Palate morphogenesis. III. Changes in cell shape and orientation during shelf elevation

Implications of TGFβ on Transcriptome and Cellular Biofunctions of Palatal Mesenchyme

Development of the palate comprises sequential stages of growth, elevation, and fusion of the palatal shelves. The mesenchymal component of palates plays a major role in early phases of palatogenesis, such as growth and elevation. Failure in these steps may result in cleft palate, the second most common birth defect in the world. These early stages of palatogenesis require precise and chronological orchestration of key physiological processes, such as growth, proliferation, differentiation, migration, and apoptosis. There is compelling evidence for the vital role of TGFβ-mediated regulation of palate development. We hypothesized that the isoforms of TGFβ regulate different cellular biofunctions of the palatal mesenchyme to various extents. Human embryonic palatal mesenchyme (HEPM) cells were treated with TGFβ1, β2, and β3 for microarray-based gene expression studies in order to identify the roles of TGFβ in the transcriptome of the palatal mesenchyme. Following normalization and modeling of 28,869 human genes, 566 transcripts were detected as differentially expressed in TGFβ-treated HEPM cells. Out of these altered transcripts, 234 of them were clustered in cellular biofunctions, including growth and proliferation, development, morphology, movement, cell cycle, and apoptosis. Biological interpretation and network analysis of the genes active in cellular biofunctions were performed using IPA. Among the differentially expressed genes, 11 of them are known to be crucial for palatogenesis (EDN1, INHBA, LHX8, PDGFC, PIGA, RUNX1, SNAI1, SMAD3, TGFβ1, TGFβ2, and TGFβR1). These genes were used for a merged interaction network with cellular behaviors. Overall, we have determined that more than 2% of human transcripts were differentially expressed in response to TGFβ treatment in HEPM cells. Our results suggest that both TGFβ1 and TGFβ2 orchestrate major cellular biofunctions within the palatal mesenchyme in vitro by regulating expression of 234 genes.

Distributional changes of BrdU, PCNA, E2F1 and PAL31 molecules in developing murine palatal rugae

The distribution of cells incorporating bromodeoxyuridine (BrdU) and the expression of molecules involved in the control of cell proliferation (proliferating cell nuclear antigen [PCNA], a cellular factor in F9 teratocarcinoma cells that recognizes an adenovirus E1A inducible promoter 1 [E2F1] and proliferation-related acidic nuclear protein 31 [PAL31]) during morphogenesis of the murine palatine rugae (PR) was examined histochemically. Pattern formation of the PR rudiment was initiated with cell cycle related molecules in the epithelium of the primary palate. Cells which had incorporated BrdU were detected at the outer areas of the presumptive epithelial placode (EP) and the EP at 11.5-13.5 days post coitum (dpc) and the outer areas of the PR protrusion after 14.5 dpc. The number of PCNA-positive cells at the central area of the PR protrusion decreased after 16.5 dpc. E2F-positive cells were detected at the outer areas of the PR protrusion at 15.5 and 16.5 dpc. The number of PAL31-positive cells at the presumptive EP area and the already-formed EP area was decreased at 11.5-13.5 dpc. In two dimensional histological reconstructions, PAL31 expression approximately corresponded to the distribution of BrdU-positive cells at 11.5 and 13.5 dpc. EP placode formation might be regulated by spatiotemporal cell proliferation control involving the expression of the PAL31 molecule. Following EP formation, PR development and growth control involved the expression of E2F1 and PCNA molecules.

Microarray analysis of murine palatogenesis: temporal expression of genes during normal palate development

The mammalian face is assembled in utero in a series of complex and interdependent molecular, cell and tissue processes. The orofacial complex appears to be exquisitely sensitive to genetic and environmental influence and this explains why clefts of the lip and palate are the most common congenital anomaly in humans (one in 700 live births). In this study, microarray technology was used to identify genes that may play pivotal roles in normal murine palatogenesis. mRNA was isolated from murine embryonic palatal shelves oriented vertically (before elevation), horizontally (following elevation, before contact), and following fusion. Changes in gene expression between the three different stages were analyzed with GeneChip microarrays. A number of genes were upregulated or downregulated, and large changes were seen in the expression of loricrin, glutamate decarboxylase, gamma-amino butyric acid type A receptor beta3 subunit, frizzled, Wnt-5a, metallothionein, annexin VIII, LIM proteins, Sox1, plakophilin1, cathepsin K and creatine kinase. In this paper, the changes in genetic profile of the developing murine palate are presented, and the possible role individual genes/proteins may play during normal palate development are discussed. Candidate genes with a putative role in cleft palate are also highlighted.

