Role of the Sortase A in the Release of Cell-Wall Proteinase PrtS in the Growth Medium of Streptococcus thermophilus 4F44.

Growth of the lactic acid bacterium Streptococcus thermophilus in milk depends on its capacity to hydrolyze proteins of this medium through its surface proteolytic activity. Thus, strains exhibiting the cell envelope proteinase (CEP) PrtS are able to grow in milk at high cellular density. Due to its LPNTG motif, which is possibly the substrate of the sortase A (SrtA), PrtS is anchored to the cell wall in most S. thermophilus strains. Conversely, a soluble extracellular PrtS activity has been reported in the strain 4F44. It corresponds, in fact, to a certain proportion of PrtS that is not anchored to the cell wall but rather is released in the growth medium. The main difference between PrtS of strain 4F44 (PrtS4F44) and other PrtS concerns the absence of a 32-residue imperfect duplication in the prodomain of the CEP, postulated as being required for the maturation and correct subsequent anchoring of PrtS. In fact, both mature (without the prodomain at the N-terminal extremity) and immature (with the prodomain) forms are found in the soluble PrtS4F44 form along with an intact LPNTG at their C-terminal extremity. Investigations we present in this work show that (i) the imperfect duplication is not implied in PrtS maturation; (ii) the maturase PrtM is irrelevant in PrtS maturation which is probably automaturated; and (iii) SrtA allows for the PrtS anchoring in S. thermophilus but the SrtA of strain 4F44 (SrtA4F44) displays an altered activity.

Implication of sortase-dependent proteins of Streptococcus thermophilus in adhesion to human intestinal epithelial cell lines and bile salt tolerance.

Streptococcus thermophilus (ST) is a lactic acid bacterium widely used in dairy industry and displays several properties which could be beneficial for host. The objective of this study was to investigate, in vitro, the implication of sortase A (SrtA) and sortase-dependent proteins (SDPs) in the adhesion of ST LMD-9 strain to intestinal epithelial cells (IECs) and resistance to bile salt mixture (BSM; taurocholoate, deoxycholate, and cholate). The effect of mutations in prtS (protease), mucBP (MUCin-Binding Protein), and srtA genes in ST LMD-9 in these mechanisms were examined. The HT29-MTX, HT29-CL.16E, and Caco-2 TC7 cell lines were used. HT29-MTX and HT29-CL.16E cells express different mucins found in the gastro intestinal tract; whereas, Caco-2 TC7 express cell surface proteins found in the small intestine. All mutants showed different adhesion profiles depending on cell lines. The mutation in genes srtA and mucBP leads to a significant decrease in LMD-9 adhesion capacity to Caco-2 TC7 cells. A mutation in mucBP gene has also shown a significant decrease in LMD-9 adhesion capacity to HT29-CL.16E cells. However, no difference was observed using HT29-MTX cells. Furthermore, ST LMD-9 and srtA mutant were resistant to BSM up to 3 mM. Contrariwise, no viable bacteria were detected for prtS and mucBP mutants at this concentration. Two conclusions could be drawn. First, SDPs could be involved in the LMD-9 adhesion depending on the cell lines indicating the importance of eukaryotic-cell surface components in adherence. Second, SDPs could contribute to resistance to bile salts probably by maintaining the cell membrane integrity.

Use of the dynamic gastro-intestinal model TIM to explore the survival of the yogurt bacterium Streptococcus thermophilus and the metabolic activities induced in the simulated human gut.

Streptococcus thermophilus, a lactic acid bacterium used to produce yogurts and cheeses is more and more considered for its potential probiotic properties. This implies that additional information should be obtained regarding its survival and metabolic activity in the human Gastro-Intestinal Tract (GIT). In this study, we screened 30 S. thermophilus strains for urease, small heat shock protein, and amino-acid decarboxylase functions which may play a role in survival in the upper part of the GIT. The survival kinetics of 4 strains was investigated using the TIM, a physiologically relevant in vitro dynamic gastric and small intestinal model. The three strains LMD9, PB18O and EBLST20 showed significantly higher survival than CNRZ21 in all digestive compartments of the TIM, which may be related to the presence of urease and heat shock protein functions. When LMD9 bacterial cells were delivered in a fermented milk formula, a significant improvement of survival in the TIM was observed compared to non-fermented milk. With the RIVET (Recombinase In Vivo Expression Technology) method applied to the LMD9 strain, a promoter located upstream of hisS, responsible for the histidyl-transfer RNA synthesis, was found to be specifically activated in the artificial stomach. The data generated on S. thermophilus survival and its adaptation capacities to the digestive tract are essential to establish a list of biomarkers useful for the selection of probiotic strains.

Hydrolysis of milk-derived bioactive peptides by cell-associated extracellular peptidases of Streptococcus thermophilus.

The trend to confer new functional properties to fermented dairy products by supplementation with bioactive peptides is growing in order to encounter the challenge of health-promoting foods. But these functional ingredients have not to be hydrolysed by proteases of bacteria used in the manufacture of these products. One of the two yoghurt bacteria, Streptococcus thermophilus, has long been considered as weakly proteolytic since its only cell wall-associated subtilisin-like protease, called PrtS, is not always present. Nevertheless, a recent study pointed out a possible peptidase activity in certain strains. In this present study, the stability of milk-derived bioactive peptides, e.g. the anxiolytic peptide, αs1-CN-(f91-97), in the presence of two different S. thermophilus strains with PrtS+ or PrtS− phenotype was studied. Both strains appeared to be capable of hydrolysing the αs1-CN-(f91-97) and other bioactive peptides by recurrent removal of N-terminal residues. The hydrolysis was neither due to intracellular peptidases nor to HtrA protease. Results obtained showed that the observed activity originates from the presence at the surface of both strains of an extracellular aminopeptidase activity. Moreover, a cell wall-associated X-prolyl dipeptidyl peptidase activity was also highlighted when ß-casomorphin-7 was used as substrate. All of these findings suggest that, in order to use fermented milks as vector of bioactive peptides, the stability of these bioactive peptides in this kind of products implies to carefully characterize the potential action of the surface proteolytic enzymes of S. thermophilus.

