Introduction. Silver nanoparticles are used in endodontics due to their antimicrobial activity, although it is considered that bacteria are unable to develop resistance to silver nanoparticles. Silver resistance genes have been related to resistance to nanoparticles and antibiotics. The presence of these resistance genes has not been studied in endodontic bacteria. The objective of this study is to report the prevalence of silver resistance genes in endodontic bacteria. Methods. The selected teeth were isolated using a rubber dam and any restoration, post, or caries was eliminated. The operative field was disinfected, and the root-filling material was removed. The samples were obtained using three sterile paper points to absorb the fluid of the root canal. The DNA from the samples and the control organism was extracted, and the detection of the silCBA resistance genes was carried out by PCR. Results. The results of this study show a high prevalence (73.3%) of silCBA silver resistance genes. The Spearman rank correlation coefficient was utilized to identify correlations between the presence of genes and clinical variables. Conclusions. This study reports a high frequency of silver resistance genes related to nanoparticle resistant from bacteria.
Consejo Nacional de Ciencia y Tecnología460066FAIC19-FAI-05-67.67Nanomateriales Multifuncionales para la Sustentabilidad y el Bienestar de la Sociedad511-6/18-118561. Introduction
Nanoparticles (NPs) have been widely used in various areas of dentistry, mainly due to their potent antibacterial property [1]. In endodontics, silver nanoparticles (AgNPs) are used to combat the presence of biofilms [2]. This is because AgNPs have several advantages compared to NaOCl (the gold standard of disinfection in endodontics). AgNPs can retain their antibacterial efficacy in the presence of dentine and have greater biocompatibility, especially at low concentrations [3].
In general, it is mentioned that silver nanoparticles exert their bactericidal action through two mechanisms. The first mechanism consists of the direct penetration of the nanoparticle (<10 nm) into the bacterial cell, and the second is the release of silver ions (by nanoparticles>10nm) that can also enter the bacterial cells and react with their components causing the death of the bacteria. Although it is thought that bacteria are not capable of developing resistance to silver nanoparticles, this has not been well studied, although silver-resistant bacteria isolated from clinical and nonclinical environments have been reported [4, 5]. The first clinical bacterium with silver resistance described was Salmonella typhimurium. The first plasmid coding for bacterial resistance to Ag+ was isolated from this bacterium. The plasmid was named pMG101, and it confers resistance to Ag+, Hg+, and tellurite as well as antibiotics, such as ampicillin, chloramphenicol, tetracycline, and streptomycin. This plasmid contains a region of 14.2 kb (sil operon) with nine ORFs (open reading frames) arranged in three transcriptional units (silCFBAGP, silRS, and silE) expressed from a different promoter. These transcriptional subunits are collectively designated as the Sil operon [6]. The first transcriptional unit is composed of silCFBAGP. This transcription unit encodes an internal membrane protein complex formed by three subunits (silA, silB, and silC). These three components form an efflux pump that is a member of the family of resistance, nodulation, and cell division (RND) transporters [7]. SilP is a member of the ATPase family of heavy metal resistance. SilG and silF are silver chaperones responsible for kidnapping the silver ions and transporting them to silP and silCBA complexes. In the second transcription unit and upstream of silE and in the same orientation of this, there is a gene pair, silRS, that encodes a transcriptional response regulatory protein and a membrane sensing kinase. The last transcriptional unit is composed of silE, which encodes a periplasmic protein that also binds to Ag+. Finally, between silA and silP and between silC and silB, there are two ORFs of 105 and 96aa, respectively, of unassigned function [8]. The efflux pumps synthesized from the expression of the aforementioned genes (silCBA and silP) could participate as a mechanism of resistance to silver nanoparticles. This mechanism would work through the expulsion of silver ions, preventing them from affecting the internal components of the bacteria.
The endodontic bacteria of secondary infections present a high prevalence of plasmids that carry genes of resistance to antibiotics [9]. Recently, it was found that plasmids can also contain metal resistance genes [10]. This is due to a costimulation and coselection of resistance genes [11]. Therefore, the objective of this study was to identify the presence of silver resistance genes (silCBA) in bacteria from root-filled teeth. The detection of this type of genes has not been done before in bacteria from secondary endodontic infections. The presence of these genes in this type of resistant infections would lead to reevaluating the short- and long-term use of silver nanoparticles as antimicrobial agents in resistant infections like a secondary endodontic infection.
