52

Dental Journal
(Majalah Kedokteran Gigi)

2021 March; 54(1): 52–56

Original article

Streptococcus mutans detection on mother-child pairs using 
matrix-assisted laser desorption ionization – time of flight mass 
spectrometry and polymerase chain reaction

Udijanto Tedjosasongko, Dwi Mulia Ramadhaniati and Seno Pradopo
Department of Pediatric Dentistry,
Faculty of Dental Medicine, Universitas Airlangga
Surabaya – Indonesia

ABSTRACT
Background: Streptococcus mutans (S. mutans) bacteria mainly cause dental caries in children. These bacteria are not considered 
oral indigenous bacteria since they are transmitted from people around children during their deciduous teeth eruption. The detection 
of these bacteria can be used for dental caries prevention in children. Purpose:  To determine the strain and serotype of S. mutans by 
using matrix assisted laser desorption ionization – time of flight mass spectrometry (MALDI-TOF MS) and polymerase chain reaction 
(PCR) on dental plaque samples taken from mother-child pairs. Methods: Sixteen dental plaque samples of mother-child pairs were 
cultured on brain heart infusion broth (BHIB) and mitis salivarius bacitracin (MSB) media until S. mutans colony isolates were obtained. 
Next, the isolates of S. mutans colony were introduced into the target plates of MALDI-TOF MS, and then ionized to become peptide 
mass fingerprint (PMF). Afterwards, the colony isolates were detected by database software. The detected S. mutans DNA then was 
extracted by using conventional 727 bp PCR (serotype C). Results: Six strains of S. mutans were detected by MALDI-TOF MS method. 
Five samples were classified into UA159, two samples were 3SN1, two samples were NFSM1, two samples were 11A1, two samples 
were U138, two samples were 4SM1, and one sample was classified into another bacterium. Five out of 16 samples were detected by 
PCR as serotype C (UA159). Conclusion: Six strains of S. mutans were detected, namely UA159, 3SN1, NFSM1, 11A1, U138, and 
4SM1, one of them (UA159) was detected as serotype C.

Keywords: MALDI-TOF MS; mother-child pairs; PCR; Streptococcus mutans

Correspondence: Udijanto Tedjosasongko, Department of Pediatric Dentistry, Faculty of Dental Medicine, Universitas Airlangga.            
Jl. Mayjen Prof. Dr. Moestopo No. 47 Surabaya, 60132 Indonesia. Email: udijanto@fkg.unair.ac.id

INTRODUCTION 

Dental caries is an infectious disease that can transmit 
from one to another.1,2 Children have high dental caries 
prevalence.3,4 Dental caries is considered a significant 
unsolved problem. Moreover, it is a multifactorial disease 
since it is triggered by several interrelated factors including 
Streptococcus mutans (S. mutans) bacteria which are 
the most influential microorganisms in dental caries 
formation with a percentage of 45% in dental plaque.5,6 
The polysaccharide composition of S. mutans’ extracellular 
layer enhances their survival rate in a very low plaque pH 
as to why S. mutans bacteria have high virulence besides 
being in high colonies that promote their environmental 

transmission.5 Caufield et al.7 described the concept 
“window of infectivity” as an early vulnerable period during 
which infants acquired S. mutans at the age between 19 and 
31 months. Furthermore, another research argued that S. 
mutans colonization in the child’s mouth starts with first 
tooth eruption and continues to grow with age.7 However, 
this is closely related to the mother’s oral cavity state since 
the mother is considered the primary child’s caregiver with 
the highest contact frequency.8,9

Strain is a single colony progeny or subculture that has 
been isolated in pure culture. Most individuals have one S. 
mutans strain but some may have 1-4 S. mutans strains.10 
However, since S. mutans strains have similarities and 
differences, they may be used to identify the kinship.11                   

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i1.p52–56

mailto:udijanto@fkg.unair.ac.id
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53Tedjosasongko et al./Dent. J. (Majalah Kedokteran Gigi) 2021 March; 54(1): 52–56

On the other hand, subspecies microorganism marking 
based on its antigenic component is called serotype 
(serovar). S. mutans is classified into serotypes C, E, F, and 
K. Serotype C S. mutans is the most abundant in the human 
oral cavity with a complex rhamnose-glucose-polymer 
(RGP) structure which is responsible for S. mutans survival, 
attachment, and colonization in the oral cavity.2,12,13