Variability of hydrolysis of ß-, αs1-, and αs2-caseins by 10 strains of Streptococcus thermophilus and resulting bioactive peptides.

Milk proteins contain numerous potential bioactive peptides, which may be released by digestive proteases or by the proteolytic system of lactic acid bacteria during food processing. The capacity of Streptococcus thermophilus to generate peptides, especially bioactive peptides, from bovine caseins was investigated. Strains expressing various levels of the cell envelope proteinase, PrtS, were incubated with α(s1)-, α(s2)-, or ß-casein. Analysis of the supernatants by LC-ESI-MS/MS showed that the ß-casein was preferentially hydrolyzed, followed by α(s2)-casein and then α(s1)-casein. Numbers and types of peptides released were strain-dependent. Hydrolysis appeared to be linked with the accessibility of different casein regions by protease. Analysis of bonds hydrolyzed in the region 1-23 of α(s1)-casein suggests that PrtS is at least in part responsible for the peptide production. Finally, among the generated peptides, 13 peptides from ß-casein, 5 from α(s2)-casein, and 2 from α(s1)-casein have been reported as bioactive, 15 of them being angiotensin-converting enzyme inhibitors.

Molecular typing of industrial strains of Pseudomonas spp. isolated from milk and genetical and biochemical characterization of an extracellular protease produced by one of them.

P. fluorescens is responsible for the highest depredation of milk because of its capacity to synthesize extracellular lipase and protease which hydrolyze milk fat and proteins. Several P. fluorescens synthesize an extracellular caseinolytic metalloprotease, called AprX. It is important to rapidly detect the presence of a contamination of raw milk by a strain, especially a P. fluorescens strain, having a high potential of depredation. If standard plate count procedures are often employed, they are time consuming and do not permit to rapidly evaluate the potential of depredation. An alternative method consists to search the aprX gene, but such a method remains of low sensitivity and does not allow evaluating the real potential of depredation of the contaminant. After a milk depredation event, three strains of Pseudomonas spp. (F, 2312 and 2313) have been isolated from a dairy plant. Using molecular and phenotypic approaches, these strains were identified as P. fluorescens strains. Their respective extracellular caseinolytic potential was characterized as well as that of several collection strains of P. fluorescens. It appeared that these strains secreted one protease of about 45 kDa, that their extracellular caseinolytic potential was highly variable for one strain to another and that the one of strain F was the highest. The protease secreted by the strain F was purified and its N-terminal sequence established. It shared 100% identity with the domain 14-34 of extracellular alkaline endoprotease sequences which are called AprX for some of them. Its gene was sequenced as well as that of two collection strains of P. fluorescens having a significant lower extracellular caseinolytic potential. The genomic environment of the aprX gene as well as its expression during the strain growth was investigated. It appears that the difference of extracellular caseinolytic potential which has been observed between the three strains does not mainly result from the AprX sequence/structure but it might rather result from the aprX level of expression.

Identification of an iron-binding protein of the Dps family expressed by Streptococcus thermophilus.

Streptococcus thermophilus PB18 can grow between 20 degrees and 52 degrees C and is resistant to various stresses such as heat, acidic or cold shock. During cold shock, a protein of 21.5 kDa was previously shown to be induced in S. thermophilus. In addition to its cold-shock induction, 2D-PAGE revealed that the 21.5-kDa protein was also expressed during the stationary phase of growth. The recent access to the genome sequence of S. thermophilus LMG18311 allowed the identification of a 173-amino acid protein displaying a strong homology between the 21.5-kDa protein and members of the Dps family of proteins. Specific staining of non-denaturing polyacrylamide gel electrophoresis (ND-PAGE) followed by two-dimensional PAGE (2D-PAGE) showed that the 21.5-kDa protein was an iron-binding protein.

A 16 kDa protein family overexpressed by Streptococcus thermophilus PB18 in acid environments.

The one- and two-dimensional protein patterns of Streptococcus thermophilus PB18 in the exponential and stationary phases of growth were analysed. One-dimensional SDS-PAGE showed that a 16 kDa protein was overexpressed in stationary phase as well as 2 h after an acid shock, and that it was not expressed when the bacteria reached the stationary phase in medium with limiting lactose concentrations (5 or 10 g l-1), in which the pH (5.5) was not as acid as in control cultures (pH 4.7, lactose 20 g l-1). The results support the idea that this protein is expressed in response to the acidic environment and not in response to the growth phase. Two-dimensional PAGE showed that nine proteins were expressed only during the exponential phase and ten others only during the stationary phase. The 16 kDa band seen in one-dimensional SDS-PAGE corresponded to a 16 kDa protein family observed on two-dimensional SDS-PAGE/IEF gels, whose expression was increased 8.5-fold when the extracellular pH reached a critical value below 5.0. The N-terminal sequences of proteins from two spots on the two-dimensional gels (members of the 16 kDa family) were determined and found to be identical. The physiological role of this protein family has not yet been elucidated.