2. Materials and Methods2.1. Bacterial Strain
The bacterial strain Enterobacter cloacae 13047 was acquired from the National Collection of Microbial Strains and Cell Cultures of CINVESTAV-IPN. This bacterial strain was used as a positive control for the detection of silCBA genes, according to what was reported in previous studies [12]. Enterobacter cloacae 13047 was inoculated in Brain Heart Infusion (BHI) agar plate (Sigma-Aldrich, St. Louis, MO, USA) using a sterile bail and incubated for 24 h at 37°C. After the incubation period, an inoculum was taken and placed in an Eppendorf tube with 1 ml of phosphate-buffered saline (PBS; Sigma-Aldrich, St. Louis, MO, USA) and frozen at -4°C until further processed.
2.2. Patient Selection
All patient procedures were approved by the Ethics Committee of the Stomatology Faculty of the Autonomous University of San Luis Potosí, Mexico (CEI-FE-027-018). Patients provided written informed consent before being recruited in the study. All 30 patients had an endodontically treated tooth requiring endodontic retreatment. The teeth included in the study had had previous endodontic treatment, sensitivity to percussion, pain on palpation, periapical lesion, or fistulous tract. These clinical characteristics were recorded. Patients who have received antibiotic treatment during the last 3 months or patients with teeth that present mobility and periodontal pockets were excluded. Teeth with root fracture or that could not be isolated were eliminated from the study.
2.3. Sampling Procedure
This was a descriptive cross-sectional study with consecutive nonprobabilistic sampling. The study was conducted from March to November 2018. We evaluated 735 patients, of which 30 patients met the inclusion criteria. The selected teeth were isolated using a rubber dam and any restoration, post, or caries was eliminated. The operative field was disinfected using 30% hydrogen peroxide followed by 5.25% sodium hypochlorite [13]. Subsequently, 10% sodium thiosulfate (LabChem Inc., Pittsburgh, PA) [14] was used to inactivate sodium hypochlorite. Root-filling material was removed using K-files, Gates Glidden drills, Hedstrom files, or rotary files with no solvent. The working length was determined with the use of an apex locator (Raypex 5; VDW, Munich, Germany), and transoperative radiographs were taken to ensure complete removal of the filling material. Sterile saline solution was used to remove any remaining filling material and moisten the root canal before sampling. The samples were obtained using three sterile paper points placed in the root canal for about 30 s to absorb the fluid of the root canal [15]. Samples from multiradicular teeth were taken from the widest root canal or from the one that presented some periradicular lesion or exudate. After sampling, the paper points were transferred to a 1.5 ml tube with 1 ml of phosphate-buffered saline (PBS; Sigma-Aldrich, St. Louis, MO, USA). All the samples were frozen at -4°C until further processed. After taking the sample, each patient received the indicated root canal retreatment.
2.4. DNA Extraction
DNA was extracted from the sample of a control organism (Enterobacter cloacae 13047) and all clinical samples using the following total DNA extraction protocol. The samples were centrifuged and then the phosphate-buffered saline (PBS; Sigma-Aldrich, St. Louis, MO, USA) was decanted to then add 500 μl of TES buffer (Sigma-Aldrich, St. Louis, MO, USA), 50 μl of Proteinase K (Invitrogen, Paisley, UK), and 40 μl of SDS 10%. These reagents were incubated at 55°C for 3 h in a thermo-block for their activation. After the incubation, the suspension was centrifuged for 15 min at 13000 rpm, and the supernatant was transferred to a new 1.5 ml vial. To the recovered supernatant, 578 μl of isopropanol (Sigma-Aldrich, St. Louis, MO, USA) was added, and it was allowed to incubate overnight. After incubation with isopropanol, the pellet was washed with 70% ethanol and resuspended in 30 μl of TE buffer.