Distribution of apoptotic cells and apoptosis-related molecules in the developing murine palatine rugae

Distribution of apoptotic cells and expression of the apoptosis-related factors p53, bcl-2 and bad during morphogenesis of the murine palatine rugae (PR) were examined histochemically using the terminal deoxynucleotidyl transferase-mediated UTP nick end-labeling (TUNEL) technique and specific antibodies against apoptosis and cell cycle-related molecules. Formation of the PR rudiment was controlled by cell proliferation and apoptosis in the palatal epithelium. TUNEL-positive cells were detected only at the epithelial placode area at 12.5-13.5 days post coitus (dpc), but only a few cells were positive at the protruding PR area at 14.5-16.5 dpc. Bcl-2 protein was expressed mainly in the areas outside of those containing TUNEL-positive cells at 15.5 -6.5 dpc. P53 protein was not detected throughout gestation. Bad was detected in the epithelial layer at 13.5 and 15.5 dpc and overlapping the apoptotic area at 13.5-15.5 dpc. Apoptosis of palatal epithelial cells might therefore involve spatiotemporally regulated expression of bad during murine PR development.

Epithelial cell proliferation and apoptosis in the developing murine palatal rugae

Epithelial cell proliferation and apoptosis during morphogenesis of the murine palatal rugae (PR) were examined histochemically by using anti-bromodeoxyuridine (BrdU) and the terminal deoxynucleotidyl transferase-mediated UTP nick-end-labelling (TUNEL) technique. Formation of the PR rudiment was observed as an epithelial placode in fetuses at 12.5 days post-coitus (dpc). During the PR formation, BrdU-positive cells were detected mainly in the epithelium of the interplacode and interprotruding areas in fetuses administered BrdU maternally at 2 h before killing. TUNEL-positive cells were detected only at the epithelial placode area in 12.5-14.5 dpc. At 16.5-18.5 dpc, the BrdU-positive cells were decreased in number in the epithelial cells at the interprotruding area of the PR. Only a few TUNEL-positive cells were observed in the protruding area of the PR at 16.5 dpc. These results suggest that cell proliferation and apoptosis in the palatal epithelium are involved spatiotemporally in the murine PR morphogenesis.

Development of a suspension organ culture of the fetal rat palate

On the basis of an already established suspension organ culture system of mouse palate anlagen, we developed a corresponding culture system for rat palate anlagen. In order to optimize the culture results we systematically studied the influence of main "culture conditions" such as dissection technique, rotation speed, gassing schedule, and developmental stage at the onset of culture for mice and rat palate anlagen. This system allows culturing rat palate anlagen from day 15 of gestation to day 18 + 8 h (80 h) under serum- and antibiotic-free conditions using a chemically defined medium, resulting in 90% fused palates. The explants, containing the maxillary vault and the palatal shelves, were cultured in siliconized culture flasks at a rotation speed of 12 rpm and a temperature of 37 degrees C (Table 1).

Study of the mechanisms of BUdR-induced cleft palate in the mouse

This study was designed to examine the pathogenesis of bromodeoxyuridine (BUdR)-induced clefts of the secondary palate in the LACA mouse. Intraperitoneal injections of BUdR (500 mg/kg body weight) were given at various days and combinations of days between E11 and E15 (plug day = E1). Treatment on E11 alone resulted in approximately 22% of fetuses with cleft palate when the latter were examined either on E16 or E19. Treatment on E11 and E12 approximately doubled the above incidence, and treatment on E11, 12 and 13 raised it to 100%. However, no treatment, either single or multiple, caused cleft palate when given later than E11. This suggests that the cellular changes caused by BUdR that lead to cleft palate must be inflicted during E11 and that such damage can be repaired in about 80% of embryos. All fetuses with cleft palate had severe micrognathia on E16 and E19, which skeletal staining showed to be the result of a bilateral sigmoid buckling of Meckel's cartilage. Studies with the scanning electron microscope (SEM) on E15, 16, and 19 suggested strongly that the micrognathia caused a relative macroglossia and hence mechanical interference with palatal shelf reorientation. Histological studies with the light microscope showed that BUdR caused cellular necrosis in many embryonic tissues during the 24 hours after its administration. This necrosis was strikingly more severe in the mandibular rudiment of the first branchial arch than in the maxillary. The latter observation accords well with findings by other workers that cell proliferation is more rapid in the mandibular blastema than in the maxillary. Transmission electron microscope (TEM) studies of the buckled region of Meckel's cartilage failed to reveal any ultrastructural differences from control Meckel's cartilage. Hence BUdR had only interfered with the shape of the cartilage but not with its histiogenesis. We conclude that BUdR, by its cytotoxicity or antidifferentiative effects, interfered with the formation of the anterior end of Meckel's cartilage, initiating a chain of events leading through micrognathia and relative macroglossia to failure of palatal shelf reorientation and cleft palate.

