Regulation of the lic Operon of Bacillus subtilis and Characterization of Potential Phosphorylation Sites of the LicR Regulator Protein by Site-Directed Mutagenesis

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Tobisch, S.
	Articles by Hecker, M.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Tobisch, S.
	Articles by Hecker, M.

Journal of Bacteriology, August 1999, p. 4995-5003, Vol. 181, No. 16
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Regulation of the lic Operon of Bacillus subtilis and Characterization of Potential Phosphorylation Sites of the LicR Regulator Protein by Site-Directed Mutagenesis

Steffen Tobisch,¹ Jörg Stülke,² and Michael Hecker¹^,^*

Institut für Mikrobiologie und Molekularbiologie, Ernst-Moritz-Arndt-Universität Greifswald, D-17487 Greifswald,¹ and Lehrstuhl für Mikrobiologie, Institut für Mikrobiologie, Biochemie und Genetik, Friedrich-Alexander-Universität Erlangen-Nürnberg, D-91058 Erlangen,² Germany

Received 1 February 1999/Accepted 2 June 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The lic operon of Bacillus subtilis is required for the transport and degradation of oligomeric $beta$ -glucosides, which are producedby extracellular enzymes on substrates such as lichenan or barleyglucan. The lic operon is transcribed from a $sigma$ ^A-dependent promoter and is inducible by lichenan, lichenan hydrolysate,and cellobiose. Induction of the operon requires a DNA sequencewith dyad symmetry located immediately upstream of the licBCAHpromoter. Expression of the lic operon is positively controlledby the LicR regulator protein, which contains two potential helix-turn-helixmotifs, two phosphoenolpyruvate:carbohydrate phosphotransferasesystem (PTS) regulation domains (PRDs), and a domain similar toPTS enzyme IIA (EIIA). The activity of LicR is stimulated by modification(probably phosphorylation) of both PRD-I and PRD-II by the generalPTS components and is negatively regulated by modification (probablyphosphorylation) of its EIIA domain by the specific EII^Lic in the absence of oligomeric $beta$ -glucosides. This was shown bythe analysis of licR mutants affected in potential phosphorylationsites. Moreover, the lic operon is subject to carbon cataboliterepression (CCR). CCR takes place via a CcpA-dependent mechanismand a CcpA-independent mechanism in which the general PTS enzymeHPr isinvolved.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The gram-positive soil bacterium Bacillus subtilis is able to use a wide variety of carbohydrates, among them several glucansas the only carbon source. For the utilization of polymeric carbonsources, the cell has to synthesize extracellular enzymes whichdegrade the polymers, and the oligomers have to be transportedby specific uptake systems and introduced into the metabolism.The preferred carbon source is glucose, and expression of genesand operons whose gene products are involved in utilization ofalternative carbon sources is strongly regulated, i.e., inducibleby the specific substrate and repressed by preferred carbon sources(carbon catabolite repression [CCR]) (14, 41).

The bacterial phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) takes part in the regulation of gene expressionas a central element (33). Transport and coupled phosphorylationof its substrates constitute the primary task of the PTS. OtherPTS functions include involvement in chemotaxis and in regulationof other metabolic processes (33, 36). The PTS is composedof the general proteins enzyme I (EI) and HPr and of the substrate-specificenzyme II (EII). The EII complexes represent the sugar-specificpermeases, which consist of three or four subunits either fusedin single multidomain proteins or built up of individual polypeptides(37). The proteins of the PTS transfer a phosphoryl group fromphosphoenolpyruvate (the phosphoryl donor) to the carbohydrateto be transported (33).

In contrast to HPr of enteric bacteria, HPr from gram-positive bacteria is subject to phosphorylation at a seryl residue atposition 46 by the ATP-dependent HPr kinase (PtsK or HprK) (7,9, 11, 35) in addition to phosphorylation by EI-P on thehistidyl residue at position 15. It has been shown that HPrSer-46-Pis involved in CCR of B. subtilis (8). Glycolytic intermediates(e.g., fructose-1,6-bisphosphate and 2-phosphoglycerate) stimulatethe activity of PtsK (35).

The availability of rapidly metabolizable carbon sources represses expression of genes or operons such as amyE, licTS, bglPH,lev, and xyl (13, 16, 18, 19, 23, 30). There is anoperator sequence (catabolite-responsive element [cre]) servingas the target for the complex of the DNA binding protein CcpAand HPrSer-46-P (6, 13-15). Moreover, additional CcpA-independentmechanisms for CCR have been reported (17, 30, 44) (seebelow).

Induction of several catabolic operons occurs by increasing transcriptional initiation dependent either on transcriptionalactivators or on transcript elongation mediated by the actionof transcriptional antiterminators (41). A class of these regulatorscontains two copies of a conserved structural motif, the PTS regulationdomain (PRD) (42), which are involved in the regulation of theactivity of the proteins. The activity is modulated by phosphorylationof highly conserved histidyl residues within the PRDs by the PTSin response to the availability of the substrate. The antiterminatorsBglG of Escherichia coli and SacY, SacT, GlcT, and LicT of B.subtilis and the activator protein LevR of B. subtilis belongto the family of PRD-containing regulators (42).

In the absence of their respective inducers, PRD-containing regulators such as LevR and BglG are phosphorylated by their correspondingEII. In the presence of the inducer, the PTS transports and phosphorylatesthe sugar and dephosphorylates PRD-containing regulators, thusallowing their activity. In the case of the LevR activator, ithas been shown that the histidyl residue 869 of LevR can be phosphorylatedby EIIB^Lev, causing inactivation of the regulator, if the inducer is absent(negative control) (27).

In addition to substrate-specific negative control of the activity of PRD-containing regulators, some of them are dependenton an alternative phosphorylation by HPr to be active (1, 17,30, 44). By contrast, the B. subtilis antiterminators SacYand GlcT are active irrespective of HPr-dependent phosphorylation(4, 45). LicT and SacY are phosphorylated at three sitesby HPr. The roles of the different phosphorylation sites havenot yet been established (25, 47). Positive control of PRD-containingregulators is a novel mechanism of CCR in B. subtilis (42).

Control of protein activity by HPr-dependent phosphorylation was also demonstrated for glycerol kinase from Enterococcus faecalis(3) and the lactose transporter of Streptococcus thermophilus.In the latter protein, a domain similar to EIIA^Glc is the target of phosphorylation (12).

We have recently identified a catabolic system in B. subtilis which is involved in uptake and utilization of oligomeric $beta$ -glucosides(46). It consists of five genes, which encode a PTS enzyme IIcomplex (licA, licB, and licC), a 6-phospho- $beta$ -glucosidase (licH),and a positive regulator protein (licR). These five genes areorganized in two transcriptional units. A weak promoter precedesthe monocistronic gene licR. The genes licB, -C, -A, and -H constitutean operon. Expression of this lic operon is inducible by $beta$ -glucans,such as lichenan, and their degradation products (e.g., lichenanhydrolysate and cellobiose) and is repressed by rapidly metabolizedcarbon sources. Moreover, expression of the lic operon requiresthe general PTS components and seems to be negatively controlledby the specific Lic PTS enzymes. Initiation of transcription presumablyrequires activation by the gene product of licR. The LicR proteincontains two potential helix-turn-helix motifs, two PRDs, anda C-terminal domain similar to mannitol-specific PTS EIIA. Thus,LicR represents a novel prototype of PRD-containing regulators(42).

The present study was aimed at the elucidation of the lic operon regulation by trans-acting factors, especially LicR. We reportabout the construction of B. subtilis strains encoding LicR affectedin the putative phosphorylation sites of both the PRDs and theEIIA domain. The involvement of trans-acting factors and presumptiveregulatory DNA regions around the licB promoter was investigatedby use of a variety of licB'-lacZ fusions in different geneticbackgrounds.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains and growth conditions. The B. subtilis strains used in this study are listed in Table 1. E. coli DH5 $alpha$ [F $phi$ 80 $Delta$ lacZM15 $Delta$ (lacZYA-argF)U169 deoR recA1 endA1 hsdR17(r_K m_K⁺) supE44 thi-1 gyrA96] and RR1 [F $Delta$ (gpt-proA)62 mcrB mrr ara-14 lacY1 leuB6 galK2 rpsL20 xyl-5mtl-1 supE44] (38) were used as hosts for plasmid construction.These strains were grown in nutrient broth medium (19). Forselection of transformants, ampicillin was added to a final concentrationof 100 mg/liter. B. subtilis cells were grown in ASM minimal medium(43) or in SP medium (28) supplemented with auxotrophic requirementsunder vigorous agitation at 37°C. The following carbon sourceswere used as supplements: 0.1% ribose, 0.3% glucose, 0.05% cellobiose,0.1% lichenan hydrolysate, or 0.2% lichenan. The hydrolysate oflichenan was prepared as described previously (40). Agar plateswere prepared by addition of 15 g of Bacto agar/liter. Antibioticswere added at the following concentrations: chloramphenicol, 5mg/liter; erythromycin, 1 mg/liter; lincomycin, 25mg/liter; andspectinomycin, 100 mg/liter.

