Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Open Access

Peer-reviewed

Research Article

Candida albicans Carriage in Children with Severe Early Childhood Caries (S-ECC) and Maternal Relatedness

  • Jin Xiao ,

    jin_xiao@urmc.rochester.edu

    Affiliation Eastman Institute for Oral Health, University of Rochester Medical Center, Rochester, NY, United States of America

  • Yonghwi Moon,

    Affiliation Eastman Institute for Oral Health, University of Rochester Medical Center, Rochester, NY, United States of America

  • Lihua Li,

    Affiliation Department of Dentistry, North Sichuan Medical University, Sichuan, China

  • Elena Rustchenko,

    Affiliation Department of Biochemistry and Biophysics, University of Rochester Medical Center, Rochester, NY, United States of America

  • Hironao Wakabayashi,

    Affiliation Department of Biochemistry and Biophysics, University of Rochester Medical Center, Rochester, NY, United States of America

  • Xiaoyi Zhao,

    Affiliation School of Dentistry, Peking University, Beijing, China

  • Changyong Feng,

    Affiliation Department of Biostatistics and Computational Biology, University of Rochester Medical Center, Rochester, NY, United States of America

  • Steven R. Gill,

    Affiliation Genomics Research Center, University of Rochester Medical Center, Rochester, NY, United States of America

  • Sean McLaren,

    Affiliation Eastman Institute for Oral Health, University of Rochester Medical Center, Rochester, NY, United States of America

  • Hans Malmstrom,

    Affiliation Eastman Institute for Oral Health, University of Rochester Medical Center, Rochester, NY, United States of America

  • Yanfang Ren,

    Affiliation Eastman Institute for Oral Health, University of Rochester Medical Center, Rochester, NY, United States of America

  • Robert Quivey,

    Affiliation Eastman Institute for Oral Health, University of Rochester Medical Center, Rochester, NY, United States of America

  • Hyun Koo ,

    Contributed equally to this work with: Hyun Koo, Dorota T. Kopycka-Kedzierawski

    ‡ These authors are co-mentors for the manuscript writing and critical revisions on this work.

    Affiliation Department of Orthodontics and Pediatric Dentistry & Community Oral Health Divisions, School of Dental Medicine, University of Pennsylvania, Philadelphia, PA, United States of America

  • Dorota T. Kopycka-Kedzierawski

    Contributed equally to this work with: Hyun Koo, Dorota T. Kopycka-Kedzierawski

    ‡ These authors are co-mentors for the manuscript writing and critical revisions on this work.

    Affiliation Eastman Institute for Oral Health, University of Rochester Medical Center, Rochester, NY, United States of America

Abstract

Introduction

Candida albicans has been detected together with Streptococcus mutans in high numbers in plaque-biofilm from children with early childhood caries (ECC). The goal of this study was to examine the C. albicans carriage in children with severe early childhood caries (S-ECC) and the maternal relatedness.

Methods

Subjects in this pilot cross-sectional study were recruited based on a convenient sample. DMFT(S)/dmft(s) caries and plaque scores were assessed during a comprehensive oral exam. Social-demographic and related background information was collected through a questionnaire. Saliva and plaque sample from all children and mother subjects were collected. C. albicans were isolated by BBL CHROMagar and also identified using germ tube test. S. mutans was isolated using Mitis Salivarius with Bacitracin selective medium and identified by colony morphology. Genetic relatedness was examined using restriction endonuclease analysis of the C. albicans genome using BssHII (REAG-B). Multilocus sequence typing was used to examine the clustering information of isolated C. albicans. Spot assay was performed to examine the C. albicans Caspofungin susceptibility between S-ECC children and their mothers. All statistical analyses (power analysis for sample size, Spearman’s correlation coefficient and multiple regression analyses) were implemented with SAS 9.4

Results

A total of 18 S-ECC child-mother pairs and 17 caries free child-mother pairs were enrolled in the study. Results indicated high C. albicans carriage rate in the oral cavity (saliva and plaque) of both S-ECC children and their mothers (>80%). Spearman’s correlation coefficient also indicated a significant correlation between salivary and plaque C. albicans and S. mutans carriage (p<0.01) and caries severity (p<0.05). The levels of C. albicans in the prepared saliva and plaque sample (1ml resuspension) of S-ECC children were 1.3 ± 4.5 x104 cfu/ml and 1.2 ± 3.5 x104 cfu/ml (~3-log higher vs. caries-free children). Among 18 child-mother pairs, >60% of them demonstrated identical C. albicans REAG-B pattern. C. albicans isolated from >65% of child-mother pairs demonstrated similar susceptibility to caspofungin in spot assay, while no caspofungin resistant strains were seen when compared with C. albicans wild-type strain SC5314. Interestingly, the regression analysis showed that factors such as antibiotic usage, birth weight, inhaler use, brushing frequency, and daycare attendance had no significant effect on the oral carriage of C. albicans in the S-ECC children.

Conclusions

Our results reveal that both the child with S-ECC and the mother were highly infected with C. albicans, while most of the strains were genetically related, suggesting that the mother might be a source for C. albicans acquisition in the oral cavity of children affected by the disease.

Citation: Xiao J, Moon Y, Li L, Rustchenko E, Wakabayashi H, Zhao X, et al. (2016) Candida albicans Carriage in Children with Severe Early Childhood Caries (S-ECC) and Maternal Relatedness. PLoS ONE 11(10): e0164242. https://doi.org/10.1371/journal.pone.0164242

Editor: Marcelle Nascimento, University of Florida, UNITED STATES

Received: July 25, 2016; Accepted: August 26, 2016; Published: October 14, 2016

Copyright: © 2016 Xiao et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: Dr. Hyun Koo’s research in this area was supported in part by research grant 1R01DE025220-01 from the National Institute for Dental and Craniofacial Research, National Institutes of Health (NIDCR, NIH).

Competing interests: The authors have declared that no competing interests exist.

