Abstracts. Christian Chervaux

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Applied and Environmental Microbiology, December 2000, p. 5306-5311, Vol. 66, No. 12

Physiological Study of Lactobacillus delbrueckii subsp. bulgaricus Strains in a Novel Chemically Defined Medium

Christian Chervaux, S. Dusko Ehrlich, and Emmanuelle Maguin^*

Laboratoire de Génétique Microbienne, INRA, Domaine de Vilvert, 78352 Jouy-en-Josas Cedex, France

Received 10 May 2000/Accepted 22 September 2000

	ABSTRACT

We developed a chemically defined medium called milieu proche du lait (MPL), in which 22 Lactobacillus delbrueckii subsp.bulgaricus (L. bulgaricus) strains exhibited growth rates rangingfrom 0.55 to 1 h¹. MPL can also be used for cultivation of other lactobacilli and Streptococcus thermophilus. The growth characteristics of L. bulgaricusin MPL containing different carbon sources were determined, includingan initial characterization of the phosphotransferase system transportersinvolved. For the 22 tested strains, growth on lactose was fasterthan on glucose, mannose, and fructose. Lactose concentrations below 0.4% were limiting for growth. We isolated 2-deoxyglucose-resistantmutants from strains CNRZ397 and ATCC 11842. CNRZ397-derived mutantswere all deficient for glucose, fructose, and mannose utilization,indicating that these three sugars are probably transported via a unique mannose-specific-enzyme-II-like transporter. In contrast, mutants of ATCC 11842 exhibited diverse phenotypes, suggestingthat multiple transporters may exist in that strain. We also developeda protein labeling method and verified that exopolysaccharide production and phage infection can occur in MPL. The MPL medium should thus be useful in conducting physiological studies of L.bulgaricus and other lactic acid bacteria under well controllednutritionalconditions.

	INTRODUCTION

Lactobacillus delbrueckii subsp. bulgaricus (L. bulgaricus) and Streptococcus thermophilus are used in the dairy industry to transform milk into yogurt. However, despite the industrial interest in L. bulgaricus, little is known about its physiologyand genetics. A chemically defined medium (CDM) is a prerequisitefor physiological studies that allows experimentation under reproducibleconditions via the control of all nutrient sources. So far, of the three CDMs published for L. bulgaricus, two involve an agarose-solidifiedmedium (reference 22, as modified by reference 4 and T. Sasakiand Y. Sasaki, Abstr. Fifth Symp. Lactic Acid Bacteria, abstr.E16, 1996). The third CDM was developed for an L. bulgaricus strain (NCFB2772) which exhibited an anaerobic growth rate of around0.2 h¹; this rate is at least three times lower than growth rates inrich and complex media such as milk or MRS (12, 13). In viewof these drawbacks, we considered it necessary to develop a newCDM that would allow efficient growth of L. bulgaricus strains.This criterion was fulfilled by milieu proche du lait (MPL), sinceall L. bulgaricus strains tested (22 strains) grew in this mediumwith an average rate of 0.7 h¹ (corresponding to a doubling time of about 1h).

The composition of MPL allowed us to examine sugar utilization in L. bulgaricus. Previous genetic characterization of thelactose transport system showed that the LacS permease in L. bulgaricusbelongs to the galactose-pentose-hexuronides (GPH) family (23,30). However, little is known about the transport of glucose,mannose, and fructose, the other three sugars catabolized by L.bulgaricus. There are no reports concerning mannose and fructose,two sugars that are transported by the phosphotransferase system(PTS) in other lactic acid bacteria (25, 29, 34). Biochemicalstudies have indicated that glucose and its analogue, 2-deoxyglucose(2DG), are internalized via the PTS in some L. bulgaricus strains(14). The PTS catalyzes concomitant transport and phosphorylationof sugars via a specific membrane-localized enzyme II complex(EII) which is phosphorylated by the general PTS enzymes HPr andenzyme I (for a review, see reference 31). Characterizationof PTS transporters is of interest since (i) PTS sugars are oftenpreferred carbon sources, and (ii) PTS enzymes like HPr exertregulatory functions affecting the catabolism of other sugarsvia a control of transport and/or glycolytic activities (15, 31). EII^Man (mannose-specific EII) is able to transport mannose, fructose,glucose, and 2DG in Escherichia coli and gram-positive bacteria(20, 25, 31, 37) and is found in many lactic acid bacteria,such as Lactobacillus sakei, Lactobacillus casei, Lactobacilluspentosus, Lactobacillus plantarum, Lactobacillus curvatus, andLactococcus lactis (7, 35, 39, 40). It is therefore possiblethat glucose, mannose, and fructose are transported by an EII^Man homologue in L. bulgaricus.

