Isolation, partial characterization and mode of action of acidocin J1229, a bacteriocin produced by Lactobacillus acidophilus JCM 1229

Lactobacillus acidophilus JCM 1229 produces a heat-stable bacteriocin, designated as acidocin J1229, that has a narrow inhibitory spectrum. Production of acidocin J1229 in MRS broth was pH dependent, with maximum activity detected in broth culture maintained at pH 5:0. Acidocin J1229 was purified by ammonium sulphate precipitation and sequential cation exchange and reversed-phase chromatographies. The sequence of the first 24 amino acid residues of the N terminus of acidocin J1229 was determined. The molecular mass of acidocin J1229 as determined by mass spectrometry was 6301 Da. Acidocin J1229 showed a bactericidal effect but not a bacteriolytic effect on sensitive cells. Acidocin J1229 dissipated the membrane potential and the pH gradient in sensitive cells, which affected such proton motive force-dependent processes as amino acid transport. Acidocin J1229 also caused an efflux of glutamate, previously taken up via a unidirectional ATP-driven transport system. Secondary structure prediction revealed the presence of an amphiphilic a-helix region that could form hydrophilic pores. These results suggest that acidocin J1229 is a pore-forming peptide that creates cell membrane channels through the 'barrel-stave'mechanism.     

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.     

Purification and characterisation of acidocin D20079, a bacteriocin produced by Lactobacillus acidophilus DSM 20079

Bacteriocins are natural antimicrobial agents produced by food fermentative bacteria. Lactobacillus acidophilus DSM 20079 produces a small bacteriocin, with a molecular mass of 6.6 kDa, designated acidocin D20079. This antimicrobial peptide was extremely heat-stable (30 min at 121 degrees C) and was active over a wide pH range. It was found to be sensitive to proteolytic enzymes (trypsin, ficin, pepsin, papain, and proteinase K). Acidocin D20079 has a narrow inhibitory spectrum restricted to the genus Lactobacillus which includes L. sakei NCDO 2714, an organism known to cause anaerobic spoilage of vacuum-packaged meat. Maximum production of acidocin D20079 in MRS broth was detected at pH 6.0, and the peptide was purified by ammonium sulphate precipitation followed by sequential cation exchange and hydrophobic interaction chromatography. Purified acidocin D20079 spontaneously formed spherulite crystals during dialysis. As the N-terminus was found to be blocked for sequencing, matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry was used to determine a partial sequence, and the molecular mass of the bacteriocin in the formed crystals (6.6 kDa). Estimates of the molecular weight of the partially purified peptide, using tricine-SDS-PAGE, in which bacteriocin activity was confirmed by overlayer techniques were in accordance with this value.     

Characterization and purification of acidocin 1B, a bacteriocin produced by Lactobacillus acidophilus GP1B

In the present study, acidocin 1B, a bacteriocin produced by Lactobacillus acidophilus GP1B, exhibited profound inhibitory activity against a variety of LAB and pathogens, including Gram-negative bacteria, and its mode of action was to destabilize the cell wall, thereby resulting in bactericidal lysis. Acidocin 1B was found to be heat stable, because it lost no activity when it was heated up to 95 degrees C for 60 min. It retained approximately 67% of the initial activity after storage for 30 days at 4 degrees C, and 50% of its initial activity after 30 days at 25 degrees C and 37 degrees C. The molecular mass of acidocin 1B was estimated to be 4214.65 Da by mass spectrometry. Plasmid curing results indicated that a plasmid, designated as pLA1B, seemed to be responsible for both acidocin 1B production and host immunity, and that the pLA1B could be transformed into competent cells of L. acidophilus ATCC 43121 by electroporation. Our findings indicate that the acidocin 1B and its producer strain may have potential value as a biopreservative in food systems.     

Purification and some properties of acidocin 8912, a novel bacteriocin produced by Lactobacillus acidophilus TK8912.

Acidocin 8912, a bacteriocin produced by Lactobacillus acidophilus TK8912, was purified by ammonium sulfate fractionation and successive chromatographies on CM-cellulose, Sephadex G-50, Sephadex G-25, and reversed-phase HPLC on Aquapore RP-300. The purified acidocin 8912 migrated as a single band on SDS-PAGE. The molecular weight was estimated to be 5200 by SDS-PAGE, and 5400 by HPLC gel filtration on TSKgel G3000PWXL. Both the amino acid composition and the N-terminal amino acid sequence analysis indicated that acidocin 8912 was a peptide composed of presumably 50 amino acids containing a Lys residue at the N-terminus. The purified acidocin 8912 showed a bactericidal effect on sensitive cells but not a bacteriolytic effect.     

