Abstract
Calvarial thinning and skull bone defects have been reported in infants with hypervitaminosis A. These findings have also been described in humans, mice and zebrafish with loss-of-function mutations in the enzyme CYP26B1 that degrades retinoic acid (RA), the active metabolite of vitamin A, indicating that these effects are indeed caused by too high levels of vitamin A and that evolutionary conserved mechanisms are involved. To explore these mechanisms, we have fed young mice excessive doses of vitamin A for one week and then analyzed the skull bones using micro computed tomography, histomorphometry, histology and immunohistochemistry. In addition, we have examined the effect of RA on gene expression in osteoblasts in vitro. Compared to a standard diet, a high dietary intake of vitamin A resulted in a rapid and significant reduction in calvarial bone density and suture diastasis. The bone formation rate was almost halved. There was also increased staining of tartrate resistant acid phosphatase in osteocytes and an increased perilacunar matrix area, indicating osteocytic osteolysis. Consistent with this, RA induced genes associated with bone degradation in osteoblasts in vitro. Moreover, and in contrast to other known bone resorption stimulators, vitamin A induced osteoclastic bone resorption on the endocranial surfaces.
Highlights
The skull bones protect the brain from traumatic injury
We have shown that an excessive dietary of intake of vitamin A causes a rapid calvarial thinning in mice, and that the effects involve all three types of bone cells: osteoblasts, osteoclasts and osteocytes
In accordance with our previous study demonstrating that vitamin A is a negative regulator of osteoblast mineralization [6], we could show that excess vitamin A reduced the bone formation rate on the pericranial side and the calvarial bone density
Summary
The skull bones protect the brain from traumatic injury. In spite of this important function, studies on determinants of skull bone thickness are very few. Skull bones (calvaria) are formed via direct ossification of connective tissue (intramembranous ossification), which is in contrast to long bones that use a cartilage template (endochondral ossification). Vitamin A (retinol) is an essential micronutrient, which only can be derived from the diet as no animal species has the capability for de novo synthesis [1,2]. Vitamin A is the only known molecule to induce spontaneous fractures in animals [1] and in humans an excessive vitamin A intake has been associated with an increased risk of hip fracture [3,4,5].
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