Murine tongue muscle displays a distinct developmental profile of MRF and contractile gene expression

Few studies have addressed the molecular differences that exist between muscles of the body and those of the craniofacial apparatus. In this study, we characterize the molecular events associated with determination and differentiation of the tongue musculature. We assess the expression of myogenic regulatory factors as well as the developmentally regulated myosin heavy chain, (MHC), genes which serve as markers of differentiation. These results suggest that tongue and limb muscle form by distinct molecular pathways. The myoblasts that contribute to the formation of the tongue preferentially express Myf-5 during myoblast determination rather than MyoD. Subsequently, isolated regions of myogenin expression mark the differentiation of first, the small primary myofibers and later, the larger secondary myofibers. Analysis of differentiation markers demonstrates that the tongue muscle also assumes a unique profile of MHC expression as compared to that of the muscles of the body. Unlike the myoblasts of the developing limb, which express embryonic and neonatal forms of MHC and later express MHC-slow, the tongue myoblasts co-express MHC-embryonic, MHC-slow and MHC-fast isoforms from gestational age E12. Proteins for MHC embryonic and MHC fast isoforms are detected almost simultaneously. Interestingly, MHC-slow transcripts do not appear to be translated into a detectable MHC slow protein at any developmental stage assayed. These results provide further evidence to suggest that skeletal tongue muscle represents a myoblast lineage that develops differently than the limb.

Migration of hypoglossal myoblast precursors

The intrinsic hypoglossal musculature develops from precursor myoblasts which undergo long-range migration from the occipital somites to the tongue. Little detail is known about the precise spatiotemporal pathway taken by these cells or the factors controlling migration. In this study, chick/quail chimeras in which the occipital paraxial mesoderm is quail derived, reveal that the pathway taken by the tongue muscle progenitors is both complex and highly specific. Precursor myoblasts are Pax-3 positive cells which descend from the somite and migrate around the pharyngeal endoderm. They then course rostrally, following the base of the pharynx, remaining in a tight strand. We have examined a number of factors implicated in the control of migration of the hypoglossal precursors. Replacement of the occipital somites with those originating in the flank reveals that intrinsic differences do not exist between these somites with respect to their capacity to respond to migratory cues. The lack of high level HGF/SF expression along the pathway of the migrating hypoglossal precursors suggests that this factor is not involved in the actual process of migration of the hypoglossal precursors to the tongue. The pathway followed by the migrating precursors is identical to that of both the developing hypoglossal nerve and the circumpharyngeal crest--a subpopulation of the cranial neural crest, and importantly these populations utilize this pathway before the myoblast precursors. However, ablation neither of the hypoglossal nerve nor of the neural crest results in a perturbation in the ability of this Pax-3 positive population to migrate. This demonstrates that migration of the precursors is independent of both of these cell populations, and that it is controlled by the peripheral tissues.

Changes of the lingual epithelium in Ambystoma mexicanum

Changes in the lingual epithelium during ontogenesis and after induced metamorphosis in Ambystoma mexicanum are described as observed by light microscopy and scanning electron microscopy. The epithelium of the tongue is always multilayered in the larva as well as in the adult. It consists of a stratum germinativum with little differentiated basal cells and a stratum superficiale (superficial layer) with specialized superficial cells and goblet cells. Usually, there are more than two layers because of a stratum intermedium consisting of replacement cells. The apical cell membrane of the superficial cells is perforated by fine pores. Its most typical feature are microridges. Maturing superficial cells possess microvilli. Goblet cells occur in early larvae primarily in the centre of the tongue. They spread throughout the dorsal face of the tongue as their numbers increase during ontogenesis. The small apices of the goblet cells are intercalated in the wedges between the superficial cells. Leydig cells are not found on the larval tongue but on that of adults. Due to metamorphosis, the epithelium of the tongue changes. It is furrowed in its anterior part. The furrows house the openings of the lingual glands. The surface is further modulated by ridges which are densely coated by microvilli and which bear the taste buds. The villi of the tongue which lack extrusion pores show cilia and microvilli but lack microridges. The Leydig cells disappear during metamorphosis. In addition to the two types of goblet cells found in different regions of the glandular tubules, goblet cells occur in the caudal part. They secrete directly into the cavity of the mouth. The posterior part is characterised by a dense coat of cilia.

