A Streptococcus uberis transposon mutant screen reveals a negative role for LiaR homologue in biofilm formation.

AIMS: The environmental pathogen Streptococcus uberis causes intramammary infections in dairy cows. Because biofilm growth might contribute to Strep. uberis mastitis, we conducted a biological screen to identify genes potentially involved in the regulation of biofilm growth. METHODS AND RESULTS: By screening a transposon mutant library of Strep. uberis, we determined that the disruption of 13 genes (including hasA, coaC, clpP, miaA, nox and uidA) led to increased biofilm formation. One of the genes (SUB1382) encoded a homologue of the LiaR response regulator (RR) of the Bacillus subtilis two-component signalling system (TCS). Electrophoretic mobility shift assays revealed that DNA binding by LiaR was greatly enhanced by phosphorylation. Two-dimensional differential in-gel electrophoresis analyses of the liaR mutant and the parental Strep. uberis strain revealed five differentially produced proteins with at least a 1·5-fold change in relative abundance (P < 0·05). CONCLUSIONS: The DNA-binding protein LiaR is a potential regulator of biofilm formation by Strep. uberis. SIGNIFICANCE AND IMPACT OF THE STUDY: Several molecular primary and downstream targets involved in biofilm formation by Strep. uberis were identified. This provides a solid foundation for further studies on the regulation of biofilm formation in this important pathogen.

Characterization and expression of the pepN gene encoding a general aminopeptidase from Lactobacillus helveticus.

An aminopeptidase N (pepN) gene was detected by DNA hybridization from an industrially important Lactobacillus helveticus strain using part of the L. helveticus CNRZ32 pepN gene as the probe. One of five hybridization positive clones was characterized in more detail. A subcloned 3.7 kb fragment, positive in hybridization and encoding aminopeptidase activity, was sequenced and analyzed. Only one open reading frame (ORF) of 2532 base pairs with a coding capacity for a 95.9 kDa protein could be found. The deduced amino acid sequence of the 95.9 kDa protein showed homology to PepN proteins from other lactic acid bacteria and carried the conserved catalytic and zinc binding sites of the neutral zinc metallo-peptidase family confirming the identity of the pepN gene. A 2.75 kb transcript and two transcription start sites were identified with mRNA analyses. Expression of pepN in L. helveticus, studied as the function of growth, revealed a high level of pepN transcripts throughout the growth, in contrast to the steady state levels of other peptidase mRNAs from L. helveticus analyzed in our laboratory.

Vancomycin resistance factor of Lactobacillus rhamnosus GG in relation to enterococcal vancomycin resistance (van) genes.

Lactobacillus rhamnosus GG (ATCC 53103) is a probiotic strain used in fermented dairy products in many countries and is also used as a food supplement in the form of freeze-dried powder. The relationship of the vancomycin resistance factor in L. rhamnosus GG and the vancomycin resistance (van) genes of Enterococcus faecalis and E. faecium were studied using polymerase chain reaction (PCR), Southern hybridization and conjugation methods. Our results show that the vancomycin resistance determinant in L. rhamnosus GG is not closely related to enterococcal van genes, since no PCR product was amplified in L. rhamnosus GG with any of the three sets of vanA primers used, and enterococcal vanA, vanB, vnH, vanX, vanZ, vanY, vanS and vanR genes did not hybridize with DNA of L. rhamnosus GG. This strain does not contain plasmids and transfer of chromosomal vancomycin resistance determinant from L. rhamnosus GG to enterococcal species was not detected. Our results are in accordance with previous findings of intrinsically vancomycin-resistant lactic acid bacteria.

Lactobacillus plantarum for oral peptide delivery.

