Quantification of alpha-amylase mRNA in Bacillus subtilis by nucleic acid sandwich hybridization

Rapid and multiplexed transcript analysis of microbial cultures using capillary electophoresis-detectable oligonucleotide probe pools

A rapid assay for multiplex transcript analysis based on solution hybridization with pools of oligonucleotide probes was developed. In this assay called TRAC (transcript analysis with aid of affinity capture) the mRNAs to be studied are hybridized with gene-specific detection probe pools and biotinylated oligo(dT) and captured on streptavidin-coated magnetic particles. Unbound sample material and nonspecifically bound detection probes are removed and the target-specific probes are eluted and detected by capillary electrophoresis. Simultaneous treatment of 96 samples was automated using a magnetic bead particle processor. The assay enabled detection of in vitro transcribed RNA at the level of 30 amol (20 pg) and over a 300-fold linear range. Besides extracted RNA, crude cell lysates were directly used as samples. The assay was used for transcriptional analysis of selected mRNAs in the filamentous fungus Trichoderma reesei in two experimental conditions. TRAC analysis was highly reproducible, providing expression results that were consistent with conventional Northern blot analysis. The whole procedure starting from sample collecting can be carried out in 2 h, making this assay suitable for high-throughput analysis of a limited set of mRNAs e.g. in gene expression monitoring of production organism in microbial bioprocesses.

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.

Lactobacilli carry cryptic genes encoding peptidase-related proteins: characterization of a prolidase gene (pepQ) and a related cryptic gene (orfZ) from Lactobacillus delbrueckii subsp. bulgaricus

Two genes, pepQ and orfZ, encoding a prolidase and a prolidase-like protein, respectively, were cloned and characterized from Lactobacillus delbrueckii subsp. bulgaricus. The identity of the pepQ and orfZ genes with the Lactobacillus delbrueckii subsp. lactis prolidase gene (pepQ) was shown to be 98% and 60%, respectively. Both pepQ and orfZ were preceded by a putative promoter region. Northern analysis of pepQ mRNA revealed a 1.1 kb transcript indicating that pepQ forms a monocistronic transcriptional unit. Under the growth conditions used, no evidence was obtained that orfZ was expressed, either by mRNA size determination in Northern analysis or by primer extension analysis. With reverse transcription-PCR, however, the presence of monocistronic orfZ transcripts was established. The orfZ gene could also be overexpressed in E. coli using the vector pKK223-3. The size of the protein synthesized, 41 kDa, confirmed the molecular mass of OrfZ calculated according to DNA sequence analysis. In contrast to PepQ, which showed a substrate specificity characteristic of prolidase enzymes, no enzymic activity for the orfZ-encoded protein was found with the peptide substrates tested. These results indicate that orfZ is a cryptic gene, which is expressed at a very low level under the growth conditions used. It is noteworthy that homologues of the Lb. delbrueckii subsp. bulgaricus orfZ and pepQ genes appeared to be present in both Lb. delbrueckii subsp. lactis and Lactobacillus helveticus.

High level heterologous protein production in Lactococcus and Lactobacillus using a new secretion system based on the Lactobacillus brevis S-layer signals

A secretion cassette, based on the expression and secretion signals of a S-layer protein (SlpA) from Lactobacillus brevis, was constructed. E. coli beta-lactamase (Bla) was used as the reporter protein to determine the functionality of the S-layer signals for heterologous expression and secretion in Lactococcus lactis, Lactobacillus brevis, Lactobacillus plantarum, Lactobacillus gasseri and Lactobacillus casei using a low-copy-number plasmid derived from pGK12. In all hosts tested, the bla gene was expressed under the slpA signals and all Bla activity was secreted to the culture medium. The Lb. brevis S-layer promoters were very efficiently recognized in L. lactis, Lb. brevis and Lb. plantarum, whereas in Lb. gasseri the slpA promoter region appeared to be recognized at a lower level and in Lb. casei the level of transcripts was below the detection limit. The production of Bla was mainly restricted to the exponential phase of growth. The highest yield of Bla was obtained with L. lactis and Lb. brevis. Without pH control, substantial degradation of Bla occurred during prolonged cultivations with all lactic acid bacteria (LAB) tested. When growing L. lactis and Lb. brevis under pH control, the Bla activity could be stabilized also at the stationary phase. L. lactis produced up to 80 mg/l of Bla which to our knowledge represents the highest amount of a heterologous protein secreted by LAB so far. The short production phase implied a very high rate of secretion with a calculated value of 5 x 10(5) Bla molecules/cell per h. Such a high rate was also observed with Lb. plantarum, whereas in Lb. brevis the competition between the wild type slpA gene and the secretion construct probably lowered the rate of Bla production. The results obtained indicate wide applicability of the Lb. brevis slpA signals for efficient protein production and secretion in LAB.