View this table:
[in this window]
[in a new window]

TABLE 1. B. subtilis strains used in this study

Genetic techniques. Standard techniques were used for plasmid extraction from E. coli (38), isolation of chromosomal DNA from B. subtilis (26),transformation of E. coli by the CaCl₂ method (38), and transformationof B. subtilis strains by the two-step protocol described by Kunstand Rapoport (21).

Treatment of DNA with restriction enzymes, T4 DNA ligase, Klenow fragment of DNA polymerase, and T4 polynucleotide kinasewas performed as recommended by the supplier. DNA fragments andPCR products were purified by using Wizard Prep kits (Promega)or recovered from agarose gels by using a GeneClean II kit (Bio101, Inc.). DNA sequences were determined by the chain terminationmethod (39) with modified T7 DNA polymerase (U.S. BiochemicalsCorp.) and plasmid DNA or PCR product as atemplate.

PCR products were obtained under conditions described previously (46). Unless otherwise described, PCRs were carried outwith chromosomal DNA of B. subtilis IS58 as a template. Priorto ligation of the PCR products with vector plasmids, the DNAwas purified by the Double GeneClean procedure (Bio 101, Inc.).The resulting plasmids were subsequently sequenced to excludepotential PCRartifacts.

Plasmid constructions and site-directed mutagenesis. Translational lacZ fusions were constructed by using the vector pAC5 (29), which carries the chloramphenicol resistancegene (cat) from pC194. The plasmid contains a lacZ gene withoutexpression signals located between two fragments of the B. subtilisamyE gene. The pAC5 derivatives pSTnb were obtained by cloningPCR products containing different parts of the DNA sequence aroundthe licB promoter (n is the name of the DNA fragment [Fig. 1])into the vector plasmid. PCR products were generated as outlinedin Fig. 1. Prior to ligation of the PCR products with pAC5, boththe vector and the respective DNA fragment were digested withBamHI and EcoRI. The resulting plasmids were analyzed by sequencing.Plasmids containing different translational licB'-lacZ fusionswere digested with ScaI for transformation of B. subtilis wild-typestrain IS58 (Table 1).

View larger version (14K):
[in this window]
[in a new window]

FIG. 1. PCR fragments used for construction of different licB'-lacZ fusions. Oligonucleotides (Pr-n); their orientations (

), lengths, and positions (bars); names of the DNA fragments used in plasmid construction; genes of the system ( $bullet$ $right-arrow$ ); putative cis-acting sequences (I [ $black-triangle-right$ $black-triangle-right$ ], II [ $black-triangle-right$ $black-triangle-left$ ], and III [ $black-triangle-right$ $black-triangle-left$ ]; the promoter (P); and the transcriptional start point (+1) of the lic operon are indicated. *, DNA fragments and lacZ fusions used for $beta$ -galactosidase assays from liquid cultures.

A mutagenesis method based on PCR (22) was used to construct plasmids containing mutant alleles of licR. The strategy forthis approach is shown in Fig. 2. Mutagenesis of the tripletsencoding histidyl residues probably involved in the control ofLicR activity was performed in first PCR steps with the mutagenicprimer 219D (5'-CCTCATTATCGATATCGCTATC-3') or 219A (5'-CCTCATTATCGCGATCGCTATC-3')and the primer Pr-45 (5'-G <UNL>GAATTC</UNL>

CGGGTGCTGATGACAAAATC-3'; the attachedEcoRI site is doubly underlined) for residue His-219, the mutagenicprimer 278E (5'-CTACATCACCATGGAGCTCCTTG-3') or 278A (5'-CTACATCACCATGGCGCTCCTTG-3')and Pr-45 for His-278, the mutagenic primer 333A (5'-CTTGGCACTCGCGATGAAGC-3')and Pr-45 for His-333, the mutagenic primer 392E (5'-GATATTTGGCTCTCGAGTTTGGCG-3')or 392I (5'-GATATTTGGCTCTAATATTTGGCG-3') and Pr-45 forHis-392, and the mutagenic primer 559G (5'-CATCCCGGGGCCGCTTGTTC-3')and Pr-42 (5'-G <UNL>GAATTC</UNL>

CGTCAGCTCAGCATTTTTTG-3'); the attached EcoRIsite is doubly underlined) for His-559 (nonmatching nucleotidesare underlined). The PCR products were used as primers in a secondPCR together with the primer Pr-44 (5'-GAGA <UNL>GGATCC</UNL>

TGAAGCTGCGCGGGGACGAG-3';the nonmatching nucleotides are underlined, and the attached BamHIsite is doubly underlined). The mutagenic primers were designedsuch that a novel restriction site was introduced upon mutagenesis(these sites are shown in italics). Thus, the presence of desiredmutations could be verified by restriction analysis of the finalPCR products. After verification of the expected restriction pattern,the PCR products were digested with BamHI and EcoRI and ligatedwith integrative plasmid pHT181 (24) treated with the same enzymes.

View larger version (16K):
[in this window]
[in a new window]

FIG. 2. Site-directed mutagenesis of licR. (A) Domain structure of LicR and positions of putative phosphorylation sites (H, histidine). The two putative helix-turn-helix motifs are indicates by bars. The PRDs having similarity to PRD-containing regulator proteins (

) and the domain of LicR which shows similarities to PTS EIIA proteins (

) are shown. (B) Mutageneses of residues His-219, His-278, His-333, His-392, and His-559 were performed by amplification of licR fragments with the indicated mutagenic oligonucleotides (219D, 219A, 278E, 278A, 333A, 392E, 392I, and 559G) and the oligonucleotides Pr-45 and Pr-42. The PCR products were used as megaprimers in a second PCR with the oligonucleotide Pr-44. The resulting DNA fragments containing the mutation and a new restriction site (*; the restriction sites are indicated) were digested with BamHI and EcoRI and ligated with the plasmid pHT181 (24) which was treated with the same enzymes. B. subtilis IS58 was cotransformed with the resulting plasmids and chromosomal DNA of strain BGT2530b. The names of the resulting plasmids and strains are indicated.

The resulting plasmids were named pSTLicR followed by the position of the mutated amino acid in LicR and the inserted aminoacid in one-letter code, e.g., pSTLicR219D (Fig. 2), and servedas template in PCRs with primers Pr-44 and Pr-45 or Pr-42. ThesePCR products were also verified by restrictionanalysis.

Construction of B. subtilis strains containing mutations in licR. The point mutations present in the plasmids pSTLicR219D to pSTLicR559G were introduced into the B. subtilis chromosome bycotransformation of strain IS58 with chromosomal DNA of strainBGT2530b (licB'[2530]-lacZ cat) and the respectiveplasmid.

Expression of the lic operon is inducible by lichenan, and a licR::neo mutation prevents expression of the operon (46).We used these effects to screen for introduction of point mutationsinto the licR gene in the chromosome of B. subtilis. Cm^r transformants were analyzed by a screening test (see below) forexpression of the lic operon. Colonies which showed a patternof $beta$ -galactosidase activity different from that of the wild-typestrain on plates were checked for sensitivity to erythromycinto verify that the vector part of the plasmid was lost. The resultingstrains (Table 1; Fig. 2) were designated BGT2530b followed bythe number of the replaced residue (1, His-219; 2, His-278; 3,His-333; 4, His-392; 5, His-559) and the name of the new aminoacid in one-letter code, e.g., BGT2530b1D (licB'[2530]-lacZ catlicRH219D).

