Heterologous expression of the lactacin F peptides by Carnobacterium piscicola LV17.

The lactacin F complex, composed of LafA and LafX peptides, is produced by Lactobacillus johnsonii VPI 11088 and is active against five other Lactobacillus species and Enterococcus faecalis. The genetic determinants encoding the lactacin F complex are organized in a 1-kb polycistronic operon which comprises three genes, lafA, lafX, and ORFZ (encoding the putative immunity protein). The lafA and lafX genes encode the bacteriocin precursors with N-terminal extensions characterized by a Gly-Gly-1*Xaa+1 cleavage site (*). The Gly-Gly motif is conserved in several other bacteriocins, including carnobacteriocins A, BM1, and B2. Carnobacterium piscicola LV17 produces carnobacteriocins which are active against Listeria monocytogenes and other lactic acid bacteria. In this study, the lactacin F operon was introduced into C. piscicola LV17. The transformants produced lactacin F concurrently with the carnobacteriocins. When the lafA and lafX genes were separated and cloned individually into LV17, production of either LafA or LafX by C. piscicola LV17 was detected by complementation with L. johnsonii clones producing LafX or LafA, respectively. Transformants of C. piscicola LV17 which produced lactacin F, LafA, or LafX, in combination with the carnobacteriocins, were assayed for an increased and expanded inhibitory spectrum. The recombinant organisms were only active against lactacin F- and carnobacteriocin-sensitive strains. A plasmidless derivative of LV17 which does not produce the carnobacteriocins failed to produce lactacin F, LafA, or LafX when transformed with the appropriate recombinant plasmids. The ability of C. piscicola LV17 to produce lactacin F demonstrates that the machinery for the carnobacteriocins is capable of processing and exporting bacteriocins from both systems.     

Utilization of the leucocin A export system in Leuconostoc gelidum for production of a Lactobacillus bacteriocin

Abstract The lactacin F complex, composed of LafA and LafX peptides, is produced by Lactobacillus johnsonii VPI 11088 (ATCC 11506) and is active against various lactobacilli and Enterococcus faecalis . The genetic determinants encoding the lactacin F peptides, LafA and LafX, are organized in a chromosomal operon comprised of genes lafA, lafX , and ORFZ. The lactacin F operon was introduced into Leuconostoc (Lc.) gelidum UAL187-22 which produces leucocin A. Leucocin A, a plasmid-encoded bacteriocin, inhibits E. faecalis, Listeria monocytogenes , and other lactic acid bacteria. The culture supernatant of the Leuconostoc transformant containing the lactacin F operon inhibited both lactacin F-and leucocin A-sensitive indicators. Concurrent expression of both bacteriocins did not alter the production of native leucocin A. Additive inhibitory effects due to the presence of both bacteriocins were not observed. An isogenic derivative of UAL187-22, which has lost the leucocin-encoding plasmid, was unable to produce active lactacin F when transformed with the appropriate recombinant plasmid. The ability of Lc. gelidum UAL187-22 to produce lactacin F demonstrates that the export system for leucocin A is capable of producing both bacteriocins simultaneously.     

Molecular analysis of the lactacin F operon.

Lactacin F is a nonlantibiotic, heat-stable, peptide bacteriocin produced by Lactobacillus johnsonii VPI11088. Molecular analysis of the lactacin F DNA region characterized a small operon that codes for three open reading frames, designated lafA, lafX, and ORFZ. The peptide encoded by lafA, the lactacin F structural gene, was compared with various peptide bacteriocins from lactic acid bacteria, and similarities were identified in the amino and carboxy termini of the propeptides. Site-directed mutagenesis of the LafA precursor at the two glycine residues in positions -1 and -2 defined an essential motif for processing of mature lactacin F. The involvement of the peptides encoded by lafX and ORFZ in bacteriocin expression was investigated by subcloning various fragments from the lactacin F region into the shuttle vector pGKV210. In addition to lafA, expression of lafX is essential to lactacin F activity. The lactacin F operon resembles the genetic organization of lactococcin M. Although no function has been assigned to ORFZ by genetic analysis, both peptide Z and the lactococcin M immunity protein are predicted to be integral membrane proteins with four putative transmembrane segments. Lactacin F activity, defined by bactericidal action on Lactobacillus delbrueckii, is dependent on the expression of two genes, lafA and lafX.     

