Osmotic and Chill Activation of Glycine Betaine Porter II in Listeria monocytogenes Membrane Vesicles

doi:10.1128/JB.182.9.2544-2550.2000

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Journal of Bacteriology, May 2000, p. 2544-2550, Vol. 182, No. 9
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Osmotic and Chill Activation of Glycine Betaine Porter II in Listeria monocytogenes Membrane Vesicles

Paul N. M. Gerhardt,¹^, Linda Tombras Smith,² and Gary M. Smith¹^,^*

Departments of Food Science and Technology¹ and Agronomy and Range Science,² University of California, Davis, California 95616

Received 11 June 1999/Accepted 16 February 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Listeria monocytogenes is a foodborne pathogen known for its tolerance to conditions of osmotic and chill stress. Accumulationof glycine betaine has been found to be important in the organism'stolerance to both of these stresses. A procedure was developedfor the purification of membranes from L. monocytogenes cellsin which the putative ATP-driven glycine betaine permease glycinebetaine porter II (Gbu) is functional. As is the case for theL. monocytogenes sodium-driven glycine betaine uptake system (glycinebetaine porter I), uptake in this vesicle system was dependenton energization by ascorbate-phenazine methosulfate. Vesicleslacking the gbu gene product had no uptake activity. Transportby this porter did not require sodium ion and could be drivenonly weakly by artificial gradients. Uptake rates could be manipulatedunder conditions not affecting secondary transport but known toaffect ATPase activity. The system was shown to be both osmoticallyactivated and cryoactivated. Under conditions of osmotic activation,the system exhibited Arrhenius-type behavior although the uptakerates were profoundly affected by the physical state of the membrane,with breaks in Arrhenius curves at approximately 10 and 18°C.In the absence of osmotic activation, the permease could be activatedby decreasing temperature within the range of 15 to 4°C. Kineticanalyses of the permease at 30°C revealed K_m values for glycinebetaine of 1.2 and 2.9 µM with V_max values of 2,200 and 3,700pmol/min · mg of protein under conditions of optimal osmotic activationas mediated by KCl and sucrose,respectively.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Listeria monocytogenes is a foodborne pathogen responsible for a variety of infective syndromes in humans (7, 24). Theorganism is considered to be saprophytic and is known for itsability to survive and grow under adverse conditions (31, 32).It is especially well known for its ability to grow under conditionsof high osmolarity and desiccation and at low temperatures (3,6, 30). One mechanism of adaptation to osmotic stress byeubacteria is accumulation of compatible solutes, organic osmolytesthat have comparatively minimal deleterious effects on cell physiologyat high concentrations (2, 5, 9, 20). The compatiblesolute glycine betaine (N,N,N-trimethylglycine) has been shownto be accumulated to high levels in several species of bacteria(11, 25, 26), including L. monocytogenes (16, 23), andhas been shown to confer a substantial degree of both osmotoleranceand cryotolerance upon L. monocytogenes (16).

In eubacteria, glycine betaine is taken up through both primary and secondary transport systems. We have previously describeda sodium-driven, osmotically activated glycine betaine uptakesystem in L. monocytogenes (glycine betaine porter I) that isfunctional in membrane vesicles (10). Ko and Smith have clonedglycine betaine porter II, sequenced the gbu locus, and determinedthat it belongs to the family of ATP-binding cassette (ABC) transporters(17). We now report that glycine betaine porter II is also functionalin membrane vesicles and can be activated either by an osmoticgradient or by lowtemperature.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Materials. ¹⁴C-labeled glycine betaine was synthesized from [¹⁴C]choline HCl (NEN, Boston, Mass.) as described by Landfald and Strøm (19).Egg white lysozyme, mutanolysin, and DNase were obtained fromSigma Chemical Co. (St. Louis, Mo.). Other materials were of reagentgrade and were obtained from commercial sources. The bicinchoninicacid reagent (Pierce Chemical, Rockford, Ill.) was used to determineprotein concentrations (28). Mixed-ester filters (MilliporeGSWP; 0.22-µm pore size, 25-mm diameter) were used in uptake assays,and liquid scintillation counting was performed with ScintiverseI fluid (Fisher Scientific, Pittsburgh, Pa.). The osmotic strengthof assay mixtures was adjusted with appropriate concentrationsof sucrose and KCl using values given previously (33). Culturedensities were measured with a Klett-Summerson colorimeter witha no. 45 (green)filter.

Growth conditions and preparation of membrane vesicles. L. monocytogenes DP-L1044 (hly::Tn917-LTV3) (29) was grown aerobically at 30°C in a 5-liter batch culture of tryptose broth(Difco Laboratories, Detroit, Mich.), supplemented with 281 gof sucrose per liter, to a mid-exponential-phase culture densityof 80 to 85 Klett units. Cells were harvested (13,200 × g, 30min at 4°C) and washed twice in 100 mM potassium phosphate buffer(pH 7.0).

Vesicles were prepared using a modification of procedures for gram-negative bacteria described by other groups (13, 27).The washed cell pellet was resuspended to a volume of 100 ml in50 mM potassium phosphate buffer (pH 7.0) containing 20 mM MgSO₄,25% (wt/vol) sucrose, 1.4 × 10⁶ U of egg white lysozyme, and 1.0 × 10⁴ U of mutanolysin and incubated under gentle shaking at 30°C.Protoplast formation, which was monitored by phase-contrast microscopy,was allowed to proceed to about 95% completion (50 to 55 min).Protoplasts were then concentrated by centrifugation (27,000 ×g, 15 min at 4°C) and resuspended on ice by means of a Potter-Elvehjemhomogenizer to a volume of 3 ml in 50 mM potassium phosphate (pH7.0) containing 20 mM MgSO₄, 25% sucrose, and 16 mg of DNase.The mixture was allowed to incubate on ice for 10 min, after whichit was injected by means of a syringe (19-gauge needle) into 1.5liters of rapidly stirring 50 mM potassium phosphate (pH 7.0)at 37°C. The solution was gently stirred at 37°C for 15 min, afterwhich potassium-EDTA was added to a final concentration of 10mM; after a further 15 min of stirring, MgSO₄ was added to a finalconcentration of 15 mM. Cell debris and remaining whole cellswere removed by centrifugation (3,300 × g, 15 min, 4°C). Purifiedmembranes were collected by centrifugation (21,500 × g, 60 min,4°C) and suspended by means of a Potter-Elvehjem glass homogenizerin 50 mM potassium phosphate (pH 7.0) containing 10 mM MgSO₄.Aliquots of 300 µl containing membrane protein levels of 6 to8 mg/ml were then frozen and stored in liquidnitrogen.