Matrix assisted laser desorption ionization – time 
of flight mass spectrometry (MALDI-TOF MS) is an 
alternative detecting microorganisms’ method with relative 
higher speed, more sensitivity and specificity, simpler work 
procedure, less laboratory equipment requirement, and 
lower cost compared to other molecular and immunological 
based methods.14–16 This method has been widely used by 
microbiologists for several purposes including identification 
of strains and taxonomic microorganisms (bacteria, viruses, 
and fungi), and epidemiological studies in addition to 
detection of bioterrorism, water and food pathogens, and 
antibiotic resistance, etc.15,16  MALDI-TOF MS method’s 
principles of strains and taxonomic microorganisms’ 
identification are based on the generated peptide mass 
fingerprint (PMF) by samples. The unknown organisms can 
be identified whether by comparing their PMF with existed 
database PMF or by matching their biomarker mass with 
proteomic databases.16–18

Recently, microorganism detection is conducted mainly 
by molecular methods such as polymerase chain reaction 
(PCR) followed by DNA sequencing which is considered 
the gold standard method in detecting and identifying 
microorganisms up to chromosome DNA level.19,20 
Furthermore, this method has the highest sensitivity and 
specificity, which is fast and accurate (100%). Therefore, 
this research aimed to determine the strain and serotype of 
S. mutans using MALDI-TOF MS and PCR methods on 
dental plaque samples taken from mother-child pairs.

MATERIALS AND METHODS

The research samples were dental plaque taken from 16 
subjects in Jagiran Tambaksari area in Surabaya. The 
subjects were eight mother-child pairs; the children were 
younger than 2 years old, the pairs were healthy and did 
not consume antibiotics and corticosteroid drugs while the 
mothers had DMF-T index of more than 2.7, and were willing 
to participate in the research signing the informed consents. 
The ethical clearance certificate was submitted by the 
ethical clearance committee of Faculty of Dental Medicine, 
Universitas Airlangga (No. 77/KKEPK.FKG/VI/2016).

The research was conducted at the Institute of Tropical 
Disease (ITD), Universitas Airlangga. The plaque 
samples were taken by brushing method for maxillary and 
mandibular teeth surfaces, including the tongue, using 
sterile toothbrushes.8 After that, the plaque was added to 
the brain heart infusion broth (BHIB) liquid media and 
incubated at 37°C for 48 hours. Thereafter, the plaque 
samples were cultured on mitis salivarius bacitracin (MSB) 

media and incubated anaerobically at 37°C for 48 hours 
using Gas-Pack anaerobic jars. Subsequently, a solitary 
colony from the incubated samples was taken carefully 
using a stick and cultured on the second BHIB media tubes. 
All tubes with S. mutans colonies then were incubated again 
at 37°C for 48 hours. 

After the incubation process, the S. mutans colonies 
were re-cultured by diffusing them in a zigzag pattern on the 
second MSB media, in which each Petri dish was divided 
into 4 parts for 4 samples. The second MSB media then were 
incubated anaerobically at 37°C for 48 hours using Gas-
Pack anaerobic jars. Next, the morphology of each sample 
on the second MSB media was examined under an inverted 
microscope (Olympus CK 128, Tokyo, Japan) to ascertain 
whether the emerged bacterial colonies were S. mutans or 
not. Afterward, a solitary colony was taken carefully using 
a stick to transfer it to the third BHIB media tubes and then 
was incubated at 37°C for 48 hours. After that, the tubes 
were vortexed to be homogeneous, and each sample was 
then transferred into two different sterile eppendorf tubes 
with a size of 2 ml micropipette. One eppendorf tube was 
used as a sample for the MALDI-TOF MS process,17 while 
the other eppendorf tube was used as a sample for the PCR 
process.

