Regulatory Functions of Serine-46-Phosphorylated HPr in Lactococcus lactis

doi:10.1128/JB.183.11.3391-3398.2001

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Journal of Bacteriology, June 2001, p. 3391-3398, Vol. 183, No. 11
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.11.3391-3398.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Regulatory Functions of Serine-46-Phosphorylated HPr in Lactococcus lactis

Vicente Monedero,¹^, Oscar P. Kuipers,²^, Emmanuel Jamet,³ and Josef Deutscher¹^,^*

Laboratoire de Génétique des Microorganismes, INRA-CNRS URA 1925, 78850 Thiverval-Grignon,¹ and Génétique Microbienne, INRA, 78352 Jouy en Josas, France,³ and NIZO Food Research, 6710 BA Ede, The Netherlands²

Received 18 December 2000/Accepted 19 March 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

In most low-G+C gram-positive bacteria, the phosphoryl carrier protein HPr of the phosphoenolpyruvate:sugar phosphotransferasesystem (PTS) becomes phosphorylated at Ser-46. This ATP-dependentreaction is catalyzed by the bifunctional HPr kinase/P-Ser-HPrphosphatase. We found that serine-phosphorylated HPr (P-Ser-HPr)of Lactococcus lactis participates not only in carbon cataboliterepression of an operon encoding a $beta$ -glucoside-specific EII anda 6-P- $beta$ -glucosidase but also in inducer exclusion of the non-PTScarbohydrates maltose and ribose. In a wild-type strain, transportof these non-PTS carbohydrates is strongly inhibited by the presenceof glucose, whereas in a ptsH1 mutant, in which Ser-46 of HPris replaced with an alanine, glucose had lost its inhibitory effect.In vitro experiments carried out with L. lactis vesicles had suggestedthat P-Ser-HPr is also implicated in inducer expulsion of nonmetabolizablehomologues of PTS sugars, such as methyl $beta$ -D-thiogalactoside (TMG)and 2-deoxy-D-glucose (2-DG). In vivo experiments with the ptsH1mutant established that P-Ser-HPr is not necessary for inducerexpulsion. Glucose-activated 2-DG expulsion occurred at similarrates in wild-type and ptsH1 mutant strains, whereas TMG expulsionwas slowed in the ptsH1 mutant. It therefore seems that P-Ser-HPris not essential for inducer expulsion but that in certain casesit can play an indirect role in this regulatoryprocess.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

HPr is one of the four proteins (or domains) forming the phosphorylation cascade of the phosphoenolpyruvate (PEP):sugar phosphotransferasesystem (PTS), which in gram-positive and gram-negative bacteriacatalyzes the uptake and phosphorylation of numerous carbohydrates(for a review, see reference 28). During PTS-mediated carbohydrateuptake and phosphorylation, HPr becomes phosphorylated by PEPand enzyme I at the N $delta$ 1 position of His-15. P-His-HPr transfersits phosphoryl group to one of several sugar-specific EIIAs usuallypresent in bacterial cells. P~EIIAs donate their phosphoryl groupto the corresponding EIIB, from where the phosphoryl group isfinally transferred to the carbohydrate bound to the membrane-integratedEIIC. After phosphorylation by P~EIIB, the phosphorylated sugaris released into the cytoplasm. In enzyme I and EIIAs, the phosphorylgroup is attached to the N $varepsilon$ 2 position of a histidyl residue, whereasin EIIBs the phosphoryl group can be bound either to the N $delta$ 1 positionof a histidyl residue or to a cysteyl residue (28).

In gram-positive bacteria, HPr functions not only as a phosphoryl carrier within the PTS phosphorylation cascade but alsoas the central regulator of carbohydrate metabolism. For example,P~His-HPr phosphorylates not only EIIAs but also histidyl residuesin non-PTS proteins such as glycerol kinase (6), antiterminators,transcriptional activators (32), and non-PTS transporters (containingan EIIA^Glc domain) (17). In most cases, P~His-HPr-mediated phosphorylationof non-PTS proteins leads to a stimulation of their activity.In addition, HPr of gram-positive bacteria is also phosphorylatedat the regulatory serine-46 (9, 11). This reaction requiresATP and is catalyzed by the metabolite-controlled bifunctionalHPr kinase/P-Ser-HPr phosphatase (5, 12, 14, 19, 21,29). The resulting P-Ser-HPr functions as a corepressor in carboncatabolite repression (CCR) or as a coactivator in carbon cataboliteactivation (CCA) by interacting with catabolite control proteinA (CcpA) (8, 20), a member of the LacI/GalR repressor family(18). The P-Ser-HPr/CcpA complex binds to specific operatorsites (13) called catabolite response elements (cre) (39).The cre's of catabolite-activated genes or operons are locatedin front of the promoter. By contrast, in the case of catabolite-repressedgenes and operons, the cre's either overlap the promoter or arelocated downstream of it (for reviews see references 7 and33).

