Permeabilization and lysis induced by bacteriocins and its effect on aldehyde formation by Lactococcus lactis

Permeabilization induced by lacticin 3147, lactococcins A, B and M, enterocin AS-48 and nisin, bacteriocins described as cell membrane-pore forming and lytic agents, enhanced in all cases aldehyde formation by Lactococcus lactis IFPL730. Nevertheless, the conversion of isoleucine into 2-methylbutyraldehyde depended not only on the degree of permeabilization but also on the bacteriocin that caused the cell membrane damage. The highest values of 2-methylbutyraldehyde corresponded to cell suspensions containing lacticin 3147 and lactococcins, treatments that provoked further lysis in addition to induced permeabilization.     

Characterization and Structure Analysis of a Novel Bacteriocin,Lacticin Z,Produced by Lactococcus lactis QU 14

A novel bacteriocin, lacticin Z, produced by Lactococcus lactis QU 14 isolated from a horse’s intestinal tract was identified. Lacticin Z was purified through a three step procedure comprised of hydrophobic-interaction, cation-exchange chromatography, and reverse-phase HPLC. ESI-TOF MS determined the molecular mass of lacticin Z to be 5,968.9 Da. The primary structure of lacticin Z was found to consist of 53 amino acid residues without any leader sequence or signal peptide. Lacticin Z showed homology to lacticin Q from L. lactis QU 5, aureocin A53 from Staphylococcus aureus A53, and mutacin BHT-B from Streptococcus rattus strain BHT. It exhibited a nanomolar range of MICs against various Gram-positive bacteria, and the activity was completely stable up to 100 °C. Unlike many of other LAB bacteriocins, the stability of lacticin Z was emphasized under alkaline conditions rather than acidic conditions. All the results indicated that lacticin Z belongs to a novel type of bacteriocin.     

Purification and Partial Characterization of Lacticin 481, a Lanthionine-Containing Bacteriocin Produced by Lactococcus lactis subsp. lactis CNRZ 481

Lacticin 481, a bacteriocin produced during the growth of Lactococcus lactis subsp. lactis CNRZ 481, was purified sequentially by ammonium sulfate precipitation, gel filtration, and preparative and analytical reversed-phase high-pressure liquid chromatography. Ammonium sulfate precipitations resulted in a 455-fold increase in total lacticin 481 activity. The entire purification protocol led to a 107, 506-fold increase in the specific activity of lacticin 481. On the basis of its electrophoretic pattern in sodium dodecyl sulfate-polyacrylamide gels, lacticin 481 appeared as a single peptide band of 1.7 kDa. However, dimers of 3.4 kDa also exhibiting lacticin activity were detected. Derivatives of the lacticin-producing strain which did not produce lacticin 481 (Bac^-) were sensitive to this bacteriocin (Bac^s) and failed to produce the 1.7-kDa band. Amino acid composition analysis of purified lacticin 481 revealed the presence of lanthionine residues, suggesting that lacticin 481 is a member of the lantibiotic family of antimicrobial peptides. Seven residues (K G G S G V I) were sequenced from the N-terminal portion of lacticin 481, and these did not shown any homology with nisin or other known bacteriocin sequences.     

Potential application of the nisin Z preparation of Lactococcus lactis W8 in preservation of milk

Aims: The aim of the study is to evaluate the effectiveness of the preparation of nisin Z from Lactococcus lactis W8‐fermented milk in controlling the growth of spoilage bacteria in pasteurized milk. Methods and Results: Spoilage bacteria isolated from pasteurized milk at 8 and 15°C were identified as Enterococcus italicus, Enterococcus mundtii, Enterococcus faecalis, Bacillus thuringiensis, Bacillus cereus, Lactobacillus paracasei, Acinetobacter sp., Pseudomonas fluorescens and Enterobacter aerogenes. These bacteria were found to have the ability to survive pasteurization temperature. Except Enterobacter aerogenes, the spoilage bacteria were sensitive to the nisin Z preparation of the L. lactis W8. Addition of the nisin Z preparation to either the skim milk or fat milk inoculated with each of the spoilage bacteria reduced the initial counts (about 5 log CFU ml^?1) to an undetectable level within 8–20 h. The nisin Z preparation extended the shelf life of milk to 2 months under refrigeration. Conclusions: The nisin Z preparation from L. lactis W8‐fermented milk was found to be effective as a backup preservative to counteract postpasteurization contamination in milk. Significance and Impact of the Study: A rapid inhibition of spoilage bacteria in pasteurized skim and fat milk with the nisin Z preparation of L. lactis W8 is more significant in comparison with the commercially available nisin (nisin A). The nisin Z preparation can be used instead of commercial nisin, which is not effective in fat milk.     