In the MALDI-TOF MS process, the eppendorf tubes 
samples were diluted with 3 ml of 0.45% NaCl, then 
introduced to the target plates, and mixed with reagents 
including a matrix (mixture of water and organic solvent) 
of acetonitrile and strong acid (Trifluoroacetate - TFA), as 
well as a matrix of 3,5-dimethoxy-4-hydroxycinnamic acid 
(Sinapic acid). Next, they were dried. After that, the target 
plates were inserted into the MALDI-TOF MS machine 
(Vitex, bioMérieux S.A, Marcy l’Étoile, France) to match 
the microorganisms with the software existing data. Then, 
the results were printed.18

In the PCR process, the eppendorf tube samples 
containing DNA were isolated with the DNA Isolation 
Purification Kit Wizard (Wizard® Genomic DNA 
Purification Kit, Promega Corporation, Singapore) to 
obtain the DNA extract of each sample.  Next, each DNA 
extract was processed by the conventional PCR process that 
performed in 25 cycles under initial denaturation at 96°C 
for 2 minutes. In Each cycle, they exposed to denaturation 
at 96°C for 15 seconds, annealing at 61°C for 30 seconds, 
extension at 72°C for 1 minute, and post extension at 72°C 
for 10 minutes using SC-F primer pairs (CGG AGT GCT 
TTT TAC AAG TGC TGG) and SC - R (AAC CAC GGC 
CAG CAA ACC CTT TAT) at site 727 bp.21 After that, 
DNA samples were processed by Bio-Rad T100 PCR 
Machine, California, USA. Subsequently, the PCR product 
was confirmed by 1% agarose gel electrophoresis (Mupid-
2plus) on a voltage of 90 volts for 30 minutes. After the 
electrophoresis process was completed, the gel was soaked 
into a 2% Ethidium Bromide immersion solution for 30 
minutes, and the PCR product then was visualized using 
a translucent UV to observe whether the band was in the 
predetermined location or not.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i1.p52–56

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http://dx.doi.org/10.20473/j.djmkg.v54.i1.p52-56


54 Tedjosasongko et al./Dent. J. (Majalah Kedokteran Gigi) 2021 March; 54(1): 52–56

RESULTS

There were 16 dental plaque samples taken from mother-
child pairs. After samples’ culturing on BHIB and MSB 
media, their morphology was tested using an inverted 
microscope (Olympus CK 128, Tokyo, Japan). The results 
showed round or ovoid single cubes with a 1-2 μm diameter 
arranged in chains.

The pure S. mutans isolation was processed on the Vitex 
machine (bioMérieux S.A, Marcy l’Étoile, France) using 
MALDI-TOF MS method to detect S. mutans strains. The 
results of the detection of S. mutans strain with MALDI-
TOF MS method are presented in Table 1.

During the PCR process, serotype C S. mutans was 
detected since serotype C is the most dominant serotype in 
the human oral cavity. The results of serotype C S. mutans 
detection with PCR method were shown in Figure 1. Based 
on PCR process results at the 727 bp amplification site, 
three samples which are line 1 (An 8), line 2 (Ib1), and line 
3 (Ib 4) samples were detected as serotype C S. mutans, 
while the other13 samples were not.

DISCUSSION 

The results of the S. mutans detection on the dental plaque 
samples of the mother-child pairs with MALDI-TOF MS 
approach showed six different strains of S. mutans with 
some samples had the same S. mutans strains. Gibbons et 
al.11 stated that the microorganism strains show similarities 
and differences among individuals, that is why the strain can 
be used to identify the individuals’ kinship. According to 
Klein et al.10  humans can have 1-4 strains of S. mutans in 
their oral cavity; at least one strain in each. The strains are 
varied among individuals according to their geographical 
locations, bacterial culture conditions (not significantly 
different), and the sample preparation methods.

The National Center for Biotechnology Information 
(NCBI) in 2016 recognized 172 strains of S. mutans.22 
These strains have been detected from complete previous 
studies. For instance, S. mutans UA 159 with ID Taxonomy 
637000288 and ID NCBI 21007 was officially announced 
on 1st December 2006 as a common facultative and 
pathogenic gram-positive cocci in the oral cavity of children 
with active caries , including serotype C S. mutans which 
is the sequencing status has already been studied.