Neurotrophic factors in the tongue: expression patterns, biological activity, relation to innervation and studies of neurotrophin knockout mice

How taste buds develop and how they become innervated has been a matter of debate for a long time. Brain-derived neurotropic factor (BDNF) and neurotrophin-3 (NT3) mRNA expression patterns suggested a possible involvement in lingual gustatory and somatosensory innervation. Studies of null-mutated mice showed that BDNF-/- mice had few abnormal taste buds and were unable to discriminate between primary tastes. NT3-/- mice had a severe loss of lingual somatosensory innervation. These novel findings may have clinical implications in rare human conditions such as familial dysautonomia and/or in more common cases of problems with loss of taste and sensation in the mouth such as those seen after injury to the nerves, either by accident or following oral/facial surgery. Knowledge about which proteins that are required to stimulate nerve fibers to grow into mucous membranes of the oral cavity during development suggests that these same proteins might become helpful in stimulating regeneration of injured nerves in patients, perhaps helping them to regain lost taste and sensory functions. Here, the presence of glial cell-derived neurotrophic factor (GDNF) families of neurotrophic factors and receptors in the tongue is also discussed. Further, a model for the development and innervation of taste buds in mammals is proposed.

Quantitative relationships between taste bud development and gustatory ganglion cells

To determine whether patterns of taste bud innervation change during postnatal rat development, the number of geniculate ganglion cells that innervate single taste buds were quantified in adult and developing rats. While there was a large variation in numbers of ganglion cells that innervate individual taste buds, there was a high degree of organization in the system. Namely, the number of labeled geniculate ganglion cells innervating a taste bud was highly correlated with the size of the taste bud. This relationship between taste bud size and number of innervating ganglion cells develops over a prolonged postnatal period and is not established until postnatal day 40 (P40), when taste buds reach their adult size. In a second series of experiments, we sought to determine whether neural rearrangement of chorda tympani neurons is responsible for the development of this relationship by double-labeling single taste buds at different ages. We found that the number of ganglion cells innervating individual taste buds on P10 predicts the size that taste buds become by P40. This finding suggests that neural rearrangement is not responsible for establishing the relationship between taste bud size and the number of innervating ganglion cells during development. More importantly, it strongly suggests that the 'neural template' for the mature innervation pattern is determined during early postnatal development.

Transforming growth factor alpha up-regulates desmin expression during embryonic mouse tongue myogenesis

Myogenesis is determined by a set of myogenic differentiation factors that are, in turn, regulated by a number of peptide growth factors. During embryonic mouse tongue formation, transforming growth factor alpha (TGF alpha), epidermal growth factor (EGF), and their cognate receptor (EGFR) are co-expressed spatially and temporally with desmin, a muscle-specific structural protein. This investigation tested the hypothesis that TGF alpha directly regulates the myogenic program in developing tongue myoblasts. Mandibular processes from the first branchial arch of embryonic day 10.5 (E10.5) mouse embryos were microdissected and explanted into an organ culture system using serumless chemically defined medium. Exogenous TGF alpha at 10 and 20 ng/ml specifically increased the amount of desmin expression and the number of desmin-positive cells without affecting the general growth and development of the mandibles. This inductive response was detected as early as 2 days after treatment and sustained up to 9 days in culture. EGFR antisense oligonucleotides (30 microM) as well as tyrphostin (80 microM) were able to negate TGF alpha-induced up-regulation of desmin expression. These data indicate that autocrine and/or paracrine action of TGF alpha promotes tongue myogenesis, and that this action is mediated through functional kinase activity of the EGFR. We speculate that the myogenic program in the developing mouse tongue is dependent upon growth factor mediated cell-cell communication of mesenchymal cells originating from the occipital somites and ectomesenchymal cells originating from the cranial neural crest.

Initial innervation of embryonic rat tongue and developing taste papillae: nerves follow distinctive and spatially restricted pathways