In vivo expression of the Lactobacillus brevis S-layer gene

Lactobacillus brevis possesses a surface layer protein (SlpA) with tightly regulated synthesis. The slpA gene is expressed by two adjacent promoters, P1 and P2. The level of P2-derived transcripts was approximately 10 times higher than that of P1-derived transcripts throughout the entire growth of L. brevis. The half-lives of slpA transcripts were shown to be exceptionally long (14 min).

Characterization of a prolinase gene and its product and an adjacent ABC transporter gene from Lactobacillus helveticus

A prolinase (pepR) gene was cloned from an industrial Lactobacillus helveticus strain (53/7). Three clones, hybridizing with a gene probe specific for a peptidase shown to have activity against di- and tripeptides, were detected from a L. helveticus genomic library constructed in Escherichia coli. None of the three clones, however, showed enzyme activity against the di- or tripeptide substrates tested. One of the clones, carrying a vector with a 5.5 kb insert, was further characterized by DNA sequencing. The sequence analysis revealed the presence of two ORFs, ORF1 and ORF2 of 912 and 1602 bp, respectively. ORF2, located upstream of and in the opposite orientation to ORF1, had a promoter region overlapping that of ORF1. ORF1 had the capacity to encode a 35083 Da protein. When amplified by PCR, ORF1 with its control regions specified a 35 kDa protein in E. coli that was able to hydrolyse dipeptides, with highest activity against Pro-Leu, whereas from the tripeptides tested, only Leu-Leu-Leu was slowly degraded. By the substrate-specificity profile and protein homologies, the 35 kDa protein was identified as a prolinase. The activity of the cloned prolinase was inhibited by p-hydroxymercuribenzoate. Northern and primer-extension analyses of ORF1 revealed a 1.25 kb transcript and two adjacent transcription start sites, respectively, thus confirming the DNA sequence data. ORF2 had encoding capacity for a 59.5 kDa protein that showed significant homology to several members of the family of ABC transporters. Determination of the mRNA levels at different growth phases revealed that the pepR gene and ORF2 are transcribed in L. helveticus at the exponential and stationary phases of growth, respectively. Furthermore, two ORF2 deletion constructs, carrying the intact pepR gene, showed that this upstream operon adversely affected PepR activity in E. coli, which explains the enzymic inactivity of the original clones.

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.

S-layer protein gene of Lactobacillus brevis: cloning by polymerase chain reaction and determination of the nucleotide sequence

The surface (S)-layer protein of Lactobacillus brevis was isolated, purified, and characterized. The S-layer protein is the major protein of the cell, with an apparent molecular mass of 46 kDa in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Immunogold electron microscopy with polyclonal antiserum against the isolated 46-kDa protein was used to confirm the surface location of this protein. N-terminal amino acid sequences of the intact 46-kDa protein and its tryptic peptides were determined. The gene of the S-layer protein was amplified from the genome of L. brevis by polymerase chain reaction with oligonucleotides, synthesized according to the N-terminal amino acid sequences, as primers. The polymerase chain reaction fragments containing the entire S-layer gene and its regulatory regions were sequenced. Nucleic acid sequence analysis revealed one open reading frame with a capacity to encode a protein of 48,159 Da. From the regulatory region of the gene, two subsequent promoters and a ribosome binding site, showing typical features of prokaryotic consensus sequences, were found. The coding region contained a characteristic gram-positive-type signal peptide of 30 amino acids. Removal of the signal peptide results in a polypeptide of 435 amino acids, which is in excellent agreement with the size of the S-layer protein determined by SDS-PAGE. The size and the 5' end analyses of the S-layer transcripts confirmed the monocistronic nature of the S-layer operon and the functionality of the two promoters found.

Secretory S complex of Bacillus subtilis: sequence analysis and identity to pyruvate dehydrogenase

We have cloned the operon coding for the Bacillus subtilis S complex, which has been proposed to be a component in protein secretion machinery. A lambda gt10 library of B. subtilis was screened with antiserum directed against the Staphylococcus aureus membrane-bound ribosome protein complex, which is homologous to the B. subtilis S complex. Two positive overlapping lambda clones were sequenced. The S-complex operon, 5 kilobases in size, was shown to contain four open reading frames and three putative promoters, which are located upstream of the first, the third, and the last gene. The four proteins encoded by the operon are 42, 36, 48, and 50 kilodaltons in size. All of these proteins were recognized by antisera separately raised against each protein of the S. aureus membrane-bound ribosome protein and B. subtilis S complexes, thus verifying the S-complex identity of the lambda clones. Sequence analysis revealed that all four proteins of the B. subtilis S complex are homologous to the four subunits of the human pyruvate dehydrogenase (PDH). Also, the N terminus of the 48-kilodalton protein was found to have 70% amino acid identity with the N-terminal 211 amino acids, determined so far, from the E2 subunit of B. stearothermophilus PDH. Furthermore, chromosomal mapping of the S-complex operon gave a linkage to a marker gene located close to the previously mapped B. subtilis PDH genes. Thus, the S complex is evidently identical to the B. subtilis PDH, which has been shown to contain four subunits with molecular weights very similar to those of the S complex. Therefore, we propose that the S complex is not a primary component of protein secretion.