Introduction

Early childhood caries (ECC) is the single most common chronic childhood disease and is known to disproportionately afflict up to 72.7% of underprivileged preschool children in both developing and industrialized countries [1]. ECC is defined as “the presence of one or more decayed (non-cavitated or cavitated lesions), missing teeth (due to caries), or filled tooth surfaces in any primary tooth in a child 72 of months age or younger [2]. In children younger than 3 years of age, any sign of smooth-surface caries is indicative of severe early childhood caries (S-ECC) [2]. From ages 3 through 5, one or more cavitated, missing teeth (due to caries), or filled smooth surfaces in primary maxillary anterior teeth, or decayed, missing, or filled score of ≥4 (age 3), ≥5 (age 4), or ≥6 (age 5) surfaces constitutes S-ECC [2]. The onset and progression of ECC is rapid, aggressive, painful, recurrent, and frequently requires total oral rehabilitation under general anesthesia at towering costs [3]. Consequences of ECC include higher risk of new carious lesions, risk for delayed physical growth and development, loss of school days, and hospitalizations and emergency room visits [4]. Thus, ECC constitutes a major challenge for public health systems [5].

Dental caries is a transmissible, and biofilm-dependent infectious disease [6, 7]. Understanding the acquisition of cariogenic microbes are important for development of improved preventive strategies. Traditional microbial risk markers for ECC include Streptococcus mutans and Lactobacillus species, whose transmission routes have been thoroughly investigated [814]. In the past decade, the fungus Candida albicans has been frequently detected in high numbers together with S. mutans in oral biofilms (known as dental plaque) collected from children with ECC [1518]. Clinical studies have provided evidence of the positive association of Candida carriage and occurrence of caries in children [1421]. In vitro studies have also demonstrated an interaction between C. albicans and S. mutans in the presence of sucrose, leading to co-species biofilm development [2227]. Furthermore, a recent in vivo study have shown that the presence of C. albicans enhances the formation of highly cariogenic biofilms, causing the onset of rampant caries in an animal model of the disease [23]. Although previous research suggested the cariogenic association between C. albicans and ECC, to date, the transmission patterns of C. albicans within ECC children have not been characterized.

Fungal colonization in neonates, especially in very low birth weight infants has been investigated in pediatric medicine. Both vertical and horizontal transmission were implicated. The vertical transmission rate ranges from 14% typed by electrophoretic karyotyping and restriction endonuclease analysis of genomic DNA with pulsed-field gel electrophoresis, to 41% typed by DNA fingerprinting using a C. albicans strain-specific DNA probe [28, 29]. Molecular epidemiology has been used to analyze genetic relationship and to identify the route of transmission for C. albicans [30]. Methods such as pulsed-field gel electrophoresis (PFGE), Ca3 fingerprinting, and multi-locus gene sequencing typing offer high-resolution, greater stability, and they have proved to be more discriminatory than phenotypic methods [31]. Restriction endonuclease analysis of the genome using BssHII (REAG-B) is one of the PFGE assay, and it has proven to be a reliable method with high discriminatory abilities for C. albicans relatedness research [29, 3236]. It has been successfully used to investigate outbreaks and performed well when compared with other typing techniques [37].

Identifying the acquisition source of C. albicans to children with ECC may be an important component to help prevent the onset and relapse of this highly infectious and difficult to treat disease. The main purpose of this study was to examine the carriage of C. albicans and the maternal relatedness of C. albicans in children with S-ECC using a combination of culturing and genetic (REAG-B and multilocus sequence typing) methods. We hypothesized that the mother and the child with ECC were both infected with C. albicans, and that C. albicans strains isolated from children with S-ECC were genetically related with the C. albicans isolated from their mothers.

Materials and Methods

Study design

This cross-sectional study was single centered and carried out at the Eastman Institute for Oral Health (EIOH) at the University of Rochester. Ethical approval of the study and the written consent/permission forms were obtained from the Research Subject Review Board at the University of Rochester (RSRB00056870) prior to the study commencement. A convenience sample of children with S-ECC and their mothers were recruited to the study. These children were patients seen at EIOH from June 2015 to September 2015, whose oral health condition required oral rehabilitation in the operating room under general anesthesia. Study subjects provided written informed consent to participate in this study. For subjects younger than 7 years old, written permission form was reviewed and signed by their legal guardians. The sample size calculation was based on the estimated proportion of 60% that the children and mothers shared identical C. albicans strains in our pilot study, compared with the proportion of 14–41% in the general population as reported in the literature [28, 29]. The average of the reported proportions was included as the null proportion (25%) and used in a z-test with a one-sided alternative at alpha = 0.05. The needed sample size to achieve 90% power comprised of 15 child-mother pairs.

Inclusion and exclusion criteria

The inclusion criteria for the children were: 1) 12–71 months of age; 2) diagnosis of S-ECC, defined by the 2014 Reference Manual of the American Academy of Pediatric Dentistry (AAPD); 3) at least one active untreated carious lesion; 4) mother is also willing to take part in the study. Children and mothers who received local and/or systemic antifungal therapy within 90 days of the sample collection visit were excluded from the study. As control group, caries free children aged from 12–71 months of age and their mother were also enrolled, same exclusion criteria was applied except caries lesion.

Comprehensive oral examination

A comprehensive oral examination was performed on the day of the sample collection by one of the two-calibrated dentists, using a standard dental mirror and CPI probe, with artificial headlight. The number of teeth was determined, and dental caries status of the dentition was charted using decayed (D), missing due to decay (M), or filled (F) index according to the codes proposed by WHO Oral health surveys—basic methods, 4th edition, 1997 [38]. Specifically, DMFT(S) for permanent dentition teeth and surfaces and dmft(s) for primary dentition teeth and surfaces. Radiographic bitewings were also used to assess the occlusal and interproximal caries, and used for decayed teeth/surfaces calculation. Plaque status for adult was examined and charted for 6 index teeth according to criteria modified from Silness and Löe [39]. Plaque status for primary dentition and mixed dentition was examined and recorded according to criteria modified from Ribeiro et al, 2002 [40]. Only a single score was used for the whole dentition: 0, for absence of visible plaque; 1, for thin plaque, in anterior and/or posterior teeth, visible just after drying with gauze; 2, for thick plaque, in anterior or posterior teeth, visible without drying; 3, for thick plaque, firmly adhered, in anterior and posterior teeth, visible without drying. Inter- and intra-examiner agreement for the evaluated criteria was calculated by Kappa statistics, and exceeded 82% at the calibration.

Medical-social-demographic survey

A survey (S1 File) including questions related to medical-social-demographic background was completed by the children’s mother. Questions regarding oral hygiene behavior, previous yeast infection history, antibiotic use, birth weight, and daycare attendance were asked.

