Stéphane Chaillou

The complete genome sequence of the meat-borne lactic acid bacterium Lactobacillus sakei 23K

Lactobacillus sakei is a psychrotrophic lactic acid bacterium found naturally on fresh meat and fish. This microorganism is widely used in the manufacture of fermented meats and has biotechnological potential in biopreservation and food safety. We have explored the 1,884,661-base-pair (bp) circular chromosome of strain 23K encoding 1,883 predicted genes. Genome sequencing revealed a specialized metabolic repertoire, including purine nucleoside scavenging that may contribute to an ability to successfully compete on raw meat products. Many genes appear responsible for robustness during the rigors of food processing – particularly resilience against changing redox and oxygen levels. Genes potentially responsible for biofilm formation and cellular aggregation that may assist the organism to colonize meat surfaces were also identified. This genome project is an initial step for investigating new biotechnological approaches to meat and fish processing and for exploring fundamental aspects of bacterial adaptation to these specific environments.

Lactobacillus sakei: recent developments and future prospects.

Lactobacillus sakei is one of the most important bacterial species involved in meat preservation and meat fermentation. In the last fifteen years, numerous studies have focused on this species due to its important role in food microbiology. The present paper reviews current knowledge of this emerging species in the fields of taxonomy, phylogeny and physiology, and metabolism. Recent developments in genetic tools and molecular genetics will also be emphasized to evaluate future prospects.

Population Genetics of Lactobacillus sakei Reveals Three Lineages with Distinct Evolutionary Histories

Lactobacillus sakei plays a major role in meat fermentation and in the preservation of fresh meat. The large diversity of L. sakei strains represents a valuable and exploitable asset in the development of a variety of industrial applications; however, an efficient method to identify and classify these strains has yet to be developed. In this study, we used multilocus sequence typing (MLST) to analyze the polymorphism and allelic distribution of eight loci within an L. sakei population of 232 strains collected worldwide. Within this population, we identified 116 unique sequence types with an average pairwise nucleotide diversity per site (π) of 0.13%. Results from Structure, goeBurst, and ClonalFrame software analyses demonstrated that the L. sakei population analyzed here is derived from three ancestral lineages, each of which shows evidence of a unique evolutionary history influenced by independent selection scenarios. However, the signature of selective events in the contemporary population of isolates was somewhat masked by the pervasive phenomenon of homologous recombination. Our results demonstrate that lineage 1 is a completely panmictic subpopulation in which alleles have been continually redistributed through the process of intra-lineage recombination. In contrast, lineage 2 was characterized by a high degree of clonality. Lineage 3, the earliest-diverging branch in the genealogy, showed evidence of both clonality and recombination. These evolutionary histories strongly indicate that the three lineages may correspond to distinct ecotypes, likely linked or specialized to different environmental reservoirs. The MLST scheme developed in this study represents an easy and straightforward tool that can be used to further analyze the population dynamics of L. sakei strains in food products.

Erratum to "Lactobacillus sakei: recent developments and future prospects" [Research in Microbiology 152 (2001) 839].

Lactobacillus sakei is one of the most important bacterial species involved in meat preservation and meat fermentation. In the last fifteen years, numerous studies have focused on this species due to its important role in food microbiology. The present paper reviews current knowledge of this emerging species in the fields of taxonomy, phylogeny and physiology, and metabolism. Recent developments in genetic tools and molecular genetics will also be emphasized to evaluate future prospects.

Physical and genetic map of the Lactobacillus sakei 23K chromosome.

The Lactobacillus sakei 23K chromosome was analysed by pulsed-field gel electrophoresis after digestion with the restriction enzymes AscI, NotI and SfiI. The chromosome size was estimated to be 1845+/-80 kb. The use of I-CeuI, specific for rrn genes encoding 23S rRNAs, showed that seven rrn loci were present, on 40% of the chromosome. The seven rrn clusters were mapped and their orientation was determined, allowing the position of the replication origin to be estimated. Partial I-CeuI digestions were used to construct a backbone and the different restriction fragments obtained with AscI, NotI and SfiI were assembled to a physical map by Southern hybridization. Eleven L. sakei gene clusters previously identified were mapped, as well as 25 new loci located randomly on the chromosome and 11 regions flanking the rrn gene clusters. A total of 47 clusters were thus mapped on L. sakei chromosome. The new loci were sequenced, allowing the identification of 73 complete or incomplete coding sequences. Among these 73 new genes of L. sakei, the function of 36 could be deduced from their similarity to known genes described in databases. However, 10 genes had no homologues, 10 encoded proteins similar to proteins of unknown function and 17 were similar to hypothetical proteins.

Quantification and efficiency of Lactobacillus sakei strain mixtures used as protective cultures in ground beef

Lactobacillus sakei is a lactic acid bacterium, naturally associated with long term storage of fresh meat at low temperature. Here we investigated the effect, on the evolution of pathogenic and spoilage microorganisms in ground beef, of L. sakei cocktails used as bioprotective cultures. We selectively developed a real time quantitative PCR method, allowing the quantification of individual L. sakei strains inoculated in ground meat with specific probes. Six cocktails of three strains were tested to evaluate their effect on the growth of Salmonella enterica Typhimurium, Escherichia coli O157:H7 and Brochothrix thermosphacta at 4°C and 8°C, under vacuum or modified atmosphere packaging. Using plating methods to quantify the different bacterial species, one cocktail showed an effect against S. Typhimurium and E. coli under given conditions. Real time quantitative PCR showed that the three inoculated L. sakei strains had a different growth pattern, and that the association of these three strains indeed impaired growth of S. Typhimurium and E. coli.

