Streptococcus mutans

S. mutans is naturally present in the human oral microbiota, along with at least 25 other species of oral streptococci. The taxonomy of these bacteria remains tentative. Different areas of the oral cavity present different ecological niches, and each species has specific properties for colonizing different oral sites. S. mutans is most prevalent on the pits and fissures, constituting 39% of the total streptococci in the oral cavity. Fewer S. mutans bacteria are found on the buccal surface (2–9%). Bacterial-fungal co-coaggregation can help to increase the cariogenic potential of S. mutans. A symbiotic relationship with S. mutans and Candida albicans leads to increased glucan production and increased biofilm formation. This therefore amplifies the cariogenic effect of S. mutans. Oral streptococci comprise both harmless and harmful bacteria. However, under special conditions commensal streptococci can become opportunistic pathogens, initiating disease and damaging the host. Imbalances in the microbial biota can initiate oral diseases. C. albicans is an opportunistic pathogenic yeast that can be found within the oral cavity. Its presence in the biofilm promotes higher levels of S. mutans when looking at early childhood caries. It stimulates the formation of S. mutans microcolonies. This is achieved through low concentrations of cross-kingdom metabolites, such as farnesol, derived from the biofilm. It has been suggested that when both microbes are present, more biofilm matrix is produced, with a greater density. When farnesol is in high concentration, it inhibits the growth of both S. mutans and C. albicans. This decreases the biofilm pathogenesis, and therefore its caries promoting potential. This offers the potential for an anti-fungal to be used in the prevention of dental caries. ==Role in disease==

