The transverse nasal line: an embryonic fault line

The transverse nasal line has long been neglected and frequently overlooked. This narrow pink or hyperpigmented line or groove extends transversely between the upper two-thirds and the lower third of the nose. It is often hereditary and may be the locus of comedones and milia. Eighteen examples are reported by us, along with a possible embryological interpretation.

The embryonic development of sensory organs and the skull in the trisomy 16 mouse, an animal model for Down's syndrome

The trisomy 16 mouse is a widely accepted animal model for the study of the embryonic development of human trisomy 21. While the development of the brain and heart has been thoroughly studied, there are hardly any data on the development of sensory organs like the eye, nose and ear. By studying scanning electron microscopic pictures and semithin sections from the tenth to the 15th day of development, we found delayed development of the nose, and, in particular, of the vomer. Sensory structures of the otic vesicle also showed a marked developmental delay. Pigmentation of the outer layer of the otic cup starts later in trisomic animals. Cleared specimens on day 16 showed retarded development of ossification centres in all areas of the skull. These findings correspond with the abnormal facial morphology found in Down's syndrome and may also provide new insights into the hearing impairment commonly found. The observations in the eye and skull bones indicate that neural crest tissue maldevelopment is not the sole cause of malformations.

Measurement of fetal nasal width by ultrasonography

OBJECTIVE

This study was designed to determine the range of normal fetal nasal width by ultrasonography, which may be beneficial for detection of trisomy 21 and other chromosomal abnormalities. We hypothesize that a wide, saddle-shaped nose, which is one of the clinical neonatal anatomic features of trisomy 21, can be diagnosed prenatally.

STUDY DESIGN

Fetal nasal width diameter was measured on 782 normal white fetuses by ultrasonography. Gestational ages ranged from 13.8 to 40.4 weeks. Mean and SD of fetal width diameter was calculated weekly by gestational age to establish normal values.

RESULTS

The fetal nasal width increased as a function of gestational age, showing a polynomial curve during pregnancy (r = 0.912, p = 0.002). With use of mean +/- 1 SD as a cutoff value, the results showed a sensitivity of 80% with a specificity of 67% and a positive predictive value of 2.2% with a negative predictive value of 99.7% for the diagnosis of trisomy 21.

CONCLUSION

The fetal nasal width diameter may be used as a biometric measurement and may be useful to identify trisomy 21 or other chromosomal abnormalities in conjunction with other already defined parameters used in a genetic ultrasonographic screen.

Growth of the fetal nose width and nostril distance in normal pregnancies

The study was planned to obtain the dimensions of the fetal nose width and nostril distance during normal pregnancy as a basis for further studies and for identification of deviations in growth. The study group included 302 healthy pregnant women at 14-40 weeks' gestation. Routine biometric measurements were obtained from all the participants, including biparietal diameter, head and abdominal circumferences, measurements of the long bones and dimensions of the fetal nose width and nostril distance. The nose width and nostril distance were also calculated for each gestational age. A linear growth relationship was observed between nose width and gestational age (r = 0.88; p < 0.0001; y = 0.27 + 0.57 x gestational age), biparietal diameter (r = 0.92; p < 0.0001; y = 0.41 + 0.23 x biparietal diameter), head circumference (r = 0.91; p < 0.00001; y = 0.85 + 0.63 x head circumference), femoral length (r = 0.91; p < 0.0001; y = 3.18 + 0.26 x femoral length) and humeral length (r = 0.73; p < 0.0001; y = 1.94 + 0.11 humeral length). A linear growth function was also observed between nostril distance and gestational age (r = 0.54; p < 0.00001; y = 2.77 + 0.15 x gestational age), biparietal diameter (r = 0.71; p < 0.00001; y = 1.83 + 0.08 x biparietal diameter), head circumference (r = 0.70; p < 0.00001; y = 1.99 + 0.2 x head circumference), femoral length (r = 0.75; p < 0.00001; y = 2.49 + 0.09 x femoral length) and humeral length (r = 0.91; p < 0.00001; y = 1.89 + 0.32 x humeral length). A linear growth relationship was found between nose width and nostril distance (r = 0.71; p < 0.00001; y = 1.81 + 0.31 x nose width). These results provide normative data of the fetal nose width and nostril distance in various dimensions and across gestational age. In addition, the data offer the potential for prenatal diagnosis of nose and nostril abnormalities.

