Clinical effects of stannous fluoride dentifrice in reducing plaque microbial virulence III: Lipopolysaccharide and TLR2 reporter cell gene activation.

PURPOSE: This study expanded the analysis of subgingival dental plaques from previous research to include the evaluation of cohort, site and treatment effects on chemically measured endotoxin and activation of Toll-like receptor (TLR) based gene expression in two additional reporter cell lines: a TLR2 specific cell line and a THP-1 (multi TLR reporter) cell line. METHODS: Participants from high and low bleeding cohorts were sampled at baseline for both supra and subgingival dental plaque at both healthy as well as clinically diseased sites and then provided with intervention hygiene products including a stabilized SnF2 dentifrice and a new soft bristle manual toothbrush. Following 2 and 4 weeks of assigned dentifrice use, participants returned for a re-evaluation of gingival inflammation and bleeding and repeat samplings of dental plaque. Subgingival sampled plaques were chemically analyzed for endotoxin concentration using a Thermo Scientific Pierce LAL chromogenic endotoxin quantitation kit. Samples were also used for inoculation of two reporter cell assays (an HEK293 TLR2 reporter cell line and a THP-1 monocyte cell line). Reporter cell activation was analyzed via luminescence changes of secreted embryonic alkaline phosphatase. RESULTS: The endotoxin content of subgingival plaque could be measured directly with dye assays and plaque isolates activated gene expression in both TLR reporter cell lines. Higher disease cohorts and sites with gingival inflammation generally showed more endotoxins and higher levels of plaque virulence as compared to low disease cohorts or plaque sampled from clinically healthy sites. SnF2 dentifrice treatment was associated with broad scale reductions in endotoxin content and virulence potentiation properties of dental plaque samples collected subgingivally from patients. CLINICAL SIGNIFICANCE: These results collectively support the use of dye or various reporter cell lines in the characterization of plaque virulence in diseased populations and as a potential route for analysis in clinical evaluations of treatment interventions. Subgingival plaque 'detoxification' including effects on microbial pathogenicity as well as metabolic activity may be considered important mechanisms contributing to clinical benefits of SnF2 dentifrice.

Clinical Effects of Stabilized Stannous Fluoride Dentifrice in Reducing Plaque Microbial Virulence I: Microbiological and Receptor Cell Findings.

OBJECTIVES: Lipopolysaccharides (LPSs) and lipoteichoic acids (LTAs), or bacterial endotoxins, bind with Toll-like receptors (TLRs) that are expressed on host cells of the periodontium, thereby contributing to the periodontal pathogenicity of oral bacteria. Stannous fluoride (SnF2), an antibacterial fluoride that treats and controls gingivitis, has been shown to react with lipophilic domains/anionic charges in LPS and LTA. The effects of bacterial species and dental plaque on toll receptors can be studied using genetically engineered cell lines containing linked toll receptors on their surfaces. This randomized, examiner-blinded study examined the clinical effects of stabilized SnF2 dentifrice intervention on gingivitis and dental plaque virulence in populations exhibiting high and low levels of clinical gingivitis. METHODS: Recruited populations were evaluated for gingival inflammation (MGI) and gingival bleeding (GBI) at baseline and assigned into two cohorts of 20 each, those with high (GBI > 20 sites) and low (GBI < 3 sites) levels of observed bleeding/gingivitis. Participants were sampled at baseline for both supra- and subgingival dental plaque at both healthy (no bleeding, PD = 2 mm), as well as clinically diseased sites (bleeding, PD = 3-4 mm), and then provided with an intervention hygiene product including a stabilized SnF2 dentifrice and a new soft bristle manual toothbrush. Following two and four weeks of assigned dentifrice use, participants returned for a re-evaluation of gingival inflammation and bleeding and repeat samplings of dental plaque. Plaque samples were analyzed by anaerobic culturing of gram negative anaerobes (GNA), as well as by incubation of subgingival sampled plaques with TLR4 transfected HEK293 cells, where gene expression was assessed by measurement of a SEAP alkaline phosphatase reporter as a marker of toll receptor activation. RESULTS: Clinical assessments showed statistically significant reductions in MGI (24-26%) and GBI (42-53%) gingivitis in both diseased and healthy cohorts following four weeks of dentifrice intervention. For all clinical examinations, MGI and bleeding sites were statistically significantly different (lower) in the low bleeding versus the higher bleeding cohort. Supragingival and subgingival GNAs were significantly reduced (p < 0.05) in both high and low disease cohorts at bleeding and healthy sites following four weeks of stabilized SnF2 dentifrice use. TLR activation from subgingival sampled plaque was reduced following four weeks of stabilized SnF2 dentifrice use in both high and low disease cohorts and in both healthy, as well as diseased sites. CONCLUSIONS: Collectively, these results support the potential for stabilized SnF2 dentifrice to provide clinical gingivitis benefits via mechanisms beyond control of plaque mass, potentially directly decreasing the pathogenicity of plaque biofilms by blocking reactivity of LPS and LTA ligands with tissue receptors associated with inflammation. Importantly, benefits could be seen in both diseased sites, as well as sites not yet exhibiting symptoms of inflammation, supporting the activity of SnF2 not just in treating diseased sites, but in preventing disease development. These learnings may influence treatment planning for patients susceptible to gingivitis.

