Histological changes induced in developing limb buds of C57BL mouse embryos submitted in utero to the combined influence of acetazolamide and cadmium sulphate

Microscopic defects in limb buds of C57BL mouse embryos after the combined teratogenic action of acetazolamide plus cadmium sulphate administered on day 9 of gestation were studied in serial sections. Postaxial deficiencies observed in 12-15-day embryos and affecting preferentially the right forelimbs were classified in nine morphological types according to increasing amounts of missing parts. Type X defect consists of a nearly complete amelia in which all four limbs are represented only by the girdle and proximal end of the stylopod. Type XI abnormality appears as an intermediate reduction affecting the area of digit IV. In addition to modifications of the forelimb bud shape detected from the 10-day stage onwards, observations made 24 and 48 hr after treatment confirmed that the postaxial defects result from an absolute lack of postaxial mesoderm occurring without cell necrosis as a consequence of a postaxial shortening of the apical ectodermal ridge (aer). In 10-day embryos, the latter appears shortened and hypertrophied; it is later fragmented into alternate thick and thin portions in 11-day affected limb buds. These ectodermal changes might account for the genesis of all types of defects observed. Untreated 9-day embryos with 12-25 pairs of somites display a number of asymmetries between their right and left forelimb territories: Until the 19-somite stage, the vascular supply to that area is provided exclusively by the umbilical vein, which is larger on the right side; the initial amount of somatopleural limb mesoderm is greater in the right rudiment and the genesis of its aer is slightly protracted as compared to the left one. These asymmetries might contribute to the right side predominance of the forelimb defects induced by acetazolamide and cadmium.     

An Ancient Gene Network Is Co-opted for Teeth on Old and New Jaws

Vertebrate dentitions originated in the posterior pharynx of jawless fishes more than half a billion years ago. As gnathostomes (jawed vertebrates) evolved, teeth developed on oral jaws and helped to establish the dominance of this lineage on land and in the sea. The advent of oral jaws was facilitated, in part, by absence of hox gene expression in the first, most anterior, pharyngeal arch. Much later in evolutionary time, teleost fishes evolved a novel toothed jaw in the pharynx, the location of the first vertebrate teeth. To examine the evolutionary modularity of dentitions, we asked whether oral and pharyngeal teeth develop using common or independent gene regulatory pathways. First, we showed that tooth number is correlated on oral and pharyngeal jaws across species of cichlid fishes from Lake Malawi (East Africa), suggestive of common regulatory mechanisms for tooth initiation. Surprisingly, we found that cichlid pharyngeal dentitions develop in a region of dense hox gene expression. Thus, regulation of tooth number is conserved, despite distinct developmental environments of oral and pharyngeal jaws; pharyngeal jaws occupy hox-positive, endodermal sites, and oral jaws develop in hox-negative regions with ectodermal cell contributions. Next, we studied the expression of a dental gene network for tooth initiation, most genes of which are similarly deployed across the two disparate jaw sites. This collection of genes includes members of the ectodysplasin pathway, eda and edar, expressed identically during the patterning of oral and pharyngeal teeth. Taken together, these data suggest that pharyngeal teeth of jawless vertebrates utilized an ancient gene network before the origin of oral jaws, oral teeth, and ectodermal appendages. The first vertebrate dentition likely appeared in a hox-positive, endodermal environment and expressed a genetic program including ectodysplasin pathway genes. This ancient regulatory circuit was co-opted and modified for teeth in oral jaws of the first jawed vertebrate, and subsequently deployed as jaws enveloped teeth on novel pharyngeal jaws. Our data highlight an amazing modularity of jaws and teeth as they coevolved during the history of vertebrates. We exploit this diversity to infer a core dental gene network, common to the first tooth and all of its descendants.     