AIMS: To evaluate strains of lactobacilli for their ability to persist and secrete heterologous protein in the oral cavity. METHODS AND RESULTS: Four different strains of common oral lactobacilli, Lactobacillus brevis, Lactobacillus johnsonii, Lactobacillus murinus and Lactobacillus plantarum, were transformed with the plasmid pKTH2121, which contains a secretion cassette for beta-lactamase. Lactobacilli isolated from the mouth of host mice were also transformed with pKTH2121 for later feeding. Lactococcus lactis, transformed with pKTH2121, was also fed to mice as a negative control. All transformed isolates were fed to C57Black mice in varying schedules. The number of transformed bacteria persisting in the mouth was reported as a percentage of total oral bacteria recovered by swabbing. CONCLUSIONS: The transformed L. lactis, L. brevis, L. johnsonii, L. murinus, and the endogenous murine lactobacillus strain failed to persist in the mouth. Transformed L. plantarum, however, persisted in the mouth and comprised up to 25% of the total lactobacilli at 18 h and 10% at 24 h after feeding. L. plantarum recovered after feeding retained its ability to secrete beta-lactamase into culture medium efficiently. Beta-lactamase activity could be detected in oral secretions at 8 h after feedings. After repeated feedings, however, the L. plantarum containing pKTH2121 gradually lost its ability to persist after feedings. This experiment demonstrates that L. plantarum can transiently colonize the oral mucosa in large numbers, while continuously secreting foreign proteins, raising the possibility of using lactobacilli as a vector for delivery of oral mucosal peptides.

New convenient defined media for [(35)S]methionine labelling and proteomic analyses of probiotic lactobacilli.

AIMS: To develop experimental conditions for efficient protein radiolabelling and two-dimensional (2D) polyacrylamide gel electrophoresis for investigation of stress proteomes of probiotic Lactobacillus spp. METHODS AND RESULTS: Three chemically defined media (CDM) optimized from a commercial medium supported rapid growth of the probiotic Lactobacillus rhamnosus E97800, Lactobacillus brevis ATCC 8287 and Lactobacillus reuteri E97849, and a broad range of other lactic acid bacteria. These CDM allowed efficient protein radiolabelling, requiring as little as 200 mul of logarithmic culture and pulse-chase labelling of 20 min to detect c. 300 distinct protein spots in a mini-scale 2D-gel. Proteins including DnaK, GroEL and ClpATPases were identified from the 2D-gels by immunoblotting. CONCLUSIONS: Radiolabelling coupled with 2D gel electrophoresis provides a sensitive means to monitor changes in protein synthesis rates in probistic lactobacilli. SIGNIFICANCE AND IMPACT OF THE STUDY: Efficient tools for proteomic analyses of probiotic Lactobacillus were developed and applied for stress-response studies.

Inactivation of a gene that is highly conserved in Gram-positive bacteria stimulates degradation of non-native proteins and concomitantly increases stress tolerance in Lactococcus lactis.

Exposure of cells to elevated temperatures triggers the synthesis of chaperones and proteases including components of the conserved Clp protease complex. We demonstrated previously that the proteolytic subunit, ClpP, plays a major role in stress tolerance and in the degradation of non-native proteins in the Gram-positive bacterium Lactococcus lactis. Here, we used transposon mutagenesis to generate mutants in which the temperature- and puromycin-sensitive phenotype of a lactococcal clpP null mutant was partly alleviated. In all mutants obtained, the transposon was inserted in the L. lactis trmA gene. When analysing a clpP, trmA double mutant, we found that the expression normally induced from the clpP and dnaK promoters in the clpP mutant was reduced to wild-type level upon introduction of the trmA disruption. Additionally, the degradation of puromycyl-containing polypeptides was increased, suggesting that inactivation of trmA compensates for the absence of ClpP by stimulating an as yet unidentified protease that degrades misfolded proteins. When trmA was disrupted in wild-type cells, both stress tolerance and proteolysis of puromycyl peptides was enhanced above wild-type level. Based on our results, we propose that TrmA, which is well conserved in several Gram-positive bacteria, affects the degradation of non-native proteins and thereby controls stress tolerance.

An operon from Lactobacillus helveticus composed of a proline iminopeptidase gene (pepI) and two genes coding for putative members of the ABC transporter family of proteins.

