Carmen Peláez

Hydrolysis of Oligofructoses by the Recombinant β-Fructofuranosidase from Bifidobacterium lactis

The ability of the beta-fructofuranosidase (EC 3.2.1.26) from Bifidobacterium lactis DSM 10140T to cleave a variety of fructooligosaccharides was characterised. We identified its gene on a cloned chromosomal DNA fragment by sequence similarity (69% identity) to the putative CscA protein encoded in the Bifidobacterium longum genome. The deduced amino acid sequence of 532 residues (59.4 kDa) appeared to be identical to the beta-fructofuranosidase from the same strain recently described by Ehrmann et al. (Curr. Microbiol. 2003, 46, 391-397). However, the characterisation of the heterologously expressed enzyme showed several discrepancies to the referred study. First, the B. lactis beta-fructofuranosidase gene was found to have 41% identity with CscA from E. coli in contrast to the 16% reported, therefore it was assigned to as CscA protein instead of BfrA. Second, we observed only low activity of the enzyme towards sucrose (6%) instead of the 100% previously reported. Instead, we measured highest activity (100%) of the enzyme with the oligofructose Raftilose as a substrate compared with the inulin of low degree of polymerisation Raftiline LS (29%) and the highly polymerised Raftiline HP (10%). Altogether, the enzyme showed high affinity to terminal beta(2-1) glycosyl linkages between fructose moieties. The Km values obtained for Raftilose, Raftiline LS and sucrose were 0.12, 7.08 and 8.37 mM, respectively, and V(max) values for the conversion to fructose were calculated to be 5, 21 and 17 micromol/min per mg of protein, respectively. Growth of B. lactis was supported by fructans of low degree of polymerisation (Raftilose and Raftiline LS), whereas we observed no growth with highly polymerised inulin (Raftiline HP).

Lactobacillus casei and Lactobacillus plantarum initiate catabolism of methionine by transamination

F. AMARITA, T. REQUENA, G. TABORDA, L. AMIGO AND C. PELAEZ. 2001.

Physiological and biochemical characterization of the two α-L-rhamnosidases of Lactobacillus plantarum NCC245

This work is believed to be the first report on the physiological and biochemical characterization of alpha-l-rhamnosidases in lactic acid bacteria. A total of 216 strains representing 37 species and eight genera of food-grade bacteria were screened for alpha-l-rhamnosidase activity. The majority of positive bacteria (25 out of 35) were Lactobacillus plantarum strains, and activity of the L. plantarum strain NCC245 was examined in more detail. The analysis of alpha-l-rhamnosidase activity under different growth conditions revealed dual regulation of the enzyme activity, involving carbon catabolite repression and induction: the enzyme activity was downregulated by glucose and upregulated by l-rhamnose. The expression of the two alpha-l-rhamnosidase genes rhaB1 and rhaB2 and two predicted permease genes rhaP1 and rhaP2, identified in a probable operon rhaP2B2P1B1, was repressed by glucose and induced by l-rhamnose, showing regulation at the transcriptional level. The two alpha-l-rhamnosidase genes were overexpressed and purified from Escherichia coli. RhaB1 activity was maximal at 50 degrees C and at neutral pH and RhaB2 maximal activity was detected at 60 degrees C and at pH 5, with high residual activity at 70 degrees C. Both enzymes showed a preference for the alpha-1,6 linkage of l-rhamnose to beta-d-glucose, hesperidin and rutin being their best substrates, but, surprisingly, no activity was detected towards the alpha-1,2 linkage in naringin under the tested conditions. In conclusion, we identified and characterized the strain L. plantarum NCC245 and its two alpha-l-rhamnosidase enzymes, which might be applied for improvement of bioavailability of health-beneficial polyphenols, such as hesperidin, in humans.

