Defining the Normal Bacterial Flora of the Oral Cavity

More than 700 bacterial species or phylotypes, of which over50% have not been cultivated, have been detected in the oralcavity. Our purposes were (i) to utilize culture-independentmolecular techniques to extend our knowledge on the breadthof bacterial diversity in the healthy human oral cavity, includingnot-yet-cultivated bacteria species, and (ii) to determine thesite and subject specificity of bacterial colonization. Ninesites from five clinically healthy subjects were analyzed. Sitesincluded tongue dorsum, lateral sides of tongue, buccal epithelium,hard palate, soft palate, supragingival plaque of tooth surfaces,subgingival plaque, maxillary anterior vestibule, and tonsils.16S rRNA genes from sample DNA were amplified, cloned, and transformedinto Escherichia coli. Sequences of 16S rRNA genes were usedto determine species identity or closest relatives. In 2,589clones, 141 predominant species were detected, of which over60% have not been cultivated. Thirteen new phylotypes were identified.Species common to all sites belonged to the genera Gemella,Granulicatella, Streptococcus, and Veillonella. While some specieswere subject specific and detected in most sites, other specieswere site specific. Most sites possessed 20 to 30 differentpredominant species, and the number of predominant species fromall nine sites per individual ranged from 34 to 72. Speciestypically associated with periodontitis and caries were notdetected. There is a distinctive predominant bacterial floraof the healthy oral cavity that is highly diverse and site andsubject specific. It is important to fully define the humanmicroflora of the healthy oral cavity before we can understandthe role of bacteria in oral disease.

INTRODUCTION

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Introduction

The oral cavity is comprised of many surfaces, each coated witha plethora of bacteria, the proverbial bacterial biofilm. Someof these bacteria have been implicated in oral diseases suchas caries and periodontitis, which are among the most commonbacterial infections in humans. For example, it has been estimatedthat at least 35% of dentate U.S. adults aged 30 to 90 yearshave periodontitis (1). In addition, specific oral bacterialspecies have been implicated in several systemic diseases, suchas bacterial endocarditis (4), aspiration pneumonia (26), osteomyelitisin children (8), preterm low birth weight (6, 20), and cardiovasculardisease (2, 34). Surprisingly, little is known about the microfloraof the healthy oral cavity.

By using culture-independent molecular methods, we previouslydetected over 500 species or phylotypes in subgingival plaqueof healthy subjects and subjects with periodontal diseases (21),necrotizing ulcerative periodontitis in human immunodeficiencyvirus-positive subjects (23), dental plaque in children withrampant caries (3), noma (22), and on the tongue dorsum of subjectswith and without halitosis (15). Other investigators have usedsimilar techniques to determine the bacterial diversity of saliva(25), subgingival plaque of a subject with gingivitis (16),and dentoalveolar abscesses (10, 29). Over half of the speciesdetected have not yet been cultivated. Data from these studieshave implicated specific species or phylotypes in a varietyof diseases and oral infections, but still only limited informationis available on species associated with health. Recently, Mageret al. (19) demonstrated significant differences in the bacterialprofiles of 40 oral cultivable species on soft and hard tissuesin healthy subjects. They also found that the profiles of thesoft tissues were more similar to each other than those of supragingivaland subgingival plaques.

Our purposes were as follows: (i) to utilize culture-independentmolecular techniques to extend our knowledge on the breadthof bacterial diversity in the healthy human oral cavity, includingnot-yet-cultivated phylotypes, and (ii) to determine the siteand subject specificity of bacterial colonization.

MATERIALS AND METHODS

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Materials and Methods

Subjects. Five subjects, representing both genders, ranging in age from23 to 55 and with no clinical signs of oral mucosal diseasewere included in the study. Subjects did not suffer from severehalitosis. The periodontia were healthy in that all periodontalpockets were less than 3 mm deep with no redness or inflammationof the gums. Subjects did not have active white spot lesionsor caries on the teeth. Our results were consistent with theseclinical observations in that species typically found in cariessubjects were not detected (3). The subjects had not used antibioticsfor the last 6 months.

