Structural Characterization of Peptide-Mediated Inhibition of Porphyromonas gingivalis Biofilm Formation

Abstract

ABSTRACT Porphyromonas gingivalis is a periodontal pathogen whose primary niche is the anaerobic environment of subgingival dental plaque, but initial colonization of the oral cavity is likely to occur on supragingival surfaces that already support robust biofilm communities. Our studies have shown that P. gingivalis adheres to Streptococcus gordonii through interaction of the minor fimbrial antigen Mfa1 with a specific region of the streptococcal SspB polypeptide (residues 1167 to 1193) designated BAR. We show that a synthetic peptide comprising the BAR sequence potently inhibits P. gingivalis adherence to S. gordonii (50% inhibitory concentration = 1.3 μM) and prevents the development of P. gingivalis biofilms. However, a retroinverso peptide that possessed the same side chain topology as that of BAR was inactive, suggesting that interactions of Mfa1 with the peptide backbone of BAR are important for binding. A conformationally constrained analog of BAR inhibited P. gingivalis adherence and biofilm formation but at a lower specific activity than that of BAR. Therefore, to further define the structural features of the Mfa1-BAR interaction, we functionally screened combinatorial libraries of BAR in which active site residues (Asn 1182 , Thr 1184 , and Val 1185 ) were replaced with each of the 19 common amino acids. Peptides containing positively charged amino acids at position 1182 or hydrophobic residues at position 1185 bound P. gingivalis more efficiently than did control peptides containing Asn and Val at these positions, suggesting that electrostatic and hydrophobic interactions may contribute to Mfa1-SspB binding. In contrast, replacement of Pro or Gly at these positions was detrimental to adherence, suggesting that perturbation of the BAR secondary structure influences activity. The net effect of substitutions for Thr 1184 was less pronounced either positively or negatively than that at the other sites. These results define physicochemical characteristics of the interacting interface of Mfa1 and SspB and suggest that peptides or peptidomimetics with greater specific inhibitory activity than that of BAR can be developed. These compounds may represent potential therapeutics that target some of the first molecular interactions that allow P. gingivalis to colonize the oral cavity.