We previously reported that alymphoplasia (aly/aly) mice, which have a natural loss-of-function mutation in the Nik gene, which encodes a kinase essential for the processing of p100 to p52 in the alternative nuclear factor-κB (NF-κB) pathway, show mild osteopetrosis with an increase in several parameters of bone formation: bone formation rate, mineral apposition rate, and osteoblast number. We therefore investigated the molecular mechanisms triggered by the alternative NF-κB pathway in the regulation of osteoblast differentiation using primary osteoblasts (POB) prepared from aly/aly mice. Alkaline phosphatase (ALP) activity and mineralization induced by the presence of β-glycerophosphate and ascorbic acid were enhanced in POB from aly/aly compared with wild-type (WT) mice. Furthermore, osteoblastic differentiation induced by bone morphogenetic protein 2 (BMP2), as shown by ALP activity, mRNA expression of osteocalcin, Id1, Osterix and Runx2, and Sma- and Mad-related protein (Smad)1/5/8 phosphorylation, was also enhanced in POB from aly/aly mice. The ectopic bone formation in vivo that was induced by BMP2 was enhanced in aly/aly mice compared with controls. Transfection of a mutant form of p100, p100ΔGRR, which cannot be processed to p52, stimulated ALP activity and Smad phosphorylation. In contrast to p100ΔGRR, overexpression of p52 inhibited these events. Both BMP2-induced ALP activity and Smad phosphorylation were reduced in POB from p100-deficient mice, which carry a homozygous deletion of the COOH-terminal ankyrin repeats of p100 but still express functional p52 protein. p52 and p100ΔGRR interacted with a BMP receptor, ALK2, in overexpressed COS7 cells and changed the ALK2 protein levels in opposite directions: p52 reduced ALK2 and p100 increased it. Thus, the alternative the NF-κB pathway via the processing of p52 from p100 negatively regulates osteoblastic differentiation and bone formation by modifying BMP activity.
Nerve growth factor (NGF) plays a critical role in the trigeminal ganglion (TG) following peripheral nerve damage in the oral region. Although neurons in the TG are surrounded by satellite glial cells (SGCs) that passively support neural function, little is known regarding NGF expression and its interactions with TG neurons and SGCs. This study was performed to examine the expression of NGF in TG neurons and SGCs with nerve damage by experimental tooth movement. An elastic band was inserted between the first and second upper molars of rats. The TG was removed at 0–7 days after tooth movement. Using in situ hybridization, NGF mRNA was expressed in both neurons and SGCs. Immunostaining for NGF demonstrated that during tooth movement the number of NGF-immunoreactive SGCs increased significantly as compared with baseline and reached maximum levels at day 3. Furthermore, the administration of the gap junction inhibitor carbenoxolone at the TG during tooth movement significantly decreased the number of NGF-immunoreactive SGCs. These results suggested that peripheral nerve damage may induce signal transduction from neurons to SGCs via gap junctions, inducing NGF expression in SGCs around neurons, and released NGF may be involved in the restoration of damaged neurons.
Several theories have been proposed regarding pain transmission mechanisms in tooth. However, the exact signaling mechanism from odontoblasts to pulp nerves remains to be clarified. Recently, ATP-associated pain transmission has been reported, but it is unclear whether ATP is involved in tooth pain transmission. In the present study, we focused on the vesicular nucleotide transporter (VNUT), a transporter of ATP into vesicles, and examined whether VNUT was involved in ATP release from odontoblasts. We examined the expression of VNUT in rat pulp by RT-PCR and immunostaining. ATP release from cultured odontoblast-like cells with heat stimulation was evaluated using ATP luciferase methods. VNUT was expressed in pulp tissue, and the distribution of VNUT-immunopositive vesicles was confirmed in odontoblasts. In odontoblasts, some VNUT-immunopositive vesicles were colocalized with membrane fusion proteins. Additionally P2X3, an ATP receptor, immunopositive axons were distributed between odontoblasts. The ATP release by thermal stimulation from odontoblast-like cells was inhibited by the addition of siRNA for VNUT. These findings suggest that cytosolic ATP is transported by VNUT and that the ATP in the vesicles is then released from odontoblasts to ATP receptors on axons. ATP vesicle transport in odontoblasts seems to be a key mechanism for signal transduction from odontoblasts to axons in the pulp.
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