Cholinesterase (ChE) is one of the most ubiquitous enzymes and in addition to its well characterized catalytic function, the morphogenetic involvement of ChE has also been demonstrated in neuronal tissues and in non-neuronal tissues such as bone and cartilage. We have previously reported that during mouse tooth development, acetylcholinesterase (AChE) activity is dynamically localized in the dental epithelium and its derivatives whereas butyrylcholinesterase (BuChE) activity is localized in the dental follicles. To test the functional conservation of ChE in tooth morphogenesis among different species, we performed cholinesterase histochemistry following the use of specific inhibitors of developing molar and incisors in the hamster from embryonic day 11 (E11) to postnatal day 1 (P1). In the developing molar in hamster, the localization of ChE activity was found to be very similar to that of the mouse. At the bud stage, no ChE activity was found in the tooth buds, but was first detectable in the dental epithelium and dental follicles at the cap and bell stages. AChE activity was found to be principally localized in the dental epithelium whereas BuChE activity was observed in the dental follicle. In contrast to the ChE activity in the molars, BuChE activity was specifically observed in the secretory ameloblasts of the incisors, whilst no AChE activity was found in the dental epithelium of incisors. The subtype and localization of ChE activity in the dental epithelium of the incisor thus differed from those of the molar in hamster. In addition, these patterns also differed from the ChE activity in the mouse incisor. These results strongly suggest that ChE may play roles in the differentiation of the dental epithelium and dental follicle in hamster, and that morphogenetic subtypes of ChE may be variable among species and tooth types.
Dentin, a major component of teeth, is formed by odontoblasts which produce the dentin matrix beneath the dental epithelium and induce the mineralization of dentin. To date, the biochemical properties of dentin matrix proteins have been well characterized, but upstream regulators of these proteins are not yet well known. Recently in this regard, several transcription factors have been identified as potential regulators of matrix proteins. Most transcription factors are generally involved in diverse biological processes and it is essential to identify those that are odontoblast-specific transactivators to further understand the process of dentin formation. We thus analyzed the expression pattern of dentin matrix proteins and the activities of established transactivators containing a Cre-locus. Expression analyses using in situ hybridization showed that dentin matrix proteins are sequentially expressed in differentiating odontoblasts, including type-I collagen, Dmp-1 and Dspp. The activities of the transactivators were evaluated using β-galactosidase following the generation of double transgenic mice with each transactivator and the ROSA26R reporter line. The β-galactosidase activity of each transactivator paralled the expression of the matrix proteins. These results thus showed that these transactivators could be utilized for odontoblastspecific conditional gene targeting. In addition, time- and tissue-specific conditional gene targeting might also be achieved using a combination of these transactivators. Odontoblast-specific conditional gene targeting with these transactivators will likely also provide new insights into the molecular mechanisms underlying dentin formation.
Expression of invasion/metastasis suppressor, E-cadherin, is reduced in many types of human carcinomas. Although somatic and germline mutations in the CDH1, which encodes the human E-cadherin, have frequently been reported in cases with diffuse gastric and lobular breast cancers, irreversible genetic inactivations are rare in other human carcinomas. Recently, it has been well documented that some genes in human cancers may be inactivated by altered CpG methylation. Herein, we determined the expression and methylation status of E-cadherin in oral squamous cell carcinoma(SCC) by immunohistochemistry and methylation-specific PCR. The expression of E-cadherin was significantly higher in the well-differentiated oral SCCs than the moderately or poorly differentiated ones. None of eight tested benign epithelial hyperplasias showed aberrant methylation, whereas five of 12 oral squamous cell carcinomas showed aberrant methylation. When we compared E-cadherin expression with methylation status, oral SCCs with normal methylation showed a higher expression of E-cadherin than those with methylation. These findings suggest that aberrant CpG methylation of CDH1 promoter region is closely associated with transcriptional inactivation and might be involved in tumor progression of the oral mucosa.