Calcium movement in vivo and in vitro in secretory-stage enamel of rat incisors

Calcium transport across the dental enamel epithelium

Dental enamel is the most highly calcified tissue in mammals, and its formation is an issue of fundamental biomedical importance. The enamel-forming cells must somehow supply calcium in bulk yet avoid the cytotoxic effects of excess calcium. Disrupted calcium transport could contribute to a variety of developmental defects in enamel, and the underlying cellular machinery is a potential target for drugs to improve enamel quality. The mechanisms used to transport calcium remain unclear despite much progress in our understanding of enamel formation. Here, current knowledge of how enamel cells handle calcium is reviewed in the context of findings from other epithelial calcium-transport systems. In the past, most attention has focused on approaches to boost the poor diffusion of calcium in cytosol. Recent biochemical findings led to an alternative proposal that calcium is routed through high-capacity stores associated with the endoplasmic reticulum. Research areas needing further attention and a working model are also discussed. Calcium-handling mechanisms in enamel cells are more generally relevant to the understanding of epithelial calcium transport, biomineralization, and calcium toxicity avoidance.

Time-related changes of developing enamel crystals after exposure to the tissue fluid in vivo: analysis of a subcutaneously implanted rat incisor

To investigate the effects of tissue fluid on the growth of enamel crystals, upper and lower incisors extracted from 3-week-old Wistar rats were removed of the enamel organ, implanted subcutaneously in the dorsal portion of animals from the same litter, and harvested at 72 h or 1 week after implantation. The grafts were chemically fixed with surrounding tissues and prepared for light and electron microscopy, X-ray microanalysis, or for the immunohistochemistry of amelogenin. Mineralization of implanted enamel layers was examined by contact X-ray microradiography. The immunoreactivities for 25 kD amelogenin in immature enamel decreased sequentially, starting from the surface to the deeper layers; by 1 week after implantation, no positive reactivities remained in the entire enamel layers at the stages of matrix formation and early maturation. In accordance with the loss of enamel proteins, immature enamel gained mineral density until it attained higher radio opacity than that of the adjacent dentin by 1 week. In contrast, the radio opacity of the full thickness of the enamel at early maturation remained low except for a superficial thin layer. Electron microscopy revealed no sign of growth of original enamel crystals, but showed heavy precipitation of electron-dense fine granules of calcium phosphate in all layers of the secretory enamel and the superficial layer of enamel at early maturation, which showed high radio opacity. The Ca/P ratio and electron diffraction patterns of the granular materials precipitated between intrinsic enamel crystals indicated the property of hydroxy apatite or octacalcium phosphate though a characteristic ribbon-like profile of enamel crystals was lacking. These data indicate that the enamel organ blocks exogenous mineral precipitates in growing enamel during the stage of matrix formation and plays an essential regulatory role for fine enamel crystallites to grow into large hexagonal crystals.

Mitochondrial ATP synthase F1-beta-subunit is a calcium-binding protein

Mitochondrial ATP synthase is responsive to changes in cytosolic calcium concentration, but the regulatory mechanisms are unclear. Here we identified a major 52 kDa calcium-binding protein in rat enamel cells as the mitochondrial ATP synthase F1-beta-subunit. The F1-beta-subunit behaved as a low affinity and moderate capacity calcium-binding protein during comparative 45Ca overlay analyses. Equivalent behavior was shown by the F1-beta-subunit from rat liver mitochondria, but not by the homologous F1-alpha-subunit, supporting the specificity of calcium binding. Evidence that the catalytic F1-beta-subunit binds calcium specifically introduces new mechanistic possibilities for regulating ATP synthase, and thereby coordinating ATP production with demand for ATP-fuelled calcium pump activity.

Abundant calcium homeostasis machinery in rat dental enamel cells. Up-regulation of calcium store proteins during enamel mineralization implicates the endoplasmic reticulum in calcium transcytosis

Enamel cells handle large amounts of calcium, particularly during the developmental phase (termed maturation) when dental enamel is hypermineralized. The extent of intracellular calcium burden, and the nature of calcium homeostasis machinery used to accommodate it, are largely unknown. Here, the calcium-binding capacity of enamel cell cytosol was found to increase during development, in parallel with the putative transcellular flux of calcium. At maturation, the abundance of calcium-binding proteins in enamel cells exceeded that in brain and other established calcium-oriented tissues, which implies a large calcium burden. A search for likely cytosolic calcium transporters revealed only one high-affinity calcium-binding protein (12 kDa, distinguished from alpha-parvalbumin) that was up-regulated during maturation, but its low abundance (0.02% of soluble protein) precluded a major calcium transport or cytoprotective role. Two low-affinity calcium-binding proteins up-regulated during maturation (by 1.8-fold and 2.1-fold respectively) were identified as calreticulin and endoplasmin, both residents of the endoplasmic reticulum. Together, calreticulin and endoplasmin constituted an exceptionally high proportion (5%) of soluble protein during maturation, which gives an inferred calcium capacity 67-fold higher than that of the principal cytosolic calcium-binding protein. 28-kDa calbindin. Evidence that endoplasmin expression varied inversely with serum calcium concentration, and that the inositol trisphosphate receptor also was highly expressed during maturation, supported the novel hypothesis that non-mitochondrial calcium stores play a major role in transcellular calcium transport.

