Physiological role and complex regulation of O-reducing enzymes in the obligate anaerobe .

UNLABELLED

, the major cause of antibiotic-associated diarrhea, is a strict anaerobic, sporulating Firmicutes. However, during its infectious cycle, this anaerobe is exposed to low oxygen (O) tensions, with a longitudinal decreasing gradient along the gastrointestinal tract and a second lateral gradient with higher O tensions in the vicinity of the cells. A plethora of enzymes involved in oxidative stress detoxication has been identified in , including four O-reducing enzymes: two flavodiiron proteins (FdpA and FdpF) and two reverse rubrerythrins (revRbr1 and revRbr2). Here, we investigated the role of the four O-reducing enzymes in the tolerance to increasing physiological O tensions and air. The four enzymes have different, yet overlapping, spectra of activity. revRbr2 is specific to low O tensions (<0.4%), FdpA to low and intermediate O tensions (0.4%-1%), revRbr1 has a wider spectrum of activity (0.1%-4%), and finally FdpF is more specific to tensions > 4% and air. These different O ranges of action partly arise from differences in regulation of expression of the genes encoding those enzymes. Indeed, we showed that is under the dual control of σ and σ. We also identified a regulator of the Spx family that plays a role in the induction of and genes upon O exposure. Finally, is regulated by Rex, a regulator sensing the NADH/NAD ratio. Our results demonstrate that the multiplicity of O-reducing enzymes of is associated with different roles depending on the environmental conditions, stemming from a complex multi-leveled network of regulation.

IMPORTANCE

The gastrointestinal tract is a hypoxic environment, with the existence of two gradients of O along the gut, one longitudinal anteroposterior decreasing gradient and one proximodistal increasing from the lumen to the epithelial cells. O is a major source of stress for an obligate anaerobe such as the enteropathogen . This bacterium possesses a plethora of enzymes capable of scavenging O and reducing it to HO. In this work, we identified the role of the four O-reducing enzymes in the tolerance to the physiological O tensions faced by during its infectious cycle. These four enzymes have different spectra of action and protect the vegetative cells over a large range of O tensions. These differences are associated with a distinct regulation of each gene encoding those enzymes. The complex network of regulation is crucial for to adapt to the various O tensions encountered during infection.