To demonstrate that the detected phenotypes were caused by the introduced licR mutations, we amplified fragments containingthe licR allele by PCR with the oligonucleotides Pr-44 and Pr-45(for residues 219, 278, 333, and 392) or Pr-42 (for residue 559).The PCR fragments were analyzed for the presence of the restrictionsites which were introduced upon mutagenesis. All tested strainscontained a new restriction site in the licR gene. Thus, the respectivelicR mutations were correctly introduced in all strains. In addition,the licR alleles of the constructed strains were reisolated byPCR and analyzed by nucleotide sequencing. No mutations in additionto those introduced werepresent.

Assay of $beta$ -galactosidase activity. B. subtilis cultures were grown in ASM supplemented with ribose or glucose for noninducing conditions or with the inducingsubstrate lichenan, lichenan hydrolysate, or cellobiose. Bothglucose and an inducing carbon source were supplemented if CCRof the lic operon was being investigated. Cells were harvested(2-ml samples) 1.5 h after the culture entered stationary phase.The samples were stored at $-$ 20°C until the assay was carried out,as described by Miller (31). Cells were permeabilized withtoluene.

For the screening test of $beta$ -galactosidase activity, the cells were plated on SP plates containing either no additional substrateor lichenan or cellobiose and 5-bromo-4-chloro-3-indolyl- $beta$ -D-galactopyranoside(X-Gal) (50 mg/liter). The plates were incubated overnight at37°C. Strains showing the same induction pattern as the wild typeformed white colonies on the control plates and blue coloniesunder inducingconditions.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Involvement of CcpA in expression of the lic operon. Recently, we have reported that the supplementary addition of glucose to inducing carbon sources results in loss of expressionof a licH'-lacZ fusion, and a putative cre sequence was identifiedin the spacer region of the licBCAH promoter (46). We testedthe involvement of CcpA in CCR of the lic operon. Strain BGT63(licH'-lacZ cat) was transformed with chromosomal DNA of B. subtilisQB5407 (ccpA::Tn917 spc). The resulting strain, BGT635, and theisogenic wild-type strain BGT63 were grown in ASM supplementedwith either ribose, lichenan hydrolysate, or lichenan. The presenceof lichenan hydrolysate and lichenan resulted in a strong increaseof $beta$ -galactosidase activity compared to that under the noninducingconditions (ribose) in both strains (data not shown). As describedabove, no $beta$ -galactosidase activity was detectable in the referencestrain upon addition of glucose to the inducing substrates. Theaverage repression ranged from 160-fold (lichenan hydrolysatecompared to lichenan hydrolysate plus glucose) to 330-fold (lichenancompared to lichenan plus glucose). By contrast, only fivefoldrepression was observed in the ccpA genetic background (Table2). This indicates that CcpA is involved in CCR of the lic operon.The incomplete abolishment of CCR in BGT635 could be caused bya CcpA-independent mechanism (see Discussion).

View this table:
[in this window]
[in a new window]

TABLE 2. Influence of CcpA on CCR of the lic operon^a

Identification of a sequence motif responsible for induction of the lic operon. As reported previously, the intergenic region between licR and licB extends over 50 nucleotides. Upstream of licB, putativecis-acting sequences could be identified (Fig. 1, regions I, II,and III). The deduced $-$ 35 region of the licB promoter has ratherweak similarity to promoters recognized by the vegetative RNApolymerase (46). Induction of the lic operon requires the LicRprotein and a cis-acting sequence as the target. The target forinduction of the lic operon is located in the regulatory regionaround the licB promoter. This was shown by analyzing a transcriptionallicB'-lacZ fusion containing a 2.04-kb DNA fragment of the licBpromoter region in front of the promoterless lacZ gene (46).Transcriptional and translational licB'-lacZ fusions showed similarlevels and regulation patterns of $beta$ -galactosidase activity, suggestingthat induction takes place at the level of transcription (45a).

To identify the DNA region involved in induction of the operon, a set of strains containing different licB'-lacZ translationalfusions was constructed (see Materials and Methods) (Table 1;Fig. 1). These strains were plated on X-Gal-SP plates containingeither no supplemented carbon source (control) or an inducingsubstrate (cellobiose or lichenan). The results are summarizedin Table 3. All strains formed white colonies in the absenceof an inducer, indicating that the licB promoter was not active.Strains containing lacZ fusions with DNA regions spanning fromposition $-$ 1196 (with respect to the transcriptional start pointof licB) (Fig. 1, forward primer Pr-23) to positions +84 and +966(Fig. 1, reverse primer Pr-30 to Pr-32) showed the same inductionpattern as the wild type, indicating that the DNA sequence locateddownstream of the licB promoter is not required for regulationof the lic operon.

View this table:
[in this window]
[in a new window]

TABLE 3. Screening test with different licB'-lacZ fusions^a

Deletions of the sequence located upstream of the lic promoter containing putative cis-acting sequences were constructed asdescribed in Materials and Methods (Fig. 1). Strains harboringfusions of the promoterless lacZ gene with DNA fragments startingat positions $-$ 1196 to $-$ 92 (with respect to the transcriptionalstart point of licB) (Fig. 1, forward primer Pr-23 to Pr-27) formedblue colonies on plates with cellobiose or lichenan, as did theisogenic wild-type strain. In contrast, strains containing lacZfusions with DNA fragments starting in the middle of the regionexhibiting dyad symmetry of region III (Fig. 1, position $-$ 52,primer Pr-28) or downstream of region III (Fig. 1, position $-$ 39,primer Pr-29) did not show any $beta$ -galactosidase activity (Table3). This indicates that motifs I and II (Fig. 1) were not necessaryfor induction of the system but that sequence III (Fig. 1) mightbe the target forinduction.

To verify the assumption that the region required for regulation of the system is located immediately upstream of the $-$ 35region of the licB promoter, we chose some of these strains, whichcover the regulatory region (Fig. 1, asterisks), for $beta$ -galactosidaseassays. Cells were grown in ASM under inducing or noninducingconditions. The $beta$ -galactosidase activity was inducible by cellobiose(induction ratio of 50- to 140-fold) and lichenan hydrolysate(induction ratio of 180- to 320-fold) in strains BGT2332b to BGT2730b,but strains in which the complete region III exhibiting dyad symmetrywas not present (BGT2833b and BGT2830b) showed no $beta$ -galactosidaseactivity (Fig. 3). Thus, these results were consistent with theobservations from the screening test; i.e., the induction of thelic operon depends on the sequence with dyad symmetry (5'-TTTTTCCGttgctgCGAAAAA-3')situated immediately in front of the licB promoter.

View larger version (28K):
[in this window]
[in a new window]

FIG. 3. Activity of $beta$ -galactosidase from selected licB'-lacZ fusions. Growth conditions and sample collection were as described in Table 2, footnote a. Representative results from three independent experiments are shown.

Characterization of potential phosphorylation sites of LicR by site-directed mutagenesis. LicR belongs to the PRD-containing regulators, which can be modified in their activity by phosphorylation of highly conservedhistidyl residues by the PTS (42). To investigate the possibleinvolvement of the conserved histidyl residues in the PRDs andthe EIIA domain (Fig. 2 and 4) in the modification of the LicRactivity and consequently in the regulation of the lic operon,we constructed mutants in which these residues were replaced byother amino acids. The strategy and construction of strains containingboth a mutant allele of licR and the licB'-lacZ fusion are describedin Materials and Methods (Table 1; Fig. 2).

View larger version (14K):
[in this window]
[in a new window]

FIG. 4. Proposed model for the regulation of LicR activity by the PTS. The activity of LicR is stimulated by phosphorylation of histidyl residues in both PRD-I and PRD-II of LicR by HPrHis-15-P. Replacement of any of these histidyl residues results in loss of LicR activity and thus of induction of the lic operon. In the absence of lichenan hydrolysate, the PTS EII^Lic is phosphorylated, and its components (LicA and LicB) may phosphorylate the PTS EIIA domain of LicR, causing inactivation of it regardless of the phosphorylation status of the PRDs. In the presence of lichenan hydrolysate, LicA and LicB and subsequently the EIIA-like domain of LicR are dephosphorylated. The PTS EIIA domain of LicR cannot be phosphorylated in licRH559G and EII^Lic mutants. Therefore, the lic operon is constitutively expressed in these mutants, as it is in the wild type under inducing conditions. Modification of LicR via phosphorylation by HPr may be involved in CCR. In the presence of rapidly metabolizable PTS sugars, the competition of the sugar-specific PTS EIIs and the PRD of LicR for the phosphoryl donor HPrHis-15-P will lower the level of phosphorylation of the PRDs of LicR and thus attenuate activity of LicR.

