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Journal of Clinical Microbiology, October 2004, p. 4586-4592, Vol. 42, No. 10
0095-1137/04/$08.00+0     DOI: 10.1128/JCM.42.10.4586-4592.2004
Copyright © 2004, American Society for Microbiology. All Rights Reserved.

Comparative Analysis of Gtf Isozyme Production and Diversity in Isolates of Streptococcus mutans with Different Biofilm Growth Phenotypes

Department of Microbiology and Immunology, Piracicaba School of Dentistry, University of Campinas, São Paulo, Brazil,¹ Department of Microbiology, School of Dentistry at Matsudo, Nihon University, Chiba, Japan,² Departments of Molecular Genetics,³ Immunology, The Forsyth Institute, Boston, Massachusetts⁴

Received 2 March 2004/ Returned for modification 13 April 2004/ Accepted 10 June 2004

	ABSTRACT

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Streptococcus mutans is the main pathogenic agent of dental caries. Glucosyltransferases (Gtfs) produced by these bacteria are important virulence factors because they catalyze the extracellular synthesis of glucans that are necessary for bacterial accumulation in the dental biofilm. The diversity of GtfB and GtfC isozymes was analyzed in 44 genotypes of S. mutans that showed a range of abilities to form biofilms in vitro. Several approaches were used to characterize these isozymes, including restriction fragment length polymorphism analysis of the gtfB and gtfC genes, zymographic analysis of the identified GtfB and GtfC genotypes, and quantitation of isozyme production in immunoblot experiments with specific monoclonal antibodies. A high diversity of gtf genes, patterns of enzymatic activity, and isozyme production was identified among the isolates tested. GtfC and, to a lesser extent, GtfB were produced in significantly higher amounts by strains that had high biofilm-forming ability than by strains with low biofilm-forming ability. Biofilm formation was independent of the GtfB and GtfC genotype. Atypical strains that showed an apparent single Gtf isozyme of intermediate size between GtfB and GtfC were also identified. The results indicate that various expression levels of GtfB and GtfC isozymes are associated with the ability of distinct S. mutans genotypes to grow as biofilms, strengthening the results of previous genetic and biochemical studies performed with laboratory strains. These studies also emphasize the need to identify factors that control gtf gene expression.

	INTRODUCTION

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Streptococcus mutans is the major pathogen of dental caries. One of its most intensively studied virulence factors is the ability to synthesize extracellular water-insoluble glucan from sucrose through the activity of secreted glucosyltransferases (Gtf), leading to bacterial accumulation in the dental biofilm. Three distinct Gtfs (GtfB, GtfC, and GtfD) were demonstrated to participate in the sucrose-dependent adherence process (16, 23, 26). Antibodies raised against Gtfs have been shown to protect against dental caries in animal models (18, 21). Gtfs have also been incorporated into vaccines used in human clinical trials (3, 19, 20). GtfB and GtfC enzymes are encoded by highly homologous genes that are organized in a sequential operon-like fashion (17, 24). These two Gtfs are involved in the synthesis of water-insoluble (1-3)-rich glucans (17, 24). A third isotype, GtfD, shows less homology with GtfB and GtfC and is encoded by a gene located elsewhere in the chromosome. This enzyme catalyzes the synthesis of water-soluble (1-6)-rich glucans (8).

Genes coding for each Gtf isozyme have been inactivated, and the resulting mutant strains were analyzed for sucrose-dependent adherence in vitro and cariogenicity in animal models. These studies indicated that GtfB and GtfC have the highest association with virulence (16, 26). We have shown that there is significant variability in the ability to form biofilms in vitro among a large group of clinical isolates containing distinct S. mutans genotypes and have suggested that these variations may be associated with differential expression of proteins involved in the accumulation phase of biofilm growth (12).

A study of distinct genotypes that vary in biofilm growth may help us to understand how virulence factor expression is related to the ability of S. mutans to accumulate in the dental biofilm and ultimately help to explain the differences in caries activity observed among S. mutans-infected children (11). Toward these goals, in this study, we characterized Gtf isozymes with respect to gtf gene polymorphisms and enzyme production and activity patterns in a large number of clinical isolates which differ in their abilities to grow as biofilms. The results of our study indicate that S. mutans biofilm formation is influenced more by the amounts of GtfC and GtfB produced than by the inherent gtf gene polymorphisms, suggesting that factors that control expression of GtfB and GtfC may account for differences in virulence among infecting S. mutans strains.