Sample collection. Samples from the following nine sites were analyzed for eachsubject: dorsum of the tongue, lateral sides of the tongue,buccal fold, hard palate, soft palate, labial gingiva and tonsilsof soft tissue surfaces, and supragingival and subgingival plaquesfrom tooth surfaces. Microbiological samples of supragingivaland subgingival plaque samples were taken with a sterile Graceycurette. Other samples were collected with sterile swab brushes.

Sample lysis. Plaque samples were directly suspended in 50 µl of 50mM Tris buffer (pH 7.6), 1 mM EDTA, pH 8, and 0.5% Tween 20.Proteinase K (200 µg/ml; Roche Applied Science, Indianapolis,IN) was added to the mixture. The samples were then heated at55°C for 2 h. Proteinase K was inactivated by heating at95°C for 5 min. Detection of species is dependent upon obtainingDNA that can be amplified. Thus, a difficult-to-lyse bacteriummay not be detected. However, by using our lysis technique,we were able to detect many hard-to-lyse species, such as speciesof Actinomyces and Streptococcus.

Amplification of 16S rRNA genes by PCR and purification of PCR products. The 16S rRNA genes were amplified under standardized conditionsusing a universal primer set (forward primer, 5'-GAG AGT TTGATY MTG GCT CAG-3'; reverse primer, 5'-GAA GGA GGT GWT CCA RCCGCA-3') (21). Primers were synthesized commercially (OperonTechnologies, Alameda, CA). The PCR primers do not necessarilyinclude all bacterial species. Nevertheless, a wide range ofphylogenetic types were obtained in this study and our previousstudies by using this universal primer set (3, 15, 21-23). PCRwas performed in thin-walled tubes with a GeneAmp PCR system9700 (ABI, Foster City, CA). One microliter of the lysed samplewas added to a reaction mixture (final volume, 50 µl)containing 20 pmol of each primer, 40 nmol of deoxynucleosidetriphosphates, and 1 U of Platinum Taq polymerase (Invitrogen,San Diego, CA). In a hot-start protocol, the samples were preheatedat 95°C for 4 min, followed by amplification under the followingconditions: denaturation at 95°C for 45 s, annealing at60°C for 45 s, and elongation at 72° for 1.5 min, withan additional 15 s for each cycle. A total of 30 cycles wereperformed; this was followed by a final elongation step at 72°Cfor 15 min. The results of the PCR amplification were examinedby electrophoresis in a 1% agarose gel. DNA was stained withethidium bromide and visualized under short-wavelength UV light.

Cloning procedures. Cloning of PCR-amplified DNA was performed with the TOPO TAcloning kit (Invitrogen) according to the instructions of themanufacturer. Transformation was done with competent Escherichiacoli TOP10 cells provided by the manufacturer. The transformedcells were then plated onto Luria-Bertani agar plates supplementedwith kanamycin (50 µg/ml), and the plates were incubatedovernight at 37°C. Each colony was placed into 40 µlof 10 mM Tris. Correct sizes of the inserts were determinedin a PCR with an M13 (–20) forward primer and an M13 reverseprimer (Invitrogen). Prior to sequencing of the fragments, thePCR-amplified 16S rRNA fragments were purified and concentratedwith Microcon 100 (Amicon, Bedford, MA), followed by use ofthe QIAquick PCR purification kit (QIAGEN, Valencia, CA).

16S rRNA gene sequencing. Purified PCR-amplified 16S rRNA inserts were sequenced usingan ABI Prism cycle sequencing kit (BigDye terminator cycle sequencingkit with AmpliTaq DNA polymerase FS, GeneAmp PCR system 9700;ABI). The primers used for sequencing have been described previously(21). Quarter dye chemistry was used with 80 µM primersand 1.5 µl of PCR product in a final volume of 20 µl.Cycle sequencing was performed with a GeneAmp PCR system 9700(ABI) with 25 cycles of denaturation at 96°C for 10 s, annealingat 55° for 5 s, and extension at 60°C for 4 min. Thesequencing reactions were run on an ABI 3100 DNA sequencer (ABI).