Strain, according to Dijkshoorn et al,’s statement cited 
in Bergey’s Manual of Systemic Bacteriology, is a progeny 
or subculture of a solitary colony isolated in pure culture.23 
Furthermore, strain is divided into several types according 
to certain basic properties. First of all, biotype strain, in 
which the strain is classified based on the biochemical 
or physiological structure of species. Although biotype 
strain is often used to describe the species’ characteristics, 
it has not the capability to demonstrate the whole species 
properties. Therefore, other classifications, based on 
other criteria, were conducted such as morphotype strain 
(morphovar) in which the strain is grouped based on their 
morphology and serotype strain (serovars) in which the 
strain is classified based on antigenic structures, as well as 
patotype strain (patovars), or phagotype strain (fagovars) 
which are used sometimes to denote certain properties of 
strain variation.24,25  

S. mutans is classified based on its antigenic structure 
(cell wall carbohydrate specificity, H2O2 production, 
bacitracin sensitivity, fermented substrate, and DNA 
content) into four serotypes which are: serotype C, serotype 
E, serotype F, and serotype K.21,26,27 Serotype C S. mutans is 
the most common type in the human oral cavity, especially 
in dental plaque with a prevalence of 75-90%, since 
serotype C S. mutans has a complex RGP structure that 
enhances its survival, attachment, and colonization in the 
oral cavity.28 Therefore, S. mutans serotype C was selected 
in this research as S. mutans determinant.

Substantially, bacterial identification methods include 
the phenotypic method in which bacteria are classified 
based on their profile, metabolic properties, and chemical 
composition and the genotypic method in which bacteria 
are categorized according to their genetic material (DNA). 
In the phenotypic method, bacteria are taken from various 

727 bp 

500 bp 

   M     An8     Ib1     Ib4 

Figure 1. The results of the PCR process. Three samples were 
detected as serotype C S. mutans, i.e. An8, Ib 1, and 
Ib 4, while the other 13 samples were not.

Table 1. The results of S. mutans strain detection with MALDI-
TOF MS method

Samples Taxon Ids Name of the organism
Mother 1
Child 1

637000288
637000288

S. mutans UA159
S. mutans UA159

Mother 2
Child 2

2558860343
2558860343

S. mutans 3SN1
S. mutans 3SN1

Mother 3
Child 3

2558860323
2558860323

S. mutans NFSM1
S. mutans NFSM1

Mother 4
Child 4

637000288
2639762775

S. mutans UA159
S. gordonii IE35

Mother 5
Child 5

2558860348
2558860348

S. mutans 11a1
S. mutans 11a1

Mother 6
Child 6

2558860328
2558860328

S. mutans U138
S. mutans U138

Mother 7
Child 7

2558860342
2558860342

S. mutans 4SM1
S. mutans 4SM1

Mother 8
Child 8

637000288
637000288

S. mutans UA159
S. mutans UA159

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i1.p52–56

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55Tedjosasongko et al./Dent. J. (Majalah Kedokteran Gigi) 2021 March; 54(1): 52–56

specimens to be cultured, isolated, and then detected based 
on taxonomic principles. The microscopic observation, 
in which bacteria is detected based on shape, size, group, 
Gram staining reaction, and motility, should be combined 
with the natural environment data during the bacterial 
identification method. Bergey’s Manual of Determinative 
Bacteriology is an example of a guidebook that detects 
bacteria based on their microscopic and physiological 
characters. However, the phenotypic method can only 
distinguish genus from the same family members and cover 
some bacterial species, while the genotypic method has the 
capability to recognize the microorganism subtypes as to 
why modern taxonomy tend to use more complex detection 
method including molecular analysis.29,30

On the other hand, MALDI-TOF MS is considered 
an efficient analytical technique for detecting chemical 
structures in which chemical compounds are ionized into 
molecules based on the mass calculation of the molecule 
and its fragmentation pattern (m / z). This method is 
considered an alternative method in bacterial identification 
because of its advantageous characteristics including 
simplicity, fast result, high specificity and sensitivity, lower 
cost compared to the molecular and immunological method, 
and no laboratory requirements. Furthermore, this method is 
used for various purposes including identification of strain 
type, microbial taxonomy, bioterrorism, water and food 
pathogens, blood and urinary tract pathogens, and antibiotic 
resistance,  in addition to supporting the bacterial, fungal, 
and viral diseases diagnosis, etc.15,17,18

