Molecular and Physiological Analysis of the Role of Osmolyte Transporters BetL, Gbu, and OpuC in Growth of Listeria monocytogenes at Low Temperatures

Listeria monocytogenes is a ubiquitous food-borne pathogen foundwidely distributed in nature as well as an undesirable contaminantin a variety of fresh and processed foods. This ubiquity canbe at least partly explained by the ability of the organismto grow at high osmolarity and reduced temperatures, a consequenceof its ability to accumulate osmo- and cryoprotective compoundstermed osmolytes. Single and multiple deletions of the knownosmolyte transporters BetL, Gbu, and OpuC significantly reducegrowth at low temperatures. During growth in brain heart infusionbroth at 7°C, Gbu and OpuC had a more pronounced role incryoprotection than did BetL. However, upon the addition ofbetaine to defined medium, the hierarchy of transporter importanceshifted to Gbu > BetL > OpuC. Upon the addition of carnitine,only OpuC appeared to play a role in cryoprotection. Measurementsof the accumulated osmolytes showed that betaine is preferredover carnitine, while in the absence of a functional Gbu, carnitinewas accumulated to higher levels than betaine was at 7°C.Transcriptional analysis of the genes encoding BetL, Gbu, andOpuC revealed that each transporter is induced to differentdegrees upon cold shock of L. monocytogenes LO28. Additionally,despite being transcriptionally up-regulated upon cold shock,a putative fourth osmolyte transporter, OpuB (identified bybioinformatic analysis and encoded by lmo1421 and lmo1422),showed no significant contribution to listerial chill tolerance.Growth of the quadruple mutant LO28 ${Delta}$ BCGB ( ${Delta}$ betL ${Delta}$ opuC ${Delta}$ gbu ${Delta}$ opuB)was comparable to the that of the triple mutant LO28 ${Delta}$ BCGsoe ( ${Delta}$ betL ${Delta}$ opuC ${Delta}$ gbu) at low temperatures. Here, we conclude that betaineand carnitine transport upon low-temperature exposure is mediatedvia three osmolyte transporters, BetL, Gbu, and OpuC.

INTRODUCTION

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Introduction

The gram-positive food-borne pathogen Listeria monocytogenesaccounts for almost 35% of all deaths in the United States dueto known food-borne bacterial pathogens (23). A number of recentoutbreaks have been associated with ready-to-eat foods thathave been minimally processed (9). As the demand for fresh foodproducts is increasing, cold storage of these products is becomingmore widespread. This continuing trend toward minimal food processingand reliance on refrigeration as a preservation technique hasin turn been accompanied by a steady increase in the incidenceof food poisoning, particularly by psychrotrophic pathogenssuch as L. monocytogenes, which can grow at temperatures aslow as –0.1°C (36).

Mechanisms that allow low-temperature growth of microorganismsinvolve the maintenance of the cellular membrane fluidity, structurestabilization of macromolecules such as ribosomes which arenecessary for continued protein synthesis, and the uptake orsynthesis of compatible solutes (17). For L. monocytogenes,the adaptation of membranes to low temperatures is accomplishedby altering branching in the methyl end of the fatty acid fromiso to anteiso and by shortening of the fatty acid chain length,resulting mainly in an increase of anteiso-C_15:0 fatty acids(5). In L. monocytogenes, instability in the 70S ribosomal particlestructure is found upon cold shock (6), which must be overcometo allow normal protein synthesis. In Escherichia coli, proteinsynthesis after cold shock is related to the synthesis of so-calledcold shock proteins (CSPs) (26). In L. monocytogenes LO28, fourcold shock proteins have been identified, two of which are producedin increased amounts following a cold shock from 30 to 10°C(37).

With the exception of proline (31), L. monocytogenes appearsunable to synthesize osmolytes (22) either de novo or from precursorcompounds (33). However, the transport of the principal osmolytesglycine betaine (N,N,N-trimethylglycine) and carnitine (ß-hydroxy- ${gamma}$ -N-trimethylaminobutyrate) was found to be increased 15- and 4.5-fold, respectively,upon low-temperature stress (3, 21).