16S rRNA gene sequencing and data analysis of unrecognized inserts. A total of 2,589 clones with an insert of the correct size ofapproximately 1,500 bases were analyzed. The number of clonesper subject that were sequenced ranged from 42 to 69, with anaverage of 57.5 and a standard deviation of 7.1. A sequenceof approximately 500 bases was obtained first to determine identityor approximate phylogenetic position. Full sequences of about1,500 bases were obtained by using five to six additional sequencingprimers (15) for those species deemed novel. For identificationof closest relatives, the sequences of the unrecognized insertswere compared to the 16S rRNA sequences of over 10,000 microorganismsin our database and over 100,000 sequences in the RibosomalDatabase Project (7) and the GenBank databases. Our cutoff forspecies differentiation was 2%, or approximately 30 bases fora full sequence. The similarity matrices were corrected formultiple base changes at single positions by the method of Jukesand Cantor (13). Similarity matrices were constructed from thealigned sequences by using only those sequence positions forwhich data were available for 90% of the strains tested. Phylogenetictrees were constructed by the neighbor-joining method of Saitouand Nei (24). TREECON, a software package for the MicrosoftWindows environment, was used for the construction and drawingof evolutionary trees (28). We are aware of the potential creationof 16S rRNA chimera molecules assembled during the PCR (18).The percentage of chimeric inserts in 16S rRNA gene librariesranged from 1 to 15%. Chimeric sequences were identified byusing the Chimera Check program in the Ribosomal Database Project,by treeing analysis, or by base signature analysis. Speciesidentification of chimeras was obtained, but the sequences werenot examined for phylogenetic analysis.

Nucleotide sequence accession numbers. The complete 16S rRNA gene sequences of clones representingnovel phylotypes defined in this study, sequences of known speciesnot previously reported, and published sequences are availablefor electronic retrieval from the EMBL, GenBank, and DDBJ nucleotidesequence databases under the accession numbers shown in Fig.1 to 9.

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FIG. 1. Bacterial profiles of the buccal epithelium of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are shown by the columns of boxes to the right of the tree as either not detected (clear box), <15% of the total number of clones assayed (shaded box), or $≥$ 15% of the total number of clones assayed (darkened box). The 15% was chosen arbitrarily. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

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FIG. 9. Bacterial profiles of the subgingival plaque of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are as described for Fig. 1. Novel phylotypes identified in this study are indicated in bold. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

RESULTS AND DISCUSSION

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Results and Discussion

It has long been known that oral bacteria preferentially colonizedifferent surfaces in the oral cavity as a result of specificadhesins on the bacterial surface binding to complementary specificreceptors on a given oral surface (11, 12). Indeed, the profilesof 40 cultivable bacterial species differed markedly on differentoral soft tissue surfaces, saliva, and supragingival and subgingivalplaques from healthy subjects (19). The purpose of this studywas to define the predominant bacterial flora of the healthyoral cavity by identifying and comparing the cultivable andthe not-yet-cultivated bacterial species on different soft tissuesand supra- and subgingival plaques.