The rat tongue has an extensive, complex innervation from four cranial nerves. However, the precise developmental time course and spatial routes of these nerves into the embryonic tongue are not known, although this knowledge is crucial for studying mechanisms that regulate development and innervation of the lingual taste organs, gustatory papillae and resident taste buds. We determined the initial spatial course of nerves in the developing tongue and papillae, and tested the hypothesis that sensory nerves first innervate the tongue homogeneously and then retract to more densely innervate papillae and taste buds. Antibodies to GAP-43 and neurofilaments were used to label nerve fibers in rat embryo heads from gestational day 11 through 16 (E11-E16). Serial sagittal sections were traced and reconstructed to follow paths of each nerve. In E11 rat, geniculate, trigeminal and petrosal ganglia were labeled and fibers left the ganglia and extended toward respective branchial arches. At E13 when the developing tongue is still a set of tissue swellings, the combined chorda/lingual, hypoglossal and petrosal nerves approached the lingual swellings from separate positions. Only the chorda/lingual entered the tongue base at this stage. At E14 and E15, the well-developed tongue was innervated by all four cranial nerves. However, the nerves maintained distinctive entry points and relatively restricted mesenchymal territories within the tongue, and did not follow one another in common early pathways. Furthermore, the chorda/lingual and glossopharyngeal nerves did not set up an obvious prepattern for gustatory papilla development, but rather seemed attracted to developing papillae which became very densely innervated compared to surrounding epithelium at E15. To effect this dense papilla innervation, sensory nerves did not first innervate the tongue in a homogeneous manner with subsequent retraction and/or extensive redirection of fibers into the taste organs. Results contribute to a set of working principles for development of tongue innervation. Points of entry and initial neural pathways are restricted from time of tongue formation through morphogenesis, suggesting distinctive lingual territories for each nerve. Thus, sensory and motor nerves distribute independently of each other, and sensory innervation to anterior and posterior tongue remains discrete. For taste organ innervation, gustatory papillae are not induced by a prepatterned nerve distribution. In fact, papillae might attract dense sensory innervation because neither chorda/lingual nor glossopharyngeal nerve grows homogeneously to the lingual epithelium and then redistributes to individual papillae.

Expression of neuropsin in the keratinizing epithelial tissue-immunohistochemical analysis of wild-type and nude mice

Neuropsin is a trypsin-type serine protease that was first cloned from the mouse brain as a factor related to neural plasticity. Subsequent in situ hybridization histochemical analysis indicated a broad localization of its mRNA throughout the whole body, although the details remain obscure. In this study, we showed that neuropsin immunoreactivity is localized in the keratinized stratified epithelia of the mouse epidermis, hair, tongue, palate, nasal cavity, pharynges, esophagus, and forestomach. In the skin and mucous membranes, neuropsin immunoreactivity was found in the stratum spinosum and the stratum granulosum. The immunoreactivity in the former sublayer was mainly present in the cytoplasm, but that in the latter sublayer was exclusively present in the intercellular space or on the outer surface of the cell membrane and thus exhibited a lamellar-like peripheral distribution. During development, the appearance of neuropsin immunoreactivity in the various epithelia was found at embryonic days 14.5-15.5, prior to formation of the stratum corneum. More extensive expression of neuropsin immunoreactivity was found in the nude mouse skin and mucous membranes than in wild-type mice. Because the nude mouse is characterized by genetic impairment of keratinization, such abnormal neuropsin expression might be caused or affected by this impairment. Therefore, neuropsin, an extracellular serine protease, is suggested to be involved in keratinization in the stratified epithelia.

Transvaginal sonographic measurement of fetal lingual width in early pregnancy

Our objective was to construct a nomogram of the fetal lingual size early pregnancy and to assess the size of the tongue in abnormal fetuses. The lingual width was measured by using transvaginal ultrasonography in 80 normal fetuses at 13 and 18 weeks' gestation. In addition the tongue was measured in 22 fetuses at these gestational ages who had an abnormal karyotype or oro-facial malformations. A linear relationship was found between the lingual width and gestational age in normal fetuses. The lingual size was within the normal range in cases of trisomy 13, trisomy 21 and Turner syndrome. A small tongue was observed in fetuses with micrognathia. Correlation between lingual width and gestational age was observed in early pregnancy. The relationship between the size of the tongue and oro-facial malformation needs further evaluation.

Changes in neurotrophin-3 messenger RNA expression patterns in the prenatal rat tongue suggest guidance of developing somatosensory nerves to their final targets

While brain-derived neurotrophic factor (BDNF) messenger RNA (mRNA) has been localized in the developing gustatory epithelium, little information is available about neurotrophin-3 (NT-3) mRNA expression pattern in the prenatal developing gustatory and lingual epithelium. In the present study, using in situ hybridization histochemistry, we report on NT-3 mRNA expression in the tongue of rats. At embryonic day (E) 13-17, NT-3 mRNA was expressed subepithelially in the periphery of the developing tongue, as well as among developing muscle. At E19, there was a shift in the expression of NT-3 mRNA. It was then expressed in the surface epithelium of the developing tongue in the developing filiform papillae and, in higher concentrations, in top-surface and fringe epithelium of the developing circumvallate papillae, and top- and lateral-surface epithelium of the developing fungiform papillae. NT-3 mRNA expression in areas rich in somatosensory innervation of the tongue, as well as its specific expression in defined regions compared with BDNF, and the decreased labeling noted from prenatal and early postnatal animals to adults indicate a specific role for NT-3 in the development of lingual somatosensory innervation, as well as for maintenance of this innervation.