Cloning, phenotypic expression, and DNA sequence of the gene for lactacin F, an antimicrobial peptide produced by Lactobacillus spp

Lactacin F is a heat-stable bacteriocin produced by Lactobacillus acidophilus 11088. A 63-mer oligonucleotide probe deduced from the N-terminal lactacin F amino acid sequence was used to clone the putative laf structural gene from plasmid DNA of a lactacin F-producing transconjugant, L. acidophilus T143. One clone, NCK360, harbored a recombinant plasmid, pTRK160, which contained a 2.2-kb EcoRI fragment of the size expected from hybridization experiments. An Escherichia coli-L. acidophilus shuttle vector was constructed, and a subclone (pTRK162) containing the 2.2-kb EcoRI fragment was introduced by electroporation into two lactacin F-negative strains, L. acidophilus 89 and 88-C. Lactobacillus transformants containing pTRK162 expressed lactacin F activity and immunity. Bacteriocin produced by the transformants exhibited an inhibitory spectrum and heat stability identical to those of the wild-type bacteriocin. An 873-bp region of the 2.2-kb fragment was sequenced by using a 20-mer degenerate lactacin F-specific primer to initiate sequencing from within the lactacin F structural gene. Analysis of the resulting sequence identified an open reading frame which could encode a protein of 75 amino acids. The 25 N-terminal amino acids for lactacin F were identified within the open reading frame along with an N-terminal extension, possibly a signal sequence. The lactacin F N-terminal sequence, through the remainder of the open reading frame (57 amino acids; 6.3 kDa), correlated extremely well with composition analyses of purified lactacin F which also predicted a size of 51 to 56 amino acid residues. Molecular characterization of lactacin F identified a small hydrophobic peptide that may be representative of a common bacteriocin class in lactic acid bacteria.     

Detection and activity of lactacin B, a bacteriocin produced by Lactobacillus acidophilus

A total of 52 strains of Lactobacillus acidophilus were examined for production of bacteriocins. A majority (63%) demonstrated inhibitory activity against all members of a four-species grouping of Lactobacillus leichmannii, Lactobacillus bulgaricus, Lactobacillus helveticus, and Lactobacillus lactis. Four L. acidophilus strains with this activity also inhibited Streptococcus faecalis and Lactobacillus fermentum, suggesting a second system of antagonism. Under conditions eliminating the effects of organic acids and hydrogen peroxide, no inhibition of other gram-positive or -negative genera was demonstrated by L. acidophilus. The agent produced by L. acidophilus N2 and responsible for inhibition of L. leichmannii, L. bulgaricus, L. helveticus, and L. lactis was investigated. Ultrafiltration studies indicated a molecular weight of approximately 100,000 for the crude inhibitor. The agent was sensitive to proteolytic enzymes and retained full activity after 60 min at 100 degrees C (pH 5). Activity against sensitive cells was bactericidal but not bacteriolytic. These characteristics identified the inhibitory agent as a bacteriocin, designated lactacin B. Examination of strains of L. acidophilus within the six homology groupings of Johnson et al. (Int. J. Syst. Bacteriol. 30:53-68, 1980) demonstrated that production of the bacteriocin lactacin B could not be used in classification of neotype L. acidophilus strains. However, the usefulness of employing sensitivity to lactacin B in classification of dairy lactobacilli is suggested.     

Analysis of the genetic region encoding a novel rhizobiocin from Rhizobium leguminosarum bv. viciae strain 306

Cross-testing of a number of strains of Rhizobium leguminosarum for bacteriocin production revealed that strain 306 produced at least two distinct bacteriocins. Further analysis involving plasmid transfer to Agrobacterium and other hosts demonstrated that there were bacteriocin determinants on plasmids pRle306b and pRle306c, as well as a third bacteriocin. The bacteriocin encoded by pRle306b was indistinguishable from the bacteriocin encoded by strain 248, whereas the bacteriocin encoded by plasmid pRle306c had a distinctive spectrum of activity against susceptible strains, as well as different physical properties from other bacteriocins that we have studied in our lab. Two mutants altered in production of the pRle306c bacteriocin were generated by transposon Tn5 mutagenesis, and the DNA flanking the transposon inserts in these mutants was cloned and characterized. DNA sequence analysis suggested that the pRle306c bacteriocin was a large protein belonging to the RTX family, and that a type I secretion system involving an ABC type transporter was required for export of the bacteriocin. A mutant unable to produce this bacteriocin was unaltered in its competitive properties, both in broth and in nodulation assays, suggesting that the bacteriocin may not play a major role in determining the ecological success of this strain.     