Inductive and axial properties of prospective wing-bud mesoderm in the chick embryo

Prospective wing-bud mesoderm, stripped of ectoderm mechanically through the use of glass needles, or chemically by means of EDTA or trypsin, was obtained from donor embryos of stages 11 through 21. Grafts were made in both homopleural (aadd and apdv) and heteropleural (aadv and apdd) combinations to the right flank of host embryos of the same range of stages. Flank ectoderm from the host healed over the graft in a few hours and, in combinations between donors and hosts in the range of stages 12 through 17, the composite formed, with high frequency, a limb bud capped by an apical ectodermal ridge, and then developed into a supernumerary wing in which all proximodistal levels were represented. When either member of the combination was older than stage 17, only incomplete limbs, if any, were formed. Regardless of their orientation on the host, the supernumerary limbs always showed the axial characteristics appropriate to their side of origin.Supernumerary wings failed to form if the grafts were inserted into a space tunneled between flank ectoderm and its underlying mesoderm. If the covering ectoderm were deliberately torn and forced to heal over the graft, however, an ectodermal ridge formed and a supernumerary limb developed.It is concluded, therefore, that: (1) the wing-bud mesoderm, appropriately combined with flank ectoderm, has the property of morphological and axial self-differentiation by stage 12; (2) the apical ectodermal ridge is induced in flank ectoderm by prospective wing-bud mesoderm; (3) this inductive power is restricted to prospective wing-bud mesoderm from donors of stages 12 through 17; (4) the response competence is limited to flank ectoderm that has healed over the mesoderm; and (5) this competence is lost by the end of stage 17.     

The in vitro maintenance of the apical ectodermal ridge of the chick embryo wing bud: an assay for polarizing activity.

We have devised an in vitro bioassay for limb bud polarizing activity in the chick embryo. This assay has proven to be a relatively quick and effective test for a morphogenetic factor asymmetrically distributed in the limb bud which is capable of maintaining or thickening the apical ectodermal ridge.A small section of the preaxial border of the chick embryo wing bud was cultured alone, with tissue from the posterior border, mid-dorsal or anterior corner of a second donor wing, or from the flank. The tissue from the preaxial border (responding tissue) consisted of mesoderm with overlying ectoderm and apical ectodermal ridge. When the responding tissue was cultured alone, with flank, or with anterior corner limb tissue, the apical ectodermal ridge flattened in 24–36 hr and many macrophages appeared in the underlying mesoderm. When cultured with posterior border limb tissue however, the apical ridge of the responding tissue remained thickened for up to 48 hr., and no macrophages appear in the underlying mesoderm. The behavior of responding tissue was intermediate between these two extremes when cultured with mid-dorsal limb tissue. The morphogenetic activity assayed by this procedure thus seems to be present as a gradient in the wing bud, with activity decreasing from posterior to anterior. Contact with the responding tissue is not required to enable posterior border tissue to elicit ridge thickening and inhibit the cell death.     

Spatial and temporal patterns of cell death in limb bud mesoderm after apical ectodermal ridge removal

A spatiotemporal pattern of cell death occurred in the chick wing and leg bud mesoderm after removal of apical ectodermal ridge at stages 18–20. Cells died in a region extending from the limb bud distal surface to 150–200 μm into the mesoderm. Limb buds from which ridge was removed at later stages in development did not exhibit a spatiotemporal pattern of cell death. In control experiments in which dorsal ectoderm was removed, a pattern of cell death did not occur. Removal of the ridge and part of the 150- to 200-μm zone of prospective cell death resulted in cell death in an area approximately equal to the amount of the zone remaining. After removal of all of the prospective zone of cell death plus the apical ridge, cell death was observed in the remaining limb bud mesoderm. In these limb buds, cell death occurred in a region in which it had not been seen in limb bud with apical ridge alone removed. We conclude that at stages 18–20 the mesodermal cells 150–200 μm beneath the ridge require the apical ridge to survive. More proximal mesodermal cells do not die after ridge removal alone, but apparently require the presence of the more distal mesoderm to survive. Whether this is a requirement for something intrinsic to the distal mesoderm or something it possesses by way of the ridge is unknown. After stage 23, the limb mesoderm cells do not die when the apical ridge is removed. Nevertheless, at the later stages, ridge continues to be required for limb bud proximal-distal elongation and the differentiation of distal limb elements.     