Based on the analysis of 2,589 16S rRNA clones, the bacterialdiversity of the microflora from nine different sites of fiveclinically healthy subjects was striking—a total of 141different bacterial taxa representing six different bacterialphyla were detected. The six phyla included the Firmicutes (previouslyreferred to as the low-G+C gram positives, such as species ofStreptococcus, Gemella, Eubacterium, Selenomonas, Veillonella,and related ones), the Actinobacteria (previously referred toas the high-G+C gram positives, such as species of Actinomyces,Atopobium, Rothia, and related ones), the Proteobacteria (e.g.,species of Neisseria, Eikenella, Campylobacter, and relatedones), the Bacteroidetes (e.g., species of Porphyromonas, Prevotella,Capnocytophaga, and related ones), the Fusobacteria (e.g., speciesof Fusobacterium and Leptotrichia), and the TM7 phylum, forwhich there are no cultivable representatives. As determinedin our previous studies using culture-independent moleculartechniques (15, 21, 22), over 60% of the bacterial flora wasrepresented by not-yet-cultivated phylotypes. Thirteen new phylotypes(see Fig. 2 through 9) were identified for the first time inthis study. In a comparable ongoing study of caries in permanentteeth, using the same techniques, we detected 224 species inthe analysis of 1,275 16S rRNA clones with about 60% as not-yet-cultivablephylotypes (J. A. Aas, S. R. Dardis, A. L. Griffen, L. N. Stokes,A. M. Lee, I. Olsen, F. E. Dewhirst, E. J. Leys, and B. J. Paster.J. Dent. Res. 84:abstract 2805, 2005). Consequently, it is importantto identify both the cultivable and not-yet-cultivated bacterialflora in a given environment before we can ascribe associationto health or disease status. There is no evidence to suggestthat the not-yet-cultivated segment is any less important thanthe cultivable segment.

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FIG. 2. Bacterial profiles of the maxillary anterior vestibule of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are as described for Fig. 1. Novel phylotypes identified in this study are indicated in bold. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

Bacterial profiles for each site tested for each subject areshown in nine phylogenetic trees (see Fig. 1 through 9). Inthese dendrograms, the distribution of bacterial species orphylotypes in each subject can be observed at a glance. Forexample, it is clear that Streptococcus mitis, S. mitis bv.2, and Gemella hemolysans are the predominant species of thebuccal epithelium (Fig. 1). Each of these species was detectedin most or all of the subjects and represented $≥$ 15% of the totalnumber of assayed clones (Fig. 1). Similarly, the predominantbacterial flora for the other eight oral sites was examined.In the maxillary anterior vestibule, S. mitis, Granulicatellaspp., and Gemella spp. predominated (Fig. 2). On the tonguedorsum, several species of Streptococcus, such as S. mitis,Streptococcus australis, Streptococcus parasanguinis, Streptococcussalivarius, Streptococcus sp. clone FP015, and Streptococcussp. clone FN051, Granulicatella adiacens, and Veillonella spp.were the predominant species (Fig. 3). On the lateral tonguesurface (Fig. 4), S. mitis, S. mitis bv. 2, Streptococcus sp.clone DP009, Streptococcus sp. clone FN051, S. australis, G.adiacens, G. hemolysans, and Veillonella spp. predominated.It is interesting that there were considerable differences inthe bacterial profiles of the tongue dorsum and the lateraltongue surface. For example, S. mitis bv. 2 was well representedat the lateral side of the tongue but not detected on the tonguedorsum. Conversely, S.parasanguinis strain 85-81 was presenton the tongue dorsum, but was absent on the lateral side. Thiswas not surprising, because these surfaces are known to be differentin ultrastructure and function. For instance, the lateral sideof the tongue has a smooth nonkeratinized surface, in contrastto the dorsum of the tongue, which is a keratinized, highlypapillated surface with a large surface area and underlyingserous glands. These anatomic differences likely influence theecology of these habitats and create microbial environmentaldifferences.

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FIG. 3. Bacterial profiles of the tongue dorsum of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are as described for Fig. 1. Novel phylotypes identified in this study are indicated in bold. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

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FIG. 4. Bacterial profiles of the lateral tongue surface of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are as described for Fig. 1. Novel phylotypes identified in this study are indicated in bold. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

On the hard palate, the predominant bacterial species includedS. mitis, S. mitis biovar 2, Streptococcus sp. clone FN051,Streptococcus infantis, Granulicatella elegans, G. hemolysans,and Neisseria subflava (Fig. 5). On the soft palate, S. mitis,other cultivable and not-yet-cultivable species of Streptococcus,G. adiacens and G. hemolysans were predominant (Fig. 6). Thetonsil bacterial flora (Fig. 7) was rather diverse—somesubjects had Prevotella and Porphyromonas spp. (subjects 1 and5), and others had Firmicutes species (subjects 2, 3, and 4).On the tooth surface, several species of Streptococcus, includingStreptococcus sp. clone EK048, S. sanguinis, and S. gordonii,and Rothia dentocariosa, G. hemolysans, G. adiacens, Actinomycessp. clone BL008, and Abiotrophia defectiva were often detected(Fig. 8). Finally, in subgingival plaque, several species ofStreptococcus and Gemella were often found (Fig. 9).