For experiments involving preloading of the vesicles with ATP or ortho-vanadate, either 5 mM ATP or 1 mM sodium ortho-vanadatewas included in the buffer duringlysis.

Transport assays. Membrane vesicles were thawed rapidly at 45°C, held on ice, and used within 120 min of thawing. Incubation mixtures for transportstudies contained 50 mM potassium phosphate, 10 mM MgSO₄, 200µM phenazine methosulfate (PMS), 20 mM potassium ascorbate, [¹⁴C]glycine betaine, and solutes at concentrations yielding theosmotic pressures indicated in the figure legends. Unless statedotherwise, assays were conducted at 30°C. These conditions wereused in all of the experiments except those employing artificialgradients for energization of the transporter. Vesicles were preincubatedfor 10 min in buffer containing the appropriate solutes, afterwhich ascorbate and PMS were added in that order. The reactionwas initiated by the addition of [¹⁴C]glycine betaine (0.05 µCi per assay). For each time point, a50-µl aliquot containing approximately 100 µg of protein was withdrawn.The reaction was terminated by diluting the aliquot into 2 mlof an ice-cold solution containing 100 mM LiCl and KCl of thesame osmotic strength as that used in the uptake mixture. Thesamples were filtered and then washed with 2 ml of the same LiCl-KClsolution; radioactivity was determined by liquid scintillationcounting. Transport rates obtained from duplicate experimentsusing a single preparation of vesicles differed by <10%.

Measurement of ATP production. Vesicles were incubated under a steady flow of water-saturated oxygen gas at 30°C in potassium phosphate buffer containingMgSO₄ and sucrose for 2 min before the reaction was initiatedby addition of PMS. Final concentrations were 3.5 mg of proteinper ml, 610 mM sucrose, 20 mM potassium ascorbate, 20 µM PMS,4.8 mM magnesium sulfate, and 25 mM potassium phosphate, pH 7.Except for the omission of glycine betaine, the conditions werethe same as those used to measure osmotically activated transport(e.g., see Fig. 1, inset). ATP present in the solution was determinedas described by Prossnitz et al. (27). Aliquots (25 µl) werewithdrawn at various time intervals, the reaction was quenched,and the vesicles were lysed by addition of 650 µl of cold 9% perchloricacid. After incubation for 10 min in an ice bath, the solutionwas neutralized by the addition of 188 µl of cold 4 M potassiumhydroxide, followed immediately by 188 µl of 2 M potassium bicarbonate.After an additional 10 min, the samples were centrifuged at 11,500× g for 10 min. Aliquots (100 µl) of the supernatant solutionwere assayed for ATP using 50 µl of luciferin-luciferase reagent(Sigma) and a TD 20/20 luminometer (Turner Designs, Sunnyvale,Calif.). The reagent, which contained glycine buffer, luciferin,and luciferase, was used at a concentration of 8 mg/ml. Experimentswere run induplicate.

Artificial gradient-driven transport. Concentrated membrane vesicles (20 mg of protein/ml) were incubated on ice for 60 min in 20 mM potassium phosphate, pH 6.0,containing 100 mM potassium acetate and 10 mM MgSO₄ in eitherthe presence or the absence of valinomycin (2 nmol/mg of protein).The equilibrated vesicles were then collected by centrifugation(48,200 × g, 20 min, 4°C) and suspended (with or without 1 µMvalinomycin) in 20 mM potassium phosphate (pH 6.0) containing100 mM potassium acetate, 10 mM MgSO₄, and 350 mM sucrose. Thevesicles were then recentrifuged and resuspended in the same bufferto a concentration of approximately 30 mg of protein/ml.

Valinomycin-treated vesicles (6-µl aliquots) were then diluted 100-fold with buffers at 30°C as indicated. All diluting bufferscontained 20 µM [¹⁴C]glycine betaine (0.2 µCi), 500 mM sucrose, and 10 mM MgSO₄,pH 6. The valinomycin-treated vesicles were used to establishdriving forces consisting of a membrane potential ( $Delta$ $Psi$ ), pH gradient( $Delta$ pH), and sodium gradient ( $Delta$ µ_Na⁺/F) created bydilution into 120 mM sodium phosphate; a membrane potential andsodium gradient created by dilution into 100 mM sodium acetate-20mM sodium phosphate; a membrane potential and pH gradient ( $Delta$ P)created by dilution into 120 mM Tris-phosphate; or a membranepotential alone created by dilution into 100 mM Tris-acetate-20mM Tris-phosphate.

Vesicles not treated with valinomycin were used to establish driving forces consisting of a pH gradient and sodium gradientcreated by dilution into 120 mM sodium phosphate; a pH gradientcreated by dilution into 120 mM potassium phosphate; or a sodiumgradient alone created by dilution into 100 mM sodium acetate-20mM sodium phosphate. To determine uptake rates, aliquots (80 µl)of the reaction mixture were withdrawn, immediately placed onprewashed mixed-ester filters, and washed and processed as describedfor the ascorbate-PMS-energizedsystem.

Membrane phase transition temperature. Membrane phase transition temperatures were measured by Fourier transform infrared (FTIR) spectroscopy (4). Membranes werecollected by centrifugation (30 min, 48,000 × g, 4°C) and resuspendedto a level of approximately 30 mg of protein per ml in 50 mM potassiumphosphate buffer, pH 7.0, containing 10 mM MgSO₄ and with solutesat concentrations indicated in the figure legends. A 30-µl aliquotof the membrane suspension was then placed between glass platesand then inserted into a temperature controller. The CH₂ symmetricstretching frequency (within the wave number range of 2,850 to2,854 cm¹) at different temperatures was then measured using a Perkin-Elmer1750 Fourier-Transform InfraredSpectrometer.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Vesicle preparation methodology. Glycine betaine transport activity could be demonstrated upon energization by the ascorbate-PMS electron donor system in vesiclesderived from cells grown in tryptose broth supplemented with 281g of sucrose per liter and prepared as described in Materialsand Methods. Activity also was apparent in vesicles prepared usingconventional methods for mesophilic gram-positive bacteria (e.g.,see references 10 and 22) or methods originally used for gram-negativebacteria (13, 27) and modified (EDTA treatment omitted, lysintreatment optimized) for L. monocytogenes. Transport activitywas, however, extremely variable in preparations using the methodfor L. monocytogenes described previously (10); uptake ratesranged from 20 to 70% of those consistently obtainable using theprocedure described in this work. Furthermore, membrane yieldswere also approximately fourfold greater using the methodologydescribed in the present work. In the absence of large amountsof sodium ion in the assay mixtures, transport activity couldnot be demonstrated in vesicles prepared from cells grown underconditions of osmotic stress mediated by either NaCl or KCl insteadofsucrose.