Cardiac and extracardiac expression of Csx/Nkx2.5 homeodomain protein

Csx/Nkx2.5 is an evolutionary conserved homeobox gene related to the Drosophila tinman gene, which is essential for the dorsal mesoderm formation. Expression of Csx/Nkx2.5 mRNA is the earliest marker for heart precursor cells in all vertebrates so far examined. Previous studies have demonstrated that Csx/Nkx2.5 mRNA is highly expressed in the heart and at lower levels in the spleen, tongue, stomach, and thyroid in the murine embryo. Since some developmental genes are regulated by posttranscriptional mechanisms, we analyzed the developmental pattern of Csx protein expression at the single-cell level using Csx-specific antibodies. Immunohistochemical analysis of murine embryos at 7.8 days post coitum revealed that Csx protein is strongly expressed in the nucleus of endodermal and mesodermal cells in the cardiogenic plate. Subsequently, in the heart, Csx protein was detected only in the nucleus of myocytes of the atrium and the ventricle through the adult stage. During the fetal period, Csx protein expression in the nucleus was also noted in the spleen, stomach, liver, tongue, and anterior larynx. Unexpectedly, confocal microscopy revealed that Csx immunoreactivity was detected only in the cytoplasm of a subset of cranial skeletal muscles. Csx protein was not detected in the thyroid glands. The expression of Csx protein in all organs was markedly downregulated after birth except in the heart. These results raise the possibility that Csx/Nkx2.5 may play a role in the early developmental process of multiple tissues in addition to its role in early heart development.

Induced expression of myoD, myogenin and desmin during myoblast differentiation in embryonic mouse tongue development

Significant progress has been made in defining mechanisms governing myogenesis at the transcriptional levels, but the extracellular signal-transduction pathways involved in myogenesis are not as yet defined. The developing mouse tongue provides a model for the regulation of myogenesis during precise time periods in embryogenesis. The molecular cues that regulate the close-range autocrine and/or paracrine signalling processes required for the fast-twitch complex tongue musculature are not known. This study was designed to test the hypothesis that transforming growth factor-alpha (TGF alpha) controls myogenesis in embryonic mouse tongue through the induction of myogenic regulatory factors such as myoD, myf5, myogenin and MRF4/myf6/herculin. To test this hypothesis, the effects of exogenous TGF alpha on the transcription of myoD, myf5, myogenin, MRF4 and desmin were examined in tongue samples from embryonic day-10.5 mandibular explants cultured in serum-free, chemically defined medium and then processed for competitive, reverse transcription-polymerase chain reaction. TGF alpha induced myoD, myogenin and desmin expression. Treatment with 20 and 40 ng/ml TGF alpha decreased or downregulated myf5 mRNA. MRF4 was not detected in the explants. TGF alpha apparently induces the early developmental stages of myogenesis through sequential upregulation of myoD and myogenin, downregulation of myf5 and corresponding significant increases in muscle-specific gene expression such as desmin transcription.

Innervation of developing human taste buds. An immunohistochemical study

Morphological changes in developing human gustatory papillae during the 6th to the 23rd postovulatory week have been studied. The general innervation pattern of taste papillae and taste bud primordia was revealed immunohistochemically using antibodies against protein gene product 9.5 (PGP9.5), neurofilament H (NFH), neurofilament L (NFL), neurone-specific enolase (NSE), and tubulin. The autonomic and somatosensory nerve supply has been investigated using antibodies against substance P (SP), calcitonin gene-related peptide (CGRP), tyrosine hydroxylase (TH), neuropeptide Y (NPY), the neuronal form of nitric oxide synthase (n-NOS), and, enzyme histochemically, NADPH-diaphorase. Nerve fibers approach the basal membrane of the lingual epithelium around the 7th postovulatory week and invade the epithelium of papilla-like structures at the 8th week, but some also penetrate the basal membrane of the non-papillary epithelium. They are in close contact with slender epithelial cells that are considered to be the taste bud's progenitor cells. Early human taste buds situated at the anterior part of the tongue do not necessarily require a dermal (later fungiform) papilla. The NADPH-diaphorase reaction revealed positive results in dermal nerve fibers, but the immunohistochemical reaction against n-NOS was negative. Immunohistochemical detection of neuropeptides and vasoactive substances rendered negative results for developmental stages of 7-18 postovulatory weeks. By the 18th week, only SP was detected in dermal papillae, but not in the vicinity of taste buds' primordia. Thus, autonomic and somatosensory nerves seem not to play a key role in formation and maintenance of early human taste buds.