Each member of the Id gene family exhibits a unique expression pattern in mouse gastrulation and neurogenesis

We have performed a detailed comparative in situ hybridization analysis to examine the patterns of expression of all the members of the Id gene family (Id1-4) during murine gastrulation and neurogenesis. During gastrulation, both Id1 and Id3 are expressed in the tissues derived from the inner cell mass from 5.5 dpc onward, whereas Id2 is expressed in tissues derived from trophoblasts. Id4 expression is absent during this period of development. Embryonic Id1 messages are detected during gastrulation on the proximal side of the embryonic ectoderm, which is the border between the embryo proper and the extraembryonic tissues, and the expression of Id3 is found throughout the entire embryo proper. This unique pattern of expression of the different members of the Id family suggests a nonredundant role for these genes in antagonizing the activity of bHLH transcription factors during very early mouse development. During neurogenesis, the expression of each member of the Id family is present in an unique pattern along the dorsal-ventral axis of the neural tube: In the early stages of spinal cord development, both Id1 and Id2 are expressed in the roof plate, whereas Id3 is expressed both in the roof and the floor plates. As development progresses, the expression of both Id1 and Id3 is detected in the dividing neuroblasts, whereas Id2 and 4 are expressed in presumptive neurons which are undergoing maturation. The expression patterns of all the members of the Id gene family persist throughout the entire CNS, both in the spinal cord and in the brain. In addition, the characteristic expression of Id2 and Id4 in more mature neurons is reiterated both in the PNS and in the neurons of some of the sensory organs. These data suggest that the expression of different subgroups of the Id gene family may have different physiological consequences and thereby contributes in unique ways to specify the differentiation state of neuronal cells during development.

A peculiar malformation of the upper lip: report of six cases

Six cases of a peculiar type of upper lip malformation have been observed by the author during the last 40 years. The malformations in this case series were remarkably similar, suggesting a single teratologic entity not been reported before. The six patients included 1-, 11-, 4-, and 6-month-old males, a 20 year-old male, and an 11-year-old female. Each was characterized by a crooked folded philtrum, a flat thin vermilion region of the upper lip, and high-positioned ala(e), that was unilateral or bilateral. The upper median incisors were separated occasionally by the thick lip frenulum without marked distortion of the nasomaxillary framework. The author speculates that these cases exhibited some disturbed penetration of the lateral nasal eminence (process) to the median part of the nasolabial region in their early embryologic development.

Common pattern of CD44 isoforms is expressed in morphogenetically active epithelia

CD44 is a widely distributed cell surface glycoprotein that is expressed as many isoforms arising from a single gene by alternative splicing. An important ligand for the widespread CD44 isoform, CD44s (standard form of CD44), is hyaluronan but ligands for the numerous variant isoforms are not as well characterized. Although it has been documented that CD44 is present at critical sites and stages of morphogenesis of several organs, the nature of the isoforms expressed and their precise localization have not been described. In this study we have determined the identity and distribution of CD44 isoforms expressed during development of several embryonic mouse organs by a combination of immunohistochemistry, in situ hybridization, reverse transcription-polymerase chain reaction, and DNA sequencing. As expected from previous studies, numerous CD44 variants are expressed by actively proliferating and invaginating epithelia at sites of epithelial-mesenchymal interaction, e.g., in the developing tooth, nose and hair follicle. Our results show that most prominent amongst these variants at these sites are CD44(v3-v10), CD44(v4-v10), and CD44(v6-v10), as was also found previously in the apical ectodermal ridge of the developing limb (Yu et al. [1996]). The common pattern of expression of these three particular variants in active epithelia implies that they play an important role in morphogenesis. Also very prominent in morphogenetically active epithelia is CD44s; hyaluronan is uniformly absent from these epithelia and often also from associated mesenchyme with which they interact, supporting the previously documented role of CD44s in endocytic removal of hyaluronan.

