Resistance to the Bacteriocin Lcn972 Deciphered by Genome Sequencing.

In view of the current threat of antibiotic resistance, new antimicrobials with low risk of resistance development are demanded. Lcn972 is a lactococcal bacteriocin that inhibits septum formation by binding to the cell wall precursor lipid II in Lactococcus. It has a species-specific spectrum of activity, making Lcn972 an attractive template to develop or improve existing antibiotics. The aim of this work was to identify mutations present in the Lcn972-resistant clone Lactococcus cremoris D1-20, previously evolved from the sensitive strain L. cremoris MG1614. Whole-genome sequencing and comparison over the reference genome L. cremoris MG1363 identified several unexpected mutations in the parental strain MG1614, likely selected during in-house propagation. In the Lcn972R clone, two previously identified mutations were mapped and confirmed. Additionally, another transposition event deregulating cellobiose uptake was identified along with three point mutations of unknown consequences for Lcn972 resistance. Two new independent evolution experiments exposing L. cremoris MG1614 to Lcn972 revealed transposition of IS981 into the LLMG_RS12285 locus as the predominant mutation selected by Lcn972. This event occurs early during evolution and was found in 100% of the evolved clones, while other mutations were not selected. Therefore, activation of LLMG_RS12285 coding for a putative anti-ECF (extra-cytoplasmic function) sigma factor is regarded as the main Lcn972 resistance factor in L. cremoris MG1614.

Resident TP712 Prophage of Lactococcus lactis Strain MG1363 Provides Extra Holin Functions to the P335 Phage CAP for Effective Host Lysis.

Prophages are widely present in Lactococcus lactis, a lactic acid bacterium (LAB) that plays a key role in dairy fermentations. L. lactis MG1363 is a laboratory strain used worldwide as a model LAB. Initially regarded as plasmid and prophage free, MG1363 carries two complete prophages, TP712 and MG-3. Only TP712 seems to be inducible but unable to lyse the host. Several so-called TP712 lysogens able to lyse upon prophage induction were reported in the past, but the reason for their lytic phenotype remained unknown. In this work, we describe CAP, a new P335 prophage detected in the "lytic TP712 lysogens" which had remained unnoticed. CAP is able to be excised after mitomycin C treatment, along with TP712, and able to infect L. lactis MG1363-like strains but not the lytic TP712 lysogens. Both phages cooperate for efficient host lysis. While the expression in trans of the CAP lytic genes was sufficient to trigger cell lysis, this process was boosted when the resident TP712 prophage was concomitantly induced. Introduction of mutations into the TP712 lytic genes revealed that its holin but not its endolysin plays a major role. Accordingly, it is shown that the lytic activity of the recombinant CAP endolysin relies on membrane depolarization. Revisiting the seminal work that generated the extensively used L. lactis MG1363 strain led us to conclude that the CAP phage was originally present in its ancestor, L. lactis NCDO712, and our results solved long-standing mysteries around the MG1363 resident prophage TP712 reported in the "presequencing" era. IMPORTANCE Prophages are bacterial viruses that integrate into the chromosomes of bacteria until an environmental trigger induces their lytic cycle, ending with lysis of the host. Prophages present in dairy starters can compromise milk fermentation and represent a serious threat in dairy plants. In this work, we discovered that two temperate phages, TP712 and CAP, infecting the laboratory strain Lactococcus lactis MG1363 join forces to lyse the host. Based on the in vitro lytic activity of the LysCAP endolysin, in combination with mutated versions of TP712 lacking either its holin or endolysin, we conclude that this cooperation relies on the combined activity of the holins of both phages that boost the activity of LysCAP. The presence of an additional prophage explains the lytic phenotype of the lysogens formerly thought to be single TP712 lysogens that had remained a mystery for many years.

Reduced Binding of the Endolysin LysTP712 to Lactococcus lactis ΔftsH Contributes to Phage Resistance.

Absence of the membrane protease FtsH in Lactococcus lactis hinders release of the bacteriophage TP712. In this work we have analyzed the mechanism responsible for the non-lytic phenotype of L. lactis ΔftsH after phage infection. The lytic cassette of TP712 contains a putative antiholin-pinholin system and a modular endolysin (LysTP712). Inducible expression of the holin gene demonstrated the presence of a dual start motif which is functional in both wildtype and L. lactis ΔftsH cells. Moreover, simulating holin activity with ionophores accelerated lysis of wildtype cells but not L. lactis ΔftsH cells, suggesting inhibition of the endolysin rather than a role of FtsH in holin activation. However, zymograms revealed the synthesis of an active endolysin in both wildtype and L. lactis ΔftsH TP712 lysogens. A reporter protein was generated by fusing the cell wall binding domain of LysTP712 to the fluorescent mCherry protein. Binding of this reporter protein took place at the septa of both wildtype and L. lactis ΔftsH cells as shown by fluorescence microscopy. Nonetheless, fluorescence spectroscopy demonstrated that mutant cells bound 40% less protein. In conclusion, the non-lytic phenotype of L. lactis ΔftsH is not due to direct action of the FtsH protease on the phage lytic proteins but rather to a putative function of FtsH in modulating the architecture of the L. lactis cell envelope that results in a lower affinity of the phage endolysin to its substrate.