Tooth decay Early colonizers of the tooth surface are mainly Neisseria spp. and streptococci, including S. mutans. They must withstand the oral cleansing forces (e.g. saliva and the tongue movements) and adhere sufficiently to the dental hard tissues. The growth and metabolism of these pioneer species changes local environmental conditions (e.g., Eh, pH, coaggregation, and substrate availability), thereby enabling more fastidious organisms to further colonize after them, forming dental plaque. Along with S. sobrinus, S. mutans plays a major role in tooth decay, metabolizing sucrose to lactic acid. The acidic environment created in the mouth by this process is what causes the highly mineralized tooth enamel to be vulnerable to decay. S. mutans is one of a few specialized organisms equipped with receptors that improve adhesion to the surface of teeth. S. mutans uses the glucosyltransferase enzymes to convert the glucosyl moiety of sucrose into a sticky, extracellular, dextran-like polysaccharide that allows them to cohere, forming plaque: : n sucrose → (glucose)n + n fructose Sucrose is the only sugar that bacteria can use to form this sticky polysaccharide. Due to the role S. mutans plays in tooth decay, many attempts have been made to create a vaccine for the organism. So far, such vaccines have not been successful in humans. Recently, proteins involved in the colonization of teeth by S. mutans have been shown to produce antibodies that inhibit the cariogenic process. A molecule recently synthesized at Yale University and the University of Chile, called Keep 32, is supposed to be able to kill S. mutans. Another candidate is a peptide called C16G2, synthesised at UCLA. It is believed that Streptococcus mutans acquired the gene that enables it to produce biofilms through horizontal gene transfer with other lactic acid bacterial species, such as Lactobacillus. Dental plaque, typically the precursor to tooth decay, contains more than 600 different microorganisms, contributing to the oral cavity's overall dynamic environment that frequently undergoes rapid changes in pH, nutrient availability, and oxygen tension. Dental plaque adheres to the teeth and consists of bacterial cells, while plaque is the biofilm on the surfaces of the teeth. Dental plaque and S. mutans is frequently exposed to "toxic compounds" from oral healthcare products, food additives, and tobacco. While S. mutans grows in the biofilm, cells maintain a balance of metabolism that involves production and detoxification. Biofilm is an aggregate of microorganisms in which cells adhere to each other or a surface. Bacteria in the biofilm community can actually generate various toxic compounds that interfere with the growth of other competing bacteria. S. mutans has over time developed strategies to successfully colonize and maintain a dominant presence in the oral cavity. The oral biofilm is continuously challenged by changes in the environmental conditions. In response to such changes, the bacterial community evolved with individual members and their specific functions to survive in the oral cavity. S. mutans has been able to evolve from nutrition-limiting conditions to protect itself in extreme conditions. A study into pH of plaque said that the critical pH for increased demineralisation of dental hard tissues (enamel and dentine) is 5.5. The Stephan curve illustrates how quickly the plaque pH can fall below 5.5 after a snack or meal. Dental caries is a dental biofilm-related oral disease associated with increased consumption of dietary sugar and fermentable carbohydrates. When dental biofilms remain on tooth surfaces, along with frequent exposure to sugars, acidogenic bacteria (members of dental biofilms) will metabolize the sugars to organic acids. Untreated dental caries is the most common disease affecting humans worldwide . Persistence of this acidic condition encourages the proliferation of acidogenic and aciduric bacteria as a result of their ability to survive at a low-pH environment. The low-pH environment in the biofilm matrix erodes the surface of the teeth and begins the "initiation" of the dental caries. and is thought to be a vital microorganism that contributes to this initiation. S. mutans thrives in acidic conditions, becoming the main bacterium in cultures with permanently reduced pH . If the adherence of S. mutans to the surface of teeth or the physiological ability (acidogenity and aciduricity) of S. mutans in dental biofilms can be reduced or eliminated, the acidification potential of dental biofilms and later cavity formations can be decreased. In young children, the pain from a carious lesion can be quite distressing and restorative treatment can cause an early dental anxiety to develop. Dental anxiety has knock-on effects for both dental professionals and patients. Treatment planning and therefore treatment success can be compromised. The dental staff can become stressed and frustrated when working with anxious children. This can compromise their relationship with the child and their parents. Studies have shown a cycle to exist, whereby dentally anxious patients avoid caring for the health of their oral tissues. They can sometimes avoid oral hygiene and will try to avoid seeking dental care until the pain is unbearable. Susceptibility to disease varies between individuals and immunological mechanisms have been proposed to confer protection or susceptibility to the disease. These mechanisms have yet to be fully elucidated but it seems that while antigen presenting cells are activated by S. mutans in vitro, they fail to respond in vivo. Immunological tolerance to S. mutans at the mucosal surface may make individuals more prone to colonisation with S. mutans and therefore increase susceptibility to dental caries. In children S. mutans is often acquired in the oral cavity subsequent to tooth eruption, but has also been detected in the oral cavity of predentate children. It is generally, but not exclusively, transmitted via vertical transmission from caregiver (generally the mother) to child. This can also commonly happen when the parent puts their lips to the child's bottle to taste it, or to clean the child's pacifier, then puts it into the child's mouth. Cardiovascular disease S. mutans is implicated in the pathogenesis of certain cardiovascular diseases, and is the most prevalent bacterial species detected in extirpated heart valve tissues, as well as in atheromatous plaques, with an incidence of 68.6% and 74.1%, respectively. Streptococcus sanguinis, closely related to S. mutans and also found in the oral cavity, has been shown to cause Infective Endocarditis. Streptococcus mutans has been associated with bacteraemia and infective endocarditis (IE). IE is divided into acute and subacute forms, and the bacterium is isolated in subacute cases. The common symptoms are: fever, chills, sweats, anorexia, weight loss, and malaise. S. mutans has been classified into four serotypes; c, e, f, and k. The classification of the serotypes is devised from the chemical composition of the serotype-specific rhamnose-glucose polymers. For example, serotype k initially found in blood isolates has a large reduction of glucose side chains attached to the rhamnose backbone. S. mutans has the following surface protein antigens: glucosyltransferases, protein antigen and glucan-binding proteins. If these surface protein antigens are not present, then the bacteria is a protein antigen-defective mutant with the least susceptibility to phagocytosis therefore causing the least harm to cells. Furthermore, rat experiments showed that infection with such defective streptococcus mutants (S. mutans strains without glucosyltransferases isolated from a destroyed heart valve of an infective endocarditis patient) resulted in a longer duration of bacteraemia. The results demonstrate that the virulence of infective endocarditis caused by S. mutans is linked to the specific cell surface components present. In addition, S. mutans DNA has been found in cardiovascular specimens at a higher ratio than other periodontal bacteria. This highlights its possible involvement in a variety of types of cardiovascular diseases, not just confined to bacteraemia and infective endocarditis. ==Prevention and treatment==

