Article Menu

Export Article

More by Authors Links

Article Data

  • Views 719
  • Dowloads 167

Original Research

Open Access

Contribution of Streptococcus Mutans Virulence Factors and Saliva Agglutinating Capacity to Caries Susceptibility in Children: A Preliminary Study

  • Eloa Ramalho de Camargo1
  • Jonas Bitencourt Canalle2
  • Rodriguo Capozzoli2
  • Tanila Wood dos Santos1
  • Margareth Bulhman Ballini2
  • Lucio Fabio Caldas Ferraz1
  • Thaís Manzano Parisotto2
  • Michelle Darrieux1,*,

1Laboratório de Biologia Molecular de Microrganismos, Universidade São Francisco, Bragança Paulista, Brazil

2Universidade São Francisco, Bragança Paulista, Brazil

DOI: 10.17796/1053-4628-42.3.4 Vol.42,Issue 3,May 2018 pp.188-194

Published: 01 May 2018

*Corresponding Author(s): Michelle Darrieux E-mail: sampaiomichelle@uol.com.br

PDF (567.34 kB) View Full-text

Abstract

Background: Many factors contribute to caries development in humans, such as diet, host factors – including different saliva components – and the presence of acidogenic bacteria in the dental biofilm, particularly Streptococcus mutans (S. mutans). Despite the influence of S. mutans in caries, this bacterium is also prevalent among healthy individuals, suggesting the contribution of genetic variation on the cariogenic potential. Based on this hypothesis, the present work investigated the influence of S. mutans virulence factors and saliva agglutinating capacity on caries susceptibility in children. Study design: Saliva samples of 24 children from low income families (13 caries-free and 11 caries-active individuals) were collected and tested for their ability to agglutinate S. mutans. The bacteria were isolated from these samples and analyzed for the presence of the gene coding for mutacin IV (mut IV). Biofilm formation and acid tolerance were also investigated in both groups (caries-free and caries-active). Results: Saliva samples from caries-free children showed an increased capacity to agglutinate S. mutans (p=0.006). Also, bacteria isolated from the caries-free group formed less biofilm when compared to the caries-active group (p=0.04). The presence of mut IV gene did not differ between bacteria isolated from caries-free and caries-active individuals, nor did the ability to tolerate an acidic environment, which was the same for the two groups. Conclusions: Altogether, the results suggest that the adhesive properties of S. mutans and the agglutinating capacity of the saliva samples correlated with the presence of caries lesions in children.

Keywords

Streptococcus mutans, caries, mutacin, biofilm

Cite and Share

Eloa Ramalho de Camargo,Jonas Bitencourt Canalle,Rodriguo Capozzoli,Tanila Wood dos Santos,Margareth Bulhman Ballini,Lucio Fabio Caldas Ferraz,Thaís Manzano Parisotto,Michelle Darrieux. Contribution of Streptococcus Mutans Virulence Factors and Saliva Agglutinating Capacity to Caries Susceptibility in Children: A Preliminary Study. Journal of Clinical Pediatric Dentistry. 2018. 42(3);188-194.

URL:

https://www.jocpd.com/articles/10.17796/1053-4628-42.3.4

References

1. Bowen WH. Dental caries–not just holes in teeth! A perspective. Mol Oral Microbiol 31: 228-33, 2016.

2. Caufield PW. Dental caries – a transmissible and infectious disease revis-ited: a position paper. Pediatr Dent 19: 491-498, 1997.

3. Islam B, Khan SN, Khan AU. Dental caries: from infection to prevention. Med Sci Monit 13: 196-203, 2007.

4. Alaluusua S, Kleemola-Kujala E, Nystrom M, Evalahti M, Gronroos L. Caries in the primary teeth and salivary Streptococcus mutans and lacto-bacillus levels as indicators of caries in permanent teeth. Pediatr Dent 9: 126- 130, 1987.

5. Guo L, Shi W. Salivary biomarkers for caries risk assessment. J Calif Dent Assoc 41: 107-109, 2013.

6. Fejerskov O. Changing paradigms in concepts on dental caries: conse-quences for oral health care. Caries Res 38: 182-191, 2004.

7. Ingemansson Hultquist A, Lingstrom P, Bagesund M. Risk factors for early colonization of mutans streptococci–a multiple logistic regression analysis in Swedish 1-year-olds. BMC Oral Health 14: 147, 2014.

8. Lagerweij MD, van Loveren C. Declining Caries Trends: Are We Satisfied? Curr Oral Health Rep 2: 212-217, 2015.

9. Kishi M, Abe A, Kishi K, Ohara-Nemoto Y, Kimura S, Yonemitsu M. Relationship of quantitative salivary levels of Streptococcus mutans and S. sobrinus in mothers to caries status and colonization of mutans streptococci in plaque in their 2.5-year-old children. Community Dent Oral Epidemiol 37: 241-249, 2009.