Based on in vitro results, P-Ser-HPr has been suggested to participate also in inducer exclusion in Lactobacillus brevis (44,47). This concept was further supported by in vivo experimentswith a Streptococcus salivarius Ile47Thr ptsH mutant (16), whichhad lost the preferential uptake and metabolism of glucose overlactose. The participation of P-Ser-HPr in inducer exclusion hasbeen established by in vivo experiments with Lactobacillus caseiptsH1 and hprK mutants, which are not able to form P-Ser-HPr.Maltose uptake, which was completely inhibited by glucose in awild-type strain, was not affected by glucose in the ptsH1 (37)and hprK mutants (12).

In vitro results had suggested that P-Ser-HPr would also participate in inducer expulsion in Lactococcus lactis (42, 43).Addition of glucose to cells which had accumulated the nonmetabolizablemethyl $beta$ -D-thiogalactoside (TMG) or 2-deoxy-D-glucose (2-DG) causedrapid expulsion of the nonmetabolizable sugar analogues from L.lactis wild-type cells (35) or vesicles (43). Both sugar analoguesare taken up by the PTS and are therefore accumulated as 6-P derivatives.In the first step of inducer expulsion, an intracellular sugar-Pphosphohydrolase dephosphorylates the accumulated P-sugars beforethe unphosphorylated sugars are expelled from the cells in thesecond step (30). In several gram-positive bacteria, includingL. lactis, a sugar-P phosphohydrolase has been described whichwas activated by P-Ser-HPr (41, 45) and which was thoughtto catalyze the first step of inducer expulsion. In addition,electroporation of Bacillus subtilis Ser46Asp mutant HPr, whichstructurally resembles P-Ser-HPr (40), into L. lactis vesicleswas reported to lead to stronger inducer expulsion than electroporationof Ser46Ala mutant HPr (42). It was therefore concluded thatP-Ser-HPr would participate in inducer expulsion. However, recentin vivo experiments with L. casei ptsH1 and hprK mutants had establishedthat in this organism inducer expulsion does not require P-Ser-HPr.Following the addition of glucose, ptsH1 and hprK mutants, whichare not able to form P-Ser-HPr, expelled preaccumulated TMG ata rate similar to that observed with an L. casei wild-type strain(12, 37).

We here report the construction of an L. lactis ptsH1 mutant strain synthesizing Ser46Ala mutant HPr with the aim to testwhether P-Ser-HPr-dependent inducer exclusion is a widespreadphenomenon in gram-positive bacteria and is present also in L.lactis. In addition, we carried out in vivo expulsion experimentswith TMG and 2-DG in order to test whether P-Ser-HPr participatesin this regulatory process, as has been proposed based on thereported stimulation of a sugar-P phosphohydrolase by P-Ser-HPr(45) and on in vitro expulsion experiments carried out withL. lactis vesicles, into which purified B. subtilis wild-typeand mutant HPrs had been electroporated (42, 43).

	MATERIALS AND METHODS

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Strains, culture conditions, and transformation procedures. L. lactis MG5267, an MG1363 derivative (15) carrying the lactose operon integrated in the chromosome (36), was used inthis study. MG5267 and its derivatives were grown at 30°C understatic conditions in M17 medium supplemented with either 0.5 or0.8% of the indicated carbohydrates. Escherichia coli NM522 (Stratagene)was used as a host for the cloning experiments. It was grown inLuria-Bertani medium at 37°C under agitation. The antibioticschloramphenicol and erythromycin were used at a concentrationof 5 µg/ml for L. lactis. For E. coli, chloramphenicol was usedat 10 µg/ml and ampicillin was used at 100 µg/ml. Solid mediawere prepared by adding 1.5% agar to the liquid media. For $alpha$ -complementationin E. coli, 5-bromo-4-chloro-3-indolyl- $beta$ -D-galactopyranoside wasused at a concentration of 20 µg/ml. For the electroporation experimentswith L. lactis cells, strains were grown in M17 medium supplementedwith 0.5% glucose, 0.5 M sucrose, and 1% glycine to an opticaldensity at 600 nm (OD₆₀₀) of 0.5. The cells were subsequentlywashed twice with cold 0.5 M sucrose containing 10% glycerol andfinally resuspended in this solution (1% of initial volume). A50-µl aliquot was electroporated at 2.5 kV, 200 $Omega$ , and 25 µF incuvettes with a 0.2-cm distance between the electrodes (Bio-RadGene-Pulser). Five milliliters of M17 medium containing 0.5% glucose,0.5 M sucrose, 20 mM MgCl₂, and 2 mM CaCl₂ was rapidly added tothe electroporated cells, which were subsequently incubated for2 h at 30°C before aliquots were plated on selectivemedia.