Antibacterial metabolites of lactic acid bacteria: Their diversity and properties

The review is devoted to literature data on antimicrobial metabolites produced by lactic acid bacteria (LAB), which have long been used for the preparation of cultured dairy products. This paper summarizes data on low-molecular-weight antimicrobial substances, which are primary products or by-products of lactic fermentation. Individual sections are devoted to a variety of antifungal agents and bacteriocins produced by LAB; their potential use as food preservatives has been discussed. The characteristics and classification of bacteriocins are presented in a greater detail; their synthesis and mechanism of action are described using the example of nisin A, which belongs to class I lantibiotics synthesized by the bacterium Lactococcus lactis subsp. lactis. The mechanism of action of class II bacteriocins has been demonstrated with lacticin. Prospective directions for using LAB antimicrobial metabolites in industry and medicine are discussed in the Conclusion.     

A comparison of the properties of bacteriocins formed by Lactococcus lactis subsp. lactis strains of diverse origin

Bacteriocins formed by four strains of Lactococcus lactis subsp. lactis have been studied and compared: 729 (a natural strain isolated from milk), 1605 (a mutant of strain 729), F-116 (a recombinant obtained by fusing of protoplasts of the two related strain 729 and 1605), and a nisin-forming strain obtained by adaptive selection at Moscow State University. Antimicrobial activity studies revealed differences between the strains in the effects on individual groups of microorganisms; the activities of the strains were also distinct from that of Nisaplin (a commercial preparation of the bacteriocin nisin). Methods for isolation and purification of bacteriocins have been developed, making it possible to obtain individual components of antibiotic complexes as chromatographically pure preparations. Bacteriocins formed by the strains of Lactococcus lactis subsp. lactis have been identified and differences in their biological and physicochemical properties, established. A novel potent broad-spectrum antibiotic substance distinct from nisin has been isolated from the recombinant strain F-116.     

Influence of the phosphorus and nitrogen source on nisin production in Lactococcus lactis subsp. lactis batch fermentations using a complex medium

The influence of different phosphorus and nitrogen sources on Lactococcus lactis subsp. lactis NIZO 22186 growth and nisin production was studied in batch fermentations using a complex medium. KH₂PO₄ was found to be the best phosphorus source for nisin production. Increasing initial phosphate concentrations from 0 to 5% KH₂PO₄ exerted a double effect, creating favourable pH conditions and particularly stimulating the nisin production levels, which were highest at 5% KH₂PO₄. Up to now, no such high initial phosphate concentrations have been reported for the production of other antibiotics or bacteriocins. Nisin, a lanthionine-containing peptide antibiotic with bacteriocin properties, clearly behaved as a primary metabolite, since its formation was linked with active growth and was not suppressed by phosphate concentrations up to 5%. A complex medium supplemented with cotton seed meal as nitrogen source also gave very high nisin yields. Correspondence to: L. De Vuyst     

Characteristics and identification of bacteriocins produced by Lactococcus lactis subsp. lactis 194-K

The Lactococcus lactis subsp. lactis 194-K strain has been established to be able to produce two bacteriocins, one of which was identified as the known lantibiotic nisin A, and the other 194-D bacteriocin represents a polypeptide with a 2589-Da molecular mass and comprises 20 amino acid residues. Both bacteriocins were produced in varying proportions in all of the studied culture media, which support the growth of the producer. Depending on the cultivation medium, the nisin A content was 380- to 1123-fold lower in the 194-K stain culture broth than that of the 194-D peptide. In comparision to nisin A Bacteriocin 194-D possessed a wide range of antibacterial activity and suppressed the growth of both Gram-positive and Gram-negative bacteria. An optimal medium for 194-D bacteriocin synthesis was shown to be a fermentation medium which contained yeast extract, casein hydrolysate, and potassium phosphate. The biosynthesis of bacteriocin 194-D by the 194-K strain in these media occurred parallel to producer growth, and its maximal accumulation in the culture broth was observed at14–20 h of the strain’s growth.     