10. Lapirattanakul J, Nakano K. Mother-to-child transmission of mutans strep-tococci. Future Microbiol 9: 807-823, 2014.

11. Marsh PD. Dental plaque: biological significance of a biofilm and commu-nity life-style. J Clin Periodontol 32: 7-15, 2005.

12. Hale JD, Ting YT, Jack RW, Tagg JR, Heng NC. Bacteriocin (mutacin) production by Streptococcus mutans genome sequence reference strain UA159: elucidation of the antimicrobial repertoire by genetic dissection. Appl Environ Microbiol 71: 7613-7617, 2005.

13. Yang Y, Li Y, Lin Y, Du M, Zhang P, Fan M. Comparison of immunolog-ical and microbiological characteristics in children and the elderly with or without dental caries. Eur J Oral Sci 123: 80-87, 2015.

14. Law V, Seow WK. A longitudinal controlled study of factors associated with mutans streptococci infection and caries lesion initiation in children 21 to 72 months old. Pediatr Dent 28: 58-65, 2006.

15. Saarela M, Hannula J, Matto J, Asikainen S, Alaluusua S. Typing of mutans streptococci by arbitrarily primed polymerase chain reaction. Arch Oral Biol 41: 821-826, 1996.

16. Beighton D, Rippon HR, Thomas HE. The distribution of Streptococcus mutans serotypes and dental caries in a group of 5- to 8-year-old Hampshire schoolchildren. Br Dent J 162: 103-106, 1987.

17. Law V, Seow WK, Townsend G. Factors influencing oral colonization of mutans streptococci in young children. Aust Dent J 52: 93-100, 2007.

18. Shen S, Samaranayake LP, Yip HK. In vitro growth, acidogenicity and cariogenicity of predominant human root caries flora. J Dent 32: 667-678, 2004.

19. Beighton D. The complex oral microflora of high-risk individuals and groups and its role in the caries process. Community Dent Oral Epidemiol 33: 248-255, 2005.

20. Kamiya RU, Taiete T, Goncalves RB. Mutacins of Streptococcus mutans. Braz J Microbiol 42: 1248-1258, 2011.

21. Napimoga MH, Kamiya RU, Rosa RT, et al. Genotypic diversity and virulence traits of Streptococcus mutans in caries-free and caries-active individuals. J Med Microbiol 53: 697-703, 2004.

22. Kirstila V, Hakkinen P, Jentsch H, Vilja P, Tenovuo J. Longitudinal analysis of the association of human salivary antimicrobial agents with caries incre-ment and cariogenic micro-organisms: a two-year cohort study. J Dent Res 77: 73-80, 1998.

23. Parisotto TM, King WF, Duque C, et al. Immunological and microbiologic changes during caries development in young children. Caries Res 45: 377- 385, 2011.

24. Levine MJ, Herzberg MC, Levine MS, et al. Specificity of salivary-bac-terial interactions: role of terminal sialic acid residues in the interaction of salivary glycoproteins with Streptococcus sanguis and Streptococcus mutans. Infect Immun 19: 107-115, 1978.

25. Levine M. Susceptibility to dental caries and the salivary proline-rich proteins. Int J Dent 2011: 953412, 2011.

26. Yu PL, Bixler D, Goodman PA, Azen EA, Karn RC. Human parotid proline-rich proteins: correlation of genetic polymorphisms to dental caries. Genet Epidemiol 3: 147-152, 1986.

27. Oral Health Surveys – Basic Methods. World Health Organization; 1997.

28. Hardie JM. Bergey’s Manual of Systematic Bacteriology. Ed Williams and Wilkins, Baltimore, 1986.

29. Welsh J, McClelland M. Fingerprinting genomes using PCR with arbitrary primers. Nucleic Acids Res 18: 7213-7218, 1990.

30. Kamiya RU, Napimoga MH, Hofling JF, Goncalves RB. Frequency of four different mutacin genes in Streptococcus mutans genotypes isolated from caries-free and caries-active individuals. J Med Microbiol 54: 599-604, 2005.

31. Qi F, Chen P, Caufield PW. The group I strain of Streptococcus mutans, UA140, produces both the lantibiotic mutacin I and a nonlantibiotic bacte-riocin, mutacin IV. Appl Environ Microbiol 67: 15-21, 2001.

32. Oho T, Yu H, Yamashita Y, Koga T. Binding of salivary glycoprotein-secre-tory immunoglobulin A complex to the surface protein antigen of Strepto-coccus mutans. Infect Immun 66: 115-121, 1998.

33. Banu LD, Conrads G, Rehrauer H, Hussain H, Allan E, van der Ploeg JR. The Streptococcus mutans serine/threonine kinase, PknB, regulates compe-tence development, bacteriocin production, and cell wall metabolism. Infect Immun 78: 2209-2220, 2010.

34. Hanna MN, Ferguson RJ, Li YH, Cvitkovitch DG. uvrA is an acid-induc-ible gene involved in the adaptive response to low pH in Streptococcus mutans. J Bacteriol 183: 5964-5973, 2001.

