Second Era of OMICS in Caries Research: Moving Past the Phase of Disillusionment
Abstract
Novel approaches using OMICS techniques enable a collective assessment of multiple related biological units, including genes, gene expression, proteins, and metabolites. In the past decade, next-generation sequencing (NGS) technologies were improved by longer sequence reads and the development of genome databases and user-friendly pipelines for data analysis, all accessible at lower cost. This has generated an outburst of high-throughput data. The application of OMICS has provided more depth to existing hypotheses as well as new insights in the etiology of dental caries. For example, the determination of complete bacterial microbiomes of oral samples rather than selected species, together with oral metatranscriptome and metabolome analyses, supports the viewpoint of dysbiosis of the supragingival biofilms. In addition, metabolome studies have been instrumental in disclosing the contributions of major pathways for central carbon and amino acid metabolisms to biofilm pH homeostasis. New, often noncultured, oral streptococci have been identified, and their phenotypic characterization has revealed candidates for probiotic therapy. Although findings from OMICS research have been greatly informative, problems related to study design, data quality, integration, and reproducibility still need to be addressed. Also, the emergence and continuous updates of these computationally demanding technologies require expertise in advanced bioinformatics for reliable interpretation of data. Despite the obstacles cited above, OMICS research is expected to encourage the discovery of novel caries biomarkers and the development of next-generation diagnostics and therapies for caries control. These observations apply equally to the study of other oral diseases.
Get full access to this article
View all access and purchase options for this article.
References
Aas JA, Griffen AL, Dardis SR, Lee AM, Olsen I, Dewhirst FE, Leys EJ, Paster BJ. 2008. Bacteria of dental caries in primary and permanent teeth in children and young adults. J Clin Microbiol. 46(4):1407–1417.
Abusleme L, Hong BY, Dupuy AK, Strausbaugh LD, Diaz PI. 2014. Influence of DNA extraction on oral microbial profiles obtained via 16s rRNA gene sequencing. J Oral Microbiol. 6:23990.
Baba T, Ara T, Hasegawa M, Takai Y, Okumura Y, Baba M, Datsenko KA, Tomita M, Wanner BL, Mori H. 2006. Construction of Escherichia coli k-12 in-frame, single-gene knockout mutants: the Keio collection. Mol Syst Biol. 2:2006.0008.
Barriuso J, Valverde JR, Mellado RP. 2011. Estimation of bacterial diversity using next generation sequencing of 16s rDNA: a comparison of different workflows. BMC Bioinformatics. 12:473.
Becker MR, Paster BJ, Leys EJ, Moeschberger ML, Kenyon SG, Galvin JL, Boches SK, Dewhirst FE, Griffen AL. 2002. Molecular analysis of bacterial species associated with childhood caries. J Clin Microbiol. 40(3):1001–1009.
Belda-Ferre P, Alcaraz LD, Cabrera-Rubio R, Romero H, Simón-Soro A, Pignatelli M, Mira A. 2012. The oral metagenome in health and disease. ISME J. 6(1):46–56.
Belda-Ferre P, Williamson J, Simón-Soro A, Artacho A, Jensen ON, Mira A. 2015. The human oral metaproteome reveals potential biomarkers for caries disease. Proteomics. 15(20):3497–3507.
Belstrom D, Jersie-Christensen RR, Lyon D, Damgaard C, Jensen LJ, Holmstrup P, Olsen JV. 2016. Metaproteomics of saliva identifies human protein markers specific for individuals with periodontitis and dental caries compared to orally healthy controls. PeerJ. 4:e2433.
Benítez-Páez A, Belda-Ferre P, Simón-Soro A, Mira A. 2014. Microbiota diversity and gene expression dynamics in human oral biofilms. BMC Genomics. 15:311.
Benítez-Páez A, Portune KJ, Sanz Y. 2016. Species-level resolution of 16s rRNA gene amplicons sequenced through the minion portable nanopore sequencer. Gigascience. 5:4.
Bonder MJ, Abeln S, Zaura E, Brandt BW. 2012. Comparing clustering and pre-processing in taxonomy analysis. Bioinformatics. 28(22):2891–2897.
Brooks JP. 2016. Challenges for case-control studies with microbiome data. Ann Epidemiol. 26(5):336–341.
Camelo-Castillo A, Benitez-Paez A, Belda-Ferre P, Cabrera-Rubio R, Mira A. 2014. Streptococcus dentisani sp. nov., a novel member of the mitis group. Int J Syst Evol Microbiol. 64(Pt 1):60–65.