Energetics of transport. The use of ionophores can result in inhibition of ABC-type transporters, either by direct inhibition of the permease or byindirect inhibition due to effects on internal pH. We thereforechose instead to investigate the porter's energetics through intravesicularincorporation of ortho-vanadate and ATP and through the use ofartificial chemical gradients to selectively generate componentsof the proton motive and sodium motive forces. Vesicles preparedby lysis of protoplasts in hypotonic potassium phosphate buffercontaining 1 mM sodium ortho-vanadate had uptake rates approximatelyone-fifth of those prepared in the absence of ortho-vanadate (Fig.1), while lysis in the same buffer containing 5 mM ATP enhanceduptake rates by approximately one-third. Uptake was dependenton addition of ascorbate-PMS.

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FIG. 1. Energetics of transport: enhancement and inhibition of ATP-dependent glycine betaine transport activity in membrane vesicles of L. monocytogenes. ATP and sodium ortho-vanadate were loaded into vesicles during the membrane purification procedure by addition of the compounds to the lysis buffer. The vesicles were stressed with 600 mOsm (506 mM) sucrose at pH 7 and energized with ascorbate-PMS as described in Materials and Methods. Symbols:

, no additions; $open circle$ , no additions, unenergized (PMS omitted); $black-triangle$ , 5 mM ATP; $black-down-triangle$ , 1 mM sodium ortho-vanadate. (Inset) Artificial gradient-driven uptake of 20 mM [¹⁴C]glycine betaine into membrane vesicles of L. monocytogenes. Vesicles were loaded and gradients were imposed at pH 6.0 and 30°C as described in Materials and Methods. Symbols:

, $Delta$ µ_Na⁺/F and $Delta$ P;

, $Delta$ µ_Na⁺/F and $Delta$ $Psi$ ; $black-down-triangle$ , $Delta$ µ_Na⁺/F and $Delta$ pH; $black-triangle$ , $Delta$ µ_Na⁺/F; $open circle$ , $Delta$ P;

, $Delta$ $Psi$ ; $down-triangle$ , $Delta$ pH; $triangle$ , control (osmotic gradient alone).

Artificial gradient-driven transport of glycine betaine in the presence of high concentrations of Na⁺ has been previously demonstrated for glycine betaine porter I(10). Under conditions of energization provided by acetate andvalinomycin-mediated potassium diffusion potentials (Fig. 1, inset),uptake was rapid in the presence of both sodium and a proton motiveforce, $Delta$ P (closed circles), or sodium and a charge gradient, $Delta$ $Psi$ (closed squares). Uptake was apparent but low in the presenceof $Delta$ P or $Delta$ $Psi$ alone. The results show that the vesicles are electrochemicallyrobust because glycine betaine can be taken up by glycine betaineporter I, a sodium-driven porter having low affinity for sodiumion. However, glycine betaine transport by Na⁺-independent glycine betaine porter II is slow under conditionsthat would directly energize a porter that uses H⁺ as the coupling ion. $Delta$ P or $Delta$ $Psi$ alone is able to support only alow level of activity, suggesting that energization occurred throughan indirectmechanism.

ATP production by vesicles. ATP levels in PMS-ascorbate-energized vesicles, vesicles containing 2 µM carbonyl cyanide m-chlorophenylhydrazone (CCCP),and unenergized controls were determined under osmotic stressprovided by sucrose (data not shown). ATP was found to be presentat a level of 0.4 nmol/mg of protein in unenergized controls,CCCP-treated vesicles, and energized vesicles at time zero. Uponaddition of ascorbate-PMS, the ATP level increased to 1.4 nmol/mgof protein after 5 min; CCCP-treated vesicles did not show ATPsynthesis, nor did unenergized vesicles. These data are similarto those obtained with Escherichia coli by Prossnitz et al. (27),who termed the basal level of ATP in unenergized vesicles "notaccessible for energizing transport," suggesting it to be boundor sequestered. Our result demonstrates that there is sufficientADP and phosphate in the vesicles for the production of ATP andthat the machinery for doing so operates under the conditionsunder which transport isobserved.

Osmotic activation of the permease. Glycine betaine porter II, like glycine betaine porter I, is osmotically activated. Glycine betaine was taken up by glycinebetaine porter II at a high rate under hypertonic conditions (Fig.2). Uptake was completely dependent on energization by the exogenousenergy source ascorbate and PMS. Uptake under energized conditionswas very low (<2 pmol/min · mg of protein) at 30°C in the absenceof hypertonic stress but could be activated by over 1,000-foldin the presence of a hypertonic solute gradient. The system showedmaximal activation at an osmotic pressure of 600 mOsm for eitherpotassium chloride or sucrose (Fig. 2). The dependence of transporton osmotic strength was similar for KCl and sucrose, and activitydecreased rapidly above the osmotic optimum. Activity was approximately50% higher in the presence of a sucrose gradient than in the presenceof a KCl gradient at 30°C, where sucrose-mediated activation wasoptimal. In vesicles derived from strain LTG59, in which the gbugenes are disrupted by a transposon insertion, uptake was notobserved below an osmotic pressure of 600 mOsm mediated by eithersucrose or KCl; at 600 mOsm, activity of the LTG59-derived vesicleswas less than 2% of that observed at maximal activation of vesiclesderived from strain DP-L1044, which bears the same transposonat an unrelated site.

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FIG. 2. Osmotic activation of glycine betaine uptake in membrane vesicles of L. monocytogenes. Systems were supplemented with either KCl or sucrose to provide osmotic pressures at the levels indicated. Vesicles were energized with ascorbate-PMS at pH 7 as described in Materials and Methods. Strain DP-L1044 (gbu⁺) was tested with KCl (

) or sucrose ( $black-triangle$ ). Strain LTG59 (gbu) was also tested with KCl ( $open circle$ ) or sucrose ( $triangle$ ).