Mouse Eya homologues of the Drosophila eyes absent gene require Pax6 for expression in lens and nasal placode

We have identified and mapped three members of a new family of vertebrate genes, designated Eya1, Eya2 and Eya3, which share high sequence similarity with the Drosophila eyes absent (eya) gene. Comparison of all three murine Eya gene products and that encoded by the Drosophila eya gene defines a 271 amino acid carboxyl terminal Eya domain, which has been highly conserved during evolution. Eya1 and Eya2, which are closely related, are extensively expressed in cranial placodes, in the branchial arches and CNS and in complementary or overlapping patterns during organogenesis. Eya3 is also expressed in the branchial arches and CNS, but lacks cranial placode expression. All three Eya genes are expressed in the developing eye. Eyal is expressed in developing anterior chamber structures, including the lens placode, the iris and ciliary region and the prospective corneal ectoderm. Eyal is also expressed in retinal pigment epithelium and optic nerve. Eya2 is expressed in neural retina, sclera and optic nerve sheath. Moreover, Eya1 and Eya2 expressions in the lens and nasal placode overlap with and depend upon expression of Pax6. The high sequence similarity with Drosophila eya, the conserved developmental expression of Eya genes in the eye and the Pax6 dependence of Eya expression in the lens and nasal placode indicates that these genes likely represent functional homologues of the Drosophila eya gene. These results suggest that members of the Eya gene family play critical roles downstream of Pax genes in specifying placodal identity and support the idea that despite enormous morphological differences, the early development of insect and mammalian eyes is controlled by a conserved regulatory hierarchy.

Expression of 72-kDa gelatinase (matrix metalloproteinase-2) in the developing mouse craniofacial complex

Tissue remodelling is an important feature during embryogenesis. Although the matrix metalloproteinases are believed to participate in these processes, the relation between matrix metalloproteinases and tissue remodelling during craniofacial morphogenesis remains unclear. The purpose of the study was to look for the presence of enzymes involved in extracellular matrix degradation during craniofacial morphogenesis. Protein expression of the matrix metalloproteinase, 72-kDa gelatinase (matrix metalloproteinase-2, gelatinase A, 72-kDa type IV collagenase) was studied by gelatine zymography and by indirect immunofluorescence with conventional and confocal microscopy. In the anterior region of the developing mouse face, 72-kDa gelatinase was labelled mainly in the tips and peripheral regions of the nasal and facial prominences. Upon contact and fusion of the prominences, the staining was intensely localized to the zone of the fusion and the tips and peripheral regions of the nasal prominences and the maxilla. The labelling of 72-kDa gelatinase was also present in the peripheral regions of the mandible, second branchial arch, and the face around the developing eye. However, during lens vesicle formation, the staining of 72-kDa gelatinase was absent in the invaginated lens ectoderm. After the lens had completely detached from the surface ectoderm, the staining was resumed in the corneal epithelium and mesenchyme. Gelatine zymography was used to confirm the presence of active and latent 72-kDa gelatinase in the developing mouse craniofacial complex. Collectively, these data indicate that 72-kDa gelatinase may play a significant part in localized tissue remodelling during craniofacial morphogenesis and the aberrant expression or function of the enzyme could be involved in causing facial abnormalities.

Transcripts for two members of the transforming growth factor-beta superfamily BMP-3 and BMP-7 are expressed in developing rat embryos

Bone morphogenetic protein-3 (BMP-3) and BMP-7 are members of the transforming growth factor beta superfamily that have been implicated in the formation of cartilage and bone. Using in situ hybridization, we localized mRNAs for BMP-3 and BMP-7 during organogenesis in rats. Both mRNAs were expressed in a variety of cells, in particular, in the developing hair follicle, tooth, kidney, and lung tissues, in which reciprocal epithelial-mesenchymal interactions are essential. In some tissues, the distribution of BMP-3 and BMP-7 mRNAs overlapped. In other tissues, the patterns of expression were quite different. Moreover, the site of expression of the transcripts changed from one cell type to another during organogenesis. These results suggest that BMP-3 and BMP-7 play important roles in organogenesis and that the differential patterns of their expression might reflect their distinct roles in embryogenesis.

