Catabolite-responsive Element Research Articles

Regulation of the Bacillus subtilis phosphotransacetylase gene.

The enzyme, phosphotransacetylase (Pta), catalyzes the conversion of acetyl coenzyme A to acetyl phosphate. The putative pta gene of Bacillus subtilis, which had been sequenced as part of the Genome Project, was cloned and overexpressed in Escherichia coli. We confirmed that the gene encodes Pta by measuring the enzymatic activity of the purified protein. Insertional mutagenesis of the pta gene resulted in complete loss of the Pta activity, indicating that B. subtilis contains only one kind of pta gene. Expression of a pta-lacZ fusion was induced in the presence of excess glucose in the growth medium, and the intact ccpA gene was required for this activation. The transcriptional start site of the pta gene was located at 37 nucleotides upstream of the pta start codon, and a cre (catabolite responsive element) sequence, a cis-acting element that is responsible for the catabolite repression of a number of carbon utilization genes in B. subtilis, was identified upstream of the tentative promoter site. Experiments involving oligonucleotide-directed mutagenesis showed that the cre sequence is involved in glucose-mediated transcriptional activation.

Regulation of expression of the fructan hydrolase gene of Streptococcus mutans GS-5 by induction and carbon catabolite repression.

The polymers of fructose, levan and inulin, as well as sucrose and raffinose, are substrates for the product of the fruA gene of Streptococcus mutans GS-5. The purpose of this study was to characterize the DNA immediately flanking fruA, to explore the regulation of expression of fruA by the carbohydrate source, and to begin to elucidate the molecular basis for differential expression of the gene. Located 3' to fruA was an open reading frame (ORF) with similarity to beta-fructosidases which was cotranscribed with fruA. A transcriptional initiation site, located an appropriate distance from an extended -10-like promoter, was mapped at 165 bp 5' to the fruA structural gene. By the use of computer algorithms, two overlapping, stable stem-loop sequences with the potential to function as rho-independent terminators were found in the 5' untranslated region. Catabolite response elements (CREs), which have been shown to govern carbon catabolite repression (CCR) by functioning as negative cis elements in gram-positive bacteria, were located close to the promoter. The levels of production of fruA mRNA and FruA were elevated in cells growing on levan, inulin, or sucrose as the sole carbohydrate source, and repression was observed when cells were grown on readily metabolizable hexoses. Deletion derivatives containing fusions of fruA promoter regions, lacking sequences 5' or 3' to the promoter, and a promoterless chloramphenicol acetyltransferase gene were used (i) to demonstrate the functionality of the promoter mapped by primer extension, (ii) to demonstrate that CCR of the fru operon requires the CRE that is located 3' to the promoter region, and (iii) to provide preliminary evidence that supports the involvement of an antitermination mechanism in fruA induction.

Phosphorylation of either Crh or HPr mediates binding of CcpA to the Bacillus subtilis xyn cre and catabolite repression of the xyn operon

Carbon catabolite repression (CCR) of several Bacillus subtilis catabolic genes is mediated by ATP-dependent phosphorylation of Ser46 of the histidine-containing protein (HPr), a phosphocarrier protein of the phosphoenolpyruvate (PEP): sugar phosphotransferase system. A recently discovered HPr-like protein of B. subtilis, Crh, cannot be phosphorylated by PEP and enzyme I but becomes phosphorylated at Ser46 by the ATP-dependent, metabolite-activated HPr kinase. Genetic data suggested that Crh is also implicated in CCR. We here demonstrate that in a ptsH1 crh1 mutant, in which Ser46 of both HPr and Crh is replaced with an alanyl residue, expression of the β-xylosidase-encoding xynB gene was completely relieved from CCR. No effect on CCR could be observed in strains carrying the crh1 allele, suggesting that under the experimental conditions P-Ser-HPr can substitute for P-Ser-Crh in CCR. By contrast, a ptsH1 mutant was slightly relieved from CCR of xynB, indicating that P-Ser-Crh can substitute only partly for P-Ser-HPr. Mapping experiments allowed us to identify the xyn promoter and a catabolite responsive element (cre) located 229 bp downstream of the transcription start point. Using DNase I footprinting experiments, we could demonstrate that similar to P-Ser-HPr, P-Ser-Crh stimulates binding of CcpA to the xyn cre. Fructose 1,6-bisphosphate was found to strongly enhance binding of the P-Ser-HPr/CcpA and P-Ser-Crh/CcpA complexes to the xyn cre, but had no effect on binding of CcpA alone.

