A possible explanation of what's happening at the moment of palatal shelf elevation

Cleft lip and palate is multifactorial in aetiology. The elevation of palatal shelves is a key point of palatogenesis. However, there were many different opinions on the explanation of the elevation. In this article, we offered a new explanation. Before sixth week of gestation in humans, Palatal mesenchymal proliferation was along the horizontal direction. Because of the block of the tongue, the palatal shelves had to grow first vertically in the oral cavity. In the process of cells migration, much horizontal stress accumulated in the palatal shelves, meanwhile increased the collagen secretion of the palatal mesenchymal cells in order to strengthen the elasticity of palatal shelf and maintain the integrity to make palatal shelf look like an elastic palate. The intrinsic elevating force and the block of tongue made the palatal shelf curved. After seventh week facial structures grew predominantly in the sagittal plane. The activity of the geniohyoid and genioglossus muscles caused the mandibular retraction and the widening of the angulation between the bilateral hemimandibles. These changes provided the space for palatal shelf elevation. At some moment of the eighth to tenth weeks, the elastic stress center of the palatal shelf was above the horizontal surface because of the drop of the tongue. The palatal shelves might bounce up and elevate in a horizontal position when enough horizontal stress accumulated, and then adhered and fused.     

Differential expression of TGF beta isoforms in murine palatogenesis

We have studied the expression of genes encoding transforming growth factors (TGFs) beta 1, beta 2 and beta 3 during development of the secondary palate in the mouse from 11.5 to 15.5 days postcoitum using in situ hybridisation. The RNA detected at the earliest developmental stage is TGF beta 3, which is localised in the epithelial component of the vertical palatal shelf. This expression continues in the horizontal palatal shelf, predominantly in the medial edge epithelium, and is lost as the epithelial seam disrupts, soon after palatal shelf fusion. TGF beta 1 RNA is expressed with the same epithelial pattern as TGF beta 3, but is not detectable until the horizontal palatal shelf stage. TGF beta 2 RNA is localised to the palatal mesenchyme underlying the medial edge epithelia in the horizontal shelves and in the early postfusion palate. The temporal and spatial distribution of TGF beta 1, beta 2 and beta 3 RNAs in the developing palate, together with a knowledge of in vitro TGF beta biological activities, suggests an important role for TGF beta isoforms in this developmental process.     

Site-Specific Expression of Gelatinolytic Activity during Morphogenesis of the Secondary Palate in the Mouse Embryo

Morphogenesis of the secondary palate in mammalian embryos involves two major events: first, reorientation of the two vertically oriented palatal shelves into a horizontal position above the tongue, and second, fusion of the two shelves at the midline. Genetic evidence in humans and mice indicates the involvement of matrix metalloproteinases (MMPs). As MMP expression patterns might differ from sites of activity, we used a recently developed highly sensitive in situ zymography technique to map gelatinolytic MMP activity in the developing mouse palate. At embryonic day 14.5 (E14.5), we detected strong gelatinolytic activity around the lateral epithelial folds of the nasopharyngeal cavity, which is generated as a consequence of palatal shelf elevation. Activity was concentrated in the basement membrane of the epithelial fold but extended into the adjacent mesenchyme, and increased in intensity with lateral outgrowth of the cavity at E15.5. Gelatinolytic activity at this site was not the consequence of epithelial fold formation, as it was also observed in Bmp7-deficient embryos where shelf elevation is delayed. In this case, gelatinolytic activity appeared in vertical shelves at the exact position where the epithelial fold will form during elevation. Mmp2 and Mmp14 (MT1-MMP), but not Mmp9 and Mmp13, mRNAs were expressed in the mesenchyme around the epithelial folds of the elevated palatal shelves; this was confirmed by immunostaining for MMP-2 and MT1-MMP. Weak gelatinolytic activity was also found at the midline of E14.5 palatal shelves, which increased during fusion at E15.5. Whereas MMPs have been implicated in palatal fusion before, this is the first report showing that gelatinases might contribute to tissue remodeling during early stages of palatal shelf elevation and formation of the nasopharynx.     

