Ronald Piddington

Myo-inositol and prostaglandins reverse the glucose inhibition of neural tube fusion in cultured mouse embryos

SummaryNeural tube defects in infants of diabetic mothers constitute an important and frequent cause of neonatal mortality/morbidity and long-term chronic handicaps. The mechanism by which normal neural tube fusion occurs is not known. The failure of rostral neural tube fusion seen in mouse embryos incubated in the presence of excess-D-glucose can be significantly prevented by the supplementation of myo-inositol to the culture medium. This protective effect of myo-inositol is reversed by indomethacin, an inhibitor of arachidonic acid metabolism leading to prostaglandin synthesis. Prostaglandin E2 added to the culture medium completely protects against the glucose-induced neural tube defect. These data suggest that the failure of neural tube fusion seen in diabetic embryopathy is mediated through a mechanism involving abnormalities in both the myo-inositol and arachidonic acid pathways, resulting in a functional deficiency of prostaglandins at a critical time of neural tube fusion.

Expression, gene regulation, and roles of Fisp12/CTGF in developing tooth germs

Odontogenesis involves multiple events, including tissue–tissue interactions, cell proliferation, and cell differentiation, but the underlying mechanisms of regulation are far from clear. Because Fisp12/CTGF is a signaling protein involved in similar events in other systems, we asked whether it is expressed in developing tooth germs and what roles it may have. Indeed, Fisp12/CTGF transcripts were first expressed by dental laminas, invaginating epithelium, and condensing mesenchyme at the bud stage, and then became abundant in enamel knot and preameloblasts. Fisp12/CTGF was present not only in inner dental epithelium but also in stratum intermedium and underlying dental mesenchyme. Fisp12/CTGF expression decreased markedly in secreting ameloblasts. Tissue reconstitution experiments showed that Fisp12/CTGF expression in dental epithelium required interaction with mesenchyme but was maintained by treatment of epithelium with transforming growth factor‐1, a factor regulating Fisp12/CTGF expression in other systems, or with bone morphogenetic protein‐2. Loss‐of‐function studies using CTGF neutralizing antibodies revealed that interference with endogenous factor action in tooth germ explants led to a severe inhibition of proliferation in both epithelium and mesenchyme and a marked delay in cytodifferentiation of ameloblasts and odontoblasts. Treatment of dental epithelial and mesenchymal cells in culture with recombinant CTGF stimulated cell proliferation, whereas treatment with neutralizing antibodies inhibited it. The data demonstrate for the first time that Fisp12/CTGF is expressed during odontogenesis. Expression is confined to specific sites and times, is regulated by epithelial–mesenchymal interactions and critical soluble factors, and appears to be needed for proliferation and differentiation along both ameloblast and odontoblast cell lineages.

Over- and Ectopic Expression of Wnt3 Causes Progressive Loss of Ameloblasts in Postnatal Mouse Incisor Teeth

Intercellular signaling is essential for the development of teeth during embryogenesis and in maintenance of the continuously growing incisor teeth in postnatal rodents. WNT intercellular signaling molecules have been implicated in the regulation of tooth development, and the Wnt3 gene shows specific expression in the enamel knot at the cap stage. We demonstrate here that Wnt3 also is expressed in specific epithelial cell layers in postnatal incisor teeth. To begin to delineate the functions of Wnt3 in developing and postnatal teeth, we determined the effects of over- and ectopic expression of Wnt3 in the tooth epithelium of mice carrying a keratin 14- Wnt3 transgene. Expression of the transgene caused a progressive loss of ameloblasts from postnatal lower incisor teeth. Loss of ameloblasts may be due to defective proliferation or differentiation of ameloblast precursors, progressive apoptosis of ameloblasts, or loss of ameloblast stem cells.

Inhibition of Programmed Cell Death in Mouse Embryonic Palate in Vitro by Cortisol and Phenytoin: Receptor Involvement and Requirement of Protein Synthesis

Abstract In an in vitro model Cortisol and phenytoin inhibit the precisely timed process of palatal development, the lysosomally mediated cell death of the medial edge palatal epithelium. This inhibition of programmed cell death of the palatal midline epithelium by each drug is virtually completely blocked by the antiglucocorticoid, cortexolone, whose blocking action results from competitive binding of the glucocorticoid receptor site. The inhibition produced by each of these drugs is prevented by the protein synthesis blocker, cycloheximide. Thus, blockade of programmed cell death by each of these drugs involves the glucocorticoid receptor site and requires protein synthesis.

Diabetes mellitus affects prostaglandin E2 levels in mouse embryos during neurulation.

SummaryThe arachidonic acid cascade leading to prostaglandins has been implicated in diabetic embryopathy. Both arachidonic acid and prostaglandin E2 reverse the teratogenic effects of high glucose concentrations on neural tube development in mouse embryos in culture. Arachidonic acid supplementation also protects against diabetes-induced neural tube defects in vivo. In the present study, prostaglandin E2 was measured directly in embryos from normal and diabetic mice. In normal mice a clear developmental pattern was seen. Prostaglandin E2 levels were high during early formation of the cranial neural folds (day 8), declined during convergence and fusion of the cranial neural folds to form the neural tube (day 9), and were low after neurulation was complete (days 10 and 11). In addition, evidence in this study indicates that embryos have cyclooxygenase activity capable of generating prostaglandin E2 during a brief developmental period preceding neural tube closure. In embryos from mice made diabetic (>13.9 mmol/l glucose) with streptozotocin, prostaglandin E2 levels were significantly lower than normal during early development of the cranial neural folds (day 8), but similar to normal after the cranial neural tube had closed (late day 9 and day 10). The findings suggest that diabetes mellitus, as ascertained by high blood glucose, promotes cranial neural tube malformations by causing a functional deficiency of prostaglandin E2 during early neurulation. Whether the altered PGE2 pattern in the embryo indicates a diabetic effect on the arachidonic acid-prostaglandin cascade in cells of the embryo or in cells of extraembryonic or maternal tissues is uncertain.