To date, three osmolyte transporters, Gbu, OpuC, and BetL (3,10, 14, 15, 20, 24, 30, 34; for a review, see reference 32),dedicated to betaine and carnitine uptake in L. monocytogenes,have been identified and characterized experimentally. However,recent in silico analysis of the L. monocytogenes EGD-e genomesequence (16) revealed a fourth putative osmolyte transporterwith significant homology to the high-affinity choline uptakesystem OpuB of Bacillus subtilis. Consisting of two genes, lmo1421and lmo1422, this operon is located approximately 2.4 kb downstreamof opuC on the listerial chromosome (32). While a possible rolefor OpuB as a carnitine uptake system in Listeria has previouslybeen suggested (11, 38), Angelidis and Smith (2) recently demonstratedthat, at least in L. monocytogenes 10403S, carnitine uptakeis mediated exclusively by OpuC and Gbu. However, the existenceor potential impact of OpuB was not examined in this strain.

The principal betaine uptake system Gbu is a binding protein-dependentATP-binding cassette (ABC) transporter homologous to OpuA inB. subtilis (20). The growth rate of L. monocytogenes 10403Sin the absence of a functional Gbu transporter was significantlylower than that of the wild type at 7°C, with uptake ratesfor [¹⁴C]glycine betaine being reduced approximately eightfoldin this mutant (20). Moreover, in vitro activation of the Gbutransport activity was demonstrated to occur in membrane vesiclesat reduced temperatures (14). OpuC, the principal carnitinetransporter, encoded by the opuCABCD operon (10, 34), is homologousto opuC and opuB in B. subtilis and is also an ABC transporter,coupling ATP hydrolysis to osmolyte transport across the membrane.An interesting feature of opuC is that it is preceded by a consensus ${sigma}$ ^B-dependent promoter binding site (10, 12), which may also implychill-stimulated osmolyte uptake since transcription of ${sigma}$ ^B hasitself been shown to be up-regulated in response to a temperaturedownshift (7). Indeed, a ${sigma}$ ^B deletion mutant of L. monocytogenes10403S exhibited reduced growth rates at 8°C in definedmedium (DM) supplemented with either betaine or carnitine (0.011and 0.010 h^–1, respectively) compared with wild-type 10403S(0.018 and 0.017 h^–1, respectively) (8). Finally, BetL,a secondary betaine uptake system that couples a Na⁺ motiveforce to solute transport across the membrane, is homologousto OpuD of B. subtilis and BetP of Corynebacterium glutamicum(30). The reduced growth rate for the 10403S ${sigma}$ ^B deletion mutantat 8°C upon addition of betaine (8) might reflect the presenceof a putative ${sigma}$ ^B-dependent promoter binding site upstream ofbetL (33). However, the growth rate of a strain in which betLis functionally inactivated was not affected at 4°C (33);in addition, in vitro betaine transport via BetL in proteoliposomesdoes not appear to be activated by cold (15).

Previously, a set of mutants carrying deletions in the knownosmolyte uptake systems Gbu, BetL, and OpuC was constructedand the role of these systems in listerial growth and survivalat elevated osmolarity was determined (33, 34, 38). Here, weemploy a similar strategy to analyze the role of osmolyte uptakein growth at refrigeration temperature (7°C). Recently,Angelidis et al. (4) characterized a Gbu mutant at low temperaturesand predicted that additionally removing BetL may further impairgrowth, while deleting opuC from this background would possiblyeliminate growth altogether under cold stress. Herein, we demonstratethat while the proposed triple mutant LO28 ${Delta}$ BCGsoe ( ${Delta}$ betL ${Delta}$ opuC ${Delta}$ gbu) is indeed severely affected at low temperatures (illustratingthe importance of these systems to listerial chill tolerance),growth is not completely abolished, thus suggesting the existenceof at least one additional cryoprotective system. However, removingOpuB, a putative fourth osmolyte uptake system, from the existingtriple mutant background showed no further reduction in growthat low temperatures, thus ruling out a potential cryoprotectiverole for OpuB in Listeria.