Positional determination of the naso-temporal retinal axis coincides with asymmetric expression of proteins along the anterior-posterior axis of the eye primordium

We used two different methodologies to examine at what stage development retinal positional specificity is established and which molecules are responsible. The first goal was achieved by removing parts of the presumptive temporal primary optic vesicle at stage 11 (40 to 45 hr of incubation) and fate mapping of tissue with presumptive nasal properties that shifted into the wound during the events of wound-healing. Participation of the shifted tissue in the healing resulted in assembly of a temporal retina with mosaic-like projection properties, as examined by retrograde double staining of the retinal ganglion cells from the optic tectum. In addition to cells with normal temporal-rostral projections, clusters of ganglion cells with nasal-like projection identities appeared labelled within the temporal hemiretina. The number of clusters increased with the amount of resected tissue, and by almost complete ablation of the presumptive temporal anlage, a temporal hemiretina with predominantly nasal retinotectal specificity was created. These neuroanatomical results suggested that neuroepithelial cells had fixed nasal and temporal positional specificities at stage 11. To examine differences in the cells derived of either half of the eye cup, we performed biochemical one- and two-dimensional gel electrophoresis of the hemianlagen at stage 11. In addition, incorporation of 35S-methionin into newly synthesized peptides was investigated. Both techniques revealed the exclusive expression of one major and three less-abundant proteins within the presumptive nasal anlage. The most abundant of these proteins has a molecular weight of about 40 kDa and is clearly distinguishable both in gel electrophoresis and autoradiography. The asymmetric protein patterns had disappeared when the retina was analysed with the same methods at the more advanced embryonic days E4 and E6. The asymmetry in the expression of proteins in the retinal primordium may be the biochemical correlate of an early positional specification of the retinal neuroepithelium. The difference in the protein expression may explain that mixing the positionally specified cells of either origins results in projection mosaics.

Differential expression of alpha A- and alpha B-crystallin during murine ocular development

PURPOSE

To compare the temporal and spatial expression patterns of alpha A- and alpha B-crystallin mRNA during ocular development.

METHODS

Tissue samples from embryonic day 9.5 (E9.5) through postnatal day 14 were collected from FVB/N strain mice. The specimens were fixed in paraformaldehyde, histologically processed, and assayed for alpha A- and alpha B-crystallin mRNA expression by in situ hybridization.

RESULTS

During ocular development, alpha B-crystallin transcripts are present in the lens placode at E9.5. Transcripts of alpha A-crystallin are first observed in the lens cup at E10 to 10.5. During subsequent development of the lens, alpha A crystallin transcripts are most abundant in the fiber cells, and alpha B crystallin mRNA is preferentially expressed in epithelial cells. Transcripts of alpha A-crystallin were detected only in the lens. In contrast, alpha B-crystallin transcripts are present in retinal pigment epithelium, optic nerve, extraocular muscle, iris, ciliary body, cornea, and several nonocular sites, such as heart and nasal epithelium.

CONCLUSIONS

Transcription of alpha B-crystallin precedes the expression of alpha A-crystallin during murine ocular development. Furthermore, the patterns of alpha A- and alpha B-crystallin expression in the lens are distinctive: alpha A is upregulated and alpha B is downregulated during prenatal fiber cell differentiation. These results indicate that the alpha-crystallin genes are not identically regulated either within or outside the lens.

OTX2 homeoprotein in the developing central nervous system and migratory cells of the olfactory area