MALDI-TOF MS is based on PMF generated by 
samples to detect the strain type or the microbial taxonomy. 
Target samples that have been trapped and dissolved in the 
matrix solution would be exposed to laser spectrometry to 
undergo an ionization process turning them into PMF. PMF 
is used in the detection process by comparing unknown 
organisms PMF with the existing database PMF or by 
matching the unknown microorganism biomarkers mass 
with proteome databases. Furthermore, matching the 
sample PMF pattern with the ribosome protein PMF is 
required to detect some particular species’ microorganisms 
and their strain type. However, the PMF pattern matching in 
this method still has some limitations since the new isolates 
can be detected if the software database matches the sample 
PMF pattern. That is why the database of this method 
should be locally prepared for a specific taxonomy (e.g. 
Streptococcus or Staphylococcus) as to why geographical 
variations can occur among the genotype and phenotype 
of a microorganism.14,17,18

Recently, microorganisms identification tends to be 
more dependant on DNA sequencing approaches. For 
example, PCR and DNA sequencing methods become 
the “gold standard” in microorganism identification in 
modern taxonomy, defining phylogenies, and analyzing 
epidemiological studies ecosystem. Furthermore, this 
method is used for revealing bacterial evolution, constructing 
phylogenetic trees, tracing species diversity, and detecting 
new species without isolating the microorganisms. This 

method has many superior properties including the fast 
procedure, accurate result, high specificity and sensitivity 
reach to 100%, low vulnerability to contamination, and 
simultaneous detection for several microorganisms. 
However, this approach requires high cost, specific primary 
determinations, appropriate thermal cycles, and specialized 
expertise.29

Serotype C S. mutans, in particular, can be detected 
through serotype C primers wherein a specific primary PCR 
process will be encoded according to the nucleotide base 
sequence of a DNA sample. Thus, DNA samples that do 
not match with the nucleotide base sequence on the PCR 
primers will not be recognized or appeared in the amplified 
band. In this research, serotype C S. mutans were detected 
with SC-forward primers (CGG AGT GCT TTT TAC AAG 
TGC TGG) and SC-reverse primers (AAC CAC GGC CAG 
CAA ACC CTT TAT) at the amplification region of 727 
bp19. From the 16 S. mutans DNA samples, three samples 
were detected as serotype C S. mutans as follows: in line 1 
(Child 8), line 2 (Mother 1), and line 3 (Mother 4), while the 
other 13 samples were not identified as serotype C S. mutans 
since serotype C primers were the only used primers. The 
other 13 samples may follow other serotypes, such as 
serotype E S. mutans, serotype F S. mutans, etc., or genetic 
polymorphism of previously studied S. mutans.19,31

Genetic polymorphism is a variation in the microorganism 
DNA structure in which a change in the nucleotide base 
sequence is occurred due to the insertion, addition, or 
subtraction of a particular base.32  Genetic polymorphism is 
caused whether by the spontaneous gene mutations triggered 
by the normal cell function changes or by interaction with 
the environment. If the changes occur in only one base, 
referred to as point mutation, it can be inferred that the 
microorganism has been genetically polymorphed. Most 
point mutations occur as substitutions of G - C (Guanin - 
Cytosine) or A - T (adenine - thymine). 

In conclusion, there were six strains of S. mutans 
detected by MALDI-TOF MS method follows Five samples 
of S. mutans UA159, two samples of S. mutans 3SN1, two 
samples of S. mutans NFSM1, two samples of S. mutans 
11A1, two samples of S. mutans U138, and two samples of 
S. mutans 4SM1. However, UA159  was the only strain that 
was detected as serotype C by PCR method. It is expected 
to use these results as a basis for further researches related 
to early detection of dental caries, identification of new S. 
mutans isolates, and epidemiological studies.

REFERENCES

 1.  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. 2001; 
39(6): 2313–6. 

 2.  Baca P, Castillo A-M, Liébana M-J, Castillo F, Martín-Platero A, 
Liébana J. Horizontal transmission of Streptococcus mutans in 
schoolchildren. Med Oral Patol Oral Cir Bucal. 2012; 17(3): e495-
500. 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i1.p52–56

https://e-journal.unair.ac.id/MKG/index
http://dx.doi.org/10.20473/j.djmkg.v54.i1.p52-56


56 Tedjosasongko et al./Dent. J. (Majalah Kedokteran Gigi) 2021 March; 54(1): 52–56

 3.  Zou J, Meng M, Law CS, Rao Y, Zhou X. Common dental diseases 
in children and malocclusion. Int J Oral Sci. 2018; 10(1): 7. 

