Pathway and Enzyme Redundancy in Putrescine Catabolism in Escherichia coli

Putrescine as the sole carbon source requires a novel catabolic pathway with glutamylated intermediates. Nitrogen limitation does not induce genes of this glutamylated putrescine (GP) pathway but instead induces genes for a putrescine catabolic pathway that starts with a transaminase-dependent deamination.We determined pathway utilization with putrescine as the sole nitrogen source by examining mutants with defects in both pathways. Blocks in both the GP and transaminase pathways were required to prevent growth with putrescine as the sole nitrogen source. Genetic and biochemical analyses showed redundant enzymes for -aminobutyraldehyde dehydrogenase (PatD/YdcW and PuuC), -aminobutyrate transaminase (GabT and PuuE), and succinic semialdehyde dehydrogenase (GabD and PuuC). PuuC is a nonspecific aldehyde dehydrogenase that oxidizes all the aldehydes in putrescine catabolism. A puuPmutant failed to use putrescine as the nitrogen source, which implies one major transporter for putrescine as the sole nitrogen source. Analysis of regulation of the GP pathway shows induction by putrescine and not by a product of putrescine catabolism and shows that putrescine accumulates in puuA, puuB, and puuCmutants but not in any other mutant. We conclude that two independent sets of enzymes can completely degrade putrescine to succinate and that their rela-tive importance depends on the environment. Polyamines are ubiquitous and important biologicalmolecules.The major polyamine in Escherichia coli is the diamine pu-trescine (1,4-diaminobutane), although the triamine spermidine (aminopropyl-putrescine) and the diamine cadaverine (1,5-di