Carlsson J. 1986. Metabolic activities of oral bacteria. In: Thylstrup A CFO, editor. Textbook of cariology. Copenhagen (Denmark): Munksgaard. p. 74–106.
Casiano-Colón A, Marquis RE. 1988. Role of the arginine deiminase system in protecting oral bacteria and an enzymatic basis for acid tolerance. Appl Environ Microbiol. 54(6):1318–1324.
Chen T, Yu WH, Izard J, Baranova OV, Lakshmanan A, Dewhirst FE. 2010. The human oral microbiome database: a web accessible resource for investigating oral microbe taxonomic and genomic information. Database (Oxford). 2010:baq013.
Duran-Pinedo AE, Frias-Lopez J. 2015. Beyond microbial community composition: functional activities of the oral microbiome in health and disease. Microbes Infect. 17(7):505–516.
Edlund A, Yang Y, Yooseph S, Hall AP, Nguyen DD, Dorrestein PC, Nelson KE, He X, Lux R, Shi W, et al. 2015. Meta-omics uncover temporal regulation of pathways across oral microbiome genera during in vitro sugar metabolism. ISME J. 9(12):2605–2619.
Faust K, Lahti L, Gonze D, de Vos WM, Raes J. 2015. Metagenomics meets time series analysis: unraveling microbial community dynamics. Curr Opin Microbiol. 25:56–66.
Ferrer MD, Mira A. 2016. Oral biofilm architecture at the microbial scale. Trends Microbiol. 24(4):246–248.
Gevers D, Knight R, Petrosino JF, Huang K, McGuire AL, Birren BW, Nelson KE, White O, Methe BA, Huttenhower C. 2012. The human microbiome project: a community resource for the healthy human microbiome. PLoS Biol. 10(8):e1001377.
Griffen AL, Beall CJ, Campbell JH, Firestone ND, Kumar PS, Yang ZK, Podar M, Leys EJ. 2012. Distinct and complex bacterial profiles in human periodontitis and health revealed by 16s pyrosequencing. ISME J. 6(6):1176–1185.
Griffen AL, Beall CJ, Firestone ND, Gross EL, Difranco JM, Hardman JH, Vriesendorp B, Faust RA, Janies DA, Leys EJ. 2011. Core: a phylogenetically-curated 16s rDNA database of the core oral microbiome. PLoS One. 6(4):e19051.
Gross EL, Beall CJ, Kutsch SR, Firestone ND, Leys EJ, Griffen AL. 2012. Beyond Streptococcus mutans: dental caries onset linked to multiple species by 16s rRNA community analysis. PLoS One. 7(10):e47722.
Guha-Chowdhury N, Clark AG, Sissons CH. 1997. Inhibition of purified enolases from oral bacteria by fluoride. Oral Microbiol Immunol. 12(2):91–97.
Huang X, Palmer SR, Ahn SJ, Richards VP, Williams ML, Nascimento MM, Burne RA. 2016. A highly arginolytic streptococcus species that potently antagonizes Streptococcus mutans. Appl Environ Microbiol. 82(7):2187–2201.
Keegan KP, Glass EM, Meyer F. 2016. Mg-rast, a metagenomics service for analysis of microbial community structure and function. Methods Mol Biol. 1399:207–233.
Keijser BJ, Zaura E, Huse SM, van der Vossen JM, Schuren FH, Montijn RC, ten Cate JM, Crielaard W. 2008. Pyrosequencing analysis of the oral microflora of healthy adults. J Dent Res. 87(11):1016–1020.
Kelly BJ, Gross R, Bittinger K, Sherrill-Mix S, Lewis JD, Collman RG, Bushman FD, Li H. 2015. Power and sample-size estimation for microbiome studies using pairwise distances and permanova. Bioinformatics. 31(15):2461–2468.
Kurita-Ochiai T, Seto S, Suzuki N, Yamamoto M, Otsuka K, Abe K, Ochiai K. 2008. Butyric acid induces apoptosis in inflamed fibroblasts. J Dent Res. 87(1):51–55.
Lee CK, Herbold CW, Polson SW, Wommack KE, Williamson SJ, McDonald IR, Cary SC. 2012. Groundtruthing next-gen sequencing for microbial ecology-biases and errors in community structure estimates from PCR amplicon pyrosequencing. PLoS One. 7(9):e44224.
