Functional analysis of putative adhesion factors in Lactobacillus acidophilus NCFM

Lactobacilli are major inhabitants of the normal microflora of the gastrointestinal tract, and some select species have been used extensively as probiotic cultures. One potentially important property of these organisms is their ability to interact with epithelial cells in the intestinal tract, which may promote retention and host-bacterial communication. However, the mechanisms by which they attach to intestinal epithelial cells are unknown. The objective of this study was to investigate cell surface proteins in Lactobacillus acidophilus that may promote attachment to intestinal tissues. Using genome sequence data, predicted open reading frames were searched against known protein and protein motif databases to identify four proteins potentially involved in adhesion to epithelial cells. Homologous recombination was used to construct isogenic mutations in genes encoding a mucin-binding protein, a fibronectin-binding protein, a surface layer protein, and two streptococcal R28 homologs. The abilities of the mutants to adhere to intestinal epithelial cells were then evaluated in vitro. Each strain was screened on Caco-2 cells, which differentiate and express markers characteristic of normal small-intestine cells. A significant decrease in adhesion was observed in the fibronectin-binding protein mutant (76%) and the mucin-binding protein mutant (65%). A surface layer protein mutant also showed reduction in adhesion ability (84%), but the effect of this mutation is likely due to the loss of multiple surface proteins that may be embedded in the S-layer. This study demonstrated that multiple cell surface proteins in L. acidophilus NCFM can individually contribute to the organism's ability to attach to intestinal cells in vitro.     

Molecular analysis of mutated Lactobacillus acidophilus promoter-like sequence P15

The promoter-like sequence P15 that was previously cloned from the chromosome of Lactobacillus acidophilus ATCC 4356 is active in Lactobacillus reuteri, Lactobacillus plantarum, Lactobacillus acidophilus, and Escherichia coli, but not in Lactococcus lactis. N-methyl-N-nitroso-N-guanidine (MNNG) mutagenesis of P15 was used to select for a promoter active in L. lactis MG1363. Molecular analysis of the mutated promoter (designated P16) revealed a 90 bp deletion and a T-->A transversion. This deletion, in combination with the addition to the transversion, created a promoter with putative -35 and -10 hexamers identical to the consensus promoter sequence found in E. coli and Bacillus subtilis vegetative promoters. The activity of P16 was measured by its ability to promote chloramphenicol resistance in different bacteria when inserted in the promoter-probe plasmid pBV5030 (designated pLA16). The MIC of chloramphenicol in L. lactis, L. reuteri, L. plantarum, E. coli, and L. acidophilus harbouring pLA16 were 30, 170, 180, > 500, and 3 micrograms/mL, respectively. This represents an increase in promoter activity compared to P15 in L. reuteri of 3-fold, in L. plantarum of 9-fold, and in E. coli of at least 2.5-fold, but a decrease in L. acidophilus of 7-fold.     

Characterization of natural isolate Lactobacillus acidophilus BGRA43 useful for acidophilus milk production

Lactobacillus acidophilus BGRA43 was selected from a set of human origin isolates of Lact. acidophilus strains for the highest growth rates and antagonistic effect against both Gram-positive and Gram-negative bacteria. The strain BGRA43 also exhibited an inhibitory effect on the growth of Clostridium sporogenes. Inhibition of this strain seems to be due to lactic acid production rather than hydrogen peroxide or bacteriocin. Growth of Lact. acidophilus BGRA43 in non-fat skim milk for 6 h at 37 °C resulted in a lowering of the pH value to 4·53. Besides the fast acidification, this strain generated a high viscosity of skim milk. These characteristics make the strain BGRA43 attractive for acidophilus milk production. Lactobacillus acidophilu s BGRA43 produces an extracellular proteinase. Whole cells efficiently degraded casein for 3 h at 37 °C especially α- and β-casein fractions. Total DNA isolated from the strain BGRA43 did not show any hybridization with lactococcal proteinase probes indicating that this strain produces a distinctive proteinase.     

LC-MS/MS analysis of surface layer proteins as a useful method for the identification of lactobacilli from the Lactobacillus acidophilus group

For precise identification of a Lactobacillus K1 isolate, LC-MS/MS analysis of the putative surface layer protein was performed. The results obtained from LTQ-FT-ICR mass spectrometry confirmed that the analyzed protein spot is the surface layer protein originating from Lb. helveticus species. Moreover, the identified protein has the highest similarity with the surface layer protein from Lb. helveticus R0052. To evaluate the proteomic study, multilocus sequence analysis of selected housekeeping gene sequences was performed. Combination of 16S rRNA sequencing with partial sequences for the genes encoding the RNA polymerase alpha subunit (rpoA), phenylalanyl-tRNA synthase alpha subunit (pheS), translational elongation factor Tu (tuf), and Hsp60 chaperonins (groEL) also allowed to classify the analyzed isolate as Lb. helveticus. Further classification at the strain level was achieved by sequencing of the slp gene. This gene showed 99.8% identity with the corresponding slp gene of Lb. helveticus R0052, which is in good agreement with data obtained by nano-HPLC coupled to an LTQ-FT-ICR mass spectrometer. Finally, LC-MS/ MS analysis of surface layer proteins extracted from three other Lactobacillus strains proved that the proposed method is the appropriate molecular tool for the identification of S-layer-possessing lactobacilli at the species and even strain levels.     