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FIG. 5. Bacterial profiles of the hard palate of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are as described for Fig. 1. Novel phylotypes identified in this study are indicated in bold. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

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FIG. 6. Bacterial profiles of the soft palate of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are as described for Fig. 1. Novel phylotypes identified in this study are indicated in bold. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

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FIG. 7. Bacterial profiles of the tonsils of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are as described for Fig. 1. Novel phylotypes identified in this study are indicated in bold. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

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FIG. 8. Bacterial profiles of the tooth surfaces of healthy subjects. Distribution and levels of bacterial species/phylotypes among five subjects are as described for Fig. 1. Novel phylotypes identified in this study are indicated in bold. GenBank accession numbers are provided. Marker bar represents a 5% difference in nucleotide sequences.

The number of cultivable and not-yet-cultivable species detectedin each subject for each site is also shown in Fig. 1 through9. For example, in Fig. 1, only four species (S. mitis, S.mitisbv. 2, A. defectiva, and G. hemolysans) were detected on thebuccal epithelium in subject 5. For convenience, the numberof bacterial species detected in each oral site for each subjectis summarized in Table 1. Surprisingly, the highest number ofdifferent species was found on the tonsils in subject 1, with28 predominant species; collectively, 57 species were detectedon the tonsils (Table 1; Fig. 7). In contrast, the maxillaryanterior vestibule had the lowest diversity of the bacterialflora compared with the other sites, with as few as three tonine species detected among the subjects (Table 1; Fig. 2).A common question asked is how many bacterial species are presentin the oral cavity of a single individual. The last column ofTable 1 indicates the number of predominant species in eachhealthy individual from all nine different sites; thus, thenumbers ranged from a low of 34 in subject 4 to a high of 72in subject 3.

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TABLE 1. Number of predominant bacterial species per site and subject

Overall, cultivable and not-yet-cultivable species of Gemella,Granulicatella, Streptococcus, and Veillonella were commonlydetected in most sites. S. mitis was the most commonly foundspecies in essentially all sites and subjects (Fig. 1 through9). In one subject, 79% of the clones identified were S. mitis(data not shown in figures). Note that in this study, S. mitisand Streptococcus pneumoniae have been grouped together. Somemembers of the mitis group share more than 99% 16S rRNA sequencesimilarity, although DNA-DNA similarity values for the entirechromosomes are estimated to be less than 60% (14). Both S.mitis and Streptococcus oralis have been associated with bacterialendocarditis, especially in patients with prosthetic valves(9). In addition, they are now recognized as frequent causesof infection in immunocompromised patients, particularly immediatelyafter tissue transplants and in neutropenic cancer patients(30). G. adiacens, often considered an opportunistic pathogen,was also detected at all sites in the healthy oral cavity. G.adiacens isolates have been reported from bacteremia/septicemiain patients with infective endocarditis/atheroma (33) and inprimary bacteremia in patients with neutropenic fever (33).A high mortality rate for endocarditis by G. adiacens has beenreported (5).