Characterization of a prolidase from Lactobacillus delbrueckii subsp. bulgaricus CNRZ 397 with an unusual regulation of biosynthesis.

Lactobacillus delbrueckii subsp. bulgaricus CNRZ 397 (Lb. bulgaricus) is characterized by a high level of peptidase activities specific to proline-containing peptides. A prolidase (PepQ, EC 3.4.13.9) was purified to homogeneity and characterized as a strict dipeptidase active on X-Pro dipeptides, except Gly-Pro and Pro-Pro. The values for Km and Vmax were, respectively, 2.2 mM and 0.33 mmol min(-1) mg(-1), with Leu-Pro as the substrate. The enzyme exhibited optimal activity at 50 degrees C and pH 6.0, and required the presence of Zn2+. Size exclusion chromatographies and SDS-PAGE analysis led to the conclusion that this prolidase was a homodimer. Antibodies raised against the purified protein allowed the detection of PepQ among several Lactobacillus species but not lactococci. The pepQ gene and the upstream region were isolated and sequenced. The deduced peptide sequence showed that PepQ belongs to the M24 family of metallopeptidases. The pepR1 gene is located immediately upstream of pepQ and its product is homologous to the transcription factor CcpA, which is involved in catabolite repression of catabolic operons from Gram-positive bacteria. The pepR1-pepQ intergenic region contains a consensus catabolite-responsive element (CRE) which could be a target for PepR1 protein. Moreover, in contrast to other proline-specific enzymes from Lb. bulgaricus, PepQ biosynthesis was shown to be dependent on the composition of the culture medium, but not on the peptide concentration. A possible regulation mechanism is discussed.

Catabolite repression of the xylanase gene (xynA) expression in Bacillus stearothermophilus no. 236 and B. subtilis.

Catabolite repression of the Bacillus stearothermophilus No. 236 xynA gene, encoding an extracellular xylanase, was investigated in this work. Expression of the xynA gene in the B. stearothermophilus strain was found to be subject to glucose catabolite repression, and the level of repression was about 50-fold when the relative amounts of xynA transcript synthesized on different carbon sources were analyzed. The experiments with the B. subtilis MW15 strains carrying plasmids containing the xynA::aprA fusion gene showed that the cloned xynA gene did not require any specific carbon source for its induction. Nevertheless, the expression of the cloned gene was repressed by the presence of glucose. From the nucleotide sequence of the cloned xynA gene, we found two potential catabolite responsive elements (cre) within its reading frame region (cre-1: nucleotides +160 to +173 and cre-2: +173 to +186). Furthermore, by using various deletion derivatives of the xynA::aprA fusion plasmid (pMGW23), we suggested that only the cre-2 element might play a role in the glucose catabolite repression. Repression level of the xynA gene expression in the recombinant B. subtilis strain was estimated to be about 3-fold by analysis of the amounts of xynA transcript.

Catabolite regulation of the Bacillus subtilis ctaBCDEF gene cluster.