Selection of bioprotective cultures for preventing cold-smoked salmon spoilage

Biopreservation is a natural technology of food preservation, which consists of inoculating food with microorganisms selected for their antibacterial properties. The objective of this study was to select lactic acid bacteria (LAB) to improve the quality of cold-smoked salmon (CSS). In this work, different strains representative of the 4 dominant species, identified in a previous study by pyrosequencing the 16S rRNA gene, were isolated and their spoiling potential in CSS blocks, sterilized by ionization, was assessed by twelve trained panelists along the vacuum storage at 8°C. Photobacterium phosphoreum, Brochothrix thermosphacta and Serratia proteamaculans released strong off-odors whereas the spoiling potential of Carnobacterium divergens was weaker. The spoiling capacity of Lactococcus piscium EU2241, Leuconostoc gelidum EU2247, Lactobacillus sakei EU2885, Staphylococcus equorum S030674 and 4 commercial starters was tested by the same method and 2 strains were eliminated due to off-odor production. The effect of the 6 selected LAB against the 4 specific spoiling organisms (SSOs) selected was tested by challenge tests in sterile CSS blocks. The protective effect of the LAB differed from one SSO to another and no correlation could be established between the sensory improvement, SSO inhibition, and the implantation or acidification of protective cultures (PCs). All the PCs except L. piscium reduced the off-odors released by P. phosphoreum although some of them had no effect on its growth. S. equorum, which did not grow in CSS, favored the implantation of P. phosphoreum but prevented its off-odor formation. L. piscium was the only strain that prevented the spoilage of B. thermosphacta and S. proteamaculans although it did not grow very well and did not acidify the product. L. gelidum EU2247 inhibited the growth of these 2 SSOs and lowered the pH but had no effect on the sensory quality. Finally, L. piscium was tested in 2 naturally contaminated products, with a positive effect on 1 batch. This effect was not correlated with the microbial ecosystem as determined by acultural and cultural techniques. Based on these results, the selection strategy is discussed.

Gene Expression in Lactobacilli

Lactobacilli have always occupied an important place in food production. Their properties are widely exploited all over the world, in particular, in the preparation of food products and beverages (Table 6.1). Lactic acid fermentation is one of the oldest techniques used for the preservation of highly perishable raw materials like milk, meat, and vegetables. This method of food conservation dates back to ancient times, before recorded history. Food products fermented by lactic acid bacteria have an increased nutritive value, they are rich in flavor and are considered as hygienically safe. The unique properties of lactic acid bacteria in fermented food mainly result from their carbohydrate metabolism. Lactic acid, the main product formed during sugar metabolism, is responsible for the characteristic fresh acid taste of the fermented product. It also contributes to a “clean” fermentation process by preventing the outgrowth of pathogenic or putrefactive organisms. The preservation of food products by lactic acid bacteria is also exerted by the production of bacteriocins, antibacterial polypeptides acting on undesired pathogenic bacteria such as Listeria and Clostridium (Klaenhammer, 1988). But the most interesting aspect of lactic acid bacteria regarding food fermentation is certainly the establishment of a characteristic flavor, texture, and wholesomeness as a result of their metabolic activities, which give unique sensory properties to the fermented product.

Phenotypic and genotypic characterization of peptidoglycan hydrolases of Lactobacillus sakei

Lactobacillus sakei, a lactic acid bacterium naturally found in fresh meat and sea products, is considered to be one of the most important bacterial species involved in meat fermentation and bio-preservation. Several enzymes of Lb. sakei species contributing to microbial safeguarding and organoleptic properties of fermented-meat were studied. However, the specific autolytic mechanisms and associated enzymes involved in Lb. sakei are not well understood. The autolytic phenotype of 22 Lb. sakei strains isolated from Tunisian meat and seafood products was evaluated under starvation conditions, at pH 6.5 and 8.5, and in the presence of different carbon sources. A higher autolytic rate was observed when cells were grown in the presence of glucose and incubated at pH 6.5. Almost all strains showed high resistance to mutanolysin, indicating a minor role of muramidases in Lb. sakei cell lysis. Using Micrococcus lysodeikticus cells as a substrate in activity gels zymogram, peptidoglycan hydrolase (PGH) patterns for all strains was characterized by two lytic bands of ∼80 (B1) and ∼70 kDa (B2), except for strain BMG.167 which harbored two activity signals at a lower MW. Lytic activity was retained in high salt and in acid/basic conditions and was active toward cells of Lb. sakei, Listeria monocytogenes, Listeria ivanovii and Listeria innocua. Analysis of five putative PGH genes found in the Lb. sakei 23 K model strain genome, indicated that one gene, lsa1437, could encode a PGH (N-acetylmuramoyl-L-alanine amidase) containing B1 and B2 as isoforms. According to this hypothesis, strain BMG.167 showed an allelic version of lsa1437 gene deleted of one of the five LysM domains, leading to a reduction in the MW of lytic bands and the high autolytic rate of this strain. Characterization of autolytic phenotype of Lb. sakei should expand the knowledge of their role in fermentation processes where they represent the dominant species.