A unique mouse strain expressing Cre recombinase for tissue-specific analysis of gene function in palate and kidney development

Mammalian palate development is a multistep process, involving initial bilateral downward outgrowth of the palatal shelves from the oral side of the maxillary processes, followed by stage-specific palatal shelf elevation to the horizontal position above the developing tongue and subsequent fusion of the bilateral palatal shelves at the midline to form the intact roof of the oral cavity. While mutations in many genes have been associated with cleft palate pathogenesis, the molecular mechanisms regulating palatal shelf growth, patterning, and elevation are not well understood. Genetic studies of the molecular mechanisms controlling palate development in mutant mouse models are often complicated by early embryonic lethality or gross craniofacial malformation. We report here the development of a mouse strain for tissue-specific analysis of gene function in palate development. We inserted an IresCre bicistronic expression cassette into the 3' untranslated region of the mouse Osr2 gene through gene targeting. We show, upon crossing to the R26R reporter mice, that Cre expression from the Osr2(IresCre) knockin allele activated beta-galactosidase expression specifically throughout the developing palatal mesenchyme from the onset of palatal shelf outgrowth. In addition, the Osr2(IresCre) mice display exclusive Cre-mediated recombination in the glomeruli tissues derived from the metanephric mesenchyme and complete absence of Cre activity in other epithelial and mesenchymal tissues in the developing metanephric kidney. These data indicate that the Osr2(IresCre) knockin mice provide a unique tool for tissue-specific studies of the molecular mechanisms regulating palate and kidney development.     

Experimental induction of palate shelf elevation in glutamate decarboxylase 67-deficient mice with cleft palate due to vertically oriented palatal shelf

BACKGROUND: Gamma-aminobutyric acid is an inhibitory neurotransmitter, synthesized by two isoforms of glutamate decarboxylase (GAD), GAD65 and -67. Unexpectedly, inactivation of GAD67 induces cleft palate in mice. Reduction of spontaneous tongue movement resulting from decreased motor nerve activity has been related to the development of cleft palate in GAD67(-/-) fetuses. In the present study, development of cleft palate was examined histologically and manipulated with culture of the maxilla and partial resection of fetal tongue. METHODS: GAD67(-/-) mice and their littermates were used. Histological examination and immunohistochemistry were performed conventionally. Organ culture of the maxilla was carried out as reported previously. Fetuses were maintained alive under anesthesia and tips of their tongues were resected. RESULTS: Elevation of palatal shelves, the second step of palate formation, was not observed in GAD67(-/-) mice. In wild-type mice, GAD67 and gamma-aminobutyric acid were not expressed in the palatal shelves, except in the medial edge epithelium. During 2 days of culture of maxillae dissected from E13.5-E14.0 GAD67(-/-) fetuses, elevation and fusion of the palatal shelves were induced. When E13.5-15.5 mutant fetuses underwent partial tongue resection, the palatal shelves became elevated within 30 min. CONCLUSIONS: These results suggest that the potential for palate formation is maintained in the palatal shelves of GAD67(-/-) fetuses, but it is obstructed by other, probably neural, factors, resulting in cleft palate.     

Temporal and Spatial Expression of Hoxa-2 During Murine Palatogenesis

1. Mice homozygous for a targeted mutation of the Hoxa-2 gene are born with a bilateral cleft of the secondary palate associated with multiple head and cranial anomalies and these animals die within 24 hr of birth (Gendron-Maguire et al., 1993; Rijli et al., 1993; Mallo and Gridley, 1996). We have determined the spatial and temporal expression of the Hoxa-2 homeobox protein in the developing mouse palate at embryonic stages E12, E13, E13.5, E14, E14.5, and E15.2. Hoxa-2 is expressed in the mesenchyme and epithelial cells of the palate at E12, but is progressively restricted to the tips of the growing palatal shelves at E13.3. By the E13.5 stage of development, Hoxa-2 protein was found to be expressed throughout the palatal shelf. These observations correlate with palatal shelf orientation and Hoxa-2 protein may play a direct or indirect role in guiding the palatal shelves vertically along side the tongue, starting with the tips of the palatal shelves at E13, followed by the entire palatal shelf at E13.5.4. As development progresses to E14, the stage at which shelf elevation occurs, Hoxa-2 protein is downregulated in the palatal mesenchyme but remains in the medial edge epithelium. Expression of Hoxa-2 continues in the medial edge epithelium until the fusion of opposing palatal shelves.5. By the E15 stage of development, Hoxa-2 is downregulated in the palate and expression is localized in the nasal and oral epithelia.6. In an animal model of phenytoin-induced cleft palate, we report that Hoxa-2 mRNA and protein expression were significantly decreased, implicating a possible functional role of the Hoxa-2 gene in the development of phenytoin-induced cleft palate.7. A recent report by Barrow and Capecchi (1999), has illustrated the importance of tongue posture during palatal shelf closure in Hoxa-2 mutant mice. This along with our new findings of the expression of the Hoxa-2 protein during palatogenesis has shed some light on the putative role of this gene in palate development.     