2.5. PCR Primers and PCR Protocol
The PCR reactions for each of the samples and the positive control were prepared using 1 μl of total template DNA, for a total of 25 μl of reaction. In the negative control, 1 μl of milliQ water was used as a template. The primers used for the detection of the silCBA genes were those reported by Woods et al. [5]. Primers were purchased from T4oligo Company (Guanajuato, Mexico). SilCBA gene primer sequences were as follows: silCBA forward cgggaaacgctgaaaaatta and silCBA reverse gtacgttcccagcaccagtt. PCRs were carried out using the following PCR protocol: denaturation temperature was 95°C for 3 min followed by 45 cycles consisting of an initial denaturation at 95°C for 40 s; the alignment temperature was 56°C for 40 s and an extension temperature of 72°C for 40 s. A final extension step was performed at 72°C for 10 min. All the amplifications were performed in a C1000 Touch™ Thermal Cycler (Bio-Rad, California, USA). The PCR products were separated by gel electrophoresis with a 2% agarose gel stained with 0.5 mg/ml ethidium bromide and TAE (Tris-acetate–EDTA) as running buffer. In each agarose gel, a 50 bp DNA ladder (Invitrogen, Paisley, UK) was loaded to define PCR fragment sizes together with the positive control, negative control, and the samples. The electrophoresis consisted of 1 h at 70 V/cm. The agarose gels were revealed in an ENDURO™ GDS Gel Documentation System (Labnet International).
2.6. Clinical Features
The data for clinical features and genes detected were entered into a spreadsheet and analyzed.
2.7. Statistical Analysis
Categorical variables were reported with frequencies and percentages, while continuous variables were reported with means and standard deviations (SD). Categorical variables were analyzed as absence=0 and presence=1 to calculate correlations. Shapiro-Wilk and Brown Forsythe tests were performed to determine the distribution of the variables. The Spearman rank correlation coefficient was utilized to identify all correlations. A P<0.05 was considered statistically significant. Data were analyzed using JMP ver. 9.0 (SAS Institute, Cary, NC, USA) and Stata ver. 11.0 (Stata Corp LP, College Station, TX, USA) statistical software.
3. Results
The mean age of the patients was 46.43 years (range, 11-76). There were more female patients (21=70%) than male patients (9=30%) (Table 1). The teeth from which the samples were taken consisted of 2 incisors, 1canine, 4 premolars, and 23 molars. Of the molar teeth, 14 were mandibular, and 5 were maxillary. Of all the samples analyzed, 22 (73.34%) samples were positive for the silCBA resistance genes. The samples that were negative for the resistance genes analyzed were 8 (22.6%) (Table 2). Despite the difference between men and women, the frequency of silCBA genes in both groups was very similar, 76.1% for women and 77.77% for men. The positive samples with injury were 9 (40.9%). The positive samples with symptomatology were 15 (68.1%). The positive samples that presented lesion and symptomatology were 5 (22.72%). Some DNA bands are barely visible on the agarose gels (Figure 1), suggesting that the genes are present at a relatively low copy number in some samples.
Silver resistance gene (silCBA) detection in root-filled teeth by PCR. Results and patients’ data.
Patients
Sex
Age (y)
Lesion
Symptomatology
Tooth
Genes
1
Female
38
Yes
Yes
44
Yes
2
Female
53
Yes
No
13
Yes
3
Male
66
No
Yes
22
No
4
Female
14
No
No
26
No
5
Male
42
No
No
36
Yes
6
Female
44
No
No
45
No
7
Female
45
Yes
Yes
26
Yes
8
Male
40
Yes
Yes
26
No
9
Female
49
Yes
Yes
46
Yes
10
Female
30
Yes
No
46
Yes
11
Female
76
No
No
14
No
12
Male
59
No
Yes
47
Yes
13
Female
67
No
Yes
34
Yes
14
Male
41
Yes
Yes
37
No
15
Female
26
Yes
No
47
Yes
16
Female
39
Yes
Yes
36
No
17
Female
70
Yes
Yes
47
No
18
Male
25
No
Yes
11
Yes
19
Male
58
No
Yes
16
Yes
20
Female
18
Yes
Yes
46
Yes
21
Female
11
Yes
Yes
36
Yes
22
Female
55
No
Yes
16
Yes
23
Female
68
No
Yes
37
Yes
24
Male
36
No
No
47
Yes
25
Female
63
No
Yes
37
Yes
26
Female
62
No
Yes
17
Yes
27
Female
48
No
Yes
47
Yes
28
Male
36
No
No
25
Yes
29
Female
68
No
Yes
15
Yes
30
Female
46
Yes
No
24
Yes
Summary of reported frequencies.