A kinetic analysis of glycine betaine uptake was carried out under conditions of optimal osmotic activation by sucrose andKCl at 30°C. The initial rate of glycine betaine uptake withinthe concentration range of 1.0 to 20.0 µM yielded Michaelis constants(Table 1) for glycine betaine of 2.9 and 1.2 µM with activationby sucrose and KCl, respectively. Values of V_max under these conditionswere predicted to be 3,700 and 2,200 pmol/mg of protein · min,respectively.

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TABLE 1. Kinetics of osmotic-gradient- and cold-activated glycine betaine transport^a

Temperature influence on osmotic activation. The effect of temperature under conditions of optimal osmotic activation was examined. Interestingly, activity was optimalat 30°C (the temperature at which the culture was grown) underhypertonic conditions mediated by sucrose, while activation underhypertonic conditions mediated by KCl was optimal at 20°C (Fig.3A). Because of the difference in temperature optima, KCl-elicitedactivities were higher than those of sucrose at temperatures below20°C; the opposite effect was true at temperatures above 20°C.A sharp decrease in glycine betaine uptake rates in the presenceof either sucrose or KCl was observed with increasing temperatureabove 30°C.

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FIG. 3. Effect of temperature on glycine betaine uptake under conditions of optimal osmotic activation. (A) Effect of temperature on uptake in the presence of 600 mOsm KCl (

) or sucrose (

). Vesicles were energized with ascorbate-PMS at pH 7 as described in Materials and Methods. (B) Arrhenius plot of data from panel A within the temperature range of 4 to 30°C. Symbols:

, 600 mOsm KCl;

, 600 mOsm sucrose. Arrows indicate temperatures corresponding to discontinuities in lines.

When the temperature dependence data (Fig. 3A) are presented as Arrhenius plots (Fig. 3B), data derived from either the sucroseor the KCl curves exhibit three distinct phases. Sharp breaksoccur at about 10 and 18°C. Activation energies (E_a) for the permeaseare not solute dependent below 20°C, as slopes are parallel, andboth the KCl- and sucrose-activated systems have E_a of about 48kcal/mol below and E_a of about 18 kcal/mol above the 10°C breaks(Table 2). Between 18°C and its optimum temperature of 30°C,under conditions of osmotic activation by sucrose, the systemcontinues to show temperature activation consistent with the Arrheniusequation whereas activity in the KCl-mediated system shows decreasingactivity. The fact that the temperature dependence of transportbelow 18°C is independent of the nature of the solute suggeststhat the membrane plays an important role in determining the rateof transport.

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TABLE 2. Effect of transport-activating conditions on energies of activation for the rate of transport of glycine betaine in L. monocytogenes membrane vesicles^a

Measurement of membrane order. Membrane phase transitions can be determined by changes in the vibrational frequency of the CH₂ bands in membrane phospholipids.Analysis of the CH₂ symmetric stretch band in FTIR spectra revealeda broad membrane lipid phase transition (Fig. 4A). The lower boundaryof the phase transition is 0°C, and the upper boundary is 29°C.The addition of sucrose or KCl to 600 mOsm had no apparent effecton the phase transition temperature. When lipid phase transitiondata obtained in the presence of either 600 mOsm sucrose or 600mOsm KCl are analyzed by means of Arrhenius curves depicting thedegree of membrane ordering (log percent maximum wave number versusinverse absolute temperature) (Fig. 4B), a very strong correlationis revealed. Two distinct breaks are evident in the plot, suggestinga triphasic phase transition in the membrane. In the presenceof either solute, breaks are observed at about 10 and 18°C. Thereis thus a close correlation between the phase of the L. monocytogenesmembrane and permease activity in the presence of either sucroseor KCl at 600 mOsm. Results summarizing predicted phase transitionsas measured by solute gradient-mediated enzymatic activity andFTIR spectroscopy are presented in Table 3. These results showthe dependence of porter activity on membrane order.

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FIG. 4. Effect of temperature on L. monocytogenes membrane order. Vibrational frequencies of CH₂ symmetric stretch bands in membrane vesicles of L. monocytogenes as measured by FTIR spectroscopy are shown. (A) Effect of temperature on CH₂ symmetric stretching frequency. A higher wave number signifies a more disordered state. Membranes were tested in 600 mOsm KCl (

), in 600 mOsm sucrose (

), or without added solutes ( $triangle$ ). (B) Arrhenius plot of data in panel A. The log percentage of the maximum wave number versus the inverse of the absolute temperature in systems containing KCl and sucrose is shown. Membranes were tested in 600 mOsm KCl (

) or 600 mOsm sucrose (

). Temperatures at discontinuities in the lines are noted; arrows at 29.0 and 0.1°C mark the ends of the phase transitions.

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TABLE 3. Predicted values of phase transitions in L. monocytogenes membrane vesicles as measured by solute gradient-mediated enzymatic activity and FTIR spectroscopy^a

Temperature influence in the absence of osmotic activation. In whole cells of L. monocytogenes, transport of glycine betaine has been shown to be stimulated by low temperature (16)in the absence of osmotic stress. In membrane vesicles energizedby ascorbate-PMS, glycine betaine transport was clearly stimulatedby decreasing temperature within the range of 15 to 4°C (Fig.5A). Transport could be stimulated approximately sevenfold withinthis range but was very low or undetectable above 10°C and fellto approximately 50% of the maximal value at 1°C. Uptake ratesin the presence of 20 mM ascorbate and 200 µM PMS reached approximately28 pmol/mg of protein · min. As in the case for osmotic activation,this effect is energy dependent, as transport at low temperaturecould not be observed in the absence of the electron donor system(open circles), nor was this activity apparent in energized vesiclesprepared from strain LTG59, which lacks gbu (closed squares).When these data are presented as Arrhenius plots (Fig. 5B), apositive slope is obtained within the temperature range of 4 to15°C, resulting in a calculated apparent negative activation energyof $-$ 27.5 kcal/mol. A kinetic analysis of chill-activated glycinebetaine uptake conducted within the range of 1.0 to 30.0 µM glycinebetaine yielded a Michaelis constant (Table 1) for glycine betaineof 16 µM and a V_max value of 28.1 pmol/mg of protein · min.