Requirement of autolytic activity for bacteriocin-induced lysis

ABSTRACT The bacteriocin produced by Lactococcus lactis IFPL105 is bactericidal against several Lactococcus andLactobacillus strains. Addition of the bacteriocin to exponential-growth-phase cells resulted in all cases in bacteriolysis. The bacteriolytic response of the strains was not related to differences in sensitivity to the bacteriocin and was strongly reduced in the presence of autolysin inhibitors (Co2+ and sodium dodecyl sulfate). When L. lactis MG1363 and its derivative deficient in the production of the major autolysin AcmA (MG1363acmAΔ1) were incubated with the bacteriocin, the latter did not lyse and no intracellular proteins were released into the medium. Incubation of cell wall fragments of L. lactisMG1363, or of L. lactis MG1363acmAΔ1 to which extracellular AcmA was added, in the presence or absence of the bacteriocin had no effect on the speed of cell wall degradation. This result indicates that the bacteriocin does not degrade cell walls, nor does it directly activate the autolysin AcmA. The autolysin was also responsible for the observed lysis of L. lactis MG1363 cells during incubation with nisin or the mixture of lactococcins A, B, and M. The results presented here show that lysis of L. lactis after addition of the bacteriocins is caused by the resulting cell damage, which promotes uncontrolled degradation of the cell walls by AcmA.

Use of a bacteriocin-producing transconjugant as starter in acceleration of cheese ripening

The non-conjugative 46 kb plasmid that encodes the biosynthesis of lacticin 3147 in Lactococcus lactis IFPL105 has been transferred to the starter L. lactis IFPL359, used in goats milk cheesemaking. The accelerating effect exerted on proteolysis and development of sensory characteristics of semi-hard cheese by the bacteriocin-producing transconjugant L. lactis IFPL3593 (Lac+ Bac+ Imm+), which is able to induce cell lysis in starter adjuncts with high peptidase activity, has been studied. It has been demonstrated that the use of IFPL3593 as starter accelerates cheese ripening as it increases the level of amino nitrogen correlated with early cell lysis of adjuncts. The fact that the bacteriocin-producing microorganism used is immune to the bacteriocin. allowed proper acidification of the curd without altering the cheese-making process.

Enzymatic Ability of Bifidobacterium animalis subsp. lactis To Hydrolyze Milk Proteins: Identification and Characterization of Endopeptidase O

ABSTRACT The proteolytic system of Bifidobacterium animalis subsp. lactis was analyzed, and an intracellular endopeptidase (PepO) was identified and characterized. This work reports the first complete cloning, purification, and characterization of a proteolytic enzyme in Bifidobacterium spp. Aminopeptidase activities (general aminopeptidases, proline iminopeptidase, X-prolyl dipeptidylaminopeptidase) found in cell extracts of B. animalis subsp. lactis were higher for cells that had been grown in a milk-based medium than for those grown in MRS. A high specific proline iminopeptidase activity was observed in B. animalis subsp. lactis. Whole cells and cell wall-bound protein fractions showed no caseinolytic activity; however, the combined action of intracellular proteolytic enzymes could hydrolyze casein fractions rapidly. The endopeptidase activity of B. animalis subsp. lactis was examined in more detail, and the gene encoding an endopeptidase O in B. animalis subsp. lactis was cloned and overexpressed in Escherichia coli. The deduced amino acid sequence for B. animalis subsp. lactis PepO indicated that it is a member of the M13 peptidase family of zinc metallopeptidases and displays 67.4% sequence homology with the predicted PepO protein from Bifidobacterium longum. The recombinant enzyme was shown to be a 74-kDa monomer. Activity of B. animalis subsp. lactis PepO was found with oligopeptide substrates of at least 5 amino acid residues, such as met-enkephalin, and with larger substrates, such as the 23-amino-acid peptide αs1-casein(f1-23). The predominant peptide bond cleaved by B. animalis subsp. lactis PepO was on the N-terminal side of phenylalanine residues. The enzyme also showed a post-proline secondary cleavage site.

