Analysis of the two-peptide bacteriocins lactococcin G and enterocin 1071 by site-directed mutagenesis.

The two peptides (Lcn-alpha and Lcn-beta) of the two-peptide bacteriocin lactococcin G (Lcn) were changed by stepwise site-directed mutagenesis into the corresponding peptides (Ent-alpha and Ent-beta) of the two-peptide bacteriocin enterocin 1071 (Ent), and the potencies and specificities of the various hybrid constructs were determined. Both Lcn and, to a lesser extent, Ent were active against all the tested lactococcal strains, but only Ent was active against the tested enterococcal strains. The two bacteriocins thus differed in their relative potencies to various target cells, despite their sequence similarities. The hybrid combination Lcn-alpha+Ent-beta had low potency against all strains tested, indicating that these two peptides do not interact optimally. The reciprocal hybrid combination (i.e., Ent-alpha+Lcn-beta), in contrast, was highly potent, indicating that these two peptides may form a functional antimicrobial unit. In fact, this hybrid combination (Ent-alpha+Lcn-beta) was more potent against lactococcal strains than wild-type Ent was (i.e., Ent-alpha+Ent-beta), but it was inactive against enterococcal strains (in contrast to Ent but similar to Lcn). The observation that Ent-alpha is more active against lactococci in combination with Lcn-beta and more active against enterococci in combination with Ent-beta suggests that the beta peptide is an important determinant of target cell specificity. Especially the N-terminal residues of the beta peptide seem to be important for specificity, since Ent-alpha combined with an Ent-beta variant with Ent-to-Lcn mutations at positions 1 to 4, 7, 9, and 10 was >150-fold less active against enterococcal strains but one to four times more active against lactococcal strains than Ent-alpha+Ent-beta. Moreover, Ent-to-Lcn single-residue mutations in the region spanning residues 1 to 7 in Ent-beta had a more detrimental effect on the activity against enterococci than on that against lactococcal strains. Of the single-residue mutations made in the N-terminal region of the alpha peptide, the Ent-to-Lcn mutations N8Q and P12R in Ent-alpha influenced specificity, as follows: the N8Q mutation had no effect on activity against tested enterococcal strains but increased the activity 2- to 4-fold against the tested lactococcal strains, and the P12R mutation reduced the activity >150-fold and only approximately 2-fold against enterococcal and lactococcal strains, respectively. Changing residues in the C-terminal half/part of the Lcn peptides (residues 20 to 39 and 25 to 35 in Lcn-alpha and Lcn-beta, respectively) to those found in the corresponding Ent peptides did not have a marked effect on the activity, but there was an approximately 10-fold or greater reduction in the activity upon also introducing Lcn-to-Ent mutations in the mid-region (residues 8 to 19 and 9 to 24 in Lcn-alpha and Lcn-beta, respectively). Interestingly, the Lcn-to-Ent F19L+G20A mutation in an Lcn-Ent-beta hybrid peptide was more detrimental when the altered peptide was combined with Lcn-alpha (>10-fold reduction) than when it was combined with Ent-alpha ( approximately 2-fold reduction), suggesting that residues 19 and 20 (which are part of a GXXXG motif) in the beta peptide may be involved in a specific interaction with the cognate alpha peptide. It is also noteworthy that the K2P and A7P mutations in Lcn-beta reduced the activity only approximately 2-fold, suggesting that the first seven residues in the beta peptides do not form an alpha-helix.