Serotonin as a regulator of craniofacial morphogenesis: site specific malformations following exposure to serotonin uptake inhibitors.

During craniofacial development in the mouse embryo (days 9-12 of gestation; plug day = day 1), transient expression of serotonin (5-HT) uptake in epithelial structures of this region correlates with critical morphogenetic events (Lauder et al., '88; Shuey, '91; Shuey et al., '89, '92). The purpose of the present investigation was to assess the possible functional significance of these uptake sites by examination of patterns of dysmorphology following exposure of embryos to selective 5-HT uptake inhibitors. Exposure of mouse embryos in whole embryo culture to sertraline, at a concentration (10 microM) which produced no evidence of general embryotoxicity, caused craniofacial malformations consistent with direct action at 5-HT uptake sites. Two other 5-HT uptake inhibitors, fluoxetine and amitriptyline, produced similar defects. The critical period of sertraline exposure occurred on days 10-11. The observed craniofacial defects were associated with decreased proliferation and extensive cell death in mesenchyme located 5-6 cell layers deep from the overlying epithelium. In contrast, the subepithelial mesenchymal layers showed normal or elevated levels of proliferation. From these results it appears that inhibition of 5-HT uptake into craniofacial epithelia may produce developmental defects by interference with serotonergic regulation of epithelial-mesenchymal interactions important for normal craniofacial morphogenesis.     

Sites of serotonin uptake in epithelia of the developing mouse palate, oral cavity, and face: possible role in morphogenesis

With the method of whole mouse embryo culture, together with immunocytochemistry with an antiserum to serotonin (5-HT), sites of 5-HT uptake were found to be transiently expressed in the epithelia of the developing palate, tongue, nasal septum, and maxillary and mandibular prominences during the period of active morphogenesis (embryonic days 12-14; or E12-14). These sites had the ability to take up 5-HT when added to the culture medium in the presence of the MAO inhibitor nialamide and an antioxiant, L-cysteine (NC), and could also be seen after exposure of embryos to the 5-HT precursor L-tryptophan (L-TRP) + NC. These sites were also visible after culturing embryos without any additives, which may have been due to the presence of L-TRP in one component of the culture medium (DMEM) or to 5-HT itself, which is present in relatively high amounts in fetal calf serum. At E12-13, the appearance of 5-HT immunoreactivity (IR) at these sites after treatment with 5-HT + NC was blocked by the 5-HT uptake inhibitor fluoxetine, providing further evidence that these are true sites of 5-HT uptake. However, fluoxetine did not completely block the appearance of these sites in E14 embryos after 5-HT + NC or L-TRP + NC although it was effective with NC alone. This finding could mean that at E14 5-HT uptake into these sites occurs by mechanisms not completely blocked by fluoxetine or that there is some limited capacity for 5-HT synthesis. Taken together with results from previous studies where 1) 5-HT has been reported to stimulate palatal shelf reorientation and palatal mesenchyme cell motility in vitro [Wee et al., J Embryol Exp Morphol 53:75-90, 1979; Zimmerman et al., J Craniofac Genet Dev Biol 3:371-385, 1983] and 2) long-term culturing of mouse embryos in the presence of 5-HT or fluoxetine has been shown to cause malformations of the craniofacial region (Lauder, Thomas, and Sadler, in preparation), the results of the present study suggest that 5-HT could act as a developmental signal in the palate, oral cavity, and face during the period of active morphogenesis.     

Analysis of distribution patterns of gap junctions during development of embryonic chick facial primordia and brain.

Gap junction distribution in the facial primordia of chick embryos at the time of primary palate formation was studied employing indirect immunofluorescence localization with antibodies to gap junction proteins initially identified in rat liver (27 x 10(3) Mr, connexin 32) and heart (43 x 10(3) Mr, connexin 43). Immunolocalization with antibodies to the rat liver gap junction protein (27 x 10(3) Mr) demonstrated a ubiquitous and uniform distribution in all regions of the epithelium and mesenchyme except the nasal placode. In the placodal epithelium, a unique non-random distribution was found characterized by two zones: a very heavy concentration of signal in the superficial layer of cells adjacent to the exterior surface and a region devoid of detectable signal in the interior cell layer adjacent to the mesenchyme. This pattern was seen during all stages of placode invagination that were examined. The separation of gap junctions in distinct cell layers was unique to the nasal placode, and was not found in any other region of the developing primary palate. One other tissue was found that exhibited this pattern-the developing neural epithelium of the brain and retina. These observations suggest the presence of region-specific signaling mechanisms and, possibly, an impedance of cell communication among subpopulations of cells in these structures at critical stages of development. Immunolocalization with antibodies to the 'heart' 43 x 10(3) Mr gap junction protein also revealed the presence of gap junction protein in facial primordia and neural epithelium. A non-uniform distribution of immunoreactivity was also observed for connexin 43.     