Bacillus subtilis cytochrome c oxidase caa3 is encoded by the ctaCDEF genes at the ctaABCDEF locus, with the ctaBCDEF genes organized as an operon-like unit. A dyad symmetry sequence and a catabolite response element homolog can be recognized in the 240-bp intercistronic region between ctaB and ctaC. ctaB'-lacZ and ctaBCD'-lacZ transcriptional fusions integrated at the native locus were used to study catabolite effects on transcription of the ctaB and ctaCDEF genes. In Schaeffer's medium lacking glucose, ctaBCD'-lacZ was expressed at a very low level during the exponential phase, and expression increased about 30-fold 2 h after entry into the stationary phase. In the presence of 0.5% glucose, ctaBCD'-lacZ expression was totally repressed. In contrast to ctaBCD'-lacZ, ctaB'-lacZ was constitutively expressed regardless of carbon source. The ctaCDEF genes were separated from ctaB by insertion of plasmids carrying selectable markers in such a way that the ctaCDEF and ctaB transcription units remained intact. Enzymatic assays of caa3 with these constructs, showed that ctaCDEF was not expressed independently of ctaB. Also, when a 'ctaB-ctaC'-lacZ fusion (containing the ctaB-ctaC intercistronic region) was placed at a remote nonessential locus, beta-galactosidase activity could not be detected. The absence of a promoter in the ctaB-ctaC intercistronic space also was indicated by the inability to detect ctaC-specific transcripts with RNase protection assays, primer extension, and rapid amplification of 5' cDNA ends. Direct mRNA measurements showed that, in the presence of 0.5% glucose, ctaBCDEF transcripts terminated at the 3' end of the putative stem-loop structure and the distal portion was down-regulated. A possible mechanism for ctaCDEF gene regulation is suggested. Catabolite repression of ctaBCD'-lacZ was partly dependent on CcpA but was independent of HPr. The expression of ctaBCDEF also appears to require the strC, ctaA, and resD-resE gene products.

Transcriptional activation of the Bacillus subtilis ackA gene requires sequences upstream of the promoter.

Transcriptional activation of the Bacillus subtilis ackA gene, encoding acetate kinase, was previously shown to require catabolite control protein A (CcpA) and sequences upstream of the ackA promoter. CcpA, which is responsible for catabolite repression of a number of secondary carbon source utilization genes in B. subtilis and other gram-positive bacteria, recognizes a cis-acting consensus sequence, designated cre (catabolite response element), generally located within or downstream of the promoter of the repressed gene. Two sites resembling this sequence are centered at positions -116.5 and -56.5 of the ackA promoter and have been termed cre1 and cre2, respectively. Synthesis of acetate kinase, which is involved in the conversion of acetyl coenzyme A to acetate, is induced when cells are grown in the presence of an easily metabolized carbon source such as glucose. In this study, cre2, the site closer to the promoter, and the region upstream of cre2 were shown to be indispensable for CcpA-dependent transcriptional activation of ackA, whereas cre1 was not required. In addition, insertion of 5 bp between cre2 and the promoter disrupted activation, while 10 bp was tolerated, suggesting face-of-the-helix dependence of the position of cre2 and/or upstream sequences. DNase footprinting experiments demonstrated binding of CcpA in vitro to cre2 but not cre1, consistent with the genetic data. Activation of ackA transcription was blocked in a ptsH1/crh double mutant, suggesting involvement of this pathway in CcpA-mediated transcriptional activation.