Clinical sample collection

Subjects were asked not to brush the teeth 2 hours before sample collection. Concentrated oral rinse [41, 42] was used for salivary sample collection for mothers. Subjects were asked to rinse the mouth with 10 ml of sterile 0.9% sodium chloride irrigation solution, USP (Baxter, Deerfield, USA), for 1 min prior to the collection in a sterile 50ml centrifuge tube. The oral rinse was centrifuged at 2,000 × g for 10 min, the supernatant was discarded, and the deposit was resuspended in 1ml of 0.9% sodium chloride solution. The saliva sample of S-ECC children was collected through a disposable saliva ejector attached to a 15 mL sterile centrifuge tube, which in turn was attached to a vacuum pump [43, 44]. Approximately 1 ml of saliva was collected for each subject. After collection, the sample was stored on ice and transferred to the lab located at the Center for Oral Biology at the University of Rochester within 2 hours. Each saliva sample was sonicated on ice by the Branson Sonifier 150 (Branson Ultrasonics Corp., Danbury, CT, USA) to disperse the cell clumps. The swab sample was taken by rubbing the buccal mucosa and back of the tongue using a sterile cotton transport swab and transferred using the modified liquid Stuart’s transport medium (Startplex Scientific Inc, Etibicoke, Canada). Dental plaque was collected throughout the whole dentition using a sterilized periodontal scaler. The sample was suspended in 1ml of a 0.9% sodium chloride solution in a sterilized Eppendorf tube. The plaque sample was gently vortexed and sonicated (10sec sonication, 30sec rest on ice, repeat three times) to break down the aggregated plaque before plating.

Isolation of C. albicans and S. mutans

All saliva/concentrated oral rinse, plaque, and swab samples were plated within 2 hours onto BBL CHROMagar Candida (BD, Sparks, MD, USA) and incubated at 37°C for 48 hours to isolate C. albicans. This medium permitted presumptive identification of several clinically important Candida species including C. albicans based on colony color and morphology [45]. C. albicans was also identified using germ tubing test from three randomly selected colonies in each sample. The saliva and plaque samples were plated on Mitis Salivarius with Bacitracin selective medium and incubated at 37°C for 48h to isolate S. mutans and identified by colony morphology [46].

REAG-B typing

REAG-B typing was performed through Pulsed-Field Gel Electrophoresis (PFGE) of genomic DNA cleaved using the restriction endonuclease BssHII as described previously [3335]. Electrophoresis was performed with a contour-clamped homogenous electric field apparatus (CHEF DR-II; Bio-Rad, California, USA). A Lambda DNA ladder (Bio-Rad California, USA) was included as the size marker. The genetic relatedness analysis was performed with the Bionumerics software (Applied Maths, Austin, TX, USA). The software assigned bands automatically. Each gel was normalized to the respective size markers (Lambda DNA ladder). The position tolerance and optimization was 3 and 3%, respectively, which was modified from the previous study by Chen et al, 2005 [47]. Dice coefficients were used to calculate the similarity percentage of the band patterns. The isolates were considered “genetically identical” when all the bands (100%) observed by the PFGE matched. Banding patterns with ≥95% but less than 100% of the bands matching were termed “genetically similar.” Isolates with less than 95% of the bands matching were considered “genetically different.”

Multi locus sequence typing (MLST)

MLST is a DNA-based method that examines nucleotide sequence variation in seven housekeeping genes and is highly reproducible between different laboratories. MLST has a discriminatory power of 0.999 and moderate degree of easy of use [48]. MLST of C. albicans has been used widely to assess the genetic relatedness of isolates recovered from disparate geographic locations and for C. albicans population analysis [49] [50]. C. albicans strains isolated from ECC children were typed using an MLST scheme [49]. The internal regions of seven housekeeping genes (AAT1a, ACC1, ADP1, MPIb, SYA1, VPS13, and ZWF1b) were sequenced. Each strain was characterized by a diploid sequence type (DST) resulting from the combination of the genotypes obtained at the seven loci. The dendrogram was constructed by using the unweighed pair-group method. Sanger sequence analysis and merger was performed using CAP3. The reference database used to build the MLST scheme was the C. albicans library from PubMLST. Lineage assignment/tree construction was performed using START2.

Spot assay

The spot dilution assay was performed on solid YPD medium with different concentration of caspofungin as described previously [51]. Briefly, cells from a −80°C stock were streaked for independent colonies on YPD plates and incubated at 37°C until young colonies of the approximate size of 1 × 105 to 3 × 105 cells/colony grew up. Colonies then were collected, and serial 10-fold dilutions were prepared in sterile distilled water with the aid of a hemacytometer. The corresponding suspensions were plated at 104, 105, 106 CFU per spot on the YPD medium with 7.5ng/ml, 15ng/ml and 30ng/ml caspofungin. The plates were incubated for 5 days at 37°C and photographed with a Molecular Imager Gel Doc XR+ system (Bio-Rad laboratories, Inc. California, USA). Caspofungin inhibits the enzyme (1→3)-β-D-glucan synthase and thereby disturbs the integrity of the fungal cell wall, killing the organism. The agar-based spot assay has been reported to be a precise and reproducible method for determining relative caspofungin susceptibility [51, 52]. In our study, the rationale of performing caspofungin susceptibility testing was to examine microbiological differences between the C. albicans strains isolated from child and their mother.

Statistical analysis

Descriptive characteristics of age, gender, plaque index, DMFT/dmft index and C. albicans/ S.mutans CFUs were analyzed. Correlation between C.albicans / S.mutans and caries severity was examined using Spearman’s correlation coefficient. A multiple regression analysis using the DMFT(S)/dmft(s) scores as the dependent variable and the genetic relatedness of C. albicans, CFUs of C. albicans, age, gender, plaque index, and medical history (yeast infection) as the independent variables was performed to explore the potential importance of C. albicans infection in S-ECC outcomes. All statistical analyses were implemented with SAS 9.4 (SAS Institute Inc., Cary, NC).