Functional analysis of promoters involved in quorum sensing-based regulation of bacteriocin production in Lactobacillus

Bacteriocin production in Lactobacillus sake LTH673 involves at least four operons: a regulatory operon (sppIPKR); two operons encoding bacteriocins and their immunity proteins (sppAiA and orfX); and an operon needed for secretion (sppTE). We show here that the response regulator encoded by sppR in L. sake LTH673, as well as the homologous response regulators encoded by plnC and plnD in Lactobacillus plantarum C11, bind to characteristic repeats found in the -80 to -40 regions of spp operons. The promoters controlling bacteriocin operons are strictly regulated, and their activity is increased more than 1000-fold upon activation. Constitutive expression for the regulatory and transport operons is driven, at least in part, by promoters upstream of the -80 to -40 regions. Peak promoter activity of the regulatory and transporter operons precedes that of the two bacteriocin operons. The results reveal how promoters involved in quorum sensing-based regulation of bacteriocin production in Lactobacillus differ in strength, leakiness and timing of their activity.     

Cloning, sequencing, and expression in Escherichia coli of lcnB, a third bacteriocin determinant from the lactococcal bacteriocin plasmid p9B4-6.

On the bacteriocin plasmid p9B4-6 of Lactococcus lactis subsp. cremoris 9B4, a third bacteriocin determinant was identified. The genes encoding bacteriocin production and immunity resided on a 1.2-kb CelII-ScaI fragment and were located adjacent to one of two previously identified bacteriocin operons (M. J. van Belkum, B. J. Hayema, R. E. Jeeninga, J. Kok, and G. Venema, Appl. Environ. Microbiol. 57:492-498, 1991). The fragment was sequenced and analyzed by deletion and mutation analyses. The bacteriocin determinant consisted of two genes which were transcribed as an operon. The first gene (lcnB), containing 68 codons, was involved in bacteriocin activity. The second gene (lciB) contained 91 codons and was responsible for immunity. The specificity of this novel bacteriocin, designated lactococcin B, was different from that of the other two bacteriocins specified by p9B4-6. Part of the nucleotide sequence of the lactococcin B operon was similar to a nucleotide sequence also found in the two other bacteriocin operons of p9B4-6. This conserved region encompassed a nucleotide sequence upstream of the bacteriocin gene and the 5' part of the gene. When the lactococcin B operon was expressed in Escherichia coli by using a T7 RNA polymerase-specific promoter, antagonistic activity could be detected.     

Cloning, sequencing, and expression in Escherichia coli of lcnB, a third bacteriocin determinant from the lactococcal bacteriocin plasmid p9B4-6.

On the bacteriocin plasmid p9B4-6 of Lactococcus lactis subsp. cremoris 9B4, a third bacteriocin determinant was identified. The genes encoding bacteriocin production and immunity resided on a 1.2-kb CelII-ScaI fragment and were located adjacent to one of two previously identified bacteriocin operons (M. J. van Belkum, B. J. Hayema, R. E. Jeeninga, J. Kok, and G. Venema, Appl. Environ. Microbiol. 57:492-498, 1991). The fragment was sequenced and analyzed by deletion and mutation analyses. The bacteriocin determinant consisted of two genes which were transcribed as an operon. The first gene (lcnB), containing 68 codons, was involved in bacteriocin activity. The second gene (lciB) contained 91 codons and was responsible for immunity. The specificity of this novel bacteriocin, designated lactococcin B, was different from that of the other two bacteriocins specified by p9B4-6. Part of the nucleotide sequence of the lactococcin B operon was similar to a nucleotide sequence also found in the two other bacteriocin operons of p9B4-6. This conserved region encompassed a nucleotide sequence upstream of the bacteriocin gene and the 5' part of the gene. When the lactococcin B operon was expressed in Escherichia coli by using a T7 RNA polymerase-specific promoter, antagonistic activity could be detected.     