First, the licR mutant strains and the isogenic wild-type strain (BGT2530b) were analyzed in a screening test by cultivationon X-Gal-SP plates in the absence or presence of an inducer (seeMaterials and Methods). Strains carrying mutations affecting thehistidyl residues in the PRDs of LicR formed white colonies undernoninducing conditions, as observed with the wild-type strain.In contrast, a mutation in the residue equivalent to the phosphorylationsite in EIIA^Mtl (34) (licRH559G) resulted in the formation of blue coloniesin the absence of inducer, indicating activity of the mutant LicRprotein under noninducing conditions. While the wild-type strainformed blue colonies on plates containing lichenan, no expressionof the licB'-lacZ fusion was detectable when the histidyl residuesof the PRDs were replaced by nonphosphorylatable amino acids,suggesting that the histidyl residues in the PRDs of LicR arerequired for activity. As observed in the absence of inducer,strain BGT2530b5G, harboring the licRH559G mutant allele of licR,formed blue colonies on plates containing lichenan. This LicRprotein therefore has constitutiveactivity.

Second, we investigated the influence of these different mutations on the activity of LicR in $beta$ -galactosidase assays. Strainscontaining mutant alleles of licR and the isogenic wild-type strain(BGT2530b) were grown in ASM supplemented with either ribose,glucose, cellobiose, lichenan hydrolysate, or both glucose andan inducing carbon source. The results of these experiments areshown in Table 4. As described above, expression of the lic operonwas induced by cellobiose and lichenan hydrolysate in the wild-typestrain. In contrast, loss of expression occurred in such strainsin which one of the four conserved histidyl residues of PRD-I(219 and 278) or PRD-II (333 and 392) was replaced by asparticacid or glutamic acid. Similar results were obtained upon replacementof the conserved histidyl residues by neutral amino acids. Inductionof the licB'-lacZ fusion was lost in strains BGT2530b2A (licRH278A)and BGT2530b3A (licRH333A) and was reduced to a minor level instrains BGT2530b1A (licRH219A) and BGT2530b4I (licRH392I). Thus,the conserved histidyl residues of both PRDs are necessary forLicR activity.

View this table:
[in this window]
[in a new window]

TABLE 4. Effect of point mutations in licR on $beta$ -galactosidase activity of the translational licB'[2530]-lacZ fusion^a

High-level expression of the licB'-lacZ fusion occurred under inducing or noninducing conditions when the conserved histidylresidue 559 in the EIIA domain of LicR was replaced by glycine.Thus, the histidyl residue at position 559 seems to be the targetof negative regulation of LicR activity by PTS EII^Lic, because the expression of the licB'-lacZ fusion was constitutivein both a licRH559G mutant and a licC::neo genetic background(data notshown).

Summarizing these results, we suggest that all tested histidyl residues are involved in the modification of the LicR activity.CCR of the lic operon is not affected by replacement of the fivehistidyl residues (Table 4).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Expression of the lic operon in B. subtilis is induced in the presence of oligomeric $beta$ -glucosides, which are the degradationproducts of polymeric $beta$ -glucans (40, 46), and is repressedby glucose or other rapidly metabolized carbon sources (46).We present data showing that the regulatory protein LicR, theproteins of the PTS, and the CcpA protein are involved in theregulation of licBCAH geneexpression.

In B. subtilis the CcpA protein, the HPr protein, and a catabolite-responsive element (cre) are involved in CCR (13-15). Apotential cre sequence was identified in the licBCAH promoterregion (46). As observed with other catabolic systems, glucoserepression of the lic operon decreases drastically in a ccpA mutant,indicating that CcpA is involved in the regulation of licBCAHexpression by glucose. In addition, the arrangement of the creis similar to that for other catabolic systems which are subjectto CCR (e.g., bglPH) (18). Thus, CCR of licBCAH expression followsthe CcpA- and cre-dependent mechanism which was investigated intensivelyfor catabolic systems in B. subtilis and other gram-positive bacteria(14). However, CCR of the lic operon was not completely abolishedin the ccpA mutant; i.e., a residual repression was observed.It thus seemed possible that a CcpA-independent mechanism is additionallyinvolved in CCR of the lic operon. CcpA-independent CCR was describedfor the lev and bglPH operons of B. subtilis and involves positivecontrol of PRD-containing operon-specific regulators by the HPrprotein of the PTS (17, 30, 44).

The $-$ 35 region of the licBCAH promoter has rather weak similarity to promoters recognized by the vegetative RNA polymerase,and expression of a licB'-lacZ fusion is strongly inducible. Thus,we suggested the requirement of a transcriptional activator (LicR)and a target site recognized by the activator, which is locatedclose to the promoter (46). During the DNA sequence analysisof the lic system, three motifs upstream of the promoter wereidentified (Fig. 1). Two of these sequences are located withinthe coding region of licR, whereas the third motif (motif III)is located within the intergenic region between licR and licB(immediately upstream of the licBCAH promoter). Deletion analysisof the promoter region revealed that only region III is requiredfor induction of the lic operon. This inverted repeat might thereforebe a target for the binding of the transcriptional activatorLicR.

Sequence analysis of the complete B. subtilis genome (20) by using the SubtiList server (32) indicates that sequence motifIII, with one mismatch in the dyad symmetry and differences inthe length of the spacer, is present upstream of yjdC (manR) (20,42) and yvfQ (encoding a putative endo-1,4- $beta$ -galactosidase)(20). The ManR protein, with a domain structure similar to thatof LicR, is probably involved in the regulation of genes necessaryfor mannose utilization (yjdD and yjdE) (20).

LicR regulates the expression of the lic operon by acting as an activator (reference 46 and this work). In addition to theantiterminator BglG of E. coli and the activator LevR of B. subtilis,LicR is a prototype of a novel group of PRD-containing regulators(42). These positive regulators are controlled in their activityby PTS-dependent phosphorylation on highly conserved histidylresidues in the duplicated PRDs. However, the actual phosphorylationsites differ among these regulators. The activator LevR is phosphorylatedat a histidyl residue in PRD-II by EIIB^Lev in the absence of the inducer fructose, causing inactivation(27), while the antiterminators of this class of regulatorsare negatively controlled by phosphorylation of a residue in PRD-I(2, 5, 47). In contrast, activation of LevR takes placeby HPr-dependent phosphorylation on His-585 (27). This histidine,however, does not correspond to a histidyl residue which is conservedin all PRDs. Additionally, the proteins SacY and LicT were phosphorylatedby HPr on several histidyl residues (25, 47).

In this study we investigated the involvement of the conserved histidyl residues in the PRDs and in the EIIA domain of theLicR protein in the regulation of LicR activity. Surprisingly,the activity of LicR seems to require phosphorylation of bothPRD-I and PRD-II. The replacement of each of the four histidylresidues in the PRDs leads to the loss of induction of the licoperon. Similarly, expression of the operon is also completelyabolished in a $Delta$ ptsGHI genetic background (46). Thus, LicR mightbe activated by phosphorylation of histidyl residues in PRD-Iand PRD-II by HPr (in analogy to the other PRD-containing regulators),and all histidyl residues might be necessary for LicR activity.The presumptive phosphorylation site of the EIIA-like domain,His-559, seems to be involved in negative control of LicR activity.The expression of the lic operon is constitutive in a licRH559Gmutant as well as in an EII^Licmutant.

These results suggest the existence of a regulatory mechanism for LicR different from the one proposed for other PRD-containingregulators (42). Both PRDs are required for positive controlof LicR, and a third regulatory domain (the EIIA domain) is involvedin negative regulation of the regulator. This notion is in agreementwith the conclusion that possibly more than one mechanism fornegative control of PRD-containing regulators is operative (2).

