Genetic and biochemical evidence was obtained for lysine catabolism via cadaverine and 8-aminovalerate in both the P-lactam producer Streptomyces clavuligerus and the nonproducer Streptomyces lividans. This pathway is used when lysine is supplied as the sole source of diitrogen for the organism. A second pathway for lysine catabolism is present in S. clavuligerus but not in S. lividans. It leads to oa-aminoadipate, a precursor for ,-lactam biosynthesis. Since it does not allow S. clavuligerus to grow on lysine as the sole nitrogen source, this pathway may be used exclusively to provide a precursor for B-lactam biosynthesis. j8-Lactam producers were unable to grow well on a-amin6adipate as the only nitrogen source, whereas three of seven species not known to produce P-lactam grew well under the same conditions. Lysine E-aminotransferase, the initial enzyme in the ea-aminoadipate pathway for lysine catabolism, was detected in cell extracts only from the ,I-lactam producers. These results suggest that synthesis of a-aminoadipate is exclusively a secondary metabolic trait, present or expressed only in I8-lactam producers, while genes governing the catabolism of a-aminoadipate are present or fully expressed only in ,B-lactam nonproducers.Lysine catabolism in aerobic bacteria is notable for its biochemical diversity. In the genus Pseudomonas, there are four inducible lysine catabolic pathways. Two of these lead to 8-aminovalerate, one pathway initiated by decarboxylation of lysine to cadaverine (5, 18) and the other by a monooxygenase-catalyzed conversion of lysine to 5-aminovaleramide (13, 20). In the remaining pathways, lysine is transaminated either to 1-piperideine-6-carboxylate (5) or to pipecolate (12), both of which may be catabolized to aaminoadipate. In Flavobacterium lutescens, lysine catabolism proceeds through 1-piperideine-6-carboxylate to cx-aminoadipate (16, 17). Romano and Nickerson (14) reported that lysine supported modest growth of Streptomyces fradiae when it was supplied as the sole source of nitrogen and carbon, but they provided no information on the pathway involved. Subsequently, the ca-aminoadipyl side chain of P-lactam antibiotics was found to be derived from lysine, and the first enzyme catalyzing this conversion was identified as lysine E-aminotransferase (10). Association of this enzyme with P-lactam production in cultures of Streptomyces (now Nocardia) lactamdurans and the isolation of mutants blocked in both 1-lactam production and lysine e-aminotransferase (10) suggested that the pathway for P-lactam antibiotic biosynthesis might start from lysine.In this paper, we present biochemical and genetic evidence for the catabolism of lysine via cadaverine in both the P-lactam producer Streptomyces clavuligerus and in Streptomyces lividans, a species not known to produce P-lactam antibiotics. We also provide evidence that the pathway for conversion of lysine to a-aminoadipate is absent from S. lividans, suggesting that this pathway is principally involved in antibiotic production, and show th...