Gene Cluster Responsible for Secretion of and Immunity to Multiple Bacteriocins,the NKR-5-3 Enterocins

Enterococcus faecium NKR-5-3, isolated from Thai fermented fish, is characterized by the unique ability to produce five bacteriocins, namely, enterocins NKR-5-3A, -B, -C, -D, and -Z (Ent53A, Ent53B, Ent53C, Ent53D, and Ent53Z). Genetic analysis with a genome library revealed that the bacteriocin structural genes (enkA [ent53A], enkC [ent53C], enkD [ent53D], and enkZ [ent53Z]) that encode these peptides (except for Ent53B) are located in close proximity to each other. This NKR-5-3ACDZ (Ent53ACDZ) enterocin gene cluster (approximately 13 kb long) includes certain bacteriocin biosynthetic genes such as an ABC transporter gene (enkT), two immunity genes (enkIaz and enkIc), a response regulator (enkR), and a histidine protein kinase (enkK). Heterologous-expression studies of enkT and ΔenkT mutant strains showed that enkT is responsible for the secretion of Ent53A, Ent53C, Ent53D, and Ent53Z, suggesting that EnkT is a wide-range ABC transporter that contributes to the effective production of these bacteriocins. In addition, EnkIaz and EnkIc were found to confer self-immunity to the respective bacteriocins. Furthermore, bacteriocin induction assays performed with the ΔenkRK mutant strain showed that EnkR and EnkK are regulatory proteins responsible for bacteriocin production and that, together with Ent53D, they constitute a three-component regulatory system. Thus, the Ent53ACDZ gene cluster is essential for the biosynthesis and regulation of NKR-5-3 enterocins, and this is, to our knowledge, the first report that demonstrates the secretion of multiple bacteriocins by an ABC transporter.     

DNA analysis of the genes encoding acidocin LF221 A and acidocin LF221 B,two bacteriocins produced by<Emphasis Type="Italic"> Lactobacillus gasseri</Emphasis> LF221

Lactobacillus gasseri LF221, an isolate from the feces of a child, produces two bacteriocins. Standard procedures for molecular techniques were used to locate, clone and sequence the fragments of LF221 chromosomal DNA carrying the acidocin LF221 A and B structural genes, respectively. Sequencing analysis revealed the gene of acidocin LF221 A to be an open reading frame encoding a protein composed of 69 amino acids, including a 16-amino-acid N-terminal extension. The acidocin LF221 B gene was found to encode a 65-amino-acid bacteriocin precursor with a 17-amino-acid N-terminal leader peptide. DNA homology searches showed similarities of acidocin LF221 A to brochocin B, lactococcin N and thermophilin B, whereas acidocin LF221 B exhibited some homology to lactacin F and was virtually identical to gassericin X. The peptides encoded by orfA1 and orfB3 showed characteristics of class II bacteriocins and are suspected to be the complementary peptides of acidocin A and B, respectively. orfA3 and orfB5 are proposed to encode putative immunity proteins for the acidocins. Acidocin LF221 A and acidocin LF221 B are predicted to be members of the two-component class II bacteriocins, where acidocin LF221 A appears to be a novel bacteriocin. L. gasseri LF221 is being developed as a potential probiotic strain and a food/feed preservative. Detailed characterization of its acidocins is an important piece of background information useful in applying the strain into human or animal consumption. The genetic information on both acidocins also enables tracking of the LF221 strain in mixed populations and complex environments.     