	MATERIALS AND METHODS

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Bacterial strains and growth conditions. A total of 76 S. mutans isolates included in this study were obtained from 35 young children (11) and included 44 distinct S. mutans amplitypes, as previously determined by AP-PCR (13). Laboratory strains were S. mutans SJ32, UA130 (ATCC 700611), and GS5 (kindly provided by H. K. Kuramitsu, State University of New York). S. mutans strains were grown in either Todd-Hewitt broth (THB; Difco), brain heart infusion (Difco), or chemically defined medium (CDM) under anaerobic conditions (10% H₂, 10% CO₂, 80% N₂) or in candle jars.

DNA isolation. S. mutans chromosomal DNA was isolated by using a MasterPure DNA purification kit from Epicentre Technologies (Madison, Wis.) as described by the manufacturer.

PCR-RFLP analysis of gtfB and gtfC. Polymorphisms of gtfB and gtfC genes were identified by PCR-restriction fragment length polymorphism (RFLP) in the 44 S. mutans amplitypes and in strains SJ32, UA130, and GS5. Seven additional isolates of duplicate amplitypes were also included to check agreement between RFLP patterns of gtf genes and S. mutans AP-PCR identity, giving a total of 51 isolates tested. Since gtfB and gtfC sequences are sequentially arranged in the chromosome and are highly homologous (76% amino acid sequence identity), primer sets used for independent amplification of gtfB and gtfC included a nonconserved region located between the GtfB and GtfC open reading frames. The sequence used for primer design was obtained from S. mutans strain GS5 (GenBank accession number M17361). Figure 1 shows primer locations and restriction maps of the gtfB and gtfC amplicons. Amplification of gtfB with the specific primers GTFBF (5'-CAAAGATGAAGAAGCAGTAAT-3') and GTFBR (5'-TTCTATAACAAAAGCACAATG-3') yielded amplicons of 5.2 kb. Amplicons of 4.3 kb, corresponding to gtfC, were obtained with primers GTFCF (5'-TTGGAGGAAATATGGAAAAG-3') and GTFCR (5'-GTCTAAAACGAACAGCACT-3'). Amplification reactions were performed with a polymerase enzyme system specific for the generation of long PCR products (Advantage2; Clontech Labs, Inc.). The PCR included 23 cycles of denaturing at 95°C (30 s), annealing at 59°C (1 min), and extension at 70°C (2 min). The restriction enzymes BsrI and SspI were selected for RFLP analysis of the gtfB and gtfC amplicons, respectively, since restriction maps indicated that these enzymes give the highest number of cleavage sites and yielded fragments suitable for electrophoretic separation. Fragments of digested gtfB and gtfC amplicons were separated by electrophoresis at 5 V/cm for 3 h in 3 and 2% low-melting-point agarose gels (GTG; Novagen), respectively, in 0.5x Tris-borate-EDTA. Gels were then stained with ethidium bromide.

View larger version (34K): [in this window] [in a new window]   FIG. 1. Chromosome locus of the GS5 strain containing the gtfB and gtfC genes (GenBank accession number M17361). (A) Primer pairs used for specific amplification of gtfB and gtfC genes are represented as black and shaded arrows, respectively. The restriction sites of the 5.2-kb gtfB and 4.3-kb gtfC amplicons are represented by the dashed lines; within them, the size of fragments are indicated. (B) PCR products obtained with the GTFBF-GTFBR (lane 1) and GTFCF-GTFCR (lane 2) primer pairs. In 18 isolates, efficient amplification of the gtfC genes was not obtained. Instead, PCRs yielded two weaker products as shown in lane 2b. Thus, RFLP analysis of gtfC could not be performed with these 18 strains. ORF, open reading frame.