IGFBP5 is a potential regulator of craniofacial skeletogenesis

Six known proteins bind to the insulin-like growth factor (IGF) with high affinity. Igfbp5 encodes one of these proteins, which regulates the activity of IGF, but also exerts IGF-independent actions. Using in situ hybridization to detect cells expressing Igfbp5 mRNA, we show that Igfbp5 is expressed in a dynamic pattern in the mouse embryonic craniofacial region. At early stages corresponding to the completion of neural crest migration, Igfbp5 mRNA was found predominantly in the epithelia, whereas when the craniofacial mesenchyme has begun its differentiation into skeletal tissue, Igfbp5-expressing cells surrounded the developing cartilages and bones. Embryos transgenically expressing Igfbp5 in restricted areas of the mesenchyme fated to form craniofacial bones revealed decreased ossification and even deletion of head bones areas. Transgenic expression of a mutant Igfbp5, encoding a product with reduced binding affinity for IGF, led to no skeletal abnormalities, suggesting that the observed negative effects on skeletal development rely on a mechanism that depends on binding to IGF.     

Embryonic development of Python sebae - II: Craniofacial microscopic anatomy, cell proliferation and apoptosis

This study explores the microscopic craniofacial morphogenesis of the oviparous African rock python (Python sebae) spanning the first two-thirds of the post-oviposition period. At the time of laying, the python embryo consists of largely undifferentiated mesenchyme and epithelium with the exception of the cranial base and trabeculae cranii, which are undergoing chondrogenesis. The facial prominences are well defined and are at a late stage, close to the time when lip fusion begins. Later (11-12d), specializations in the epithelia begin to differentiate (vomeronasal and olfactory epithelia, teeth). Dental development in snakes is different from that of mammals in several aspects including an extended dental lamina with the capacity to form 4 sets of generational teeth. In addition, the ophidian olfactory system is very different from the mammalian. There is a large vomeronasal organ, a nasal cavity proper and an extraconchal space. All of these areas are lined with a greatly expanded olfactory epithelium. Intramembranous bone differentiation is taking place at stage 3 with some bones already ossifying whereas most are only represented as mesenchymal condensations. In addition to routine histological staining, PCNA immunohistochemistry reveals relatively higher levels of proliferation in the extending dental laminae, in osseous mesenchymal condensations and in the olfactory epithelia. Areas undergoing apoptosis were noted in the enamel organs of the teeth and osseous mesenchymal condensations. We propose that localized apoptosis helps to divide a single condensation into multiple ossification centres and this is a mechanism whereby novel morphology can be selected in response to evolutionary pressures. Several additional differences in head morphology between snakes and other amniotes were noted including a palatal groove separating the inner and outer row of teeth in the upper jaw, a tracheal opening within the tongue and a pharyngeal adhesion that closes off the pharynx from the oral cavity between stages 1 and 4. Our studies on these and other differences in the python will provide valuable insights into in developmental, molecular and evolutionary mechanisms of patterning.     

The vomeronasal organ and associated structures of the fetal African elephant, Loxodonta africana (Proboscidea, Elephantidae)