Construction of plasmids and strains. Chromosomal DNA from L. lactis MG5267 was isolated as previously described (24) and was used to amplify by PCR a 3-kb DNAfragment containing the complete ptsHI operon and its upstreamsequence. The PCR was carried out with Pfu DNA polymerase (Promega)and oligonucleotides PTS3 (5'-GACCTGCAGTACAAAGTTATC-3') and PTS4(5'-TAAGGATCCTATTATAGCTAAACAG-3') as primers. The resulting 3-kbDNA fragment was digested with BamHI (restriction site indicatedin italics in PTS4) and cloned into SmaI-BamHI-digested pNEB193(New England Biolabs). In order to replace serine 46 in HPr withan alanine, the obtained plasmid pTSHI was used as a templatein a PCR amplification together with the two divergent primersS46A (5'-CCTTAAAGCAATCATGGGTGT-3') and S46A2 (5'-TTTACTGATTTACCTTTGTAT-3').The altered codon 46 leading to the Ser46Ala replacement in ptsH(TCA to GCA) is underlined in the sequence of primer S46A. Theresulting PCR product was phosphorylated with T4 polynucleotidekinase, ligated, and used to transform E. coli NM522. The presenceof the ptsH1 mutation (Ser46Ala replacement) and the absence ofother mutations were verified by sequencing the insert of plasmidsisolated from several clones using a Perkin-Elmer Abiprism 373automated sequencer. One plasmid, called pTS46A, carried the correctmutant ptsH1 allele and wild-type ptsI and was used for furtherexperiments. Plasmid pTS46A was digested with KpnI and made bluntended with Klenow DNA polymerase. After digestion with BamHI,the 3-kb fragment obtained was cloned into the thermosensitivepGhostCm vector (2) digested with EcoRV and BamHI, thus providingpGhostS46A.

Strain LlG100 (ptsH::erm) was constructed by transforming L. lactis MG5267 with pNZ9290 (26) and selecting for erythromycin-resistantclones (Fig. 1). Strains carrying the plasmid inserted by a doublecrossover, which leads to the inactivation of ptsH, were identifiedby their inability to grow on PTS sugars, and in one such strain,LlG100, the insertion of the erythromycin resistance cassetteinto ptsH was confirmed by PCR amplification with appropriateprimers.

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FIG. 1. Construction of an L. lactis strain expressing Ser46Ala mutant HPr. The wild-type strain MG5267 was transformed with plasmid pNZ9290 (26), which contains the 5' part of the L. lactis ptsl gene and several hundred base pairs of the upstream region of the ptsHI operon. The ptsH gene located in front of ptsI is partly deleted and the deleted region is replaced with an erythromycin resistance cassette. After a double-crossover recombination, a ptsH::erm strain (LlG100) was obtained. This strain exhibited a pts-negative phenotype and was transformed with the thermosensitive plasmid pGhostS46A, which carries the ptsH1 allele (the position of the Ser46Ala mutation is indicated with a triangle). After two successive recombination events, a pts⁺ strain carrying the ptsH1 allele (LlG101) was obtained.

For the construction of the chromosomal ptsH1 mutant LlG101, LlG100 was transformed with pGhostS46A (Fig. 1). One chloramphenicol-resistanttransformant was grown overnight at 38°C in the absence of antibioticsand subsequently plated on chloramphenicol-containing solid M17medium and incubated at 38°C. Since pGhost is not replicated at38°C, this procedure forced the integration of pGhostS46A intothe chromosome of LlG100 by homologous recombination. One strainresistant to chloramphenicol and erythromycin during growth at38°C was subsequently grown for several generations at 30°C inthe absence of antibiotics and then plated on M17 medium, incubatedat 30°C, and replica plated on M17 medium containing chloramphenicoland erythromycin. LlG101 was selected as a chloramphenicol- anderythromycin-sensitive strain in which the disrupted ptsH genewas replaced with the ptsH1 mutant allele by a second crossoverevent. The presence of this mutation in LlG101 was confirmed bysequencing appropriate PCRproducts.

Western blotting. L. lactis strains were grown in 25 ml of glucose-containing M17 medium to an OD₆₀₀ between 0.6 and 0.7 before the pH of theculture was rapidly lowered to 4.5 by adding concentrated HCl.After centrifugation at 4°C, the cell pellets were resuspendedin 1 ml of 20 mM sodium acetate, pH 4.5, and cells were brokenin a Fast-prep apparatus (Biospec) using 0.1-mm glass beads andthree cycles of 30 s at maximum speed. The low pH and temperaturewere used to minimize changes in the HPr phosphorylation statepotentially caused by enzyme I and HPr kinase/P-Ser-HPr phosphatasepresent in the extracts. The cell lysates were clarified by centrifugation,and proteins were separated on a 15% nondenaturing polyacrylamidegel. After electrophoretic transfer of the proteins onto nitrocellulosemembranes, the blots were probed with rabbit polyclonal antibodiesraised against B. subtilis HPr and developed by using anti-rabbitimmunoglobulin G conjugated with alkaline phosphatase (Promega)as a secondantibody.