MATERIALS AND METHODS

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Materials and Methods

Strains, chemicals, and growth conditions.
Bacterial strains used in this study are listed in Table 1.Strains were grown either in brain heart infusion (BHI) broth(Oxoid, Basingstoke, United Kingdom) or in DM (27). Where indicated,carnitine and glycine betaine (Sigma Chemical Co., St. Louis,Mo.) were added to DM as filter-sterilized solutions to a finalconcentration of 1 mM. For growth of LO28 ${Delta}$ C ( ${Delta}$ opuC), LO28 ${Delta}$ CG ( ${Delta}$ opuC ${Delta}$ gbu), and LO28 ${Delta}$ BCG ( ${Delta}$ betL ${Delta}$ opuC ${Delta}$ gbu), erythromycin (10 µg/ml)was used as a selection marker. Cell growth was monitored spectrophotometricallyby measuring the optical density at 620 nm (OD₆₂₀), and growthrates were calculated by plotting the natural logarithm of theOD₆₂₀ versus time (standard deviations varied within 10% ofthe values; experiments were performed in triplicate).

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TABLE 1. L. monocytogenes strains used in this study

Creation of the triple SOEing mutant LO28BCGsoe.
Creation of a SOEing (splicing by overlap extension) mutantwas essentially performed as described by Horton et al. (18).For the creation of the triple SOEing mutant LO28BCGsoe, theSOE (oSOE-A, oSOE-B, oSOE-C, and oSOE-D) and forward and reverse(oSOE-F and oSOE-R) primers used were of the same sequence asthose used by Angelidis and Smith (2). The hybrid 882-bp opuCconstruct (comprised of two regions in the 5' and 3' end ofopuC) was digested with HindIII and BamHI, cloned into pKSV7,and transformed into E. coli DH5 ${alpha}$ to yield pCPL18. This constructwas then electroporated into L. monocytogenes LO28 ${Delta}$ BG, and successfultransformants were selected on BHI plates containing 10 µgof chloramphenicol/ml. Selection at 42°C of cells with chromosomalintegration of pCPL18 followed by sequential passaging in BHIbroth at 30°C in the absence of chloramphenicol facilitatedthe recovery of cells in which allelic exchange between theintact opuC operon and the 882-bp insert on pCPL18 had occurred,thus giving rise to LO28BCGsoe. Confirmation of the deletionevent was obtained by PCR with the forward and reverse primersoSOE-F and oSOE-R.

Transcriptional analysis of the osmolyte transporters.
Reverse transcription (RT)-PCR experiments were performed essentiallyas described by Sleator et al. (33). L. monocytogenes cellswere grown to mid-exponential phase at 37°C. Cells werethen centrifuged and resuspended in 1 ml of BHI at 10 or 37°C(control temperature). After 15 and 30 min of incubation, cellswere harvested and flash frozen at –80°C. RNA wasextracted by using a hot acid phenol procedure as describedby Ripio et al. (29), and cDNA was synthesized by adding 1 µlof total RNA to 4 µl of 5x RT buffer (Roche), 2 µlof 100 mM dithiothreitol, 0.5 µl of a deoxynucleosidetriphosphate mix (10 mM [each] dATP, dCTP, dGTP, and dTTP),0.25 µl of RNasin, 100 ng of the random primer p(dN)₆,and 1 µl of Expand reverse transcriptase (Roche). Thereaction mixture was incubated at 42°C for 9 h. PCR on cDNAwas carried out by using the following primers: for gbu, gbuSOEA and gbu SOEB (38), targeting gbuB; for betL, betL SOECand betL SOED (36); for opuC, opuC-F (5'-CACCAAAAGTAGCGAAC-3')and opuC-R (5'-GAATTAAGTCTGGACGGTATAAG-3'), targeting opuCB;for opuB, opuB-F (5'-ATCTAGAAAATGACTTCGTTAAA-3') and opuB-R(5'-ACAAGCTCACCTGAACTTTCC-3'), targeting lmo1421; and for 16SRNA, 16SRNA-E (5'-TTAGCTAGTTGGTAGGGT-3') and 16SRNA-B (5'-AATCCGGACAACGCTTGC-3').PCRs were carried out for 16, 22, and 30 cycles to allow optimalquantification of PCR products.