35. Nakano K, Fujita K, Nishimura K, Nomura R, Ooshima T. Contribution of biofilm regulatory protein A of Streptococcus mutans, to systemic viru-lence. Microbes Infect 7: 1246-1255, 2005.

36. Soukka T, Tenovuo J, Rundegren J. Agglutination of Streptococcus mutans serotype C cells but inhibition of Porphyromonas gingivalis autoaggrega-tion by human lactoferrin. Arch Oral Biol 38: 227-232, 1993.

37. Johansson I, Witkowska E, Kaveh B, Lif Holgerson P, Tanner AC. The Microbiome in Populations with a Low and High Prevalence of Caries. J Dent Res 95: 80-6, 2016.

38. Mattos-Graner RO, Li Y, Caufield PW, Duncan M, Smith DJ. Genotypic diversity of mutans streptococci in Brazilian nursery children suggests horizontal transmission. J Clin Microbiol 39: 2313-2316, 2001.

39. Mattos-Graner RO, Napimoga MH, Fukushima K, Duncan MJ, Smith DJ. Comparative analysis of Gtf isozyme production and diversity in isolates of Streptococcus mutans with different biofilm growth phenotypes. J Clin Microbiol 42: 4586-4592, 2004.

40. Alaluusua S, Matto J, Gronroos L, et al. Oral colonization by more than one clonal type of mutans streptococcus in children with nursing-bottle dental caries. Arch Oral Biol 41: 167-173, 1996.

41. Ghasempour M, Rajabnia R, Irannejad A, Hamzeh M, Ferdosi E, Bagheri M. Frequency, biofilm formation and acid susceptibility of streptococcus mutans and streptococcus sobrinus in saliva of preschool children with different levels of caries activity. Dent Res J 10: 440-445, 2013.

42. Kamiya RU, Hofling JF, Goncalves RB. Frequency and expression of mutacin biosynthesis genes in isolates of Streptococcus mutans with different mutacin-producing phenotypes. J Med Microbiol 57: 626-635, 2008.

43. Kamiya RU, Napimoga MH, Rosa RT, Hofling JF, Goncalves RB. Mutacin production in Streptococcus mutans genotypes isolated from caries-affected and caries-free individuals. Oral Microbiol Immunol 20: 20-24, 2005.

44. Matsui R, Cvitkovitch D. Acid tolerance mechanisms utilized by Strepto-coccus mutans. Future Microbiol 5: 403-417, 2010.

45. Malcolm J, Sherriff A, Lappin DF, et al. Salivary antimicrobial proteins associate with age-related changes in streptococcal composition in dental plaque. Mol Oral Microbiol 29: 284-293, 2014.

46. Ericson D. Agglutination of Streptococcus mutans by low-molecu-lar-weight salivary components: effect of beta 2-microglobulin. Infect Immun 46: 526-530, 1984.


Abstracted / indexed in

Science Citation Index Expanded (SciSearch) Created as SCI in 1964, Science Citation Index Expanded now indexes over 9,500 of the world’s most impactful journals across 178 scientific disciplines. More than 53 million records and 1.18 billion cited references date back from 1900 to present.

Biological Abstracts Easily discover critical journal coverage of the life sciences with Biological Abstracts, produced by the Web of Science Group, with topics ranging from botany to microbiology to pharmacology. Including BIOSIS indexing and MeSH terms, specialized indexing in Biological Abstracts helps you to discover more accurate, context-sensitive results.

Google Scholar Google Scholar is a freely accessible web search engine that indexes the full text or metadata of scholarly literature across an array of publishing formats and disciplines.

JournalSeek Genamics JournalSeek is the largest completely categorized database of freely available journal information available on the internet. The database presently contains 39226 titles. Journal information includes the description (aims and scope), journal abbreviation, journal homepage link, subject category and ISSN.

Current Contents - Clinical Medicine Current Contents - Clinical Medicine provides easy access to complete tables of contents, abstracts, bibliographic information and all other significant items in recently published issues from over 1,000 leading journals in clinical medicine.

BIOSIS Previews BIOSIS Previews is an English-language, bibliographic database service, with abstracts and citation indexing. It is part of Clarivate Analytics Web of Science suite. BIOSIS Previews indexes data from 1926 to the present.

Journal Citation Reports/Science Edition Journal Citation Reports/Science Edition aims to evaluate a journal’s value from multiple perspectives including the journal impact factor, descriptive data about a journal’s open access content as well as contributing authors, and provide readers a transparent and publisher-neutral data & statistics information about the journal.

Scopus: CiteScore 2.0 (2022) Scopus is Elsevier's abstract and citation database launched in 2004. Scopus covers nearly 36,377 titles (22,794 active titles and 13,583 Inactive titles) from approximately 11,678 publishers, of which 34,346 are peer-reviewed journals in top-level subject fields: life sciences, social sciences, physical sciences and health sciences.

Submission Turnaround Time

Conferences

Top