Identification of Nisin-Producing Strains by Nisin-Controlled Gene Expression System

A specific method to identify nisin-producing strains was developed based on Nisin-Controlled gene Expression (NICE) vector pSec:Nuc. The plasmid pSec:Nuc was transformed into non-nisin-producing strain Lactococcus lactis NZ9000, a host commonly used for the NICE system. The generating strain L. lactis NZ9000/pSec:Nuc could sense extracellular inducer nisin and efficiently secrete a reporter protein Nuc, the staphylococcal nuclease (Nuc) into the medium. Instead of using purified nisin, the culture supernatants of nisin-producing strains were also used as inducers. Therefore, the NICE system could be used to identify nisin-producing strains. With this principle, 4 among 56 lactococci strains isolated from raw milk were identified as nisin producers. The results were further confirmed by polymerase chain reaction amplification with their genomic DNA as templates, and nucleotide sequencing revealed that three of them produced nisin A, and the others produced nisin Z. Those results made it possible to isolate and identify nisin-producing strains specifically and rapidly using NICE system.     

Detection of specific bacteriocin-producing lactic acid bacteria by colony hybridization

A colony hybridization method for detecting lactic acid bacteria encoding specific bacteriocins was developed. Specific PCR-generated probes were used to detect colonies of pediocin PA-1, lactococcin A, enterocin AS-48, nisin A and lacticin 481 producing strains. The probes were shown to be sensitive and specific for sequences belonging to the structural genes of the respective bacteriocins.     

Bacteriocin detection from whole bacteria by matrix-assisted laser desorption ionization-time of flight mass spectrometry

Class I bacteriocins (lantibiotics) and class II bacteriocins are antimicrobial peptides secreted by gram-positive bacteria. Using two lantibiotics, lacticin 481 and nisin, and the class II bacteriocin coagulin, we showed that bacteriocins can be detected without any purification from whole producer bacteria grown on plates by matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF-MS). When we compared the results of MALDI-TOF-MS performed with samples of whole cells and with samples of crude supernatants of liquid cultures, the former samples led to more efficient bacteriocin detection and required less handling. Nisin and lacticin 481 were both detected from a mixture of their producer strains, but such a mixture can yield additional signals. We used this method to determine the masses of two lacticin 481 variants, which confirmed at the peptide level the effect of mutations in the corresponding structural gene.     

Inhibition of Listeria innocua in Cheddar Cheese by Addition of Nisin Z in Liposomes or by In Situ Production in Mixed Culture

The effect of addition of purified nisin Z in liposomes to cheese milk and of in situ production of nisin Z by Lactococcus lactis subsp. lactis biovar diacetylactis UL719 in the mixed starter on the inhibition of Listeria innocua in cheddar cheese was evaluated during 6 months of ripening. A cheese mixed starter culture containing Lactococcus lactis subsp. lactis biovar diacetylactis UL719 was selected for high-level nisin Z and acid production. Experimental cheddar cheeses were produced on a pilot scale, using the selected starter culture, from milk with added L. innocua (10⁵ to 10⁶ CFU/ml). Liposomes with purified nisin Z were prepared from proliposome H and added to cheese milk prior to renneting to give a final concentration of 300 IU/g of cheese. The nisin Z-producing strain and nisin Z-containing liposomes did not significantly affect cheese production and gross chemical composition of the cheeses. Immediately after cheese production, 3- and 1.5-log-unit reductions in viable counts of L. innocua were obtained in cheeses with encapsulated nisin and the nisinogenic starter, respectively. After 6 months, cheeses made with encapsulated nisin contained less than 10 CFU of L. innocua per g and 90% of the initial nisin activity, compared with 10⁴ CFU/g and only 12% of initial activity in cheeses made with the nisinogenic starter. This study showed that encapsulation of nisin Z in liposomes can provide a powerful tool to improve nisin stability and inhibitory action in the cheese matrix while protecting the cheese starter from the detrimental action of nisin during cheese production.     