Isolation and characterization of acidocin A and cloning of the bacteriocin gene from Lactobacillus acidophilus.

Acidocin A, a bacteriocin produced by Lactobacillus acidophilus TK9201, is active against closely related lactic acid bacteria and food-borne pathogens including Listeria monocytogenes. The bacteriocin was purified to homogeneity by ammonium sulfate precipitation and sequential ion-exchange and reversed-phase chromatographies. The molecular mass was determined by high-performance liquid chromatography gel filtration to be 6,500 Da. The sequence of the first 16 amino acids of the N terminus was determined, and oligonucleotide probes based on this sequence were constructed to detect the acidocin A structural gene acdA. The probes hybridized to the 4.5-kb EcoRI fragment of a 45-kb plasmid, pLA9201, present in L. acidophilus TK9201, and the hybridizing region was further localized to the 0.9-kb KpnI-XbaI fragment. Analysis of the nucleotide sequence of this fragment revealed that acidocin A was synthesized as an 81-amino-acid precursor including a 23-amino-acid N-terminal extension. An additional open reading frame (ORF2) encoding a 55-amino-acid polypeptide was found downstream of and in the same operon as acdA. Transformants containing this ORF2 became resistant to acidocin A, suggesting that ORF2 encodes an immunity function for acidocin A. The 7.2-kb SacI-XbaI fragment containing the upstream region of acdA of pLA9201 was necessary for acidocin A expression in the acidocin A-deficient mutant, L. acidophilus TK9201-1, and other Lactobacillus strains.     

Characterization and purification of acidocin CH5, a bacteriocin produced by Lactobacillus acidophilus CH5

AIMS: To characterize and to purify a bacteriocin produced by Lactobacillus acidophilus strain with its activity restricted to Gram-positive bacteria. METHODS AND RESULTS: Native acidocin CH5, a bacteriocin produced by L. acidophilus CH5 an isolate from a dairy starter culture forms in MRS (Oxoid, Basingstoke, UK) broth high-molecular weight aggregates which can dissociate into smaller units (retained by 5 kDa membrane) with higher activity. Acidocin CH5 was purified using combinations of chromatographic methods based on hydrophobic and cation exchange principles and the N-terminal region was sequenced. CONCLUSIONS: Based on our results it is evident that acidocin CH5 belongs, according to bacteriocin classification, to the class II bacteriocins with identical N-terminal amino acid sequence described in the literature previously. SIGNIFICANCE AND IMPACT OF THE STUDY: The study has provided further data on bacteriocin acidocin CH5 from class II with wide spectrum of antimicrobial activity atypical for bacteriocins produced by L. acidophilus sharing the same homology.     

Cloning and nucleotide sequence of the gene for acidocin 8912, a bacteriocin from Lactobacillus acidophilus TK8912

K. KANATANI, T. TAHARA, M. OSHIMURA, K. SANO AND C. UMEZAWA. 1995. Acidocin 8912 is a bacteriocin produced by Lactobacillus acidophilus TK8912. The acidocin 8912 structural gene, acdT , was cloned and determined. It was located on the 14–kb plasmid pLA103 and encoded a 46 amino acid precursor including a 20 amino acid N-terminal extension. The precursor sequence of the acdT gene shows a conservation of the general structural characteristics of the bacteriocin precursors from some lactic acid bacteria.     

Purification and Some Properties of Acidocin 8912, a Novel Bacteriocin Produced by Lactobacillus acidophilus TK8912

Acidocin 8912, a bacteriocin produced by Lactobacillus acidophilus TK8912, was purified by ammonium sulfate fractionation and successive chromatographies on CM-cellulose, Sephadex G-50, Sephadex G-25, and reversed-phase HPLC on Aquapore RP-300. The purified acidocin 8912 migrated as a single band on SDS–PAGE. The molecular weight was estimated to be 5200 by SDS–PAGE, and 5400 by HPLC gel filtration on TSKgel G3000PW_XL. Both the amino acid composition and the N-terminal amino acid sequence analysis indicated that acidocin 8912 was a peptide composed of presumably 50 amino acids containing a Lys residue at the N-terminus. The purified acidocin 8912 showed a bactericidal effect on sensitive cells but not a bacteriolytic effect.     