Figure 10 represents the overall summary of this study—namely,that there are emerging bacterial profiles that help definethe healthy oral cavity. As already discussed, several species,such as S. mitis and G. adiacens, were detected in most or alloral sites, whereas several species were quite site specific.For example, R. dentocariosa, Actinomyces spp., S. sanguinis,S.gordonii, and A. defectiva appeared to preferentially colonizethe teeth, while S. salivarius was found mostly on the tonguedorsum. Some species appeared to have a predilection for softtissue, e.g., S. sanguinis and S. australis did not colonizethe teeth or subgingival crevice. S. intermedius preferentiallycolonized the subgingival plaque in most of the subjects butwas not detected in most other sites. On the other hand, Neisseriaspp. were not found in subgingival plaque but were present inmost other sites. Simonsiella muelleri colonized only the hardpalate. Indeed, S. muelleri was initially isolated from thehuman hard palate (32), although it has been isolated from aneonate with dental cyst and early eruption of teeth (31). SeveralPrevotella species were detected in most sites, but only inone or two subjects. For example, P. melaninogenica and Prevotellasp. clone BE073 were abundant in seven out of nine sites ofone subject and were detected sporadically in other subjects(Fig. 10). Prevotella sp. clone HF050 was found in the maxillaryanterior vestibule of one subject, dominating the bacterialflora as 44% of the clones (Fig. 2 and 10). This clone was alsofound in lower proportions on the soft palate and tonsils ofanother subject (Fig. 6, 7, and 10).

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FIG. 10. Site specificity of predominant bacterial species in the oral cavity. In general, bacterial species or phylotypes were selected on the basis of their detection in multiple subjects for a given site. Distributions of bacterial species in oral sites among subjects are indicated by the columns of boxes to the right of the tree as follows: not detected in any subject (clear box), <15% of the total number of clones assayed (yellow box), $≥$ 15% of the total number of clones assayed (green box). The 15% cutoff for low and high abundance was chosen arbitrarily. Marker bar represents a 10% difference in nucleotide sequences.

In conclusion, there is a distinctive bacterial flora in thehealthy oral cavity which is different from that of oral disease.For example, many species specifically associated with periodontaldisease, such as Porphyromonas gingivalis, Tannerella forsythia,and Treponema denticola, were not detected in any sites tested.In addition, the bacterial flora commonly thought to be involvedin dental caries and deep dentin cavities, represented by Streptococcusmutans, Lactobacillus spp., Bifidobacterium spp., and Atopobiumspp., were not detected in supra- and subgingival plaques fromclinically healthy teeth. A more detailed description of bacterialspecies associated with oral disease is discussed elsewhere(17). As noted in this study on healthy subjects, some speciesare site specific at one or multiple sites, while other speciesare subject specific. As much as 60% of the species detectedare not presently cultivable. Overall, there are still morespecies to be discovered, although the number of new speciesis beginning to reach saturation.

As we have previously asserted (21), to rigorously assess theassociation of specific species or phylotypes with oral healthor disease, it is necessary to analyze larger numbers of clinicalsamples for the levels of essentially all oral bacteria in well-controlledclinical studies. The bacterial complexes involved in periodontaldisease as defined by Socransky et al. (27) were based on themicrobial analyses of 185 subjects representing about 13,000plaque samples using DNA probes to 40 bacterial cultivable speciesin checkerboard hybridization assays. We are currently developingDNA probes for approximately 500 known bacterial species andnovel phylotypes for use in similar studies. These DNA probesare being developed for use in the checkerboard hybridizationassay (3, 22, 23) and DNA microarray formats (S. K. Boches,A. M. Lee, B. J. Paster, and F. E. Dewhirst, J. Dent. Res. 83:abstract2263, 2004). Our intent was to first establish the full bacterialdiversity of the oral cavity and then to determine variationand reproducibility using the microarrays. Consequently, itwill be relatively easy to compare the bacterial compositionof a statistically significant number of samples to more preciselyidentify those species that are associated with health and withoral disease from different anatomic sites. It is necessaryto first define the bacterial flora of the healthy oral cavitybefore we can determine the role of oral bacteria in disease.

ACKNOWLEDGMENTS

This study was supported by NIH grant DE-11443 from the NationalInstitute of Dental and Craniofacial Research and grants fromthe Dental Faculty, University of Oslo, Norway.

FOOTNOTES

* Corresponding author. Mailing address: Institute of Oral Biology, University of Oslo, Postbox 1052 Blindern, 0316 Oslo, Norway. Phone: (47) 22840343. Fax: (47) 22840305. E-mail: jornaaas{at}odont.uio.no.

REFERENCES

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