Regulation of Reactive Nitrogen Species (RNS) Metabolism and Resistance Mechanisms in Haemophilus influenzae: A Dissertation

Haemophilus influenzae encounters niches within the human host that are predicted to differ in availability of oxygen and reactive nitrogen species (RNS: nitrite and nitric oxide), which influence the environmental redox state. Previously reported data has indicated that an altered redox condition could serve as a signal recognized by H. influenzae to optimize its survival within host microenvironments. To elucidate the role of redox signaling in virulence, we examined regulation by the FNR homolog of H. influenzae, whose counterpart in E. coli has been reported to be a direct oxygen sensor and a regulator of genes responsible for RNS metabolism and resistance. Many members of the FNR regulon are subject to coordinated transcriptional control by NarP, a regulator in E. coli that is activated by cognate sensor NarQ in response to environmental nitrite. To study the regulatory activities of FNR and NarQ-NarP in H. influenzae, I targeted a gene predicted to be FNR-regulated, nrfA, which encodes nitrite reductase, a periplasmic cytochrome-c involved in anaerobic respiration. The fnr, narP and nrfA mutants were assayed for nitrite reduction, which implicated the roles of FNR, NarP and NrfA in RNS metabolism. Using Western blot detection of an epitope-tagged reporter protein fused to the endogenous nrf promoter (Pnrf-HA), I demonstrate that FNR and NarP, but not NarQ, are required for full activation of the nrf promoter. Additionally, Pnrf-HA expression increases as oxygen becomes depleted and decreases when exposed to high concentrations of nitrite, implying that the nrf promoter is modulated by environmental