Quantitation of endotoxin and lipoteichoic acid virulence using toll receptor reporter gene.

PURPOSE: To apply quantitative Toll-like receptors (TLR) cell assays to compare lipopolysaccharides (LPSs) and lipoteichoic acids (LTAs) from different oral bacterial strains for potential pathogenicity in vitro. METHODS: The potency of LPS and LTA from different bacteria on activation of TLR reporter genes in HEK-tlr cell lines was examined. P. gingivalis LPS mix, P. gingivalis 1690 LPS, P. gingivalis 1435/50 LPS, E. coli LPS (E. coli K12), B. subtilis LTA, S. aureus LTA, E. hirae LTA and S. pyogenes LTA were examined in both TLR2 and TLR4 HEK cell line reporter assays. Solutions of LPS and LTA from selected bacteria were applied in a dose response fashion to the TLR reporter cells under standard culture conditions for mammalian cells. Reporter gene secreted-embryonic-alkaline-phosphatase (SEAP) was measured, and half maximal effective concentration (EC50) was determined for each sample. Concentration dependent TLR activation was compared to similar responses to LPS and LTA for commercial BODIPY-TR-Cadaverine and LAL biochemical (non cell based) assays. RESULTS: All LPS from P. gingivalis activated both TLR2 and TLR4 responses. E. coli LPS is a strong activator for TLR4 but not for TLR2 responses. In contrast, both B. subtilis and S. aureus LTA provoked responses only in TLR2, but not in the TLR4 assay. Interestingly, E. hirae LTA and S. pyogenes LTA did not stimulate strong TLR2 responses. Instead, both E. hirae LTA and S. pyogenes LTA mounted a reasonable response in TLR4 reporter gene assay. Both LPS and LTA showed deactivation of fluorescence in BODIPY-TR-Cadaverine while only LPS was active in LAL. As with biochemical assays, an EC50 could be determined for LPS and LTA from various bacterial strains. The EC50 is defined as a concentration of LPS or LTA that provokes a response halfway between the baseline and maximum responses. Lower EC50 means higher potency in promoting TLR responses, and in principle indicates greater toxicity to the host. CLINICAL SIGNIFICANCE: InvivoGen TLR2 and TLR4 assays distinguish specific types of microbial products, such as LPS and LTA from different bacteria. Application of EC50 determinations creates a means for quantitative and comparisons of LPS and LTA virulence in a cellular-based assay and combinations of TLR reporter cell assays along with biochemical evaluation of LPS#47;LTA in BODIPY-TR-Cadaverine and LPS in LAL assays provides a means to quantitate virulence of plaque samples with respect to both LPS and LTA. These learnings have long-term implications for patient care in that understanding the virulence of patients' plaque provides important information to assess risk of oral diseases.

Lipopolysaccharide and lipoteichoic acid binding by antimicrobials used in oral care formulations.

