Genetic analysis of the iron uptake region of the Vibrio anguillarum plasmid pJM1: molecular cloning of genetic determinants encoding a novel trans activator of siderophore biosynthesis.

Clones carrying the iron uptake region of the Vibrio anguillarum plasmid pJM1 were subjected to insertion mutagenesis, using transposon Tn3::HoHo1 which carries a promoterless lacZ gene and can thus generate lacZ transcriptional fusions if inserted downstream from an indigenous promoter. Four classes of insertion mutants were obtained based on the level of expression of components of the iron uptake system, and six genetic units were defined according to the phenotype of the mutants. Five of the six genetic units were crucial for biosynthesis of the siderophore anguibactin. Insertions in the remaining genetic unit led to an iron uptake-deficient phenotype and showed either reduced levels of the outer membrane protein OM2 as well as anguibactin activity or a complet shutoff of both OM2 and anguibactin biosyntheses. Analysis of beta-galactosidase production by cells carrying the lacZ fusion derivatives identified iron-regulated and constitutive transcriptional units as well as their orientation in the genetic units. Molecular cloning of pJM1 plasmid DNA noncontiguous to the iron uptake region also identified genetic determinants for a trans-acting factor required for full expression of anguibactin activity. Evidence obtained from bioassays, spectrophotometric measurements, and the lacZ fusion mutants suggested that the trans-acting factor is a novel activator of siderophore biosynthesis at the transcriptional level.