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For now, brushing beats biopharma
in caries prevention
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Back in the late 90s, I was involved in the licensing of an early-stage peptide drug aimed at preventing tooth decay by blocking the anchoring of the acid-producing (and enamel destroying) bacterium, Streptococcus mutans. As is not unusual in small biopharma, development was never progressed, but I’ve remained interested in the concept of caries prevention through pharmaceutical intervention.
Tooth decay is an infectious disease, the principal villains being S.mutans, S.sobrinus and other acid-producing/acid-loving bad actors which outstrip other bacteria present on the tooth surface and modify the local environment to their advantage. S.mutans breaks down the sugars found in our diet and the resulting acid initiates and continues the destructon of enamel and dentine, an essential tooth mineral. Caries risk is influenced by a variety of factors, the most obvious being sugar consumption and oral hygiene habits, although the recent identification of highly virulent S.mutans strains by Swedish researchers associated with mutations in saliva proteins indicates that genetics may play a part.
As a bacterial disease, it’s not surprising that vaccination has been pursued as a possible means of caries prevention. Saliva contains secretory IgA (sIgA), a class of antibody evolved for the protection of mucosal surfaces and oral protection is theoretically possible providing effective levels of specific sIgA can be generated. Vaccination is also a low-cost and practical means of protecting large populations from an early age.
Since the 70s, a multitude of potential vaccine targets expressed by both S.mutans and S.sobrinus have been identified and evaluated in a variety of formulations and different delivery routes (systemic, oral, intranasal), largely in animal models and a small number of volunteers studies. Despite more recently applied technical sophistication (including DNA vaccines and synthetic proteins combining several bacterial targets), development has never moved out of the transitional phase and the challenge of eliciting an effective, long-lasting antibody response remains.
Almost as old a concept is “passive” immunisation- the use of bacteria-specific antibodies delivered in a mouth rinse or gel to sequester unwanted acid-producers. While the concept has been established in animal models and a few clinical studies, formulations based on mouse, bovine, chicken and even plant-grown antibodies have remained as curiosities.
A recent approach combines advances in antibody generation to probe for targets actually present on living S.mutans and S.sobrinus and evolve corresponding antibody fragments which retain their specific binding properties. Fragments can be produced cheaply at large scale, and while successful in reducing caries in an animal model, formulation to give effective protection without frequent reapplication poses a formidable problem.
A variety of both natural and synthetic peptides with antimicrobial action have been evaluated as a means of ablating S.mutans and other acid-producers, although with mixed results. Clinical trials of a “specifically targeted antimicrobial peptide”- STAMP, designated C1652 and sponsored by a small US biotech company, C3J Therapeutics, are underway. C1652 was designed to act only on S.mutans to avoid unwanted effects on the oral microbiome.
Interestingly, C1652 treatment appears to prevent S.mutans recolonization after treatment, although it’s too early to tell whether this useful property will be observed in human studies. A collaboration between Johnson & Johnson, a pharmaceutical and consumer healthcare giant, and the University of Pennsylvania School of Dental Medicine is looking at the feasibility of low-cost antimicrobial peptide production in plants.
Effective immunological or antimicrobial-based protection against decay probably remains decades away, but drug-based means of repairing the damage might be on the horizon. Researchers at the Dental Institute, Kings College London have shown that, tideglusib, a drug originally investigated as a potential Alzheimer’s disease treatment, acts upon stem cells present in dental pulp to stimulate dentine production. This process does occur naturally, but at a level too low to result in a robust repair.
Tideglusib inhibits an enzyme, glycogen synthase kinase 3 (GSK-3), yhat normally serves as a brake on dentine production. When drug-loaded protein sponges were place in cavities formed in mouse teeth, sufficient dentine was produced to repair the tooth within six weeks. Optimised GSK-3 inhibitors could proof to be even more effective restoratives.
In the meantime, the toothbrush, dentist and the fluoridation of drinking water remain our best defence against the ravages of S.mutans and its companions.
Photo credit: Thegreenj, Wikipedia Creative Commons
Streptococcus mutans adhesin biotypes that match and predict individual caries development. Anders, E et al. EBioMedicine, 2017; DOI: 10.1016/j.ebiom.2017.09.027 http://tinyurl.com/ydbx2aa5 (Open Access).
Synthetic antigen-binding fragments (Fabs) against S. mutans and S. sobrinus inhibit caries formation. Kalam, MK et al. doi.org/10.1038/s41598-018-28240-0 (2018). http://tinyurl.com/y7368pdl (Open Access).
Promotion of natural tooth repair by small molecule GSK3 antagonists. Sci. Rep. 7, 39654; Neves, VCM. et al.doi: 10.1038/srep39654 (2017). http://tinyurl.com/yd2p8pp5 (Open Access).
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