A series of integrative plasmids for Bacillus subtilis containing unique cloning sites in all three open reading frames for translational lacZ fusions

Promoter recognition by a complex of Spx and the C-terminal domain of the RNA polymerase alpha subunit

Background

Spx, an ArsC (arsenate reductase) family member, is a global transcriptional regulator of the microbial stress response and is highly conserved amongst Gram-positive bacteria. Bacillus subtilis Spx protein exerts positive and negative control of transcription through its interaction with the C-terminal domain of the RNA polymerase (RNAP) α subunit (αCTD). Spx activates trxA (thioredoxin) and trxB (thioredoxin reductase) in response to thiol stress, and bears an N-terminal C10XXC13 redox disulfide center that is oxidized in active Spx.

Methodology/Principal Findings

The structure of mutant Spx^C10S showed a change in the conformation of helix α4. Amino acid substitutions R60E and K62E within and adjacent to helix α4 conferred defects in Spx-activated transcription but not Spx-dependent repression. Electrophoretic mobility-shift assays showed αCTD interaction with trxB promoter DNA, but addition of Spx generated a supershifted complex that was disrupted in the presence of reductant (DTT). Interaction of αCTD/Spx complex with promoter DNA required the cis-acting elements -45AGCA-42 and -34AGCG-31 of the trxB promoter. The Spx^G52R mutant, defective in αCTD binding, did not interact with the αCTD-trxB complex. Spx^R60E not only failed to complex with αCTD-trxB, but also disrupted αCTD-trxB DNA interaction.

Conclusions/Significance

The results show that Spx and αCTD form a complex that recognizes the promoter DNA of an Spx-controlled gene. A conformational change during oxidation of Spx to the disulfide form likely alters the structure of Spx α helix α4, which contains residues that function in transcriptional activation and αCTD/Spx-promoter interaction. The results suggest that one of these residues, R60 of the α4 region of oxidized Spx, functions in αCTD/Spx-promoter contact but not in αCTD interaction.

Cre/lox system and PCR-based genome engineering in Bacillus subtilis

We have developed a fast and accurate method to engineer the Bacillus subtilis genome that involves fusing by PCR two flanking homology regions with an antibiotic resistance gene cassette bordered by two mutant lox sites (lox71 and lox66). The resulting PCR products were used directly to transform B. subtilis, and then transient Cre recombinase expression in the transformants was used to recombine lox71 and lox66 into a double-mutant lox72 site, thereby excising the marker gene. The mutation process could also be accomplished in 2 days by using a strain containing a cre isopropyl-beta-d-thiogalactopyranoside (IPTG)-inducible expression cassette in the chromosome as the recipient or using the lox site-flanked cassette containing both the cre IPTG-inducible expression cassette and resistance marker. The in vivo recombination efficiencies of different lox pairs were compared; the lox72 site that remains in the chromosome after Cre recombination had a low affinity for Cre and did not interfere with subsequent rounds of Cre/lox mutagenesis. We used this method to inactivate a specific gene, to delete a long fragment, to realize the in-frame deletion of a target gene, to introduce a gene of interest, and to carry out multiple manipulations in the same background. Furthermore, it should also be applicable to large genome rearrangement.

Temperature dependence of mycosubtilin homologue production in Bacillus subtilis ATCC6633

Bacillus subtilis ATCC6633 produces mycosubtilin, a non-ribosomally synthesized lipopeptide of the iturin family which presents antagonistic activities toward various phytopathogens. Different homologues with fatty acid moiety varying from C15 to C17 are usually co-produced, with their biological activities increasing with the number of carbons in the fatty acid chain. In the present report, we highlight that growth temperature modulates both the extent of mycosubtilin production and the relative abundance of the different homologues. A 30-fold increase in mycosubtilin production was observed when the temperature was decreased from 37 degrees C to 25 degrees C for both strain ATCC6633 and its derivative BBG100, a constitutive mycosubtilin overproducer. However, no significant difference in either the expression of the mycosubtilin synthetase encoding genes or in the intracellular synthetase concentration could be found, suggesting that the observed phenotype originated from a higher mycosubtilin synthetase turnover at lower temperature. We also point out that lower growth temperature leads to an increased proportion of odd-numbered fatty acid homologues as a consequence of de novo synthesis of C17 anteiso fatty acid following cell adaptation to low temperatures.