Results

In a period of 4 months, a consecutive series of 18 S-ECC children who were scheduled to receive oral rehabilitation in operating room were enrolled. A total of 18 S-ECC child-mother pairs were recruited, which was above the needed sample size based on power analysis (Materials and Methods) for the purpose of this study. According to the mothers, most of the children in the study have not received any dental care prior to the oral rehabilitation. The demographic, social, oral hygiene, yeast infection history, was listed in Table 1. Among the 18 children with S-ECC, there were 10 boys and 8 girls; the average age was 3.9 ± 0.9 years of age. There were approximately 66% Caucasian, 17% African American, and 17% Asian children; the majority of the children (89%) were non-Hispanic. The average age of the 18 mothers was 31.8 ± 6.8 years of age. Four children and one mother had a history of yeast infections; its clinical demonstration in the children included cradle cap and diaper rash yeast infections; its form in the mother manifested with oral thrush. No subjects in the study reported long-term (>3 months) antibiotic use. Only one child was a low birth weight infant at delivery as reported by the mother. As reported in the questionnaires, two children and two mothers had a history of inhaler use for asthma. According to the mothers, 61% of the children were brushing their teeth twice/daily, 28% once daily, and 11% less than once daily. The majority of the children (78%) stayed at home with their family members and did not attend childcare programs.

thumbnail
Download:
Table 1. Social-demographic and related background information of the study subjects.

https://doi.org/10.1371/journal.pone.0164242.t001

As control, 17 caries free children-mother pairs were also enrolled; the average age of the caries free children was 3.6 ± 1.5 years of age. Among them, there were 9 boys and 8 girls, 41% Caucasian, 41% African American and 18% Asian. According to the mothers, 88% of the children were brushing teeth twice/daily. In addition, 47% of the caries free children were receiving home care, which was lower than 78% in S-ECC group. One caries free child had previous yeast infection history, 2 children were born with low birth weight, 3 children were using inhaler for asthma.

Carriage of C. albicans/ S. mutans and caries score

The detection rate and CFU of C. albicans and S. mutans was shown in Table 2. The C. albicans detection ranked the highest in the oral rinse and plaque samples of mothers (83.3%) and plaque samples of S-ECC children (83%). The saliva/oral-rise and plaque samples yielded higher detection rates than the swab samples. S. mutans was detected in both the saliva/oral-rinse and plaque samples in all the subjects at high detection rate (≥94%). The CFU of C. albicans in S-ECC children’s saliva and plaque was 1.3 ± 4.5 x104 and 1.2 ± 3.5 x104 per ml respectively. Candida tropicalis, Candida Krusei and Candida glabrata were also identified in 6% (1/18), 17% (3/18), and 6% (1/18) of the S-ECC children, and 6% (1/18), 28% (5/18), 6% (1/18) of the family members. The S. mutans carriage in the saliva and plaque samples of the S-ECC children was 7.6 ± 1.1 x106 and 36.7 ± 46.0 x106 CFU/ml respectively.

thumbnail
Download:
Table 2. Carriage of C. albicans and S. mutans and caries score in the S-ECC children and their mothers.

https://doi.org/10.1371/journal.pone.0164242.t002

In the caries free group, the C. albicans detection rate was significantly lower when compared with S-ECC group. C. albicans was only detected in 12% of the saliva samples, 6% of the plaque and swab samples from caries free children. C. albicans was detected in 29% of the oral rinse sample, 12% of the plaque and swab samples from caries free children’s mother. The CFU of C. albicans in caries free children’s saliva and plaque was 3.8 ± 12.4 and 4.1 ± 17.0 per ml, which was ~3 log less compared to the CFU counts found in S-ECC samples. Furthermore, S. mutans detection in caries free children and mothers was significantly lower than the S-ECC as well, the carriage in the saliva and plaque samples of the caries free children was 0.3 ± 0.6 x106 and 2.2 ± 8.0 x106 CFU/ml respectively, which was one log lower than the carriage in S-ECC children.

DMFT(S)/dmft(s) were recorded through a comprehensive oral exam, shown in Table 2. The mean dmft and dmfs scores for the S-ECC children were 10.8 ± 5.1 and 26.4 ± 14.3, respectively; the major portion of the dmft(s) in the children was comprised of decayed teeth and surfaces. The mean DMFT and DMFS scores for the S-ECC mothers were 9.9 ± 7.0 and 25.8 ± 22.4, respectively. As expected, the mothers of caries free children demonstrated significantly lower value of DT/S, DMFT/S when compared with the mothers of S-ECC children. The plaque index was 2 ± 0.7 and 1.9 ± 0.7 for the S-ECC children and mothers and 0.8 ± 1.0 and 1.0 ± 0.8 for the caries free children and mothers. Thus, the caries levels and severity as well as C. albicans carriage were both elevated in S-ECC children and the respective mothers.

The correlations between the C. albicans, S. mutans, and dmft(s) analyzed by Spearman’s rank correlation test were listed in Table 3. The results demonstrated a significant correlation between salivary and plaque S. mutans and C. albicans (with an index of 0.83 and 0.68, respectively; p<0.01) as well as with caries severity (p<0.05).

thumbnail
Download:
Table 3. Spearman’s rank correlation between C. albicans, S. mutans and caries score among S-ECC children.

https://doi.org/10.1371/journal.pone.0164242.t003

The regression analysis showed that none of the factors such as antibiotic usage, birth weight, inhaler use, brushing frequency, and daycare attendance had significant effect on the carriage of salivary and plaque C. albicans in the S-ECC children.

Relatedness evaluation by REAG-B and MLST

Having shown high fungal carriage in both S-ECC children and their mothers, REAG-B was used to exam the genetic relatedness of C. albicans isolated from each of the 18 S-ECC child-mother pairs. Among them, C. albicans was both detected in 12 pairs. In another 6 child-mother pairs, C. albicans was detected in either child or mother, or not detected in both samples. Among the 12 child-mother pairs that both carried C. albicans in the oral cavity, the REAG-B analysis showed 11 identical pairs (61.1%), 0 related pairs, and 1 different pair. Fig 1A demonstrates the REAG-B pattern in 2 representative child-mother pairs. Relatedness analysis was performed by BioNumerics software (Applied Maths, Austin, TX). The C. albicans isolated from the child-1 and mother-1 were genetically identical, the C. albicans isolated from the child-5 and mother-5 were genetically different. The C. albicans from different resources (saliva/oral-rinse, plaque and swab) of the same subject were also analyzed using REAG-B. In one S-ECC children’s mother, the C. albicans isolated from the saliva showed different pattern from that isolated from the plaque using REAG-B, and was confirmed as two different strains by BioNumerics software. Among the other study subjects, only one type of C. albicans strain was identified across from saliva/oral-rinse, plaque and swab samples. Regarding caries free children-mother pairs, only one pair of child and mother both had C. albicans in their samples, REAG-B results indicated that strains from child and mother were identical.

thumbnail
Download:
Fig 1. Representative PFGE patterns and genetic relatedness of C. albicans obtained by restriction endonuclease analysis of genomic DNA using BssHII (REAG-B) among family members.