Morphogenesis of the secondary palate in mouse embryos with special reference to the development of rugae

Morphological studies of secondary palate formation, with special reference to the development of rugae, were carried out on Jcl:ICR mouse embryos. Three rugae were observed on the anterior part of the future oral surface of the vertically developing palatal shelves in 13-day embryos. Rugae increased in number as the development of the palatal shelves proceeded, and five to six prominent rugae were observed in 14-day embryos just prior to shelf elevation. The folding of these five to six rugae progressed in conjunction with the formation of a sharp, valley-like groove at the base of the anterior two-fifths of the vertical palatal shelves. As palatal shelves elevated, the groove disappeared gradually, and, accordingly, the folding of rugae loosened. In the groove region, the superficial epithelial cells were roundish, while the basal ones were elongated. Such characteristic features were no longer observed when the disappearance of the groove was completed. Eight rugae were observed on the future hard palate of 14-day embryos with already completed palatal fusion. An additional ruga was frequently found in 15-day embryos, and the pattern then was almost the same as that of an adult. Epithelial thickening and condensation at the rugae region, as well as mesenchymal condensation under the epithelium of the rugae, were confirmed in embryos both before and after elevation of the palatal shelves. There is a possibility that these structural characteristics observed in the epithelial and mesenchymal cells of the rugae and groove regions may be related to palatal shelf elevation.

Tissue and species specific responsiveness of developing avian and murine secondary palates to prostaglandin E2 stimulation

The objective of this study was to determine the responsiveness of isolated embryonic murine and avian epithelial and mesenchymal tissue to PGE2 stimulation. On days 12 and 14 of gestation, murine palatal epithelium responded to PGE2 (10(-5) M) with 3.5 and 4.0 fold elevations in intracellular cAMP, respectively. On day 13 of gestation, murine palatal epithelium was responsive to forskolin, PGE1 and isoproterenol as indicated by the accumulation of cAMP, but unresponsive to PGE2 and PGF2 alpha less than treatment. Avian palatal epithelium and mesenchyme, developmental stages 31 to 34, as well as murine palatal mesenchyme on day 13 of gestation responded to PGE2 treatment with dose-dependent elevations in intracellular cAMP. Of importance, is the lack of responsiveness of murine palatal epithelium to PGE2 treatment on day 13 of gestation. This corresponds to the time of murine palatal medial edge epithelial differentiation. Lack of a PGE2 response may effect, initiate or occur as the result of murine medial edge epithelial differentiation.

Characteristics of growth and palatal shelf development in ICR mice after exposure to methylmercury

A single dose of 25 mg/kg methylmercuric chloride (MeHg) was given orally to gravid ICR mice. Cleft palate was induced in 100% of the offspring, with the critical treatment period ranging from day 10/8 hours (10/8) to 12/16 of gestation. Dose-dependent body weight reduction was observed in day 18 fetuses from both the day 10/8 and 12/16 groups. However, fetal weight reduction was greater in the day 12/16 group for all the MeHg treatments investigated. The relative potency of the induction of cleft palate by MeHg was slightly but significantly higher in the fetuses of the day 12/16 group (1.044-1.197-fold in 95% limits) than in the day 10/8 group. The results showed that when 25 mg/kg of MeHg was given to the fetuses in the day 10/8 group, palatal shelf growth was delayed at a more primitive stage than in the day 12/16 fetuses. Moreover, disharmony of development between the overall fetus and palatal shelf was noticed. Furthermore, in the day 12/16 fetuses, a delay of palatal shelf growth occurred just prior to shelf elevation. Prior to shelf elevation, coordination was probably lost in the development between the fetus and the palatal shelves. Normal palatal closure in ICR fetuses occurs about 1 day and 10 hours earlier (P less than 0.05) than in the A/J fetuses (Biddle, '80). Normal palatal shelves in ICR fetuses moved rapidly, with 3.0 to 5.7 hours (in 95% limits) required for all fetuses to achieve elevation, while, in MeHg-treated groups, palatal shelf elevation did not occur. The results suggest that the cause of the failure in palatal shelf elevation may be understood by examining the disharmonious development of the fetus after exposure to MeHg.