Nisin-selectable food-grade secretion vector for Lactococcus lactis

A nisin-resistant Lactococcus lactis strain TML01 was isolated from crude milk. A gene with 99% homology to the nisin-resistance gene, nsr, was identified. The food-grade secretion plasmid, pLEB690 (3746 bp), was constructed based on this novel nsr gene enabling primary selection with up to 5 μg nisin/ml. The functionality of pLEB690 as a secretion vector was shown by expressing and secreting the pediocin AcH gene papA in L. lactis. pLEB690 is therefore, a functional food-grade secretion vector potentially useful for the food industry.     

Spontaneous resistance in Lactococcus lactis IL1403 to the lantibiotic lacticin 3147

The ability and frequency at which target organisms can develop resistance to bacteriocins is a crucial consideration in designing and implementing bacteriocin-based biocontrol strategies. Lactococcus lactis ssp. lactis IL1403 was used as a target strain in an attempt to determine the frequency at which spontaneously resistant mutants are likely to emerge to the lantibiotic lacticin 3147. Following a single exposure to lacticin 3147, resistant mutants only emerged at a low frequency (10(-8)-10(-9)) and were only able to withstand low levels of the bacteriocin (100 AU mL(-1)). However, exposure to increasing concentrations, in a stepwise manner, resulted in the isolation of eight mutants that were resistant to moderately higher levels of lacticin 3147 (up to 600 AU mL(-1)). Interestingly, in a number of cases cross-resistance to other lantibiotics such as nisin and lacticin 481 was observed, as was cross-resistance to environmental stresses such as salt. Finally, reduced adsorption of the bacteriocin in to the cell was documented for all resistant mutants.     

Lactococcal membrane-permeabilizing antimicrobial peptides

A number of lactococcal antimicrobial peptides, bacteriocins have been discovered and characterized. Since Lactococcus spp. are generally regarded as safe bacteria, their bacteriocins are expected for various application uses. Most of lactococcal bacteriocins exert antimicrobial activity via membrane permeabilization. The most studied and prominent bacteriocin, nisin A is characterized in the high activity and has been utilized as food preservatives for more than half a century. Recently, other lactococcal bacteriocins such as lacticin Q were found to have distinguished features for further applications as the next generation to nisin.     

Loss of IrpT Function in Lactococcus lactis subsp. lactis N8 Results in Increased Nisin Resistance

The antibiotic nisin, produced by Lactococcus lactis subsp. lactis N8, offers an extensive commercial prospect as natural food preservatives. The nisin immunity of the L. lactis strains is regulated by a variety of mechanisms. In this study, we isolated a L. lactis L31 strain with increased nisin resistance from a mini-Mu transposon mutant pool of strain N8. The single Mu insertion in strain L31 was in the irpT gene with unknown function. By comparing the proteomic profiles of L. lactis L31 and its parental strain, we found that changes occurred in the synthesis of a protein involved in cell wall biosynthesis (RmlD). Strain L31 had 13.7% higher content of rhamnose in the cell wall than the N8 strain. Overexpression of RmlD involved in the synthesis of dTDP-l-rhamnose in the nisin-sensitive MG1363 strain increased nisin resistance of the strain. The results indicate that these cellular proteins effected nisin resistance in L. lactis N8.     

Bacteriocin detection by liquid chromatography/mass spectrometry for rapid identification