Practice of good oral hygiene including daily brushing, flossing and the use of appropriate mouthwash can significantly reduce the number of oral bacteria, including S. mutans and inhibit their proliferation. S. mutans often live in dental plaque, hence mechanical removal of plaque is an effective way of getting rid of them. The best toothbrushing technique to reduce plaque build up, decreasing caries risk, is the modified Bass technique. Brushing twice daily can help decrease the caries risk. However, there are some remedies used in the treatment of oral bacterial infection, in conjunction with mechanical cleaning. These include fluoride, which has a direct inhibitory effect on the enolase enzyme, as well as chlorhexidine, which works presumably by interfering with bacterial adherence. Furthermore, fluoride ions can be detrimental to bacterial cell metabolism. Fluoride directly inhibits glycolytic enzymes and H+ATPases. Fluoride ions also lower the pH of the cytoplasm. This means there will be less acid produced during the bacterial glycolysis. Therefore, fluoride mouthwashes, toothpastes, gels and varnishes can help to reduce the prevalence of caries. However, findings from investigations into the effect of fluoride-containing varnish, on the level of Streptococcus mutans in the oral environment in children suggest that the reduction of caries cannot be explained by a reduction in the level of Streptococcus mutans in saliva or dental plaque. Fluoride varnish treatment with or without prior dental hygiene has no significant effect on the plaque and salivary levels of S. mutans. S. mutans secretes Glucosyltransferase on its cell wall, which allows the bacteria to produce polysaccharides from sucrose. These sticky polysaccharides are responsible for the bacteria's ability to aggregate with one another and adhere to tooth enamel, i.e. to form biofilms. Use of Anti Cell-Associated Glucosyltransferase (Anti-CA-gtf) Immunoglobulin Y disrupts S. mutans' ability to adhere to the teeth enamel, thus preventing it from reproducing. Studies have shown that Anti-CA-gtf IgY is able to effectively and specifically suppress S. mutans in the oral cavity. Other common preventative measures center on reducing sugar intake. One way this is done is with sugar replacements such as xylitol or erythritol which cannot be metabolized into sugars which normally enhance S. mutans growth. The molecule xylitol, a 5 carbon sugar, disrupts the energy production of S.mutans by forming a toxic intermediate during glycolysis. Various other natural remedies have been suggested or studied to a degree, including deglycyrrhizinated licorice root extract, tea tree oil, macelignan (found in nutmeg), curcuminoids (the main components of turmeric), and eugenol (found in bay leaves, cinnamon leaves and cloves). Additionally various teas have been tested for activity against S. mutans and other dental benefits. Recently, small molecule inhibitors selectively inhibit or disperse S. mutans biofilms have been identified and developed. Additionally, structure-based drug designs have identified selective inhibitors targeting S. mutans glucosyltransferases. These lead compounds are efficacious in preclinical animal models. However, none of these remedies have been subject to clinical trials or are recommended by mainstream dental health groups to treat S. mutans. The addition of bioactive glass beads to dental composites reduces penetration of S. mutans into the marginal gaps between tooth and composite. They have antimicrobial properties, reducing bacterial penetration. Several different phages have been found that infect S. mutans, including SMHBZ8. ==Survival under stressful conditions==

Conditions in the oral cavity are diverse and complex, frequently changing from one extreme to another. Thus, to survive in the oral cavity, S. mutans must tolerate rapidly harsh environmental fluctuations and exposure to various antimicrobial agents to survive. Transformation is a bacterial adaptation involving the transfer of DNA from one bacterium to another through the surrounding medium. Transformation is a primitive form of sexual reproduction. For a bacterium to bind, take up, and recombine exogenous DNA into its chromosome, it must enter a special physiological state termed "competence". In S. mutans, a peptide pheromone quorum-sensing signaling system controls genetic competence. This system functions optimally when the S. mutans cells are in crowded biofilms. S. mutans cells growing in a biofilm are transformed at a rate 10- to 600-fold higher than single cells growing under uncrowded conditions (planktonic cells). Knowing about quorum-sensing gives rise to the potential development of drugs and therapies. Quorum-sensing peptides can be manipulated to cause target suicide. Furthermore, quenching quorum-sensing can lead to prevention of antibiotic resistance. ==Evolution==

Three key traits have evolved in S. mutans and increased its virulence by enhancing its adaptability to the oral cavity: increased organic acid production, the capacity to form biofilms on the hard surfaces of teeth, and the ability to survive and thrive in a low pH environment. During its evolution, S. mutans acquired the ability to increase the amount of carbohydrates it could metabolize, and consequently more organic acid was produced as a byproduct. This is significant in the formation of dental caries because increased acidity in the oral cavity amplifies the rate of demineralization of the tooth, which leads to carious lesions. It is thought that the trait evolved in S. mutans via lateral gene transfer with another bacterial species present in the oral cavity. There are several genes, SMU.438 and SMU.1561, involved in carbohydrate metabolism that are up-regulated in S. mutans. These genes possibly originated from Lactococcus lactis and S. gallolyticus, respectively. The third trait that evolved in S. mutans is its ability to not only survive, but also thrive in acidic conditions. This trait gives S. mutans a selective advantage over other members of the oral microbiota. As a result, S. mutans could outcompete other species, and occupy additional regions of the mouth, such as advanced dental plaques, which can be as acidic as pH 4.0. == See also ==