Characterization and heterologous expression of the genes encoding enterocin a production, immunity, and regulation in Enterococcus faecium DPC1146

Enterocin A is a small, heat-stable, antilisterial bacteriocin produced by Enterococcus faecium DPC1146. The sequence of a 10, 879-bp chromosomal region containing at least 12 open reading frames (ORFs), 7 of which are predicted to play a role in enterocin biosynthesis, is presented. The genes entA, entI, and entF encode the enterocin A prepeptide, the putative immunity protein, and the induction factor prepeptide, respectively. The deduced proteins EntK and EntR resemble the histidine kinase and response regulator proteins of two-component signal transducing systems of the AgrC-AgrA type. The predicted proteins EntT and EntD are homologous to ABC (ATP-binding cassette) transporters and accessory factors, respectively, of several other bacteriocin systems and to proteins implicated in the signal-sequence-independent export of Escherichia coli hemolysin A. Immediately downstream of the entT and entD genes are two ORFs, the product of one of which, ORF4, is very similar to the product of the yteI gene of Bacillus subtilis and to E. coli protease IV, a signal peptide peptidase known to be involved in outer membrane lipoprotein export. Another potential bacteriocin is encoded in the opposite direction to the other genes in the enterocin cluster. This putative bacteriocin-like peptide is similar to LafX, one of the components of the lactacin F complex. A deletion which included one of two direct repeats upstream of the entA gene abolished enterocin A activity, immunity, and ability to induce bacteriocin production. Transposon insertion upstream of the entF gene also had the same effect, but this mutant could be complemented by exogenously supplied induction factor. The putative EntI peptide was shown to be involved in the immunity to enterocin A. Cloning of a 10.5-kb amplicon comprising all predicted ORFs and regulatory regions resulted in heterologous production of enterocin A and induction factor in Enterococcus faecalis, while a four-gene construct (entAITD) under the control of a constitutive promoter resulted in heterologous enterocin A production in both E. faecalis and Lactococcus lactis.     

Double-glycine-type leader peptides direct secretion of bacteriocins by ABC transporters: colicin V secretion in Lactococcus lactis

Many non-lantibiotic bacteriocins of lactic acid bacteria are produced as precursors which have N-terminal leader peptides that share similarities in amino acid sequence and contain a conserved processing site of two glycine residues in positions -1 and -2. A dedicated ATP-binding cassette (ABC) transporter is responsible for the proteolytic cleavage of the leader peptides and subsequent translocation of the bacteriocins across the cytoplasmic membrane. To investigate the role that these leader peptides play in the recognition of the precursor by the ABC transporters, the leader peptides of leucocin A, lactococcin A or colicin V were fused to divergicin A, a bacteriocin from Carnobacterlum divergens that is secreted via the cell's general secretion pathway. Production of divergicin was monitored when these fusion constructs were introduced into Leuconostoc gelidum, Lactococcus lactis and Escherichia coli, which carry the secretion apparatus for leucocin A, lactococcins A and B, and colicin V, respectively. The different leader peptides directed the production of divergicin in the homologous hosts. In some cases production of divergicin was also observed when the leader peptides were used in heterologous hosts. For ABC-transporter-dependent secretion in E. coli the outer membrane protein TolC was required. Using this strategy, colicin V was produced in L. lactis by fusing this bacteriocin behind the leader peptide of leucocin A.     

Primary amino acid and DNA sequences of gassericin T, a lactacin F-family bacteriocin produced by Lactobacillus gasseri SBT2055

A broad-spectral bacteriocin, named gassericin T, produced by Lactobacillus gasseri SBT 2055 (from human feces) was isolated to homogeneity from the culture supernatant by hydrophobic chromatography. By SDS-PAGE and in situ activity assay, the purified gassericin T migrated as a single band with bacteriocin activity and molecular size of 5,400. A 2.9-kbp HindIII-HindIII fragment of chromosome DNA was hybridized with the oligonucleotide probe designed from the partial N-terminal amino acid sequence of gassericin T and was cloned. Six ORFs including the structural gene of gassericin T were deduced by computer analysis and the data bases. The structural gene of gassericin T (gatA) was identified as the fourth ORF, which encoded a protein composed of 75 amino acids that included the GG motif of the cleavage site. Chemical sequencing analysis of the complete amino acid sequence showed that gassericin T (57 amino acids) had a disulfide bond in the molecule and no modified amino acid residues, making it a class II bacteriocin. The gassericin T had 60% sequence similarity to mature LafA (57 amino acids, lactacin F, bacteriocins produced by L. johnsonii VPI11088), and the sequences around the processing site and C-terminal area were well conserved. The fifth ORF was designated as gatX, encoded as a peptide composed of 65 amino acids containing the GG motif of the putative cleavage site, however mature GatX and its antibacterial activity were not detected in the culture supernatant. GatX has higher similarity with LafX than with lactobin A (50 amino acids) belonging to the first lactacin F-family. These results indicated that gassericin T belongs to the hydrophobic class II bacteriocins and the most vicinal lactacin F-family.     