Uptake studies.
The L. monocytogenes LO28 wild type was grown in DM at 30°Cuntil early exponential phase (OD₆₂₀ of $~$ 0.25). Where indicated,a cold shock to 10°C was performed as previously described(37). Osmolyte uptake studies were carried out essentially asdescribed by Verheul et al. (35). Cells were concentrated toan OD₆₂₀ of 20 in 50 mM potassium phosphate buffer (pH 6.8)containing 5 mM MgSO₄ and chloramphenicol (100 µg/ml)to inhibit protein synthesis. Cells (OD₆₂₀ of 1) were preenergizedat 37°C with 1% glucose for 5 min prior to the additionof radiolabeled osmolyte N,N,N-[1-¹⁴C]trimethylglycine (finalconcentration of 19 µM) purchased from Campo Scientific(Veenendaal, The Netherlands). Samples were withdrawn after0.5, 1, 2, 3, and 4 min, and uptake was stopped by the additionof 2 ml of cold 50 mM potassium phosphate buffer (pH 6.8) containing5 mM MgSO₄. After the reaction was stopped, the cells were immediatelycollected on 0.2-µm-pore-size cellulose nitrate filters(Schleicher and Schuell GmbH, Dassell, Germany) under vacuum,the filters were washed with 2 ml of buffer, and the radioactivitytrapped in the cells was measured with a scintillation counter(model 1600TR; Packard Instruments Co., Downers Grove, Ill.).Uptake of osmolytes by the cells was normalized to total cellularprotein. The experiment was performed in duplicate, and theresults of a typical experiment are displayed in Fig. 4.

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FIG. 4. Glycine betaine transport in wild-type strain LO28 at 37°C for exponential-phase cells ( ${blacklozenge}$ ) and cells cold shocked for 4 h ( ${lozenge}$ ) and betaine transport at 10°C for exponential-phase cells (•) and cells cold shocked for 4 h ( ${circ}$ ) are shown.

Accumulation studies.
Cells were grown in BHI at 30°C or at 7°C until mid-exponentialgrowth phase (OD₆₂₀ of $~$ 0.4). One hundred milliliters of culturewas pelleted and washed twice in potassium phosphate buffer(50 mM with 5 mM MgSO₄, pH 6.8, 7°C) before being resuspendedin 750 µl of water and freeze dried for determinationof dry weight. The cells were extracted by the procedure describedby Galinski and Herzog (13) using methanol and chloroform. Betaineand carnitine concentrations were determined as described byVerheul et al. (35). Betaine and carnitine were measured byrefractive index after high-performance liquid chromatographyby using a LiChrosphere 100-NH₂ 5-µm column (Merck, Darmstadt,Germany) at a flow rate of 1 ml/min at 45°C with a mobilephase of 80:20 (vol/vol) acetonitrile-20 mM potassium phosphate(pH 7.0). The concentrations of betaine and carnitine were calculatedfrom the area under the respective peaks by using calibrationcurves. The experiment was performed in duplicate, and the resultsof a typical experiment are displayed in Fig. 5.

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FIG. 5. Internal concentration of betaine (black bars) and carnitine (white bars) in L. monocytogenes LO28 and mutants grown at 7°C in BHI.

RESULTS

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Results

Deletion of osmolyte transporters reduces growth at low temperatures.
To identify the role of each osmolyte transporters in growthat low temperatures, we monitored the growth of various osmolyteuptake mutants in BHI at 7°C (Fig. 1). While growth of thewild-type and mutant strains in BHI at 30°C was similar(data not shown), the effect of deleting the various osmolytetransporters at 7°C was clearly observed. The growth rateof the wild type in BHI at 7°C was 0.028 h^–1 (Table2), and deleting gbu or opuC decreased growth rates to 0.026h^–1, whereas removing betL had no significant effect.Deleting all three transporters in combination had the mostdramatic effect, resulting in a reduction in the growth rateof 0.028 to 0.018 h^–1. Notably, growth of the quadruplemutant LO28 ${Delta}$ BCGB was similar to that of the triple mutant, suggestingthat, at least under the conditions tested, OpuB is unlikelyto contribute to listerial chill tolerance.

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FIG. 1. Growth of LO28 and osmolyte uptake mutants in BHI at 7°C. LO28 ( ${diamondsuit}$ ), LO28 ${Delta}$ B ( ${Delta}$ betL) ( ${square}$ ), LO28 ${Delta}$ C ( ${Delta}$ opuC) ( ${triangleup}$ ), LO28 ${Delta}$ G ( ${Delta}$ gbu) (x), LO28 ${Delta}$ BG ( ${Delta}$ betL ${Delta}$ gbu) ( ${circ}$ ), LO28 ${Delta}$ CG ( ${Delta}$ opuC ${Delta}$ gbu) (+), LO28 ${Delta}$ BCGsoe ( ${Delta}$ betL ${Delta}$ opuC ${Delta}$ gbu) ( ${diamond}$ ), and LO28 ${Delta}$ BCGB ( ${Delta}$ betL ${Delta}$ opuC ${Delta}$ gbu ${Delta}$ opuB) () are shown.