(A) Representative PFGE patterns and genetic relatedness of C. albicans within different child-mother pairs; (B) Relatedness of C. albicans among S-ECC child-mother pairs. * Relatedness analysis was performed by BioNumerics software (Applied Maths, Austin, TX). The C. albicans isolated from the child-1 and mother-1 were genetically identical, the C. albicans isolated from the child-5 and mother-5 were genetically different.

https://doi.org/10.1371/journal.pone.0164242.g001

C. albicans Isolates from 15 S-ECC children were analyzed with the consensus C. albicans MLST scheme [49]. New allelic profiles and DSTs were identified in 4 isolates. Of the seven loci investigated for each isolate, four new VPS13 alleles were identified. A UPGMA dendrogram depicting the C. albicans MLST clustering information between the 15 isolates from ECC children was shown in Fig 2 and were grouped in three main clusters. No enrichment of C. albicans MLST clusters was found regards to the geographic zip code and caries severity based on caries score in the study samples.

thumbnail
Download:
Fig 2. Dendrogram of genetic relationship between 15 C. albicans isolates from the S-ECC children saliva sample, based on the seven housekeeping loci.

*The dendrogram was constructed by using the unweighed pair-group method. The linkage distance is indicated at the bottom.

https://doi.org/10.1371/journal.pone.0164242.g002

Susceptibility to caspofungin

Clinical strains isolated from 12 pairs S-ECC child-mother were used to perform the susceptibility test to caspofungin to assess microbiological differences among the isolates. In 8 (66.6%) child-mother pair, the strains demonstrated similar susceptible to caspofungin. In 2 child-mother pair, the strains from child were seen forming colonies 1 day earlier on the plate than the strain from the mother. In another 2 child-mother pair, the strains from the child were more susceptible to caspofungin. Examples of susceptibility of the clinical isolated C. albicans from S-ECC child-mother pair to antifungal agents casopfungin compared to C. albicans wild strain SC5314 was shown in Fig 3. From left to right, 104, 105, and 106 cells were spotted on each plate and incubated at 37°C for up to 5 days. Clinical isolated C. albicans demonstrated less growth and smaller colonies than SC5314 on the YPD medium with caspofungin. However, no significant growth difference was seen between the C. albicans from S-ECC children and their mother on the YPD medium with 7.5 ng/ml and 15 ng/ml of caspofungin.

thumbnail
Download:
Fig 3. Examples of susceptibility of the clinical isolated C. albicans from S-ECC children and their mothers to antifungal agents casopfungin compared to C. albicans wild strain SC5314.

From left to right, 104, 105, and 106 cells were spotted on each plate and incubated at 37°C for up to 5 days. Clinical isolated C. albicans demonstrated less growth and smaller colonies than SC5314 on the YPD medium with caspofungin. However, no significant growth difference was seen between the C. albicans from S-ECC children and their mothers on the YPD medium with caspofungin.

https://doi.org/10.1371/journal.pone.0164242.g003

Discussion

In the past decade, the fungus Candida albicans has been detected more frequently in the oral cavity of children with ECC than caries-free (CF) children [1521]. For example, high detection rate of C. albicans was found in plaque of ECC (60–62% vs 14–22% in CF-children [16, 17]) as well as in saliva (67% vs 2% in CF children [18]). Compared to the published literature, we detected 77% in the saliva, 83% in the plaque samples and 44% in swab sample, reinforcing the potential role of C. albicans in ECC pathogenesis. However, how the children acquire C. albicans remain an intriguing question. Our findings provide initial evidence that maternal transmission could be at least one source for the C. albicans infection in S-ECC children. Results from this study reveal that mothers of the children affected by S-ECC also have high C. albicans carriage (>80% detection in both saliva and plaque samples), and more than 60% of the S-ECC children were carrying the same C. albicans strains as their mothers. Both findings are novel and have not been reported previously, which provides the framework for larger and longitudinal studies to further validate and expand our observations.

Another important finding from our study is the strong correlation between the salivary and plaque viable cells of S. mutans and C. albicans. In the oral cavity, the co-adhesion between C. albicans and oral bacteria is crucial for C. albicans colonization and persistence [53]. When sucrose is available, C. albicans could interact and develop biofilms with S. mutans, which greatly enhanced the colonization by these organisms on apatitic surfaces [22, 23]. A major mechanism involved in this cross-kingdom association appears to be linked with the S. mutans–derived exoenzyme glucosyltransferase B (GtfB), a key exopolysacharides (EPS) producer. GtfB can bind to the surface of C. albicans cells in an active form, produce EPS locally that provide enhanced binding sites for S. mutans, which in turn promote the formation of biofilms containing elevated EPS amounts and high numbers of S. mutans and C. albicans [22, 23, 26]. Once together within a diffusion-limiting EPS-rich matrix, it is conceivable that co-existence of S. mutans and C. albicans could induce each other’s growth [2325] and further enhance acid production in the biofilm (as the fungus is highly acidogenic and aciduric [54, 55]), leading to rampant caries in an animal model of the disease [23].

Our clinical findings are consistent with previous evidence suggesting that C. albicans and S. mutans are found together and interact in conditions conducive of ECC. We also found a significant correlation between plaque C. albicans counts and caries severity (dmft/dmfs). Furthermore, the number of decayed teeth/surfaces in the subjects with both C. albicans and S. mutans carriage were clearly higher than that of subjects detected with S. mutans only, suggesting that the fungal presence might escalate the severity of ECC. It is important to note that plaque sample was collected from the whole dentition combining the plaque from sound and carious tooth surfaces. It is possible that a stronger correlation might have been observed within the plaque from carious lesion teeth. Also, we used colony morphology to distinguish S. mutans from other streptococci that could also grow in the MSB medium, which has some limitations and could over-estimate the carriage of S. mutans. Thus, site-specific sample collection combined with species-specific molecular probes will be used in future studies. Nevertheless, further larger scale and longitudinal clinical studies is certainly warranted to validate these findings.