A proline iminopeptidase gene (pepI) of an industrial Lactobacillus helveticus strain was cloned and found to be organized in an operon-like structure of three open reading frames (ORF1, ORF2 and ORF3). ORF1 was preceded by a typical prokaryotic promoter region, and a putative transcription terminator was found downstream of ORF3, identified as the pepI gene. Using primer-extension analyses, only one transcription start site, upstream of ORF1, was identifiable in the predicted operon. Although the size of mRNA could not be judged by Northern analysis either with ORF1-, ORF2- or pepI-specific probes, reverse transcription-PCR analyses further supported the operon structure of the three genes. ORF1, ORF2 and ORF3 had coding capacities for 50.7, 24.5 and 33.8 kDa proteins, respectively. The ORF3-encoded PepI protein showed 65% identity with the PepI proteins from Lactobacillus delbrueckii subsp. bulgaricus and Lactobacillus delbrueckii subsp. lactis. The ORF1-encoded protein had significant homology with several members of the ABC transporter family but, with two distinct putative ATP-binding sites, it would represent an unusual type among the bacterial ABC transporters. ORF2 encoded a putative integral membrane protein also characteristic of the ABC transporter family. The pepI gene was overexpressed in Escherichia coli. Purified PepI hydrolysed only di and tripeptides with proline in the first position. Optimum PepI activity was observed at pH 7.5 and 40 degrees C. A gel filtration analysis indicated that PepI is a dimer of M(r) 53,000. PepI was shown to be a metal-independent serine peptidase having thiol groups at or near the active site. Kinetic studies with proline-p-nitroanilide as substrate revealed Km and Vmax values of 0.8 mM and 350 mmol min-1 mg-1, respectively, and a very high turnover number of 135,000 s-1.

Molecular characterization of a stress-inducible gene from Lactobacillus helveticus.

A gene (htrA) coding for a stress-inducible HtrA-like protein from Lactobacillus helveticus CNRZ32 was cloned, sequenced, and characterized. The deduced amino acid sequence of the gene exhibited 30% identity with the HtrA protein from Escherichia coli; the putative catalytic triad and a PDZ domain that characterize the HtrA family of known bacterial serine proteases were also found in the sequence. Expression of the L. helveticus htrA gene in a variety of stress conditions was analyzed at the transcriptional level. The strongest induction, resulting in over an eightfold increase in the htrA transcription level, was found in growing CNRZ32 cells exposed to 4% (wt/vol) NaCl. Enhanced htrA mRNA expression was also seen in CNRZ32 cells after exposure to puromycin, ethanol, or heat. The reporter gene gusA was integrated in the Lactobacillus chromosome downstream of the htrA promoter by a double-crossover event which also interrupted the wild-type gene. The expression of gusA in the stress conditions tested was similar to that of htrA itself. In addition, the presence of an intact htrA gene facilitated growth under heat stress but not under salt stress.

Characterization and expression of the Lactobacillus helveticus pepC gene encoding a general aminopeptidase.

An aminopeptidase C gene (pepC) was detected by nucleic acid hybridization from an industrially important Lactobacillus helveticus strain. Three hybridization positive clones were isolated from a gene library of this L. helveticus strain, and one of them was characterized in more detail. Deletion mapping localized the hybridization positivity into a 2.8-kb fragment, which also encoded aminopeptidase activity. This fragment was sequenced and two open reading frames (ORF1 and 2) of 1347 and 840 base pairs were identified. The ORF1 was preceded by a typical prokaryotic promoter region, and an inverted repeat structure with delta G of -49.0 kJ mol-1 was found downstream of the coding region. The deduced amino acid sequence of ORF1, with an encoding capacity for a 51.4-kDa protein, was shown to share 48.3% and 98.0% identities with the PepC proteins from Lactococcus lactis and L. helveticus CNRZ32, respectively, thus confirming that ORF1 codes for an aminopeptidase C. mRNA size analyses revealed 1.7-kb and 2.7-kb transcripts in Northern blot with the pepC-specific probe. A further analysis with the pepC- and ORF2-specific probes showed that downstream ORF2 is co-transcribed with the pepC gene at the exponential phase of growth whereas, at the stationary growth phase, transcripts derived from the pepC promoter were below the detection limit, and the ORF2 was expressed by its own promoter. The 5' end mapping of the pepC transcripts with primer extension revealed one transcription start site suggesting a new position for the pepC promoter region when compared to that predicted for the L. helveticus CNRZ32 pepC gene. Expression of pepC was also studied in L. helveticus as the function of growth in a bioreactor study. Transcription of pepC was typical to exponential growth phase expression. The level of total thiol-aminopeptidase activity, however, remained nearly constant throughout the stationary growth phase.