Analysis of GtfB and GtfC activity patterns in zymographic assays. To compare the patterns of GtfB and GtfC enzyme activity among the distinct RFLP classes of gtfB and gtfC, 3 or more strains representative of each gtfB and gtfC genotype identified were randomly selected from the 51 strains analyzed. These strains represented a subset of 34 clinical isolates. Briefly, the samples of culture fluids were obtained from 18-h cultures grown in 4 ml of brain heart infusion during incubation in candle jars. These cultures had been inoculated with an adjusted inoculum size of 18-h cultures from frozen stocks prepared under the same conditions. The final absorbance (A₅₅₀) of cultures used for enzyme analysis was measured again to check for variations in growth (mean ± SD, 0.89 ± 0.10; range, 0.71 to 1.05). Bacterial cells were removed from 3 ml of culture by centrifuging twice at 4°C (1,385 x g, 3 min). Culture supernatants were dialyzed at 4°C against 0.02 M sodium phosphate buffer, pH 6.8, containing 10 µM phenylmethylsulfonyl fluoride, followed by dialysis against 0.2 mM sodium phosphate containing 10 µM phenylmethylsulfonyl fluoride, a protease inhibitor. After dialysis, samples were concentrated 100-fold by lyophilization. To prepare for electrophoresis, 7.5 µl of each concentrated culture fluid was resuspended in 2x Laemmli buffer (1:1), boiled for 1 min, and applied to sodium dodecyl sulfate (SDS)-6% polyacrylamide gels by using the mini-Protean II system (Bio-Rad).

GtfB and GtfC enzyme activities were analyzed in simultaneously run quadruplicate SDS-6% polyacrylamide gel electrophoresis (PAGE) gels. The first gel was used for protein detection by staining with Coomassie blue. The second gel was used for the zymogram assay. Proteins separated in the other two gels were transferred to nitrocellulose membranes for detection of the corresponding GtfB and GtfC isozymes in Western blot assays performed with MAbs P72 (anti-GtfB) and P32 (anti-GtfC), respectively.

For zymogram analysis, following electrophoretic separation, gels were washed twice for 15 min each with renaturing buffer containing 2.5% Triton X-100. Gels were then incubated for 18 h at 37°C with 0.2 M sodium phosphate buffer (pH 6.5) containing 0.2% dextran T70 and 5% sucrose. The reactions were stopped by washing gels with distilled water at 4°C for 10 min, and digital images of the resulting white opaque glucan bands, synthesized by Gtf within the gels, were captured by using a black background to enhance visibility.

Western blot analyses of GtfB and GtfC from electrophoretic separation of culture supernatants were performed as described above for the dot blot assay, except that MAbs P72 and P32 were used at 1:200 dilutions. The antibody-reactive GtfB and GtfC bands were detected by using the horseradish peroxidase-conjugated goat anti-mouse immunoglobulin G reagent followed by the ECL system (Amersham). The relationships of antibody-stained Gtf bands to the corresponding glucan bands observed in zymograms were confirmed by measuring the distances of antibody-recognized bands from prestained molecular size markers (Gibco BRL, Carlsbad, Calif.), which were included in separate lanes of all gels. Intensities of the zymographic and Western blot bands were obtained from digital images captured by a scanning densitometer (Bio-Rad GS-700 imaging densitometer). To control for interassay variability, intensities of the principal glucan and protein bands of all isolates tested were divided by the intensity of a control strain (3VF2) used in all the experiments.

Biofilm formation in microtiter plates. Biofilm growth in microtiter plates was initiated from 1:100 dilutions of 18-h THB cultures transferred into fresh medium. THB contains trace amounts of sucrose, thus providing the substrate for Gtf activities (7). Briefly, after incubation, planktonic cells were removed by washing and the biofilms were stained with a 1% aqueous solution of crystal violet. The absorbances of crystal violet dissolved from ethanol treatment of the stained biofilms (A₅₇₅) and of planktonic cultures grown under the same conditions (A₅₅₀) were measured.

Statistical analysis. Pearson correlation analyses were used to evaluate associations between production of GtfB, GtfC, and GtfD (normalized according to the A₅₅₀ of the tested cultures) and biofilm or planktonic growth among S. mutans amplitypes. Means of glucan band intensities were compared among the PCR-RFLP patterns identified for their respective Gtf isozyme by the Kruskal-Wallis U test.