Markowitz VM, Chen IM, Palaniappan K, Chu K, Szeto E, Grechkin Y, Ratner A, Jacob B, Huang J, Williams P, et al. 2012. Img: The integrated microbial genomes database and comparative analysis system. Nucleic Acids Res. 40(Database issue):D115–D122.
Mark Welch JL, Rossetti BJ, Rieken CW, Dewhirst FE, Borisy GG. 2016. Biogeography of a human oral microbiome at the micron scale. Proc Natl Acad Sci USA. 113(6):E791–E800.
Marquis RE, Bender GR, Murray DR, Wong A. 1987. Arginine deiminase system and bacterial adaptation to acid environments. Appl Environ Microbiol. 53(1):198–200.
Marsh PD. 2006. Dental plaque as a biofilm and a microbial community—implications for health and disease. BMC Oral Health. 6(Suppl 1):S14.
Nascimento MM, Liu Y, Kalra R, Perry S, Adewumi A, Xu X, Primosch RE, Burne RA. 2013. Oral arginine metabolism may decrease the risk for dental caries in children. J Dent Res. 92(7):604–608.
Nobbs AH, Jenkinson HF, Jakubovics NS. 2011. Stick to your gums: mechanisms of oral microbial adherence. J Dent Res. 90(11):1271–1278.
Nossa CW, Oberdorf WE, Yang L, Aas JA, Paster BJ, Desantis TZ, Brodie EL, Malamud D, Poles MA, Pei Z. 2010. Design of 16S rRNA gene primers for 454 pyrosequencing of the human foregut microbiome. World J Gastroenterol. 16(33):4135–4144.
Ozok AR, Persoon IF, Huse SM, Keijser BJ, Wesselink PR, Crielaard W, Zaura E. 2012. Ecology of the microbiome of the infected root canal system: a comparison between apical and coronal root segments. Int Endod J. 45(6):530–541.
Prosser JI. 2010. Replicate or lie. Environ Microbiol. 12(7):1806–1810.
Quinn RA, Navas-Molina JA, Hyde ER, Song SJ, Vazquez-Baeza Y, Humphrey G, Gaffney J, Minich JJ, Melnik AV, Herschend J, et al. 2016. From sample to multi-omics conclusions in under 48 hours. mSystems. 1(2):pii:e00038-16.
Rotroff DM, Motsinger-Reif AA. 2016. Embracing integrative multiomics approaches. Int J Genomics. 2016:1715985.
Salzberg SL. 2007. Genome re-annotation: a wiki solution? Genome Biol. 8(1):102.
Segata N, Izard J, Waldron L, Gevers D, Miropolsky L, Garrett WS, Huttenhower C. 2011. Metagenomic biomarker discovery and explanation. Genome Biol. 12(6):R60.
Shaffer JR, Feingold E, Wang X, Lee M, Tcuenco K, Weeks DE, Weyant RJ, Crout R, McNeil DW, Marazita ML. 2013. GWAS of dental caries patterns in the permanent dentition. J Dent Res. 92(1):38–44.
Simón-Soro A, Belda-Ferre P, Cabrera-Rubio R, Alcaraz LD, Mira A. 2013. A tissue-dependent hypothesis of dental caries. Caries Res. 47(6):591–600.
Simón-Soro A, Mira A. 2015. Solving the etiology of dental caries. Trends Microbiol. 23(2):76–82.
Sogin ML, Morrison HG, Huber JA, Mark Welch D, Huse SM, Neal PR, Arrieta JM, Herndl GJ. 2006. Microbial diversity in the deep sea and the underexplored “rare biosphere.” Proc Natl Acad Sci USA. 103(32):12115–12120.
Takahashi N. 2015. Oral microbiome metabolism: from “who are they?” to “what are they doing?” J Dent Res. 94(12):1628–1637.
Takahashi N, Washio J. 2011. Metabolomic effects of xylitol and fluoride on plaque biofilm in vivo. J Dent Res. 90(12):1463–1468.
Takahashi N, Yamada T. 1999. Glucose and lactate metabolism by Actinomyces naeslundii. Crit Rev Oral Biol Med. 10(4):487–503.
Takahashi N, Yamada T. 2000. Pathways for amino acid metabolism by Prevotella intermedia and Prevotella nigrescens. Oral Microbiol Immunol. 15(2):96–102.