$beta$ -Glucoside transport and 6-P- $beta$ -glucosidase assays. Strains MG5267 and LlG101 were grown in 20 ml of M17 medium supplemented with either 0.8% salicin or 0.8% salicin plus 0.8%glucose to an OD₆₀₀ between 0.4 and 0.5. Cells grown in mediumcontaining only salicin exhibited an about 1.8-fold slower growthrate than cells grown on salicin plus glucose. The cells werewashed twice with 50 mM Tris-HCl buffer, pH 7.4, and resuspendedin 200 µl of the same buffer. 6-P- $beta$ -Glucosidase activities weredetermined in 50-µl assay mixtures containing 50 mM Tris-HCl,pH 7.4, 40 µl of the cell suspension, 5 mM p-nitrophenyl- $beta$ -D-glucopyranoside,and 5 mM MgCl₂. The assay mixtures were incubated for 30 min at30°C before the reaction was stopped by adding 800 µl of 10% sodiumcarbonate. After centrifugation, the OD₄₀₅ was measured in thesamples. Control experiments carried out with salicin-grown wild-typecells confirmed that there was a linear correlation between themeasured OD₄₀₅ and either the incubation time or the amount ofcells used for the assay. Enzyme activities are expressed in nanomolesof p-nitrophenol formed per minute per milliliter of cell cultureexhibiting an OD₆₀₀ of 0.5. To determine whether glucose exertsan exclusion effect on p-nitrophenyl- $beta$ -D-glucopyranoside uptake,the above-described assay was carried out with salicin-grown wild-typeand ptsH1 mutant cells in the presence of 10 mMglucose.

Sugar transport, inducer exclusion, and inducer expulsion. Sugar transport studies and inducer exclusion experiments in the presence of 10 mM glucose were performed using the rapid-filtrationmethod (37). Cells used for transport studies were grown inM17 medium containing different carbohydrates (at a concentrationof 0.5%). Glucose-promoted expulsion experiments with cells whichhad accumulated the lactose analogue TMG or the glucose analogue2-DG were carried out as previously described (12). ¹⁴C-radiolabeled sugars were purchased from Isotopchim (Ganagobie-Peyrus,France) and used at a final concentration of 1 mM (at a specificradioactivity of 0.5 mCi/mmol).

Thin-layer chromatography was used to separate phosphorylated and nonphosphorylated [¹⁴C]TMG. After cells had taken up [¹⁴C]TMG, they were washed twice with 1 ml of transport buffer before10 mM glucose was added to one-half of the suspension (500 µl)and expulsion was allowed to proceed for 5 min. Subsequently,cells were kept for 10 min at 100°C and clarified by centrifugation,and 10-µl aliquots were separated by thin-layer chromatographyon Silica Gel 60 plates (Merck) using a mixture of 1 M ammoniumacetate, pH 5, 98% ethanol, and 0.1 M EDTA, pH 8 (70:29:1), asthe solvent. The approximate amounts of TMG and TMG-6-P were determinedby autoradiography (4 days of exposure with a Biomax MR film [Kodak]).The migration position of TMG was determined with untreated [¹⁴C]TMG.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Construction of an L. lactis ptsH1 mutant strain. To study the role of P-Ser-HPr in the regulation of carbon metabolism in L. lactis, we constructed a ptsH1 mutant strain inwhich the phosphorylatable Ser-46 of HPr was replaced with analanine. The L. lactis ptsHI operon encoding enzyme I and HProf the PTS has recently been cloned and characterized (26).After insertion of an erythromycin resistance gene at the 3' endof the ptsH gene of strain MG5267, the antibiotic resistance cassetteand the wild-type ptsH were replaced with the Ser46Ala ptsH allele(ptsH1) present on the integrative plasmid pGhostS46A as describedin Materials and Methods (Fig. 1). The expected absence of P-Ser-HPrin the resulting ptsH1 mutant strain LlG101 was confirmed by Westernblotting. Polyacrylamide gel electrophoresis was performed undernondenaturing conditions with crude extracts prepared from theL. lactis wild-type and the ptsH1 mutant strains grown in glucose-containingM17 medium. This allowed us to separate HPr, P~His-HPr/P-Ser-HPr,and doubly phosphorylated HPr and to get an estimate of theirratios in the cell. The approximate amounts of the different formsof HPr were detected with polyclonal antibodies directed againstB. subtilis HPr. Heating an aliquot of the crude extract to 65°Callowed us to distinguish between P~His-HPr and P-Ser-HPr, whichmigrate to nearly identical positions. P~His-HPr is rapidly hydrolyzedat 65°C (38), whereas P-Ser-HPr is stable under these conditions.According to the results presented in lanes 1 and 2 of Fig. 2,glucose-grown L. lactis wild-type cells were estimated to containa considerable amount of P-Ser-HPr and somewhat less HPr and P~His-HPr,whereas only a small amount of doubly phosphorylated HPr was present.By contrast, glucose-grown ptsH1 mutant cells contained neitherP-Ser-HPr nor doubly phosphorylated HPr and the major part ofHPr was present as P~His-HPr (Fig. 2, lanes 3 and 4).

