Degenerate oligonucleotides based on the published Escherichia coli glutamate decarboxylase (GAD) protein sequence were used in a polymerase chain reaction to generate a DNA probe for the E. coli GAD structural gene. Southern blots showed that there were two cross-hybridizing GAD genes, and both of these were cloned and sequenced. The two GAD structural genes, designated gadA and gadB, were found to be 98% similar at the nucleotide level. Each gene encoded a 466-residue polypeptide, named, respectively, GAD a and GAD 13, and these differed by only five amino acids. Both GAD a and GAD 13 contain amino acid residues which are highly conserved among pyridoxal-dependent decarboxylases, but otherwise the protein sequences were not homologous to any other known proteins. By restriction mapping and hybridization to the Kohara miniset library, the two GAD genes were located on the E. coli chromosome. gadA maps at 4046 kb and gadB at 1588 kb. Neither of these positions is in agreement with the current map position for gadS as determined by genetic means. Analysis of Southern blots indicated that two GAD genes were present in all E. coli strains examined, including representatives from the ECOR collection. However, no significant cross-hybridizing gene was found in Salmonella species. Information about the DNA sequences and map positions of gad4 and gadB should facilitate a genetic approach to elucidate the role of GAD in E. coli metabolism.The enzyme glutamate decarboxylase (GAD; also known as glutamic acid decarboxylase; EC 4.1.1.15) catalyzes the a-decaboxylation of glutamic acid to produce -y-aminobutyric acid. Within bacteria, GAD activity seems to be relatively unique to Escherichia coli (37). Gale (14) proposed a general role for the inducible bacterial amino acid decarboxylases, including GAD, in the maintenance of physiological pH under acidic conditions. E. coli GAD has been extensively characterized with respect to its biophysical and biochemical properties (1,14,30,31,(39)(40)(41)(42)(43)(44)(45)(46), and a partial protein sequence has been available for some time (42, 43). Based on genetic linkage studies in E. coli, the structural gene for GAD (gadS) and a potential regulatory gene (gadR) have been mapped between mtl at approximately 80.7 minutes and gltS at approximately 82.4 minutes (3,23,26,27), but these early results have not been followed up. For the purposes of our immunological studies, we were interested in obtaining the complete DNA and protein sequences of E. coli GAD. At the time this work was initiated, an extensive search of the literature and all available sequence data bases suggested that neither the complete protein sequence nor the gene sequence for E. coli GAD had been determined. To obtain this information, we generated a DNA probe for the gene based on a recent more extensive partial protein sequence (24). By using this probe on E. coli genomic DNA, we discovered that there were not one but two separate cross-hybridizing GAD genes. We report here the complete DNA sequences and map pos...
