INTRODUCTION

Dental caries continuous to be significant public health problem in many parts of the world. Although the bacte- ria responsible for caries initiation and early caries pro- gression have been studied extensively, the microbiology of dentine caries has been reported to show considerable diversity and has not yet been fully characterized. It is a multifactorial disease which is caused by host agents and environmental factors. The disease continues to be major problem in dentistry affecting the mankind even today. It affects persons of both genders in all races, all socioeconomic strata and every age group. A wide group of microorganisms can be isolated from carious lesions of which Streptococcus mutans, Lactobacillus acidophilus, Lactobacillus fermentum, Actinomyces vis- cosus are the main pathogenic species involved in the initiation and development of carious lesions (Aas et al., 2008 Rizwan Ullah and Zafar, 2015).

However, Lactobacilli are generally considered to be non-pathogenic except in dental caries (Attebery and Finegold, 1970). Historically Lactobacilli were the first microorganisms implicated in dental caries devel- opment. This genus is involved in the progression of carious and caries dentin is the main ecological site of Lactobacilli. They appear during the first years of child’s and are present in high numbers in saliva, on the dorsum of the tongue, mucous membranes, the hard plate, in dental plaque and few numbers, on tooth sur- face (Straetemans et al., 1998). During the last fifteen years, the Lactobacillus genus has subjected to numer- ous taxonomical changes and includes at present more than 80 species (Loesche et al., 1984), some of which having been found in the oral cavity. Lactobacilli seem to be mostly transient in the oral cavity of small chil- dren, and only later a resident Lactobacillus f lora is established (Badet and Thebaud, 2008). Their analysis of Lactobacilli by culture under micro aerophilic condi- tions in 65 deep caries samples indicated that Lactoba- cillus acidophilus was numerically dominant, although Lactobacillus paracasei, Lactobacillus rhamnosus, and Lactobacillus fermentum were also present in many samples (Martin et al., 2002 and Bernable and Shei- ham, 2014).

Lactic acid bacteria produce various compounds such as organic acids di-acetyl, hydrogen peroxide and bacteriocin or bacteria proteins during lactic fer- mentations (Oyetayo et al., 2003). But in the oral cav- ity infections caused by Lactobacillus may be under reported in the medical literature because of the fail- ure or reluctance to recognize it as a true pathogen (Antony et al., 1996). Children receiving 200,000 U of oral penicillin daily for rheumatic fever prophylaxis

Vijayalakshmi and Mohankumar

have been reported to experience reduction in the inci- dence of dental caries of up to 56% as compared with their untreated sibling’s (Handle man et al., 1966). The oral penicillin therapy had no effect on the number of salivary Lactobacilli and that the penicillin resistances of the total flora, the Streptococci, and the Staphylo- cocci in the saliva’s of the antibiotic users were higher than those in the untreated sibling’s (Handle man and Hawas, 1965,1964).

Antibiotics provide an invaluable tool for a control of infection in modern dentistry (Cruickshank, 1968). Development of resistance to various antibiotics makes it necessary to select logically and rationally, a drug for successful gingival therapy during orthodontic treat- ment. Moreover, most of the antimicrobial agents that are currently in use have been rendered ineffective by a wide occurrence of multiple drug resistant strains of microbes (Owhe – Ureghe et al., 2010).

Infectious diseases are the leading cause of death world-wide and at the same time antibiotic resistance has become a global concern (Westh et al., 2004). There- fore there has been an increasing incidence of multi- ple resistance in human pathogenic microorganisms in recent years, largely due to indiscriminate use of com- mercial antimicrobial drugs commonly employed in the treatment of infectious diseases. The development of bacterial resistance to presently available antibiotics has necessitated the search for new antibacterial agents (Mylotte et al., 1987).