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FIG. 2. Western blot with L. lactis crude extracts prepared from glucose-grown wild-type and ptsH1 mutant strains and separated on a nondenaturing polyacrylamide gel. The various forms of HPr were detected with antibodies raised against B. subtilis HPr. Crude extracts from L. lactis wild-type MG5267 (lanes 1 and 2) and L. lactis ptsH1 mutant LlG101 (lanes 3 and 4) are shown. Extracts separated in lanes 2 and 4 were heated for 10 min at 65°C before they were loaded onto the gel.

Glucose transport in L. lactis wild-type and ptsH1 mutant strains and glucose-mediated exclusion of PTS sugars. Since the main function of HPr is to act as phosphocarrier protein during PTS-catalyzed sugar transport and phosphorylation,we tested whether the ptsH1 mutation would influence PTS-catalyzedsugar uptake. Glucose transport activities were found to be verysimilar for the wild-type and the ptsH1 mutant strains (Fig. 3).By contrast, the ptsH disruption strain LlG100 had completelylost the capacity to transport glucose at the concentration usedin the transport assay (1 mM). However, strain LlG100 was ableto slowly grow in M17 medium containing 25 mM glucose, indicatingthe presence of a non-PTS transporter capable of transportingglucose with low affinity. Slow growth of an L. lactis ptsH strainon glucose has also been reported by Luesink et al. (26). InL. lactis MG5267, TMG is taken up by a lactose-specific chromosome-encodedPTS and accumulated as TMG-6-P (see Fig. 6). Compared to the wild-typestrain, PTS-catalyzed TMG uptake by the ptsH1 mutant was slightlyslower (Fig. 4A). In addition, the inhibition exerted by glucoseon TMG uptake in the wild-type strain (sevenfold) was much weakerin the ptsH1 mutant (only about twofold).

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FIG. 3. Transport of [¹⁴C]glucose (1 mM) by the L. lactis wild-type strain MG5267 (filled squares), the ptsH::erm disruption strain LlG100 (filled rhombs), and the ptsH1 mutant LlG101 (open circles). Cells were grown in M17 medium containing 0.5% glucose.

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FIG. 4. Transport of ¹⁴C-labeled TMG and mannitol and their exclusion by glucose in the L. lactis MG5267 (wild-type [wt]) and LlG101 (ptsH1 mutant) strains. (A) TMG transport with cells grown in M17 medium containing 0.5% lactose; (B) mannitol transport with cells grown in M17 medium containing 0.5% mannitol. Transport assays were carried out in the absence of glucose (squares) or with 10 mM glucose added 1 min prior to adding the radiolabeled sugar (circles). In panel B, the error bars for the experiments carried out in the presence of glucose were too small to be drawn by the program.

The inability of strain LlG100 to grow on mannitol suggested that this sugar might also be transported by the PTS. This assumptionwas supported by the finding that the genome of L. lactis IL1403contains an operon (mtlARFD) encoding proteins with high sequencesimilarity to EIICB^Mtl, MtlR, EIIA^Mtl, and mannitol-1-P dehydrogenase from other organisms (3, 4)(see also http://www.ncbi.nlm.nih.gov/cgi-bin/Entrez/framik?db=Genome&gi=171).Compared to the wild-type strain, mannitol uptake via the PTSwas almost twofold greater in the ptsH1 mutant. Interestingly,the presence of glucose completely inhibited mannitol uptake inthe wild-type strain. Glucose inhibition of mannitol transportwas only slightly relieved in the ptsH1 mutant strain (Fig. 4B).

CCR of aryl- $beta$ -D-glucoside metabolism. L. lactis strain IL1403 was found to be capable of growing on aryl- $beta$ -D-glucosides such as esculin, salicin, and arbutin (1).Similarly, the wild-type strain MG5267 was able to grow on salicin,whereas the ptsH::erm strain LlG100 had lost this capacity, confirmingthat in L. Lactis aryl- $beta$ -D-glucosides are transported and phosphorylatedby a PTS before they are split by a 6-P- $beta$ -D-glucosidase into glucose-6-Pand the aglycon. The EII necessary for aryl- $beta$ -D-glucoside transportby MG5267 cells is probably encoded by the homologue of the ptbAgene located at kb 1482 of the L. lactis IL1403 chromosome (3,4). This EIIBCA exhibits strong similarity to the EIIBCA^Bgl (BglP) of B. subtilis (23). p-Nitrophenyl- $beta$ -D-glucopyranosidewas found to be a substrate for the PtbA of L. lactis, since itwas taken up by salicin-grown MG5267 cells and subsequently splitinto glucose-6-P and p-nitrophenol. These activities were repressedsixfold in cells grown in the presence of salicin and glucose(Table 1). The repressive effect of glucose had disappeared inthe ptsH1 mutant strain. p-Nitrophenyl- $beta$ -D-glucopyranoside transportand hydrolysis experiments carried out in the presence of glucosewith salicin-grown wild-type and ptsH1 mutant cells showed thatglucose exerts no inducer exclusion effect on p-nitrophenyl- $beta$ -D-glucopyranosideuptake. The presence of glucose in the assay mixtures even stimulatedp-nitrophenyl- $beta$ -D-glucopyranoside uptake and its subsequent hydrolysisabout 1.5-fold in both wild-type and ptsH1 mutant strains (Table1).