Isolation, partial characterization, and mode of action of Acidocin J1132, a two-component bacteriocin produced by Lactobacillus acidophilus JCM 1132.

Lactobacillus acidophilus JCM 1132 produces a heat-stable, two-component bacteriocin designated acidocin J1132 that has a narrow inhibitory spectrum. Maximum production of acidocin J1132 in MRS broth was detected at pH 5.0. Acidocin J1132 was purified by ammonium sulfate precipitation and sequential cation exchange and reversed-phase chromatographies. Acidocin J1132 activity was associated with two components, termed alpha and beta. On the basis of N-terminal amino acid sequencing and the molecular masses of the alpha and beta components, it is interpreted that the compounds differ by an additional glycine residue in the beta component. Both alpha and beta had inhibitory activity, and an increase in activity by the complementary action of the two components was observed. Acidocin J1132 is bactericidal and dissipates the membrane potential and the pH gradient in sensitive cells, which affect such proton motive force-dependent processes as amino acid transport. Acidocin J1132 also caused efflux of preaccumulated amino acid taken up via a unidirectional ATP-driven transport system. Secondary structure prediction revealed the presence of an amphiphilic alpha-helix region that could form hydrophilic pores. These results suggest that acidocin J1132 is a pore-forming bacteriocin that creates cell membrane channels through the "barrel-stave" mechanism.     

Bacteriocins of Lactobacillus gasseri K7 – Monitoring of gassericin K7 A and B genes’ expression and isolation of an active component

The genome of Lactobacillus gasseri K7, isolated from baby's faeces, contains gene regions encoding two-component bacteriocins named gassericin K7 A (GenBank EF392861) and gassericin K7 B (GenBank AY307382). The strain has been known to exhibit bacteriocin activity in vitro, however, no data exist on the expression of particular genes of bacteriocins’ operons or on the activity of individual components of this bacteriocin complex, which has not been isolated so far. The objectives of this study were to examine bacteriocin genes’ expression during the growth of L. gasseri K7 and to isolate individual components in order to reveal the contribution of individual peptides to the overall bacteriocin activity. All eight target genes were expressed during exponential phase of growth in MRS broth. Mass spectrometry analysis revealed that the amino acid sequence of isolated peptide matched the deduced amino acid sequence of putative active peptide of gassericin K7 B (Gas K7 B_AcP) and GatX, a complementary peptide of gassericin T, previously supposed to have no antimicrobial activity. The isolated peptide showed a broad spectrum of antimicrobial activity. Furthermore, the isolation protocol developed in this study will enable to obtain a considerable amount of purified bacteriocins needed for further investigation of their functionality.     

Isolation and Characterization of Carnocyclin A, a Novel Circular Bacteriocin Produced by Carnobacterium maltaromaticum UAL307

Carnobacterium maltaromaticum UAL307, isolated from fresh pork, exhibits potent activity against a number of gram-positive organisms, including numerous Listeria species. Three bacteriocins were isolated from culture supernatant, and using matrix-assisted laser desorption ionization-time of flight mass spectrometry and Edman sequencing, two of these bacteriocins were identified as piscicolin 126 and carnobacteriocin BM1, both of which have previously been described. The remaining bacteriocin, with a molecular mass of 5,862 Da, could not be sequenced by traditional methods, suggesting that the peptide was either cyclic or N-terminally blocked. This bacteriocin showed remarkable stability over a wide temperature and pH range and was unaffected by a variety of proteases. After digestion with trypsin and α-chymotrypsin, the peptide was de novo sequenced by tandem mass spectrometry and a linear sequence deduced, consisting of 60 amino acids. Based on this sequence, the molecular mass was predicted to be 5,880 Da, 18 units higher than the observed molecular mass, which suggested that the peptide has a cyclic structure. Identification of the genetic sequence revealed that this peptide is circular, formed by a covalent linkage between the N and C termini following cleavage of a 4-residue peptide leader sequence. The results of structural studies suggest that the peptide is highly structured in aqueous conditions. This bacteriocin, named carnocyclin A, is the first reported example of a circular bacteriocin produced by Carnobacterium spp.     

