Phosphonopeptides as substrates for peptide transport systems and peptidases of Escherichia coli.

Peptide transport and peptidase susceptibility of the antibacterial agent alafosfalin and other phosphonopeptides have been characterized in Escherichia coli. Phosphonodipeptides were accumulated by a process which appeared to involve multiple permeases; saturation was not achieved even at concentrations of 128 microM. Competition studies showed that these compounds had only a low affinity for the system transporting phosphonooligopeptides and were rapidly taken up by and were inhibitory to E. coli mutants unable to transport the toxic peptide triornithine. Phosphonodipeptides containing D-residues were not appreciably transported. By contrast, phosphonooligopeptides were generally transported by a distinct saturable permease system for which they had a high affinity. This system was identical to that utilized by triornithine. Phosphonooligopeptides with simple monoalkyl substituents at the amino terminus were also transported except in the case of a t-butyl substituent. The oligopeptide permease was also able to transport certain derivatives which contained some residues having D rather than L stereochemistry. Intracellular metabolism of phosphonooligopeptides was initiated almost exclusively by hydrolysis from the N terminus by an L-specific peptidase. This initial hydrolytic activity was unaffected by the aminopeptidase inhibitor bestatin, unlike the final hydrolysis step which yields L-1-aminoethylphosphonic acid from the phosphonodipeptide intermediate.