IN CONCLUSION

(a) enamel cells contain a general high abundance of calcium homeostasis proteins, consistent with a heavy intracellular calcium burden; (b) the expression pattern (phenotype) of calcium-binding proteins varies with enamel cell function; (c) enamel cells appear to contain unusually large non-mitochondrial calcium stores; (d) contrary to the prevailing view that calcium passes mainly through the cytosol of calcium-transporting cells, the findings imply a route through the endoplasmic reticulum. This study gives novel information about how a highly calcium-oriented tissue avoids calcium toxicity, and provides a new focus for investigations into the mechanisms of transcellular calcium transport.

Expression of amelogenin mRNA sequences during development of rat molars

The expression of amelogenin mRNA in growing rat molars was studied. Northern blotting and the analysis of cDNA isolates revealed two predoninant variants. One group of cDNA inserts contained sequences of a long mRNA version and the other group contained mRNA sequences of the shorter leucin-rich amelogenin polypeptide (LRAP). The LRAP group was deficient in an internal stretch which coded for a peptide with a high potential for beta turns. Northern blot experiments showed that most amelogenin RNA in rat teeth was represented by two bands of 1.1 and 0.8 kb. Two oligonucleotide probes were designed that were specific for the long version and for the LRAP variant. The probes were used for in situ hybridization experiments on sections of developing maxillar teeth of rats between day 2 and day 15 after birth. Both RNA species were accumulated concomitantly and exclusively in cells of the inner enamel epithelium. Expression was first observed at the mesial cusp sides and finally involved the whole ameloblast layer except for the cells adjacent to the enamel-free region at the tip of the cusps. The early amelogenin RNA expression occurred adjacent to the initial deposition of the dentin matrix. Low amounts of amelogenin RNA persisted after the differentiation of ameloblasts into the maturative stage. The sequence of events was similar in all three molars.

Calbindin28kDa and calmodulin are hyperabundant in rat dental enamel cells. Identification of the protein phosphatase calcineurin as a principal calmodulin target and of a secretion-related role for calbindin28kDa

Enamel cells are likely to experience heavy demands for intracellular calcium homeostasis during the secretion and hypermineralization of dental enamel. Here, the two major high-affinity calcium-binding proteins in rat enamel epithelium were identified as calbindin28kDa and calmodulin, using a microscale approach. Both proteins were hyperabundant, totalling up to 2% of the soluble protein and surpassing the amounts in cerebellum, the benchmark tissue. Calbindin28kDa and calmodulin accounted for 26% of the total calcium-binding capacity in enamel cell cytosol, under near physiological conditions. Numerous calmodulin-binding proteins were detected with an overlay assay, indicating that calmodulin has multiple major targets in enamel cells. The calcium/calmodulin-regulated protein phosphatase, calcineurin, was identified as a principal calmodulin target constituting 0.1% of the soluble protein. Calmodulin and calcineurin were expressed constitutively, implying continued heavy usage of calcium/calmodulin-based and phosphorylation-based signalling events throughout enamel cell development. Calbindin28kDa, in contrast, was expressed at fourfold higher levels in secretion-phase cells than during the calcium-intensive hypermineralization phase, unexpectedly pointing to an important role associated with secretion. Supporting this notion, immunoblots revealed that 33% of total (SDS-soluble) calbindin28kDa was in the particulate fraction and predominantly associated with the Triton-insoluble cytoskeleton. Solubilisation of cytoskeletal calbindin28kDa required high concentrations of NaCl or urea, indicating the existence of a high-affinity target ligand. The unusual abundance of calmodulin, calbindin28kDa and calcineurin demonstrated here provides the first molecular evidence that enamal cells possess a strong capability for intracellular calcium homeostasis. Since none of these proteins was up-regulated during enamel hypermineralization, it appears that other calcium-binding proteins are primarily involved in the putative transcellular passage of calcium.

Problems associated with estimation of net calcium uptake during enamel formation using 45Ca

45Ca uptake in mineralizing tissues may occur by net Ca uptake or by isotopic exchange. It is rarely possible to differentiate between these effects, making interpretation of the findings difficult. Unfortunately, this problem is not often considered, and 45Ca uptake is usually regarded as representative of only net calcium uptake. The study reported here was undertaken to estimate the extent to which 45Ca uptake in mineralizing enamel is due to net Ca deposition or to isotopic exchange, and to consider the implications. The enamel surfaces of the lower incisors of adult rats were notched at the gingival line, and the eruption distance over 16 hours was measured. This distance was used to establish the position of a 0.3-mm-wide increment of enamel at the beginning and end of the 16-hour period, during which it passed through the early-maturation stage of enamel formation. The rate of Ca uptake was determined by chemical assay. Other rats were injected with 45Ca, mean plasma specific activity values for the experimental period determined, and the rate of Ca uptake through the same area of enamel formation was estimated. The estimates were from two- to nearly ten-fold greater than those established by chemical assay, indicating that from 50 to 90% of the 45Ca uptake occurred by isotopic exchange. 45Ca uptake may indicate more about the labile state of Ca in mineralizing enamel than about the rate of mineral deposition.

Enamel mineralization and the role of ameloblasts in calcium transport

Amelogenesis is a dynamic and unique process of cell-matrix interactions in that matrix synthesis, degradation and resorption all proceed simultaneously, coupled with mineral depositions in a compartment between ameloblasts and dentin or dental papilla. Accumulation of data suggest the role of ameloblasts in tooth morphogenesis and matrix formation, but no fully acceptable explanation has been given concerning the role of ameloblasts in calcium transport. In this article, old and new points of issue raised regarding the role of ameloblasts in calcium acquisition are reviewed and possible mechanisms whereby the ameloblasts prevent the rise of cytosolic calcium while actively or less actively transporting calcium are elaborated upon based on recent findings.