Production and physicochemical characterization of acidocin D20079, a bacteriocin produced by Lactobacillus acidophilus DSM 20079

Lactobacillus acidophilus DSM 20079 is the producer of a novel bacteriocin termed acidocin D20079. In this paper, a partial sequence of this peptide is determined, together with data on its secondary structure. A modification of the MRS-growth medium (replacing the detergent Tween 80 with oleic acid), was shown to improve the production level of the peptide by one order of magnitude, as well as to stabilize the activity level. Addition of a detergent (Tween 20, less interfering in mass spectrometric analysis), was however necessary for solubilization of the purified acidocin D20079. Digestion of the peptide followed by de-novo sequencing of generated fragments, allowed determination of a partial sequence consisting of 39 of the totally estimated 65 residues. Acidocin D20079 has a high content of glycine residues, hydrophobic residues, and acidic residues. No modified amino acids were found. Edman degradation, and C-terminal sequencing failed, suggesting that the peptide may be cyclic, and a novel member of class IIc bacteriocins. Circular dichroism spectroscopy and secondary structure prediction showed random coil conformation in aqueous solution, but secondary structure was induced in the presence of sodium-dodecyl sulfate. The data could be fitted assuming 2–13% of the residues to be in α-helix and 23–27% of the residues to be in β-strand conformation. This indicates that a membrane/membrane-mimicking hydrocarbon–water interface induces an active conformation.     

Antimicrobial activity of lactobacilli: preliminary characterization and optimization of production of acidocin B, a novel bacteriocin produced by Lactobacillus acidophilus M46

Approximately 1000 lactobacillus strains were isolated and screened for the production of antimicrobial activity, using a target panel of spoilage organisms and pathogens. Only eight positive strains were found; two of these were studied in more detail. Lactobacillus salivarius M7 produces the new broad spectrum bacteriocin salivaricin B which inhibits the growth of Listeria monocytogenes, Bacillus cereus, Brochothrix thermosphacta, Enterococcus faecalis and many lactobacilli. A new atypical bacteriocin produced by Lact. acidophilus M46, acidocin B, combines the inhibition of Clostridium sporogenes with a very narrow activity spectrum within the genus Lactobacillus and was selected for further characterization. Acidocin B is sensitive to trypsin, heat-stable (80°C for 20 min) and can be extracted from the culture supernatant fluid with butanol. Native acidocin B occurs as a large molecular weight complex (100 kDa), while with SDS-PAGE the partly purified activity migrates as a peptide of 2·4 kDa. Optimization of the cultivation conditions resulted in an eightfold increase of the amount of acidocin B produced during growth. Growth is not necessary for acidocin B production; washed producer cells can synthesize the bacteriocin in a chemically defined production medium. The application potential of acidocin B is discussed.     

Wide-Inhibitory Spectra Bacteriocins Produced by Lactobacillus gasseri K7

The aim of our study was to determine the genetic characterization and classification of Lb. gasseri K7 bacteriocins, comparison with bacteriocins of the Lb. gasseri LF221 strain and other related strains. Bacteriocin-encoding genes were amplified by PCR, subjected to DNA sequencing, and BLAST sequence analysis was performed to search the database for homologous peptides. Lb. gasseri K7 produces two two-peptide bacteriocins, named gassericin K7 A and gassericin K7 B. Their nucleotide sequences were deposited at GenBank, under accession numbers EF392861 for the gassericin K7 A and AY307382 for the gassericin K7 B. Analysis of gene clusters of bacteriocins in Lb. gasseri K7 strain revealed a 100 percent sequence identity with bacteriocins in LF221 strain. An active peptide of gassericin K7 B is homologous to the complementary peptide of gassericin T, and a complementary peptide of gassericin K7 B is homologous to the active peptide of gassericin T. Another surprising finding was that the sakacin T-beta peptide is partly homologous to the active peptide of gassericin K7 A, while the other sakacin T peptide (alfa) is partly homologous to the complementary peptide of gassericin K7 B. Gassericins of Lb. gasseri K7 strain were both classified as two-peptide bacteriocins. Human probiotic strains Lb. gasseri K7 and LF221 are different isolates but with identical bacteriocin genes. They produce wide-inhibitory spectra bacteriocins that are new members of two-peptide bacteriocins with some homologies to other bacteriocins in this group. Described bacteriocins offer a great potential in applications in food industry, pharmacy and biomedicine.     