Variables
Frequency (%)
Sex
Female
21 (70)
Male
9 (30)
Type of tooth
Anterior
3 (10)
Posterior
27 (90)
Resistance genes
Absent
08 (26.66)
Present
22 (73.34)
Symptomatology
Absent
10 (33.33)
Present
20 (66.66)
Periapical lesion
Absent
17 (56.66)
Present
13 (43.34)
Mean±standarddeviation
Age (years)
46.43±17.42
Agarose gel electrophoresis of PCR products from bacteria samples extracted from root-filled teeth. In the first well, the base pair marker (50 bp) was loaded. In the following wells, negative (milliQ water) and positive control (Enterobacter cloacae 13047) were loaded. The amplification products of each sample were loaded in triplicate from individual reactions.
The absence/presence of silver resistance genes (absence=0 and presence=1) was correlated with periapical lesion (absence=0 and presence=1), symptomatology (absence=0 and presence=1), and type of tooth (anterior=0 and posterior=1). A Rho=0.08 (periapical lesion), 0.20 (tooth), and 0.05 (symptomatology) with a P>0.05 was obtained. Considering the three variables, the highest correlation identified was between the presences of silver resistance genes with posterior teeth.
4. Discussion
The objective of this study was to identify the presence of silCBA genes in a bacterial pool from root-filled teeth. During the review of the literature, no studies similar to ours were found in endodontic bacteria. The results of this study show a high presence of silCBA silver resistance genes. Of all the samples analyzed, 73.3% of the samples were positive for the desired genes. This is the first time that silver resistance genes have been identified in bacteria from root-filled teeth. There is only one previous report in which it was possible to isolate two strains of silver-resistant Enterobacter cloacae from samples of extracted teeth. In that study, only the presence of the silE silver resistance gene was identified in the genomic and plasmid DNA from the two strains of silver-resistant Enterobacter cloacae. The gene, silE, only encodes for a silver ion transport protein and is not always present together with the other genes that constitute the sil operon. In our study, we analyzed the presence of silCBA genes, since these are the ones that encode for the silver ion efflux pump, which is the main mechanism of resistance [16]. We consider that the presence of the silCBA genes reported in this study is high in comparison with what was previously reported. For example, Davis et al. isolated 97 bacteria, of which only 2 were resistant to AgNO3. These two bacteria (Enterobacter cloacae Ag703 and Enterobacter cloacae Ag1157) were also positive for the presence of the silE genes that represents 2% of the total bacteria isolated [16]. Finley et al. analyzed the presence of the 8 genes of the sil operon in 859 bacterial strains isolated from patients at a tertiary care facility. They found that these genes were present in 32 isolates, representing 3.7% of the total samples [12]. Woods et al. reported the presence of sil genes in 6 of 172 (3.4%) bacteria isolated from chronic wounds in humans and horses. Sütterlin et al. analyzed the presence of silver resistance genes (silE, silS, and silP) in 839 isolated bacterial strains over a period of 10 years. At least one of the three silver resistance genes analyzed was present in 176 (21%) strains of the 839 strains analyzed [17]. In one study, we found a prevalence of sil genes similar to that reported by us. Andrade et al. analyzed the presence of silA in 27 Enterobacter cloacae Complex (EcC) and 8 Enterobacter aerogenes isolates. They found the silA gene in 21 of 27 (78%) EcC isolates, while the silA gene was found only in a single E. cloacae isolate [18].
The difference of the aforementioned results to those of our study may be due to the fact that in the aforementioned studies a preselection of bacteria capable of growing on agar supplemented with AgNO3 was done [5]. This preselection of bacterial strains tended to reduce considerably the number of strains from which the detection of the resistance genes was carried out. Besides, it is possible that some bacteria have the resistance genes but do not express them in sufficient quantities to allow them to grow on agar supplemented with AgNO3. This could have caused its incorrect elimination of the total bacterial strains studied. These factors could be the cause of the extremely low prevalence reported in previous studies in comparison with the high prevalence reported in this study. Another difference between our study and the previous studies is that we did the detection of genes in mixed bacterial samples, whereas most of the previous reports made the detection of the genes from pure cultures of bacterial strains.