 4.  Pierce A, Singh S, Lee J, Grant C, Cruz de Jesus V, Schroth RJ. The 
burden of early childhood caries in Canadian children and associated 
risk factors. Front public Heal. 2019; 7: 328. 

 5.  Okada M, Soda Y, Hayashi F, Doi T, Suzuki J. PCR detection of 
Streptococcus mutans and S. sobrinus in dental plaque samples from 
Japanese pre-school children. J Med Micro. 2002; 51(5): 443–7. 

 6.  Jiang Q, Yu M, Min Z, Yi A, Chen D, Zhang Q. AP-PCR detection 
of Streptococcus mutans and Streptococcus sobrinus in caries-free     
and caries-active subjects. Mol Cell Biochem. 2012; 365(1–2): 
159–64. 

 7.  Caufield PW, Cutter GR, Dasanayake AP. Initial acquisition of 
mutans streptococci by infants: evidence for a discrete window of 
infectivity. J Dent Res. 1993; 72(1): 37–45. 

 8.  Tedjosasongko U, Kozai K. Initial acquisition and transmission of 
mutans streptococci in children at day nursery. ASDC J Dent Child. 
2002; 69(3): 284–8, 234–5. 

 9.  Hameş-Kocabaş EE, Uçar F, Kocataş Ersin N, Uzel A, Alpöz AR. 
Colonization and vertical transmission of Streptococcus mutans in 
Turkish children. Microbiol Res. 2008; 163(2): 168–72. 

10.  Klein MI, Flório FM, Pereira AC, Höfling JF, Gonçalves RB. 
Longitudinal study of transmission, diversity, and stability of 
Streptococcus mutans and Streptococcus sobrinus genotypes 
in Brazilian nursery children. J Clin Microbiol. 2004; 42(10): 
4620–6. 

11.  Gibbons RJ, Cohen L, Hay DI. Strains of Streptococcus mutans and 
Streptococcus sobrinus attach to different pellicle receptors. Infect 
Immun. 1986; 52(2): 555–61. 

12.  Pieralisi FJS, Rodrigues MR, Segura VG, Maciel SM, Ferreira FBA, 
Garcia JE, Poli-Frederico RC. Genotypic diversity of Streptococcus 
mutans in caries-free and caries-active preschool children. Int J Dent. 
2010; 2010: 1–5. 

13.  Damé-Teixeira N, Arthur RA, Parolo CCF, Maltz M. Genotypic 
diversity and virulence traits of Streptococcus mutans isolated from 
carious dentin after partial caries removal and sealing. Sci World J. 
2014; 2014: 1–6. 

14.  Murray PR. What is new in clinical microbiology-microbial 
identification by MALDI-TOF mass spectrometry: a paper from 
the 2011 William Beaumont Hospital Symposium on molecular 
pathology. J Mol Diagn. 2012; 14(5): 419–23. 

15.  Singhal N, Kumar M, Kanaujia PK, Virdi JS. MALDI-TOF mass 
spectrometry: an emerging technology for microbial identification 
and diagnosis. Front Microbiol. 2015; 6(AUG): 791. 

16.  Croxatto A, Prod’hom G, Greub G. Applications of MALDI-TOF 
mass spectrometry in clinical diagnostic microbiology. FEMS 
Microbiol Rev. 2012; 36(2): 380–407. 

17.  Cla rk A E, Kaleta EJ, A rora A, Wolk DM. Matr ix-assisted 
laser desorption ionization-time of flight mass spectrometry: a 
fundamental shift in the routine practice of clinical microbiology. 
Clin Microbiol Rev. 2013; 26(3): 547–603. 

18.  Bilecen K, Yaman G, Ciftci U, Laleli YR. Performances and 
reliability of Bruker Microf lex LT and VITEK MS MALDI-
TOF mass spectrometry systems for the identification of clinical 
microorganisms. Biomed Res Int. 2015; 2015: 516410. 

19.  Childers NK, Osgood RC, Hsu K-L, Manmontri C, Momeni 
SS, Mahtani HK, Cutter GR, Ruby JD. Real-time quantitative 

polymerase chain reaction for enumeration of Streptococcus mutans 
from oral samples. Eur J Oral Sci. 2011; 119(6): 447–54. 