	RESULTS

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Polymorphisms of gtfB and gtfC genes and zymographic patterns. Significant genetic diversity was identified in both gtfB and gtfC genes. Figure 2 illustrates the distinct representative classes of gtfB (Fig. 2A) and gtfC (Fig. 2B) genes identified in the RFLP analysis. The frequencies of each RFLP class among the 44 S. mutans amplitypes tested are also shown (Fig. 2). The gtfB RFLP class b was, as predicted, the pattern identified in strain GS5. This same gtfB genotype was also identified in strain SJ32 and in 8 clinical amplitypes (18.2%). The gtfB RFLP class c was the most frequently detected genotype, observed in 40.9% of the clinical amplitypes (n = 18) and in UA130. Only strains 3SN1, 2SN3, and 4SM1 reflected gtfB RFLP class f. PCR products corresponding to the 4.3-kb gtfC gene were not efficiently generated in 18 strains, although GtfC was recognized by the appropriate MAb (MAb P32) in the immunological analysis. Thus, the gtfC RFLP patterns were analyzed in 26 clinical amplitypes. Class k was the most frequently identified gtfC genotype (n = 12) and was also observed in strain GS5. The gtfC RFLP class n genotype was detected in strain SJ32 and 10 other distinct S. mutans amplitypes.

View larger version (44K): [in this window] [in a new window]   FIG. 2. (A) Ten distinct RFLP classes of the gtfB amplicon (a to j) were detected by BsrI digestion among the clinical strains analyzed. (B) Patterns of RFLP identified by SspI digestion of gtfC amplicons (k to o).

View larger version (50K): [in this window] [in a new window]   FIG. 3. Representative patterns of Gtf isozyme production and activities analyzed in clinical isolates representative of the gtfB and gtfC genotypes identified by RFLP. GtfB and GtfC were electrophoretically separated on quadruplicate SDS-6% PAGE gels and then analyzed for protein by Coomassie staining, for glucan production after incubation of gels with sucrose, and immunologically for GtfB and GtfC in Western blots developed with MAb P72 or MAb P32, respectively. Strains are indicated above each lane. RFLP classes of gtfB and gtfC amplicons are shown beneath each lane. Note that strains 4SM1 and 3SN1 presented a glucan-synthesized band of intermediate size between the typical GtfB- and GtfC-related glucan bands. Strains 5ST1 and 11SSST2, representative of a single S. mutans amplitype, did not display detectable levels of GtfB.

Comparisons of Gtf production and gtf gene polymorphisms with biofilm growth.
Relative amounts of secreted Gtf isozymes quantified by immuno dot blot analysis were quite variable among the 44 S. mutans amplitypes tested. Relative amounts of GtfB, expressed as the intensities of dot blot reactivities, normalized by the A₅₅₀ of the cultures tested, ranged from 0 to 131 arbitrary units (U) (mean ± SD, 54.8 ± 44.1 U). Relative amounts of GtfC ranged from 19.2 to 80.7 U for GtfC (mean ± SD, 50.2 ± 16.8 U). For GtfD, relative amounts ranged from 4.5 to 72.7 U (mean ± SD, 20.7 ± 15.2 U). Relative amounts of GtfB produced were associated with amounts of GtfC in a high proportion of amplitypes studied (Pearson correlation, r = 0.49, P < 0.001) but not with amounts of GtfD (r = 0.01; P = 0.95). Amounts of GtfC also were not associated with amounts of GtfD (r = 0.07; P = 0.62).

To investigate the influence of varying production of Gtf isozymes from clinical isolates on their ability to grow as biofilms, the relative amounts of GtfB, GtfC, and GtfD produced were compared to biofilm growth measurements (Fig. 4). Relative amounts of GtfC produced by the 44 amplitypes were significantly associated with the ability of these strains to grow as biofilms (Pearson correlation, r = 0.36, P < 0.02). Amounts of GtfB expressed were also associated with biofilm formation, although to a lower extent than those of GtfC (Pearson correlation, r = 0.31, P < 0.05). An inverse relationship was observed between amounts of GtfD produced and biofilm growth (Pearson correlation, r = –0.33, P < 0.05). Planktonic growth was not related to levels of Gtf isozyme production (GtfB, r = –0.39, P = 0.01; GtfC, r = –0.48, P = 0.76; GtfD, r = 0.20, P = 0.20).

View larger version (20K): [in this window] [in a new window]   FIG. 4. Distribution of Gtf isozyme production and biofilm growth in 44 S. mutans amplitypes. The relative amounts of Gtf produced were expressed as the intensities of the immunological dot blot reactions adjusted for the A550 of the cultures tested. Biofilm growth was expressed as the A575 of ethanol-eluted crystal violet of the stained biofilms. A significant positive association was observed between amounts of GtfB (A) and GtfC (B) produced and biofilm formation. No positive association was detected between amounts of GtfD and biofilm growth (C).