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FIG. 5. Chill activation of glycine betaine transport. Vesicles were assayed without osmotic stress at pH 7.0 as described in Materials and Methods. Vesicles prepared from strain DP-L1044 (gbu⁺) were tested with (

) or without ( $open circle$ ) energization by addition of PMS; vesicles prepared from strain LTG59 (gbu) were energized by addition of 200 µM PMS (

). The inset shows an Arrhenius plot of the transport rate in energized vesicles without osmotic stress between 4 and 20°C.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Transport activity by the putative L. monocytogenes ATP-driven glycine betaine porter encoded by gbu (glycine betaine porterII) can be effectively recovered and studied as an isolated systemin membrane vesicles derived from cells grown in tryptose brothsupplemented with sucrose. This Na⁺-independent activity likely is the result of retention by vesiclesof a cytoplasmic constituent (presumably ADP), allowing in situgeneration of ATP and the concomitant transport of substrates.Such a system has previously been demonstrated for the histidinepermease of Salmonella enterica serovar Typhimurium(27) usingvesicles prepared essentially as described for this system. Koand Smith have sequenced the gbu open reading frame (17), andthe deduced amino acid sequences were found to have high homologyto components of the OpuA glycine betaine permease of Bacillussubtilis (14, 15). In whole-cell studies in our laboratory,we have shown this porter to be osmotically activated and responsiblefor cold-activated glycine betainetransport.

Initial experiments utilizing ionophores provided little information on the nature of system energetics (Fig. 1). Experimentsemploying artificial gradients were used to determine whetherbetaine transport by this porter could be driven directly by transmembranegradients. Only very low levels of transport were observed (Fig.1, inset, open circles and squares). To assess the significanceof these low levels of transport, transport by a genuine $Delta$ $Psi$ -drivenporter, glycine betaine porter I (10), was measured as a positivecontrol. This activity required Na⁺ (the coupling ion for this symporter) in the assay mixture inaddition to the other components of energization. Substantialtransport (Fig. 1, inset, closed circles and squares) was catalyzedby porter I under these conditions, which is consistent with thedata reported in reference 10. This result strongly suggeststhat the potentials we provided would be adequate to drive porterII if it were directly powered by $Delta$ $Psi$ or $Delta$ P. Our conclusion wasthat porter II cannot be driven directly by gradients. It wouldbe expected that $Delta$ P should drive ATP formation, which should,in turn, drive porter II, as is the case for energization by ascorbate-PMS.However, it might also be expected that ascorbate-PMS is capableof generating a larger pool of ATP and is therefore much moreefficient at driving porter II, albeit indirectly, than are artificialgradients.

If transport by the permease is ATP dependent, manipulation of conditions not affecting components of $Delta$ P but affecting eitherthe intravesicular ATP pool or the permease directly should influencetransport rates. Preliminary evidence that a $Delta$ P drives transportindirectly was shown by inhibition of the F₀F₁ ATPase, as glycinebetaine uptake rates decreased approximately 50% in the presenceof 100 µM N,N'-dicyclohexylcarbodiimide (data not shown). Theresults illustrated in Fig. 1 show a clear sensitivity to 1 mMsodium ortho-vanadate and clear stimulation by 5 mM ATP (providedduring vesicle formation). In addition, direct measurement ofATP production corresponded well with the observation of transportafter energization with ascorbate-PMS. The biochemical evidencepresented in this study is therefore in complete agreement withthe genetic evidence available (17). If glycine betaine is nottaken up via an ATP-dependent transporter, the system should remaininsensitive to ortho-vanadate, a potent inhibitor of both P-typeATPases and binding protein-dependent transporters (8), andincorporation of ATP into the intravesicular space also shouldhave no significant effect on the glycine betaine uptakerate.

At 30°C, glycine betaine is taken up at a high rate only in the presence of a hypertonic solute gradient (Fig. 2). Uptakein the absence of added sodium ion was completely energy dependent,as uptake was not observed when PMS was omitted from assay mixtures(Fig. 1). Interestingly, no downhill efflux of glycine betainealong its concentration gradient was observed, indicating thatthis carrier, unlike glycine betaine porter I, is not capableof mediating influx in the absence of an energy source. Such alack of influx is consistent with evidence provided by severalgroups that hydrolysis of ATP is a required step in substratetransport by ABC-type porters (12).

Uptake was also dependent on the presence of the gbu gene product, since in the presence of solute gradients of either sucroseor KCl, uptake was practically nil in fully energized membraneslacking Gbu. This experiment shows that although glycine betaineporter I is clearly present and active in these vesicles, porterII-dependent transport can be studied in isolation under conditionsof optimal osmotic activation if Na⁺ is withheld. While sucrose appears to be a better osmotic activatorof the permease than does KCl, this effect is dependent on assaytemperature. The identity of the stressing solute also influencesthe affinity for glycine betaine (Table 1).

In the presence of a 600 mOsm hypertonic solute gradient, several kinetic parameters of glycine betaine transport are influencedboth by the temperature and by the stressing solute (Fig. 3A).For example, the temperature optimum for activation by sucroseoccurred at 30°C but maximal activation produced by KCl occurredat 20°C. Arrhenius plots of the data (Fig. 3B) show discontinuities(corresponding to changes in E_a) at about 18°C for both the sucroseand KCl systems. These discontinuities correlate very well withdiscontinuities in membrane order observed by FTIR spectroscopyat about 18°C in systems containing either sucrose or KCl at 600mosM. A second region correlating breaks in enzymatic activityand membrane order is apparent at 10°C.

The temperature dependence data suggest that transport is influenced by both the physical state of the membrane and the natureof the stressing solute between 4 and 18°C. The slopes of theactivity curves are parallel, and the calculated activation energiesare indistinguishable within this range. Above 18°C, the stateof the membrane is no longer the dominant influence on the activationof glycine betaine porter II and the species of the stressingsolute has a strong influence on reaction velocity, possibly bydirect action on the permease. Responses of permeases to changesin lipid fluidity are quite diverse and do not necessarily alwayscorrelate positively (1). Clearly, the activity of glycinebetaine porter II is not influenced by lipid fluidity within thetemperature range of 20 to 30°C.