Butyrivibriocin AR10, a new cyclic bacteriocin produced by the ruminal anaerobe Butyrivibrio fibrisolvens AR10: characterization of the gene and peptide

The gene (bviA) encoding the ruminal bacteriocin butyrivibriocin AR10 was cloned from an EcoRI library by using an oligonucleotide probe based on a partial peptide sequence of the previously isolated peptide. The gene encoded an 80 amino acid prebacteriocin that demonstrated significant identity with the cyclic bacteriocin gassericin A. Negative ion time of flight mass spectroscopic analysis (ESI/MS) indicated a mass of 5981.5 Da for the isolated bacteriocin, a molecular mass that could not be generated by removal of a leader peptide alone. However, an N- to C-terminal cyclization of the predicted mature bacteriocin resulted in a peptide that conformed to the determined mass and charge characteristics. Northern blotting confirmed that expression of bviA mirrored the production of the bacteriocin in both liquid and solid media.     

Conjugative Plasmid from Lactobacillus gasseri LA39 That Carries Genes for Production of and Immunity to the Circular Bacteriocin Gassericin A

Gassericin A is a circular bacteriocin produced by Lactobacillus gasseri strain LA39. We found a 33,333-bp plasmid, designated pLgLA39, in this strain. pLgLA39 contained 44 open reading frames, including seven genes related to gassericin A production/immunity (gaa), as well as genes for replication, plasmid maintenance, and conjugative transfer. pLgLA39 was transferred from LA39 to the type strain of L. gasseri (JCM 1131) by filter mating. The transconjugant exhibited >30-fold-higher more resistance to gassericin A and produced antibacterial activity. Lactobacillus reuteri LA6, the producer of reutericin 6, was proved to harbor a plasmid indistinguishable from pLgLA39 and carrying seven genes 100% identical to gaa. This suggests that pLgLA39 might have been transferred naturally between L. gasseri LA39 and L. reuteri LA6. The seven gaa genes of pLgLA39 were cloned into a plasmid vector to construct pGAA. JCM 1131^T transformed with pGAA expressed antibacterial activity and resistance to gassericin A. pGAA was segregationally more stable than a pGAA derivative plasmid from which gaaA was deleted and even was more stable than the vector. This suggests the occurrence of postsegregational host killing by the gaa genes. pLgLA39 carried a pemIK homolog, and segregational stabilization of a plasmid by the pLgLA39-type pemIK genes was also confirmed. Thus, pLgLA39 was proved to carry the genes for at least two plasmid maintenance mechanisms, i.e., gaa and pemIK. Plasmids containing a repA gene similar to pLgLA39 repA were distributed in several L. gasseri strains.Lactobacillus species are normal inhabitants of the human gastrointestinal tract, and Lactobacillus gasseri is one of the most commonly detected of these species (37, 47). Health-promoting effects of this species, such as immunomodulation (35), suppression of Helicobacter pylori-induced interleukin-8 production (44), and improvement of intestinal conditions (34), have been reported, and some L. gasseri strains are used in commercial probiotic products.Bacteriocins are antimicrobial peptides, proteins, or protein complexes produced by bacteria and active mainly against related bacterial species (38). Several bacteriocins also inhibit the growth of food-borne pathogens, such as Listeria, Bacillus cereus, and Clostridium perfringens. Production of bacteriocin is thought to be a desired feature for probiotic strains, since bacteriocin is believed to provide an advantage for survival in the ecological niche and to prevent the growth of pathogens. Several L. gasseri