Bulging medial edge epithelial cells and palatal fusion

The surface of the medial edge epithelium of embryonic day 12, 13 and 14 mouse palatal shelves was observed utilising Environmental Scanning Electron Microscopy (ESEM). This technique offers the advantage of visualisation of biological samples after short fixation times in their natural hydrated state. Bulging epithelial cells were observed consistently on the medial edge epithelium prior to palatal shelf fusion. Additionally, we have used ESEM to compare the morphology and surface features of palatal shelves from embryonic day 13 to 16 mouse embryos that are homozygous null (TGF-beta3 -/-), heterozygous (TGF-beta3 +/-) or homozygous normal (TGF-beta3 +/+) for transforming growth factor beta-3 (TGF-beta3). At embryonic day 15 and 16 most TGF-beta3 +/- and +/+ embryos showed total palatal fusion, whilst all TGF-beta3 null mutants had cleft palate: the middle third of the palatal shelves had adhered, leaving an anterior and posterior cleft. From embryonic day 14 to 16 abundant cells were observed bulging on the medial edge epithelial surface of palates from the TGF-beta3 +/- and +/+ embryos. However, they were never seen in the TGF-beta3 null embryos, suggesting that these surface bulges might be important in palatal fusion and that their normal differentiation is induced by TGF-beta3. The expression pattern of E-Cadherin, beta-catenin, chondroitin sulphate proteoglycan, beta-Actin and vinculin as assayed by immunocytochemistry in these cells shows specific variations that suggest their importance in palatal shelf adhesion.     

The distribution of syndecan during murine secondary palate morphogenesis.

The distribution of syndecan, an integral membrane proteoglycan, has been immunohistochemically mapped during the course of murine secondary palate morphogenesis, gestational days 12-15. Syndecan has been shown to mediate cell adhesion and shape change and to be involved in epithelial-mesenchymal interactions during the morphogenesis of several structures. Changes in epithelial cell architecture accompany and may serve to direct the reorientation of the murine secondary palatal shelves from a vertical position on either side of the tongue to a horizontal and adhering position above it. Using a monoclonal antibody made to the core protein of the ectodomain of syndecan, staining was observed to correlate with epithelial cell shape, packing and degree of differentiation. Staining of condensing mesenchyme was also observed. Syndecan may be involved in modulating epithelial cell shape, architecture and fates during both major phases of secondary palate morphogenesis: shelf reorientation and midline epithelial seam dissolution.     

Characterization of desmosomal component expression during palatogenesis

Adhesion of the opposing palatal shelves is a critical first step in the mechanism for palatal fusion. Formation of desmosomal junctions between the two medial edge epithelia provides a mechanism for palatal shelf adhesion. RT-PCR and immunohistochemistry were used to determine the pattern of expression of desmosomal components during palatogenesis. Desmosomal expression was specifically upregulated in the medial edge epithelia (MEE) at the early stages of palatal fusion as detected by both immunohistochemistry and electron microscopy. RT-PCR characterization of the desmosomal components detected all known elements, except desmocollin 1 (DSC1). Desmocollin 2 (DSC2) was expressed as both the DSC2a and DSC2b variants. The two variants are expressed at the same level. Western analysis of desmoglein expression paralleled the RT-PCR result. The temporal and spatial upregulation of desmosomal gene expression is evidence that the MEE induce new gene expression required to accomplish palatal shelf adhesion and initiate the first stage of palatal fusion.     