Characterization of Rhamnosidases from Lactobacillus plantarum and Lactobacillus acidophilus

Lactobacilli are known to use plant materials as a food source. Many such materials are rich in rhamnose-containing polyphenols, and thus it can be anticipated that lactobacilli will contain rhamnosidases. Therefore, genome sequences of food-grade lactobacilli were screened for putative rhamnosidases. In the genome of Lactobacillus plantarum, two putative rhamnosidase genes (ram1_Lp and ram2_Lp) were identified, while in Lactobacillus acidophilus, one rhamnosidase gene was found (ramA_La). Gene products from all three genes were produced after introduction into Escherichia coli and were then tested for their enzymatic properties. Ram1_Lp, Ram2_Lp, and RamA_La were able to efficiently hydrolyze rutin and other rutinosides, while RamA_La was, in addition, able to cleave naringin, a neohesperidoside. Subsequently, the potential application of Lactobacillus rhamnosidases in food processing was investigated using a single matrix, tomato pulp. Recombinant Ram1_Lp and RamA_La enzymes were shown to remove the rhamnose from rutinosides in this material, but efficient conversion required adjustment of the tomato pulp to pH 6. The potential of Ram1_Lp for fermentation of plant flavonoids was further investigated by expression in the food-grade bacterium Lactococcus lactis. This system was used for fermentation of tomato pulp, with the aim of improving the bioavailability of flavonoids in processed tomato products. While import of flavonoids into L. lactis appeared to be a limiting factor, rhamnose removal was confirmed, indicating that rhamnosidase-producing bacteria may find commercial application, depending on the technological properties of the strains and enzymes.Lactobacilli such as Lactobacillus plantarum have been used for centuries to ferment vegetables such as cabbage, cucumber, and soybean (34). Fruit pulps, for instance, those from tomato, have also been used as a substrate for lactobacilli for the production of probiotic juices (38). Recently, the full genomic sequences of several lactobacilli have become available (1, 22). A number of the plant-based substrates for lactobacilli are rich in rhamnose sugars, which are often conjugated to polyphenols, as in the case of cell wall components and certain flavonoid antioxidants. Utilization of these compounds by lactobacilli would involve α-l-rhamnosidases, which catalyze the hydrolytic release of rhamnose. Plant-pathogenic fungi such as Aspergillus species produce the rhamnosidases when cultured in the presence of naringin, a rhamnosilated flavonoid (24, 26). Bacteria such as Bacillus species have also been shown to use similar enzyme activities for metabolizing bacterial biofilms which contain rhamnose (17, 40).In food processing, rhamnosidases have been applied primarily for debittering of citrus juices. Part of the bitter taste of citrus is caused by naringin (Fig. ​(Fig.1),1), which loses its bitter taste upon removal of the rhamnose (32). More recently, application of rhamnosidases for improving the bioavailability of flavonoids has been described. Human intake of flavonoids has been associated with a reduced risk of coronary heart disease in epidemiological studies (19). Food flavonoids need to be absorbed efficiently from what we eat in order to execute any beneficial function. Absorption occurs primarily in the small intestine (12, 37). Unabsorbed flavonoids will arrive in the colon, where they will be catabolized by the microflora, which is then present in huge quantities. Therefore, it would be desirable for flavonoids to be consumed in a form that is already optimal for absorption in the small intestine prior to their potential degradation. For the flavonoid quercetin, it has been demonstrated that the presence of rhamnoside groups inhibits its absorption about fivefold (20). A number of flavonoids which are present in frequently consumed food commodities, such as tomato and citrus products, often carry rutinoside (6-β-l-rhamnosyl-d-glucose) or neohesperidoside (2-β-l-rhamnosyl-d-glucose) residues (Fig. ​(Fig.1).1). Therefore, removal of the rhamnose groups from such flavonoid rutinosides and neohesperidosides prior to consumption could enhance their intestinal absorption. With this aim, studies were recently carried out toward the application of fungal enzyme preparations as a potential means to selectively remove rhamnoside moieties (16, 30).Open in a separate windowFIG. 1.Chemical structures of rhamnose-containing flavonoids from plants. Relevant carbon atoms in glycoside moieties are numbered. (1) Rutin (quercetin-3-glucoside-1→6-rhamnoside); (2) narirutin (naringenin-7-glucoside-1→6-rhamnoside); (3) naringin (naringenin-7-glucoside-1→2-rhamnoside); (4) p-nitrophenol-rhamnose.In view of the frequent occurrence of lactobacilli on decaying plant material and fermented vegetable substrates, one could anticipate that their genomes carry one or more genes encoding enzymes capable of utilizing rhamnosilated compounds. In the work reported here, we describe the identification of three putative rhamnosidase genes in lactobacillus genomes. We expressed these genes in Escherichia coli and characterized their gene products. The activities of all three lactobacillus rhamnosidases on flavonoids naturally present in tomato pulp were then assessed. One of the L. plantarum genes, which encoded the enzyme with the highest activity and stability in E. coli, was then also expressed in Lactococcus lactis, with the aim of investigating the potential use of such a recombinant organism to improve the bioavailability of fruit flavonoids and thus their efficacy in common foodstuffs.     