Conversations with NADP

Catabolite repression is a central multigene regulatory network that enables bacteria to select and utilize the optimal carbon and energy sources available in a given environment. Cyclic AMP and catabolite gene activator protein (CAP) play central roles in mediating catabolite repression in enteric bacteria but are absent from Gram-positive bacteria, such as Bacillus sp. Instead, catabolite repression is mediated by the binding of catabolite control protein A (CcpA) to catabolite response elements at target genes. Recent data from Kim, Voskuil and Chambliss[1xNADP, corepressor for the Bacillus catabolite control protein CcpA. Kim, J-H., Voskuil, M.I., and Chambliss, G.H. Proc. Natl. Acad. Sci. U. S. A. 1998; 95: 9590–9595Crossref | PubMed | Scopus (60)See all References][1]indicate that NADP (but not NAD) significantly enhances CcpA-mediated repression of the α-amylase gene (amyE) of Bacillus subtilis. As NADP carries energy-rich electrons from catabolic reactions to anabolic reactions, this would allow bacteria to coordinate their choice of carbon/energy sources with the energy cycle. The mechanism by which NADP acts as a co-repressor is not clear, but might involve a conformational change in CcpA that alters its interaction with the transcriptional apparatus. Precedent for this comes from studies of the gal operon in Escherichia coli by Chatterjee et al.[2xInteraction of Gal repressor with inducer and operator: induction of gal transcription from repressor-bound DNA. Chatterjee, S. et al. Proc. Natl. Acad. Sci. U. S. A. 1997; 94: 2957–2962Crossref | PubMed | Scopus (26)See all References][2]These studies indicate that, during induction of gal transcription by d-galactose, the GalR repressor remains bound to DNA. d-Galactose is thought to block the interaction of GalR with RNA polymerase by altering GalR conformation.

Cloning, expression, and catabolite repression of a gene encoding beta-galactosidase of Bacillus megaterium ATCC 14581.

A gene encoding beta-galactosidase, designated mbgA, was isolated from Bacillus megaterium ATCC 14581. Chromosomal beta-galactosidase production could be dramatically induced by lactose but not by isopropyl-beta-D-thiogalactopyranoside (IPTG) and was subject to catabolite repression by glucose. Disruption of mbgA in the B. megaterium chromosome resulted in loss of lactose-inducible beta-galactosidase production. A 27-bp inverted repeat was found to overlap the mbgA promoter sequence. Two partially overlapping catabolite-responsive elements (CREs) were identified within the inverted repeat. Base substitutions within CRE-I and/or CRE-II caused partial relief from catabolite repression. The results suggest that the 27-bp inverted repeat may serve as a target for a catabolite repressor(s).

Expression of the bglH gene of Lactobacillus plantarum is controlled by carbon catabolite repression.

A newly identified bglH gene coding for a phospho-beta-glucosidase of Lactobacillus plantarum was isolated and expressed in Escherichia coli. The sequence analysis of the cloned DNA fragment showed an open reading frame encoding a 480-amino-acid protein with a calculated molecular mass of 53 kDa. The bglH gene was shown to be expressed on a monocistronic transcriptional unit. Its transcription was repressed 10-fold in L. plantarum cells grown on glucose compared to the beta-glucoside salicin as a sole carbon source. A catabolite-responsive element (CRE) spanning from -3 to +11 with respect to the transcriptional start point was found, and its functionality was assessed by mutational analysis. In vitro and in vivo DNA binding experiments suggested the occurrence of a DNA-protein complex at the CRE site, which would mediate glucose repression of bglH expression.

Sequencing and characterization of the xyl operon of a gram-positive bacterium, Tetragenococcus halophila.

The xyl operon of a gram-positive bacterium, Tetragenococcus halophila (previously called Pediococcus halophilus), was cloned and sequenced. The DNA was about 7.7 kb long and contained genes for a ribose binding protein and part of a ribose transporter, xylR (a putative regulatory gene), and the xyl operon, along with its regulatory region and transcription termination signal, in this order. The DNA was AT rich, the GC content being 35.8%, consistent with the GC content of this gram-positive bacterium. The xyl operon consisted of three genes, xylA, encoding a xylose isomerase, xylB, encoding a xylulose kinase, and xylE, encoding a xylose transporter, with predicted molecular weights of 49,400, 56,400, and 51,600, respectively. The deduced amino acid sequences of the XylR, XylA, XylB, and XylE proteins were similar to those of the corresponding proteins in other gram-positive and -negative bacteria, the similarities being 37 to 64%. Each polypeptide of XylB and XylE was expressed functionally in Escherichia coli. XylE transported D-xylose in a sodium ion-dependent manner, suggesting that it is the first described xylose/Na+ symporter. The XylR protein contained a consensus sequence for binding catabolites of glucose, such as glucose-6-phosphate, which has been discovered in glucose and fructose kinases in bacteria. Correspondingly, the regulatory region of this operon contained a putative binding site of XylR with a palindromic structure. Furthermore, it contained a consensus sequence, CRE (catabolite-responsive element), for binding CcpA (catabolite control protein A). We speculate that the transcriptional regulation of this operon resembles the regulation of catabolite-repressible operons such as the amy, lev, xyl, and gnt operons in various gram-positive bacteria. We discuss the significance of the regulation of gene expression of this operon in T. halophila.