We analyzed the distribution of OTX2 during mouse development. OTX2 is a homeoprotein encoded by Otx2, a vertebrate homeobox gene expressed in the developing brain and anterior head regions. The protein is already detectable in pre-streak embryos, in nuclei of embryonic ectoderm or epiblast and primitive endoderm or hypoblast. Its distribution is uniform along the entire epiblast, while showing an antero-posterior gradient along the hypoblast at the time when primitive streak first forms. Between embryonic day 7 (E7) and E7.5 there is a progressive confinement of the protein to the anterior ectoderm corresponding to the forming headfold. At E7.5-E7.8, the protein is mainly confined in this region but is still present, though at lower level, in more posterior ectoderm. Starting from day 8 of development it is essentially confined to anterior neuroectoderm corresponding to presumptive fore- and midbrain. Its subsequent distribution in forebrain, midbrain, developing isthmo-cerebellum and posterior central nervous system is analyzed in detail. Of particular interest is the presence of OTX2 in nuclei of cells of the olfactory system starting from its origin in the olfactory placode. OTX2 protein is present in some cells of the olfactory epithelium, in both the major olfactory epithelium and the vomero-nasal organ, and in scattered migratory cells present in the mesenchyme outside it. These cells surround the axon bundles of the olfactory nerve along its path from the olfactory epithelium in the nasal cavities to the olfactory bulb in rostral telencephalon and include both ensheathing glial cells and luteinizing hormone-releasing hormone (LHRH)-positive cells.

Alteration in facial shape in the anencephalic human foetus

Tracings were produced from frontal radiographs of 11 anencephalic foetuses. These were compared analytically with standards derived from 60 normal foetuses. The anencephalics showed a marked reduction in the relative size of the cranium with considerable flattening of the calvarium, which is characteristic of the condition. The orbits were more medially placed, being closer together and somewhat higher in position that the normal foetal outline. The right and left mandible were more elongated with an increase in the intermaxillary space. The condyles were more medially positioned and were closer to the orbits than in the normal outlines. In normal growth, expansion of the brain flattens the cranial base, displacing the nasomaxillary segment forwards. In anencephally this does not happen so that the nasomaxillary segment rotates in an antero-inferior postero-superior direction along with the intermaxillary space and mandible. This produces a significant lengthening of the face accompanied by narrowing in the region of the cranial base relative to the normal outline.

Detailed staging of inbred C57BL/6 mice between Theiler's [1972] stages 18 and 21 (11-13 days of gestation) based on craniofacial development

A detailed staging table of inbred C57BL/6 embryonic mice was developed to facilitate a study of the stage-by-stage cellular and molecular mechanisms underlying cranial skeletal development and elucidation of the developmental mechanisms potentially involved in evolutionary changes in cranial skeletal morphology exhibited by different inbred strains of mice. Mice were mated for only 2 hr and embryos were recovered every 2 or 4 hr between 11 and 13 days of gestation. Theiler's [1972] stages 18 through 21 were divided into substages and divisions based on the development of five external structures--the frontonasal area, eyes, auditory meatus, mandibular and hyoid auricular hillocks/pinna, and vibrissae--and three internal histological structures--eyes, tongue, and vibrissae. Each substage and division was designated with a decimal point: e.g., substage 20.1 and division 20.11. Embryos were staged using the staging table and the relationship of the substages and divisions with days of gestation was examined. The results showed considerable intra- and inter-litter variation in stages of embryos, suggesting that days of gestation are not a good indicator for staging embryos. Our staging table offers a more reliable and precise method to standardize embryonic development. Regression analyses of substages on days of gestation showed that the duration of stages increased from stages 18 to 21. Estimated durations were 3.5 hr for stages 18 and 19, 8.8 hr for stage 20, and 38.8 hr for stage 21. Our staging table also provides baseline information on development of the frontonasal area (muzzle) and vibrissae and development and the transformation of the auricular hillocks into the pinna. The developmental sequence of mystacial and labial vibrissae indicated highly regulated differentiation and morphogenesis of vibrissal development at stages 20 and 21. Three hyoid auricular hillocks transiently became four hillocks at stage 19.1 before transforming to the pinna during stage 21. The second and third hyoid auricular hillocks were the major contributor to the pinna before stage 21.2, whereas mandibular auricular hillocks contributed to the pinna from stage 21.32 onward. The staging table has already served to demonstrate stage-specific skeletogenesis of the first arch cartilages in inbred C57BL/6 mice and to reveal differences in the onset of timing of skeletogenesis among inbred C57BL/6, C3H/He and CBA/J mice.

