Among these three receptors, only HgbA is required for virulence in the human model of chancroid, and HgbA alone is both necessary Selleck Temsirolimus and sufficient for heme/iron acquisition by H. ducreyi [30, 31]. Thus, H. ducreyi expresses several redundant mechanisms for acquiring this essential nutrient, and any contribution of OmpP4 to heme/iron uptake, like those of TdhA or TdX, is likely secondary to the activity of HgbA. H. influenzae e (P4) is necessary for utilization of the essential coenzyme NAD + (V factor). Members of the Pasteurellaceae cannot synthesize NAD + de

novo and must salvage either NAD + or a suitable Nutlin-3a supplier nicotinamide-based precursor from their environment [32]. So-called V-factor dependent Pasteurellaceae can only utilize NAD + or the precursors nicotinamide mononucleotide (NMN) or nicotinamide riboside (NR) [33, 34]. This NAD + salvage pathway is well characterized in H. influenzae [32, 34]: NAD+, NMN, Crenolanib chemical structure and NR pass through porins into the periplasm, where NAD + is converted to NMN by the enzyme NadN, and NMN is converted to NR primarily through the catalytic activity of e (P4) [17, 21, 35]. The inner membrane transporter PnuC then transports NR into the cytoplasm, where the enzyme NadR converts NR to NAD + [36, 37]. In contrast to H. influenzae, V-factor independent Pasteurellaceae, such as H. ducreyi, can utilize the precursor nicotinamide (NAm) to synthesize NAD + [34].

In this alternative salvage pathway, NAm diffuses across the cell wall into the cytoplasm, where the nicotinamide phosphoribosyltransferase NadV converts NAm to NMN, which is then

converted to NAD + by an unidentified NMN adenylyltransferase [32, 38]. Critical to this alternative salvage Paclitaxel chemical structure pathway is the enzyme NadV; in H. ducreyi strains, the nadV gene is carried on extrachromosomal or integrated copies of plasmid pNAD1, suggesting horizontal transfer of nadV [38, 39]. Strain 35000HP, used to generate the ompP4 mutant, contains two tandem, chromosomal copies of pNAD1 [39]. A previous study reported that H. ducreyi 35000HP encodes a complete H. influenzae-like NAD + salvage pathway [37]. However, at that time the H. ducreyi genome and its annotation were only available in preliminary form. Our analysis of the finalized H. ducreyi 35000HP genome showed that, while 35000HP includes full-length ORFs predicted to encode intact homologs of e (P4) (ompP4) and the NR transporter PnuC (HD1041), the homologs of nadN and nadR are pseudogenes. H. influenzae NadR is a bifunctional enzyme whose C-terminus contains NMN adenylyltransferase activity [37]. Possibly, the 3’ end of the H. ducreyi nadR pseudogene may express a truncated NadR with this activity. Alternatively, an as-yet-unidentified enzyme is required to convert NMN to NAD + in H. ducreyi. Overall, the absence of intact nadN and nadR genes suggests that the H. influenzae-like NAD + salvage pathway is dispensible in H. ducreyi because of NadV-driven utilization of NAm.