In order to initiate the genetic characterization of PTS transporters, mutants resistant to 2DG were isolated. Transport of2DG via EII^Man leads to accumulation of phosphorylated 2DG, which is toxic forthe cell. Previous studies indicated that spontaneous 2DG-resistant mutants usually affect EII^Man-specific enzymes (10, 20, 36). We analyzed the phenotypesof mutants for their growth properties on various sugars in MPL.

Finally, to facilitate the use of MPL for various physiological studies, we developed a protocol to label neosynthesized proteinsand verified that phage infection and exopolysaccharide (EPS)production occur in thismedium.

	MATERIALS AND METHODS

Strains and culture conditions. L. bulgaricus strains used in this study were as follows: CNRZ208, which corresponds to the type strain ATCC 11842, CNRZ397,CNRZ1057, and 21 strains numbered from VI1001 to VI1021 whichare natural isolates of various origins (T. Smokvina, unpublisheddata). Other lactic acid bacteria strains used were L. delbrueckiisubsp. delbrueckii CNRZ225 and subsp. lactis CNRZ207, Lactobacillusacidophilus CNRZ204 and CNRZ462, Lactobacillus helveticus CNRZ223, Lactobacillus fermentum CNRZ209 and CNRZ236, Lactobacillus plantarumCNRZ211, Lactobacillus buchneri CNRZ214, Lactobacillus zeae ATCC393, formerly classified as Lactobacillus casei (8), Streptococcusthermophilus CNRZ1358 and IL73, and Leuconostoc mesenteroidesCNRZ1019. All CNRZ strains were provided by the INRA NationalCulture Collection (URLGA, Jouy-en-Josas, France). L. delbrueckii,L. acidophilus, L. fermentum, L. buchneri, and S. thermophilus cultures were incubated at 42°C, and L. plantarum, L. zeae, andL. mesenteroides were incubated at 30°C.

Liquid cultures were inoculated with dilutions (at least 100-fold) of (i) a fresh colony grown on MRS complex medium (Difco)plates and resuspended in 1 ml of medium or (ii) cells from afresh culture that were first washed in 0.9% NaCl. Growth wasestimated by measuring optical density at 600 nm (OD₆₀₀) and/orby serial dilution and plating. Growth kinetics measurements wereperformed using a microplate reader (Microbiology Reader BioscreenC; Labsystems). The culture volume was around 350 µl, and sampleswere overlaid with mineral oil to avoid aeration during shaking.For experiments in larger volumes (in which OD and pH were monitored), cultures were distributed into several tubes; each tube was usedfor one measurement to avoid aeration due tomixing.

Optimization of MPL component concentrations. Strain CNRZ397 was cultured in MPL containing various concentrations of one of the following components: thioglycolate, riboflavin,cobalamine, calcium chloride, or a mixture of four vitamins (folicacid, calcium pantothenate, niacin, and pyridoxal). Growth kineticswere followed using a microplate reader. The final concentrationused in MPL was higher (often 10-fold) than the concentrationleading to decreasedgrowth.

Phage infection. Phage 19 was propagated on MRS or MPL stationary-phase cultures of indicator strain L. bulgaricus CNRZ1057, using standardprocedures (1). The phage titer of each lysate was estimatedby spotting serial dilutions on a lawn of CNRZ1057 in MRS topagar supplemented with 10 mM CaCl₂.

Isolation and characterization of 2DG-resistant mutants. Bacteria were grown in MPL plus 2% lactose (MPL-lactose) to an OD₆₀₀ of 1.5, washed with MPL without sugar, and plated ontoMPL agar containing 0.1, 0.2, or 0.4% lactose and 2, 5, or 10mM 2DG. After 24 to 35 h of incubation at 42°C, colonies werepurified on MPL agar containing lactose and 2DG. Phenotypic testswere performed as follows: MPL-lactose cultures of the mutantswere serially diluted in 0.9% NaCl and spotted on MPL agar eithercontaining a 1% concentration of lactose, glucose, fructose, ormannose or without sugar (control). Growth of colonies was monitoredafter 24 to 96 h of incubation at 42°C.

