MicroRNA-155-3p Mediates TNF-α-Inhibited Cementoblast Differentiation

Abstract

Periodontitis is a prevalent and chronic inflammatory disease that is interrelated with systemic health. Periodontitis can be promoted by tumor necrosis factor α (TNF-α). Cementum, a vital part of the periodontium, is a bone-like mineralized tissue that is produced by cementoblasts. Our laboratory previously revealed that TNF-α inhibits cementoblast differentiation and mineralization. However, how TNF-α modulates cementoblast differentiation and mineralization remains largely unknown. MicroRNA-155 (miR-155) is induced and regulates TNF-α-inhibited osteogenic differentiation. In this study, we found that miR-155-3p was increased during TNF-α-stimulated OCCM-30 cells and involved in cementoblast differentiation and mineralization. Overexpression of miR-155-3p suppressed cementoblast mineralization. Bioinformatics analysis revealed that potassium channel tetramerization domain containing 1 (Kctd1) is a candidate target gene of miR-155-3p. Moreover, miR-155-3p overexpression suppressed KCTD1 levels. Meanwhile, its knockdown increased KCTD1 expression. Transfection with miR-155-3p also inhibited the luciferase activity of 3′-untranslated regions in the Kctd1 wild type but not the mutant. These data indicated that Kctd1 is a direct and novel target of miR-155-3p. The Wnt signaling pathway inhibits cementoblast differentiation, and we further demonstrated that miR-155-3p partially modulates cementoblast differentiation through the canonical Wnt signaling pathway. In addition to the gain/loss function assay of miR-155-3p, the luciferase activity assay of canonical Wnt signaling was performed. The assays revealed that miR-155-3p increased β-catenin-mediated transcriptional activation. Overall, our data clarified that miR-155-3p mediated TNF-α-inhibited cementoblast differentiation by targeting Kctd1, at least partially through canonical Wnt signaling pathway. These findings reveal the expanded function of miRNAs in cementoblast differentiation and mineralization.