Broadened substrate specificity of bacterial dipeptidyl-peptidase 7 enables release of half of all dipeptide combinations from peptide N-termini.

Abstract

Dipeptide production mediated by dipeptidyl-peptidase (DPP)4, DPP5, DPP7, and DPP11 plays a crucial role in growth of Porphyromonas gingivalis, a periodontopathic asaccharolytic bacterium. Given the particular P1-position specificity of DPPs, it has been speculated that DPP5 or DPP7 might be responsible for degrading refractory P1 amino acids, i.e., neutral (Thr, His, Gly, Ser, Gln) and hydrophilic (Asn) residues. The present results identified DPP7 as an entity that processes these residues, thus ensuring complete production of nutritional dipeptides in the bacterium. Activity enhancement by the P1' residue was observed in DPP7, as well as DPP4 and DPP5. Toward the refractory P1 residues, DPP7 uniquely hydrolyzed HX|LD-MCA (X = His, Gln, or Asn) and their hydrolysis was most significantly suppressed in dpp7 gene-disrupted cells. Additionally, hydrophobic P2 residue significantly enhanced DPP7 activity toward these substrates. The findings propose a comprehensive 20 P1 × 20 P2 amino acid matrix showing the coordination of four DPPs to achieve complete dipeptide production along with subsidiary peptidases. The present finding of a broad substrate specificity that DPP7 accounts for releasing 48 % (192/400) of N-terminal dipeptides could implicate its potential role in linking periodontopathic disease to related systemic disorders.