Resistant bacteria which are human pathogens may cause disease that are difficult to treat. A breakthrough came with the discovery that antibiotic resistance is transmitted by mixed cultivation between drug-resist- ant and sensitive strains independently of the donor strain chromosome. Many studies of drug resistant and its extra chromosomal position have been carried out. Very few reports exist on drug resistance in members of Lactobacillus genus (Sozzi and Smiley, 1980) and its link with plasmid (Klaenhammer and Sutherland, 1980). Recurrently, the fluoride ion (F) has been widely used topically in the treatment of dental caries for its anticar- iogenic and antimicrobial properties (Rizwan Ullah and Zafar, 2015). Thorough mechanical removal of plaque twice daily with a fluoride-containing tooth paste is a commonly-taught method of caries prevention. However, studies show that incidence of dental caries remains high (Bernable and Sheiham, 2014), suggesting that such regimens are commonly not strictly adhered to. So, hence the present study has made on attempt to point out the emerging of sodium fluoride resistant cari- ogenic Lactobacilli which is isolated from rural child- hood caries, and the multidrug resistant organism link with plasmids.

Vijayalakshmi and Mohankumar

MATERIALS AND METHODS

SAMPLE COLLECTION

The plaque samples were collected from tooth decay of rural patients using sterile forceps around Tirupur District. The sample was suspended in sterilized screw capped bottle with saline solution. It was place in ice pack box and were brought in to the laboratory. Then, the samples were incubated at 37°C for 24 hours and the samples were used for isolation of cariogenic bacteria.

ISOLATION OF CARIOGENIC LACTOBACILLUS SPP. FROM DENTAL PLAQUE SAMPLES

All the strains isolated from dental plaque samples were serially diluted from 10-1 to 10-9 and the dilutions 10-4 to 10-6 were plated onto Man, Rogosa and Sharpe media (MRS) agar it was incubated at 37°C for 48 hours. The individual colonies with different morphology were picked using sterile tooth pick and grown in MRS broth and it was incubated at 37°C for 24hours. Further it was plated to check for purity.

PHENOTYPIC CHARACTERIZATION

The isolated bacteria were primarily identified on the basis of the Gram staining, IMViC test, oxidase test, nitrate reduction test, motility test, different carbohy- drate fermentation test, starch hydrolysis, growth at dif- ferent pH, growth at 15°C and 45°C in the Lactobacilli de Mann Rogosa and Sharpe (MRS) broth as described as Bergy’s Manual of Systematic Bacteriology (Kandler and Weiss, 1986). These isolates were used as a lactic acid producing strain. All lactobacilli strains used in this study were grown in MRS broth at 37°C for 24 hours.

LACTIC ACID PRODUCTION ASSAY

Isolates were screened for the production of lactic acid using the titrimetric estimation (AOAC, 1990). For these measurements, the test organisms were grown on MRS broth for 48 hours and supernatant was collected by centrifuging at 10,000 rpm for 15 minutes at 4°C. Phe- nolphalein was added in to the 20 ml of supernatant as an indicator for titrimetric estimation. One ml of 0.1M NaOH is equivalent to 90.08 mg of lactic acid.

ANTIBIOTIC SUSCEPTIBILITY TEST

Antibiotic susceptibility was semi-quantitatively deter- mined by disc diffusion method (Katla et al., 2001). There are different group of antibiotics were tested: Class I Group – Inhibitors of cell wall synthesis (Amoxicillin,

Cloxacillin, Vancomycin), Class II Group – Inhibitors of protein synthesis (Azithromycin, Clarithromycin, Roxi- thromycin), Class III Group - Inhibitors of nucleic acid synthesis (Ciprofloxacin, Rifampicin), Class IV Group – Inhibitors of folate metabolism (Sulphamethizole, Tri- methoprim). The culture was inoculated into the MRS broth which was incubated at 37°C for 12hours. Plates were made with Mueller Hinton agar and allowed to solidified 10 to 15 minutes. 0.1ml of this culture were inoculated in the plates by spread plate technique. The antibiotic disks of Amoxicillin (30mcg), Cloxacillin (5mcg), Vancomycin (30mcg), Azithromycin (30mcg), Clarithromycin (15mcg), Roxithromycin (30mcg), Cip- rofloxacin (30mcg), Rifampicin (30mcg), Sulfamethizole (300mcg), and Trimethoprim (30mcg) were placed in the plates. Then the plates were incubated for 37°C 24 hours. The diameters of the inhibition zone were meas- ured using a ruler under a colony counter apparatus. The results were expressed as sensitive (S), marginally susceptible (I), and resistant (R).