A bacteriocin gene cluster able to enhance plasmid maintenance in Lactococcus lactis.

BACKGROUND: Lactococcus lactis is widely used as a dairy starter and has been extensively studied. Based on the acquired knowledge on its physiology and metabolism, new applications have been envisaged and there is an increasing interest of using L. lactis as a cell factory. Plasmids constitute the main toolbox for L. lactis genetic engineering and most rely on antibiotic resistant markers for plasmid selection and maintenance. In this work, we have assessed the ability of the bacteriocin Lactococcin 972 (Lcn972) gene cluster to behave as a food-grade post-segregational killing system to stabilize recombinant plasmids in L. lactis in the absence of antibiotics. Lcn972 is a non-lantibiotic bacteriocin encoded by the 11-kbp plasmid pBL1 with a potent antimicrobial activity against Lactococcus. RESULTS: Attempts to clone the full lcn972 operon with its own promoter (P972), the structural gene lcn972 and the immunity genes orf2-orf3 in the unstable plasmid pIL252 failed and only plasmids with a mutated promoter were recovered. Alternatively, cloning under other constitutive promoters was approached and achieved, but bacteriocin production levels were lower than those provided by pBL1. Segregational stability studies revealed that the recombinant plasmids that yielded high bacteriocin titers were maintained for at least 200 generations without antibiotic selection. In the case of expression vectors such as pTRL1, the Lcn972 gene cluster also contributed to plasmid maintenance without compromising the production of the fluorescent mCherry protein. Furthermore, unstable Lcn972 recombinant plasmids became integrated into the chromosome through the activity of insertion sequences, supporting the notion that Lcn972 does apply a strong selective pressure against susceptible cells. Despite of it, the Lcn972 gene cluster was not enough to avoid the use of antibiotics to select plasmid-bearing cells right after transformation. CONCLUSIONS: Inserting the Lcn972 cluster into segregational unstable plasmids prevents their lost by segregation and probable could be applied as an alternative to the use of antibiotics to support safer and more sustainable biotechnological applications of genetically engineered L. lactis.

Lack of the host membrane protease FtsH hinders release of the Lactococcus lactis bacteriophage TP712.

The temperate bacteriophage TP712 was unable to plaque on Lactococcus lactis ΔftsH lacking the membrane protease FtsH and complementation in trans restored the WT phenotype. Absence of ftsH did not hinder phage adsorption, phage DNA delivery or activation of the lytic cycle. Thin sections revealed that TP712 virions appeared to be correctly assembled inside the ΔftsH host, but were not released. These virions were infective, demonstrating that a functional host FtsH is required by TP712 to proceed effectively with lysis of the host.

The putative lactococcal extracytoplasmic function anti-sigma factor llmg2447 determines resistance to the cell wall-active bacteriocin lcn972.

Lactococcin 972 (Lcn972) is a cell wall-active bacteriocin that inhibits cell wall biosynthesis in Lactococcus lactis. In this work, the transcriptomes of the Lcn972-resistant (Lcn(r)) mutant L. lactis D1 and its parent strain were compared to identify factors involved in Lcn972 resistance. Upregulated genes included members of the cell envelope stress (CesSR) regulon, the penicillin-binding protein pbpX gene and gene llmg2447, which may encode a putative extracytoplasmic function (ECF) anti-sigma factor. The gene llmg2447 is located downstream of the nonfunctional ECF gene sigX(pseudo). Nisin-controlled expression of llmg2447 led to high Lcn972 resistance in L. lactis, with no cross-resistance to other cell wall-active antimicrobials. Upregulation of llmg2447 in L. lactis D1 (Lcn(r)) was linked to the integration of insertion element IS981 into the llmg2447 promoter region, replacing the native -35 box and activating the otherwise silent promoter P(2447). This is the first example of an orphan ECF anti-sigma factor involved in bacteriocin resistance. This new role in neutralizing cell wall-active compounds (e.g., Lcn972) could have evolved from a putative primary function of Llmg2447 in sensing cell envelope stress.