Cloning and characterization of a prolinase gene (pepR) from Lactobacillus rhamnosus.

A peptidase gene expressing L-proline-beta-naphthylamide-hydrolyzing activity was cloned from a gene library of Lactobacillus rhamnosus 1/6 isolated from cheese. Peptidase-expressing activity was localized in a 1.5-kb SacI fragment. A sequence analysis of the SacI fragment revealed the presence of one complete open reading frame (ORF1) that was 903 nucleotides long. The ORF1-encoded 34.2-kDa protein exhibited 68% identity with the PepR protein from Lactobacillus helveticus. Additional sequencing revealed the presence of another open reading frame (ORF2) following pepR; this open reading frame was 459 bp long. Northern (RNA) and primer extension analyses indicated that pepR is expressed both as a monocistronic transcriptional unit and as a dicistronic transcriptional unit with ORF2. Gene replacement was used to construct a PepR-negative strain of L. rhamnosus. PepR was shown to be the primary enzyme capable of hydrolyzing Pro-Leu in L. rhamnosus. However, the PepR-negative mutant did not differ from the wild type in its ability to grow and produce acid in milk. The cloned pepR expressed activity against dipeptides with N-terminal proline residues. Also, Met-Ala, Leu-Leu, and Leu-Gly-Gly and the chromogenic substrates L-leucine-beta-naphthylamide and L-phenylalanine-beta-naphthylamide were hydrolyzed by the PepR of L. rhamnosus.

X-prolyl dipeptidyl aminopeptidase gene (pepX) is part of the glnRA operon in Lactobacillus rhamnosus.

A peptidase gene expressing X-prolyl dipeptidyl aminopeptidase (PepX) activity was cloned from Lactobacillus rhamnosus 1/6 by using the chromogenic substrate L-glycyl-L-prolyl-beta-naphthylamide for screening of a genomic library in Escherichia coli. The nucleotide sequence of a 3.5-kb HindIII fragment expressing the peptidase activity revealed one complete open reading frame (ORF) of 2,391 nucleotides. The 797-amino-acid protein encoded by this ORF was shown to be 40, 39, and 36% identical with PepXs from Lactobacillus helveticus, Lactobacillus delbrueckii, and Lactococcus lactis, respectively. By Northern analysis with a pepX-specific probe, transcripts of 4.5 and 7.0 kb were detected, indicating that pepX is part of a polycistronic operon in L. rhamnosus. Cloning and sequencing of the upstream region of pepX revealed the presence of two ORFs of 360 and 1,338 bp that were shown to be able to encode proteins with high homology to GlnR and GlnA proteins, respectively. By multiple primer extension analyses, the only functional promoter in the pepX region was located 25 nucleotides upstream of glnR. Northern analysis with glnA- and pepX-specific probes indicated that transcription from glnR promoter results in a 2.0-kb dicistronic glnR-glnA transcript and also in a longer read-through polycistronic transcript of 7.0 kb that was detected with both probes in samples from cells in exponential growth phase. The glnA gene was disrupted by a single-crossover recombinant event using a nonreplicative plasmid carrying an internal part of glnA. In the disruption mutant, glnRA-specific transcription was derepressed 10-fold compared to the wild type, but the 7.0-kb transcript was no longer detectable with either the glnA- or pepX-specific probe, demonstrating that pepX is indeed part of glnRA operon in L. rhamnosus. Reverse transcription-PCR analysis further supported this operon structure. An extended stem-loop structure was identified immediately upstream of pepX in the glnA-pepX intergenic region, a sequence that showed homology to a 23S-5S intergenic spacer and to several other L. rhamnosus-related entries in data banks.