In the absence of a solute gradient, permease activity is maximal at 4°C and is barely measurable above 15°C (Fig. 5). Elevatedtransport activity appears to correlate with the discontinuityin membrane phase order observed at 10°C, and activity exhibitsa linear positive Arrhenius slope within the decreasing temperaturerange of 15 to 4°C (Fig. 5, inset). An apparent negative activationenergy is typically observed in enzyme-catalyzed reactions attemperatures sufficiently high to denature the enzyme. While,in this case, the permease is not denatured between 4 and 15°C,it is certainly reasonable to ascribe the decrease in activitywith increasing temperature to the reverse of an activation process.The mechanism of activation remains obscure, but activation couldresult from a temperature-dependent change in the lipid compositionof the fluid portion of the membrane. As higher-melting-pointlipids crystallize out into the gel phase at lower temperatures,the fluid portion of the membrane would become enriched in thelower-melting-point lipid components which might solvate the permeasedifferently than would the complete mixture of lipids in the membrane.The concentration of a specific annular lipid might also be increasedto a critical level by this mechanism. A change in the topologyof the membrane at lower temperatures is also a possible mechanismof activation. The suggestion that one or more of the proteincomponents of the permease might spontaneously undergo a conformationalchange seems unlikely in view of the correspondence between activityand lipid order (Fig. 3B and 4B). Likewise, involvement of additionalsoluble components seemsunlikely.

The chill activation of glycine betaine transport exhibits a maximum at 4°C, rather than continuing to increase, despite thefact that the membrane phase transition reaches completion atabout 0°C (by extrapolation of the data in Fig. 4A). Under hyperosmoticconditions, the permease follows the Arrhenius equation, withan activation energy of ~48 kcal/mol over this temperature rangewhen maximally activated by either KCl or sucrose (Table 2 andFig. 3B). Therefore, the enzyme is expected to catalyze the reactionfaster at 4°C than at 1°C, providing that it is in an active state.The decreasing transport rate between 4 and 1°C could simply correspondto normal Arrhenius behavior rather than a decrease in the populationof active permease molecules. However, it is also possible thatthe transport rate decrease in this temperature range resultsfrom a decrease in activation. For instance, the system may requirea certain concentration of a specific annular lipid, the concentrationof which in the liquid-crystalline state may be optimal at 4°C.Alternatively, the effect may be due to the collapse in the energeticsof the system (decreased F₀F₁ ATPasefunction).

Muench et al. (21) have proposed a general model that could produce an apparent negative activation energy in microbiologicalsystems. This model ascribes the effect to a three-state (two-step)process consisting of a membrane lipid phase transition from theliquid-crystal state to the gel state, followed by an irreversiblemetabolic reaction (involving a membrane-bound enzyme) which isthe consequence of that phase transition. The ABC transporterscatalyze essentially irreversible vectorial reactions (18) andhave not been found to be capable of mediating both uptake andefflux of substrates (12). Unidirectional catalysis by a trafficATPase would satisfy the second condition for the phenomenon ofnon-Arrheniusactivation.

Activation of glycine betaine porter II is dependent on the presence of a solute gradient or the presence of low temperature,two seemingly different modes of activation. Our results furthersuggest that the physical state of the membrane determines permeaseactivity. At 4°C, glycine betaine porter II activity is only approximatelyfivefold higher in the presence of 600 mOsm sucrose than in itsabsence, suggesting that forces mediated by the two seeminglydifferent activating phenomena acting on the porter are comparablein magnitude. It therefore seems possible, or perhaps even likely,that the porter is acted on by the same or a similar mechanism,a mechanism likely determined by specific interactions with membranecomponents. We are currently investigating mechanisms by whichthe physical state of the membrane alters glycine betaine porterIIfunction.

	ACKNOWLEDGMENTS

We thank John Crowe for the use of the FTIR spectrometer, Martin Privalsky for the use of the luminometer, and Patrick Fitzgeraldfor technicalassistance.

This work was supported by USDA grant9601744.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Food Science and Technology, University of California, Davis, CA 95616.Phone: (530) 752-6168. Fax: (530) 752-4759. E-mail: gmsmith{at}ucdavis.edu.

Present address: The National Food Laboratory, Inc., Dublin,Calif.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Benga, G. 1985. Structure and properties of cell membranes: molecular basis of selected transport systems, vol. II. CRC Press, Inc., Boca Raton, Fla.

2. Cayley, S., B. A. Lewis, and J. M. T. Record. 1992. Origins of the osmoprotective properties of betaine and proline in Escherichia coli K-12. J. Bacteriol. 174:1586-1595[Abstract/Free Full Text].

3. Cole, M., M. Jones, and C. Holyoak. 1990. The effect of pH, salt concentration, and temperature on the survival and growth of Listeria monocytogenes. J. Appl. Bacteriol. 69:63-72[Medline].

4. Crowe, J. H., F. A. Hoekstra, L. M. Crowe, T. J. Anchordoguy, and E. Drobnis. 1989. Lipid phase transitions measured in intact cells with Fourier transform infrared spectroscopy. Cryobiology 26:76-84[CrossRef][Medline].

5. Csonka, L. N., and A. D. Hanson. 1991. Prokaryotic osmoregulation, genetics, and physiology. Annu. Rev. Microbiol. 45:569-606[CrossRef][Medline].

6. Doyle, M. P. 1988. Effect of environmental and processing conditions on Listeria monocytogenes. Food Technol. 42:169-171.

7. Farber, J. M., and P. I. Peterkin. 1991. Listeria monocytogenes, a food-borne pathogen. Microbiol. Rev. 55:476-511[Abstract/Free Full Text].

8. Forward, J. A., M. C. Behrendt, N. R. Wyborn, R. Cross, and D. J. Kelly. 1997. TRAP transporters: a new family of periplasmic solute transport systems encoded by the dctPQM genes of Rhodobacter capsulatus and by homologs in diverse gram-negative bacteria. J. Bacteriol. 179:5482-5493[Abstract/Free Full Text].

9. Galinski, E. A., M. Stein, B. Amendt, and M. Kinder. 1997. The kosmotropic (structure-forming) effect of compensatory solutes. Compr. Biochem. Physiol. 117A:357-365[CrossRef].

10. Gerhardt, P. N. M., L. T. Smith, and G. M. Smith. 1996. Sodium-driven, osmotically activated glycine betaine transport in Listeria monocytogenes membrane vesicles. J. Bacteriol. 178:6105-6109[Abstract/Free Full Text].

11. Glaasker, E., W. N. Konings, and B. Poolman. 1996. Glycine betaine fluxes in Lactobacillus plantarum during osmostasis and hyper- and hypo-osmotic shock. J. Biol. Chem. 271:10060-10065[Abstract/Free Full Text].