Histochemical localization of glycosaminoglycans during morphogenesis of the secondary palate in mice

The hydration of hyaluronic acid (HA) accumulated in the secondary palatal processes is expected to exert an intrinsic tissue pressure that could, in part, provide the impetus for shelf reorientation. Glycosaminoglycans were histochemically localized in the A/J mouse palate during development (days 12 to 15) by specific enzymatic degradation followed by preferential staining with alcian blue under differential pH or MgCl2 concentration. The presence of HA and chondroitin sulphates A and C (CS) was demonstrated in proportions that differed regionally. At the time of reorientation (days 14 to 15) HA was the predominant staining component, being distributed according to the relative prominence of extracellular spaces (ECS). HA was present in higher concentration in the anterior than the posterior part of the palate, particularly in an area of low cell density adjoining the CS-rich mesenchyme of the maxillary process. This arrangement suggests that the maxillary process might provide a resilient incompressible structural base for the palate as its HA-rich ECS expands. Sulphated GAG, with CS being the predominant component, was localized for the most part on the oral-side mesenchyme both in the anterior and posterior palate. The most intense staining of sulphated proteoglycans occurred in association with the basal lamina along the presumptive oral-side. Mesenchymal cells along this region appeared condensed and may have been stabilized by these sulphated GAG providing structural constraints which might function in palate morphogenesis.

Changes in cell distribution during mouse secondary palate closure in vivo and in vitro. I. Epithelial cells

The distribution of epithelial cells around the perimeter of mouse secondary palatal shelves was observed before and after shelf reorientation in vivo and in vitro. Changes in shelf perimeter, cells per micrometer, and cell layering were measured for each of three shelf regions: anterior and posterior presumptive hard and presumptive soft palate at developmental stages which were 30, 24, and 18 hr prior to expected in vivo elevation, after in vivo elevation, and during the course of in vitro elevation. Pronounced increases in numerical cell density and cell layering accompanying shelf reorientation were noted in the superior nasal and mid-oral portions of the shelf perimeter in all three shelf regions with greatest changes noted in the posterior hard palate region. These changes were not attributable to cell division or to perimeter changes. The localized nature of the changes in cell distribution suggest that the underlying mechanisms may also be localized.

Involvement of GABA in palate morphogenesis and its relation to diazepam teratogenesis in two mouse strains

Previous studies have indicated that serotonin and acetylcholine stimulate palate shelf reorientation. The present studies were undertaken to determine whether gamma-aminobutyric acid (GABA) functions as an inhibitory neurotransmitter in the palate and whether diazepam mimics GABA to inhibit shelf reorientation and cause cleft palate. First, it was shown that 10(-4) M GABA inhibits palate shelf reorientation in day 14.5 AJ embryos cultured for 2 hours. Anterior palate reorientation stimulated by 10(-5) M serotonin was decreased by GABA; 10(-5) M picrotoxin (GABA antagonist) stimulated anterior shelf reorientation and reversed the effect of GABA. Diazepam (10(-4) M) partially inhibited palate shelf reorientation and that stimulated by 10(-5) M serotonin. Diazepam (400 mg/kg) was administered to AJ mice at day 13.5 of gestation and embryos were cultured at day 14.5. The inhibition produced by diazepam was significantly reduced by 10(-5) M picrotoxin. The teratogenic effect of diazepam was compared with AJ and Swiss-Webster Vancouver (SWV) inbred strains. Diazepam produced greater clefting in SWV mice (57% net) than in the AJ (18% net) when compared to their water- and food-starved controls. The greater sensitivity of the SWV strain than the AJ strain to diazepam, as well as to GABA, was also observed in embryo culture. GABA (10(-5) M) markedly inhibited posterior palate reorientation and reversed the stimulation produced by bethanechol in SWV mice. The inhibitory effects of GABA on the posterior palate were partially reversed by picrotoxin. Furthermore, diazepam inhibited palate reorientation either when administered to the pregnant dam or added in embryo culture.(ABSTRACT TRUNCATED AT 250 WORDS)