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TABLE 1. CCR of 6-P- $beta$ -glucosidase

The ptsH1 mutation prevents inducer exclusion of non-PTS sugars maltose and ribose. In L. lactis, maltose and ribose are probably taken up by ATP-binding cassette (ABC) transport systems (MalE, MalF, and MalG;and RbsA, RbsC, and RbsD, respectively) (3, 4). For unknownreasons, the ptsH disruption strain LlG100 was unable to growon ribose, although it grew normally on maltose. In the wild-typestrain, the uptake of both carbohydrates was strongly inhibitedwhen glucose was present during the transport reaction (Fig. 5Aand B), suggesting that an inducer exclusion mechanism was operative.Interestingly, the inhibitory effect of glucose on the uptakeof non-PTS carbohydrates ribose and maltose had disappeared inthe ptsH1 mutant LlG101 (Fig. 5A and B), although it transportedglucose at a rate identical to that observed with the wild-typestrain (Fig. 3).

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FIG. 5. Transport of the ¹⁴C-labeled non-PTS sugars ribose (A) and maltose (B) and their exclusion by 10 mM glucose in L. lactis MG5267 (wild-type) and LlG101 (ptsH1 mutant) strains. Transport assays were carried out in the absence of glucose (squares) or with 10 mM glucose added 1 min prior to adding the radiolabeled sugar (circles). Cells were grown in M17 medium containing 0.5% ribose (A) or 0.5% maltose (B).

P-Ser-HPr is not essential for inducer expulsion in L. lactis. In vitro results obtained with L. lactis vesicles had suggested that P-Ser-HPr participates in inducer expulsion by stimulatingthe activity of a sugar-P phosphohydrolase catalyzing the firststep of inducer expulsion (42, 43). To test whether P-Ser-HPris indeed implicated in this regulatory process, we measured TMGexpulsion in an L. lactis wild-type strain and a ptsH1 mutantstrain. L. lactis strain MG5267 takes up [¹⁴C]TMG via the lactose-specific PTS and accumulates it as [¹⁴C]TMG-6-P, which cannot be further metabolized (Fig. 6, lane 1).When glucose was added to MG5267 cells preloaded with [¹⁴C]TMG-6-P, the nonmetabolizable sugar was rapidly expelled fromthe cells (Fig. 7A). In the first step, the presence of glucosehas been shown to initiate the intracellular dephosphorylationof TMG-6-P (30) before TMG is expelled from the cells in thesecond step, probably via EIICB^Lac (31). In agreement with this model, only TMG and no TMG-6-Pwas found to be expelled from MG5267 cells preloaded with [¹⁴C]TMG-6-P (Fig. 6, lane 2). The ptsH1 mutant was also capableof accumulating [¹⁴C]TMG-6-P (Fig. 6, lane 3). However, expulsion of [¹⁴C]TMG occurred at a significantly slower rate and was not yetcompleted after 5 min (Fig. 7A). Similar to what was observedwith the wild-type strain, [¹⁴C]TMG-6-P was dephosphorylated during the expulsion process (Fig.6, lane 4). After 5 min of incubation in the presence of glucose,about two-thirds of the accumulated [¹⁴C]TMG-6-P was expelled from the ptsH1 mutant and dephosphorylated,whereas one-third remained in the cell as [¹⁴C]TMG-6-P (Fig. 7A).

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FIG. 6. Autoradiogram showing the amounts of [¹⁴C]TMG and [¹⁴C]TMG-6-P present in L. lactis cells and in the medium before and after inducer expulsion. [¹⁴C]TMG and [¹⁴C]TMG-6-P were separated by thin-layer chromatography. Lanes 1 and 3, [¹⁴C]TMG-6-P accumulated in wild-type and ptsH1 mutant cells; lanes 2 and 4, [¹⁴C]TMG present in cells and in the medium after 5 min of expulsion. Expulsion experiments were carried out with the wild-type strain MG5267 (lanes 1 and 2) and the ptsH1 mutant LlG101 (lanes 3 and 4). The cells were grown in 0.5% lactose-containing M17 medium.

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FIG. 7. Expulsion of accumulated [¹⁴C]TMG-6-P (A) and [¹⁴C]2-DG-6-P (B) in the L. lactis wild-type strain MG5267 and the ptsH1 mutant LlG101. Cells grown in the presence of 0.5% lactose or 0.5% glucose were preloaded with [¹⁴C]TMG or [¹⁴C]2-DG, respectively. The amount of labeled sugar remaining inside the cells during a 5-min (for TMG) or 15-min (for 2-DG) incubation period at 37°C in the presence or absence of glucose was determined by withdrawing aliquots at the indicated time intervals and analyzing them by the rapid-filtration method (37). Squares, no sugar added; circles, 10 mM glucose added at time zero. S46AO and wtO, no glucose added to cells preloaded with [¹⁴C]2-DG-6-P. For the latter samples, aliquots were withdrawn only at the beginning and at the end of the experiments. Leakage levels of [¹⁴C]2-DG-6-P from the cells were found to be nearly identical for the wild-type and the ptsH1 mutant strains, explaining why the lines for the two strains coincide.