strains are known to produce bacteriocins (18). The classification of bacteriocins remains controversial. We use the definition proposed by Maqueda et al. (30), where bacteriocins are classified into class I (lantibiotics), class II (nonlantibiotics), class III (large heat-labile bacteriocins), and class IV (circular bacteriocins linked at the N- and C-terminal ends). Among these, the class IV circular bacteriocins have attracted increasing attention, since they are the simplest prokaryotic representatives of the ubiquitous circular peptides with various physiological activities (6). Enterocin AS-48 from Enterococcus faecalis strain S-48 is the first and most vigorously characterized member of the class IV bacteriocins (30). L. gasseri strain LA39 (JCM 11657) produces a 58-amino-acid (aa) circular bacteriocin, gassericin A (18). Gassericin A is a representative of the non-AS-48-like circular bacteriocin group including butyrivibriocin AR10 from Butyrivibrio fibrisolvens AR10 (15) and carnocyclin A from Carnobacterium maltaromaticum UAL307 (32), as well as reutericin 6 from Lactobacillus reuteri LA6 (17) and acidocin B from Lactobacillus acidophilus M46 (26). The last two bacteriocins have nearly identical amino acid sequences to that of gassericin A. Though the number of reported circular bacteriocins has been increasing, their primary sequences and the genes responsible for production of and immunity to them are diversified (for a review, see reference 31). Recently, we isolated and sequenced seven genes (gaaBCADITE) from LA39 deduced to be responsible for production of and immunity to gassericin A (20). The gaa genes add new information to the complex world of the class IV bacteriocin genes.The structural gene of gassericin A, gaaA, was reported to be located on the chromosome of LA39 (19). However, the high amino acid sequence identity of gassericin A to reutericin 6 (100%) and to acidocin B (98%) suggests recent horizontal gene transfers of the relevant bacteriocin genes, possibly via mobile elements. In fact, the acidocin B genes were reported to be located on a plasmid, namely, pCV461 (26). Many Lactobacillus strains are known to harbor one or more plasmids of various sizes, and several Lactobacillus plasmids have been reported to contain genes for production of bacteriocins (48). To our knowledge, however, only three have been sequenced entirely: these are pLA103 from Lactobacillus acidophilus TK8912 (16), pRC18 from Lactobacillus curvatus (previously known as Lactobacillus casei) CRL705 (7), and pMP118 from Lactobacillus salivarius subsp. salivarius UCC118 (5). Thus, genetic information about bacteriocin-producing Lactobacillus plasmids is still limited. Furthermore, little has been known about plasmids of L. gasseri, even though the existence of plasmids in a few strains has been reported, including a 26.5-kb anonymous plasmid in strain ADH (27) and pK7 in strain K7 (28).Here we describe a 33.3-kb plasmid, designated pLgLA39, from L. gasseri LA39. The gaa genes are located on this plasmid. pLgLA39 carries a set of genes for conjugative transfer and was shown to be transmitted to another L. gasseri strain. L. reuteri LA6 also harbors a plasmid almost identical to pLgLA39. We demonstrated that production of gassericin A increased the apparent segregational stability of a plasmid carrying the gaa genes. A pemIK homolog in pLgLA39 was also functional as a plasmid-stabilizing mechanism. This is the first report describing the entire nucleotide sequence and detailed genetic analysis of an L. gasseri plasmid, which contains functional genes for circular bacteriocin production, conjugation, and plasmid maintenance.     