It is noteworthy that C. albicans enhanced co-colonization and proliferation in the oral cavity of ECC patients could be also explained by the ecological plaque hypothesis [56]. In the context of S-ECC, which is characterized by diet and dietary practices rich in fermentable carbohydrates, the acidogenic microorganisms can rapidly acidify the plaque microenvironment. In turn, the acidic pH conditions would favor the growth of acid-tolerant (aciduric) organisms, such as C. albicans and S. mutans, providing an ecological advantage compared to many other oral microbes.

Altogether, these results provide the first insights to further understand the C. albicans transmission route while confirming the coexistence with S. mutans and caries severity, which may be important for the pathogenesis of ECC. The limitation of this study was its cross-sectional nature and small sample size (albeit sufficient for this study). Future studies will focus on investigating the vertical transmission of C. albicans in neonates as well as C. albicans and S. mutans colonization and their salivary/plaque levels in the ECC children longitudinally.

Conclusion

Our results show that the child with S-ECC and the mother were both infected with high levels of C. albicans, and most of the fungal strains were genetically related, suggesting that the mother might be a primary source for C. albicans acquisition in the oral cavity of children affected with S-ECC. A strong correlation was also identified between salivary and plaque C. albicans and S. mutans carriage using the Spearman’s rank test, suggesting a symbiotic relationship between C. albicans and S. mutans in the context of ECC.

Supporting Information

S1 File. Social-demographic and medical background survey form.

https://doi.org/10.1371/journal.pone.0164242.s001

(PDF)

Acknowledgments

We thank Drs. Erin Shope, Cynthia Wong, and Lisa DeLucia from Pediatric dentistry, Eastman Institute for Oral Health, University of Rochester Medical Center, for their generous support in collecting the clinical samples for the study.

Author Contributions

  1. Conceptualization: JX CF YR RQ HK DK.
  2. Data curation: JX YM LL CF.
  3. Formal analysis: JX CF.
  4. Funding acquisition: JX HK.
  5. Investigation: JX YM LL ER HW XZ SM.
  6. Methodology: JX ER HW SG SM YR RQ DK.
  7. Project administration: JX.
  8. Resources: JX YM LL ER HW XZ SG SM HM YR RQ.
  9. Supervision: JX HK DK.
  10. Validation: JX YM LL ER HW XZ.
  11. Visualization: JX YM LL CF HK DK.
  12. Writing – original draft: JX CF HK DK.
  13. Writing – review & editing: JX YM LL ER HW XZ CF SG SM HM YR RQ HK DK.