Gross and cellular analysis of 6-mercaptopurine-induced cleft palate in hamster

The present study analyzes the morphological, histochemical, and ultrastructural aspects of the pathogenesis of 6-mercaptopurine (6MP)-induced cleft palate in hamster fetuses. Gross and light microscopic observations indicated that 6MP stunts the growth of vertical palatal shelves and thus induces cleft palate. Ultrastructural analysis showed that, in contrast to controls, 6MP-induced alterations were first seen in the mesenchymal cells 24 hr after drug administration. The initial alterations were characterized by swelling of the nuclear membrane. During the next 12 hr, lysosomes were seen first in the mesenchymal cells and then in the cells of the medial edge epithelium (MEE) of the developing palatal primordia. The appearance of lysosomes was temporally abnormal and was interpreted as a sublethal response to 6MP treatment. Subsequently, the nuclear alterations and the lysosomes diminished; and 48 hr after 6MP administration, they were absent from the palatal tissues. Ninety hours after 6MP administration, unlike the controls (in which the palatal shelves were already fused), changes were seen at the epithelial-mesenchymal interface in the developing cleft palatal shelves. These changes were characterized by breakdown of the basal lamina and epithelial-mesenchymal contacts. Eventually, at term, the MEE of the vertical shelf stratified. It was suggested that 6MP affected cytodifferentiation in the palatal tissues during the critical phase of early vertical shelf development and thereby induced cleft palate.     

Effects of cyclophosphamide on the secondary palate development in golden Syrian hamster: teratology, morphology, and morphometry

Cyclophosphamide (CP), when injected in hamster mother between days 9 and 11 of pregnancy, was teratogenic in fetuses. On the basis of a morphological study it was deduced that CP delayed the reorientation of hamster palatal shelves by 16-20 h. In a subsequent experiment, in both control and CP-treated palatal shelves, the numbers of epithelial and mesenchymal cells were counted and cross-sectional area was measured. DNA synthesis, measured by 3H-thymidine incorporation, was used as an index of growth by cell proliferation. The results showed that during the vertical development of palatal shelves, the mesenchymal cells reached their peak number during the initial 24 hours, i.e., at the end of the second peak in DNA synthesis, and remained unchanged thereafter throughout reorientation. The shelf area also showed rapid increase during the initial 24 h followed by a spurt 2 h prior to reorientation. Cyclophosphamide prolonged the acquisition of these features by affecting the mesenchymal cells and consequently delayed the reorientation of the vertical shelves until such time that the number of healthy mesenchymal cells and shelf area were restored to the control values. The data lend further support to the hypothesis that the acquisition of a specific number of cells and shelf volume, during vertical palatal development, may be essential for palatal shelf reorientation.     

Ultrastructural changes in rat palatal epithelium after beta-aminopropionitrile.

Beta-Aminopropionitrile (BAPN) retarded or suppressed epithelial changes in the medial edge of the palatal process in later stages of gestation in rats. Programmed cell death did not follow the usual pattern, and only a few lysosomes were observed on day 18 of gestation. The sensitivity of the medial epithelium to BAPN appeared to be different in various areas of the palatal epithelium; the epithelium on the anterior region of the palatal process was hypertrophied and keratinized, while posteriorly the medial or neighboring epithelium was very thin and, in neonatal rats, the covering was absent. A basal lamina was distinct in the anterior region and indistinct or fragmented posteriorly. Collagen fibers did not develop adjacent to the basal lamina, and an amorphous material was scattered throughout the mesenchymal tissue. These findings suggest that BAPN decreases the "connecting capacity" between mesenchyme and epithelium, and results in a modification of epithelial changes.     

Involvement of c-Fos proto-oncogene during palatal fusion and interdigital space formation in the rat