Desmosomes are regulated by protein kinase C in primary rat epithelial cells

In the present study, we addressed the possible relevance of protein kinase C (PKC) in the regulation of intracytoplasmic desmosome assembly. Treatment of cultured rat lingual and epidermal keratinocytes with a potent and highly selective PKC inhibitor (GF109203X) induced an increase in granular labelling for major desmosomal proteins, desmoplakins, desmoglein and plakoglobin, both intracellularly and at the cell surface. This was associated with the formation of ultrastructurally recognizable desmosomes deep in the cytoplasm and increase in intercellular desmosome number. In contrast, PKC activation upon short exposure to 12-O-tetradecanoylphorbol 13-acetate (TPA) resulted in altered cell morphology, loss of intercellular contact and accumulation of desmosomal proteins in the juxtanuclear zone. On the other hand, PKC depletion by long term TPA treatment re-established cell-cell contact, where desmosomal markers were exclusively redistributed. Taken together, these results suggest that inhibition of PKC is required for intracytoplasmic as well as intercellular desmosome assembly, whereas its activation may regulate disassembly process.

A mouse mandibular culture model permits the study of neural crest cell migration and tooth development

A major issue in developmental biology is to determine how time and position-restricted instructions are signaled and received during morphogenesis of different phenotypes, of which tooth, Meckel's cartilage and tongue formation are classical examples. It is now evident that a hierarchy of growth factors and their downstream transcription factors regulate the timing, sequence and position of cells and tissues in forming different phenotypes during embryogenesis. Here we report the development of an early mandibular organ culture model. Explants of E8 and E9 first branchial arch were cultured and produced mandibular processes with cap stage tooth formation, Meckel's cartilage and tongue development. In tandem, vital dye (Dil) labeling studies confirmed that rhombomeres 1-4 give rise to craneal neural crest (CNC) cells which emigrate from the neural fold to the forming maxillary and mandibular arches. Furthermore, we have tested the feasibility of investigating the regulation of different phenotypes within the first branchial arch by a transcription factor using this early mandibular organ culture model. Lymphoid enhancing factor 1 (Lef1), a transcription factor, has been implicated to regulate tooth formation in vivo. We have analyzed the expression of Lef1 and studied the biological effects of Lef1 on E8 embryonic mouse first branchial arch explants in organ culture. Collectively, these results demonstrate that first branchial arch explant model is suitable for studies of rhombencephalic crest cell fate during mandibular morphogenesis and can be used as a model with direct access to investigate the molecular mechanism in regulating first branchial arch morphogenesis.

[Human cervico-facial morphogenesis. Evaluation of acquired data and current outlook. Second part: cervical morphogenesis]

After having recalled the formation of the so-called "branchial" organisation, each component of the segmentary units constituting this organisation is analysed, as well as their particularities. This lead us to recognize the existence of only five branchial arches in the human embryo, without an intermediary arch between the fourth arch and the pulmonary arch. This question is moreover linked to the signification of the so-called "ultimobranchial" body, which must be connected with the fourth pharyngeal pouch. The question of cervical segmentation is inseparable from the question of cephalic metamerisation. Two segments are individualised in front of the mandibular process: the fronto-nasal process and the maxillary process, corresponding to premandibular arches, which existence is well established in paleontology. In addition to the peripheral expression of this cervico-cephalic segmentation marqued by primitive characters. We observe the paraxial expression of segmentation by the somitomeres and the somites. Recent data provided by the developmental genes confirm that only one process is at the origin of these two expressions which appear distinct, but lead to a unitary organisation. The mutation of the gene Pax 6 affecting in the same time the nasal placode and the optic vesicle confirms the unity of the fronto-nasal process. The pre-eminence of genetic expression on skeletal, muscular and nervous tissues with respect to the vascular system confirms the inadequacy of the criterion given by the aortic arches for the analysis of the cervico-cephalic development, although it is classically linked to the concept of an embryonic "branchial apparatus".