DISCUSSION The production and activity of S. mutans Gtfs and their association with virulence has been studied extensively in laboratory strains (16, 18, 23, 26). Mutants of gtfB, gtfC, or gtfD from strain UA130 showed a significantly lower potential to induce caries on smooth tooth surfaces in animal models when compared to the wild type, suggesting that all Gtf isozymes are important for colonization and caries induction (26). However, analyses of GS5 mutants carrying different combinations of gtf gene deletions indicated that GtfB and GtfC were important in sucrose-dependent adhesion in vitro while deletion of GtfD had only a modest effect (23). The gtfC mutations in GS5 caused the largest decrease in adherence in vitro (23). Since these studies suggested that differential expression of gtf genes may be related to phenotypic expressions of virulence, we explored the potential variability in the expression and activity of Gtf isotypes in a large group of clinical S. mutans isolates that had successfully colonized young children but differed in in vitro biofilm growth.

Previously, we compared both sucrose-dependent adherence on glass surfaces and Gtf activities among clinical strains isolated from young children who exhibited large differences in caries activity and established that children with high caries activity were often infected by strains showing significantly higher amounts of glucan synthesis compared to strains infecting caries-free children (14). The results suggested that diversity in Gtf expression or specific activity may be associated with the level of cariogenicity. However, analyses of specific Gtf isozymes were not performed (14).

The expression patterns of GtfB, GtfC, and GtfD were characterizedy using isozyme-specific MAbs (5, 22). This is the first study that characterized Gtf isozymes in a large number of clinical isolates, and the results support the notion that differences in expression of GtfB and GtfC are associated with the ability of the organism to form biofilms. The relationships between amounts of each Gtf isotype secreted with amounts of biofilm is consistent with the phenotypic traits observed in gtfB, gtfC, and gtfD mutants, supporting a pronounced role for GtfC in adherence (23). Contrary results have been observed with respect to the individual participation of GtfD in the virulence phenotype (23, 26). We found the amplitypes with the highest biofilm growth showed the lowest amounts of GtfD production, which may explain the lack of association observed between amounts of total secreted Gtfs and biofilm growth previously reported (12).

In the present study, no relationship was detected between specific gtfC genotypes and amounts of GtfC produced, which concurred with the assumption that differences in GtfC amounts were indeed due to variation in expression levels rather than to gtfC polymorphisms. Five atypical strains (3SN1, 2SN3, 4SM1, 17A2, and 12JP3) showed a GtfB/C intermediate size glucan band and a low level of biofilm growth (A₅₇₅ from 0.16 to 0.35). The Western blot patterns of these strains were similar to those previously observed with the strain UA101 (27). The intermediate size Gtf of UA101 had been suggested to be a product of homologous recombination of gtfB with gtfC in the UA101 ancestor (27).

Although an important role for GtfB and GtfC in the virulence of S. mutans was defined, the mechanisms that control expression of these proteins are poorly understood. For most genotypes analyzed in this study, the amounts of GtfB were positively associated with the amounts of GtfC expressed (Pearson correlation, r = 0.49, P < 0.001), supporting the notion that gtfB and gtfC genes are part of an operon (29). However, several high GtfC producers showed no detectable GtfB (3SN1, 2SN3, 5ST1, and 11SSST1), a finding which is consistent with independent transcription of these genes, as proposed in other studies (6). Isolates 5ST1 and 11SSST3 showed no detectable levels of GtfB in immunological assays, although a glucan band of migration similar to that synthesized by the GtfB isozyme was detected (Fig. 3). These apparently GtfB-related glucan bands could, however, be the consequence of GtfD activities because this latter isozyme has a molecular mass of approximately 160 kDa and may not have adequately separated from GtfB on the SDS-6% PAGE gels (Fig. 2). Another possible explanation for GtfB-like glucan bands in strains with no detectable GtfB in Western blots is that the GtfB isozymes produced by these strains were not recognized by the MAb P72, although their gtfB genes were of RFLP class c, the same as identified in high GtfB producers (Fig. 3). Sequence analysis of the whole gtf locus in these atypical S. mutans amplitypes may help to resolve these anomalies.