In vitro analysis of the centripetal migration mechanisms of developing LHRH neurons

This study was designed to gain insight into the underlying mechanisms of the centripetal migration of developing LHRH neurons. The medial wall of the nasal pit (NAP) of 12.5-day-old rat embryos (E12.5) was cultured singly or together with the E12.5 medial-basal wall of the forebrain vesicles (mFV) or with the E14.5 median eminence-arcuate complex (ME-Arc). Further, the NAP was cultured with the mFV and ME-Arc or with the mFV and nasal mesenchyme (NM), which lay between the mFV and the NAP, of E12.5 embryos (triple culture). The NAP gave rise first to fibers labeled with anti-neural cell adhesion molecules (NCAM) and then to LHRH neurons. In co-cultures, NAP- and brain-derived NCAM fibers connected the NAP and brain cultures, and frequently linked with each other to form knots at the periphery. LHRH neurons migrating along the NAP-derived fibers directly or indirectly entered brain cultures. In the latter case, the cells strayed along the way from the NAP-derived fibers to the brain-derived fibers at the knots and migrated retrogradely along the latter fibers to enter into the brain tissues; this occurred most frequently into the E14.5 ME-Arc. In triple cultures, abundant NCAM fibers emerging from the NAP were only found when the NM lay between the NAP and mFV; the fibers converged further to the mFV. These findings help elucidate the mechanisms underlying the centripetal LHRH cell migration from the NAP to the hypothalamus.

The role of Pax-6 in eye and nasal development

Small eye (Sey) mice homozygous for mutations in the Pax-6 gene have no lenses and no nasal cavities. We have examined the ontogeny of eye and nasal defects in Sey/Sey embryos and have related the defects seen to the pattern of Pax-6 mRNA expression in the mouse during normal eye and nasal development. There are two principal components of the early eye, the neural ectoderm of the optic vesicle, which forms the retina, and the overlying surface ectoderm, which forms the lens and cornea. By studying these interacting tissues in normal and Sey/Sey embryos, we have identified processes for which Pax-6 is important and can thus suggest possible roles for the Pax-6 gene. Pax-6 is essential for the formation of lens placodes from surface ectoderm. In normal development, early Pax-6 mRNA expression in a broad domain of surface ectoderm is downregulated, but expression is specifically maintained in the developing lens placode. Moreover, other Pax-6-expressing tissues are frequently those that have can transdifferentiate into lens. Thus, phenotype and expression together suggest a role for Pax-6 in lens determination. At least some functions of Pax-6 can be separated from the influence of other tissues. Early Sey/Sey optic vesicles are abnormally broad and fail to constrict proximally. These defects occur prior to the time of lens placode formation and probably reflect a requirement for Pax-6 in neural ectoderm. In surface ectoderm domains, where Pax-6 expression is known to be independent of the presence of an optic vesicle, Pax-6 function is required for the maintenance of its own transcription. The mutual dependency of lens and optic vesicle development can also be studied using the Small eye mutation. Using region-specific markers we find that, in the morphologically abnormal Sey/Sey optic vesicles, aspects of normal proximo-distal specification nevertheless persist, despite the complete absence of lens. Like the lens, the nasal cavities develop from ectodermal placodes that normally express Pax-6 mRNA, fail to form in Sey/Sey mice and show Pax-6-dependent Pax-6 mRNA regulation. Analysis of patterns of programmed cell death and absence of nasal region expression from an Msx-1 transgene in Sey/Sey embryos suggest a requirement for Pax-6 in the transition from presumptive nasal ectoderm to placode, and that Msx-1, or genes regulating it, are possible targets for Pax-6.

Distribution of p21ras during primary palate formation of non-cleft and cleft strains of mice

Cleft lip, with or without cleft palate, is one of the most common defects in craniofacial formation. The primary palatogenesis of mice is similar to that of humans and spontaneous cleft lip is associated with genotype in both mice and humans. To investigate the temporal and spatial expression of ras genes in cleft (A/WySn) and non-cleft strains of mice (BALB/cBy), a broad spectrum ras antibody was used. Positive staining was found in ectodermal, mesenchymal, and neuroepithelial cells of facial prominences before the primary palate formation stage (10 d 20 hr) in both strains. During the primary palate formation stage (11 d 20 hr), positive staining was found in the ectodermal and mesenchymal cells of the facial prominences of the non-cleft strain but not in those of the cleft strain. These results suggest ras genes may play a role in the primary palatogenesis of mice. Cleft lip could be associated with the deficiency of ras gene expression during primary palate formation of mice.

