Mn(II) removal in bacteria.