Functional characterization of seven γ-Glutamylpolyamine synthetase genes and the bauRABCD locus for polyamine and β-Alanine utilization in Pseudomonas aeruginosa PAO1.

Pseudomonas aeruginosa and many other bacteria can utilize biogenic polyamines, including diaminopropane (DAP), putrescine (Put), cadaverine (Cad), and spermidine (Spd), as carbon and/or nitrogen sources. Transcriptome analysis in response to exogenous Put and Spd led to the identification of a list of genes encoding putative enzymes for the catabolism of polyamines. Among them, pauA1 to pauA6, pauB1 to pauB4, pauC, and pauD1 and pauD2 (polyamine utilization) encode enzymes homologous to Escherichia coli PuuABCD of the γ-glutamylation pathway in converting Put into GABA. A series of unmarked pauA mutants was constructed for growth phenotype analysis. The results revealed that it requires specific combinations of pauA knockouts to abolish utilization of different polyamines and support the importance of γ-glutamylation for polyamine catabolism in P. aeruginosa. Another finding was that the list of Spd-inducible genes overlaps almost completely with that of Put-inducible ones except the pauA3B2 operon and the bauABCD operon (β-alanine utilization). Mutation analysis led to the conclusion that pauA3B2 participate in catabolism of DAP, which is related to the aminopropyl moiety of Spd, and that bauABCD are essential for growth on β-alanine derived from DAP (or Spd) catabolism via the γ-glutamylation pathway. Measurements of the pauA3-lacZ and bauA-lacZ expression indicated that these two promoters were differentially induced by Spd, DAP, and β-alanine but showed no apparent response to Put, Cad, and GABA. Induction of the pauA3 and bauA promoters was abolished in the bauR mutant. The recombinant BauR protein was purified to demonstrate its interactions with the pauA3 and bauA regulatory regions in vitro. In summary, the present study support that the γ-glutamylation pathway for polyamine utilization is evolutionarily conserved in E. coli and Pseudomonas spp. and is further expanded in Pseudomonas to accommodate a more diverse metabolic capacity in this group of microorganisms.