The mouse homolog of the orphan nuclear receptor tailless is expressed in the developing forebrain

The Drosophila tailless gene is a member of the orphan nuclear receptor subfamily. In Drosophila, the tailless gene is required for pattern formation in embryonic poles. During development, tailless is activated in the termini of the embryo in response to the torso receptor tyrosine kinase signal transduction cascade. Recessive mutations of tailless result in abnormalities in anterior portions of the head and in all structures posterior to the eighth abdominal segment. Localised expression of tailless is required in combination with a second terminal gene, huckebein, to control the expression of downstream genes. We have isolated a mouse homolog of the Drosophila tailless gene, which shows considerable homology in the DNA-binding domain suggesting that the respective proteins bind similar recognition sequences. Although the ligand-binding domain shows features in common with the tailless ligand domain, it also shares conserved amino acid stretches with other orphan nuclear receptors, the human ovalbumin upstream binding protein transcription factors (hCOUP-TF I and II). We have analysed the expression of taillees in mice, and show that it is specifically localised to the developing forebrain from day 8 p.c. and in dorsal midbrain from day 8.75 p.c. To define the anterior and posterior boundaries of expression, we compared the expression pattern of tailless to those of other forebrain markers, including distal-less (Dlx1), brain factor 1 (BF1), and the orthodenticle genes (Otx1 and Otx2). In addition to the developing forebrain, these genes show dynamic patterns of expression in two structures whose development requires inductive signals from the forebrain: the eye and the nose. These results suggest that the mouse taillees gene may be required to pattern anterior brain differentiation.

Mandibular growth rates in human fetal development

A morphometric analysis of changing proportions in the developing mandible was undertaken in 18 human embryos and fetuses of both sexes (developmental age from 8 to 14 weeks, crown-rump length, CRL, from 34 to 110 mm), previously cleared and stained with a specific method for bone (alizarin red S). Reference points were located on the mandible, i.e. condylar process (Pcl), coronoid process (Pco), gnathion (GN), gonion (GO), superior symphyseal point (SSP), for measuring linear dimensions, i.e. Pcl-GN, Pcl-Pco, Pco-GN, GO-GN, SSP-GN. The gonial (Pcl-GO-GN) and the (Pcl-GN-Pcl) angles were also measured. All linear dimensions were correlated with the CRL by bivariate allometry (1n y = 1n a+b 1n x): they all grew with positive allometry, except GO-GN with isometry. The mandibular ramus grew relatively faster than the body, both in length and height, and the greatest growth rate was found for ramus height. The relation between mandibular shape and the craniofacial structures was investigated using scale drawings obtained from photographs of fetal skulls in lateral view. In the youngest fetuses the mandible was prognathic, then became retrognathic. During the period investigated the zygomatic process and squama of the temporal bone were in a lower and more inclined position in relation to the transverse plane passing through the zygomatic arch than in the newborn and adult. This study identifies parameters fitting changing trends in height, length and shape of the human mandible during the prenatal period (8-14 weeks); moreover, it emphasizes that the mandibular growth patterns differ significantly from those of successive development periods.

[The structural-functional changes in the epithelium of the respiratory area of the nose and intrapulmonary bronchi in human ontogeny]

The epithelia of nasal respiratory area and intrapulmonary bronchi were studied in human ontogenesis by means of light and electron microscopy. The results indicate the stageness of morphofunctional organization of epithelia of the organs studied. The succession of the respiratory tract epithelium cytodifferentiation, dynamics of correlation between the epithelial layer cell elements in ontogenesis and peculiarities of ultrastructural organization of the nasal mucosa epithelial cell were established.

Detection of apoptosis by electron microscopy and in situ labelling in the rat olfactory pit

The purpose of this study was to provide further information upon the cell death process by apoptosis occurring in the olfactory pit during the primary palate formation and the vomeronasal organ detachment. Apoptotic cells were detected by coupling ultrastructural observations and in situ end-labelling of DNA breaks (TUNEL labelling) in E12-E15 rat embryos. During the primary palate formation and the vomeronasal organ closure, a strong apoptotic cell death process was observed along the midline epithelial seam after the epithelial fusion. The topographical distribution of labelled nuclei was in agreement with the morphological distribution of dying cells. One day before the nasal swellings fused, numerous degenerating cells were also detected in the regions of prospective contact which thus appeared as regions of programmed cell death.