EFFECT OF SODIUM FLUORIDE (NAF) USED AGAINST LACTOBACILLUS SPP.

The NaF was performed by using well diffusion method (Yavagal et al., 2014). About 20 ml of sterile molten Mueller Hinton agar was poured into the sterile petri- plates. Triplicate plates were swabbed with the overnight culture (108cells /ml) of pathogenic bacteria Lactobacil- lus spp. different concentration of NaF (0.25%, 0.50%, 0.75% and 1%) were prepared and screened against fifty isolates of Lactobacillus spp. The isolates were selected on the basis of Lactobacillus spp. should have above 50% antibacterial activity against the antibiotics tested: Amoxicillin, Cloxacillin, Vancomycin, Azithro- mycin, Clarithromycin, Roxithromycin, Ciprofloxacin, Rifampicin, Sulphamethizole, and Trimethoprim. The solid medium was gently punctured with the help of cork borer to make a well. Different concentration of NaF: 50μl, 100μl and 150μl, were added from the stock into each well and incubated for 24h at 37±2oC. After 24 hrs of incubation, the zone of inhibition was measured and expressed as millimeter in diameter.

PLASMID ANALYSIS

Plasmid were isolated from cariogenic Lactobacilli, using the previous method (Holmes and Quigley, 1981) and the presence of plasmid was checked by 0.7% agarose gel was with visualized under UV light on transiluminator and photographed. Size of the plasmids was determined with the help of a calibration curve prepared using log MW (kb) of the standard molecular marker.

RESULTS AND DISCUSSION

Totally 22 multidrug resistant isolates were identified as Lactobacillus spp. according to Bergy’s manual of Bac- teriology. Isolated cariogenic Lactobacillus spp. isolates were tested invitro to determine antibiotic susceptibility patterns by antibiotic disc diffusion method. There are different group of antibiotics were tested: Class I Group

–Inhibitors of cell wall synthesis (Amoxicillin, Cloxacil- lin, Vancomycin), Class II Group – Inhibitors of protein synthesis (Azithromycin, Clarithromycin, Roxithromy- cin), Class III Group - Inhibitors of nucleic acid synthesis (Ciprofloxacin, Rifampicin), Class IV Group – Inhibitors of folate metabolism (Sulphamethizole, Trimethoprim). The antibiotic discs of Amoxicillin (30mcg), Cloxacil- lin (5mcg), Vancomycin (30mcg), Azithromycin (30mcg), Clarithromycin (15mcg), Roxithromycin (30mcg), Cipro- floxacin (30mcg), Rifampicin (30mcg), Sulfamethizole (300mcg), and Trimethoprim (30mcg). Totally 10 anti- biotic discs were used to identify drug resistant Lacto- bacillus spp. All the isolates showed multiple antibiotic resistances to the antibiotic used in this study. The maxi- mum resistant pattern percentage (100%) was recorded in strain no VG22 and the minimum resistant pattern percentage (10%) was recorded in strain no VG01.