12. Higgins, C. F. 1992. ABC transporters: from microorganisms to man. Annu. Rev. Cell Biol. 8:67-113[CrossRef].

13. Kaback, H. R. 1971. Bacterial membranes. Methods Enzymol. 22:99-120.

14. Kappes, R. M., B. Kempf, and E. Bremer. 1996. Three transport systems for the osmoprotectant glycine betaine operate in Bacillus subtilis: characterization of OpuD. J. Bacteriol. 178:5071-5079[Abstract/Free Full Text].

15. Kempf, B., J. Gade, and E. Bremer. 1997. Lipoprotein from the osmoregulated ABC transport system OpuA of Bacillus subtilis: purification of the glycine betaine binding protein and characterization of a functional lipidless mutant. J. Bacteriol. 179:6213-6220[Abstract/Free Full Text].

16. Ko, R., L. T. Smith, and G. M. Smith. 1994. Glycine betaine confers enhanced osmotolerance and cryotolerance on Listeria monocytogenes. J. Bacteriol. 176:426-431[Abstract/Free Full Text].

17. Ko, R., and L. T. Smith. 1999. Identification of an ATP-driven, osmoregulated glycine betaine transport system in Listeria monocytogenes. Appl. Environ. Microbiol. 65:4040-4048[Abstract/Free Full Text].

18. Konings, W. N., W. de Vrij, A. J. M. Driessen, and B. Poolman. 1987. Primary and secondary transport in gram positive bacteria, p. 270-294. In J. Reizer, and A. Peterkofsky (ed.), Sugar transport and metabolism in gram positive bacteria. John Wiley & Sons, Inc., New York, N.Y.

19. Landfald, B., and A. R. Strøm. 1986. Choline-glycine betaine pathway confers a high level of osmotic tolerance in Escherichia coli. J. Bacteriol. 165:849-855[Abstract/Free Full Text].

20. Lucht, J. M., and E. Bremer. 1994. Adaptation of Escherichia coli to high osmolarity environments: osmoregulation of the high-affinity glycine betaine transport system ProU. FEMS Microbiol. Rev. 14:3-20[CrossRef][Medline].

21. Muench, J. L., J. Kruuv, and J. R. Lepock. 1996. A two-step reversible-irreversible model can account for a negative activation energy in an Arrhenius plot. Cryobiology 33:253-259[CrossRef][Medline].

22. Otto, R., R. G. Lageveen, H. Veldkamp, and W. N. Konings. 1982. Lactate efflux-induced electrical potential in membrane vesicles of Streptococcus cremoris. J. Bacteriol. 149:733-738[Abstract/Free Full Text].

23. Patchett, R. A., A. F. Kelly, and R. G. Kroll. 1992. Effect of sodium chloride on the intracellular solute pools of Listeria monocytogenes. Appl. Environ. Microbiol. 58:3959-3963[Abstract/Free Full Text].

24. Pearson, L. J., and E. H. Marth. 1990. Listeria monocytogenes $---$ threat to a safe food supply. J. Dairy Sci. 73:912-928[Abstract].

25. Peter, H., A. Burkovski, and R. Kraemer. 1996. Isolation, characterization, and expression of the Corynebacterium glutamicum betP gene, encoding the transport system for the compatible solute glycine betaine. J. Bacteriol. 178:5229-5234[Abstract/Free Full Text].

26. Pourkomailian, B., and I. R. Booth. 1992. Glycine betaine transport by Staphylococcus aureus: evidence for two transport systems and for their possible roles in osmoregulation. J. Gen. Microbiol. 138:2515-2518[Medline].

27. Prossnitz, E., A. Gee, and G. F-L. Ames. 1989. Reconstitution of the histidine periplasmic transport system in membrane vesicles. J. Biol. Chem. 264:5006-5014[Abstract/Free Full Text].

28. Smith, P. K., R. I. Krohn, G. T. Hermanson, A. K. Mallia, F. H. Gartner, M. D. Provenzano, E. K. Fujimoto, N. M. Goeke, B. J. Olson, and D. C. Klenk. 1985. Measurement of protein using bicinchoninic acid. Anal. Biochem. 150:76-85[CrossRef][Medline].

29. Sun, A. N., A. Camilli, and D. A. Portnoy. 1990. Isolation of Listeria monocytogenes small-plaque mutants defective for intracellular growth and cell-to-cell spread. Infect. Immun. 58:3770-3778[Abstract/Free Full Text].

30. Walker, S. J., P. Archer, and J. G. Banks. 1990. Growth of Listeria monocytogenes at refrigeration temperatures. J. Appl. Bacteriol. 68:157-162[Medline].

31. Weis, J. 1974. Listerienfunde bei heimischen Wildtiere. Fortschr. Veterinaermed. 20:240-244.

32. Weis, J., and H. P. R. Seeliger. 1975. Incidence of Listeria monocytogenes in nature. Appl. Microbiol. 95:29-32.

33. Wolf, A. V., M. G. Brown, and P. G. Prentiss. 1985. Concentrative properties of aqueous solutions: conversion tables, p. D-219-D-296. In R. C. Weast (ed.), CRC handbook of chemistry and physics, 66th ed. CRC Press, Inc., Boca Raton, Fla.

