Manganese Homeostasis Supports Stenotrophomonas maltophilia Oxidative Stress Defense and Replication in Acanthamoeba castellanii Phagosomes
- David Ojcius
- 14 minutes ago
- 1 min read
Highlights
The S. maltophilia MntH importer contributes to H2O2 resistance and intracellular survival
The Mn exporter MntP limits toxicity even at sub-inhibitory Mn²⁺ concentrations
The S. maltophilia MntR regulated genes include the extracytoplasmic TBDR-pTFP module
The TBDR-pTFP locus is specifically induced under combined Mn2+ and Fe2+ limitation
S. maltophilia Mn homeostasis is linked to iron availability and oxidative stress responses
ABSTRACT
Manganese homeostasis is essential for the environmental adaptability and pathogenic potential of Stenotrophomonas maltophilia, a bacterium that thrives across diverse and fluctuating environments. Here, we characterize the manganese homeostasis network of S. maltophilia strain Sm18, identifying a coordinated system that integrates conserved transporters with previously unrecognized candidate components. Central to this system is an MntR-controlled gene module that includes the canonical Mn²⁺ importer MntH and exporter MntP, together with a TonB-dependent receptor (TBDR) and a periplasmic thioredoxin-fold protein (pTFP), both representing novel protein families with restricted phylogenetic distribution. Transcriptomic analyses under varying Mn²⁺ and Fe²⁺ conditions revealed a tight interplay between these metals, highlighting the ferrophilic nature of S. maltophilia and the differential regulation of module components. Notably, the TBDR-pTFP locus is strongly induced under combined Mn2+ and Fe2+ limitation, suggesting a specialized role in metal acquisition under nutrient-restricted conditions. Functional analyses showed that MntP contributes to protection from Mn toxicity even at sub-inhibitory concentrations, whereas MntH supports growth under oxidative stress and promotes intracellular replication within Acanthamoeba castellanii phagosomes. Together, these findings identify a Mn-responsive module candidate associated with manganese homeostasis and provides new insight into mechanisms that support S. maltophilia adaptation to metal-limited and host-associated environments.
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