The vomeronasal organ (VNO) is a chemosensory structure of the nasal septum found in most tetrapods. Although potential behavioural correlates of VNO function have been shown in two of the three elephant species, its morphology in Loxodonta africana has not been studied. The development of the VNO and its associated structures in the African elephant are described in detail using serially sectioned material from fetal stages. The results show that many components of the VNO complex (e.g. neuroepithelium, receptor‐free epithelium, vomeronasal nerve, paravomeronasal ganglia, blood vessels, vomeronasal cartilage) are well developed even in a 154‐day‐old fetus, in which the VNO opens directly into the oral cavity with only a minute duct present. However, the vomeronasal glands and their ducts associated with the VNO were developed only in the 210‐day‐old fetus. Notably, in this fetus, the vomeronasal–nasopalatine duct system had acquired a pathway similar to that described in the adult Asian elephant; the VNOs open into the oral cavity via the large palatal parts of the nasopalatine ducts, which are lined by a stratified squamous epithelium. The paired palatal ducts initially coursed anteriorly at an angle of 45° from the oral recess and/or the oral cavity mucosa, and merged into the vomeronasal duct. This study confirms the unique characteristics of the elephant VNO, such as its large size, the folded epithelium of the VNO tube, and the dorsomedial position of the neuroepithelium. The palatal position and exclusive communication of the VNO with the oral cavity, as well as the partial reduction of the nasopalatine duct, might be related to the unique elephantid craniofacial morphogenesis, especially the enormous growth of the tusk region, and can be seen as autapomorphies.     

Shh and Fgf8 act synergistically to drive cartilage outgrowth during cranial development

Much of the skeleton and connective tissue of the vertebrate head is derived from cranial neural crest. During development, cranial neural crest cells migrate from the dorsal neural tube to populate the forming face and pharyngeal arches. Fgf8 and Shh, signaling molecules known to be important for craniofacial development, are expressed in distinct domains in the developing face. Specifically, in chick embryos these molecules are expressed in adjacent but non-overlapping patterns in the epithelium covering crest-derived mesenchyme that will give rise to the skeletal projections of the upper and lower beaks. It has been suggested that these molecules play important roles in patterning the developing face. Here, we directly examine the ability of FGF8 and SHH signaling, singly and in combination, to regulate cranial skeletogenesis, both in vitro and in vivo. We find that SHH and FGF8 have strong synergistic effects on chondrogenesis in vitro and are sufficient to promote outgrowth and chondrogenesis in vivo, suggesting a very specific role for these molecules in producing the elongated beak structures during chick facial development.     

Role of transforming growth factor-beta in the development of the mouse embryo

Using immunohistochemical methods, we have investigated the role of transforming growth factor-beta (TGF-beta) in the development of the mouse embryo. For detection of TGF-beta in 11-18-d-old embryos, we have used a polyclonal antibody specific for TGF-beta type 1 and the peroxidase-antiperoxidase technique. Staining of TGF-beta is closely associated with mesenchyme per se or with tissues derived from mesenchyme, such as connective tissue, cartilage, and bone. TGF-beta is conspicuous in tissues derived from neural crest mesenchyme, such as the palate, larynx, facial mesenchyme, nasal sinuses, meninges, and teeth. Staining of all of these tissues is greatest during periods of morphogenesis. In many instances, intense staining is seen in mesenchyme when critical interactions with adjacent epithelium occur, as in the development of hair follicles, teeth, and the submandibular gland. Marked staining is also seen when remodeling of mesenchyme or mesoderm occurs, as during formation of digits from limb buds, formation of the palate, and formation of the heart valves. The presence of TGF-beta is often coupled with pronounced angiogenic activity. The histochemical results are discussed in terms of the known biochemical actions of TGF-beta, especially its ability to control both synthesis and degradation of both structural and adhesion molecules of the extracellular matrix.     

Immunohistochemical localization of prostaglandins E and F2 alpha in the developing murine palate

Prostaglandins E2 and F2 alpha (PGE2 and PGF2 alpha) have been shown to cause changes in adenosine 3',5'-cyclic monophosphate (cAMP) levels in a wide variety of tissues. In particular, murine palatal mesenchyme responds to PGE2 stimulation with dose-dependent increases in intracellular cAMP levels. These same mesenchymal cells also synthesize PGE2 and PGF2 alpha. The purpose of this study is to localize PGE and PGF2 alpha in the developing murine palate by using immunohistochemical techniques. Fresh frozen cryostat sections of murine C57BL/6J embryo palates (days 12-14 of gestation) were incubated with anti-PGE or PGF2 alpha monoclonal antibodies. On day 12 of gestation, PGE and PGF2 alpha, identified as 3',3-diaminobenzidine (DAB) reaction products, were localized throughout palatal mesenchyme and epithelium; on day 13 of gestation, reaction product indicative of both PGE and PGF2 alpha was detectable primarily in mesenchyme subjacent to palatal epithelium. Extracellular spaces of the adjacent mesenchyme in the central region of the day 13 palate exhibited less reaction product. Palatal epithelium, particularly the medial edge epithelium, exhibited a diminished amount of reaction product for both prostaglandins on day 13 as compared to the underlying mesenchyme. After formation of a midline epithelial seam between homologous palatal processes on day 14 of gestation, medial edge, oral, and nasal epithelium exhibited light staining for PGE or PGF2 alpha. Palate mesenchymal cells subjacent to the midline seam exhibited a diminished amount of reaction product for both PGE and PGF2 alpha as compared to day 13 of gestation. Overall, the results show local and temporal changes in the distribution of prostaglandins in the developing murine palate.     