Macrolide resistance

The macrolides have evolved through four chemical generations since erythromycin became available for clinical use in 1952. The first generation, the 14-membered ring macrolide erythromycin, induced resistance and was replaced by the second generation 16-membered ring macrolides which did not. The inability to induce came at the price of mutation, in the pathogenic target strain, to constitutive expression of resistance. A third generation of macrolides improved the acid-stability, and therefore the pharmacokinetics of erythromycin, extending the clinical use of macrolides to Helicobacter pylori and Mycobacterium tuberculosis. Improved pharmacokinetics resulted in the selection of intrinsically resistant mutant strains with rRNA structural alterations. Expression of resistance in these strains was unexpected, explainable by low rRNA gene copy number which made resistance dominant. A fourth generation of macrolides, the 14-membered ring ketolides are the most recent development. Members of this generation are reported to be effective against inducibly resistant strains, and ketolide resistant strains have not yet been reported. In this review we discuss details of the ways in which bacteria have become resistant to the first three generations of macrolides, both with respect to their biochemistry, and the genetic mechanisms by which their expression is regulated.

New integrative method to generate Bacillus subtilis recombinant strains free of selection markers

The novel method described in this paper combines the use of blaI, which encodes a repressor involved in Bacillus licheniformis BlaP beta-lactamase regulation, an antibiotic resistance gene, and a B. subtilis strain (BS1541) that is conditionally auxotrophic for lysine. We constructed a BlaI cassette containing blaI and the spectinomycin resistance genes and two short direct repeat DNA sequences, one at each extremity of the cassette. The BS1541 strain was obtained by replacing the B. subtilis P(lysA) promoter with that of the P(blaP) beta-lactamase promoter. In the resulting strain, the cloning of the blaI repressor gene confers lysine auxotrophy to BS1541. After integration of the BlaI cassette into the chromosome of a conditionally lys-auxotrophic (BS1541) strain by homologous recombination and positive selection for spectinomycin resistance, the eviction of the BlaI cassette was achieved by single crossover between the two short direct repeat sequences. This strategy was successfully used to inactivate a single gene and to introduce a gene of interest in the Bacillus chromosome. In both cases the resulting strains are free of selection marker. This allows the use of the BlaI cassette to repeatedly further modify the Bacillus chromosome.

A 5' stem-loop and ribosome binding but not translation are important for the stability of Bacillus subtilis aprE leader mRNA

The Bacillus subtilis aprE leader is a determinant of extreme mRNA stability. The authors examined what properties of the aprE leader confer stability on an mRNA. The secondary structure of the aprE leader mRNA was analysed in vitro and in vivo, and mutations were introduced into different domains of an aprE leader-lacZ fusion. The half-lives of the corresponding transcripts were determined and beta-galactosidase activities were measured. Removal of a stem-loop structure at the 5' end or diminishing the strength of the RBS reduced the half-lives from more than 25 min to about 5 min. Interfering with translation by abolishing the start codon or creating an early stop codon had no or little effect on mRNA stability. The authors conclude that a 5' stem-loop and binding of ribosomes are necessary for the stability of aprE leader mRNA. The present results, together with a number of other data, suggest that translation of a B. subtilis mRNA is generally not important for its stability; the situation seems different in Escherichia coli. It is further concluded that the calculated strength of a B. subtilis RBS cannot be used to predict the stability of the corresponding transcript.