In conclusion, we propose that the PTS EII^Lic is phosphorylated in the absence of oligomeric $beta$ -glucosides. Under these conditions,LicB (or LicA) phosphorylates the EIIA domain of LicR, causinginactivation of the regulator. If oligomeric $beta$ -glucosides aretransported and phosphorylated by the PTS EII^Lic, then the EIIA domain of LicR cannot be phosphorylated by EII^Lic. Under inducing conditions, the activity of LicR depends on thephosphorylation state of the PRDs. In the absence of repressingsugars, the PRDs may be phosphorylated. Thus, the LicR proteinis stimulated, and the lic operon is expressed. By contrast, inthe presence of rapidly metabolized PTS carbon sources, a competitionof the PTS enzyme II components and the PRDs of LicR for the phosphoryldonor HPr might take place. Thus, the level of phosphorylationat the PRDs decreases, resulting in a loss of LicR activity (Fig.4).

	ACKNOWLEDGMENTS

We are grateful to A. Tschirner for excellent technical assistance. We thank S. Bachem for help with the site-directed mutagenesisof licR. G. Mittenhuber, F. Titgemeyer, and U. Zuber are acknowledgedfor critical reading of the manuscript and for helpfuldiscussions.

This work was supported by the DeutscheForschungsgemeinschaft.

	ADDENDUM IN PROOF

The Bacillus stearothermophilus MtlR activator, which has a domain structure similar to LicR, has recently been shown to bephosphorylated by PTS proteins. HPr-dependent phosphorylationstimulates MtlR binding to DNA, whereas phosphorylation by EIICBinhibits DNA binding (S. A. Henstra et al., J. Biol. Chem. 274:4754-4763,1999).

	FOOTNOTES

^* Corresponding author. Mailing address: Institut für Mikrobiologie und Molekularbiologie, Ernst-Moritz-Arndt-UniversitätGreifswald, Friedrich-Ludwig-Jahn-Strasse 15, D-17487 Greifswald,Germany. Phone: 49(0)3834-864200. Fax: 49(0)3834-864202. E-mail:hecker{at}microbio7.biologie.uni-greifswald.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Arnaud, M., P. Vary, M. Zagorec, A. Klier, M. Débarbouillé, P. Postma, and G. Rapoport. 1992. Regulation of the sacPA operon of Bacillus subtilis: identification of phosphotransferase system components involved in SacT activity. J. Bacteriol. 174:3161-3170[Abstract/Free Full Text].

2. Bachem, S., and J. Stülke. 1998. Regulation of the Bacillus subtilis GlcT antiterminator protein by components of the phosphotransferase system. J. Bacteriol. 180:5319-5326[Abstract/Free Full Text].

3. Charrier, V., E. Buckley, D. Parsonage, A. Galinier, E. Darbon, M. Jaquinod, E. Forest, J. Deutscher, and A. Claiborne. 1997. Cloning and sequencing of two enterococcal glpK genes and regulation of the encoded glycerol kinases by phosphoenolpyruvate-dependent, phosphotransferase system-catalyzed phosphorylation of a single histidyl residue. J. Biol. Chem. 272:14166-14174[Abstract/Free Full Text].

4. Crutz, A. M., M. Steinmetz, S. Aymerich, R. Richter, and D. Le Coq. 1990. Induction of levansucrase in Bacillus subtilis: an antitermination mechanism negatively controlled by the phosphotransferase system. J. Bacteriol. 172:1043-1050[Abstract/Free Full Text].

5. Débarbouillé, M., M. Arnaud, A. Fouet, A. Klier, and G. Rapoport. 1990. The sacT gene regulating the sacPA operon in Bacillus subtilis shares strong homology with transcriptional antiterminators. J. Bacteriol. 172:3966-3973[Abstract/Free Full Text].

6. Deutscher, J., E. Küster, U. Bergstedt, V. Charrier, and W. Hillen. 1995. Protein kinase-dependent HPr/CcpA interaction links glycolytic activity to carbon catabolite repression in Gram-positive bacteria. Mol. Microbiol. 15:1049-1053[Medline].

7. Deutscher, J., B. Pevec, K. Beyreuther, H.-H. Kiltz, and W. Hengstenberg. 1986. Streptococcal phosphoenolpyruvate-sugar phosphotransferase system: amino acid sequence and site of ATP-dependent phosphorylation of HPr. Biochemistry 25:6543-6551[Medline].

8. Deutscher, J., J. Reizer, C. Fischer, A. Galinier, M. H. Saier, and M. Steinmetz. 1994. Loss of protein kinase-catalyzed phosphorylation of HPr, a phosphocarrier protein of the phosphotransferase system, by mutation of ptsH gene confers catabolite repression resistance to several catabolic genes of Bacillus subtilis. J. Bacteriol. 176:3336-3344[Abstract/Free Full Text].

9. Deutscher, J., and M. H. Saier. 1983. ATP-dependent, protein kinase-catalyzed phosphorylation of a seryl residue in HPr, a phosphoryl carrier protein of the phosphotransferase system in Streptococcus pyogenes. Proc. Natl. Acad. Sci. USA 80:6790-6794[Abstract/Free Full Text].

10. Faires, N., S. Tobisch, S. Bachem, I. Martin-Verstraete, M. Hecker, and J. Stülke. 1999. The catabolite control protein CcpA controls ammonium assimilation in Bacillus subtilis. J. Mol. Microbiol. Biotechnol. 1:141-148. [Medline]

11. Galinier, A., M. Kravanja, R. Engelmann, W. Hengstenberg, M. C. Kilhoffer, J. Deutscher, and J. Haiech. 1998. New protein kinase and protein phosphatase families mediate signal transduction in bacterial catabolite repression. Proc. Natl. Acad. Sci. USA 95:1823-1828[Abstract/Free Full Text].

12. Gunnewijk, M. G. W., P. W. Postma, and B. Poolman. 1999. Phosphorylation and functional properties of the IIA domain of the lactose transport protein of Streptococcus thermophilus. J. Bacteriol. 181:632-641[Abstract/Free Full Text].

13. Henkin, T. M., F. J. Grundy, W. L. Nicholson, and G. H. Chambliss. 1991. Catabolite repression of alpha-amylase gene expression in Bacillus subtilis involves a trans-acting gene product homologous to the Escherichia coli lacI and galR repressors. Mol. Microbiol. 5:575-584[Medline].

14. Hueck, C. J., and W. Hillen. 1995. Catabolite repression in Bacillus subtilis: a global regulatory mechanism for Gram-positive bacteria? Mol. Microbiol. 15:395-401[Medline].

15. Hueck, C. J., W. Hillen, and M. H. Saier. 1994. Analysis of a cis-active sequence mediating catabolite repression in Gram-positive bacteria. Res. Microbiol. 145:503-518[Medline].

16. Kraus, A., C. Hueck, D. Gärtner, and W. Hillen. 1994. Catabolite repression of the Bacillus subtilis xyl operon involves a cis element functional in the context of an unrelated sequence, and glucose exerts additional xylR-dependent repression. J. Bacteriol. 176:1738-1745[Abstract/Free Full Text].

17. Krüger, S., S. Gertz, and M. Hecker. 1996. Transcriptional analysis of the bglPH expression in Bacillus subtilis: evidence for two distinct pathways mediating carbon catabolite repression. J. Bacteriol. 178:2637-2644[Abstract/Free Full Text].

18. Krüger, S., and M. Hecker. 1995. Regulation of the putative bglPH operon for aryl- $beta$ -glucoside utilization in Bacillus subtilis. J. Bacteriol. 177:5590-5597[Abstract/Free Full Text].

19. Krüger, S., J. Stülke, and M. Hecker. 1993. Catabolite repression of $beta$ -glucanase synthesis in Bacillus subtilis. J. Gen. Microbiol. 139:2047-2054[Medline].

20. Kunst, F., N. Ogasawara, I. Moszer, A. M. Albertini, G. Alloni, V. Azevedo, M. G. Bertero, P. Bessieres, A. Bolotin, S. Borchert, R. Borriss, L. Boursier, A. Brans, M. Braun, S. C. Brignell, S. Bron, S. Brouillet, C. V. Bruschi, B. Caldwell, V. Capuano, N. M. Carter, S. K. Choi, J. J. Codani, I. F. Connerton, A. Danchin, et al. 1997. The complete genome sequence of the Gram-positive bacterium Bacillus subtilis. Nature 390:249-256[Medline].

