Streptococcus thermophilus urease activity boosts Lactobacillus delbrueckii subsp. bulgaricus homolactic fermentation.

The proto-cooperation between Streptococcus thermophilus and Lactobacillus delbrueckii subsp. bulgaricus in the yogurt consortium enhances the growth rate and size of each population. In contrast, the independent growth of the two species in milk leads to a slower growth rate and a smaller population size. In this study, we report the first evidence that the urease activity of S. thermophilus increases the intracellular pH of L. delbrueckii in the absence of carbon source. However, in milk, in the presence of lactose the alkalizing effect of urea-derived ammonia was not detectable. Nevertheless, based on glucose consumption and lactic acid production at different pHin, L. delbrueckii showed an optimum of glycolysis and homolactic fermentation at alkaline pH values. In milk, we observed that ammonia provided by urea hydrolysis boosted lactic acid production in S. thermophilus and in L. delbrueckii when the species were grown alone or in combination. Therefore, we propose that urease activity acts as an altruistic cooperative trait, which is costly for urease-positive individuals but provides a local benefit because other individuals can take advantage of urease-dependent ammonia release.

Cholesterol removal capability of lactic acid bacteria and related cell membrane fatty acid modifications.

Milk and dairy products play an important role in a healthy diet because of their high nutritional value, even if they represent a source of lipids and cholesterol. Nowadays, some commercially hypocholesterolemic products are available, which contain lactic acid bacteria (LAB). Therefore, the aims of this study were to test and compare the cholesterol removal abilities of different LAB species and to investigate the capacity of the cholesterol to change the cellular fatty acid composition of microorganisms. Fifty-eight strains of dairy LAB were studied for their ability to remove cholesterol during 24 h of growth. Two of them, L. plantarum 885 and L. acidophilus LA-5®, showed the higher reduction capability. For these strains, the cellular fatty acid composition was studied. They showed a different behaviour, which appeared related to the needs of the cells to maintain the characteristics of membrane fluidity, but was dependent upon their original fatty acid composition. Further studies are required to better characterise the LAB strains to be used to develop fermented dairy products with reduced cholesterol content or be able to induce hypocholesterolemic effects. It will also be interesting to investigate the possible modifications of the cell membrane caused by cholesterol and its possible involvement in cell metabolism.