Protein labeling. To favor [³⁵S]methionine ([³⁵S]Met) incorporation, we used MPL containing a limiting amount of methionine (40 µM), which allowsgrowth to a final OD₆₀₀ of 1. At an OD of about 0.7, 10 µCi of[³⁵S]methionine (ICN Pharmaceuticals, Inc., Irvine, Calif.) per mlwas added to the culture. After 2 to 30 min, the labeling wasinterrupted by the addition of 0.8 mM cold methionine and 1 volumeof ice-cold MPL. Cells were collected by centrifugation for 3min at 10,000 rpm and 4°C. The equivalent of 0.2 ml of culturewas resuspended in 32 µl of TES (50 mM Tris [pH 8], 5 mM EDTA,20% sucrose), lysozyme (0.2 mg/ml), and mutanolysin (100 U/ml;Sigma) and incubated for 2 min at 37°C. An 8-µl aliquot of 5×Laemmli buffer (19) was then added before a 5-min incubationat 95°C for lysis. Protein samples were analyzed by classicalsodium dodecyl sulfate-polyacrylamide gel electrophoresis (19)andautoradiography.

	RESULTS

MPL medium. (i) Design of MPL_R. Growth of L. bulgaricus CNRZ397 was tested in CDM, described in the literature (4, 20). As growth was poor (at best reachingan OD₆₀₀ of 0.8 after 24 h), even after addition of vitamins andCasamino Acids, we chose to develop another CDM, referred to asMPL_R (Table 1). This medium was designed using components presentin previously described CDMs as well as in milk. Concentrations of lactose, phosphate, calcium, potassium, sodium, citrate, chloride, and oleic acid (the major fatty acid in cow milk) were based onmilk composition (2, 22, 26). We used several componentspreviously reported as stimulatory for L. bulgaricus growth, i.e.,formate, pyruvate, acetate, ascorbic acid, and nucleic acid bases(18, 22). Tween 80 was used as a putative lipid source, althoughit can also act as a detergent. The reducing agent thioglycolatewas added, since our tests were not carried out under strict anaerobic conditions. Amino acids, bases, vitamins, and micronutrients were used according to concentrations previously described for various CDMs (Table 1). The resulting MPL_R comprised 60 components (Table1) and allowed the growth of CNRZ397 with an average doublingtime of 1 h and a final OD₆₀₀ of 2.

TABLE 1. Composition of the CDM

(ii) Simplification and optimization of the medium. Single-omission tests were carried out to reduce the number of medium constituents without affecting CNRZ397 growth; the finalmedium was called MPL (Table 1, column 3). Fourteen MPL_R componentswere not required, and 14 elements (i.e., thioglycolate, Tween80, acetate, phosphate, bases, 6 of 12 vitamins, magnesium, calcium,and micronutrients) were essential for efficient growth (Table1, compare columns 2 and 3). Nucleoside bases and the micronutrientmix were not individually tested at thisstage.

For eight of the "essential" compounds, concentrations affecting CNRZ397 growth were determined (Materials and Methods), andfinal optimal concentrations in MPL were adjusted accordingly.Moreover, acetate, iron, amino acid, and phosphate concentrationswere modified as described below. (i) Acetate was increased to75 mM, which allowed a higher growth yield. This is probably dueto an increased buffering capacity, since addition of anotherbuffer (morpholinoethanesulfonic acid [MES]) also increased theyield in the presence of 15 mM acetate. (ii) Elimination of manganeseor iron did not affect growth as long as calcium and micronutrientswere present. Therefore, we kept these elements but the amountof iron, which is potentially toxic, was reduced about 300 fold.(iii) Amino acid concentrations were modified according to CasaminoAcid composition (Table 1). (iv) Potassium phosphate was replacedby sodium phosphate (7.91 mM) and adjusted to obtain an initialmedium pH of 6.4.

All these modifications led to MPL, which contains 45 constituents including the 20 amino acids (Table 1) and allows thegrowth of CNRZ397 with a doubling time of about 70 min, with afinal OD₆₀₀ of 2 and pH of 4.2.

Lactic acid bacteria growth in MPL. Since MPL allowed rapid growth of CNRZ397, we tested 21 other strains of L. bulgaricus that belong to several randomly amplifiedpolymorphic DNA groups (E. M. Lim, personal communication). Growthkinetics measurements carried out in microplates showed that thedoubling times of these strains ranged from 40 to 75 min (mean,60 min). Final OD₆₀₀ values for batch cultures ranged between1.1 and 3 (mean, 2.4). Although the growth rates were only slightlylower in MPL than in MRS medium, the final OD in MPL was two tothree times lower than the OD inMRS.