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TABLE 2. Growth rate of L. monocytogenes LO28 and osmolyte uptake mutants at 7°C in BHI

To study the individual contribution of betaine and carnitineto low-temperature adaptation, DM was used. Growth did not significantlydiffer at 7°C in DM. While the addition of 1 mM betaineresulted in a significant increase of growth of the wild type,the increase in growth of the mutants upon the addition of betainewas lower than that of the wild type (Fig. 2A). Given that growthwas most affected following the deletion of gbu, it appearsthat the Gbu system is the most effective transporter duringlow-temperature growth. Interestingly, it has previously beendemonstrated that for growth at elevated osmolarities (3% NaCl),Gbu also plays the dominant role (38). Upon the addition ofcarnitine to DM, the role of OpuC in the uptake of carnitinefor cryoprotective purposes is apparent, as only those mutantsdeficient in their OpuC transporter show reduced growth comparedto that of the wild type (Fig. 2B), indicating the importanceof OpuC in carnitine uptake at low temperatures. Furthermore,the deletion of the two principal betaine uptake systems Gbuand BetL (strain LO28 ${Delta}$ BG) does not influence the growth characteristicsat 7°C compared with those of the wild type upon the additionof carnitine to DM (Fig. 2B). In addition, growth of the triplemutant LO28 ${Delta}$ BCGsoe and the quadruple mutant LO28 ${Delta}$ BCGB was notinduced upon the addition of betaine or carnitine to the medium(data not shown), supporting our proposal that OpuB is unlikelyto play a role in betaine or carnitine uptake and subsequentcryoprotection.

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FIG. 2. Growth of LO28 and osmolyte uptake mutants. (A) Growth of LO28 ( ${diamondsuit}$ ), LO28 ${Delta}$ G ( ${Delta}$ gbu) (x), LO28 ${Delta}$ BG ( ${Delta}$ betL ${Delta}$ gbu) ( ${circ}$ ), and LO28 ${Delta}$ BCGsoe ( ${Delta}$ betL ${Delta}$ opuC ${Delta}$ gbu) ( ${diamond}$ ) in DM at 7°C with the addition of betaine. (B) Growth of LO28 ( ${diamond}$ ), LO28 ${Delta}$ C ( ${Delta}$ opuC) ( ${triangleup}$ ), LO28 ${Delta}$ BG ( ${Delta}$ betL ${Delta}$ gbu) ( ${circ}$ ), and LO28 ${Delta}$ BCGsoe ( ${Delta}$ betL ${Delta}$ opuC ${Delta}$ gbu) ( ${diamond}$ ) in DM at 7°C with the addition of carnitine.

Induced transcription of osmolyte transporter genes at low temperatures.
RT-PCR was performed to analyze the transcription of the differenttransporter genes following cold shock. Though expression levelsof the genes at 37°C were at the detection limit, both gbuand betL, encoding the principal betaine uptake systems, weresignificantly up-regulated following exposure to 10°C for30 min (Fig. 3). However, the level of gbu up-regulation appearsgreater than that of betL following cold shock. This resultis consistent with the observation that Gbu provides significantlymore cryoprotection than does BetL. The carnitine transporter-encodinggenes were also clearly induced following cold shock. In addition,transcription of the operon encoding OpuB, a putative fourthosmolyte uptake system, was also significantly induced uponlow-temperature exposure of L. monocytogenes LO28 cells.

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FIG. 3. (Top) Schematic of the transcription of the four osmolyte transporters in L. monocytogenes after cold shock. B, betaine; C, carnitine. (Bottom) RNA was isolated from mid-exponential-phase cells prior to cold shock (lanes labeled 37) and from cells exposed to 10°C for 30 min (lanes labeled 10). The results after 30 cycles are shown for gbu (Gbu), betL (BetL), opuC (OpuC), and opuB (OpuB).

