Involvement of the alginate algT gene and integration host factor in the regulation of the Pseudomonas aeruginosa algB gene

Abstract

Strains of Pseudomonas aeruginosa causing pulmonary infection in cystic fibrosis patients are often mucoid because of the synthesis of a capsular polysaccharide called alginate. Regulation of alginate biosynthesis includes the algB gene product (AlgB), which belongs to a class of proteins that control gene transcription in response to environmental stimuli. In this study, a homolog of the DNA-binding-and-bending protein integration host factor (IHF) and the positive regulatory gene algT were shown to be involved in algB expression. An algB-cat gene fusion was constructed on a low-copy-number, broad-host-range plasmid. In alginate-producing (Alg+) P. aeruginosa, levels of chloramphenicol acetyltransferase from algB-cat were twofold higher than in spontaneous Alg- or algT::Tn501 mutant strains, indicating that the mucoid status of the cell influences algB transcription. An algB transcription initiation site was identified 286 nucleotides upstream of translation initiation and revealed an Escherichia coli sigma 70-like promoter. Sequences in the algB promoter region were highly similar to the consensus E. coli IHF binding site. In DNA gel band mobility shift assays, a protein present in extracts from IHF+ E. coli strains and IHF purified from E. coli bound specifically to these algB DNA fragments, while extracts prepared from isogenic IHF- E. coli strains failed to alter the mobility of algB DNA fragments containing the consensus IHF binding site. A protein in cell extracts prepared from P. aeruginosa strains also demonstrated binding to algB fragments containing the IHF binding site, and the position of the complex formed with these extracts was identical to that of the complex formed with purified IHF. Moreover, this binding could be inhibited by anti-IHF antibodies. To test the role of the IHF site in algB regulation, site-specific mutations in the algB IHF site, based on changes which severely affect IHF binding in E. coli, were generated. When either purified E. coli IHF or extracts from P. aeruginosa were used in DNA binding studies, the algB mutant DNAs were severely reduced in IHF binding. Mutations affecting IHF binding at the algB promoter were introduced into the algB-cat plasmid, and all resulted in severely impaired transcriptional activity in Alg- and algT mutant strains of P. aeruginosa. However, these mutations resulted in similar or slightly reduced algB-cat transcription in Alg+ and algB::Tn501 mutant strains. Thus, the algT product plays a positive role in the high-level expression of algB in mucoid cells, whereas as protein present in P.aeruginosa extracts which is likely an IHF homolog plays a positive role in maintaining a basal level of algB expression in nonmucoid strains.