Aims: To establish a new system to detect and identify bacteriocins in the early stage of screening for novel bacteriocins. Methods and Results: Liquid chromatography/mass spectrometry (LC/MS) was employed for development of a new system for rapid detection and identification of bacteriocins. The system detected and identified bacteriocins such as nisin and lacticin 481 from 25 μl of culture supernatants of their producing strains by accurate mass determination coupled with simultaneous impurity removal within 40 min. Especially, the system clearly distinguished three nisin variants (A, Z, Q) in culture supernatants of their producing strains, although they have similar structures and molecular masses. Each one‐step pretreatment by cell adsorption–desorption or acetone precipitation improved bacteriocin detection dramatically, especially for mundticin KS. This system could be applied for detection and molecular mass determination of novel bacteriocins by extracting bacteriocin‐related ions. Conclusions: The developed system could detect and identify some kinds of bacteriocin from culture supernatants or pretreated samples. Significance and Impact of the Study: The developed system helps us to identify bacteriocins in the early stage of screening without any or with one‐step pretreatment. This system is effective on not only detection of known bacteriocins but also identification of novel bacteriocins. Consequently, this system will accelerate discovery of novel bacteriocins.     

Alternatives for biosurfactants and bacteriocins extraction from Lactococcus lactis cultures produced under different pH conditions

Aims: Study of the potential of Lactococcus lactis CECT‐4434 as a biosurfactants and nisin (the only bacteriocin allowed to be used in the food industry) producer for industrial applications, exploiting the possibility of recovering separately both metabolites, taking into account that L. lactis is an interesting micro‐organism with several applications in the food industry because it is recognized as GRAS. Methods and Results: The results showed the ability of this strain to produce cell‐bound biosurfactants, under controlled pH, and cell‐bound biosurfactants and bacteriocins, when pH was not controlled. Three extraction procedures were designed to separately recover these substances. Conclusions: The strain L. lactis CECT‐4434 showed to be a cell‐bound biosurfactants and bacterocins producer when fermentations were carried out under uncontrolled pH. Both products can be recovered separately. Significance and Impact of the Study: Development of a convenient tool for the extraction of cell‐bound biosurfactants and bacteriocins from the fermentation broth.     

Microbial production of bacteriocins: Latest research development and applications

Bacteriocins are low molecular weight peptides secreted by the predator bacterial cells to kill sensitive cells present in the same ecosystem competing for food and other nutrients. Exceptionally few bacteriocins along with their native antibacterial property also exhibit additional anti-viral and anti-fungal properties. Bacteriocins are generally produced by Gm+, Gm– and archaea bacteria. Bacteriocins from Gm?+?bacteria especially from lactic acid bacteria (LAB) have been thoroughly investigated considering their great biosafety and broad industrial applications. LAB expressing bacteriocins were isolated from fermented milk and milk products, rumen of animals and soil using deferred antagonism assay. Nisin is the only bacteriocin that has got FDA approval for application as a food preservative, which is produced by Lactococcus lactis subsp. Lactis. Its crystal structure explains that its antimicrobial properties are due to the binding of NH₂ terminal to lipid II molecule inhibiting the peptidoglycan synthesis and carboxy terminal forming pores in bacterial cell membrane leading to cell lysis. The hinge region connecting NH₂ and carboxy terminus has been mutated to generate mutant variants with higher antimicrobial activity. In a 50 ton fermentation of the mutant strain 3807 derived from L. lactis subsp. lactis ATCC 11454, 9,960?IU/mL of nisin was produced. Currently, high purity of nisin (>99%) is very expensive and hardly commercially available. Development of more advanced tools for cost-effective separation and purification of nisin would be commercially attractive. Chemical synthesis and heterologous expression of bacteriocins ended in low yields of pure proteins. At present, bacteriocins are almost solely applied in food industries, but they have a great potential to be used in other fields such as feeds, organic fertilizers, environmental protection and personal care products. The future of bacteriocins is largely dependent on getting FDA approval for use of other bacteriocins in addition to nisin to promote the research and applications.     

PCR Amplification of the Gene acmA Differentiates Lactococcus lactis subsp. lactis and L. lactis subsp. cremoris

The occurrence of the acmA gene, encoding the lactococcal N-acetylmuramidase in new lactococcal isolates from raw milk cheeses, has been determined. Isolates were genotypically identified to the subspecies level with a PCR technique. On the basis of PCR amplification of the acmA gene, the presence or absence of an additional amplicon of approximately 700 bp correlated with Lactococcus lactis subspecies. L. lactis subsp. lactis exhibits both the expected 1,131-bp product and the additional amplicon, whereas L. lactis subsp. cremoris exhibits a single 1,131-bp fragment.