Ultrastructure of Early Amelogenesis in Wild-type, , and Mice: Enamel Ribbon Initiation on Dentin Mineral and Ribbon Orientation by Ameloblasts

Overview

Journal Mol Genet Genomic Med

Specialty Genetics

Date 2016 Nov 30

PMID 27896288

Citations 28

Authors

Charles E Smith

Yuanyuan Hu

Jan C-C Hu

James P Simmer

Affiliations

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Abstract

Introduction: Dental enamel is comprised of highly organized, oriented apatite crystals, but how they form is unclear.

Methods: We used focused ion beam (FIB) scanning electron microscopy (SEM) to investigate early enamel formation in 7-week-old incisors from wild-type, , and C56BL/6 mice. FIB surface imaging scans thicker samples so that the thin enamel ribbons do not pass as readily out of the plane of section, and generates serial images by a mill and view approach for computerized tomography.

Results: We demonstrate that wild-type enamel ribbons initiate on dentin mineral on the sides and tips of mineralized collagen fibers, and extend in clusters from dentin to the ameloblast membrane. The clustering suggested that groups of enamel ribbons were initiated and then extended by finger-like membrane processes as they retracted back into the ameloblast distal membrane. These findings support the conclusions that no organic nucleator is necessary for enamel ribbon initiation (although no ribbons form in the mice), and that enamel ribbons elongate along the ameloblast membrane and orient in the direction of its retrograde movement. Tomographic reconstruction videos revealed a complex of ameloblast membrane processes and invaginations associated with intercellular junctions proximal to the mineralization front and also highlighted interproximal extracellular enamel matrix accumulations proximal to the interrod growth sites, which we propose are important for expanding the interrod matrix and extending interrod enamel ribbons. mice produce oriented enamel ribbons, but the ribbons fuse into fan-like structures. The matrix does not expand sufficiently to support formation of the Tomes process or establish rod and interrod organization.

Conclusion: Amelogenin does not directly nucleate, shape, or orient enamel ribbons, but separates and supports the enamel ribbons, and expands the enamel matrix to accommodate continued ribbon elongation, retrograde ameloblast movement, and rod/interrod organization.

Citing Articles

Mutations Can Cause Hypomaturation Amelogenesis Imperfecta.

Wang Y, Lin H, Liang T, Lin J, Simmer J, Hu J J Dent Res. 2024; 103(6):662-671.

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Dentin defects caused by a Dspp frameshift mutation are associated with the activation of autophagy.

Liang T, Smith C, Hu Y, Zhang H, Zhang C, Xu Q Sci Rep. 2023; 13(1):6393.

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Ganoin and acrodin formation on scales and teeth in spotted gar: A vital role of enamelin in the unique process of enamel mineralization.

Kawasaki K, Sasagawa I, Mikami M, Nakatomi M, Ishiyama M J Exp Zool B Mol Dev Evol. 2022; 340(7):455-468.

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Enamel defects in Acp4 mice and human ACP4 mutations.

Liang T, Wang S, Smith C, Zhang H, Hu Y, Seymen F Sci Rep. 2022; 12(1):16477.

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