Among 22 strains, Strain No Vg22 was observed 100% resistant with the following antibiogram: SM-

VA-RO-TR-RIF-AZM-AMX-CIP-CLR-COX followed by the 90% with antibiogram of SM-VA-RO-TR-AZM- AMX-CIP-CLR-COX was recorded in strain no. Vg21. Whereas strain no. Vg20 was logged 70% with antibio- gram of VA-RO-TR-AZM-CIP-CLR-COX followed by the strain no. Vg19 showed 60% with antibiogram of SM- RO-TR-CIP-CLR-COX followed by the strain no. Vg16, Vg17 and Vg18, noted resistant against five antibiot- ics which showed 50% frequency the antibiogram was SM-VA-RO-TR-COX, VA-RO-CIP-CLR-COX and SM-VA-

Table 1: Antibiotic Resistant

Percentage of Lactobacillus spp.

Vijayalakshmi and Mohankumar

RO-AZM-COX followed by the strain no. Vg12, Vg13, Vg14 and Vg15, documented resistant against four anti- biotics which showed 40% frequency the antibiogram was VA-RO-CLR-COX, SM-TR-COX-CLR, VA-TR-AZM- COX and TR-SM-AZM-COX followed by the strain no. Vg05, Vg06, Vg07, Vg08, Vg09, Vg10 and Vg11, showed resistant against three antibiotics which showed 30% frequency the antibiogram was TR-VA-COX, SM-VA- COX, SM-TR-COX, VA-AMX-COX, TR-AZM-COX, VA- AZM-COX and SM-AMX-COX followed by the strain no. Vg02, Vg03 and VGg4, showed resistant against two antibiotics which exhibited 20% frequency the antibio- gram was SM-TR, TR-COX and VA-COX monitored by the strain no. Vg01, detailed resistant against one anti- biotics which showed 10% frequency the antibiogram was COX.

The isolates were analyzed for antibiogram as described to determine the antibiotic susceptibility pattern along with the tendency of current resistance against widely used drugs. Among 50 isolates, 22 different antibiogram were found and showed resistance against Amoxicillin (8%), Cloxacillin (98%), Vancomycin (40%), Azithromy- cin (18%), Clarithromycin (14%), Roxithromycin (18%), Ciprofloxacin (10%), Rifampicin (2%), Sulfamethizole (40%), and Trimethoprim (68%) (Table: 14).

Multiple Antibiotic Resistance (MAR) index was cal- culated according to the standard formula. Maximum MAR index 1.0 was showed by Vg15 and minimum MAR index 0.1 was showed by Vg6 and Vg07.

Seven isolates: Vg08, Vg13, Vg14, Vg15, Vg22, Vg47, and Vg48 which was showed more than above 50% resistance used for plasmid DNA isolation by boil- ing preparation method of (Holmes & Quigley, 1981; modified by Riggs & McLachlan, 1986).

Three fragments were obtained in Strain No Vg22, Vg47 and Vg48 with molecular weight of 1500bp, 1000bp, and 100bp respectively, followed by the Strain No. Vg08, Vg13, and Vg14 were harboured three frag- ments of molecular weight 1500bp, 300bp, and 100bp and other one isolate Vg15 were harboured one frag- ment of molecular weight 1500bp respectively. This strain was showed maximum resistant against the anti- biotics tested. Molecular weight of the fragments was estimated by using 100bp DNA ladder (Medox, Chennai), Multidrug resistance bacteria were found to be carrying plasmids (Figure: 7).

The growth medium of Lactobacillus spp. was adjusted at different pH values: pH 2.0, pH 2.5, pH 3.0, pH 3.5, pH 4.0, pH 4.5, pH 5.0, pH 5.5, pH 6.0, pH 6.5, pH 7.0, pH 7.5 and pH 8.0. The results indicated that the rapid growth was obtained from pH 6 to pH 8, and declined in pH 2.0 and pH 5.5. Maximum growth was recorded in pH 6.5 it indicates the optimum pH for the growth of Lactobacillus spp. is pH 6.5.

The growth medium of Lactobacillus spp. was adjusted at different temperature: 30°C, 35°C, 40°C and 45°C. The results showed maximum growth was observed in 35°C it indicates the optimum temperature for the growth of cariogenic LAB and the growth was declined in 45°C.