Tanner AC, Kressirer CA, Faller LL. 2016. Understanding caries from the oral microbiome perspective. J Calif Dent Assoc. 44(7):437–446.
Tanner AC, Mathney JM, Kent RL, Chalmers NI, Hughes CV, Loo CY, Pradhan N, Kanasi E, Hwang J, Dahlan MA, et al. 2011. Cultivable anaerobic microbiota of severe early childhood caries. J Clin Microbiol. 49(4):1464–1474.
van der Horst J, Buijs MJ, Laine ML, Wismeijer D, Loos BG, Crielaard W, Zaura E. 2013. Sterile paper points as a bacterial DNA-contamination source in microbiome profiles of clinical samples. J Dent. 41(12):1297–1301.
Vartoukian SR, Adamowska A, Lawlor M, Moazzez R, Dewhirst FE, Wade WG. 2016. In vitro cultivation of ‘unculturable’ oral bacteria, facilitated by community culture and media supplementation with siderophores. PLoS One. 11(1):e0146926.
Vincent AT, Derome N, Boyle B, Culley AI, Charette SJ. 2016. Next-generation sequencing (NGS) in the microbiological world: how to make the most of your money. J Microbiol Methods [epub ahead of print 16 Mar 2016] in press.
Wang J, Gao Y, Zhao F. 2016. Phage-bacteria interaction network in human oral microbiome. Environ Microbiol. 18(7):2143–2158.
Washio J, Ogawa T, Suzuki K, Tsukiboshi Y, Watanabe M, Takahashi N. 2016. Amino acid composition and amino acid-metabolic network in supragingival plaque. Biomed Res. 37(4):251–257.
Wright JT. 2010. Defining the contribution of genetics in the etiology of dental caries. J Dent Res. 89(11):1173–1174.
Zaura E, Brandt BW, Prodan A, Teixeira de, Mattos MJ, Imangaliyev S, Kool J, Buijs MJ, Jagers FL, Hennequin-Hoenderdos NL, Slot DE, et al. 2017. On the ecosystemic network of saliva in healthy young adults. ISME J. 11(5):1218-1231.
Zaura E, Keijser BJ, Huse SM, Crielaard W. 2009. Defining the healthy “core microbiome” of oral microbial communities. BMC Microbiol. 9:259.
Cite article
Cite article
Cite article
OR
Download to reference manager
If you have citation software installed, you can download article citation data to the citation manager of your choice
Information, rights and permissions
Information
Published In
Article first published online: April 6, 2017
Issue published: July 2017
Keywords
PubMed: 28384412
Authors
Metrics and citations
Metrics
Article usage*
Total views and downloads: 1419
*Article usage tracking started in December 2016
Altmetric
See the impact this article is making through the number of times it’s been read, and the Altmetric Score.
Learn more about the Altmetric Scores
Articles citing this one
Receive email alerts when this article is cited
Web of Science: 33 view articles Opens in new tab
Crossref: 44
- The oral microbiota and periodontal health in orthodontic patients
- Salivary Proteins and Metabolites as Caries Biomarkers in Adolescents
- Sweet Orange Juice Processing By-Product Extracts: A Caries Management Alternative to Chlorhexidine
- High conservation of the dental plaque microbiome across populations with differing subsistence strategies and levels of market integration
- Oral Microbiota Transplant: A Potential New Therapy for Oral Diseases
- ERKEN ÇOCUKLUK ÇAĞI ÇÜRÜĞÜ MİKROBİYOTASINDA GÜNCEL TÜRLER: DERLEMENOVEL SPECIES IN MICROBIOTA OF EARLY CHILDHOOD CARIES: A REVIEW
- Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo
- Precision dentistry—what it is, where it fails (yet), and how to get there
- Metataxonomic and metabolomic evidence of biofilm homeostasis disruption related to caries: An in vitro study
- Streptococcus dentisani is a common inhabitant of the oral microbiota worldwide and is found at higher levels in caries-free individuals
- View More
Figures and tables
Figures & Media
Tables
View Options
Access options
If you have access to journal content via a personal subscription, university, library, employer or society, select from the options below:
I am signed in as:
View my profileSign out
I can access personal subscriptions, purchases, paired institutional access and free tools such as favourite journals, email alerts and saved searches.
loading institutional access options
Alternatively, view purchase options below:
Purchase 24 hour online access to view and download content.
Access journal content via a DeepDyve subscription or find out more about this option.