Effects of nicotine on tongue development in the CD-1 mouse

Fetuses of pregnant CD-1 mice, exposed to 0.1% nicotine sulfate at a dose of 1.67 mg/kg body weight from the 6th through the 15th gestational days were compared with control fetuses to assess the effects of nicotine on tongue development. Mothers were sacrificed on the 18th gestational day. The heads of a total of 130 nicotine-treated and 348 control fetuses were embedded in paraffin and sectioned in the frontal plane. 9.6% of the nicotine-treated fetuses had palatal clefts and their tongue development was much retarded compared to the controls. The tongues of the clefted fetuses were misshaped, reduced in size, had no filiform or fungiform papillae, and their myotubes were just in the process of formation. The circumvallate papilla of these fetuses were present but neither taste buds nor glands of von Ebner had as yet developed. Tongue development of nicotine-treated, non-clefted fetuses were closer to those of the controls. The anlagen of their filiform and fungiform papillae were developing, their myotubes were longer and better arranged, their circumvallate papilla was present but without taste buds, and their glands of von Ebner were not developed. It is suggested that nicotine interferes with both palatal and mesenchymal components of tongue development.

TGF-alpha, EGF, and their cognate EGF receptor are co-expressed with desmin during embryonic, fetal, and neonatal myogenesis in mouse tongue development

The developing mouse tongue provides a model for discrete patterns of morphogenesis during short periods of embryonic development. Occipital somite-derived myogenic cells interact with cranial neural crest-derived ecto-mesenchymal cells to form the musculature of the tongue. The biochemical signals that control close range autocrine and/or paracrine signaling processes required to establish the fast-twitch complex tongue musculature are not known. The present study was designed to test the hypothesis that desmin, epidermal growth factor (EGF), and transforming growth factor-alpha (TGF alpha) and their cognate receptor, epidermal growth factor receptor (EGFr), are co-expressed during tongue myogenesis and define specific developmental stages of tongue muscle cell differentiation. To test this hypothesis, we performed studies to analyze the timing, position, and concentration of desmin, TGF alpha, EGF, and EGFr from embryonic day 9 (E9) through birth in Swiss Webster mouse tongue development. Desmin, TGF alpha, EGF, and EGFr co-localized to cells of myogenic lineage in the four occipital somites and subsequently in myoblasts and myotubes from E9 through E17. By newborn stage, desmin is localized to discrete regions in myofibers corresponding to Z-line delimiting sarcomeres, and A-band within sarcomeres; immunostaining for desmin, TGF alpha, and EGF persisted in differentiated myotubes and striated skeletal muscle. Desmin increased from 0.01% at E11 to 0.51% of the total protein by E17 and at birth. Concomitantly, the patterns and increases in TGF alpha, EGF, and EGFr showed significant increases during the same developmental period. The temporal and positional co-localization of TGF alpha, EGF, and EGFr support the hypothesis that autocrine and paracrine regulation of desmin by actions of growth factor ligand and receptor defines critical stages of tongue myogenesis.

Matrix metalloproteinases regulate morphogenesis, migration and remodeling of epithelium, tongue skeletal muscle and cartilage in the mandibular arch