The Lcn972 bacteriocin-encoding plasmid pBL1 impairs cellobiose metabolism in Lactococcus lactis.

pBL1 is a Lactococcus lactis theta-replicating 10.9-kbp plasmid that encodes the synthetic machinery of the bacteriocin Lcn972. In this work, the transcriptomes of exponentially growing L. lactis strains with and without pBL1 were compared. A discrete response was observed, with a total of 10 genes showing significantly changed expression. Upregulation of the lactococcal oligopeptide uptake (opp) system was observed, which was likely linked to a higher nitrogen demand required for Lcn972 biosynthesis. Strikingly, celB, coding for the membrane porter IIC of the cellobiose phosphoenolpyruvate-dependent phosphotransferase system (PTS), and the upstream gene llmg0186 were downregulated. Growth profiles for L. lactis strains MG1363, MG1363/pBL1, and MG1363 ΔcelB grown in chemically defined medium (CDM) containing cellobiose confirmed slower growth of MG1363/pBL1 and MG1363 ΔcelB, while no differences were observed with growth on glucose. The presence of pBL1 shifted the fermentation products toward a mixed acid profile and promoted substantial changes in intracellular pool sizes for glycolytic intermediates in cells growing on cellobiose as determined by high-pressure liquid chromatography (HPLC) and nuclear magnetic resonance (NMR). Overall, these data support the genetic evidence of a constriction in cellobiose uptake. Notably, several cell wall precursors accumulated, while other UDP-activated sugar pools were lower, which could reflect rerouting of precursors toward the production of structural or storage polysaccharides. Moreover, cells growing slowly on cellobiose and those lacking celB were more tolerant to Lcn972 than cellobiose-adapted cells. Thus, downregulation of celB could help to build up a response against the antimicrobial activity of Lcn972, enhancing self-immunity of the producer cells.

Contribution of the CesR-regulated genes llmg0169 and llmg2164-2163 to Lactococcus lactis fitness.

Lactococcus lactis is one of the main components of the starter cultures used in cheese manufacture. As starter, L. lactis must tolerate harsh conditions encountered either during their production in bulk quantities or during dairy products processing. To face these hostile conditions, bacteria monitor the environment and respond by modifying gene expression appropriately. Previous transcriptomic studies showed that the two component system CesSR is the main pathway that triggers the cell envelope stress response in L. lactis treated with lactococcin 972 (Lcn972), a cell wall synthesis inhibiting bacteriocin. Among the CesR-regulated genes, llmg0169 and the operon llmg2164-2163, encoding proteins of unknown function, are among the highest up-regulated genes after activation of CesSR. In this study, we have assessed the contribution of these genes to the survival of L. lactis to different technologically-relevant stresses. Overexpressing and knock-out mutants of the genes were generated and their viability to low pH, heat, freeze-drying, presence of NaCl, cell wall antimicrobials and lytic phages attack was compared to the wild type strain. The genes llmg0169 and llmg2164-2163 contributed differently to L. lactis fitness. L. lactis Deltallmg0169 was very sensitive to heat treatment while L. lactis Deltallmg2164 was more sensitive to NaCl. Absence of both genes also compromised viability at low pH. On the contrary, higher expression levels of llmg0169 and llmg2164-2163, up to 26- and 14-fold increase determined by qRT-PCR, respectively, did not enhance L. lactis survival in any of the above stressful conditions (heat, pH and NaCl) or after freeze-drying. All the mutants displayed a similar phage susceptibility profile. Overexpression of llmg2164-2163 seemed to specifically protect L. lactis against the bacteriocin Lcn972 but not against other cell wall active antimicrobials. Based on our phenotypic analysis, the investigated genes are required to mount a proper response to guarantee survival of L. lactis under technologically-relevant stresses and their functionality could be a useful marker to select robust dairy starters.

Structure of the high-molecular weight exopolysaccharide isolated from Lactobacillus pentosus LPS26.

The strain Lactobacillus pentosus LPS26 produces a capsular polymer composed of a high- (2.0x10(6)Da) (EPS A) and a low-molecular mass (2.4x10(4)Da) (EPS B) polysaccharide when grown on semi-defined medium containing glucose as the carbon source. The structure of EPS A and its deacetylated form has been determined by monosaccharide and methylation analysis as well as by 1D/2D NMR studies ((1)H and (13)C). We conclude that EPS A is a charged heteropolymer, with a composition of D-glucose, D-glucuronic acid and L-rhamnose in a molar ratio 1:2:2. The repeating unit is a pentasaccharide with two O-acetyl groups at O-4 of the 3-substituted alpha-D-glucuronic acid and at O-2 of the 3-substituted beta-L-rhamnose, respectively. -->4)-alpha-D-Glcp-(1-->3)-alpha-D-GlcpA4Ac-(1-->3)-alpha-L-Rhap-(1-->4)-alpha-D-GlcpA-(1-->3)-beta-L-Rhap2Ac-(1--> This unbranched structure is not common in EPSs produced by Lactobacilli. Moreover, the presence of acetyl groups in the structure is an unusual feature which has only been reported in L. sake 0-1 [Robijn et al. Carbohydr. Res., 1995, 276, 117-136].