Cloning of Pseudomonas aeruginosa algG, which controls alginate structure.

The biochemical mechanism by which alpha-L-guluronate (G) residues are incorporated into alginate by Pseudomonas aeruginosa is not understood. P. aeruginosa first synthesizes GDP-mannuronate, which is used to incorporate beta-D-mannuronate residues into the polymer. It is likely that the conversion of some beta-D-mannuronate residues to G occurs by the action of a C-5 epimerase at either the monomer (e.g., sugar-nucleotide) or the polymer level. This study describes the results of a molecular genetic approach to identify a gene involved in the formation or incorporation of G residues into alginate by P. aeruginosa. Mucoid P. aeruginosa FRD1 was chemically mutagenized, and mutants FRD462 and FRD465, which were incapable of incorporating G residues into alginate, were independently isolated. Assays using a G-specific alginate lyase from Klebsiella aerogenes and 1H-nuclear magnetic resonance analyses showed that G residues were absent in the alginates secreted by these mutants. 1H-nuclear magnetic resonance analyses also showed that alginate from wild-type P. aeruginosa contained no detectable blocks of G. The mutations responsible for defective incorporation of G residues into alginate in the mutants FRD462 and FRD465 were designated algG4 and algG7, respectively. Genetic mapping experiments revealed that algG was closely linked (greater than 90%) to argF, which lies at 34 min on the P. aeruginosa chromosome and is adjacent to a cluster of genes required for alginate biosynthesis. The clone pALG2, which contained 35 kilobases of P. aeruginosa DNA that included the algG and argF wild-type alleles, was identified from a P. aeruginosa gene bank by a screening method that involved gene replacement. A DNA fragment carrying algG was shown to complement algG4 and algG7 in trans. The algG gene was physically mapped on the alginate gene cluster by subcloning and Tn501 mutagenesis.