Pilar Casaus

Enterocin B, a new bacteriocin from Enterococcus faecium T136 which can act synergistically with enterocin A

The strain Enterococcus faecium T136 produces two bacteriocins, enterocin A, a member of the pediocin family of bacteriocins, and a new bacteriocin termed enterocin B. The N-terminal amino acid sequences of enterocins A and B were determined, and the gene encoding enterocin B was sequenced. The primary translation product was a 71 aa peptide containing a leader peptide of the double-glycine type which is cleaved off to give mature enterocin B of 53 aa. Enterocin B does not belong to the pediocin family of bacteriocins and shows strong homology to carnobacteriocin A. However, sequence similarities in their leader peptides and C-termini suggest that enterocin B and carnobacteriocin A are related to bacteriocins of the pediocin family. Enterocins A and B had only slightly different inhibitory spectra, and both were active against a wide range of Gram-positive bacteria, including listeriae, staphylococci and most lactic acid bacteria tested. Both had bactericidal activities, but survival at a frequency of 10(-4)-10(-2) was observed when sensitive cultures were exposed to either bacteriocin. The number of survivors was drastically reduced when a mixture of the two bacteriocins was added to the cells.

Biochemical and Genetic Evidence that Enterococcus faecium L50 Produces Enterocins L50A and L50B, the sec-Dependent Enterocin P, and a Novel Bacteriocin Secreted without an N-Terminal Extension Termed Enterocin Q

Enterococcus faecium L50 grown at 16 to 32 degrees C produces enterocin L50 (EntL50), consisting of EntL50A and EntL50B, two unmodified non-pediocin-like peptides synthesized without an N-terminal leader sequence or signal peptide. However, the bacteriocin activity found in the cell-free culture supernatants following growth at higher temperatures (37 to 47 degrees C) is not due to EntL50. A purification procedure including cation-exchange, hydrophobic interaction, and reverse-phase liquid chromatography has shown that the antimicrobial activity is due to two different bacteriocins. Amino acid sequences obtained by Edman degradation and DNA sequencing analyses revealed that one is identical to the sec-dependent pediocin-like enterocin P produced by E. faecium P13 (L. M. Cintas, P. Casaus, L. S. Hâvarstein, P. E. Hernández, and I. F. Nes, Appl. Environ. Microbiol. 63:4321-4330, 1997) and the other is a novel unmodified non-pediocin-like bacteriocin termed enterocin Q (EntQ), with a molecular mass of 3,980. DNA sequencing analysis of a 963-bp region of E. faecium L50 containing the enterocin P structural gene (entP) and the putative immunity protein gene (entiP) reveals a genetic organization identical to that previously found in E. faecium P13. DNA sequencing analysis of a 1,448-bp region identified two consecutive but diverging open reading frames (ORFs) of which one, termed entQ, encodes a 34-amino-acid protein whose deduced amino acid sequence was identical to that obtained for EntQ by amino acid sequencing, showing that EntQ, similarly to EntL50A and EntL50B, is synthesized without an N-terminal leader sequence or signal peptide. The second ORF, termed orf2, was located immediately upstream of and in opposite orientation to entQ and encodes a putative immunity protein composed of 221 amino acids. Bacteriocin production by E. faecium L50 showed that EntP and EntQ are produced in the temperature range from 16 to 47 degrees C and maximally detected at 47 and 37 to 47 degrees C, respectively, while EntL50A and EntL50B are maximally synthesized at 16 to 25 degrees C and are not detected at 37 degrees C or above.

Biochemical and genetic evidence of enterocin P production by two Enterococcus faecium-like strains isolated from fermented sausages.

Abstract. Two bacteriocin-producing Enterococcus faecium-like strains were independently isolated from fermented sausages. Bacteriocins were purified to homogeneity by ammonium sulfate precipitation, gel filtration, cationic exchange, hydrophobic interaction, and reverse-phase liquid chromatography. Two peptide inhibitory fractions were purified from each strain, denominated A and B for E. faecium AA13, and C and D for E. faecium G16. Fraction B was blocked for amino acid sequencing by Edman degradation, while the amino acid sequences obtained from peptides A, C, and D contained the YGNGV consensus motif in positions 5 to 9, and the ATRS sequence in positions 1 to 4. By use of PCR techniques and nucleotide sequencing, the structural gene of enterocin P was found both in E. faecium AA13 and E. faecium G16. Metabolic and genetic features of the two strains suggest that they are slightly different, they may produce more than one bacteriocin, and both produce enterocin P.

Inhibition of Listeria monocytogenes by Lactobacillus sake strains of meat origin

The ability of two Lactobacillus sake strains of meat origin to inhibit the growth of Listeria monocytogenes at 4, 8, 15, 24 and 32°C in a conventional liquid media was investigated. Growth of L. monocytogenes was affected by Lac. sake strains at all temperatures. The inhibition was higher at 15, 24 and 32°C than at refrigeration temperatures. The inhibitory activity of both lactobacilli was similar perhaps due to the fact that Lac. sake 148 produces a bacteriocin inhibitory to L. monocytogenes, while Lac. sake 23 is a strong lactic acid producer. The antagonism exhibited by the lactobacilli on the L. monocytogenes strains seems to display a bacteriostatic rather than a bacteriocidal effect.

Inhibition of Yersinia enterocolitica by Lactobacillus sake strains of meat origin

The growth of Yersinia enterocolitica at 4, 8, 15 and 24°C, in mixed cultures with Lactobacillus sake strains previously isolated from Spanish dry fermented sausages was investigated. Growth of Y. enterocolitica was affected by L. sake strains at all temperatures studied. The inhibition was higher as the incubation temperature increased. L. sake 148, a bacteriocinogenic strain, was less inhibitory to Y. enterocolitica growth than L. sake 23, a stronger lactic acid producer strain. The low pH and the lactic acid produced by the lactobacilli seem to be major factors contributing to the inhibition of Y. enterocolitica strains.