The high prevalence of the silCBA resistance genes in endodontic bacteria from root-filled teeth reported in this study may be due to the fact that these genes were previously reported in bacteria like Enterobacter cloacae, Enterococcus sp., Klebsiella oxytoca, Klebsiella pneumoniae, Proteus mirabilis, Pseudomonas aeruginosa, and Staphylococcus aureus [12]. Some of these bacteria have also been reported in teeth with persistent endodontic infections. For example, Murad et al. reported the presence of Enterococcus faecalis, Enterococcus faecium, Klebsiella pneumoniae, Enterobacter cloacae, and Staphylococcus aureus in different percentages using checkerboard DNA-DNA hybridization [19]. Sunde et al. detected Staphylococcus aureus in persistent periradicular lesions after root canal treatment [20]. Peciuliene et al. isolated Proteus mirabilis, Klebsiella pneumoniae, and E. faecalis from root-filled teeth with chronic apical periodontitis [21]. Although the genes of the sil operon are only expressed by gram-negative bacteria, some studies also report the presence of these genes in gram-positive bacteria [12]. This could be due to the fact that these genes move together with antibiotic resistance genes in plasmids that could be present in both types of bacteria. Although the genes of the sil operon cannot be expressed in gram-positive bacteria, its presence in this type of bacteria is of importance. Under stress conditions, these genes could be transmitted to bacterial strains with the ability to express them [22, 23] due to horizontal gene transfer, which is increased in biofilms that are the main form of bacterial growth in infected root canals with secondary endodontic infection [24, 25].
The presence of silver resistance genes in endodontic bacteria could be due to the fact that these genes move together with antibiotic resistance genes found in plasmids, and clinical strains of bacteria species associated with root canal infections (like Enterococcus faecalis) can carry a large variety of plasmids [9]. For example, Pal et al. analyzed the genomic sequence of plasmids from NCBI bacterial genome database. They reported that frequently in the same plasmid could be found genes of resistance to antibiotics and metals [26]. Even nonpathogenic bacteria such as E. coli have a large presence of plasmids with both types of resistance genes [10]. The finding of these genes in endodontic bacteria is important since the efflux pumps expressed by them have been linked to the development of resistance to nanoparticles and antibiotics; and to date, this type of resistance has not been studied in endodontic bacteria. For example, Jianhua et al. exposed Pseudomonas aeruginosa PAO1 to different concentrations (1, 10, and 50 mg/l CuONPs) of copper nanoparticles. They found that this caused an upregulation of resistance genes that code for cation diffusion facilitator transporters, P-type ATPase efflux, and copper efflux pumps from the RND family [27]. Yang et al. also exposed Pseudomonas aeruginosa PAO1 to low concentration (160 nM) of intact and weathered quantum dots (QDs) (7.4±1.1nm). After the sublethal exposure to QDs, the transcriptomic analysis revealed an upregulation in the transcriptional unit czcABC that codes for three proteins (CzcA, CzcB, and CzcC) that together form an efflux pump from the RND family. A secondary effect of the sublethal exposure was the increase of antibiotic resistance to different antibiotics (ampicillin, chloramphenicol, kanamycin, and tetracycline) reported by the increase in their minimum inhibitory concentrations (up to 100% in some cases) [28]. The resistance genes (silCBA) that we studied in this article also code for efflux pumps of the RND family (silCBA). In addition, the sil operon contains the gene silP that codes for an efflux pump of the ATPase family, although this efflux pump has not been well characterized [29]. There are reports in which negative and positive gram bacteria generate resistance to silver nanoparticles after exposure to sublethal doses, but none of these studies evaluates the participation of the silver resistance genes that code for efflux pumps from the RND family [30, 31]. For example, Kaweeteerawat et al. exposed gram-negative (E. coli) and gram-positive bacteria (S. aureus) at sublethal doses of silver nanoparticles and observed an increase in the minimum inhibitory concentrations after only four rounds of subculturing. The authors of this article did not investigate the participation of silver ion efflux pumps from the RND family in this type of resistance [32]. Mishra et al. treated Enterobacter cloacae 13047 and multidrug resistance Enterobacter cloacae, with a sublethal concentration of AgNPs (6 mg/ml) and silver-metal-carbohydrate nanoparticle (Ag-MCNPs) (0.75 mg/ml) for 0, 30, 60, 120, and 180 min. They did not find a significant increase in the expression of the AcrAB-TolC efflux pump. In this study, the authors did not analyze the participation of silver ion efflux pumps in the development of resistance. The authors only analyzed the participation of the AcrAB-TolC efflux pump, which does not participate in the efflux of silver ions. The AcrAB-TolC efflux pump only participates in the expulsion of antibacterial drugs [33].
