RESUMEN
Streptococcus mutans is recognized as one of the key contributors to the dysbiotic state that results in dental caries. Existing treatment strategies reduce the incidence of tooth decay, but they also eliminate both the cariogenic and beneficial microbes. Here we introduce a novel treatment alternative using Sephadex, cross-linked dextranomer microspheres (DMs), typically used for gel filtration chromatography. In addition DM beads can be used for affinity purification of glucosyltransferases (GTFs) from S. mutans. In this study we take advantage of the native pathogenic mechanisms used by S. mutans to adhere, form a biofilm and induce dental caries through the expression of surface-associated GTFs. We demonstrate that planktonic and biofilm-grown (adhered to hydroxyapatite-coated pegs to mimic the tooth surface) S. mutans, specifically and competitively attach to DMs. Further investigation demonstrated that DMs are a specific affinity resin for S. mutans and other cariogenic/pathogenic oral streptococci, whereas other commensal and probiotic strains failed to readily adhere to DMs. Using antimicrobial cargo loaded into the DM lumen, we demonstrate that when in co-culture with non-binding to even modestly binding commensal species, S. mutans was selectively killed. This proof of concept study introduces a novel means to safely and effectively reduce the pool of S. mutans and other pathogenic streptococci in the oral cavity with limited disturbance of the necessary commensal (healthy) microbiota when compared with current oral healthcare products.
Asunto(s)
Caries Dental/microbiología , Dextranos/metabolismo , Microesferas , Streptococcus mutans/metabolismo , Biopelículas/crecimiento & desarrollo , Dextranos/farmacología , Glucosiltransferasas/metabolismo , Humanos , Microbiota , Boca/microbiología , Probióticos , Streptococcus/metabolismoRESUMEN
The 5' untranslated region (5' UTR) of an mRNA molecule embeds important determinants that modify its stability and translation efficiency. In Streptococcus pyogenes, a strict human pathogen, a gene encoding a secreted protease (speB) has a large 5' UTR with unknown functions. Here we describe that a partial deletion of the speB 5' UTR caused a general accumulation of mRNA in the stationary phase, and that the mRNA accumulation was due to retarded mRNA degradation. The phenotype was observed in several M serotypes harboring the partial deletion of the speB 5' UTR. The phenotype was triggered by the production of the truncated speB 5' UTR, but not by the disruption of the intact speB 5' UTR. RNase Y, a major endoribonuclease, was previously shown to play a central role in bulk mRNA turnover in stationary phase. However, in contrast to our expectations, we observed a weaker interaction between the truncated speB 5' UTR and RNase Y compared with the wild-type, which suggests that other unidentified RNA degrading components are required for the pleiotropic effects observed from the speB UTR truncation. Our study demonstrates how S. pyogenes uses distinct mRNA degradation schemes in exponential and stationary growth phases.
Asunto(s)
Regiones no Traducidas 5'/genética , Proteínas Bacterianas/genética , Exotoxinas/genética , Estabilidad del ARN , Streptococcus pyogenes/genética , Proteínas Bacterianas/química , Cisteína Endopeptidasas/metabolismo , Exotoxinas/química , Exotoxinas/metabolismo , Regulación Bacteriana de la Expresión Génica , Fenotipo , Procesamiento Postranscripcional del ARN , Eliminación de Secuencia , Streptococcus pyogenes/metabolismo , Streptococcus pyogenes/patogenicidadRESUMEN
Considerable interest has recently mounted regarding the biological roles of Gram-negative outer membrane vesicles (MVs). The first discovery of MVs was made over four decades ago, and it is now clear that most Gram-negative bacteria produce MVs, with Pseudomonas aeruginosa and Escherichia coli as the most extensively studied. Much of our knowledge of the biological roles of MVs and mechanism of MV formation is due to T.J. Beveridge and colleagues. Beveridge pioneered the field of MV research not only by enhancing our understanding of MV function, but also through the application of a wide variety of physical, chemical, and genetic techniques to complement his elegant electron microscopy investigations. Here we review the contributions of Beveridge's group to our understanding of MV biology.