Enterocin-HF

The solution structure of enterocin HF (EntHF), a class IIa bacteriocin of 43 amino acids produced by Enterococcus faecium M3K31, was evaluated by CD and NMR spectroscopy. Purified EntHF was unstructured in water, but CD analysis supports that EntHF adopts an α-helical conformation when exposed to increasing concentrations of trifluoroethanol. Furthermore, NMR spectroscopy indicates that this bacteriocin adopts an antiparallel β-sheet structure in the N-terminal region (residues 1-17), followed by a well-defined central α-helix (residues 19-30) and a more disordered C-terminal end (residues 31-43). EntHF could be structurally organized into three flexible regions that might act in a coordinated manner. This is in agreement with the absence of long-range nuclear Overhauser effect signals between the β-sheet domain and the C-terminal end of the bacteriocin. The 3D structure recorded for EntHF fits emerging facts regarding target recognition and mode of action of class IIa bacteriocins.

In this work, synthetic genes designed from (a), the native amino acid sequence of the class IIa bacteriocins enterocin HF (EntHF) and enterocin CRL35 (EntCRL35), (b) from hybrid bacteriocins derived from fusion of enterocin A (EntA) to itself and to EntHF and EntCRL35 through a tri-glycine peptide linker, and (c) from bacteriocin-derived chimeras devised from fusion of the N-terminal region of EntA and enterocin P (EntP) to the C-terminal end of EntHF and EntCRL35, were cloned in plasmid pPICZαA for expression by P. pastoris X-33. Synthetic genes encoding EntHF and EntCRL35 were also cloned in plasmid pP-αhSUMO3 for expression of the hSUMO3-fused bacteriocins by P. pastoris. Only recombinant P. pastoris expressing the bacteriocin-derived chimeras displayed a direct antimicrobial activity whereas P. pastoris X-33, producer of EntP::EntHF, showed the highest antimicrobial activity in their supernatants and in the multi-step chromatographic purified fractions. The MRM-ESI-LC-MS/MS (QTRAP) analysis of purified fractions from P. pastoris producers of hybrid- and bacteriocin-derived chimeras, permitted detection in the samples of peptides with the expected molecular mass of the bacteriocins produced. The antimicrobial activity of the EntP::EntHF chimera compared to that of the synthetic EntP::EntHF peptide, suggest that the biologically-produced bacteriocin-derived chimera shows a higher specific antimicrobial activity than its synthetic counterpart against different Listeria strains, including L. monocytogenes. More important, the N-terminal region of EntA and EntP seems to drive the production, processing and secretion of hybrid- and bacteriocin-derived chimeras, by P. pastoris X-33.

Genome sequencing of Enterococcus faecium M3K31, a strain isolated from griffon vultures, previously revealed the presence of three sequences encoding for bacteriocins, namely enterocin P, enterocin HF, and a SRCAM 602-like bacteriocin. In this work, we describe the SRCAM 602-like bacteriocin that we named faerocin MK. Mature faerocin MK consists of 43 residues and contains an YGNGV-motif and two cysteine residues at positions 10 and 15, consistent with other class IIa bacteriocins. Faerocin MK and SRCAM 602 were chemically synthesized and their scope of activity was tested. Faerocin MK is active against a wide range of Gram-positive organisms while SRCAM 602 was not active against any tested organism. Although both peptides are more structured in trifluoroethanol, faerocin MK has an α-helical character nearly twice that of SRCAM 602. Nucleotide sequence analysis revealed that the faerocin MK precursor is produced with a 28-amino acid signal peptide and that an immunity gene follows the structural faerocin MK gene. Heterologous expression of the faerocin MK operon showed that faerocin MK and its immunity protein were successfully expressed in other organisms. This indicates that the bacteriocin is secreted through the sec pathway.