References

  1. 1. Dye BA, Hsu KL, Afful J. Prevalence and Measurement of Dental Caries in Young Children. Pediatric dentistry. 2015;37(3):200–16. pmid:26063550.
  2. 2. Colak H, Dulgergil CT, Dalli M, Hamidi MM. Early childhood caries update: A review of causes, diagnoses, and treatments. Journal of natural science, biology, and medicine. 2013;4(1):29–38. pmid:23633832; PubMed Central PMCID: PMC3633299.
  3. 3. Hajishengallis E, Parsaei Y, Klein MI, Koo H. Advances in the microbial etiology and pathogenesis of early childhood caries. Molecular oral microbiology. 2015. pmid:26714612.
  4. 4. American Academy of Pediatric Dentistry Council on Clinical A. Policy on early childhood caries (ECC): unique challenges and treatment options. Pediatric dentistry. 2005;27(7 Suppl):34–5. pmid:16541879.
  5. 5. Dye BA, Tan S, Smith V, Lewis BG, Barker LK, Thornton-Evans G, et al. Trends in oral health status: United States, 1988–1994 and 1999–2004. Vital and health statistics Series 11, Data from the national health survey. 2007;(248):1–92. pmid:17633507.
  6. 6. Caufield PW, Li Y, Dasanayake A. Dental caries: an infectious and transmissible disease. Compendium of continuing education in dentistry. 2005;26(5 Suppl 1):10–6. pmid:17036539.
  7. 7. American Academy on Pediatric D, American Academy of P. Policy on early childhood caries (ECC): classifications, consequences, and preventive strategies. Pediatric dentistry. 2008;30(7 Suppl):40–3. pmid:19216381.
  8. 8. Kanasi E, Johansson I, Lu SC, Kressin NR, Nunn ME, Kent R Jr., et al. Microbial risk markers for childhood caries in pediatricians' offices. Journal of dental research. 2010;89(4):378–83. pmid:20164496; PubMed Central PMCID: PMC2880172.
  9. 9. Caufield PW, Cutter GR, Dasanayake AP. Initial acquisition of mutans streptococci by infants: evidence for a discrete window of infectivity. Journal of dental research. 1993;72(1):37–45. pmid:8418105.
  10. 10. Li Y, Caufield PW, Dasanayake AP, Wiener HW, Vermund SH. Mode of delivery and other maternal factors influence the acquisition of Streptococcus mutans in infants. Journal of dental research. 2005;84(9):806–11. pmid:16109988.
  11. 11. Zhan L, Tan S, Den Besten P, Featherstone JD, Hoover CI. Factors related to maternal transmission of mutans streptococci in high-risk children-pilot study. Pediatric dentistry. 2012;34(4):e86–91. pmid:23014079.
  12. 12. Slayton RL. Reducing mutans streptococci levels in caregivers may reduce transmission to their children and lead to reduced caries prevalence. The journal of evidence-based dental practice. 2011;11(1):27–8. pmid:21420005.
  13. 13. Klein MI, Florio FM, Pereira AC, Hofling JF, Goncalves RB. Longitudinal study of transmission, diversity, and stability of Streptococcus mutans and Streptococcus sobrinus genotypes in Brazilian nursery children. Journal of clinical microbiology. 2004;42(10):4620–6. pmid:15472319; PubMed Central PMCID: PMC522380.
  14. 14. Klinke T, Urban M, Luck C, Hannig C, Kuhn M, Kramer N. Changes in Candida spp., mutans streptococci and lactobacilli following treatment of early childhood caries: a 1-year follow-up. Caries research. 2014;48(1):24–31. pmid:24216710.
  15. 15. Raja M, Hannan A, Ali K. Association of oral candidal carriage with dental caries in children. Caries research. 2010;44(3):272–6. pmid:20516688.
  16. 16. Rozkiewicz D, Daniluk T, Zaremba ML, Cylwik-Rokicka D, Stokowska W, Pawinska M, et al. Oral Candida albicans carriage in healthy preschool and school children. Advances in medical sciences. 2006;51 Suppl 1:187–90. pmid:17458089.
  17. 17. de Carvalho FG, Silva DS, Hebling J, Spolidorio LC, Spolidorio DM. Presence of mutans streptococci and Candida spp. in dental plaque/dentine of carious teeth and early childhood caries. Archives of oral biology. 2006;51(11):1024–8. pmid:16890907.
  18. 18. Hossain H, Ansari F, Schulz-Weidner N, Wetzel WE, Chakraborty T, Domann E. Clonal identity of Candida albicans in the oral cavity and the gastrointestinal tract of pre-school children. Oral microbiology and immunology. 2003;18(5):302–8. pmid:12930522.
  19. 19. Srivastava B, Bhatia HP, Chaudhary V, Aggarwal A, Kumar Singh A, Gupta N. Comparative Evaluation of Oral Candida albicans Carriage in Children with and without Dental Caries: A Microbiological in vivo Study. International journal of clinical pediatric dentistry. 2012;5(2):108–12. pmid:25206148; PubMed Central PMCID: PMC4148750.
  20. 20. Yang XQ, Zhang Q, Lu LY, Yang R, Liu Y, Zou J. Genotypic distribution of Candida albicans in dental biofilm of Chinese children associated with severe early childhood caries. Archives of oral biology. 2012;57(8):1048–53. pmid:22717324.
  21. 21. Qiu R, Li W, Lin Y, Yu D, Zhao W. Genotypic diversity and cariogenicity of Candida albicans from children with early childhood caries and caries-free children. BMC oral health. 2015;15(1):144. pmid:26576955; PubMed Central PMCID: PMC4650516.
  22. 22. Gregoire S, Xiao J, Silva BB, Gonzalez I, Agidi PS, Klein MI, et al. Role of glucosyltransferase B in interactions of Candida albicans with Streptococcus mutans and with an experimental pellicle on hydroxyapatite surfaces. Applied and environmental microbiology. 2011;77(18):6357–67. pmid:21803906; PubMed Central PMCID: PMC3187131.
  23. 23. Falsetta ML, Klein MI, Colonne PM, Scott-Anne K, Gregoire S, Pai CH, et al. Symbiotic relationship between Streptococcus mutans and Candida albicans synergizes virulence of plaque biofilms in vivo. Infection and immunity. 2014;82(5):1968–81. pmid:24566629; PubMed Central PMCID: PMC3993459.
  24. 24. Sztajer H, Szafranski SP, Tomasch J, Reck M, Nimtz M, Rohde M, et al. Cross-feeding and interkingdom communication in dual-species biofilms of Streptococcus mutans and Candida albicans. The ISME journal. 2014;8(11):2256–71. pmid:24824668.
  25. 25. Metwalli KH, Khan SA, Krom BP, Jabra-Rizk MA. Streptococcus mutans, Candida albicans, and the human mouth: a sticky situation. PLoS pathogens. 2013;9(10):e1003616. pmid:24146611; PubMed Central PMCID: PMC3798555.
  26. 26. Hwang G, Marsh G, Gao L, Waugh R, Koo H. Binding Force Dynamics of Streptococcus mutans-glucosyltransferase B to Candida albicans. Journal of dental research. 2015;94(9):1310–7. pmid:26138722.
  27. 27. Koo H, Bowen WH. Candida albicans and Streptococcus mutans: a potential synergistic alliance to cause virulent tooth decay in children. Future microbiology. 2014;9(12):1295–7. pmid:25517895.
  28. 28. Bliss JM, Basavegowda KP, Watson WJ, Sheikh AU, Ryan RM. Vertical and horizontal transmission of Candida albicans in very low birth weight infants using DNA fingerprinting techniques. The Pediatric infectious disease journal. 2008;27(3):231–5. pmid:18277930.
  29. 29. Waggoner-Fountain LA, Walker MW, Hollis RJ, Pfaller MA, Ferguson JE 2nd, Wenzel RP, et al. Vertical and horizontal transmission of unique Candida species to premature newborns. Clinical infectious diseases: an official publication of the Infectious Diseases Society of America. 1996;22(5):803–8. pmid:8722935.