Degradation of Thymidine by Lactobacillus acidophilus

Whole cells of Lactobacillus acidophilus are capable of degrading thymidine to thymine, suggesting the presence of thymidine phosphorylase (or thymidine hydrolase). This activity was also demonstrated in cell-free extracts.     

Lactobacillus acidophilus contributes to a healthy environment for vaginal epithelial cells

Lactobacillus species in the female genital tract are thought to act as a barrier to infection. Several studies have demonstrated that lactobacilli can adhere to vaginal epithelial cells. However, little is known about how the adherence of lactobacilli to vaginal epithelial cells affects the acidity, cell viability, or proliferation of the lactobacilli themselves or those of vaginal epithelial cells. Lactobacillus acidophilus was co-cultured with immortalized human vaginal epithelial cells (MS74 cell line), and the growth of L. acidophilus and the acidity of the culture medium were measured. MS74 cell density and viability were also assessed by counting cell numbers and observing the cell attachment state. L. acidophilus showed exponential growth for the first 6 hr until 9 hr, and the pH was maintained close to 4.0-5.0 at 24 hr after culture, consistent with previous studies. The growth curve of L. acidophilus or the pH values were relatively unaffected by co-culture with MS74 cells, confirming that L. acidophilus maintains a low pH in the presence of MS74 cells. This co-culture model could therefore potentially be used to mimic vaginal conditions for future in vitro studies. On the other hand, MS74 cells co-cultured with L. acidophilus more firmly attached to the culture plate, and a higher number of cells were present compared to cells cultured in the absence of L. acidophilus. These results indicate that L. acidophilus increases MS74 cell proliferation and viability, suggesting that lactobacilli may contribute to the healthy environment for vaginal epithelial cells.     

Assimilation of cholesterol by Lactobacillus acidophilus

Considerable variation was found among strains of Lactobacillus acidophilus isolated from the fecal flora of pigs with regard to the ability to grow well in the presence of bile and to assimilate cholesterol from a laboratory growth medium. The uptake of cholesterol occurred only when the culture(s) was growing in the presence of bile under anaerobic conditions. Consumption of L. acidophilus RP32, which was selected for its ability to grow well in the presence of bile and to assimilate cholesterol from the laboratory medium, significantly inhibited increases in serum cholesterol levels of pigs (P less than 0.05) fed a high-cholesterol diet. Consumption of L. acidophilus P47, which was selected for its ability to grow in the presence of bile and lack of ability to remove cholesterol from the growth medium, failed to have a similar effect. This indicates that certain strains of L. acidophilus act directly on cholesterol in the gastrointestinal tract, and thus may be beneficial in reducing serum cholesterol levels.     

Specific antigens of Lactobacillus acidophilus.

Antigens specific for Lactobacillus acidophilus were investigated by double immunodiffusion in agar-gel. Antigenic materials were extracted from whole bacteria and some walls with cold trichloroacetic acid. Antisera were prepared by intravenous injection into rabbits of suspensions of whole organisms in solutions of bovine serum albumin, which had been heated and then washed. Four specific antigens were found as precipitinogens and denoted as antigens 11, 12, 13 and 14. Of 43 strains of L. acidophilus studied, 33 strains possessed antigen 11, six strains antigen 12, two strains antigen 13 and two strains antigen 14. Sugar compositions of wall preparations were analysed in an attempt to characterize the determinants of antigens 11 and 12. The walls contained glucose, galactose, hexosamine and sometimes glycerol, but no rhamnose was found. It was considered that alpha-glucopyranose was the major component of the determinant of antigen 11 since trehalose and maltose significantly inhibited the reaction between antibody 11 and its antigen; the determinant of antigen 12 was not clarified.     