Anatomical structure and surface epithelial distribution in the nasal cavity of the common cotton-eared marmoset (Callithrix jacchus).

To validate use of the common cotton-eared marmoset (Callithrix jacchus) in inhalation toxicity studies, its nasal morphology was examined. The nasal turbinates each consisted of one maxilloturbinate and one ethmoturbinate: these were more planar in structure than the comparable structures of rodents or dogs. The nasal cavity epithelia comprised squamous epithelium (SE), nasal transitional epithelium (NTE), respiratory epithelium (RE) and olfactory epithelium (OE), listed in order of occurrence from anterior to posterior positions. NTE was distributed as a narrow band lying between SE and RE. OE was limited to the dorsal part of the cavity, which was structurally similar to that of the macaque or man. Overall, this study revealed structural the similarity of the whole nasal cavity in the marmoset to that of macaques or humans. Prediction of nasal cavity changes in man based on extrapolation from experimentally induced changes in the common marmoset therefore seems likely to be feasible, making it a useful animal model for inhalation studies.     

Cell-adhesion molecule uvomorulin during kidney development

We studied the expression of a cell adhesion molecule during morphogenesis of the embryonic kidney. The 120-kDa glycoprotein, called uvomorulin, is known to be present on a number of epithelia. During the development of the kidney, a mesenchyme is converted into an epithelium when it is properly induced. The uninduced mesenchyme did not express uvomorulin, as judged by immunofluorescence and immunoblotting using previously characterized antibodies. Uvomorulin does not appear in the mesenchyme as a direct consequence of induction. Rather it becomes detectable approximately 12 hr after completion of induction, at 30-36 hr in vitro when the cells adhere to each other. Distinct differences in uvomorulin expression were seen in the different parts of the nephron. In the mesenchymally derived epithelia (glomeruli, tubules), uvomorulin could be detected only in the tubules, whereas the epithelium of the glomeruli remained negative at all stages of development. Our embryonic studies show that these differences arise very early, as soon as the different parts of the nephron can be distinguished morphologically. It is likely that uvomorulin plays a role in the initial adhesion of the differentiating tubule cells. However, we failed to disrupt histogenesis by applying antibodies to the organ cultures of developing tubules although the antibodies penetrated the tissues well and bound to the differentiating cells.     

Cell movements and control of patterned tissue assembly during craniofacial development.

Craniofacial mesenchyme is heterogeneous with respect to origins (e.g., paraxial mesoderm, lateral mesoderm, prechordal mesoderm, neural crest, placodes) and fates. The many disparate cell migratory behaviors exhibited by these mesenchymal populations have only recently been revealed, necessitating a reappraisal of how these different populations come together to form specific tissues and organs. The objectives of this review are to characterize the diverse migratory behaviors of craniofacial mesenchymal subpopulations, to define the interactions necessary for their assembly into tissues, and to discuss these data in the context of recent discoveries concerning the molecular basis of craniofacial development. The application of antibodies that recognize features unique to migrating neural crest cells has verified the results of previous transplantation experiments in birds and shown the migratory pathways in murine embryos to be similar. Within paraxial or prechordal mesoderm arise myoblasts that are precursors of craniofacial voluntary muscles. These cells migrate, usually en masse, to the sites where overt muscle differentiation occurs. Whereas the initial alignment of primary myotubes presages the fiber orientation seen in the adult, the time at which individual myotubes appear relative to the formation of discrete, individual muscle bundles and attachments with connective tissues varies with each muscle. The pattern of primary myotube alignment is determined by local connective tissue-forming mesenchyme and is independent of the source of myoblasts. Also found within paraxial and lateral mesodermal tissues are endothelial precursors (angioblasts). Some of these aggregate in situ, forming vesicles that coalesce with ingrowing endothelial cords. Others are highly invasive, moving in all directions and infiltrating tissues such as the neural crest, which lacks endogenous angioblasts. The patterns of initial blood vessel formation in the head are also determined by local connective tissue-forming mesenchyme and are independent of the origin of endothelial cells. Neural crest cells, which constitute the predominant connective tissue-forming mesenchyme in the facial, oral, and branchial regions of the head, acquire a regional identity while still part of the neural epithelium, and carry this with them as they move into the mandibular, hyoid, and branchial arches. Some of these regionally unique propensities correspond spatially to genetic and cellular patterns unique to rhombomeres, although the links between gene expression and crest population phenotypes are not yet known. In contrast, the inherent spatial programming of those crest cells that populate the maxillary and frontonasal regions is altered by their proximity to the prosencephalon.     

