Behavior of the Meat-Borne Bacterium Lactobacillus sakei during Its Transit through the Gastrointestinal Tracts of Axenic and Conventional Mice

A Lactobacillus sakei strain named FLEC01 was isolated from human feces and characterized genotypically. Comparison of the genetic features of this strain with those of both the meat-borne L. sakei strain 23K and another human isolate, LTH5590, showed that they belong to different but closely related clusters. The three L. sakei strains did not persist and only transited through the gastrointestinal tracts (GITs) of conventional C3H/HeN mice. In contrast, they all colonized the GITs of axenic mice and rapidly reached a population of 10⁹ CFU/g of feces, which remained stable until day 51. Five days after mice were fed, a first subpopulation, characterized by small colonies, appeared and reached 50% of the total L. sakei population in mice. Fifteen to 21 days after feeding, a second subpopulation, characterized by rough colonies, appeared. It coexisted with the two other populations until day 51, and its cell shapes were also affected, suggesting a dysfunction of the cell division or cell wall. No clear difference between the behaviors of the meat-borne strain and the two human isolates in both conventional and axenic mice was observed, suggesting that L. sakei is a food-borne bacterium rather than a commensal one and that its presence in human feces originates from diet. Previous observations of Escherichia coli strains suggest that the mouse GIT environment could induce mutations to increase their survival and colonization capacities. Here, we observed similar mutations concerning a food-grade gram-positive bacterium for the first time.Although initially characterized from rice wine (28), the lactic acid bacterium species Lactobacillus sakei is considered the main representative flora of meat products, representing the major population of many fermented meat products and of raw meat stored under vacuum-packaged conditions (10, 12, 13). L. sakei is naturally present in many fish and meat products that are traditionally processed without the use of starter cultures (33). In addition, when small-scale facilities producing traditional dry fermented sausage were searched, L. sakei was detected only in the meat matrix, suggesting that meat is contaminated by this species mainly during the early processing steps (certainly by hide or feces of the animals) and not later on or by contact with the environment or materials within the facilities (2).L. sakei shows high degrees of phenotypic and genomic diversity (11-13) that may explain the difficult detection and misidentification of it in the past. For instance, although the human gut microbiota has been intensively investigated by different microbial and molecular methods for many years, the presence of L. sakei in the feces of healthy humans was reported only recently (16, 17, 26, 39). The presence of the meat-borne species L. sakei in human feces, similar to that of several other lactobacilli, could be correlated to human diet, including raw and fermented meat (or fish), for millennia (37). Considering its relatively high concentration in human feces (10⁶ per g) that was previously reported (16), L. sakei was considered as one of the predominant food-associated Lactobacillus species present in human feces. Its natural reservoir and its origin prior to meat contamination are still not known. One can hypothesize that it belongs to the intestinal microbiota of animals used for meat production, although its presence has not yet been reported in mammals and has been reported only recently in the intestines of salmonids (5).Most of the available literature on L. sakei deals with its physiology in relation to preservation, fermentation, or spoilage of meat products (see references 10 and 13 and the references therein). Since its use as an ingredient or additive bioprotective culture, to ensure microbial safety of nonfermented meat products, has been proposed (8, 10), information on its behavior in the gastrointestinal tract (GIT) after ingestion of foodstuffs is required. The purpose of this study was thus to evaluate the ability of L. sakei to survive and transit in the GIT. Therefore, we compared two independent L. sakei strains isolated from human feces to the meat-associated L. sakei 23K model strain and analyzed their behaviors in the GITs of both conventional and axenic mice.