  30. 30. Leung WK, Dassanayake RS, Yau JY, Jin LJ, Yam WC, Samaranayake LP. Oral colonization, phenotypic, and genotypic profiles of Candida species in irradiated, dentate, xerostomic nasopharyngeal carcinoma survivors. Journal of clinical microbiology. 2000;38(6):2219–26. pmid:10834980; PubMed Central PMCID: PMC86768.
  31. 31. McEllistrem MC, Pass M, Elliott JA, Whitney CG, Harrison LH. Clonal groups of penicillin-nonsusceptible Streptococcus pneumoniae in Baltimore, Maryland: a population-based, molecular epidemiologic study. Journal of clinical microbiology. 2000;38(12):4367–72. pmid:11101566; PubMed Central PMCID: PMC87607.
  32. 32. Shin JH, Park MR, Song JW, Shin DH, Jung SI, Cho D, et al. Microevolution of Candida albicans strains during catheter-related candidemia. Journal of clinical microbiology. 2004;42(9):4025–31. pmid:15364985; PubMed Central PMCID: PMC516333.
  33. 33. Shin JH, Og YG, Cho D, Kee SJ, Shin MG, Suh SP, et al. Molecular epidemiological analysis of bloodstream isolates of Candida albicans from a university hospital over a five-year period. Journal of microbiology. 2005;43(6):546–54. pmid:16410772.
  34. 34. Voss A, Pfaller MA, Hollis RJ, Rhine-Chalberg J, Doebbeling BN. Investigation of Candida albicans transmission in a surgical intensive care unit cluster by using genomic DNA typing methods. Journal of clinical microbiology. 1995;33(3):576–80. pmid:7751360; PubMed Central PMCID: PMC227993.
  35. 35. Heo SM, Sung RS, Scannapieco FA, Haase EM. Genetic relationships between Candida albicans strains isolated from dental plaque, trachea, and bronchoalveolar lavage fluid from mechanically ventilated intensive care unit patients. Journal of oral microbiology. 2011;3. pmid:21731911; PubMed Central PMCID: PMC3124833.
  36. 36. Shin JH, Bougnoux ME, d'Enfert C, Kim SH, Moon CJ, Joo MY, et al. Genetic diversity among Korean Candida albicans bloodstream isolates: assessment by multilocus sequence typing and restriction endonuclease analysis of genomic DNA by use of BssHII. Journal of clinical microbiology. 2011;49(7):2572–7. pmid:21562112; PubMed Central PMCID: PMC3147862.
  37. 37. Krawczyk B, Leibner-Ciszak J, Mielech A, Nowak M, Kur J. PCR melting profile (PCR MP)—a new tool for differentiation of Candida albicans strains. BMC infectious diseases. 2009;9:177. pmid:19906294; PubMed Central PMCID: PMC2778650.
  38. 38. Organization. WH. Oral health surveys—basic methods, 4th ed.: Geneva: World Health Organization; 1997.
    • 39. Silness J, Loe H. Periodontal Disease in Pregnancy. Ii. Correlation between Oral Hygiene and Periodontal Condtion. Acta odontologica Scandinavica. 1964;22:121–35. Epub 1964/02/01. pmid:14158464.
    • 40. Ribeiro Ade A, Portela M, Souza IP. [Relation between biofilm, caries activity and gingivitis in HIV + children]. Pesquisa odontologica brasileira = Brazilian oral research. 2002;16(2):144–50. pmid:12131988.
    • 41. White PL, Williams DW, Kuriyama T, Samad SA, Lewis MA, Barnes RA. Detection of Candida in concentrated oral rinse cultures by real-time PCR. Journal of clinical microbiology. 2004;42(5):2101–7. pmid:15131176; PubMed Central PMCID: PMC404626.
    • 42. Samaranayake LP, MacFarlane TW, Lamey PJ, Ferguson MM. A comparison of oral rinse and imprint sampling techniques for the detection of yeast, coliform and Staphylococcus aureus carriage in the oral cavity. Journal of oral pathology. 1986;15(7):386–8. pmid:3098945.
    • 43. Leverett DH, Featherstone JD, Proskin HM, Adair SM, Eisenberg AD, Mundorff-Shrestha SA, et al. Caries risk assessment by a cross-sectional discrimination model. Journal of dental research. 1993;72(2):529–37. pmid:8423251.
    • 44. Berkowitz RJ, Koo H, McDermott MP, Whelehan MT, Ragusa P, Kopycka-Kedzierawski DT, et al. Adjunctive chemotherapeutic suppression of mutans streptococci in the setting of severe early childhood caries: an exploratory study. Journal of public health dentistry. 2009;69(3):163–7. pmid:19486465; PubMed Central PMCID: PMC2855972.
    • 45. Odds FC, Bernaerts R. CHROMagar Candida, a new differential isolation medium for presumptive identification of clinically important Candida species. Journal of clinical microbiology. 1994;32(8):1923–9. pmid:7989544; PubMed Central PMCID: PMC263904.
    • 46. Little WA, Korts DC, Thomson LA, Bowen WH. Comparative recovery of Streptococcus mutans on ten isolation media. Journal of clinical microbiology. 1977;5(6):578–83. pmid:885999; PubMed Central PMCID: PMC274659.
    • 47. Chen KW, Lo HJ, Lin YH, Li SY. Comparison of four molecular typing methods to assess genetic relatedness of Candida albicans clinical isolates in Taiwan. Journal of medical microbiology. 2005;54(Pt 3):249–58. pmid:15713608.
    • 48. Saghrouni F, Ben Abdeljelil J, Boukadida J, Ben Said M. Molecular methods for strain typing of Candida albicans: a review. Journal of applied microbiology. 2013;114(6):1559–74. pmid:23311504.
    • 49. Bougnoux ME, Tavanti A, Bouchier C, Gow NA, Magnier A, Davidson AD, et al. Collaborative consensus for optimized multilocus sequence typing of Candida albicans. Journal of clinical microbiology. 2003;41(11):5265–6. pmid:14605179; PubMed Central PMCID: PMC262540.
    • 50. Bougnoux ME, Aanensen DM, Morand S, Theraud M, Spratt BG, d'Enfert C. Multilocus sequence typing of Candida albicans: strategies, data exchange and applications. Infection, genetics and evolution: journal of molecular epidemiology and evolutionary genetics in infectious diseases. 2004;4(3):243–52. pmid:15450203.
    • 51. Yang F, Kravets A, Bethlendy G, Welle S, Rustchenko E. Chromosome 5 monosomy of Candida albicans controls susceptibility to various toxic agents, including major antifungals. Antimicrobial agents and chemotherapy. 2013;57(10):5026–36. pmid:23896475; PubMed Central PMCID: PMC3811469.
    • 52. Schuetzer-Muehlbauer M, Willinger B, Krapf G, Enzinger S, Presterl E, Kuchler K. The Candida albicans Cdr2p ATP-binding cassette (ABC) transporter confers resistance to caspofungin. Molecular microbiology. 2003;48(1):225–35. pmid:12657057.
    • 53. Xu H, Jenkinson HF, Dongari-Bagtzoglou A. Innocent until proven guilty: mechanisms and roles of Streptococcus-Candida interactions in oral health and disease. Molecular oral microbiology. 2014;29(3):99–116. pmid:24877244; PubMed Central PMCID: PMC4238848.
    • 54. Klinke T, Guggenheim B, Klimm W, Thurnheer T. Dental caries in rats associated with Candida albicans. Caries research. 2011;45(2):100–6. pmid:21412001.
    • 55. Klinke T, Kneist S, de Soet JJ, Kuhlisch E, Mauersberger S, Forster A, et al. Acid production by oral strains of Candida albicans and lactobacilli. Caries research. 2009;43(2):83–91. pmid:19246906.
    • 56. Marsh PD. Are dental diseases examples of ecological catastrophes? Microbiology. 2003;149(Pt 2):279–94. pmid:12624191.