21. Kunst, F., and G. Rapoport. 1995. Salt stress is an environmental signal affecting degradative enzyme synthesis in Bacillus subtilis. J. Bacteriol. 177:2403-2407[Abstract/Free Full Text].

22. Landt, O., H.-P. Grunert, and U. Hahn. 1990. A general method for rapid site-directed mutagenesis using the polymerase chain reaction. Gene 96:125-128[Medline].

23. Le Coq, D., C. Lindner, S. Krüger, M. Steinmetz, and J. Stülke. 1995. New $beta$ -glucoside (bgl) genes in Bacillus subtilis: the bglP gene product has both transport and regulatory functions, similar to those of BglF, its Escherichia coli homolog. J. Bacteriol. 177:1527-1535[Abstract/Free Full Text].

24. Lereclus, D., and O. Arantes. 1992. spbA locus ensures the segregational stability of pTH1030, a novel type of Gram-positive replicon. Mol. Microbiol. 6:35-46[Medline].

25. Lindner, C., A. Galinier, M. Hecker, and J. Deutscher. 1999. Regulation of the activity of the Bacillus subtilis antiterminator LicT by PEP-dependent, enzyme I- and HPr-catalyzed phosphorylation. Mol. Microbiol. 3:995-1006.

26. Maede, H. M., S. R. Long, G. B. Ruvkun, S. E. Brown, and F. M. Ausubel. 1982. Physical and genetic characterization of symbiotic and auxotrophic mutants of Rhizobium meliloti induced by transposon Tn5 mutagenesis. J. Bacteriol. 149:114-122[Abstract/Free Full Text].

27. Martin-Verstraete, I., V. Charrier, J. Stülke, A. Galinier, B. Erni, G. Rapoport, and J. Deutscher. 1998. Antagonistic effects of dual PTS-catalyzed phosphorylation on the Bacillus subtilis transcriptional activator LevR. Mol. Microbiol. 28:293-303[Medline].

28. Martin-Verstraete, I., M. Débarbouillé, A. Klier, and G. Rapoport. 1990. Levanase operon of Bacillus subtilis includes a fructose-specific phosphotransferase system regulating the expression of the operon. J. Mol. Biol. 214:657-671[Medline].

29. Martin-Verstraete, I., M. Débarbouillé, A. Klier, and G. Rapoport. 1992. Mutagenesis of the Bacillus subtilis ' $-$ 12, $-$ 24' promoter of the levanase operon and evidence for the existence of an upstream activating sequence. J. Mol. Biol. 226:85-99[Medline].

30. Martin-Verstraete, I., J. Stülke, A. Klier, and G. Rapoport. 1995. Two different mechanisms mediate catabolite repression of the Bacillus subtilis levanase operon. J. Bacteriol. 177:6919-6927[Abstract/Free Full Text].

31. Miller, J. 1972. Experiments in molecular genetics. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.

32. Moszer, I., P. Glaser, and A. Danchin. 1995. SubtiList: a relational database for the Bacillus subtilis genome. Microbiology 141:261-268[Abstract].

33. Postma, P. W., J. W. Lengeler, and G. R. Jacobson. 1993. Phosphoenolpyruvate:carbohydrate phosphotransferase systems of bacteria. Microbiol. Rev. 57:543-594[Abstract/Free Full Text].

34. Reiche, B., R. Frank, J. Deutscher, N. Meyer, and W. Hengstenberg. 1988. Staphylococcal phosphoenolpyruvate-dependent phosphotransferase system: purification and characterization of the mannitol-specific enzyme III^mtl of Staphylococcus aureus and Staphylococcus carnosus and homology with the enzyme III^mtl of Escherichia coli. Biochemistry 27:6512-6516[Medline].

35. Reizer, J., C. Hoischen, F. Titgemeyer, C. Rivolta, R. Rabus, J. Stülke, D. Karamata, M. H. Saier, and W. Hillen. 1998. A novel protein kinase that controls carbon catabolite repression in bacteria. Mol. Microbiol. 27:1157-1169[Medline].

36. Saier, M. H. 1989. Protein phosphorylation and allosteric control of inducer exclusion and catabolite repression by the bacterial phosphoenolpyruvate:sugar phosphotransferase system. Microbiol. Rev. 53:109-120[Abstract/Free Full Text].

37. Saier, M. H., and J. Reizer. 1992. Proposed uniform nomenclature for the proteins and the protein domains of the bacterial phosphoenolpyruvate:sugar phosphotransferase system. J. Bacteriol. 174:1433-1438[Free Full Text].

38. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.

39. Sanger, F., S. Nicklen, and A. R. Coulson. 1977. DNA sequencing with chain-terminating inhibitors. Proc. Natl. Acad. Sci. USA 74:5463-5467[Abstract/Free Full Text].

40. Schnetz, K., J. Stülke, S. Gertz, S. Krüger, M. Krieg, M. Hecker, and B. Rak. 1996. LicT, a Bacillus subtilis transcriptional antiterminator protein of the BglG family. J. Bacteriol. 178:1971-1979[Abstract/Free Full Text].

41. Steinmetz, M. 1993. Carbohydrate catabolism: pathways, enzymes, genetic regulation, and evolution, p. 157-170. In A. L. Sonenshein, J. A. Hoch, and R. Losick (ed.), Bacillus subtilis and other gram-positive bacteria: biochemistry, physiology, and molecular genetics. American Society for Microbiology, Washington, D.C.

42. Stülke, J., M. Arnaud, G. Rapoport, and I. Martin-Verstraete. 1998. PRD $---$ a protein domain involved in PTS-dependent induction and carbon catabolite repression of catabolic operons in bacteria. Mol. Microbiol. 28:865-874[Medline].

43. Stülke, J., R. Hanschke, and M. Hecker. 1993. Temporal activation of $beta$ -glucanase synthesis in Bacillus subtilis is mediated by the GTP pool. J. Gen. Microbiol. 139:2041-2045[Medline].

44. Stülke, J., I. Martin-Verstraete, V. Charrier, A. Klier, J. Deutscher, and G. Rapoport. 1995. The HPr protein of the phosphotransferase system links induction and catabolite repression of the Bacillus subtilis levanase operon. J. Bacteriol. 177:6928-6936[Abstract/Free Full Text].

45. Stülke, J., I. Martin-Verstraete, M. Zagorec, M. Rose, A. Klier, and G. Rapoport. 1997. Induction of the Bacillus subtilis ptsGHI operon by glucose is controlled by a novel antiterminator, GlcT. Mol. Microbiol. 25:65-78[Medline].

45a. Tobisch, S. Unpublished results.

46. Tobisch, S., P. Glaser, S. Krüger, and M. Hecker. 1997. Identification and characterization of a new $beta$ -glucoside utilization system in Bacillus subtilis. J. Bacteriol. 179:496-506[Abstract/Free Full Text].

47. Tortosa, P., S. Aymerich, C. Lindner, M. H. Saier, J. Reizer, and D. Le Coq. 1997. Multiple phosphorylation of SacY, a Bacillus subtilis antiterminator negatively controlled by the phosphotransferase system. J. Biol. Chem. 272:17230-17237[Abstract/Free Full Text].