Betaine and carnitine accumulation at low temperatures.
Increased transcription of the transporters upon cold shock(Fig. 3) suggests an increased uptake of osmolytes at low temperatures.However, when L. monocytogenes LO28 wild-type cells, cold shockedto 10°C, were tested for betaine uptake after 4 h at 10°C,no increase in betaine uptake at low temperatures was observedwithin the time frame measured (Fig. 4). Furthermore, the uptakerate at 37°C for cold-shocked cells was lower than thatfor exponential-phase cells grown at 37°C. Notably, theintracellular concentrations of betaine and carnitine duringgrowth of wild-type LO28 in BHI at 7°C were 300 and 120µmol/g (dry weight) of cells, respectively (Fig. 5), whereasduring growth at 30°C, the betaine concentration was 70µmol/g (dry weight) of cells, while carnitine was notaccumulated to detectable levels (38). This indicates that L.monocytogenes LO28 cells do accumulate betaine and carnitineat low temperatures. For the single mutants LO28 ${Delta}$ B and LO28 ${Delta}$ C,accumulation levels similar to that for the wild type were found(Fig. 5). However, in LO28 ${Delta}$ G, the betaine concentration is muchlower ( $~$ 70 µmol/g [dry weight] of cells), which is apparentlycompensated for by the accumulation of carnitine. In strainLO28 ${Delta}$ BG ( ${Delta}$ betL ${Delta}$ gbu), OpuC is the remaining transporter responsiblefor the accumulated carnitine (about 450 µmol/g [dry weight]of cells). Analysis of the triple mutant LO28 ${Delta}$ BCGsoe followinggrowth at 7°C in BHI revealed no accumulated betaine orcarnitine (with a detection limit of about 20 µmol/g [dryweight] of cells). Thus, at least under the conditions tested,BetL, Gbu, and OpuC appear to be the only betaine and carnitineuptake systems effective during low-temperature growth in L.monocytogenes.

DISCUSSION

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Discussion

L. monocytogenes is a food-borne pathogen capable of growthat low temperatures. Given the increasing reliance on refrigerationas a method of food preservation (1), the psychrotropic natureof this pathogen is an especially important consideration froma food safety perspective. A major factor contributing to low-temperaturegrowth of L. monocytogenes is the ability of the organism toaccumulate compatible solutes such as betaine and carnitine.Using a set of mutants with deletions in the known osmolytetransporters BetL, Gbu, and OpuC, we were able to determinethe individual contribution of betaine and carnitine and theirtransporters to the low-temperature growth of L. monocytogenes.

In wild-type LO28, growth at low temperatures is clearly stimulatedby the addition of betaine and/or carnitine to DM, in whichbetaine is more successful than carnitine. This result suggeststhat betaine functions as a more effective cryoprotectant thancarnitine, an observation which also appears to extend to theirrespective osmoprotective effects (38), a phenomenon which Peddieet al. (25) attributed to differences in hydrocarbon chain length.Upon the addition of betaine to DM at 7°C, the hierarchyof transporter importance is Gbu > BetL > OpuC. However,when betaine is replaced by carnitine, the role of OpuC at lowtemperatures becomes apparent in that only those mutants deficientin their OpuC transporter are reduced in their growth comparedto that of the wild type. This is consistent with the findingsof Becker et al. (8), who showed that the growth of L. monocytogenesafter a cold shock from 37 to 8°C is stimulated upon additionof carnitine to DM, thus proving a role for carnitine in low-temperaturegrowth. Moreover, it was found that the uptake of carnitinevia OpuC seems to be regulated by the alternative sigma factor ${sigma}$ ^B, a stress-related sigma factor, which is itself induced atlow temperatures (7, 12).

The increased transcription of the transporters upon cold shock(Fig. 3) suggests an increased uptake of osmolytes at low temperatures.However, L. monocytogenes LO28 wild-type cells, cold shockedto 10°C for 4 h, did not show an increase in betaine uptakeat low temperatures within the time frame measured (Fig. 4).Furthermore, the uptake rate at 37°C for cold-shocked cellswas lower than that for exponential-phase cells grown at 37°C.In contrast, Ko et al. (21) and Mendum and Smith (24) showedthat L. monocytogenes cells (Scott A and 10403S, respectively)grown at low temperatures have an increased betaine uptake atthis temperature compared to cells grown and tested at 30°C.In addition, cold-shocked 10403S cells tested by Becker et al.(8) were found to have comparable betaine uptake levels at 8and 25°C. These apparent differences might be explainedby different experimental setups and strain differences.