Ultrastructural analysis of the apical ectodermal ridge during vertebrate limb morphogenesis: I. The human forelimb with special reference to gap junctions

The fine structure of the human forelimb apical ectodermal ridge of stages 12–19 was examined using techniques of transmission electron microscopy, freeze fracture, and scanning electron microscopy. This paper reports the presence of subcellular structures that distinguish the inductively active apical ectoderm from adjacent dorsal and ventral ectoderms.The apex of the human forelimb begins development with an epithelium of two cell layers (stage 12) which thickens at the distal tip during stages 13 and 14 into a multilayered apical ectodermal ridge. During this transition we have observed that the basal lamina differentiates from a bilayered structure to the definitive single lamina. Some cells in the ectoderm become detached from the basal lamina as stratification begins. At the same time these cells show increased mitotic activity and the developing ridge cells acquire gap junctions. Annular gap junctions are also observed. Gap junctions are not observed in adjacent, presumably noninductive, epithelia. Finally, the ridge cells next to the basal lamina acquire bundles of microfilaments that are oriented in the dorsal-ventral plane in the basal cytoplasm of the cells.The apical ridge reaches its greatest dimensions during stage 15. The number and peripheral extent of gap junctions also appear to be greatest at this same time. At stage 17, cells within the ridge begin to die, and other ridge cells engulf them. By stage 19, gap junctions in the apical epithelium are sparse and are of lesser diameter than in the definitive ridge. In addition, the oriented bundles of microfilaments present at stages 14–17 are absent. Thus, at stage 19 a morphologically distinct apical ectodermal ridge is no longer present. The apex of the limb is covered by two cell layers typical of human embryonic epidermis.     

Altered expression of the chicken homeobox-containing genes GHox-7 and GHox-8 in the limb buds of limbless mutant chick embryos.

It has been suggested that the reciprocal expression of the chicken homeobox-containing genes GHox-8 and GHox-7 by the apical ectodermal ridge and subjacent limb mesoderm might be involved in regulating the proximodistal outgrowth of the developing chick limb bud. In the present study the expression of GHox-7 and GHox-8 has been examined by in situ and dot blot hybridization in the developing limb buds of limbless mutant chick embryos. The limb buds of homozygous mutant limbless embryos form at the proper time in development (stage 17/18), but never develop an apical ectodermal ridge, fail to undergo normal elongation, and eventually degenerate. At stage 18, which is shortly following the formation of the limb bud, the expression of GHox-7 is considerably reduced (about 3-fold lower) in the mesoderm of limbless mutant limb buds compared to normal limb bud mesoderm. By stages 20 and 21, as the limb buds of limbless embryos cease outgrowth, GHox-7 expression in limbless mesoderm declines to very low levels, whereas GHox-7 expression increases in the mesoderm of normal limb buds which are undergoing outgrowth. In contrast to GHox-7, expression of GHox-8 in limbless mesoderm at stage 18 is quantitatively similar to its expression in normal limb bud mesoderm, and in limbless and normal mesoderm GHox-8 expression is highly localized in the anterior mesoderm of the limb bud. In normal limb buds, GHox-8 is also expressed in high amounts by the apical ectodermal ridge.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substance P immunoreactivity in sensory structures and the central and pharyngeal nervous system of Stenostomum leucops (Catenulida) and Microstomum lineare (Macrostomida)

Immunoreactivity (IR) obtained by monoclonal antibodies to substance P (SP) was studied in the asexually reproducing microturbellarians Stenostomum leucops and Microstomum lineare. The IR pattern was studied by confocal and ordinary fluorescence microscopy. In both species, IR occurs in the brain in peripheral cells, neuropilar fibres, in longitudinal cords and in the pharyngeal nervous system. The IR patterns reveal neuroanatomical details not observed with other neuroactive substances. In both species, immunopositive cells send fibers to the ciliary pits. In M. lineare, additional fibres run to more frontally located sensory structures. In S. leucops, two pharyngeal nerve rings are visualized. The pharyngeal nerve ring close to the surface associated with symmetrical immunopositive cell pairs is demonstrated for the first time, while the deeper-lying pharyngeal nerve ring has been previously demonstrated by antibodies to the molluscan cardioactive peptide FMRF-amide. Two cells with strong IR are connected by short fibres to the pharyngeal nerve ring in M. lineare. In the developing new individuals, i.e., the zooids of M. lineare, IR to SP is first revealed in nerve fibres growing out from parental lateral nerve cords towards the centre of the worm where the new brain commissure will appear. Immunopositive cells in the brain periphery and close to the developing ciliary pits appear later. Simultaneous staining by antibodies to SP and 5-HT shows that IR to SP appears later than IR to 5-HT.     