This article has been cited by other articles:

Perkins, A. E., Nicholson, W. L. (2008). Uncovering New Metabolic Capabilities of Bacillus subtilis Using Phenotype Profiling of Rifampin-Resistant rpoB Mutants. J. Bacteriol. 190: 807-814 [Abstract] [Full Text]
Deutscher, J., Francke, C., Postma, P. W. (2006). How Phosphotransferase System-Related Protein Phosphorylation Regulates Carbohydrate Metabolism in Bacteria. Microbiol. Mol. Biol. Rev. 70: 939-1031 [Abstract] [Full Text]
Puri-Taneja, A., Paul, S., Chen, Y., Hulett, F. M. (2006). CcpA Causes Repression of the phoPR Promoter through a Novel Transcription Start Site, PA6. J. Bacteriol. 188: 1266-1278 [Abstract] [Full Text]
Gruening, P., Fulde, M., Valentin-Weigand, P., Goethe, R. (2006). Structure, Regulation, and Putative Function of the Arginine Deiminase System of Streptococcus suis. J. Bacteriol. 188: 361-369 [Abstract] [Full Text]
Lorca, G. L., Chung, Y. J., Barabote, R. D., Weyler, W., Schilling, C. H., Saier, M. H. Jr (2005). Catabolite Repression and Activation in Bacillus subtilis: Dependency on CcpA, HPr, and HprK. J. Bacteriol. 187: 7826-7839 [Abstract] [Full Text]
Ren, D., Bedzyk, L. A., Setlow, P., England, D. F., Kjelleberg, S., Thomas, S. M., Ye, R. W., Wood, T. K. (2004). Differential Gene Expression To Investigate the Effect of (5Z)-4-Bromo- 5-(Bromomethylene)-3-Butyl-2(5H)-Furanone on Bacillus subtilis. Appl. Environ. Microbiol. 70: 4941-4949 [Abstract] [Full Text]
Dong, Y., Chen, Y.-Y. M., Burne, R. A. (2004). Control of Expression of the Arginine Deiminase Operon of Streptococcus gordonii by CcpA and Flp. J. Bacteriol. 186: 2511-2514 [Abstract] [Full Text]
Schmalisch, M. H., Bachem, S., Stulke, J. (2003). Control of the Bacillus subtilis Antiterminator Protein GlcT by Phosphorylation: ELUCIDATION OF THE PHOSPHORYLATION CHAIN LEADING TO INACTIVATION OF GlcT. J. Biol. Chem. 278: 51108-51115 [Abstract] [Full Text]
Gosalbes, M. J., Esteban, C. D., Perez-Martinez, G. (2002). In vivo effect of mutations in the antiterminator LacT in Lactobacillus casei. Microbiology 148: 695-702 [Abstract] [Full Text]
Wen, Z. T., Burne, R. A. (2002). Analysis of cis- and trans-Acting Factors Involved in Regulation of the Streptococcus mutans Fructanase Gene (fruA). J. Bacteriol. 184: 126-133 [Abstract] [Full Text]
Behrens, S., Mitchell, W. J., Bahl, H. (2001). Molecular analysis of the mannitol operon of Clostridium acetobutylicum encoding a phosphotransferase system and a putative PTS-modulated regulator. Microbiology 147: 75-86 [Abstract] [Full Text]
Yebra, M. J., Veyrat, A., Santos, M. A., Pérez-Martínez, G. (2000). Genetics of L-Sorbose Transport and Metabolism in Lactobacillus casei. J. Bacteriol. 182: 155-163 [Abstract] [Full Text]
Reizer, J., Bachem, S., Reizer, A., Arnaud, M., Saier, M. H. Jr, Stülke, J. (1999). Novel phosphotransferase system genes revealed by genome analysis - the complete complement of PTS proteins encoded within the genome of Bacillus subtilis. Microbiology 145: 3419-3429 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Tobisch, S.
	Articles by Hecker, M.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Tobisch, S.
	Articles by Hecker, M.

Appl. Environ. Microbiol.	Infect. Immun.	Eukaryot. Cell
Mol. Cell. Biol.	J. Virol.	Microbiol. Mol. Biol. Rev.
	ALL ASM JOURNALS

