ANALYSIS OF THE ERWINIA-CHRYSANTHEMI ARB GENES, WHICH MEDIATE METABOLISM OF AROMATIC BETA-GLUCOSIDES

Erwinia chrysanthemi is one of the few members of the family Enterobacteriaceae that is capable of metabolizing most of the naturally occurring β-glucosides. We previously isolated the clb genes, which allow the use of the disaccharide cellobiose as well as the aromatic β-glucosides arbutin and salicin. We report here the isolation of the arb genes, which permit fermentation of the aromatic β-glucosides only. Establishment of a functional Arb system in Escherichia coli dependent on the presence of the phosphotransferase system and on the activation by the cyclic AMP-cyclic AMP receptor protein complex. Strains carrying mini-Mu-induced LacZ fusions to the arb genes were used to analyze arb genes organization and function. Three arb genes (arbG, arbF, and arbB) were identifid and organized in this order. Genetic and structural evidence allowed us to assign a phospho-β-glucosidase and a permease activity to the ArbB and ArbF proteins, respectively. Several Lac+ arb-lacZ insertions were introduced into the E. chrysanthemi chromosome. Both ArbG- and ArbF- strains were unable to ferment the aromatic β-glucosides, whereas ArbB- strains were impaired only in salicin fermentation. None of the mutations in the arb genes affected cellobiose metabolism. The expression of the arb genes was substrate inducible and required the ArbF permease and, possibly, the ArbG protein. Collectively, our results underline the resemblance between the naturally expressed E. chrysanthemi arbGFB and the cryptic E. coli bglGFB operons, yet the arbG gene product seemed unable to activate C. coli bgl operon expression.