Satoru Hirayama

The Importance of Inter-Species Cell-Cell Co-Aggregation between Lactobacillus plantarum ML11-11 and Saccharomyces cerevisiae BY4741 in Mixed-Species Biofilm Formation

Cells of Lactobacillus plantarum ML11-11, an isolate from Fukuyama pot vinegar, and the yeast Saccharomyces cerevisiae formed significant mixed-species biofilms with concurrent inter-species co-aggregation. The co-aggregation did not occur with heated or proteinase K-treated ML11-11 cells, or in the presence of D-mannose, suggesting that surface proteins of ML11-11 and mannose-containing surface substance(s) of yeast were the predominant contributing factors. Sugar fatty acid ester inhibited mixed-species biofilm formation, but did not inhibit co-aggregation, suggesting that the cell-cell adhesion and cell-polystylene adhesion are controlled by different mechanisms. Microscopic observation and microflora analysis revealed that inter-species co-aggregation plays an important role in the formation of the mixed-species biofilm.

Yeast mannan structure necessary for co-aggregation with Lactobacillus plantarum ML11-11

Lactic acid bacteria (LAB) Lactobacillus plantarum ML11-11, an isolate from Fukuyama pot vinegar, and yeast Saccharomyces cerevisiae form significant mixed-species biofilm with direct cell-cell contact. Co-aggregation of L. plantarum ML11-11 and S. cerevisiae cells, mediated by the interaction between surface protein(s) on L. plantarum ML11-11 cells and surface mannan of S. cerevisiae cells, contributes significantly to mixed-species biofilm formation. In this study, co-aggregation activities of yeast mutants that were deleted of genes related to mannan biosynthesis were investigated to clarify the mannan structures essential for interaction with L. plantarum ML11-11. Among the 12 deletion mutants which had various incomplete mannan structures, only the mnn2 mutant lost the co-aggregation activity. In the mnn2 mutant, the gene coding the activity of attaching first branching mannose residue to mannan main chain is deleted and therefore the mnn2 mutant has unbranched mannan. From this result, it is clarified that the specific structure, consisted of mannan main chain to which are attached side chains containing one or more mannose residues, is critical for co-aggregation with L. plantarum ML11-11.

Mutants of Lactobacillus plantarum ML11-11 Deficient in Co-Aggregation with Yeast Exhibited Reduced Activities of Mixed-Species Biofilm Formation

Lactic acid bacteria (LAB) mutants deficient in inter-species co-aggregation with yeast were spontaneously derived from Lactobacillus plantarum ML11-11, a significant mixed-species biofilm former in static co-cultures with budding yeasts. These non-co-aggregative mutants also showed significant decreases in mixed-species biofilm formation. These results suggest the important role of co-aggregation between LAB and yeast in mixed-species biofilm formation. Cell surface proteins obtained by 5 M LiCl extraction from the wild-type cells and non-co-aggregative mutant cells were analyzed by SDS–PAGE. There was an obvious difference in protein profiles. The protein band at 30 kDa was present abundantly in the wild-type cell surface fraction but was significantly decreased in the mutant cells. This band assuredly corresponded to the LAB surface factors that contribute to co-aggregation with yeasts.

Manganese Ion Increases LAB-yeast Mixed-species Biofilm Formation

Remarkable LAB-yeast mixed-species biofilm was formed by lactic acid bacteria (LAB) Lactobacillus plantarum ML11-11 isolated from Fukuyama pot vinegar and Saccharomyces cerevisiae. This mixed-species biofilm formation increased in proportion to the YPD medium concentration but decreased in proportion to the MRS medium concentration. The effect of MRS components on mixed-species biofilm formation was investigated in a YPD medium environment, and it was clarified that beef extract (one of the MRS medium components) decreased mixed-species biofilm formation. On the other hand, manganese sulfate (another component in MRS) remarkably increased both LAB single- and LAB-yeast mixed-species biofilm formation. LAB single- and mixed-species biofilm formation were increased in proportion to the manganese sulfate concentration up to 1 mM and 100 μM, respectively. The growth of L. plantarum ML11-11 was increased significantly by the addition of 10 μM manganese sulfate and was resistant to higher concentration of up to 100 mM, but growth of S. cerevisiae was sensitive to manganese ion above 100 μM. These results suggested that mixed-species biofilm formation could be controlled artificially by controlling the manganese ion level.