20.  Gilbert K, Joseph R, Vo A, Patel T, Chaudhry S, Nguyen U, Trevor 
A, Robinson E, Campbell M, McLennan J, Houran F, Wong T, Flann 
K, Wages M, Palmer EA, Peterson J, Engle J, Maier T, Machida CA. 
Children with severe early childhood caries: streptococci genetic 
strains within carious and white spot lesions. J Oral Microbiol. 2014; 
6(1): 1–11. 

21.  Shibata Y, Ozaki K, Seki M, Kawato T, Tanaka H, Nakano Y, 
Yamashita Y. Analysis of loci required for determination of serotype 
antigenicity in Streptococcus mutans and its clinical utilization. J 
Clin Microbiol. 2003; 41(9): 4107–12. 

22.  Schoch CL, Ciufo S, Domrachev M, Hotton CL, Kannan S, 
Khovanskaya R, Leipe D, Mcveigh R, O’Neill K, Robbertse B, 
Sharma S, Soussov V, Sullivan JP, Sun L, Turner S, Karsch-Mizrachi 
I. NCBI Taxonomy: a comprehensive update on curation, resources 
and tools. Database (Oxford). 2020; 2020(2): 1–21. 

23.  Dijkshoorn L, Ursing BM, Ursing JB. Strain, clone and species: 
comments on three basic concepts of bacteriology. J Med Microbiol. 
2000; 49(5): 397–401. 

24.  Prescott LM, Harley JP, Klein DA. Microbial taxonomy. In: 
Microbiology. 5th ed. New York: McGraw-Hill; 2002. p. 422–
49. 

25.  Maki Y, Sakayori T, Hirata S, Ishii T, Tachino A. Monitoring caries 
risks before the window of infection and later caries increment: a 
caries prediction study on rapid detection of Streptococcus mutans 
using monoclonal antibodies. Bull Tokyo Dent Coll. 2014; 55(1): 
19–23. 

26.  Nakano K, Lapirattanakul J, Nomura R, Nemoto H, Alaluusua 
S, Grönroos L, Vaara M, Hamada S, Ooshima T, Nakagawa I. 
Streptococcus mutans clonal variation revealed by multilocus 
sequence typing. J Clin Microbiol. 2007; 45(8): 2616–25. 

27.  Nakano K, Nemoto H, Nomura R, Homma H, Yoshioka H, Shudo 
Y, Hata H, Toda K, Taniguchi K, Amano A, Ooshima T. Serotype 
distribution of Streptococcus mutans a pathogen of dental caries in 
cardiovascular specimens from Japanese patients. J Med Microbiol. 
2007; 56(4): 551–6. 

28.  Tabchoury CPM, Sousa MCK, Arthur RA, Mattos-Graner RO, 
Del Bel Cury AA, Cury JA. Evaluation of genotypic diversity of 
Streptococcus mutans using distinct arbitrary primers. J Appl Oral 
Sci. 2008; 16(6): 403–7. 

29.  Franco-Duarte R, Černáková L, Kadam S, S. Kaushik K, Salehi B, 
Bevilacqua A, Corbo MR, Antolak H, Dybka-Stępień K, Leszczewicz 
M, Relison Tintino S, Alexandrino de Souza VC, Sharifi-Rad J, Melo 
Coutinho HD, Martins N, Rodrigues CF. Advances in chemical 
and biological methods to identify microorganisms—from past to 
present. Microorganisms. 2019; 7(5): 130. 

30.  Sato T, Matsuyama J, Kumagai T, Mayanagi G, Yamaura M, Washio 
J, Takahashi N. Nested PCR for detection of mutans streptococci in 
dental plaque. Lett Appl Microbiol. 2003; 37(1): 66–9. 

31.  Kazemtabrizi A, Haddadi A, Shavandi M, Harzandi N. Metagenomic 
investigation of bacteria associated with dental lesions: A cross-
sectional study. Med Oral Patol Oral y Cir Bucal. 2020; 25(2): 
e240–51. 

32.  Williams JGK, Kubelik AR, Livak KJ, Rafalski JA, Tingey S V. 
DNA polymorphisms amplified by arbitrary primers are useful as 
genetic markers. Nucleic Acids Res. 1990; 18(22): 6531–5.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i1.p52–56

https://e-journal.unair.ac.id/MKG/index
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