The Small Bovine Amelogenin LRAP Fails to Rescue the Amelogenin Null Phenotype

Amelogenins are the most abundant secreted proteins in developing dental enamel. These evolutionarily-conserved proteins have important roles in enamel mineral formation, as mutations within the amelogenin gene coding region lead to defects in enamel thickness or mineral structure. Because of extensive alternative splicing of the primary RNA transcript and proteolytic processing of the secreted proteins, it has been difficult to assign functions to individual amelogenins. To address the function of one of the amelogenins, we have created a transgenic mouse that expresses bovine leucine-rich amelogenin peptide (LRAP) in the enamel-secreting ameloblast cells of the dental organ. Our strategy was to breed this transgenic mouse with the recently generated amelogenin knockout mouse, which makes none of the amelogenin proteins and has a severe hypoplastic and disorganized enamel phenotype. It was found that LRAP does not rescue the enamel defect in amelogenin null mice, and enamel remains hypoplastic and disorganized in the presence of this small amelogenin. In addition, LRAP overexpression in the transgenic mouse (wildtype background) leads to pitting in the enamel surface, which may result from excess protein production or altered protein processing due to minor differences between the amino acid compositions of murine and bovine LRAP. Since introduction of bovine LRAP into the amelogenin null mouse does not restore normal enamel structure, it is concluded that other amelogenin proteins are essential for normal appearance and function.

Inhibition of Programmed Cell Death in the Fetal Palate by Cortisol

Abstract In an in vitro model, cortisol inhibits a precisely timed process of palatal development, the lysosomally mediated cell death of the medial edge palatal epithelium. These steroid effects occur only in palatal shelves from mouse strains with high incidences of corticosteroid-induced cleft palate. In studies in vivo using steroid-sensitive mice, corticosteroid delays shelf elevation but does not prevent shelf contact and alters lysosomal enzyme distribution in the medial edge palatal epithelia. Thus, susceptibility to corticosteroid-promoted palatal clefting is correlated with the inhibition of programmed cell death in the medial edge epithelium in vitro and in vivo.

Further Evidence for a Role of Arachidonic Acid in Glucocorticoid Teratogenic Action in the Palate

Abstract Arachidonic acid produces a significant reversal of the production of cleft palate by cortisone in the offspring of sensitive strains of mice in vivo. Arachidonic acid in nanogram per milliliter concentrations also produces a significant reversal of the cortisol inhibition of the programmed cell death of the medial edge epithelium of palatal shelves in vitro. This corrective action of arachidonic acid in vitro is significantly blocked by indomethacin at a nanogram per milliliter concentration which selectively inhibits the conversion of arachidonic acid to prostaglandins and/or thromboxanes at the level of cyclooxygenase. These results support the hypothesis that the inhibition of arachidonic acid release and subsequent prostaglandin and/or thromboxane production by glucocorticoids is involved in the teratogenic action of glucocorticoids and demonstrate that one site of this action is the inhibition of epithelial loss.

Analysis of the regulatory region of the bovine X-chromosomal amelogenin gene.

The amelogenin proteins, which are crucial for normal enamel mineral formation, are secreted by ameloblasts during development of tooth enamel. In order to better understand the mechanisms involved in regulation of expression of the amelogenin genes, the bovine X-chromosomal amelogenin gene was cloned and a 3.5 KB fragment upstream of exon 1 was inserted into a beta galactosidase (beta gal) expression vector for production of transgenic mice. When tissues from these mice were treated with Xgal, a substrate for beta gal, only ameloblasts and some of the adjacent stratum intermedium cells contained blue stain. To obtain further information concerning regulation of expression, the 3.5 KB amelogenin gene fragment was evaluated in transfection experiments. Nonoverlapping 1.9 and 1.5 KB fragments of the upstream region were subcloned separately into a vector that contains the SV40 promoter and the CAT reporter gene. Each amelogenin gene fragment was able to suppress CAT activity driven by the heterologous SV40 promoter in transfected HeLa cells. We theorize that each of these gene fragments contains regulatory elements important for the tissue-specific and developmentally-regulated pattern of expression of the X-chromosomal amelogenin gene.

Subcellular distribution of glutamyltransferase activities in embryonic cerebral hemispheres

Glutamyltransferase (GT) activities were examined in cell groups from embryonic cerebral hemispheres. During normal development, GT activities were highest in a mixed population of small neurons and non-neuronal cells (small cell group). In culture, in response to hydrocortisone, activities exceeded normal levels only in this small cell group. In view of these findings, the small cell population was used to study the subcellular distribution of the enzyme. At the subcellular level, GT activities in the small cell group were distributed differentially but increased generally during normal development. In vitro, hydrocortisone promoted a precocious increase in GT activity, under experimental conditions regarded as optimum, only in the subcellular fraction characterized by synaptic endings.