In the wild-type strain, it is mainly betaine that is accumulatedduring growth at low temperatures. However, in strain LO28 ${Delta}$ G,more carnitine than betaine is accumulated. This increase ininternal carnitine concentration upon the deletion of Gbu wasalso observed for L. monocytogenes 10403S at low temperatures(4) and for LO28 grown at high osmolarity (38). Thus, carnitinewas accumulated to high levels only in those strains with impairedability to transport betaine via Gbu. The ability of betaineto suppress the accumulation of other osmolytes is typical ofbacterial species that can accumulate betaine together withother osmolytes (19, 28). Angelidis and Smith (2) have recentlyproposed that betaine and carnitine uptake in Listeria is mediatedexclusively by BetL, Gbu, and OpuC. An earlier triple mutantcreated in our laboratory, LO28 ${Delta}$ BCG (38), displayed low levelsof carnitine and betaine uptake which we attributed to the existenceof a possible fourth transporter, which we and others (11) suggestedto be OpuB, a potential osmolyte uptake system identified byin silico analysis of the completed genome sequence (32). Angelidisand Smith (2) suggested that the residual uptake observed mayalso be explained by the nature of the OpuC mutation, whichwas created by plasmid integration rather than SOEing mutagenesis.To resolve this issue, in this study we recreated the triplemutant by using SOEing to eliminate the OpuC gene. The resultingmutant, designated LO28 ${Delta}$ BCGsoe, was found to exhibit no detectablebetaine or carnitine accumulation either at reduced temperaturesor at elevated osmolarities. Thus, it appears that betaine andcarnitine uptake in L. monocytogenes is indeed mediated by Gbu,BetL, and OpuC alone, both at elevated osmolarities as shownby Angelidis and Smith (2) and at refrigeration temperatures.

RT-PCR analysis revealed that the genes encoding all three transporters,Gbu, BetL, and OpuC, are significantly up-regulated followinga rapid decrease in temperature from 37 to 10°C. Interestingly,the induced transcription of opuB after cold shock also suggestsa role for this transporter at low temperatures. However, nodifference in betaine or carnitine accumulation was observedbetween the triple and quadruple mutants LO28 ${Delta}$ BCGsoe and LO28 ${Delta}$ BCGB,confirming that OpuB is not involved in betaine or carnitineuptake. Furthermore, given that the growth characteristics ofboth mutants at low temperatures were similar, OpuB is unlikelyto play a significant role in listerial cryotolerance.

In high-salt environments, compatible solutes serve to balancethe osmotic disturbance. Although their functions at low temperaturesare largely unknown, some functions of compatible solutes atlow temperatures have been proposed: they can serve as stabilizersof enzyme function and as such may function in the stabilizationof membrane bilayers (22). What is interesting in regard tothis perspective is the possible overlapping function with CSPs.These proteins have been suggested to play a role in the stabilizationof macromolecules at low temperatures (and during other stresses).Induction of two of the four CSPs in LO28 after cold shock wasdescribed previously (37). We have also analyzed CSP production20 h after cold shock to 10°C of wild-type LO28 as wellas the triple mutant LO28 ${Delta}$ BCG. However, no changes in CSP productionbetween the two strains could be detected (results not shown),indicating that increasing the CSP levels does not compensatefor osmolyte depletion.

ACKNOWLEDGMENTS

We acknowledge the financial assistance of the Irish Governmentunder National Development Plan 2000-2006. R.D.S. is fundedby an IRCSET postdoctoral fellowship.

FOOTNOTES

* Corresponding author. Mailing address: Laboratory of Food Microbiology, Wageningen University, Bomenweg 2, 6703 HD Wageningen, The Netherlands. Phone: 31-317-484981. Fax: 31-317-484978. E-mail: Tjakko.Abee{at}wur.nl.

Present address: Department of Flavour, Nutrition & Ingredients,NIZO Food Research, 6710 BA Ede, The Netherlands.

REFERENCES

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