Expulsion experiments were also carried out with cells which had taken up [¹⁴C]2-DG. Like TMG, [¹⁴C]2-DG is accumulated by L. lactis cells as the phospho derivative.After glucose was added, [¹⁴C]2-DG-6-P was first intracellularly dephosphorylated and subsequentlyexpelled as unphosphorylated [¹⁴C]2-DG (34). Compared to TMG expulsion, glucose-activated expulsionof [¹⁴C]2-DG occurred at a slower rate (Fig. 7B). But almost no differenceof [¹⁴C]2-DG expulsion could be observed between L. lactis wild-typeand ptsH1 mutantstrains.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

HPr is the major regulator of carbon metabolism in gram-positive bacteria. The implication of P-Ser-HPr in CCR and CCA hasbeen well established for B. subtilis (7), Staphylococcus xylosus(19), and L. casei (12, 37) and has also been suggestedfor L. lactis. Expression of the L. lactis las operon encodingseveral glycolytic enzymes was stimulated by the presence of glucose,whereas activation of las operon expression was absent in a ccpAmutant (27) as well as a ptsH disruption mutant transformedwith a plasmid containing the ptsH1 allele (encoding Ser46AlaHPr) (26). The participation of P-Ser-HPr in catabolite regulationwas confirmed by constructing a chromosomal ptsH1 mutant. LikeB. subtilis, L. lactis possesses an aryl- $beta$ -glucoside-specificEII (PtbA) and a 6-P- $beta$ -glucosidase (BglH) (1, 4). In thewild-type strain, the synthesis of these enzymes was stronglyrepressed by glucose, but it was relieved from CCR in the ptsH1mutant. In B. subtilis, the bgl operon is regulated by two CCRmechanisms (22): one involves P-Ser-HPr/CcpA and a cre presentin the promoter region, and the other involves the antiterminatorLicT, which is activated by P~His-HPr-mediated phosphorylation(25). BglR, a homologue of LicT, is controlling $beta$ -glucosidemetabolism in L. lactis (1), and a potential cre is precedingthe ptbA gene encoding EIICBA^Bgl (4), suggesting that CCR mechanisms similar to those describedfor the B. subtilis bgl operon might be operative for the ptbA-bglHoperon in L. lactis.

We observed that in L. lactis glucose exerted a strong exclusion or expulsion effect on other PTS carbohydrates. The uptakeof TMG and mannitol was almost completely inhibited when glucosewas present. A much weaker inhibitory effect of glucose or fructoseon mannitol uptake has been observed with B. subtilis (10, 46).In the latter organism, competition for the common phosphoryldonor P~His-HPr seemed to be the reason for this inhibitory effect,since inhibition of mannitol transport was almost completely relievedin a B. subtilis ptsH1 mutant (10). Since Ser46A mutant HPrcannot be phosphorylated by HprK/P, a ptsH1 mutant contains moreP~His-HPr for the phosphoryl group transfer within the PTS phosphorylationcascade than does a wild-type strain (Fig. 2). TMG uptake in L.lactis seems to be regulated in a manner similar to that of mannitoluptake in B. subtilis, since the inhibitory effect of glucoseon TMG uptake was much weaker in a ptsH1 mutant. The slowed TMGexpulsion in the ptsH1 mutant (Fig. 7A) could also be responsiblefor the weaker inhibitory effect of glucose on TMG-6-P accumulation.Glucose-mediated inhibition of mannitol transport in L. lactisfollows a different mechanism, since glucose exerted similarlystrong inhibitory effects on mannitol transport in both wild-typestrain MG5267 and ptsH1 mutantLlG101.

P-Ser-HPr has recently been shown to participate in inducer exclusion of non-PTS carbohydrates in gram-positive bacteria.The strong inhibitory effect of glucose on the uptake of the non-PTSsugar maltose observed with L. casei wild-type cells was absentin ptsH1 and hprK mutants (12, 37). In order to find out whetherthis recently established mechanism of inducer exclusion of non-PTSsugars, which so far has not been detected in B. subtilis, iswidespread within gram-positive bacteria, we tested whether itwas also operative in L. lactis. We found that in L. lactis theuptake of maltose and ribose was subject to inducer exclusion.The two corresponding transport activities were strongly inhibitedby the presence of glucose. Similar to what is observed for L.casei, inducer exclusion in L. lactis is mediated via P-Ser-HPr,since the strong repressive effect of glucose had completely disappearedin the ptsH1 mutant. Interestingly, both non-PTS transport systemssubmitted to inducer exclusion in L. lactis are ABC transporters(3, 4). Since it is likely that in L. casei maltose is alsotaken up by an ABC transporter, there arises the question of whetherP-Ser-HPr-mediated inducer exclusion in gram-positive bacteriaaffects only ABCtransporters.

