A positive selection method for mutations affecting bioconversion of aromatic compounds was applied to a mutant strain of Agrobacterium tumefaciens A348. The nucleotide sequence of the A348 pcaHGB genes, which encode protocatechuate 3,4-dioxygenase (PcaHG) and -carboxy-cis,cis-muconate cycloisomerase (PcaB) for the first two steps in catabolism of the diphenolic protocatechuate, was determined. An omega element was introduced into the pcaB gene of A348, creating strain ADO2077. In the presence of phenolic compounds that can serve as carbon sources, growth of ADO2077 is inhibited due to accumulation of the tricarboxylate intermediate. The toxic effect, previously described for Acinetobacter sp., affords a powerful selection for suppressor mutations in genes required for upstream catabolic steps. By monitoring loss of the marker in pcaB, it was possible to determine that the formation of deletions was minimal compared to results obtained with Acinetobacter sp. Thus, the tricarboxylic acid trick in and of itself does not appear to select for large deletion mutations. The power of the selection was demonstrated by targeting the pcaHG genes of A. tumefaciens for spontaneous mutation. Sixteen strains carrying putative second-site mutations in pcaH or -G were subjected to sequence analysis. All single-site events, their mutations revealed no particular bias toward multibase deletions or unusual patterns: five (1) frameshifts, one (+1) frameshift, one tandem duplication of 88 bp, one deletion of 92 bp, one nonsense mutation, and seven missense mutations. PcaHG is considered to be the prototypical ferric intradiol dioxygenase. The missense mutations served to corroborate the significance of active site amino acid residues deduced from crystal structures of PcaHG from Pseudomonas putida and Acinetobacter sp. as well as of residues in other parts of the enzyme.