Measurement of glucan band intensities should be an indirect measurement of Gtf expression. However, zymograph variations were not always related to Western blot intensities (Fig. 3). The similar sizes of the Gtf isotypes made it difficult to determine the precise location of glucan-related bands, even when parallel Western blot assays were probed with specific MAbs. Despite this limitation, the relative amounts of glucans synthesized, which corresponded to the migration position of either GtfB and GtfC, were positively associated with biofilm growth in a subset of 29 strains (data not shown). The five atypical strains that synthesized single glucan bands were not included in these analyses. Variations in migration patterns, enzymatic kinetics, or protein degradation could influence zymographic results. For example, we cannot exclude the possibility that some glucan bands, which were associated with GtfC because of their migration position, could result from degraded GtfB that retained activity but migrated faster.

Given the high number of polymorphisms identified in the gtf genes, we presumed that different Gtfs may vary in their enzymatic kinetics, although no specific gtf genotypes were related to low or high enzymatic activity measured in zymograms. Polymorphisms in gtf genes have been described among isolates from other populations (1, 2, 4), including several that encode silent mutations that have no effect on isozyme activity (2). The gtfB RFLP class c was the most common genotype, followed by class b, which included the laboratory GS5 strain. The majority of clinical isolates also demonstrated gtfC of pattern k, the same as identified in GS5. Previous sequence comparison of the gtfB and gtfC genes between five clinical isolates and the GS5 laboratory strain have indicated several frameshift mutations in the gtfB and gtfC genes in GS5 which accounted for changes in the protein sequence (4). Besides the five atypical strains observed in the present study, no other clear influence of gtf gene polymorphism on isozyme production, activity pattern, or biofilm growth were observed. Thus, the results indicate that the amount of Gtf isozyme produced is more important to biofilm growth than gtf gene polymorphism. The positive associations of GtfB/C production with biofilm formation in vitro, determined from the large number of clinical isolates tested, suggests that further studies are required to elucidate mechanisms that regulate the expression of these isozymes. It is noteworthy that other factors could contribute to the variability in the amounts of Gtfs produced. For example, strains could differ in the affinities of their expressed Gtfs for the cell surface. We have only quantified Gtfs in culture fluids, since it has been shown that essentially all Gtf is released into the supernatant when strains are grown in non-sucrose-containing medium (7). Also, differences in the turnover of extracellular proteins cannot be excluded.

Experiments with strains GS5 and UA130 with reporter genes fused to the promoter sequences of gtfB/C indicated that the expression of these gtf genes is enhanced in bacteria growing as biofilms compared to planktonic growth (9, 25, 29). The amounts of Gtf that we quantified were from culture supernatants of planktonic cultures, and its relationship with biofilm growth suggests an intrinsic diversity in expression. Chloramphenicol acetyltransferase gene fusions performed with two S. mutans variant strains that diverged in the production of several proteins involved in virulence indicated that differences in the production of GtfC and GtfB were due to transcriptional activities of their respective gtf genes. Since no relationships to gtfB/C promoter region polymorphisms were identified, other factors controlling multiple virulence gene expression were suggested (28). In the present study, sequencing of promoter regions of the strains with divergent expression of GtfB and GtfC may shed new light on this question. A peak of expression of gtfB and gtfC genes was observed at the beginning of the log phase in planktonic cultures, suggesting that a cell density-dependent intercell communication system may play a role in regulating expression of gtfB/C genes (6). Since the biofilm growth phenotype was also shown to be regulated by such cell density-dependent systems (10, 15), factors important for biofilm growth which affect the expression of gtf genes were hypothesized (9). Alternatively, independent factors controlling gtf expression may increase the ability of distinct genotypes to grow and accumulate in the biofilm phase. Comparative transcriptional profiling or differential display analysis between the clinical strains described herein which exhibit highly divergent patterns of Gtf isozyme production may reveal factors involved in the regulation of gtf genes.

	ACKNOWLEDGMENTS

 
This study was supported by Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) grant 02/07156-1 and Public Health Service grant R37 DE-06153 (NIDCR). R.O.M-G. is also supported by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), ProDoc 028/03-7.

	FOOTNOTES

 
* Corresponding author. Mailing address: Faculdade de Odontologia de Piracicaba—UNICAMP, Departamento de Microbiologia e Imunologia, Av. Limeira, 901, CEP 13414-018 Piracicaba, SP, Brazil. Phone: 55 19 3412 5379. Fax: 55 19 3412 5218. E-mail: rmgraner{at}fop.unicamp.br.

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