DNA Sequencing and Homologous Expression of a Small Peptide Conferring Immunity to Gassericin A,a Circular Bacteriocin Produced by Lactobacillus gasseri LA39

Gassericin A, produced by Lactobacillus gasseri LA39, is a hydrophobic circular bacteriocin. The DNA region surrounding the gassericin A structural gene, gaaA, was sequenced, and seven open reading frames (ORFs) of 3.5 kbp (gaaBCADITE) were found with possible functions in gassericin A production, secretion, and immunity. The deduced products of the five consecutive ORFs gaaADITE have homology to those of genes involved in butyrivibriocin AR10 production, although the genetic arrangements are different in the two circular bacteriocin genes. GaaI is a small, positively charged hydrophobic peptide of 53 amino acids containing a putative transmembrane segment. Heterologous expression and homologous expression of GaaI in Lactococcus lactis subsp. cremoris MG1363 and L. gasseri JCM1131^T, respectively, were studied. GaaI-expressing strains exhibited at least sevenfold-higher resistance to gassericin A than corresponding control strains, indicating that gaaI encodes an immunity peptide for gassericin A. Comparison of GaaI to peptides with similar characteristics found in the circular bacteriocin gene loci is discussed.Bacteriocins are antimicrobial peptides that act primarily against related bacterial species. The classification of bacteriocins remains controversial. Here, we use the classification of Maqueda et al. (30): class I (lantibiotics); class II (nonlantibiotics) with subclasses IIa (antilisteral pediocin-like bacteriocins), IIb (two-peptide bacteriocins), and IIc (leaderless bacteriocins); class III (large heat-labile bacteriocins); and class IV (circular bacteriocins linked at the N- and C-terminal amino acids).Nine class IV circular bacteriocins have been reported to date. They can be further divided into two major groups by using their primary structures, biochemical characteristics, and genetic arrangements. One group is the family of enterocin AS-48 (32), the first circular bacteriocin described (in 1994), which includes circularin A (25) and uberolysin (40). The other group is the family of gassericin A (19, 21), the second bacteriocin found (in 1998), which includes acidocin B (28), reutericin 6 (with a primary structure 100% identical to that of gassericin A) (22, 23), butyrivibriocin AR10 (17), and carnocyclin A, from Carnobacterium maltaromaticum UAL307 (33). The lantibiotic-like subtilosin A produced by Bacillus subtilis subsp. subtilis strain 168 (24) is an orphan member of the class IV bacteriocins. The gassericin A family of bacteriocins have been isolated from various bacterial species in several countries, suggesting the bacteriocin genes may be associated with transferable genetic elements.The bacteriocins of lactic acid bacteria (LAB) and bacteriocin-producing LAB strains isolated from foods are promising food preservative candidates, and strains of human origin are expected to be probiotics that could help to prevent the growth of harmful bacteria in food and the human intestine. Lactobacillus gasseri belongs to the Lactobacillus acidophilus group of LAB, which are natural inhabitants of the human intestinal tract (35), and many L. gasseri strains have been shown to produce bacteriocins (16, 20). Gassericin A was produced by L. gasseri LA39 isolated from the feces of a human infant; it has bactericidal activity against the food-borne pathogens Listeria monocytogenes, Bacillus cereus, and Staphylococcus aureus (16). Recently, using proteose peptone, some strains of L. gasseri containing LA39 were successfully cultured in reconstituted skim milk and cheese whey, where L. gasseri LA39 produced gassericin A; these low-cost, safe media could be used to improve the safety of biopreservation (1). Gassericin A has been purified and characterized, and its structural gene (gaaA) has been cloned and sequenced (21, 22). Determination of the complete chemical structure of gassericin A showed that the bacteriocin belongs to class IV and consists of 58 amino acid residues linked at the N and C termini (19). Little is known about the mechanisms of secretion and circularization of gassericin A and immunity to the circular bacteriocin.Here, we sequenced six genes surrounding gaaA thought to be related to production of and immunity to gassericin A and examined the homologous and heterologous expression of a small hydrophobic peptide, GaaI; we found that gaaI is an immunity gene providing protection against gassericin A.     

Characterization of the amylovorin locus of Lactobacillus amylovorus DCE 471, producer of a bacteriocin active against Pseudomonas aeruginosa, in combination with colistin and pyocins

Lactobacillus amylovorus DCE 471 produces amylovorin L, a bacteriocin with an antibacterial activity against some strains of the Lactobacillus lineage. Based on the sequence of one active peptide, a gene encoding active amylovorin L was cloned and sequenced. Genome walking allowed us to sequence a larger fragment of 7577 bp of genomic DNA, with 12 predicted ORFs. The previously characterized amylovorin L peptide-encoding gene is preceded by another gene encoding a small polypeptide with a typical bacteriocin-processing double-glycine site, suggesting that amylovorin L is a two-component class IIb bacteriocin (amylovorin Lalpha/beta). Lalpha and Lbeta show the highest similarity to gassericin T from Lactobacillus gasseri SBT2055 and BlpN from Streptococcus pneumoniae R6, respectively, and to LafA and LafX, which form the lactacin F bacteriocin of Lactobacillus johnsonii NCC 533. As for other lactic acid bacteria bacteriocins, amylovorin L showed no activity against the Gram-negative opportunistic pathogen Pseudomonas aeruginosa on its own, but showed synergistic inhibitory activity when used in combination with the peptide antibiotic colistin, and, remarkably, with the P. aeruginosa soluble bacteriocins, pyocins S1 and S2.     

Plasmid-associated Bacteriocin Production by and Immunity of Lactobacillus acidophilus TK8912

Lactobacillus acidophilus TK8912 produces an antibacterial substance, designated acidocin 8912, which is active against strains of Lactobacillus and Lactococcus. Of all conditions tested, the production of acidocin 8912 was maximum at 30°C in MRS broth. Acidocin 8912 was stable to heat treatment (120°C for 20min), but completely inactivated by protease treatment. Curing a plasmid pLA103 resulted in the loss of both acidocin 8912 production (Acd⁺) and host immunity (Acd^r). A plasmid-cured strain, TK1–4 (Acd^- Acd⁸), was transformed to Acd⁺Acd^r with the pLA103 plasmid. These results provided the first direct evidence in lactobacilli for involvement of this plasmid in bacteriocin production and immunity.