We have investigated the role of proteinases in the developmental program of bone, cartilage, tongue muscle and epithelial differentiation and remodeling in the mandibular arch during murine embryogenesis. Expression of matrix metalloproteinases (MMPs) and their tissue inhibitors (TIMPs) was tissue-specific with little or no expression in the epithelium of tooth buds, tongue or oral cavity. Gelatinase A mRNA transcripts were strongly expressed in the perichondrium of Meckel's cartilage and mesenchymal areas of embryonic day 13–15 mandibles, whereas gelatinase B, collagenase-3, TIMP-1 and TIMP-2 mRNA were found primarily in the ossifying areas of the mandibles. The skeletal muscle of the tongue expressed stromelysin-3, TIMP-2 and TIMP-3 mRNA while stromelysin-3, TIMP-2 and gelatinase A were seen in the overlying connective tissue layer. Gelatinase A, gelatinase B, stromelysin-1, urokinase, TIMP-1 and TIMP-2 mRNA and protein activities were also detected in cultured mandibular explants. Culture of day 10 mandibular explants with a hydroxamic acid metalloproteinase inhibitor, but not with inhibitors of metalloendopeptidases (thiorphan and phosphoramidon), serine proteinases (aprotinin), cysteine proteinases (leupeptin) and urokinase (amiloride), altered mandibular morphogenesis dramatically. Development of the tongue (glossogenesis) and cartilage, but not bone or teeth was affected. Formation of the oral sulcus and fusion of the two epithelia of the medial sulcus were inhibited, and number and migration of myoblasts decreased. The resulting ‘tongue-tied phenotype’ indicates that MMPs are involved in epithelial morphogenesis and the migration of myoblasts to the region of the tongue. Development of the anterior segment of Meckel's cartilage was also inhibited and proteoglycan content of the cartilage was reduced by inhibiting MMPs. Our data suggest that matrix metalloproteinases play a pivotal role in the morphogenesis of structures derived from epithelium (oral sulcus), cranial paraxial mesoderm (tongue) and cranial neural crest (Meckel's cartilage).

Study by scanning electron microscopy of the morphogenesis of three types of lingual papilla in the rat

BACKGROUND

Many mammals have four different types of lingual papilla, namely filiform, fungiform, circumvallate, and foliate papillae, on the dorsal or lateral surface of the tongue. However, details of the morphogenesis of these lingual papillae have not been reported. We have investigated the changes in the three-dimensional ultrastructure that occur during the morphogenesis of filiform, fungiform, and circumvallate papillae in rats during fetal and postnatal development.

METHODS

Tongues were removed from rat fetuses on days 12 (E12) and 16 (E16) of gestation from newborns (P0) and from juveniles on days 7 (P7) and 14 (P14), and 21 (P21) after birth. Scanning electron microscopy was used for all observations.

RESULTS

In fetuses at E12, the rudiments of fungiform papillae could be observed as two rows of bulges that extended bilaterally and parallel to the median sulcus on the anterior half of the dorsal surface of the tongue. In fetuses at E16, the arrangement of the rudiments of fungiform papillae was relatively regular, with a latticelike pattern. At this stage, the outline of the rudiment of the circumvallate papilla could be recognized on the median line between the lingual body and the lingual radix. No rudiments of filiform papillae were visible. At P0, rudiments of filiform papillae were compactly distributed over the dorsal surface in the same way as in the adult. The width of these rudiments was about one-fourth that of fungiform papillae, and their tips were round as compared with those of filiform papillae in the adult. The fungiform and circumvallate papillae were large, and their outlines were somewhat irregular, as in the adult. In juveniles at P7, filiform papillae were long and slender. On the intermolar eminence, filiform papillar structures were quite large. A taste pore was clearly visible at the center of each fungiform papilla at this stage. The shape of the circumvallate papilla was similar to that in the adult. In juveniles at P14 and P21, the shapes of all three types of papilla were almost same as those in the adult.

CONCLUSIONS

The rudiments of each of the three different kinds of lingual papilla appeared at a different respective stage of development in rats. The rudiments of the fungiform and circumvallate papillae, which are related to the sense of taste, were visible earlier than those of the filiform papillae, which are not involved in this sense.

Stage-specific expression patterns of alkaline phosphatase during development of the first arch skeleton in inbred C57BL/6 mouse embryos