Construction of transcriptional and translational lacZ gene reporter plasmids for use in Streptococcus mutans

Reporter genes have become standard genetic tools used to evaluate either the transcriptional or the translational activity associated with genes of interest, whose products cannot be easily assayed. The lacZ gene from Escherichia coli has been used very effectively to quantify such regulated activities in many different organisms. This report describes the construction of a pair of plasmids that may be used for either transcriptional or translational lacZ gene fusions in Streptococcus mutans. The translational E. coli beta-galactosidase gene (lacZ) fusion plasmid, pALH109, as well as the transcriptional lacZ gene fusion plasmid, pALH122, have been used successfully in S. mutans to measure the activity of various PTS genes. Both plasmids employ fusions with the E. coli lacZ gene that can be easily quantified using standard O-nitrophenyl-beta-D-galactopyranoside (ONPG) based enzyme assays or the more sensitive fluorometric assays using 4-methyl-umbelliferyl beta-D-galactopyranoside (MUG) as the enzyme substrate. Currently, there has been only one other report of the use of lacZ as a gene reporter in S. mutans. The plasmids described in this paper will provide new tools and techniques for the analysis of S. mutans gene regulation. In addition, we have compiled the complete nucleotide sequences of these gene reporter plasmids.

Promoter cloning in the radioresistant bacterium Deinococcus radiodurans

Deinococcus radiodurans is a highly radiation-resistant bacterium that is classed in a major subbranch of the bacterial domain. Since very little is known about gene expression in this bacterium, an initial study of promoters was undertaken. In order to isolate promoters and study promoter function, a series of integrative vectors for stable chromosomal insertion in D. radiodurans were developed. These vectors are based on Escherichia coli replicons that are unable to replicate autonomously in D. radiodurans and carry homologous sequences for replacement recombination in the D. radiodurans chromosome. The resulting integration vectors were used to study expression of reporter genes fused to a number of putative promoters that were amplified from the D. radiodurans R1 genome. Further analysis of these and other putative promoters was performed by Northern hybridization and primer extension experiments. In contrast to previous reports, the -10 and -35 regions of these promoters resembled the sigma(70) consensus sequence of E. coli.

The aprE leader is a determinant of extreme mRNA stability in Bacillus subtilis

The Bacillus subtilis aprE gene encodes subtilisin, an extracellular proteolytic enzyme produced in stationary phase. The authors examined the stability of aprE mRNA and aprE leader-lacZ fusion mRNA. Both mRNAs were found to be unusually stable, with half-lives longer than 25 min, demonstrating that the aprE leader contains a determinant for extreme mRNA stability. The half-lives were the same in growing and stationary-phase cells. This contrasts with the findings of O. Resnekov et al. (1990) [Proc Natl Acad Sci USA 87, 8355-8359], which suggested a growth-phase-dependent mechanism for decay of aprE mRNA. The discrepancy is explained by the techniques used. Substitution of two bases or deletion of 25 nucleotides in the aprE leader led to a major difference in its predicted secondary structure and resulted in a fivefold reduction of the half-life of aprE mRNA. The authors also determined the half-life of amyE mRNA, which encodes alpha-amylase, another stationary-phase, excreted enzyme and found it to be around 5 min. This shows that extreme stability is not a general property of stationary-phase mRNAs encoding excreted enzymes.

Role of the DNA sequence downstream of the Bacillus subtilis hut promoter in regulation of the hut operon

To identify the role of the downstream region of a hut promoter in regulation of the Bacillus subtilis hut operon, three single-base substitutions (+9G-->A, +14C-->T, and +23T-->G) were introduced into the hut operon. Analysis of expression of the hut operon containing each of these three single-base substitutions and the hut-lacZ fusions with the single-base substitutions at position +14 showed that the position at +14 and probably the position at +23 were required for amino acid repression at the hut promoter, while the position at +14 was not required for catabolite repression at the hut promoter. The position at +9 was required for a histidine-dependent increase of activity of the hut promoter. Analysis of expression of the hut-lacZ fusions and the hut operon in the codY mutant indicated that the position at +14 and probably the position at +23 were involved in CodY-mediated amino acid repression at the hut promoter and that CodY was not required for catabolite repression at the hut promoter.

cis-acting regulatory sequences for antitermination in the transcript of the Bacillus subtilis hut operon and histidine-dependent binding of HutP to the transcript containing the regulatory sequences