Identification of a homolog of CcpA catabolite repressor protein in Streptococcus mutans.

A locus containing a gene with homology to ccpA of other bacteria has been cloned from Streptococcus mutans LT11, sequenced, and named regM. Upstream of the regM gene, on the opposite strand, is a gene encoding an X-Pro dipeptidase, pepQ. A 14-bp palindromic sequence with homology to the consensus catabolite-responsive element sequence lay in the promoter region between the two genes. To study the function of regM, the gene was inactivated by insertion of an antibiotic resistance marker. Diauxic growth of S. mutans on a number of sugars in the presence of glucose was not affected by disruption of regM. The loss of RegM increased glucose repression of alpha-galactosidase, mannitol-1-P dehydrogenase, and P-beta-galactosidase activities. These results suggest that while RegM can affect catabolite repression in S. mutans, it does not conform to the model proposed for CcpA in Bacillus subtilis.

A 35.7 kb DNA fragment from the Bacillus subtilis chromosome containing a putative 12.3 kb operon involved in hexuronate catabolism and a perfectly symmetrical hypothetical catabolite-responsive element.

The Bacillus subtilis strain 168 chromosomal region extending from 109 degrees to 112 degrees has been sequenced. Among the 35 ORFs identified, cotT and rapA were the only genes that had been previously mapped and sequenced. Out of ten ORFs belonging to a single putative transcription unit, seven are probably involved in hexuronate catabolism. Their sequences are homologous to Escherichia coli genes exuT, uidB, uxaA, uxaB, uxaC, uxuA and uxuB, which are all required for the uptake of free D-glucuronate, D-galacturonate and beta-glucuronide, and their transformation into glyceraldehyde 3-phosphate and pyruvate via 2-keto-3-deoxygluconate. The remaining three ORFs encode two dehydrogenases and a transcriptional regulator. The operon is preceded by a putative catabolite-responsive element (CRE), located between a hypothetical promoter and the RBS of the first gene. This element, the longest and the only so far described that is fully symmetrical, consists of a 26 bp palindrome matching the theoretical B. subtilis CRE sequence. The remaining predicted amino acid sequences that share homologies with other proteins comprise: a cytochrome P-450, a glycosyltransferase, an ATP-binding cassette transporter, a protein similar to the formate dehydrogenase alpha-subunit (FdhA), protein similar to NADH dehydrogenases, and three homologues of polypeptides that have undefined functions.

Binding of the Catabolite Repressor Protein CcpA to Its DNA Target Is Regulated by Phosphorylation of its Corepressor HPr

Catabolite repression of a number of catabolic operons in bacilli is mediated by the catabolite control protein CcpA, the phosphocarrier protein HPr from the phosphoenolpyruvate-dependent sugar transport system (PTS), and a cis-acting DNA sequence termed the catabolite-responsive element (cre). We present evidence that CcpA interacts with HPr that is phosphorylated at Ser46 (Ser(P) HPr) and that these proteins form a specific ternary complex with cre DNA. Titration experiments following the circular dichroism signal of the cre DNA indicate that this complex consists of two molecules of Ser(P) HPr, a CcpA dimer, and the cre sequence. Limited proteolysis experiments indicate that the domain structure of CcpA is similar to other members of the LacI/GalR family of helix-turn-helix proteins, comprised of a helix-turn-helix DNA domain and a C-terminal effector domain. NMR titration of Ser(P) HPr demonstrates that the isolated C-terminal domain of CcpA forms a specific complex with Ser(P) HPr but not with unphosphorylated HPr. Based upon perturbations to the NMR spectrum, we propose that the binding site of the C-terminal domain of CcpA on Ser(P) HPr forms a contiguous surface that encompasses both Ser(P)46 and His15, the site of phosphorylation by enzyme I of the PTS. This allows CcpA to recognize the phosphorylation state of HPr, effectively linking the process of sugar import via the PTS to catabolite repression in bacilli.