Kinetic studies of the action of lactacin F, a bacteriocin produced by Lactobacillus johnsonii that forms poration complexes in the cytoplasmic membrane.

The bacteriocin lactacin F is bactericidal against Lactobacillus delbrueckii, Lactobacillus helveticus, and Enterococcus faecalis. Activity against L. delbrueckii was recently shown to be dependent on two peptides, LafA and LafX, which are encoded within the lactacin F operon (T. R. Klaenhammer, FEMS Microbiol. Rev. 12:39-87, 1993). It has been proposed that two peptides form an active lactacin F complex. In this study, the action of lactacin F against E. faecalis ATCC 19443 and the effects of various environmental parameters were investigated in detail. Addition of lactacin F induced the loss of K+ from cells of L. delbrueckii, Lactobacillus johnsonii 88-4, and E. faecalis, while the lactacin F producer L. johnsonii VPI 11088 was not affected by the bacteriocin. Lactacin F caused an immediate loss of cellular K+, depolarization of the cytoplasmic membrane, and hydrolysis of internal ATP in E. faecalis. Lactacin F induced loss of K+ in 3,3',4',5-tetrachlorosalicylanilide-treated cells, indicating that pores are formed in the absence of a proton motive force. ATP hydrolysis was not due to dissipation of the proton motive force but was most likely caused by efflux of inorganic phosphate, resulting in a shift of the ATP hydrolysis equilibrium. Action of lactacin F was optimal at acidic pH values and was reduced in the presence of di- and trivalent cations. The lanthanide gadolinium (Gd3+) prevented action of lactacin F completely at a concentration of 0.2 mM. Lactacin F-induced loss of cell K+ was severely reduced at low temperatures, presumably as a result of increased ordering of the lipid hydrocarbon chains in the cytoplasmic membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

BlpC-regulated bacteriocin production in Streptococcus thermophilus

Streptococcus thermophilus B59671 produces a bacteriocin with anti-pediococcal activity, but genes required for its production are not characterized. Genome sequencing of S. thermophilus has identified a genetic locus encoding a quorum sensing (QS) system that regulates production of class II bacteriocins. However, in strains possessing this gene cluster, production of bacteriocin like peptides (Blp) was only observed when excess pheromone was provided. PCR analysis revealed this strain possessed blpC, which encodes the 30-mer QS pheromone. To investigate if BlpC regulates bacteriocin production in S. thermophilus B59671, an integrative vector was used to replace blpC with a gene encoding for kanamycin resistance and the resulting mutant did not inhibit the growth of Pediococcus acidilactici. Constitutive expression of blpC from a shuttle vector restored the bacteriocin production, confirming the blp gene cluster is essential for bacteriocin activity in S. thermophilus B59671.     

Characterisation of an Antilisterial Bacteriocin Produced by Lactobacillus sakei CWBI-B1365 Isolated from Raw Poultry Meat and Determination of Factors Controlling its Production

Amongst 101 lactic acid bacteria isolated from meat and fish samples, strain CWBI-B1365, identified as Lactobacillus sakei, was found to produce the subclass IIa bacteriocin sakacin G. Partial sequencing of the gene involved in the biosynthetic pathways revealed an unusual gene organisation in that the accessory gene associated with bacteriocin transport did not occur immediately downstream of the gene encoding an ABC transporter, but upstream of the putative immunity gene and encoded on the opposite DNA strand. Sakacin G production was strongly regulated by pH, temperature and the carbon sources used in the growth medium, as well as the concentration of carbon and nitrogen sources. The condition of pH 5.5 and the temperature of 25°C appeared to be optimal for bacteriocin production. The use of sucrose during culturing and the fed batch addition of sucrose and meat extract greatly enhanced bacteriocin production.