降胆固醇嗜酸乳杆菌的诱变选育

通过诱变获得具有降胆固醇功能的优良嗜酸乳杆菌新菌株。利用亚硝基胍(作用浓度为1 g/L)对嗜酸乳杆菌进行诱变。突变菌株测定其耐渗透压和抗胆盐能力后,在含有0.3 g/L胆固醇的培养基中培养48 h,测定降胆固醇率。挑选优良突变菌株制成酸奶并喂养高脂大鼠模型,28 d后测定血清及粪便胆固醇指标。嗜酸乳杆菌突变后获得的60个突变菌株中有8株具有良好的耐渗透压和抗胆盐能力,其中突变株Y48的清除胆固醇能力最高,清除率达到(61.44±1.8)%。Y48发酵酸奶喂养高脂大鼠模型28 d后与对照大鼠模型相比,血清中TC、TG明显减少(P<0.05),粪便TC明显增加。通过诱变获得了优良的嗜酸乳杆菌突变菌株,为今后获得优质降胆固醇乳酸制品提供良好的候选菌种。     

Betaine Transport Imparts Osmotolerance on a Strain of Lactobacillus acidophilus

Unlike most Lactobacillus acidophilus strains, a specific strain, L. acidophilus IFO 3532, was found to grow in rich medium containing 1 M sodium acetate, KCl, or NaCl. This strain could also grow with up to 1.8 M NaCl or 3 M nonelectrolytes (fructose, xylose, or sorbitol) added. Thus, this strain was tolerant to osmotic pressures up to 2.8 osM. A search for an intracellular solute which conferred osmoprotection led to the identification of glycine betaine (betaine). Betaine was accumulated to high concentrations in cells growing in MRS medium supplemented with 1 M KCl or NaCl. Uptake of [¹⁴C]betaine by L. acidophilus 3532 cells suspended in buffer was stimulated by increasing the medium osmotic pressure with 1 M KCl or NaCl. The accumulated betaine was not metabolized further; transport was relatively specific for betaine and was dependent on an energy source. Other lactobacilli, more osmosensitive than strain 3532, including L. acidophilus strain E4356, L. bulgaricus 8144, and L. delbrueckii 9649, showed lower betaine transport rates in response to an osmotic challenge than L. acidophilus 3532. Experiments with chloramphenicol-treated L. acidophilus 3532 cells indicated that the transport system was not induced but appeared to be activated by an increase in osmotic pressure.     

Genetic analysis of two bile salt hydrolase activities in Lactobacillus acidophilus NCFM

Two genes, bshA and bshB, encoding bile salt hydrolase enzymes (EC 3.5.1.24) were identified in the genome sequence of Lactobacillus acidophilus NCFM. Targeted inactivation of these genes via chromosomal insertion of an integration vector demonstrated different substrate specificities for these two enzymes.     

Assimilation of cholesterol by Lactobacillus acidophilus.

Considerable variation was found among strains of Lactobacillus acidophilus isolated from the fecal flora of pigs with regard to the ability to grow well in the presence of bile and to assimilate cholesterol from a laboratory growth medium. The uptake of cholesterol occurred only when the culture(s) was growing in the presence of bile under anaerobic conditions. Consumption of L. acidophilus RP32, which was selected for its ability to grow well in the presence of bile and to assimilate cholesterol from the laboratory medium, significantly inhibited increases in serum cholesterol levels of pigs (P less than 0.05) fed a high-cholesterol diet. Consumption of L. acidophilus P47, which was selected for its ability to grow in the presence of bile and lack of ability to remove cholesterol from the growth medium, failed to have a similar effect. This indicates that certain strains of L. acidophilus act directly on cholesterol in the gastrointestinal tract, and thus may be beneficial in reducing serum cholesterol levels.     

Sites of Cellular Autolysis in Lactobacillus acidophilus

Ultrastructural changes which occur during cellular autolysis of Lactobacillus acidophilus strain 63AM Gasser in 0.05 M citrate buffer, pH 5.0, were examined. Early in the process, randomly distributed electron-dense patches were seen on the wall surface, along with an accompanying eversion of mesosomes. Later, after a loss of about 20% of the initial cellular turbidity, dissolution from the outside of nascent cross walls was seen. This observation was related to the normal process of cell separation. After this stage, short lengths of the cylindrical portion of the wall appeared to be completely removed in a random manner over the entire surface. This dissolution produced gaps in the wall which allowed the extrusion of membrane and cytoplasm. Although membrane was usually extruded through one major, polar, subpolar, or septal site, other secondary points of membrane extrusion were also frequently seen in the same cell section.