Contacts between Bacillus subtilis catabolite regulatory protein CcpA and amyO target site.

Catabolite control protein A (CcpA) is a global regulatory protein involved in catabolite repression and glucose activation in Gram-positive bacteria. cis -Acting DNA sequences, catabolite response elements ( cre s), involved in this regulatory system contain a 14 base pair (bp) region of dyad symmetry. CcpA, a repressor of the Lac I family, has been shown to bind specifically to cre s. To better understand cre recognition by CcpA, we have focused on the interaction between CcpA and the amyE cre , called amyO, which is located at the transcription start site of the alpha-amylase gene. DNA-protein complexes were probed with dimethylsulfate (DMS) and N -ethylnitrosourea (EtNU) to identify guanines and phosphates that participate in complex formation. Interaction between amyO and CcpA visualized through methylation protection and interference showed that CcpA contacts guanine residues at the outer bounds of amyO with higher affinity than near the dyad axis. From ethylation interference studies, it was found that CcpA contacts three phosphate groups at each end of amyO, and one or two phosphate groups near the dyad axis. Exonuclease III protection revealed that CcpA protects a 26 bp region centered around the dyad axis of amyO. The isolated N-terminal fragment still specifically bound to the sequence resembling the half sites of the amyO sequence. Considering these findings and the helical structure of B-DNA, our results suggest that each of the two monomers of the CcpA molecule contact the major groove in each half of the region of dyad symmetry and that the contacts are on the same face of the DNA helix, which is typical of bacterial repressor-operator interactions. However, the absence of strong contacts near the dyad axis by CcpA is in contrast to the situation with the gal repressor, another member of the Lac I family of repressors.

Catabolite repression of the Bacillus subtilis gnt operon exerted by two catabolite-responsive elements.

Catabolite repression of Bacillus subtilis catabolic operons is supposed to occur via a negative regulatory mechanism involving the recognition of a cis-acting catabolite-responsive element (cre) by a complex of CcpA, which is a member of the GalR-Lacl family of bacterial regulatory proteins, and the seryl-phosphorylated form of HPr (P-ser-HPr), as verified by recent studies on catabolite repression of the gnt operon. Analysis of the gnt promoter region by deletions and point mutations revealed that in addition to the cre in the first gene (gntR) of the gnt operon (credown), this operon contains another cre located in the promoter region (creup). A translational gntR'-'lacZ fusion expressed under the control of various combinations of wild-type and mutant credown and creup was integrated into the chromosomal amyE locus, and then catabolite repression of beta-galactosidase synthesis in the resultant integrants was examined. The in vivo results implied that catabolite repression exerted by creup was probably independent of catabolite repression exerted by credown; both creup and credown catabolite repression involved CcpA. Catabolite repression exerted by creup was independent of P-ser-HPr, and catabolite repression exerted by credown was partially independent of P-ser-HPr. DNase I footprinting experiments indicated that a complex of CcpA and P-ser-HPr did not recognize creup, in contrast to its specific recognition of credown. However, CcpA complexed with glucose-6-phosphate specifically recognized creup as well as credown, but the physiological significance of this complexing is unknown.

DNA Sequence ofBacillus subtilis(natto) NR-1γ-Glutamyltranspeptidase Gene,ggt

The ggt encoding gamma-glutamyltranspeptidase (GGT) from Bacillus subtilis (natto) was cloned and sequenced. The DNA sequence contains a single open reading frame of 1761 bp that might be translated to a protein of 587 amino acid residues, and indicates that B. subtilis (natto) GGT is synthesized as prepro-GGT and processed later into large and small subunits. The putative catabolite responsive element (CRE) was located upstream of the ggt coding region.