1.	Arnaud, M., P. Vary, M. Zagorec, A. Klier, M. Débarbouillé, P. Postma, and G. Rapoport. 1992. Regulation of the sacPA operon of Bacillus subtilis: identification of phosphotransferase system components involved in SacT activity. J. Bacteriol. 174:3161-3170[Abstract/Free Full Text].
2.	Bachem, S., and J. Stülke. 1998. Regulation of the Bacillus subtilis GlcT antiterminator protein by components of the phosphotransferase system. J. Bacteriol. 180:5319-5326[Abstract/Free Full Text].
3.	Charrier, V., E. Buckley, D. Parsonage, A. Galinier, E. Darbon, M. Jaquinod, E. Forest, J. Deutscher, and A. Claiborne. 1997. Cloning and sequencing of two enterococcal glpK genes and regulation of the encoded glycerol kinases by phosphoenolpyruvate-dependent, phosphotransferase system-catalyzed phosphorylation of a single histidyl residue. J. Biol. Chem. 272:14166-14174[Abstract/Free Full Text].
4.	Crutz, A. M., M. Steinmetz, S. Aymerich, R. Richter, and D. Le Coq. 1990. Induction of levansucrase in Bacillus subtilis: an antitermination mechanism negatively controlled by the phosphotransferase system. J. Bacteriol. 172:1043-1050[Abstract/Free Full Text].
5.	Débarbouillé, M., M. Arnaud, A. Fouet, A. Klier, and G. Rapoport. 1990. The sacT gene regulating the sacPA operon in Bacillus subtilis shares strong homology with transcriptional antiterminators. J. Bacteriol. 172:3966-3973[Abstract/Free Full Text].
6.	Deutscher, J., E. Küster, U. Bergstedt, V. Charrier, and W. Hillen. 1995. Protein kinase-dependent HPr/CcpA interaction links glycolytic activity to carbon catabolite repression in Gram-positive bacteria. Mol. Microbiol. 15:1049-1053[Medline].
7.	Deutscher, J., B. Pevec, K. Beyreuther, H.-H. Kiltz, and W. Hengstenberg. 1986. Streptococcal phosphoenolpyruvate-sugar phosphotransferase system: amino acid sequence and site of ATP-dependent phosphorylation of HPr. Biochemistry 25:6543-6551[Medline].
8.	Deutscher, J., J. Reizer, C. Fischer, A. Galinier, M. H. Saier, and M. Steinmetz. 1994. Loss of protein kinase-catalyzed phosphorylation of HPr, a phosphocarrier protein of the phosphotransferase system, by mutation of ptsH gene confers catabolite repression resistance to several catabolic genes of Bacillus subtilis. J. Bacteriol. 176:3336-3344[Abstract/Free Full Text].
9.	Deutscher, J., and M. H. Saier. 1983. ATP-dependent, protein kinase-catalyzed phosphorylation of a seryl residue in HPr, a phosphoryl carrier protein of the phosphotransferase system in Streptococcus pyogenes. Proc. Natl. Acad. Sci. USA 80:6790-6794[Abstract/Free Full Text].
10.	Faires, N., S. Tobisch, S. Bachem, I. Martin-Verstraete, M. Hecker, and J. Stülke. 1999. The catabolite control protein CcpA controls ammonium assimilation in Bacillus subtilis. J. Mol. Microbiol. Biotechnol. 1:141-148. [Medline]
11.	Galinier, A., M. Kravanja, R. Engelmann, W. Hengstenberg, M. C. Kilhoffer, J. Deutscher, and J. Haiech. 1998. New protein kinase and protein phosphatase families mediate signal transduction in bacterial catabolite repression. Proc. Natl. Acad. Sci. USA 95:1823-1828[Abstract/Free Full Text].
12.	Gunnewijk, M. G. W., P. W. Postma, and B. Poolman. 1999. Phosphorylation and functional properties of the IIA domain of the lactose transport protein of Streptococcus thermophilus. J. Bacteriol. 181:632-641[Abstract/Free Full Text].
13.	Henkin, T. M., F. J. Grundy, W. L. Nicholson, and G. H. Chambliss. 1991. Catabolite repression of alpha-amylase gene expression in Bacillus subtilis involves a trans-acting gene product homologous to the Escherichia coli lacI and galR repressors. Mol. Microbiol. 5:575-584[Medline].
14.	Hueck, C. J., and W. Hillen. 1995. Catabolite repression in Bacillus subtilis: a global regulatory mechanism for Gram-positive bacteria? Mol. Microbiol. 15:395-401[Medline].
15.	Hueck, C. J., W. Hillen, and M. H. Saier. 1994. Analysis of a cis-active sequence mediating catabolite repression in Gram-positive bacteria. Res. Microbiol. 145:503-518[Medline].
16.	Kraus, A., C. Hueck, D. Gärtner, and W. Hillen. 1994. Catabolite repression of the Bacillus subtilis xyl operon involves a cis element functional in the context of an unrelated sequence, and glucose exerts additional xylR-dependent repression. J. Bacteriol. 176:1738-1745[Abstract/Free Full Text].
17.	Krüger, S., S. Gertz, and M. Hecker. 1996. Transcriptional analysis of the bglPH expression in Bacillus subtilis: evidence for two distinct pathways mediating carbon catabolite repression. J. Bacteriol. 178:2637-2644[Abstract/Free Full Text].
18.	Krüger, S., and M. Hecker. 1995. Regulation of the putative bglPH operon for aryl- $beta$ -glucoside utilization in Bacillus subtilis. J. Bacteriol. 177:5590-5597[Abstract/Free Full Text].
19.	Krüger, S., J. Stülke, and M. Hecker. 1993. Catabolite repression of $beta$ -glucanase synthesis in Bacillus subtilis. J. Gen. Microbiol. 139:2047-2054[Medline].
20.	Kunst, F., N. Ogasawara, I. Moszer, A. M. Albertini, G. Alloni, V. Azevedo, M. G. Bertero, P. Bessieres, A. Bolotin, S. Borchert, R. Borriss, L. Boursier, A. Brans, M. Braun, S. C. Brignell, S. Bron, S. Brouillet, C. V. Bruschi, B. Caldwell, V. Capuano, N. M. Carter, S. K. Choi, J. J. Codani, I. F. Connerton, A. Danchin, et al. 1997. The complete genome sequence of the Gram-positive bacterium Bacillus subtilis. Nature 390:249-256[Medline].
21.	Kunst, F., and G. Rapoport. 1995. Salt stress is an environmental signal affecting degradative enzyme synthesis in Bacillus subtilis. J. Bacteriol. 177:2403-2407[Abstract/Free Full Text].
22.	Landt, O., H.-P. Grunert, and U. Hahn. 1990. A general method for rapid site-directed mutagenesis using the polymerase chain reaction. Gene 96:125-128[Medline].
23.	Le Coq, D., C. Lindner, S. Krüger, M. Steinmetz, and J. Stülke. 1995. New $beta$ -glucoside (bgl) genes in Bacillus subtilis: the bglP gene product has both transport and regulatory functions, similar to those of BglF, its Escherichia coli homolog. J. Bacteriol. 177:1527-1535[Abstract/Free Full Text].
24.	Lereclus, D., and O. Arantes. 1992. spbA locus ensures the segregational stability of pTH1030, a novel type of Gram-positive replicon. Mol. Microbiol. 6:35-46[Medline].
25.	Lindner, C., A. Galinier, M. Hecker, and J. Deutscher. 1999. Regulation of the activity of the Bacillus subtilis antiterminator LicT by PEP-dependent, enzyme I- and HPr-catalyzed phosphorylation. Mol. Microbiol. 3:995-1006.
26.	Maede, H. M., S. R. Long, G. B. Ruvkun, S. E. Brown, and F. M. Ausubel. 1982. Physical and genetic characterization of symbiotic and auxotrophic mutants of Rhizobium meliloti induced by transposon Tn5 mutagenesis. J. Bacteriol. 149:114-122[Abstract/Free Full Text].
27.	Martin-Verstraete, I., V. Charrier, J. Stülke, A. Galinier, B. Erni, G. Rapoport, and J. Deutscher. 1998. Antagonistic effects of dual PTS-catalyzed phosphorylation on the Bacillus subtilis transcriptional activator LevR. Mol. Microbiol. 28:293-303[Medline].
28.	Martin-Verstraete, I., M. Débarbouillé, A. Klier, and G. Rapoport. 1990. Levanase operon of Bacillus subtilis includes a fructose-specific phosphotransferase system regulating the expression of the operon. J. Mol. Biol. 214:657-671[Medline].
29.	Martin-Verstraete, I., M. Débarbouillé, A. Klier, and G. Rapoport. 1992. Mutagenesis of the Bacillus subtilis ' $-$ 12, $-$ 24' promoter of the levanase operon and evidence for the existence of an upstream activating sequence. J. Mol. Biol. 226:85-99[Medline].
30.	Martin-Verstraete, I., J. Stülke, A. Klier, and G. Rapoport. 1995. Two different mechanisms mediate catabolite repression of the Bacillus subtilis levanase operon. J. Bacteriol. 177:6919-6927[Abstract/Free Full Text].
31.	Miller, J. 1972. Experiments in molecular genetics. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
32.	Moszer, I., P. Glaser, and A. Danchin. 1995. SubtiList: a relational database for the Bacillus subtilis genome. Microbiology 141:261-268[Abstract].
33.	Postma, P. W., J. W. Lengeler, and G. R. Jacobson. 1993. Phosphoenolpyruvate:carbohydrate phosphotransferase systems of bacteria. Microbiol. Rev. 57:543-594[Abstract/Free Full Text].
34.	Reiche, B., R. Frank, J. Deutscher, N. Meyer, and W. Hengstenberg. 1988. Staphylococcal phosphoenolpyruvate-dependent phosphotransferase system: purification and characterization of the mannitol-specific enzyme III^mtl of Staphylococcus aureus and Staphylococcus carnosus and homology with the enzyme III^mtl of Escherichia coli. Biochemistry 27:6512-6516[Medline].
35.	Reizer, J., C. Hoischen, F. Titgemeyer, C. Rivolta, R. Rabus, J. Stülke, D. Karamata, M. H. Saier, and W. Hillen. 1998. A novel protein kinase that controls carbon catabolite repression in bacteria. Mol. Microbiol. 27:1157-1169[Medline].
36.	Saier, M. H. 1989. Protein phosphorylation and allosteric control of inducer exclusion and catabolite repression by the bacterial phosphoenolpyruvate:sugar phosphotransferase system. Microbiol. Rev. 53:109-120[Abstract/Free Full Text].
37.	Saier, M. H., and J. Reizer. 1992. Proposed uniform nomenclature for the proteins and the protein domains of the bacterial phosphoenolpyruvate:sugar phosphotransferase system. J. Bacteriol. 174:1433-1438[Free Full Text].
38.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
39.	Sanger, F., S. Nicklen, and A. R. Coulson. 1977. DNA sequencing with chain-terminating inhibitors. Proc. Natl. Acad. Sci. USA 74:5463-5467[Abstract/Free Full Text].
40.	Schnetz, K., J. Stülke, S. Gertz, S. Krüger, M. Krieg, M. Hecker, and B. Rak. 1996. LicT, a Bacillus subtilis transcriptional antiterminator protein of the BglG family. J. Bacteriol. 178:1971-1979[Abstract/Free Full Text].
41.	Steinmetz, M. 1993. Carbohydrate catabolism: pathways, enzymes, genetic regulation, and evolution, p. 157-170. In A. L. Sonenshein, J. A. Hoch, and R. Losick (ed.), Bacillus subtilis and other gram-positive bacteria: biochemistry, physiology, and molecular genetics. American Society for Microbiology, Washington, D.C.
42.	Stülke, J., M. Arnaud, G. Rapoport, and I. Martin-Verstraete. 1998. PRD $---$ a protein domain involved in PTS-dependent induction and carbon catabolite repression of catabolic operons in bacteria. Mol. Microbiol. 28:865-874[Medline].
43.	Stülke, J., R. Hanschke, and M. Hecker. 1993. Temporal activation of $beta$ -glucanase synthesis in Bacillus subtilis is mediated by the GTP pool. J. Gen. Microbiol. 139:2041-2045[Medline].
44.	Stülke, J., I. Martin-Verstraete, V. Charrier, A. Klier, J. Deutscher, and G. Rapoport. 1995. The HPr protein of the phosphotransferase system links induction and catabolite repression of the Bacillus subtilis levanase operon. J. Bacteriol. 177:6928-6936[Abstract/Free Full Text].
45.	Stülke, J., I. Martin-Verstraete, M. Zagorec, M. Rose, A. Klier, and G. Rapoport. 1997. Induction of the Bacillus subtilis ptsGHI operon by glucose is controlled by a novel antiterminator, GlcT. Mol. Microbiol. 25:65-78[Medline].
45a.	Tobisch, S. Unpublished results.
46.	Tobisch, S., P. Glaser, S. Krüger, and M. Hecker. 1997. Identification and characterization of a new $beta$ -glucoside utilization system in Bacillus subtilis. J. Bacteriol. 179:496-506[Abstract/Free Full Text].
47.	Tortosa, P., S. Aymerich, C. Lindner, M. H. Saier, J. Reizer, and D. Le Coq. 1997. Multiple phosphorylation of SacY, a Bacillus subtilis antiterminator negatively controlled by the phosphotransferase system. J. Biol. Chem. 272:17230-17237[Abstract/Free Full Text].