Retinoic acid and mouse skin morphogenesis. I. Expression pattern of retinoic acid receptor genes during hair vibrissa follicle, plantar, and nasal gland development

The spatial and temporal expression of the nuclear retinoic acid receptors alpha, beta, and gamma (RAR-alpha, beta, and gamma) was compared by in situ hybridization during hair vibrissa follicle and nasal and plantar eccrine gland morphogenesis in mouse embryo. The RAR-alpha and RAR-gamma transcripts are abundant in the dermal papilla cells of the hair vibrissa when these cells elicit epidermal hair placode (12.5-d embryos) and hair follicle (13.5-d embryos) formation. Both these transcripts are also abundant in the dermal cells of the plantar foot pad at the initiation stage (17.5-d embryos) of glandular morphogenesis. In epidermal cells, the distribution of RAR-gamma transcripts increases in parallel with hair vibrissa follicle and sweat gland differentiation, and thus may be part of the epidermal response to the dermal instructions. The RAR-beta signal is barely above control level during both hair vibrissa and plantar gland morphogenesis. By contrast, during nasal gland formation (12.5- to 15.5-d embryos), the RAR-beta signal reaches a high level in mesenchymal cells, whereas the RAR-alpha-transcripts are present in both epithelial and mesenchymal cells. These results suggest a role for RAR-alpha and RAR-gamma in the epidermal-dermal interactions that lead to hair follicle and plantar gland morphogenesis, whereas the nasal gland development implies RAR-alpha and RAR-beta gene expression. This should be correlated with the expression of the RAR-beta gene that was previously shown to be linked to the RA-induced glandular metaplasia of hair vibrissa follicles.

Congenital abnormalities of the nose: CT and MR findings

Congenital abnormalities of the nose can occur with or without respiratory obstruction. Nasal obstruction generally is detected in the neonatal period, and the examination of choice is CT. The results of CT will determine not only the cause of obstruction but also the surgical approach. Congenital anomalies of the nose with no respiratory obstruction generally appear later in life and have characteristic morphologic features. True midfacial clefting is a complex syndrome that is accompanied by intracranial abnormalities. In these patients, evaluation of the face might require both CT and MR imaging, but the brain is better examined with MR imaging. Abnormalities involving the prenasal space usually manifest as masses in the nose. All congenital abnormalities of the nose are due to discrete faults in the embryologic development of the face.

Stimulus access to the accessory olfactory system in the prenatal and perinatal rat

The fetal rat can detect odors in its amniotic fluid. Indirect evidence suggests that the accessory olfactory system may be mediating chemoreception prenatally. The primary goal of this study was to determine if stimuli in the amniotic fluid gain access to the receptor neurons of the accessory olfactory system that are sequestered inside the vomeronasal organ. Other goals of the study were to compare the access of stimuli to the vomeronasal organ in the prenatal and young postnatal rat and to examine the role of the autonomic nervous system in this process. On the day before birth fluorescent beads (0.95 microns diameter) were injected into the amniotic sacs of rat fetuses from seven dams. After 4-6 h one group of mothers received an i.p. injection of epinephrine (either 60 or 75 micrograms) and another group received no injection. One hour later pups were collected and processed for histological examination using fluorescence microscopy. A portion of the fetuses from both treatment groups had significant numbers (< 50) of beads in their nasal passages. Some of these subjects also had beads in the vomeronasal organ. There was no significant difference in the proportion of subjects with beads in the nasal cavities or vomeronasal organ across the two treatments. In a second experiment, five- to seven-day-old rat pups had beads infused into one naris. After 3-4 h one group was injected i.p. with epinephrine (2-4 micrograms), while a second group received no injection. As expected, virtually all the subjects had large numbers of beads in their nasal cavities upon post mortem examination.(ABSTRACT TRUNCATED AT 250 WORDS)