Aquaporins in complex tissues. II. Subcellular distribution in respiratory and glandular tissues of rat

The molecular pathways for fluid transport in pulmonary, oral,and nasal tissues are still unresolved. Here we use immunocytochemistry and immunoelectron microscopy to define the sites of expression of fouraquaporins in the respiratory tract and glandular epithelia, where theyreside in distinct, nonoverlapping sites. Aquaporin-1 (AQP1) is presentin apical and basolateral membranes of bronchial, tracheal, andnasopharyngeal vascular endothelium and fibroblasts. AQP5 is localizedto the apical plasma membrane of type I pneumocytes and the apicalplasma membranes of secretory epithelium in upper airway and salivaryglands. In contrast, AQP3 is present in basal cells of tracheal andnasopharyngeal epithelium and is abundant in basolateral membranes ofsurface epithelial cells of nasal conchus. AQP4 resides in basolateralmembranes of columnar cells of bronchial, tracheal, and nasopharyngealepithelium; in nasal conchus AQP4 is restricted to basolateralmembranes of a subset of intra- and subepithelial glands. These sitesof expression suggest that transalveolar water movement, modulation ofairway surface liquid, air humidification, and generation ofnasopharyngeal secretions involve a coordinated network of aquaporinwater channels.

     

Formation and distribution of neural crest mesenchyme to the first pharyngeal arch region of the mouse embryo

Murine neural crest mesenchyme begins its escape from columnar epithelium near the tips of the midbrain-rostral hindbrain neural folds at 4+ to 5 somites of age. At that time the tip of each fold is located dorsolateral to the pharynx. Once crest formation is complete at this earliest site, it leaves behind both crest mesenchyme and overlying squamous epithelium. Crest formation then progresses medially, into the lateral margin of the neural plate. At the same time, this lateral margin elevates as the tip of the neural fold. By the time crest formation ceases at approximately 10 somites, the result of these simultaneous activities is to passively distribute the earliest mesenchyme, formed from the lateralmost epithelium, dorsolateral to the pharynx and the later, more medially derived mesenchyme lateral to the neural tube. Once formed, the crest mesenchyme dorsolateral to the pharynx is displaced ventromedially in a narrow, transient subectodermal space functionally similar to that observed in the chick embryo. Displacement might result from cell motility or the formation of matrix-filled spaces between cells of the mesenchyme. Displaced cells are closely associated with the overlying columnar epithelium. This association precedes their subsequent induction and may reflect preliminary patterning. The crest mesenchyme passively distributed lateral to the neural tube is subsequently displaced medially. Here the formation of enlarged (matrix-filled?) spaces is clearly involved in the initial displacement. Displaced cells proliferate to form the anlage of the trigeminal ganglion. The other major contributor to this ganglion is the trigeminal placode. The placodal epithelium is located dorsolateral to the pharynx of the 12-somite embryo. If the epithelia of the head maintain their relative positions, this placode is derived from the squamous epithelium formed together with the earliest crest mesenchyme. If not, an alternative source is the columnar epithelium located ventromedial to the tip of the 4+- to 5-somite neural fold.     

Expression of Sprouty genes 1, 2 and 4 during mouse organogenesis.