Lactic acid production of above 50% resistant plas- mid strains were studied by titrimetric estimation which include Vg08,Vg13,Vg14,Vg15,Vg22,Vg47 and Vg48 produce equal amount of lactic acid 9.008 mg/ml in the oral cavity of rural caries patients.

NaF was performed by using agar cup diffusion assay. Different concentrations of NaF (0.25%, 0.50%, 0.75% and 1%) were used against multidrug resistance cari- ogenic isolates. NaF was used and it shows prominent resistant activity against decay causing organism.

Dental caries is a complex process masked by many indirect factors which obscure the direct causes. Bac-

teria are through to play an integral role in this proc- ess. Cariogenic microorganisms colonize on tooth sur- face, causes a marked reduction of pH in the presence of sugar substrate, and consequently induce dental caries. Previous studies showed that Lactobacilli is an efficient cariogenic microorganisms the bacteria widely distrib- uted in the nature and occurring naturally as indigenous micro flora in decay oral that play an important role in much food and feed fermentations. This special effect is due to the production of certain antimicrobial substance in the name of lactic acid. Antibiotics provide an invalu- able tool for a control of infection in modern dentistry. Development of resistance to various antibiotics makes it necessary to select logically and rationally, a drug for successful gingival therapy during orthodontic treat- ment. Resistance in microorganisms was caused by extra chromosomal elements. Many studies of drug resistant

FIGURE 2. Plasmid profile of Lactoba- cillus spp.

and its extra chromosomal position have been carried out. Very few reports exits on drug resistance in mem- bers of Lactobacillus genus and its link with pla Kheadr, (2006) determined the susceptibility of 13 Lactobacillus strains to 14 antibiotics and to evaluate the impact of some gastrointestinal stressful conditions, particularly acid and bile stress, as well as acid adaptation on their antibiogram profiles. The strains tested were 2 of Lacto- bacillus acidophilus, 1 Lb. delbrueckii subsp. bulgaricus, 2 Lb. casei, 1 Lb. casei paracasei subsp. paracasei, 1 Lb. delbrueckii subsp. lactis, 4 Lb. plantarum and 2 Lb. rhamnosus. In control trails, the majority of the strains tested were susceptible to Ampicillin, Penicillin, Chlo- ramphenicol, Erythromycin, Novobiocin and Nisin A, but resistant to Vancomycin, Kanamycin, Neomycin, Paro- momycin, Streptomycin and Nalidixic acid. Lactobacilli strains showed variable susceptibility to Cloxacillin and Tetracycline. Acid-adaptation (strains adapted to grow at pH 4.0) resulted in increased resistance to Cloxacil- lin, Erythromycin and Tetracycline, in strain dependent manner. Acid- stressed (exposure to pH 2 for 90 min at 37˚C) Lactobacilli appeared to be more resistant to Amp- icillin, Cloxacillin, Chloramphenicol and Tetracycline compared with un-stressed strains. In the presence of 0.3% (w/v) ox gall, Lactobacilli became more susceptible to amino glycosides and slightly resistant to cell wall- targeted antibiotics. However, Oxgall stress (exposure to 0.3% (w/v) ox gall for 90 min at 37˚C) slightly modi- fied antibiogram profile depending on the strain tested. Results obtained in the present study showed Lactoba- cilli became more susceptible to ample spectrum penicil- lin such as Amoxicillin and more resistant to β–Lactam

FIGURE 3. Isolated used for plasmid isolation

group of antibiotic such as Cloxacillin, glycopeptide group of antibiotic Vancomycin and slightly resistant to inhibitors of nucleic acid synthesis.