Lactobacillus acidophilus La-5 increases lactacin B production when it senses live target bacteria

Lactobacillus acidophilus La-5 is a probiotic strain used in dairy products. Production of bacteriocin by L. acidophilus La-5 was achieved when it was grown in co-cultures with the yogurt starter species Streptococcus thermophilus and Lactobacillus delbrueckii subsp. bulgaricus. However, bacteriocin induction was not observed when heat-killed cells were used as inducers. This study demonstrates that L. acidophilus La-5 produces lactacin B and that the bacteriocin expression is controlled by an auto-induction mechanism involving the secreted peptide IP_1800. The transcript level of the lactacin B gene cluster expression was investigated in co-cultures between L. acidophilus La-5 and S. thermophilus STY-31 and a remarkable increase of the bacteriocin structural gene (lbaB) transcription was observed. However, lbaB was transcribed constitutively in uninduced L. acidophilus La-5 cells, but the levels of the secreted bacteriocin were not enough to be detected by the agar diffusion assay. A new method for bacteriocin detection was formulated based on the monitoring on real time of Lactobacillus sakei subsp. sakei growth in presence of the supernatant and the cell wall extracts of pure and induced L. acidophilus La-5. These results showed that part of lactacin B secreted remains adhered to cell envelope.

Enzymatic ability of Lactobacillus casei subsp. casei IFPL731 for flavour development in cheese

Abstract Lactobacillus casei subsp. casei IFPL731 is a wild strain isolated from artisanal goats’ milk cheese. The strain shows a multiple enzymatic system that involves esterase, cell-envelope proteinase, aminopeptidases, dipeptidases, specialized peptidases for proline-containing peptides, and amino acid converting enzymes. The broad enzymatic system of Lb. casei IFPL731 is responsible for its hydrolyzing activity towards a number of peptides, including bitter and methionine-containing peptides. Both characteristics are of great interest as regards the use of the strain as a starter culture adjunct to influence the development of cheese flavour, which has been demonstrated in the manufacture of goats’ milk and low fat cheeses. Moreover, Lb. casei IFPL731 shows methionine aminotransferase activity that leads to the production of the typical cheese aroma. The different enzymes from Lb. casei IFPL731 described in this review and its utilization as a starter culture adjunct in cheese manufacture make the strain one of the best characterized lactobacilli in the literature.

Effect of Flavan-3-ols on the Adhesion of Potential Probiotic Lactobacilli to Intestinal Cells

The effect of dietary flavan-3-ols on the adhesion of potential probiotic lactobacilli strains to intestinal cells was unraveled. The inhibitory activity of these compounds on intestinal cells was highlighted. The cytotoxic effect was shown to depend on both the compounds chemical structure (galloylation and polymerization) and degree of differentiation of intestinal cells. The effect of flavan-3-ols on bacteria adhesion differed greatly between compounds, strains, and intestinal cells. All flavan-3-ols inhibited significantly Lactobacillus acidophilus LA-5 and Lactobacillus plantarum IFPL379 adhesion except epigallocatechin gallate, which enhanced L. acidophilus LA-5 adhesion to Caco-2. Procyanidins B1 and B2 increased remarkably the adhesion of Lactobacillus casei LC115 to HT-29 cells, whereas epigallocatechin increased L. casei LC115 adhesion to Caco-2. These data showed the potential of flavan-3-ols to alter gut microecology by modifying adhesion of lactobacilli strains to intestinal cells.

YtjE from Lactococcus lactis IL1403 Is a C-S Lyase with α,γ-Elimination Activity toward Methionine

ABSTRACT Cheese microbiota and the enzymatic conversion of methionine to volatile sulfur compounds (VSCs) are important factors in flavor formation during cheese ripening and the foci in biotechnological approaches to flavor improvement. The product of ytjE of Lactococcus lactis IL1403, suggested to be a methionine-specific aminotransferase based on genome sequence analysis, was therefore investigated for its role in methionine catabolism. The ytjE gene from Lactococcus lactis IL1403 was cloned in Escherichia coli and overexpressed and purified as a recombinant protein. When tested, the YtjE protein did not exhibit a specific methionine aminotransferase activity. Instead, YtjE exhibited C-S lyase activity and shared homology with the MalY/PatC family of enzymes involved in the degradation of l-cysteine, l-cystine, and l-cystathionine. YtjE was also shown to exhibit α,γ-elimination activity toward l-methionine. In addition, gas chromatographic-mass spectrometry analysis showed that YtjE activity resulted in the formation of H2S from l-cysteine and methanethiol (and its oxidized derivatives dimethyl disulfide and dimethyl trisulfide) from l-methionine. Given their significance in cheese flavor development, VSC production by YtjE could offer an additional approach for the development of cultures with optimized aromatic properties.