The location of the cis-acting regulatory region for histidine-dependent antitermination of the Bacillus subtilis hut operon was determined. A secondary structure, whose sequences partially overlap with the downstream terminator, was found in the regulatory region of the hut transcript. Mutational analysis of the regulatory region showed that the secondary structure was required for histidine-dependent antitermination. An electrophoretic mobility-shift assay demonstrated that, in response to the presence of histidine and Mg2+, purified HutP bound hut RNA bearing putative secondary structure but not RNA lacking the potential to form putative secondary structure. Native gel electrophoresis showed that HutP existed as a hexamer. A filter-binding assay revealed that the concentration of histidine required for half-maximal binding of HutP to RNA was 3.1 mM and that the Kd for binding of HutP to RNA was approximately 0.56 microM in the presence of histidine. These results suggested that putative secondary structure in the regulatory region of hut mRNA could function as an antiterminator to inhibit the formation of the terminator structure and that HutP causes expression of the hut structural genes by binding to the putative antiterminator structure in response to the presence of histidine.

Different processing of an mRNA species in Bacillus subtilis and Escherichia coli

Expression of the Bacillus subtilis glpD gene, which encodes glycerol-3-phosphate (G3P) dehydrogenase, is controlled by termination or antitermination of transcription. The untranslated leader sequence of glpD contains an inverted repeat that gives rise to a transcription terminator. In the presence of G3P, the antiterminator protein GlpP binds to glpD leader mRNA and promotes readthrough of the terminator. Certain mutations in the inverted repeat of the glpD leader result in GlpP-independent, temperature-sensitive (TS) expression of glpD. The TS phenotype is due to temperature-dependent degradation of the glpD mRNA. In the presence of GlpP, the glpD mRNA is stabilized. glpD leader-lacZ fusions were integrated into the chromosomes of B. subtilis and Escherichia coli. Determination of steady-state levels of fusion mRNA in B. subtilis showed that the stability of the fusion mRNA is determined by the glpD leader part. Comparison of steady-state levels and half-lives of glpD leader-lacZ fusion mRNA in B. subtilis and E. coli revealed significant differences. A glpD leader-lacZ fusion transcript that was unstable in B. subtilis was considerably more stable in E. coli. GlpP, which stabilizes the transcript in B. subtilis, did not affect its stability in E. coli. Primer extension analysis showed that the glpD leader-lacZ fusion transcript is processed differently in B. subtilis and in E. coli. The dominating cleavage site in E. coli was barely detectable in B. subtilis. This site was shown to be a target of E. coli RNase III.

Cytochrome bd biosynthesis in Bacillus subtilis: characterization of the cydABCD operon

Under aerobic conditions Bacillus subtilis utilizes a branched electron transport chain comprising various cytochromes and terminal oxidases. At present there is evidence for three types of terminal oxidases in B. subtilis: a caa3-, an aa3-, and a bd-type oxidase. We report here the cloning of the structural genes (cydA and cydB) encoding the cytochrome bd complex. Downstream of the structural genes, cydC and cydD are located. These genes encode proteins showing similarity to bacterial ATP-binding cassette (ABC)-type transporters. Analysis of isolated cell membranes showed that inactivation of cydA or deletion of cydABCD resulted in the loss of spectral features associated with cytochrome bd. Gene disruption experiments and complementation analysis showed that the cydC and cydD gene products are required for the expression of a functional cytochrome bd complex. Disruption of the cyd genes had no apparent effect on the growth of cells in broth or defined media. The expression of the cydABCD operon was investigated by Northern blot analysis and by transcriptional and translational cyd-lacZ fusions. Northern blot analysis confirmed that cydABCD is transcribed as a polycistronic message. The operon was found to be expressed maximally under conditions of low oxygen tension.

Antiterminator protein GlpP of Bacillus subtilis binds to glpD leader mRNA

The Bacillus subtilis glpD gene encodes glycerol-3-phosphate (G3P) dehydrogenase. Expression of glpD is mainly controlled by termination/antitermination of transcription at an inverted repeat in the glpD leader. Antitermination is mediated by the antiterminator protein GlpP in the presence of G3P. In this paper, interaction between GlpP and glpD leader mRNA in vivo and in vitro is reported. In vivo, the antiterminating effect of GlpP can be titrated in a strain carrying the glpD leader on a plasmid. GlpP has been purified and gel shift experiments have shown that it binds to glpD leader mRNA in vitro. GlpP is not similar to other known antiterminator proteins, but database searches have revealed an Escherichia coli ORF which has a high degree of similarity to GlpP.

