Store-operated Ca2+ entry controls ameloblast cell function and enamel development
Miriam Eckstein, Martin Vaeth, Cinzia Fornai, Manikandan Vinu, Timothy G. Bromage, Meerim K. Nurbaeva, Jessica L. Sorge, Paulo G. Coelho, Youssef Idaghdour, Stefan Feske, Rodrigo S. Lacruz
Miriam Eckstein, Martin Vaeth, Cinzia Fornai, Manikandan Vinu, Timothy G. Bromage, Meerim K. Nurbaeva, Jessica L. Sorge, Paulo G. Coelho, Youssef Idaghdour, Stefan Feske, Rodrigo S. Lacruz
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Research Article Bone biology Cell biology

Store-operated Ca2+ entry controls ameloblast cell function and enamel development

Abstract

Loss-of-function mutations in stromal interaction molecule 1 (STIM1) impair the activation of Ca2+ release–activated Ca2+ (CRAC) channels and store-operated Ca2+ entry (SOCE), resulting in a disease syndrome called CRAC channelopathy that is characterized by severe dental enamel defects. The cause of these enamel defects has remained unclear given a lack of animal models. We generated Stim1/2K14cre mice to delete STIM1 and its homolog STIM2 in enamel cells. These mice showed impaired SOCE in enamel cells. Enamel in Stim1/2K14cre mice was hypomineralized with decreased Ca content, mechanically weak, and thinner. The morphology of SOCE-deficient ameloblasts was altered, showing loss of the typical ruffled border, resulting in mislocalized mitochondria. Global gene expression analysis of SOCE-deficient ameloblasts revealed strong dysregulation of several pathways. ER stress genes associated with the unfolded protein response were increased in Stim1/2-deficient cells, whereas the expression of components of the glutathione system were decreased. Consistent with increased oxidative stress, we found increased ROS production, decreased mitochondrial function, and abnormal mitochondrial morphology in ameloblasts of Stim1/2K14cre mice. Collectively, these data show that loss of SOCE in enamel cells has substantial detrimental effects on gene expression, cell function, and the mineralization of dental enamel.

Authors

Miriam Eckstein, Martin Vaeth, Cinzia Fornai, Manikandan Vinu, Timothy G. Bromage, Meerim K. Nurbaeva, Jessica L. Sorge, Paulo G. Coelho, Youssef Idaghdour, Stefan Feske, Rodrigo S. Lacruz

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Figure 2

Stim1/2K14cre mice show abnormal enamel.

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Stim1/2K14cre mice show abnormal enamel. (A) Gross examination of the d...
(A) Gross examination of the dental phenotype shows abnormal (chalky-white) appearance on incisors of Stim1/2K14cre mice compared with WT littermates. These changes were characteristic of all Stim1/2K14cre mice analyzed in this study. (B) Micro–computerized tomography analysis shows loss of enamel tissue (color-coded red) in Stim1/2K14cre mice relative to WT littermates in incisors and molars. Dentine is widely exposed on the occlusal surface of all molars in Stim1/2K14cre mice. n = 3 mice per group. (C) Incisor linear enamel thickness measured in 3 different regions of interest. The region of interest is located below the first molar. Stim1/2K14cre mice show reduced linear enamel thickness in 2 of 3 three areas (areas 1 and 3) (see Supplemental Figure 1). Data represent mean ± SEM of n = 4 mice per group (*P < 0.05, **P < 0.005, 1-way ANOVA); however, only the differences in area 1 remains statistically significant after applying Bonferroni correction for multiple comparisons (P < 0.016 ). (D) Total enamel volume was also decreased in Stim1/2K14cre mice (mean ± SEM of n = 4 mice per group; *P < 0.05, 2-tailed unpaired Student’s t test). (E) Microhardness analysis showed significantly softer enamel in Stim1/2K14cre incisor enamel compared with controls. Test site is shown in Supplemental Figure 1A. Data represent mean ( ± SEM) of n = 6 mice per group (***P < 0.0001, 2-tailed unpaired Student’s t test).