c-Fos is an indispensable proto-oncogene product in the developmental process and a key factor in the proliferation of normal and neoplastic cells. It is also implicated in triggering epithelial–fibroblastoid cell conversion and the induction of apoptosis. To clarify the role of c-Fos in the life span of rat embryonic cells, we examined the disappearance of the medial edge epithelium (MEE) of the palatal shelf on palatal fusion and formation of the interdigital web. Using immunohistochemical techniques with anti-c-Fos antibody and a TdT-mediated dUTP-digoxigenin nick end labeling (TUNEL) method, we compared the pattern of c-Fos-positive cells and DNA fragmentation. To investigate the epithelial–mesenchymal transformation, transforming growth factor (TGF)-β₃ was examined in both regions. During palatal fusion, c-Fos was detected in the nuclei of MEE cells just before the elevation of the palatal shelf and strongly stained at the MEE remaining in the center of the palate. c-Fos became undetectable in accordance with the disruption of the medial edge epithelium. We also immunohistochemically recognized the colocalization of c-Fos and TGF-β₃ in the MEE. However, DNA fragmentation was not observed at the center of fusion. Considered together, cell disappearance at the fusion site was suggested to reflect epithelial–mesenchymal transformation. In contrast, mesenchymal cells of the interdigital web and the chondrocytes of the digit expressing c-Fos appeared to be the hallmark of programmed cell death and TGF-β₃ could not be found in the interdigital mesenchyme. c-Fos in the interdigital space was detected more proximal than DNA fragmentation detection, suggesting that c-Fos acted at the upper stream of apoptosis. Our results support the involvement of c-Fos in the physiological process of cell transformation during palatogenesis and apoptosis during the interdigital formation. c-Fos may trigger a cell specific signal during organogenesis, especially transformation of epithelial cells and apoptosis of mesenchymal cells.     

Does the tongue play a role in the initial development of vertical palatal shelf in hamster?

A study was undertaken to examine whether the tongue plays any role in determining the primordial development of palatal shelves in a vertical direction in mammals. Control and 6-mercaptopurine-treated embryos from Golden Syrian hamsters were examined by scanning electron microscopic and histological techniques for the spatio-temporal relationship of primordial development of the palate, tongue, and mandible. DNA synthesis, measured by 3H-thymidine incorporation, was used as an index of growth. The data indicated that in controls, vertical palate development began in the anterior half from the roof of the oronasal cavity, whereas the tongue bulges and the mandibular process developed in the posterior half of the oronasal cavity. A burst in DNA synthesis occurred in the palate and mandible, but not in the tongue. In 6-mercaptopurine-treated fetuses, although the chronological appearance of primordia of all three structures was normal, DNA synthesis was inhibited in all three structures. The recovery in DNA synthesis, albeit partial, was faster in the palate and mandible than in the tongue. On the basis of observations from the present study, along with those from other vertebrates, it is suggested that the developing tongue may not play any role in determining the direction of development of the palatal primordia.     

Palatogenesis: morphogenetic and molecular mechanisms of secondary palate development

Mammalian palatogenesis is a highly regulated morphogenetic process during which the embryonic primary and secondary palatal shelves develop as outgrowths from the medial nasal and maxillary prominences, respectively, remodel and fuse to form the intact roof of the oral cavity. The complexity of control of palatogenesis is reflected by the common occurrence of cleft palate in humans. Although the embryology of the palate has long been studied, the past decade has brought substantial new knowledge of the genetic control of secondary palate development. Here, we review major advances in the understanding of the morphogenetic and molecular mechanisms controlling palatal shelf growth, elevation, adhesion and fusion, and palatal bone formation.     

Effect of diazepam on the embryonic development of the palate in the rat

The results of previous studies on the effect of diazepam on palate formation in animals have been inconclusive. Teratogen-induced cleft palate is usually caused by a delay in palatal shelf elevation. The present study investigated the effect of diazepam on palate formation in the Sprague-Dawley rat. Five groups of dams received subcutaneous doses of either 10, 20, 30, 40, or 50 mg/kg body weight of diazepam. Control dams received propylene glycol (vehicle). Dams in each dosage group were killed at 16.9 (16 d 9 h); 16.16, and 17.9 days of gestation, respectively, to assess delay in palatal shelf elevation. Crown rump length (CRL) of 1,283 fetuses collected from 105 dams was measured. Fetuses in each time/dosage group showed a reduction in CRL (P less than .01). With increasing dosage the number of fetuses showing delayed palatal shelf elevation was significantly increased (P less than .01). These results demonstrate that with an increase in dose there is an increased delay in palatal shelf elevation and a decrease in CRL. However, in this strain there seems to be a rapid prenatal recovery, resulting in a marked reduction in the incidence of delayed palatal shelf elevation.