In previous reports, a participation of P-Ser-HPr in inducer expulsion by L. lactis has been suggested, whereas the resultsobtained during this study argue against an implication of P-Ser-HPrin this regulatory process. In the previous inducer expulsionstudies, B. subtilis wild-type or Ser46Asp mutant HPr and glycolyticintermediates were electroporated into L. lactis vesicles, andthe results suggested an involvement of P-Ser-HPr in the expulsionof both TMG and 2-DG (42, 43). P-Ser-HPr has been proposedto stimulate the first step of inducer expulsion, the dephosphorylationof accumulated nonmetabolizable PTS sugars, since it has beenreported to activate in vitro a P-sugar phosphohydrolase (45).In contrast, in vivo experiments carried out with L. casei wild-type,ptsH1, and hprK mutant strains had allowed us to establish thatin this organism P-Ser-HPr does not participate in inducer expulsion(12, 37). An almost identical expulsion of TMG was observedin the L. casei wild-type strain and the two mutant strains unableto form P-Ser-HPr. Constructing a ptsH1 mutant was expected toallow us to either confirm or refute the proposed participationof P-Ser-HPr in inducer expulsion of L. lactis. Since in the L.lactis ptsH1 mutant, 2-DG expulsion by glucose was not affectedand TMG expulsion was still operative, although at a lower ratethan in the wild-type strain, P-Ser-HPr is not necessary for inducerexpulsion. A P-Ser-HPr-independent inducer expulsion mechanismmust be operative in L. lactis and L. casei (12, 37) and probablyin other gram-positive organisms. In the studies suggesting arole of P-Ser-HPr in inducer expulsion, the use of L. lactis vesicles,the electroporation of HPr and metabolites into these vesicles,and the use of a heterologous system (B. subtilis wild-type orSer46Asp mutant HPr instead of L. lactis HPr or P-Ser-HPr) couldhave yielded misleading results. In comparison, the results obtainedin this study seem to be more reliable, since the experimentswere carried out in vivo with intact cells of an L. lactis wild-typestrain and a ptsH1 mutant. The latter strain synthesized HPr,which was active in PTS transport but which, due to the replacementof Ser-46 with an alanine, could not be phosphorylated by HprK/P.Nevertheless, according to the Western blots (Fig. 2), the totalamounts of the various forms of HPr present in the two strainswere verysimilar.

What could have been the reason for the results of the vesicle studies suggesting an involvement of P-Ser-HPr in inducer expulsion?Ser46Asp mutant HPr might not exactly mimic P-Ser-HPr, and byusing electroporation, the amount of HPr present in the vesicleswas probably difficult to control. In addition, the reduced rateof TMG expulsion observed with the L. lactis ptsH1 mutant suggestedan indirect role of HPr in this regulatory process. Evidence haspreviously been provided that expulsion of TMG in Streptococcuspyogenes is catalyzed by EIICB^Lac (31). In a wild-type strain growing in glucose-containing medium,only about 25% of the HPr is present as P~His-HPr. Under theseconditions, EIICB^Lac might be unphosphorylated or only slightly phosphorylated. Bycontrast, in a ptsH1 mutant growing in glucose-containing medium,the about threefold-greater amount of P~His-HPr might allow amore efficient phosphorylation of EIICB^Lac. Phosphorylated EIICB^Lac probably does not expel TMG from the cells but rather transportsand rephosphorylates it and might therefore be responsible forthe slowed TMG expulsion observed with the ptsH1 mutant. Elevatedphosphorylation of EIICB^Lac in vesicles, into which Ser46Ala mutant HPr had been electroporated,might also be the reason why these vesicles exhibited reducedinducer expulsion. By contrast, coelectroporation of glycolyticintermediates with either wild-type HPr, which under the experimentalconditions employed was partly converted to P-Ser-HPr in the vesicles(42), or Ser46Asp mutant HPr, which like P-Ser-HPr is very slowlyphosphorylated at His-15 by enzyme I and PEP, probably led toinefficient phosphorylation of EIICB^Lac and therefore caused no reduction or only a slight reductionof TMGexpulsion.

	ACKNOWLEDGMENTS

This research was supported by the CNRS, the INRA, the INA-PG, and the MENRT. V. Monedero was a recipient of an FPU fellowshipfrom the Ministerio de Educación y Cultura ofSpain.

We thank Manuel Zúñiga for providing us with a protocol for electroporation of L. lactiscells.

	FOOTNOTES

^* Corresponding author. Mailing address: Laboratoire de Génétique des Microorganismes, INRA-CNRS URA 1925, 78850 Thiverval-Grignon,France. Phone: 33-1-30815447. Fax: 33-1-30815457. E-mail: jdeu{at}grignon.inra.fr.

Present address: Departamento de Biotecnologia, Instituto de Agroquímica y Tecnología de Alimentos (CSIC), Valencia,Spain.

Present address: Department of Genetics, University of Groningen, 9751 NN Haren, TheNetherlands.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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