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Literature DB >> 29502847

Mechanisms of astringency: Structural alteration of the oral mucosal pellicle by dietary tannins and protective effect of bPRPs.

Sarah Ployon¹, Martine Morzel², Christine Belloir³, Aline Bonnotte⁴, Eric Bourillot⁵, Loïc Briand⁶, Eric Lesniewska⁷, Jeannine Lherminier⁸, Ece Aybeke⁹, Francis Canon¹⁰.

Abstract

The interaction of tannins with salivary proteins is involved in astringency. This paper focussed on saliva lining oral mucosae, the mucosal pellicle. Using a cell-based model, the impact of two dietary tannins (EgC and EgCG) on the mucosal pellicle structure and properties was investigated by microscopic techniques. The role of basic Proline-Rich-Proteins (bPRPs) in protecting the mucosal pellicle was also evaluated. At low (0.05 mM) tannin concentration, below the sensory detection threshold, the distribution of salivary mucins MUC5B on cells remained unaffected. At 0.5 and 1 mM, MUC5B-tannin aggregates were observed and their size increased with tannin concentration and with galloylation. In addition, 3 mM EgCG resulted in higher friction forces measured by AFM. In presence of bPRPs, the size distribution of aggregates was greatly modified and tended to resemble that of the "no tannin" condition, highlighting that bPRPs have a protective effect against the structural alteration induced by dietary tannins.

Entities: Chemical Gene

Keywords: Astringency; Atomic Force Microscopy; EgCG; IB5; Salivary mucins MUC5B; Scanning Electron Microscopy; TR146/MUC1 cells

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Substances：

Year: 2018 PMID： 29502847 DOI： 10.1016/j.foodchem.2018.01.141

Source DB: PubMed Journal: Food Chem ISSN： 0308-8146 Impact factor: 7.514

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