We demonstrate that Sprouty genes 1, 2 and 4 are expressed in several developing organs of the craniofacial area and trunk, including the brain, cochlea, nasal organs, teeth, salivary gland, lungs, digestive tract, kidneys and limb buds. In organs such as the semicircular canal, Rathke's pouch, nasal organs, the follicle of vibrissae and teeth, Sprouty1 and Sprouty2 are expressed in the epithelium and Sprouty4 in the mesenchyme or neuronal tissue, while in the lung Sprouties1, 2 and 4 are all expressed mainly in the epithelial tissue. In the kidney, Sprouty1 is prominent in the ureteric bud whereas Sprouty2 and 4 are expressed in both the ureteric bud and the kidney mesenchyme and glomeruli deriving from it. The expression profiles suggest roles for these Sprouties in the epithelial-mesenchymal interactions that govern organogenesis.     

A novel population of neuronal cells expressing the olfactory marker protein (OMP) in the anterior/dorsal region of the nasal cavity

The olfactory marker protein (OMP) is expressed in mature chemosensory neurons in the nasal neuroepithelium. Here, we report the identification of a novel population of OMP-expressing neurons located bilaterally in the anterior/dorsal region of each nasal cavity at the septum. These cells are clearly separated from the regio olfactoria, harboring the olfactory sensory neurons. During mouse development, the arrangement of the anterior OMP-cells undergoes considerable change. They appear at about stage E13 and are localized in the nasal epithelium during early stages; by epithelial budding, ganglion-shaped clusters are formed in the mesenchyme during the perinatal phase, and a filiform layer directly underneath the nasal epithelium is established in adults. The anterior OMP-cells extend long axonal processes which form bundles and project towards the brain. The data suggest that the newly discovered group of OMP-cells in the anterior region of the nasal cavity may serve a distinct sensory function.     

Identification of respiratory and ion-transporting epithelia in the phyllosoma larvae of the slipper lobster Scyllarus arctus

Phyllosoma larvae of the Palinura lack a branchial cavity and gills. In the phyllosoma, gas and ion exchanges that occur at the level of the gill in the adult must occur in other parts of the body or through the entire body. The objective of this study was to localize epithelia bordering the body of the phyllosoma larvae that had features comparable to those of the gill epithelia of adult decapods. The first phyllosoma instar of the small Mediterranean slipper lobster Scyllarus arctus was studied. First, we used a silver nitrate staining method to identify parts of the body with high ionic permeability. Confocal laser scanning microscopy with a fluorescent vital stain for mitochondria, dimethylaminostyrylmethylpyridiniumiodine (DASPMI), was then used to localize cells with a high density of mitochondria. Next, an ultrastructural study of selected epithelia was carried out. A thick (5 microns) mitochondria-rich epithelium covers the ventral side of the cephalic shield; its cells are characterized by the presence of well-developed apical infoldings adjacent to the cuticle. This part of the body has a high ionic permeability as indicated by a positive silver nitrate staining. The ventral mitochondria-rich epithelium might be involved in active ion transport. The rest of the body, particularly the dorsal side of the shield and the appendages, shows a lower ionic permeability (no positive silver nitrate staining) and is limited by a thin (1 micron) epithelium with low numbers of mitochondria. This epithelium exhibits features of a typical respiratory epithelium.     

Regionalisation of early head ectoderm is regulated by endoderm and prepatterns the orofacial epithelium

The oral epithelium becomes regionalised proximodistally early in development, and this is reflected by the spatial expression of signalling molecules such as Fgf8 and Bmp4. This regionalisation is responsible for regulating the spatial expression of genes in the underlying mesenchyme. These genes are required for the spatial patterning of bone, cartilage orofacial development and, in mammals, teeth. The mechanism and timing of this important regionalisation during head epithelium development are not known. Using lipophilic dyes to fate map the oral epithelium in chick embryos, we show that the cells that will occupy the epithelium of the distal and the proximal mandible primordium already occupy different spatial locations in the developing head ectoderm prior to the formation of the first pharyngeal arch and neural crest migration. Moreover, the ectoderm cells fated to become proximal oral epithelium express Fgf8 and this expression requires the presence of endoderm. Thus, the first fundamental patterning process in jaw morphogenesis is controlled by the early separation of specific areas of ectoderm that are regulated by ectoderm-endoderm interactions, and does not involve neural crest cells.