PURPOSE: To study the reactivity of lipopolysaccharide (LPS) and lipoteichoic acid (LTA) with the cationically charged agents cetylpyridinium chloride, stannous fluoride, and the non-cationic agent triclosan. We also assessed the effect of these agents to inhibit LPS and LTA binding to cellular Toll-like Receptors (TLRs) in vitro. METHODS: The ability of these antimicrobials to bind with LPS and/or LTA was assessed in both the Limulus amebocyte lysate and BODIPY-TR-cadaverine dye assays. Mass spectroscopy was then used to confirm that stannous fluoride directly binds with LPS and to determine stoichiometry. Lastly, we looked for possible inhibitory effects of these antimicrobial agents on the ability of fluorescently conjugated LPS to bind to TLR4 expressed on HEK 293 cells. RESULTS: Cetylpyridinium chloride (CPC) and stannous salts including stannous fluoride interfered with LPS and LTA reactivity in both dye assays, while triclosan had no effect. Mass spectroscopy revealed direct binding of stannous fluoride with E. Coli LPS at 1:1 stoichiometric ratios. In the cellular assay, cetylpyridinium chloride and stannous fluoride, but not triclosan, inhibited LPS binding to TLR4. CLINICAL SIGNIFICANCE: These results support a potential mechanism of action for stannous fluoride and CPC formulated in oral products in which these ingredients bind bacterial toxins and potentially render them less toxic to the host. These results may influence home care recommendations for patients at risk for plaque-related diseases.

Lipopolysaccharide and Lipoteichoic Acid Virulence Deactivation by Stannous Fluoride.

OBJECTIVES: Oral bacterial pathogens promote gingivitis and periodontal disease. Bacterial endotoxins, also known as lipopolysaccharides (LPSs) and lipoteichoic acids (LTAs), are known to enhance bacterial pathogenicity through binding with Toll-like receptors (TLRs), a group of pattern recognition receptors critical to the activation of innate immunity, that are expressed on host cells. Both LPS and LTA contain lipophilic domains and anionic charges that may be susceptible to reactivity with stannous fluoride, a commonly used ingredient clinically proven for the treatment and prevention of gingivitis. This study examined the effects of stannous fluoride on Toll-like receptor activation in response to bacterially derived LPS and LTA in select cell lines and secretion of inflammatory cytokines from human primary peripheral monocytes likewise exposed to LPS. METHODS: TLR4 and TLR2 transfected HEK293 cells and THP1-Dual™ cells were exposed to bacterial LPS and LTA in the presence of increasing concentrations of stannous fluoride. Gene expression was assessed by measurement of secreted embryonic alkaline phosphatase (SEAP) reporter gene for HEK293 cells and SEAP and luciferase for THP-1 cells. Cell viability was confirmed using PrestoBlue. Human primary monocytes were treated with LPS with various concentrations of supplemented stannous fluoride, and cytokine expression was directly measured. RESULTS: Stannous fluoride inhibited gene expression response of TLR4 and TLR2 in HEK293 cells and THP1-Dual™ cells in a dose response fashion, producing complete inhibition at micromolar concentrations. The addition of stannous fluoride suppressed production of TNF-a, IFN-g, IL12p70, IL10, IL-1b, IL2, and IL-6, and also increased secretion of Il-8 in dose response fashion. Viability assays confirmed no effects of LPS or stannous fluoride on viability of HEK293, THP-1, and primary human monocytes. CONCLUSIONS: These results support the potential for stannous fluoride to provide clinical gingivitis benefits by directly decreasing the pathogenicity of plaque biofilms by blocking reactivity of LPS and LTA ligands with tissue receptors associated with inflammation. These learnings may influence recommendations for patients at risk for plaque-related diseases.

Protection of hair from damage induced by ultraviolet irradiation using tea (Camellia sinensis) extracts.

BACKGROUND: Damage to hair by UV is relevant to most people, and for many, it is a major source of hair damage. Prevention of UV damage is of high interest to cosmetic companies. OBJECTIVES: Describe UV damage mechanisms and link these mechanisms to measurable changes in hair protein composition and color changes resulting from breakdown of yellow-colored kynurenines. Test the power of botanical antioxidants, specifically Camellia sinensis (tea) extracts to prevent this protein damage and color change. Link specific phytochemistry of extract samples to hair performance. METHODS: Camellia sinensis (tea) extracts were analyzed by LC-MS to identify the key composition chemistries. ORAC (Oxygen Radical Antioxidant Capacity) was used to measure ability of the extract to react with a peroxyl radical via a hydrogen abstraction mechanism. Hair protein structural damage was measured by quantification of a biomarker peptide that is specific to UV-induced damage and hair color changes were measured with a spectrophotometer. RESULTS: Levels of key phytochemistry in the extracts, specifically the catechins, correlated with prevention of UV-induced protein damage and prevention of color changes due to kynurenine breakdown. Extracts with higher phytochemistry levels also had higher ORAC scores indicating that they were more effective antioxidants. CONCLUSIONS: Camellia sinensis (tea) extracts can be used as effective protective treatments for hair protection but this efficacy is linked to extract concentrations of key chemistries (catechins).