Lavanya et al., (2011) studied, the antimicrobial sus- ceptibilities and presence of plasmids in 7 probiotics strains which had been isolated from the fermented milk were determined. Resistance to 8 commonly used anti- biotics β- Lactams (Penicillin, Ampicillin), gram positive spectrum (Vancomycin), Broad spectrum (Rifampin, Tri- methoprim) and Aminoglycosides’ (Kanamycin, Strepto- mycin, and Bacitracin) was assessed by disk diffusion. Among these strains 20, 20, 60, 70, 90 and 100% were found to be exhibit a significant degree of resistance to Kanamycin, Trimethoprim, Rifampicin, Ampicillin and Penicillin respectively. Further, plasmid profile and cur- ing of plasmid were performed for the seven isolates. Analysis of the plasmid profiles of the 7 cured deriva- tives revealed loss of plasmids except 2 strains where curing was partially effective. All the strains lost Peni- cillin resistance after curing indicating that plasmids encodes for resistance character.

However, Vancomycin resistance is not lost upon curing which indicates that such resistance is usually intrinsic. Finally, the antimicrobial susceptibility after curing was done to check the safety aspect of the iso- lates for their application as probiotics and among the 7 strains, 5 were proved to be potent probiotics. In this present investigation, antimicrobial susceptibilities and presence of plasmids in 7 cariogenic strains which had been isolated from the plaque samples. Resistance to 3 commonly used antibiotics (Vancomycin, Rifampicin, and Trimethoprim) was assessed by disk diffusion. Among these strains 40%, 2% and 68% were found to be exhibit a significant degree of resistance to Vancomycin, Rifampicin and Trimethoprim respectively.

O’Sullivan and Klaenhammer, (1993) reported a sim- ple, rapid plasmid mini-prep procedure for Lactococci and Lactobacilli which gives high yields and can be per-

Vijayalakshmi and Mohankumar

formed on overnight broth cultures is presented. Large plasmids were isolated from both Lactococci and Lacto- bacilli, including a 70-kb plasmid from Lactobacillus acidophilus C7. The purity of the resulting plasmid DNA makes it suitable for subsequent molecular manipula- tions. The convenience of the technique makes this rapid mini-prep procedure suitable for routine plasmid isola- tion from lactic acid bacteria. But in this research, plas- mid DNA was done by boiling preparation method (Hol- mes & Quigley, 1981; modified by Riggs & McLachlan, 1986). Plasmids were isolated from Lactobacilli, includ- ing a range from 1500bp to 100bp respectively.

A significant reduction between pre-test and post-test was found only for salivary S. mutans count (p=0.006) in 0.5% NaF impregnated miswak sticks group but not for salivary Lactobacilli count. Sodium fluoride when impregnated to miswak sticks did not significantly add to the antimicrobial efficacy (Yavagal et al., 2014). But in this study showed dissimilar results of antimicrobial ability of sodium fluoride without miswak stick ingredi- ents at concentration of 0.5% used against oral patho- gen. The NaF was used and it shows prominent resistant activity against decay causing organism.

CONCLUSION

Development of resistance to antibiotics by bacteria is inevitable, not only because of their rates in mutation and transferability of drug resistant genes. Resistance in microorganisms caused by extra chromosomal ele- ments. A breakthrough came with the discovery that antibiotic resistance is transmitted by mixed cultivation between drug-resistant and sensitive strains independ- ently of the donor strain chromosome. It is concluded from the present study that species of cariogenic Lacto- bacillus isolated from plaque. The rapid emergence of drug resistant strains of microbial cariogenic pathogen especially those with multi drug resistance character- istics and the organism link with a plasmid have the ability to survive at low pH and low temperatures and had strongly to produce antimicrobial substance during fermentation process. These results also suggests that the consumption of carbonated drinks, eating of fast foods, chocolates and fruit juices from bakery shops. The products those enhances the food supply to growing plaque forming microorganisms and the condition favo- rable for development of pathogenic microorganisms. NaF is currently, as antimicrobial the most promising tools applied as antimicrobial agents for diagnosis the dental disease. However the present study NaF was used and it shows prominent resistant activity against decay causing organism. Moreover, most antimicrobial agents that are currently in use have been rendered in effective

by a wide occurrence of multi drug resistant strains of microbes.

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