Developmental mechanisms in normal and abnormal palate formation with particular reference to the aetiology, pathogenesis and prevention of cleft palate

Palatal development was studied macroscopically, microscopically and ultrastructurally in foetuses of inbred Wistar rats and Alligator mississippiensis. In the rat, elevation of the palatal shelves from a vertical position lateral to the tongue to a horizontal position above the tongue, occurs very rapidly. This reorientation is postulated to be caused by an intrinsic turgor shelf force generated by the hydration of mesenchymal mucopolysaccharides (predominantly hyaluronic acid). Cleft palate was induced in rat foetuses using 5-fluoro-2-desoxyuridine and was associated with greatly decreased mucopolysaccharide synthesis. The alligator is the only animal which develops in an external egg and which possesses a true mammal-like secondary palate: it is therefore a useful animal model system because longitudinal studies and direct surgical and pharmacological manipulations can be performed. The palatal shelves of alligators grow horizontally above the dorsum of the tongue from their first appearance. This de novo horizontal shelf growth is associated with an increase amount of space in the alligator oronasal cavity due to the small, fatty, alligator tongue. It is postulated that the evolution of the large muscular mammalian tongue constrains the palatal shelves to grow vertically until sufficient space can be created to form the common nasal passage simultaneous with shelf elevation.

Palate morphogenesis. I. Immunological and ultrastructural analyses of mouse palate

Midpalate was analyzed for the presence of nonmuscle contractile systems. The results indicate that increased amounts of actin and myosin are present in cells of regions 2 and 3. A localization of the contractile proteins in cellular projections (filopodia) and in the peripheral cytoplasm of the cell body was confirmed by indirect immunofluorescence studies, using antibodies directed against smooth muscle myosin and against skeletal muscle actin. Specificity of the immunofluorescence reactions was ascertained by immunoabsorption studies using purified myosin and actin. Electron microscopic observations of the mesenchymal cells in region 2 revealed 70A microfilaments along the cell periphery and packed in fliopodia-like projections which course between the cells. These cells, which surround a small ossification center, show no orientation, but extend up to the cranial base perichondrium and down into the shelf between the tongue side epithelium and the ossification center. The cells and projections are attached to each other by adherens and tight-like junctions, forming a putative cohesive contractile network. Putative contractile cells in region 3 are strikingly aligned perpendicular to the oral epithelium and extend one-third of the distance into the shelf. Projections from region 3 cells are contiguous with basement membrane material of the oral epithelium. Axonal bundles and single axons were commonly observed coursing through regions 2 and 3, often seen in close association with the mesenchymal cells. Both clear and dense-core vesicles were found in the axons and cells of these regions. The possible role of these putative nonmuscle contractile cells in palate morphogenesis is discussed.

Palate morphogenesis: II. Contraction of cytoplasmic processes in ATP-induced palate rotation in glycerinated mouse heads

It has been previously shown that non-muscle contractile system(s) exist in mouse palate mesenchyme underlying the palatal epithelium before shelf rotation. In order to obtain evidence that the non-muscle contractile system(s) function to elevate the palate, glycerinated heads have been incubated with ATP. It was shown that 5 mM ATP and a 30 min incubation at 25 degrees C stimulated palate rotation optimally. Elevation of the anterior end of the palate was nearly complete (PSI = 3.90, p less than 10(-6)). Although rotation of the posterior end was significant (p less than 0.02), movement was limited (PSI = 1.70). Light microscopy of the palate revealed that ATP caused a marked condensation of the cytoplasmic processes of the mesenchymal cells. The contraction of the processes of the mesenchymal cells induced by ATP increased roughly with increased palate shelf rotation and was greater at the peripheral than at the internal mesenchyme. Cytochalasin B pretreatment at 40 microM completely blocked the ATP-induced rotation at the anterior end. The effect of other nucleotides on palate rotation was tested. GTP caused a significant stimulation of anterior shelf rotation (p less than 0.005), which was less than ATP, while ADP and CTP were ineffective. Low temperature (6 degrees C) prevented the ATP-induced shelf rotation. These results suggest that the non-muscle contractile cells in the mesenchyme play a role in palate elevation and that contraction of the actomyosin containing microfilaments supplies the motive force.