Growth of several other lactic acid bacteria was also tested in modified MPL (with the vitamins of MPL_R) containing glucoseor lactose (Fig. 1). The tested strains of L. fermentum, L. mesenteroides,L. plantarum, L. buchneri, L. zeae, and S. thermophilus CNRZ1358grew well until the OD₆₀₀ reached 1 to 2.5. In contrast, S. thermophilusIL73 as well as L. delbrueckii subsp. lactis CNRZ207, L. delbrueckiisubsp. delbrueckii CNRZ225, L. helveticus CNRZ223, and L. acidophilusCNRZ204 and CNRZ462 did not grow in MPL or grew only poorly. Thesedata indicate that MPL is a suitable CDM not only for L. bulgaricusstrains but also for a wide range of other lactobacilli, includingL. fermentum, for which no CDM was previously available. Moreover,MPL may allow coculture of L. bulgaricus with at least some S.thermophilus strains and may thus be useful for concomitant physiologicalstudies of these two species, which are used together in yogurtproduction.

FIG. 1. Growth characteristics of various lactic acid bacteria in MPL. Fresh colonies obtained on MRS plates were inoculated in MPL containing a 2% concentration of either lactose or glucose and the 12 vitamins indicated in Table 1, column 2. OD₆₀₀ was measured after at least 48 h of incubation at either 42 or 30°C. The standard deviation is indicated when two independent experiments were performed.

Growth of L. bulgaricus on different carbohydrates. L. bulgaricus ferments lactose, glucose, fructose, and mannose (5, 12) and does not grow on galactose. The 22 L. bulgaricusstrains had a doubling time of about 1 h in MPL-lactose, comparedto 3 to 4 h in MPL containing 1% glucose (MPL-glucose). In both cases, cultures reached equivalent OD₆₀₀ levels after 24 to 48h of incubation at 42°C. Growth in MPL-mannose or -fructose was,for most of the tested strains, similar to that in MPL-glucose.This observation is surprising in view of the usual preferenceof bacteria for glucose, which is often transported via the PTS(15, 31). Galactose has been reported to accumulate in themedium after fermentation of the glucose moiety of lactose. To determine whether galactose accumulation might be responsiblefor the better growth on lactose, the effect of galactose on growthin MPL was tested. Supplementation of MPL-glucose (1%) with galactose (0.5 to 2%) did not modify growth, whereas addition of more than1% galactose in MPL-lactose (1%) reduced the growth rate and thefinal biomass of the cultures (Fig. 2). Thus, while galactosemay affect the efficiency of growth on lactose, it does not accountfor the growth differences observed between lactose and glucose.The efficiency of growth also depended on lactose concentration:we found that below 0.4% lactose, the growth rate was proportionalto the sugar concentration. Doubling time increased from 68 to 160 min when lactose concentration varied from 0.4 to 0.1% (datanot shown).

FIG. 2. Effect of various concentrations of galactose on CNRZ397 growth. Media were inoculated by diluting a preculture (1/100) into MPL-lactose (1%) (open circles) supplemented with galactose at 1% (triangles), 2% (squares), 3% (diamonds), or 4% (filled circles). Growth was followed using a microplate reader as described in Materials and Methods.

We also examined growth when both glucose and lactose were present (the concentration of each sugar was between 0.1 and 2%).The addition of glucose did not affect the growth rate on lactose.Moreover, no diauxic growth curve could be observed, suggestingthat both sugars are more probably simultaneously consumed (datanot shown). These results suggest that lactose catabolism is notunder catabolic repression by glucose in L. bulgaricus. This observationfits with the fact that growth on glucose is less efficient thanonlactose.

Selection and characterization of 2DG-resistant mutants. Strains ATCC 11842 and CNRZ397 were plated on MPL-lactose containing 2DG. After 2 days of incubation, colonies appeared witha frequency of 10⁵. Sugar fermentation patterns of these mutants were studied onMPL plates containing different sugars as the sole carbon source.ATCC 11842-derived mutants exhibited four phenotypes: (i) twomutants were not affected on any sugars; (ii) one mutant was unableto grow on glucose and fructose and its growth was delayed onlactose; (iii) four mutants were greatly affected on glucose andslightly affected on mannose; and (iv) three mutants grew poorly,only on glucose. Therefore it appears that growth on glucose,mannose, or fructose can be dissociated in the ATCC 11842strain.