Timing and pattern of expression of alkaline phosphatase was examined during early differentiation of the 1st arch skeleton in inbred C57BL/6 mice. Embryos were recovered between 10 and 18 d of gestation and staged using a detailed staging table of craniofacial development prior to histochemical examination. Expression of alkaline phosphatase is initiated at stage 20.2 in the plasma membrane of mesenchymal cells in the distal region of the first arch. Expression is strongest in osteoid (unmineralised bone matrix) and presumptive periosteum at stage 21.32. Mineralisation begins at stage E23. Expression is present in the mineralised bone matrix. Secondary cartilages form in the condylar and angular processes by stage M24. The cartilaginous cells and surrounding cells in the processes are all alkaline phosphatase-positive and surrounded by the common periosteum, suggesting that progenitor cells of the processes, dentary ramus and secondary cartilages all originate from a common pool. Nonhypertrophied chondrocytes of Meckel's cartilage express alkaline phosphatase at stage M23. Expression in these chondrocytes is preceded by the expression in their adjacent perichondrium. This is true of chondrocytes in all other cranial cartilages examined. 3-D reconstruction of expression in Meckel's cartilage also revealed that the chondrocytes of Meckel's cartilage which express alkaline phosphatase and the matrix of which undergoes mineralisation are those surrounded by the alkaline phosphatase-positive dentary ramus. By stage 25, coincident with mineralisation in the distal section of Meckel's cartilage, most chondrocytes are strongly positive. The perichondria of malleus and incus cartilages express alkaline phosphatase at stage M24. Nonhypertrophied chondrocytes along these perichondria also express alkaline phosphatase. Superficial and deep cells in the dental laminae of incisor and 1st molar teeth become alkaline phosphatase-positive at the bud stage, stages 21.16 and 21.32, respectively. Dental papillae are negative until stage M24 when alkaline phosphatase expression begins in the dental papillae and follicles of the incisor teeth and the dental follicles of the 1st molar teeth. The dental papillae of the 1st molar teeth express alkaline phosphatase at stage 25. Expression in the dental papillae and follicles appears to coincide with cellular differentiation of follicle from papilla. The presumptive squamosal, ectotympanic and gonial membrane bones, lingual oral epithelial cells connected to the dental laminae of the incisor teeth, hair follicle papillae and sheath and surrounding dermis all express alkaline phosphatase in a stage-specific manner.

Congenital aglossia with situs inversus totalis--a case report

Hypoglassia or aglossia is an uncommon anomaly, either of which may occur as an isolated finding or in association with other deformations, especially limb anomalies. Their genetic background is uncertain, and drug induced teratogen has not been clearly identified. We experienced a case of congenital aglossia with situs inversus in a female infant aged twelve days. Her initial complaints at admission were feeding difficulty and weight loss. In a review of literature, the association with situs inversus is very rare and only three cases have been reported until now.

Lingual papillae of the growing rat as a model of vasculogenesis

BACKGROUND

Capillary sprouting is an important mechanism that initiates neovascularization. Because observation of capillary sprouting and its morphological staging can be problematic, we sought to establish a simple model of capillary growth.

METHODS

Rats were obtained at gestational days 15, 16, and 20, at birth, and at postnatal day 10. Scanning electron microscopy (SEM) of vascular casts, freeze-fractured and epithelium-exfoliated specimens, as well as transmission electron microscopy (TEM) of tissue sections were used.

RESULTS

In day 15 fetuses, the filiform papillae and their connective tissue cores had not been formed, but a simple capillary network without regional differences was present. In day 16 fetuses, mesenchymal cells started to form papillary connective tissue cores, and, inside the epithelium, ridges were found. Capillary sprouts arose from the preexisting sinusoidal capillaries by elongation and widening, invaded into connective tissue cores in day 20 fetuses, and gradually bifurcated to form capillary loops in the prospective giant conical papillae of the newborn rat. In postnatal day 10 rats, the capillary network beneath the papillae became bilayered.

CONCLUSION

Vascular formation in the lingual papillae in growing rats offers an easy model for the observation of capillary sprouting. In this model, the sprouts arise from preexisting sinusoidal capillaries and not from veins, as usually observed in other models. The mechanism of capillary growth is the elongation of (preexisting) sinusoidal capillaries into the developing connective tissue cores and toward the forming epithelial ridges.

Development of the fetal tongue between 14 and 26 weeks of gestation: in utero ultrasonographic measurements

Our objective was to establish nomograms for fetal tongue measurements from 14 weeks until mid-gestation by using transvaginal and transabdominal high-resolution ultrasound techniques. A prospective, cross-sectional study was performed on 120 normal singleton pregnancies between 14 and 26 weeks of gestation. Tongue circumference was measured by transvaginal ultrasonography between 14 and 17 weeks, and by abdominal ultrasound between 18 and 26 weeks of gestation. Fetal tongue circumference, as a function of gestational age, was expressed by the regression equation: tongue circumference (mm) = -23.9 + 3.75 x gestational age (weeks). The correlation, r2 = 0.95, was found to be highly statistically significant (p < 0.0001). The normal mean of tongue circumference per week and the 95% prediction limits were defined. During the study period we evaluated two cases with tongue circumference outside these 95% confidence limits: one had microglossia, the other macroglossia, and both were found to be associated with abnormal fetal karyotype. The presented normative data may be helpful in the prenatal diagnosis of suspected congenital syndromes that include, among their manifestations, tongue growth disturbances.