A sigma E dependent operon subject to catabolite repression during sporulation in Bacillus subtilis

To identify genes expressed at intermediate stages of Bacillus subtilis sporulation, we screened for sigma E-dependent promoters. One promoter that we found drives expression of an operon consisting of at least five open reading frames (ORFs). The predicted products of the first three ORFs are very homologous to enzymes involved in fatty acid metabolism, including acetyl coenzyme A (acetyl-CoA) acetyltransferase (thiolase), 3-hydroxybutyryl-CoA dehydrogenase, and acyl-CoA dehydrogenase, respectively. We showed that the fourth ORF encoded a third isozyme of citrate synthase in B. subtilis. Genetic evidence and primer extension results showed that transcription of this operon is directed by the mother cell compartment-specific sigma factor, sigma E, and so the operon was named mmg (for mother cell metabolic genes). Furthermore, we found that a sequence (mmgO) with homology to a catabolite-responsive element mediates glucose repression of mmg promoter activity during sporulation and that this repression was lost in a ccpA mutant.

Catabolite repression mediated by the catabolite control protein CcpA in Staphylococcus xylosus.

The gene ccpA encoding the catabolite control protein CcpA of Staphylococcus xylosus has been cloned and characterized. The CcpA protein belongs to the Lacl/GaiR family of bacterial regulators and is comprised of 329 amino acids, with a molecular mass of 36.3 kDa. It shows 56% identity with the CcpA proteins of Bacillus subtills and Bacillus megaterium. Inactivation of the ccpA gene in the genome of S. xylosus relieved the activities of three enzymes, alpha-glucosidase, beta-glucuronidase, and beta-galactosidase, from cataboilte repression by several carbohydrates. Concomitantly, transcription initiation of the maltose-utilization operon malRA, including the alpha-glucosidase gene malA, was no longer subject to glucose-specific control. Carbon source-dependent malRA regulation was also lost upon deletion of a palindromic sequence in the malRA promoter region resembling the catabolite-responsive elements essential for CcpA-dependent catabolite repression in Bacillus. These results strongly suggest that S. xylosus CcpA controls transcription of catabolite-repressible genes and operons by binding to catabolite-responsive operators when rapidly metabolizable carbohydrates are available. Accordingly, the cloned S. xylosus ccpA gene could complement the ccpA mutation in B. subtilis. The ccpA gene of S. xylosus is transcribed from two promoters, one of which is subject to autogenous repression by CcpA. Autoregulation results in a slight reduction of CcpA protein in glucose-grown cells. The characterization of the role of CcpA in carbon catabolite repression in S. xylosus demonstrates that a regulatory mechanism originally detected in Bacillus applies to another Gram-positive bacterium with low GC content.

Characterization of pepR1, a gene coding for a potential transcriptional regulator of Lactobacillus delbrueckii subsp. lactis DSM7290

The gene designated pepR1, encoding a potential transcription regulator of Lactobacillus delbrueckii subsp. lactis DSM7290, was identified by sequence similarity of an open reading frame located upstream of the prolidase pepQ orientated in opposite direction. pepQ and pepR1 coding regions are spaced by 152 nucleotides. Upstream of the -35 region of pepQ, a 14-bp palindromic sequence, homologous to the catabolite responsive element, could be identified. The pepR1 gene has the potential to encode a protein of 333 amino acids with a calculated molecular mass of 36955 Da and a calculated p/ of 5.5. The deduced protein sequence shows significant identity to the catabolite control protein of Bacillus. Co-expression in Escherichia coli was studied with the pepR1-pepQ intergenic region fused to the promoterless β-galactosidase reporter gene. The pepQ-β-galactosidase hybrid displayed an enhanced expression in the presence of cloned pepR1.