We isolated and analyzed 74 2DG-tolerant mutants from CNRZ397. A majority (75.6%) grew normally on lactose and displayed aGlc Man Fru phenotype; some (5.4%) displayed reduced growth on glucose, mannose, and fructose; and the remainder (19%) grew normally on each ofthe three sugars. These results show that, in contrast to themutants derived from the ATCC 11842 strain, each CNRZ397-derivedmutant had a similar growth on the three sugars tested, i.e.,none, slow, or normal growth. We conclude that CNRZ397 is likelyto have a single transporter for the three sugars, which is affectedin the majority (around 80%) of the 2DG^r mutants, whereas several sugar transporters probably coexistin ATCC11842.

Protein labeling, phage infection, and EPS production in MPL. (i) De novo protein synthesis. Radioactive labeling of proteins may be useful for a number of physiological studies, in particular in conjunction with two-dimensionalgel electrophoresis. Here we showed that proteins may be labeledefficiently in MPL (Fig. 3). Incorporation of about 5 × 10⁴ to 1 × 10⁵ cpm for 0.2 OD₆₀₀ units, obtained in 2 min, gave an easily detectablesignal on X-ray film. Incorporation increased with a longer labelingtime. As expected, use of higher amounts of [³⁵S]Met (25 and 50 µCi/ml) resulted in a greater incorporation.Such labeling allows detection of induced or repressed proteinsunder different environmental conditions (24).

FIG. 3. Protein labeling in MPL. CNRZ397 was grown in MPL containing 40 µM methionine. At an OD₆₀₀ of 0.7, [³⁵S]Met was added to the cultures, and samples were withdrawn at different time intervals. Samples equivalent to 0.2 OD₆₀₀ units were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Lanes 1 to 7 correspond to samples incubated with [³⁵S]Met at 10 µCi/ml for 1, 2, 5, 10, 15, 20, or 25 min, respectively. Lanes 8 and 9 correspond to samples labeled for 2 min with 25 or 50 µCi of [³⁵S]Met/ml, respectively.

(ii) Phage infection. To test phage development in MPL, strain CNRZ1057 was infected by phage 19 (33) using a multiplicity of infection of around1/50 (Materials and Methods). Cells grown in MRS were used asa control. The resulting phage titers reached 5 × 10⁶ and 3 × 10⁸ PFU/ml in MPL and MRS, respectively. This result suggests thatMPL can be used for phage infection studies but that phage developmentmay be hampered.

(iii) EPS production. EPS production is an important industrial trait of L. bulgaricus for yogurt quality (6), although the amounts of EPS producedby these lactobacilli are often small (12). The supernatantsof MPL batch cultures of CNRZ416 and CNRZ1187 contained 30 to50 mg of EPS/liter (S. Petry, personal communication). This issimilar to the amounts detected in media optimized for EPS productionand in which L. bulgaricus growth was much slower than in MPL(12, 28).

	DISCUSSION

MPL is the first CDM described that allows a high growth rate for L. bulgaricus. Grobben et al. (12) reported growth ratesof 0.18 to 0.23 h¹ (i.e., doubling times of 3 h 50 min to 3 h) in media designedfor EPS production, and growth rates in MPL are close to 0.7 h¹ (doubling time of 60 min). Our work reveals that certain parameters are important for efficient growth of L. bulgaricus. (i) Lactoserather than glucose, as previously considered, markedly increasesthe growth rate of L. bulgaricus. (ii) A high proline concentrationappears to be essential. We observed that increasing the prolineconcentration from 0.04 to 0.54 g/liter markedly improves growth(data not shown). It was previously established that proline playsa role in osmotic protection in some lactobacilli and in Lactococcuslactis (11, 17, 27). In our case, the requirement for ahigh proline concentration could reflect an osmotic protectionrole or a nutritional requirement due to inefficient uptake. (iii)Sodium thioglycolate (-mercaptoacetate), a reducing agent, isimportant for efficient growth. It is known that during growthtoxic oxygen derivatives are produced, but the enzymes requiredto eliminate them appear not to be expressed in L. bulgaricus(3). Reducing agents may provide protection against toxic products,particularly if growth conditions are not strictlyanaerobic.

