Abstract
Although Carnobacterium maltaromaticum derived from dairy products has been used as a lactic acid bacterium industrially, several studies have reported potential pathogenicity and disease outbreaks. Because strains derived from diseased fish and dairy products are considered potentially virulent and beneficial, respectively, their genotypic and phenotypic characteristics have attracted considerable attention. A genome-wide comparison of 30 genome sequences (13, 3, and 14 strains from diseased aquatic animals, dairy products, and processed food, respectively) was carried out. Additionally, one dairy and two nondairy strains were incubated in nutrient-rich (diluted liquid media) and nutrient-deficient environments (PBS) at pH 10 to compare their alkaline resistance in accordance with different nutritional environments by measuring their optical density and viable bacterial cell counts. Interestingly, only dairy strains carried 11 shared accessory genes, and 8 genes were strongly involved in the V-type ATPase gene cluster. Given that V-type ATPase contributes to resistance to alkaline pH and salts using proton motive force generated via sodium translocation across the membrane, C. maltaromaticum with a V-type ATPase might use nutrients in food under high pH. Indeed, the dairy strain carrying the V-type ATPase exhibited the highest alkaline resistance only in the nutrient-rich environment with significant upregulation of V-type ATPase expression. These results suggest that the gene cluster of V-type ATPase and increased alkaline resistance of dairy strains facilitate adaptation in the long-term ripening of alkaline dairy products.
Highlights
Lactic acid bacteria (LAB) are among the most well-known bioresources widely used industrially. They are used in the ripening of dairy products and in probiotics, and their role and importance in ripening soft cheeses are well established [1,2,3]
Because most LAB participate in acidic microbial processes via lactate fermentation during the first phase of the ripening of soft cheese, the pH of dairy products is decreased [7]
30 strains of C. maltaromaticum were 3952 and 3226 in 18ISCm and ML-1-97, and an ave of 3386 coding sequences (CDS) was found in CDS
Summary
Lactic acid bacteria (LAB) are among the most well-known bioresources widely used industrially They are used in the ripening of dairy products and in probiotics, and their role and importance in ripening soft cheeses are well established [1,2,3]. Ammonia-producing microorganisms (e.g., Penicillium caseicolum and Geotrichum candidum) metabolize lactic acid and produce ammonia (NH3 ), which creates an alkaline environment in the ripening of dairy products [5,8]. These phenomena directly affect the switch in the composition of microbiota from aciduric to nonaciduric bacteria [1,5,9]. Nonstarter LAB (NSLAB), which are predominantly isolated from the ripening of cheese at low temperature and
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