Awa1p on the cell surface of sake yeast inhibits biofilm formation and the co-aggregation between sake yeasts and Lactobacillus plantarum ML11-11

We examined mixed-species biofilm formation between Lactobacillus plantarum ML11-11 and both foaming and non-foaming mutant strains of Saccharomyces cerevisiae sake yeasts. Wild-type strains showed significantly lower levels of biofilm formation compared with the non-foaming mutants. Awa1p, a protein involved in foam formation during sake brewing, is a glycosylphosphatidylinositol (GPI)-anchored protein and is associated with the cell wall of sake yeasts. The AWA1 gene of the non-foaming mutant strain Kyokai no. 701 (K701) has lost the C-terminal sequence that includes the GPI anchor signal. Mixed-species biofilm formation and co-aggregation of wild-type strain Kyokai no. 7 (K7) were significantly lower than K701 UT-1 (K701 ura3/ura3 trp1/trp1), while the levels of strain K701 UT-1 carrying the AWA1 on a plasmid were comparable to those of K7. The levels of biofilm formation and co-aggregation of the strain K701 UT-1 harboring AWA1 with a deleted GPI anchor signal were similar to those of K701 UT-1. These results clearly demonstrate that Awa1p present on the surface of sake yeast strain K7 inhibits adhesion between yeast cells and L. plantarum ML11-11, consequently impeding mixed-species biofilm formation.

Screening of lactic acid bacteria that can form mixed-species biofilm with Saccharomyces cerevisiae

The abilities of lactic acid bacteria (LAB) to form mixed-species biofilm with Saccharomyces cerevisiae in a static co-culture were investigated out of 168 LAB stock cultures, and two Lactobacillus plantarum strains (D71 and E31) and one Leuconostoc mesenteroides strain K01 were found to form mixed-species biofilm with S. cerevisiae BY4741. SEM observation showed that there was no significant difference in morphological properties among these three mixed-species biofilms and they resembled that formed by S. cerevisiae with L. plantarum ML11-11 previously isolated from a brewing sample of Fukuyama pot vinegar. The co-aggregation assays showed that L. plantarum D71 and L. plantarum E31 could co-aggregate with S. cerevisiae similarly to L. plantarum ML11-11, while L. mesenteroides K01 had no ability to co-aggregate with yeast. The above results indicate that aggregation followed by direct cell-to-cell contact is required for mixed-species biofilm formation between these L. plantarum strains and S. cerevisiae, though some different mechanism may be involved in biofilm formation between L. mesenteroides strain and S. cerevisiae. Microscopic observation of mixed-species biofilm formed by three L. plantarum strains (ML11-11, D71 and E31) and L. mesenteroides K01 with S. cerevisiae BY4741. Scale bars represent 5 µm.

Microbial behavior and changes in food constituents during fermentation of Japanese sourdoughs with different rye and wheat starting materials

Sourdough is a food item made by kneading grain flour and water together and allowing fermentation through the action of lactic acid bacteria (Lactobacillales) and yeast. Typically, Japanese bakeries make sourdough with rye flour, wheat flour, malt extract, and water and allow spontaneous fermentation for 6 days. We compared the microbial behavior and food components, such as organic acids, sugars, and free amino acids, of sourdoughs made using two different rye and wheat flours during the 6-day fermentation period. Comparisons were made for two types of rye and wheat flours, using different production sites and different milling, distribution, and storage conditions. The microbial count was evaluated using different culture media. All sourdough types showed a significant increase in lactic acid levels on fermentation day 2 and a decrease in free amino acid levels on day 4. Low overall lactic acid production and little fluctuation in sugar levels occurred in sourdough made from French ingredients. For sourdough made from Japanese ingredients, sugar levels (chiefly glucose, sucrose, and maltose) declined on fermentation day 1, increased on day 2, and declined by day 5. With the French ingredients, no yeast cells were detected until day 3, and many acid precursors of sourdough flavor components were detected. Yet with the Japanese ingredients, 106/g yeast cells were detected on days 3-5, as well as sourdough-flavor esters and alcohols. Differences in raw material quality affected the microbial behavior and changes in food constituents during the fermentation process and, consequently, the sourdough flavor.