A vancomycin-inducible lacZ reporter system in Bacillus subtilis: induction by antibiotics that inhibit cell wall synthesis and by lysozyme

We have constructed a Bacillus subtilis strain in which expression of a vanH::lacZ gene fusion is regulated by VanR and VanS of Enterococcus faecium. This construct allows a nonpathogenic bacterial strain to be used as a model system for studying regulation of vancomycin resistance. Antibiotics and enzymes that affect cell wall biosynthesis and stability were tested for the ability to induce lacZ expression. As a result, fosfomycin and D-cycloserine were added to the group of peptidoglycan synthesis inhibitors shown to induce expression from the vanH promoter. Induction by cell wall hydrolytic enzymes, as well as by antibiotics whose actions may lead to the accumulation of chemically different peptidoglycan precursors, raises the possibility that models that postulate induction by peptidoglycan [correction of peptidodoglycan] precursors are wrong.

Vectors using the phospho-alpha-(1,1)-glucosidase-encoding gene treA of Bacillus subtilis as a reporter

The intracellular phospho-alpha-(1,1)-glucosidase, TreA, from Bacillus subtilis (Bs) hydrolyses trehalose 6-phosphate into glucose and glucose 6-phosphate. The enzyme is also able to cleave p-nitrophenyl alpha-D-glucopyranoside (PNPG). This enzymatic reaction can be easily monitored in a beta-galactosidase analogous enzyme assay. The vectors we have constructed can be used to study promoter activity in transcriptional treA fusions and may prove especially useful under high-salt conditions due to the halophilic character of TreA. The treA gene is useful as a reporter in either Bs or Escherichia coli (Ec). Such fusions can be integrated in the Bs amyE locus and selected on either kanamycin or chloramphenicol, or used as plasmids in Ec. As an example of the general utility, we demonstrate treA expression under xylA-operator-promoter control.

Transcriptional regulation of the Bacillus subtilis menp1 promoter

The Bacillus subtilis men genes encode biosynthetic enzymes for formation of the respiratory chain component menaquinone. The menp1 promoter previously was shown to be the primary cis element for menFD gene expression. In the present work, it was found that either supplementation with nonfermentable carbon sources or reutilization of glycolytic end products increased menp1 activity in the late postexponential phase. The effect on menp1 activity by a particular end product (such as acetoin or acetate) was prevented by blocking the corresponding pathway for end product utilization. Alteration of a TGAAA motif within the promoter region resulted in unregulated menp1 activity throughout the culture cycle, irrespective of the carbon source added.

Duplicate isochorismate synthase genes of Bacillus subtilis: regulation and involvement in the biosyntheses of menaquinone and 2,3-dihydroxybenzoate

Bacillus subtilis has duplicate isochorismate synthase genes, menF and dhbC. Isochorismate synthase is involved in the biosynthesis of both the respiratory chain component menaquinone (MK) and the siderophore 2,3-dihydroxybenzoate (DHB). Several menF and dhbC deletion mutants were constructed to identify the contribution made by each gene product to MK and DHB biosynthesis. menF deletion mutants were able to produce wild-type levels of MK and DHB, suggesting that the dhbC gene product is able to compensate for the lack of MenF. However, a dhbC deletion mutant produced wild-type levels of MK but was DHB deficient, indicating that MenF is unable to compensate for the lack of DhbC. A menF dhbC double-deletion mutant was both MK and DHB deficient. Transcription analysis showed that expression of dhbC, but not of menF, is regulated by iron concentration. A dhbA'::lacZ fusion strain was constructed to examine the effects of mutations to the iron box sequence within the dhb promoter region. These mutations abolished the iron-regulated transcription of the dhb genes, suggesting that a Fur-like repressor protein exists in B. subtilis.