Our work confirmed some observations of Grobben et al. (12) concerning the nutritional requirements of L. bulgaricus. Single-omissiongrowth tests confirmed that niacin, calcium pantothenate, riboflavin,and vitamin B12 were essential for growth and that biotin, thiamine,and p-aminobenzoic acid were dispensable in MPL. However, we alsoobserved major differences in requirements, compared to those reported by Grobben et al. We found that folic acid, pyridoxal,and CaCl₂ were important for efficient growth. Conversely, citrateand ammonium were eliminated from the MPL medium without affectinggrowth efficiency. These discrepancies could be due to other differencesin medium composition or to strain-specificrequirements.

L. bulgaricus does not use galactose but catabolizes the glucose moiety of lactose (14, 32). Enzymes responsible for glucosefermentation are thus present in L. bulgaricus. However, a ratherimportant difference in doubling times was observed on MPL-lactose(1 h) and MPL-glucose (~3 h). A possible explanation is that thelactose preference may be due to characteristics of the transportersinvolved in glucose or lactoseuptake.

The lactose permease (LacS) of L. bulgaricus is homologous to LacS of S. thermophilus (30). This permease is a galactoside/H⁺ symporter which can transport either galactose or lactose. Under physiological conditions, LacS activity catalyzes the exchangeof both sugars, leading to the entry of lactose and the effluxof galactose according to the gradient of sugars (9, 38).Our results, showing that the presence of galactose results ingrowth inhibition (if more than 1% galactose with 1% lactose ispresent) or slow growth at low lactose concentrations (below 0.4%),indicate that a similar exchange mechanism may exist in L. bulgaricusCNRZ397.

Previous studies (14) indicated that glucose is imported via a PTS in some strains of L. bulgaricus. Analyses of 2DG^r mutants in this study suggest that the CNRZ397 strain imports glucose, mannose, and fructose via a single transporter. In many bacteria, the PTS-specific enzyme EII^Man is able to transport glucose, mannose, and fructose. Also, EII^Man is considered to be involved in 2DG sensitivity. Therefore wepropose that EII^Man is present in L. bulgaricus CNRZ397 and that it transports glucose,mannose, and fructose. By contrast, the ATCC 11842 strain probablyuses different systems to take up these sugars. ATCC 11842 gave a high background of growth on lactose-2DG plates, and this low2DG sensitivity may reflect the absence of EII^Man in this strain. Therefore, transport systems of sugars otherthan lactose are likely to vary among L. bulgaricusstrains.

The observations reported above strongly suggest that glucose import is inefficient in L. bulgaricus. This is in contrastwith the general idea that glucose, transported via a PTS, isthe most energetic or hierarchically preferred sugar for bacteria.We propose that this is an example of bacterial adaptation toa given growth medium, since L. bulgaricus is usually found andextensively cultured in milk in which lactose is present at ahigh concentration (around 5%).

In conclusion, our studies indicate that MPL may prove useful for biochemical studies and phage and EPS production as wellas protein labeling in L. bulgaricus. Use of this medium shouldthus facilitate physiological and genetic studies of this importantmicroorganism.

	ACKNOWLEDGMENTS

D. Lebars and S. Petry are gratefully acknowledged for amino acid and EPS measurements, respectively. We thank P. Loubièreand F. Rodolfe for helpful suggestions concerning MPL optimization,M. Zagorec for her expertise in sugar transport, and A. Grussand M. van de Guchte for valuable suggestions concerning the manuscript.We also thank L. Benbadis, C. Fremaux, and A. Sépulchre for theirinterest in thisstudy.

This work was supported, in part, by Danone (CIRDC) and Rhodia Food(Texel).

	FOOTNOTES

^* Corresponding author. Mailing address: Génétique Microbienne, INRA, Centre de Jouy-en-Josas, Domaine de Vilvert, 78352 Jouy-en-JosasCedex, France. Phone: 33-(0)1-34 65 25 18. Fax: 33-(0)1-34 6525 21. E-mail: maguin@biotec.jouy.inra.fr.

	REFERENCES

1. Accolas, J.-P., and M.-C. Chopin. 1980. Bacteriophages of lactic starters detection and enumeration, p. 159-173. In C. M. Bourgeois, and J. Y. Leveau (ed.), Techniques d'analyse et de contrôle dans les industries agroalimentaires. Le contrôle microbiologique, vol. 3. Technique et Documentation APRIA, Paris, France.

2. Alais, C. 1984. Science du lait. Principes des techniques laitières, 4th ed. Sepaic, Paris, France.

3. Archibald, F. S., and I. Fridovich. 1981. Manganese and defenses against oxygen toxicity in Lactobacillus plantarum. J. Bacteriol. 145:442-451.