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	ALL ASM JOURNALS

1.	Benga, G. 1985. Structure and properties of cell membranes: molecular basis of selected transport systems, vol. II. CRC Press, Inc., Boca Raton, Fla.
2.	Cayley, S., B. A. Lewis, and J. M. T. Record. 1992. Origins of the osmoprotective properties of betaine and proline in Escherichia coli K-12. J. Bacteriol. 174:1586-1595[Abstract/Free Full Text].
3.	Cole, M., M. Jones, and C. Holyoak. 1990. The effect of pH, salt concentration, and temperature on the survival and growth of Listeria monocytogenes. J. Appl. Bacteriol. 69:63-72[Medline].
4.	Crowe, J. H., F. A. Hoekstra, L. M. Crowe, T. J. Anchordoguy, and E. Drobnis. 1989. Lipid phase transitions measured in intact cells with Fourier transform infrared spectroscopy. Cryobiology 26:76-84[CrossRef][Medline].
5.	Csonka, L. N., and A. D. Hanson. 1991. Prokaryotic osmoregulation, genetics, and physiology. Annu. Rev. Microbiol. 45:569-606[CrossRef][Medline].
6.	Doyle, M. P. 1988. Effect of environmental and processing conditions on Listeria monocytogenes. Food Technol. 42:169-171.
7.	Farber, J. M., and P. I. Peterkin. 1991. Listeria monocytogenes, a food-borne pathogen. Microbiol. Rev. 55:476-511[Abstract/Free Full Text].
8.	Forward, J. A., M. C. Behrendt, N. R. Wyborn, R. Cross, and D. J. Kelly. 1997. TRAP transporters: a new family of periplasmic solute transport systems encoded by the dctPQM genes of Rhodobacter capsulatus and by homologs in diverse gram-negative bacteria. J. Bacteriol. 179:5482-5493[Abstract/Free Full Text].
9.	Galinski, E. A., M. Stein, B. Amendt, and M. Kinder. 1997. The kosmotropic (structure-forming) effect of compensatory solutes. Compr. Biochem. Physiol. 117A:357-365[CrossRef].
10.	Gerhardt, P. N. M., L. T. Smith, and G. M. Smith. 1996. Sodium-driven, osmotically activated glycine betaine transport in Listeria monocytogenes membrane vesicles. J. Bacteriol. 178:6105-6109[Abstract/Free Full Text].
11.	Glaasker, E., W. N. Konings, and B. Poolman. 1996. Glycine betaine fluxes in Lactobacillus plantarum during osmostasis and hyper- and hypo-osmotic shock. J. Biol. Chem. 271:10060-10065[Abstract/Free Full Text].
12.	Higgins, C. F. 1992. ABC transporters: from microorganisms to man. Annu. Rev. Cell Biol. 8:67-113[CrossRef].
13.	Kaback, H. R. 1971. Bacterial membranes. Methods Enzymol. 22:99-120.
14.	Kappes, R. M., B. Kempf, and E. Bremer. 1996. Three transport systems for the osmoprotectant glycine betaine operate in Bacillus subtilis: characterization of OpuD. J. Bacteriol. 178:5071-5079[Abstract/Free Full Text].
15.	Kempf, B., J. Gade, and E. Bremer. 1997. Lipoprotein from the osmoregulated ABC transport system OpuA of Bacillus subtilis: purification of the glycine betaine binding protein and characterization of a functional lipidless mutant. J. Bacteriol. 179:6213-6220[Abstract/Free Full Text].
16.	Ko, R., L. T. Smith, and G. M. Smith. 1994. Glycine betaine confers enhanced osmotolerance and cryotolerance on Listeria monocytogenes. J. Bacteriol. 176:426-431[Abstract/Free Full Text].
17.	Ko, R., and L. T. Smith. 1999. Identification of an ATP-driven, osmoregulated glycine betaine transport system in Listeria monocytogenes. Appl. Environ. Microbiol. 65:4040-4048[Abstract/Free Full Text].
18.	Konings, W. N., W. de Vrij, A. J. M. Driessen, and B. Poolman. 1987. Primary and secondary transport in gram positive bacteria, p. 270-294. In J. Reizer, and A. Peterkofsky (ed.), Sugar transport and metabolism in gram positive bacteria. John Wiley & Sons, Inc., New York, N.Y.
19.	Landfald, B., and A. R. Strøm. 1986. Choline-glycine betaine pathway confers a high level of osmotic tolerance in Escherichia coli. J. Bacteriol. 165:849-855[Abstract/Free Full Text].
20.	Lucht, J. M., and E. Bremer. 1994. Adaptation of Escherichia coli to high osmolarity environments: osmoregulation of the high-affinity glycine betaine transport system ProU. FEMS Microbiol. Rev. 14:3-20[CrossRef][Medline].
21.	Muench, J. L., J. Kruuv, and J. R. Lepock. 1996. A two-step reversible-irreversible model can account for a negative activation energy in an Arrhenius plot. Cryobiology 33:253-259[CrossRef][Medline].
22.	Otto, R., R. G. Lageveen, H. Veldkamp, and W. N. Konings. 1982. Lactate efflux-induced electrical potential in membrane vesicles of Streptococcus cremoris. J. Bacteriol. 149:733-738[Abstract/Free Full Text].
23.	Patchett, R. A., A. F. Kelly, and R. G. Kroll. 1992. Effect of sodium chloride on the intracellular solute pools of Listeria monocytogenes. Appl. Environ. Microbiol. 58:3959-3963[Abstract/Free Full Text].
24.	Pearson, L. J., and E. H. Marth. 1990. Listeria monocytogenes $---$ threat to a safe food supply. J. Dairy Sci. 73:912-928[Abstract].
25.	Peter, H., A. Burkovski, and R. Kraemer. 1996. Isolation, characterization, and expression of the Corynebacterium glutamicum betP gene, encoding the transport system for the compatible solute glycine betaine. J. Bacteriol. 178:5229-5234[Abstract/Free Full Text].
26.	Pourkomailian, B., and I. R. Booth. 1992. Glycine betaine transport by Staphylococcus aureus: evidence for two transport systems and for their possible roles in osmoregulation. J. Gen. Microbiol. 138:2515-2518[Medline].
27.	Prossnitz, E., A. Gee, and G. F-L. Ames. 1989. Reconstitution of the histidine periplasmic transport system in membrane vesicles. J. Biol. Chem. 264:5006-5014[Abstract/Free Full Text].
28.	Smith, P. K., R. I. Krohn, G. T. Hermanson, A. K. Mallia, F. H. Gartner, M. D. Provenzano, E. K. Fujimoto, N. M. Goeke, B. J. Olson, and D. C. Klenk. 1985. Measurement of protein using bicinchoninic acid. Anal. Biochem. 150:76-85[CrossRef][Medline].
29.	Sun, A. N., A. Camilli, and D. A. Portnoy. 1990. Isolation of Listeria monocytogenes small-plaque mutants defective for intracellular growth and cell-to-cell spread. Infect. Immun. 58:3770-3778[Abstract/Free Full Text].
30.	Walker, S. J., P. Archer, and J. G. Banks. 1990. Growth of Listeria monocytogenes at refrigeration temperatures. J. Appl. Bacteriol. 68:157-162[Medline].
31.	Weis, J. 1974. Listerienfunde bei heimischen Wildtiere. Fortschr. Veterinaermed. 20:240-244.
32.	Weis, J., and H. P. R. Seeliger. 1975. Incidence of Listeria monocytogenes in nature. Appl. Microbiol. 95:29-32.
33.	Wolf, A. V., M. G. Brown, and P. G. Prentiss. 1985. Concentrative properties of aqueous solutions: conversion tables, p. D-219-D-296. In R. C. Weast (ed.), CRC handbook of chemistry and physics, 66th ed. CRC Press, Inc., Boca Raton, Fla.