Recently, it has been hypothesized that the presence of this type of genes in bacteria is due not only to the presence of metals in the environment, but they are the result of the development of defenses against bacteria predatory organisms as the protozoa or as defense against immune system cells like macrophages. For example, both protozoa and macrophages employ Zn2+ and Cu+ to attack Fe–S clusters (essential for bacterial survival) during phagocytosis of bacteria. Therefore, resistance to silver can be a by-product of copper and zinc resistance developed by bacteria to survive phagocytosis by protozoa and macrophages. This hypothesis is because most of the so-called sil determinants are part of a bigger genomic island (recently named “copper pathogenicity island”) which confers resistance to copper and silver [34].
After a review of the literature, as far as we know, there are no studies in the endodontic literature in which the presence of resistance genes is correlated with the different clinical symptoms of resistant infections (secondary endodontic infection). Many studies have only focused on detecting the presence of resistance genes in different oral environments, including bacteria isolated from different types of endodontic infections [35, 36]. Other studies have only been dedicated to associate the presence of certain bacterial species with the presence of clinical symptoms [37]. The only study similar to ours that we found during the review of the literature is that of De Lima et al. In this study, the authors only analyzed the association between the presence of lactamic resistance genes (blaTEM) and clinical parameters (pulpal diagnosis, sinus tract, pain, and swelling); but they found no association between these variables [38]. The correlation of the presence of resistance genes with the clinical symptoms of secondary endodontic infection could provide information on why certain bacteria are present in certain types of infection and how they influence their symptomatology. In our study, considering the three variables, the highest correlation identified was between the presences of silver resistance genes with posterior teeth. This is because this type of teeth is the first to be present in the oral cavity and therefore is the first to develop deep caries and present endodontic infection. In addition, the internal anatomy of this type of teeth is more complex, so they tend to have a greater diversity of microorganisms [39].
5. Conclusion
This study demonstrates a high prevalence of silver resistance genes in endodontic bacteria. This could indicate that endodontic bacteria are able to develop resistance to silver nanoparticles in the long term. This also invites us to reevaluate the use of nanoparticles (especially silver nanoparticles) as antimicrobial agents in endodontics, since the increase in this type of resistance could bring serious side effects such as costimulation of the increase in resistance to antibiotics and other antimicrobial agents, which would make the management of resistant infections (like secondary endodontic infections) even more difficult.
5.1. Future Perspectives
Despite the great variety of studies evaluating the antimicrobial capacity of nanoparticles, few studies have been devoted to studying the defense mechanisms of bacteria against nanoparticles. The authors of this paper call into action the need for better understanding of the long-term interactions between nanoparticles and microbes. It is important to determine all possible mechanisms of bacterial resistance not only to silver nanoparticles but also to the wide variety of metal and metal oxide nanoparticles. More studies are needed to determine which bacteria have nanoparticle resistance mechanisms, which is the capacity of bacteria to maintain the mechanisms of resistance and to transmit them to other species, and how the management of resistant infections could be affected by such resistance mechanism. This will help us to avoid in the future the appearance of this type of resistance and its possible side effects, which, as already mentioned, may be the costimulation of resistance to antibiotics and other antimicrobial agents, which is already a serious global health problem.
Data Availability
The data used to support the findings of this study are included within the article.
Conflicts of Interest
The authors deny any conflicts of interest.
Acknowledgments
This article was supported by Nanomateriales Multifuncionales para la Sustentabilidad y el Bienestar de la Sociedad (511-6/18-11856) (PROFIDES), FAI (C19-FAI-05-67.67), and CONACYT Scholarship number 460066.
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