4. Atlan, D., P. Laloi, and R. Portalier. 1989. Isolation and characterization of aminopeptidase-deficient Lactobacillus bulgaricus mutants. Appl. Environ. Microbiol. 55:1717-1723.

5. Buchanan, R. E., and N. E. Gibbons (ed.). 1974. Bergey's manual of determinative bacteriology, 8th ed. The Williams & Wilkins Co., Baltimore, Md.

6. Cerning, J. 1990. Exocellular polysaccharides produced by lactic acid bacteria. FEMS Microbiol. Rev. 7:113-130.

7. Chaillou, S., P. H. Pouwels, and P. W. Postma. 1999. Transport of D-xylose in Lactobacillus pentosus, Lactobacillus casei, and Lactobacillus plantarum: evidence for a mechanism of facilitated diffusion via the phosphoenolpyruvate:mannose phosphotransferase system. J. Bacteriol. 181:4768-4773.

8. Dicks, L. M., E. M. Du Plessis, F. Dellaglio, and E. Lauer. 1996. Reclassification of Lactobacillus casei subsp. casei ATCC 393 and Lactobacillus rhamnosus ATCC 15820 as Lactobacillus zeae nom. rev., designation of ATCC 334 as the neotype of L. casei subsp. casei, and rejection of the name Lactobacillus paracasei. Int. J. Syst. Bacteriol. 46:337-340.

9. Foucaud, C., and B. Poolman. 1992. Lactose transport system of Streptococcus thermophilus. Functional reconstitution of the protein and characterization of the kinetic mechanism of transport. J. Biol. Chem. 267:22087-22094.

10. Gauthier, L., S. Thomas, G. Gagnon, M. Frenette, L. Trahan, and C. Vadeboncoeur. 1994. Positive selection for resistance to 2-deoxyglucose gives rise, in Streptococcus salivarius, to seven classes of pleiotropic mutants, including ptsH and ptsI missense mutants. Mol. Microbiol. 13:1101-1109.

11. Glaasker, E., W. N. Konings, and B. Poolman. 1996. Osmotic regulation of intracellular solute pools in Lactobacillus plantarum. J. Bacteriol. 178:575-582.

12. Grobben, G. J., I. Chin-Joe, V. A. Kitzen, I. C. Boels, F. Boer, J. Sikkema, M. R. Smith, and J. A. M. De Bont. 1998. Enhancement of exopolysaccharide production by Lactobacillus delbrueckii subsp. bulgaricus NCFB 2772 with a simplified defined medium. Appl. Environ. Microbiol. 64:1333-1337.

13. Grobben, G. J., J. Sikkema, M. R. Smith, and J. A. M. De Bont. 1995. Production of extracellular polysaccharide by Lactobacillus delbrueckii subsp. bulgaricus NCFB 2772 grown in a chemically defined medium. J. Appl. Bacteriol. 79:103-107.

14. Hickey, M. W., A. J. Hillier, and G. R. Jago. 1986. Transport and metabolism of lactose, glucose, and galactose in homofermentive lactobacilli. Appl. Microbiol. 51:825-831.

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

16. Jensen, P. R., and K. Hammer. 1993. Minimal requirements for exponential growth of Lactococcus lactis. Appl. Environ. Microbiol. 59:4363-4366.

17. Jewell, J. B., and E. R. Kashket. 1991. Osmotically regulated transport of proline by Lactobacillus acidophilus IFO 3532. Appl. Environ. Microbiol. 57:2829-2833. (Erratum, 57:3683.)

18. Juillard, V., M. E. Spinnzler, M. Desmazeaud, and C. Y. Boquien. 1987. Phénomènes de coopération et d'inhibition entre les bactéries lactiques utilisées en industrie laitière. Lait 67:149-172.

19. Laemmli, U. K. 1970. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227:680-685.

20. Lauret, R., F. Morel-Deville, F. Berthier, M. Champomier-Verges, P. Postma, S. D. Ehrlich, and M. Zagorec. 1996. Carbohydrate utilization in Lactobacillus sake. Appl. Environ. Microbiol. 62:1922-1927.

21. Ledesma, O. V., A. P. De Ruiz Holgado, G. Oliver, G. S. De Giori, P. Raibaud, and J. V. Galpin. 1977. A synthetic medium for comparative nutritional studies of lactobacilli. J. Appl. Bacteriol. 42:123-133.

