Food-grade controlled lysis of Lactococcus lactis for accelerated cheese ripening.

An attractive approach to accelerate cheese ripening is to induce lysis of Lactococcus lactis starter strains for facilitated release of intracellular enzymes involvement in flavor formation. Controlled expression of the lytic genes lytA and lytH, which encode the lysin and the holin proteins of the lactococcal bacteriophage phi US3, respectively, was accomplished by application of a food-grade nisin-inducible expression system. Simultaneous production of lysin and holin is essential to obtain efficient lysis and concomitant release of intracellular enzymes as exemplified by complete release of the debittering intracellular aminopeptidase N. Production of holin alone leads to partial lysis of the host cells, whereas production of lysin alone does not cause significant lysis. Model cheese experiments in which the inducible holinlysin overproducing strain was used showed a fourfold increase in release of L-Lactate dehydrogenase activity into the curd relative to the control strain and the holin-overproducing strain, demonstrating the suitability of the system for cheese applications.

Controlled overproduction of proteins by lactic acid bacteria.

Lactic acid bacteria are widely used in industrial food fermentations, contributing to flavour, texture and preservation of the fermented products. Here we describe recent advances in the development of controlled gene expression systems, which allow the regulated overproduction of any desirable protein by lactic acid bacteria. Some systems benefit from the fact that the expression vectors, marker genes and inducing factors can be used directly in food applications since they are all derived from food-grade lactic acid bacteria. These systems have also been employed for the development of autolytic bacteria, suitable for various industrial applications.

Controlled gene expression systems for Lactococcus lactis with the food-grade inducer nisin.

The kinetics, control, and efficiency of nisin-induced expression directed by the nisA promoter region were studied in Lactococcus lactis with transcriptional and translational fusions to the gusA reporter genes. In the nisin-producing L. lactis strain NZ9700, the specific beta-glucuronidase activity increased very rapidly after mid-exponential growth until the maximum level at the start of the stationary phase was reached. Expression of the gusA gene was also studied in L. lactis NZ9800, an NZ9700 derivative carrying a deletion in the structural nisA gene that abolishes nisin production, and in L. lactis NZ3900, an MG1363 derivative containing the regulatory nisRK genes integrated in the chromosome. In both strains, beta-glucuronidase activity was linearly dependent on the amount of nisin added to the medium. Without nisin, no beta-glucuronidase production was observed. To optimize translation initiation, an expression vector was constructed by fusing the gusA gene translationally to the start codon of the nisA gene. Use of the translational fusion vector yielded up to six times more beta-glucuronidase activity than the transcriptional fusion vector in these strains after induction by nisin. In this way, gene expression can be achieved in a dynamic range of more than 1,000-fold. The beta-glucuronidase activity was found to be up to 25-fold higher in extracts of strain NZ3900 than in extracts of strain NZ9800. This translational fusion vector was used for high-level production of aminopeptidase N, up to 47% of the total intracellular protein. These results clearly illustrate the potential of the nisin-inducible expression system for overproduction of desired proteins.

Functional analysis of promoters in the nisin gene cluster of Lactococcus lactis.

The promoters in the nisin gene cluster nisABTCIPRKFEG of Lactococcus lactis were characterized by primer extension and transcriptional fusions to the Escherichia coli promoterless beta-glucuronidase gene (gusA). Three promoters preceding the nisA, nisR, and nisF genes, which all give rise to gusA expression in the nisin-producing strain L. lactis NZ9700, were identified. The transcriptional autoregulation of nisA by signal transduction involving the sensor histidine kinase NisK and the response regulator NisR has been demonstrated previously (0. P. Kuipers, M. M. Beerthuyzen, P. G. G. A. de Ruyter, E. J. Luesink, and W. M. de Vos, J. Biol. Chem. 270: 27299-27304, 1995), and therefore the possible nisin-dependent expression of gusA under control of the nisR and nisF promoters was also investigated. The nisR promoter was shown to direct nisin-independent gusA expression in L. lactis MG 1363, which is a nisin-transposon- and plasmid-free strain. L. lactis NZ9800, which does not produce nisin because of a deletion in the nisA gene, containing the nisF-gusA fusion plasmid, gave rise to beta-glucuronidase production only after induction by nisin. A similar regulation was found in L. lactis NZ3900, which contains a single copy of the nisR and nisK genes but no other genes of the nisin gene cluster. In contrast, when the nisK gene was disrupted, no beta-glucuronidase activity directed by the nisF promoter could be detected even after induction with nisin. These results show that, like the nisA promoter, the nisF promoter is nisin inducible. The nisF and nisA promoter sequences have significant similarities and contain a conserved region that could be important for transcriptional control.

Autoregulation of nisin biosynthesis in Lactococcus lactis by signal transduction.

The post-translationally modified, antimicrobial peptide nisin is secreted by strains of Lactococcus lactis that contain the chromosomally located nisin biosynthetic gene cluster nisABTCIPRKFEG. When a 4-base pair deletion is introduced into the structural nisA gene (delta nisA), transcription of delta nisA is abolished. Transcription of the delta nisA gene is restored by adding subinhibitory amounts of nisin, nisin mutants, or nisin analogs to the culture medium, but not by the unmodified precursor peptide or by several other antimicrobial peptides. Upon disruption of the nisK gene, which encodes a putative sensor protein that belongs to the class of two-component regulators, transcription of delta nisA was no longer inducible by nisin. Fusion of a nisA promoter fragment to the promoterless reporter gene gusA resulted in expression of gusA in L. lactis NZ9800 (delta nisA) only upon induction with nisin species. The expression level of gusA was directly related to the amount of inducer that was added extracellularly. These results provide insight into a new mechanism of autoregulation through signal transduction in prokaryotes and demonstrate that antimicrobial peptides can exert a second function as signaling molecules.