22. Le Graet, Y., and G. Brulé. 1993. Les équilibres minéraux du lait: influence du pH et de la force ionique. Lait 73:51-60.

23. Leong-Morgenthaler, P., M. C. Zwahlen, and H. Hottinger. 1991. Lactose metabolism in Lactobacillus bulgaricus: analysis of the primary structure and expression of the genes involved. J. Bacteriol. 173:1951-1957.

24. Lim, E.-M., S. D. Ehrlich, and E. Maguin. 2000. Identification of stress-inducible proteins in Lactobacillus delbrueckii subsp. bulgaricus. Electrophoresis 21:2557-2561.

25. Meadow, N. D., D. K. Fox, and S. Roseman. 1990. The bacterial phosphoenolpyruvate:glycose phosphotransferase system. Annu. Rev. Biochem. 59:497-542.

26. Mietton, B., M. Desmazeaud, H. de Roissart, and F. Webeer. 1994. Transformation du lait en fromage, p. 55-132. In H. de Roissart, and F. M. Luquet (ed.), Bactéries Lactiques, vol. 2. Lorica, Uriage, France.

27. Molenaar, D., A. Hagting, H. Alkema, A. J. Driessen, and W. N. Konings. 1993. Characteristics and osmoregulatory roles of uptake systems for proline and glycine betaine in Lactococcus lactis. J. Bacteriol. 175:5438-5444.

28. Petry, S., S. Furlan, M.-J. Crepeau, J. Cerning, and M. Desmazeaud. 2000. Factors affecting exocellular polysaccharide production by Lactobacillus delbrueckii subsp. bulgaricus grown in a chemically defined medium. Appl. Environ. Microbiol. 66:3427-3431.

29. Poolman, B. 1993. Energy transduction in lactic acid bacteria. FEMS Microbiol. Rev. 12:125-147.

30. Poolman, B., J. Knol, C. van der Does, P. J. Henderson, W. J. Liang, G. Leblanc, T. Pourcher, and I. Mus-Veteau. 1996. Cation and sugar selectivity determinants in a novel family of transport proteins. Mol. Microbiol. 19:911-922.

31. Postma, P. W., J. W. Lengeler, and G. R. Jacobson. 1993. Phosphoenolpyruvate:carbohydrate phosphotransferase systems of bacteria. Microbiol. Rev. 57:543-594.

32. Premi, L., W. E. Sandine, and P. R. Elliker. 1972. Lactose-hydrolyzing enzymes of Lactobacillus species. Appl. Microbiol. 24:51-57.

33. Sechaud, L. 1990. Caractérisation de 35 bactériophages de Lactobacillus helveticus. Ph.D. thesis. University of Paris, Paris, France.

34. Thompson, J. 1987. Sugar transport, p. 13. In J. Reizer, and A. Peterkofsky (ed.), Sugar transport and metabolism in gram-positive bacteria. Ellis Horwood Ltd., London, United Kingdom.

35. Thompson, J., and B. M. Chassy. 1985. Intracellular phosphorylation of glucose analogs via the phosphoenolpyruvate:mannose-phosphotransferase system in Streptococcus lactis. J. Bacteriol. 162:224-234.

36. Thompson, J., and M. H. Saier, Jr. 1981. Regulation of methyl--D-thiogalactopyranoside-6-phosphate accumulation in Streptococcus lactis by exclusion and expulsion mechanisms. J. Bacteriol. 146:885-894.

37. Vadeboncoeur, C., and M. Pelletier. 1997. The phosphoenolpyruvate:sugar phosphotransferase system of oral streptococci and its role in the control of sugar metabolism. FEMS Microbiol. Rev. 19:187-207.

38. Veenhoff, L. M., and B. Poolman. 1999. Substrate recognition at the cytoplasmic and extracellular binding site of the lactose transport protein of Streptococcus thermophilus. J. Biol. Chem. 274:33244-33250.

39. Veyrat, A., M. J. Gosalbes, and G. Perez-Martinez. 1996. Lactobacillus curvatus has a glucose transport system homologous to the mannose family of phosphoenolpyruvate-dependent phosphotransferase systems. Microbiology 142:3469-3477.

40. Veyrat, A., V. Monedero, and G. Perez-Martinez. 1994. Glucose transport by the phosphoenolpyruvate:mannose phosphotransferase system in Lactobacillus casei ATCC 393 and its role in carbon catabolite repression. Microbiology 140:1141-1149.

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