The origin,development, and degeneration of the pronephros in Caretta caretta

An SEM and TEM study revealed details of the development of the pronephros of Caretta caretta. The pronephros develops and degenerates over 13 days from day 7 to day 20 in embryos incubated at 33°C. Podocytes, with primary branches, secondary branches, and pedicles, on a basal lamina, can be seen from day 11, as can ciliated pronephric tubule ostia opening into the coelom. At this stage the embryo has four pharyngeal arches with unfused mandibular processes, and small fore-limb buds each with an apical ectodermal ridge. Maturation of the pronephros occurs between days 15 and 17. Degeneration begins around day 18 and is advanced by day 20 when the embryo has a fully developed face, fore-limbs with digits, and the carapace and plastron have formed.     

Initial migration and distribution of the cardiac neural crest in the avian embryo: an introduction to the concept of the circumpharyngeal crest

The distribution and migration of the cardiac neural crest was studied in chick embryos from stages 11 to 17 that were immunochemically stained in whole-mount and sectioned specimens with a monoclonal antibody, HNK-1. The following results were obtained: 1) The first phase of the migration in the cardiac crest follows the dorsolateral pathway beneath the ectoderm. 2) In the first site of arrest, the cardiac crest forms a longitudinal mass of neural-crest cells, called in the present study, the circumpharyngeal crest; this mass is located dorsolateral to the dorsal edge of the pericardium (pericardial dorsal horn) where splanchnic and somatic lateral mesoderm meet. 3) A distinctive strand of neural-crest cells, called the anterior tract, arises from the mid-otic level and ends in the circumpharyngeal crest. 4) By stage 16, after the degeneration of the first somite, another strand of neural-crest cells, called the posterior tract, appears dorsal to the circumpharyngeal crest. It forms an arch-like pathway along the anterior border of the second somite. 5) The seeding of the pharyngeal ectomesenchyme takes place before the formation of pharyngeal arches in the postotic area, i.e., the crest cells are seeded into the lateral body wall ventrally from the circumpharyngeal crest; and, by the ventral-ward regression of the pericardial dorsal horn, lateral expansion of pharyngeal pouch, and caudal regression of the pericardium, the crest cell population is pushed away by the pharyngeal pouch. Thus the pharyngeal arch ectomesenchyme is segregated. 6) By stage 14, at the occipital somite level, ventrolateral migration of the neural crest is observed within the anterior half of each somite. Some of these crest cells are continuous with the caudal portion of the circumpharyngeal crest. An early contribution to the enteric neuroblasts is apparent in this area.     

Restricted expression domains of Ezrin in developing epithelia of the chick

Ezrin is a member of the ERM- (Ezrin-Radixin-Moesin-) family of actin binding proteins, which function as linkers of the cortical cytoskeleton to components of the plasma membrane. Additional roles for Ezrin in intracellular signalling and ion channel regulation were suggested. We found Ezrin mRNA in the anterior endo- and mesoderm of chick gastrula stage embryos. In these tissues Ezrin message is strongly expressed throughout early development of the foregut (pharynx) and heart tube. During later stages of development, highly restricted expression domains of Ezrin mRNA were detected in the endodermal lining of the pharyngeal pouches, the mesonephric duct and tubuli, and in the ectodermal placodes giving rise to the inner ear, eye lens and olfactory epithelium.     

Experimental manipulation leading to induction of dorsal ectodermal ridges on normal limb buds results in a phenocopy of the eudiplopodia chick mutant

Elongation of chick limb buds depends on the presence of the apical ectodermal ridge which is induced by subjacent limb bud mesoderm. Recombination experiments have shown that the limb bud mesoderm loses the capacity to induce ridges by late stage 17. Moreover, in normal limb development only one ridge forms. However, in the eudiplopodia chick mutant accessory ectodermal ridges form on the dorsal surface of limb buds as late as stage 22. Tissue recombinant experiments show that the mutation affects the ectoderm, extending the time it responds to ridge induction (Fraser and Abbott, 1971a, Fraser and Abbott, 1971b while the mesoderm is normal. The result is polydactyly, with extra digits dorsal to the normal digits. Because eudiplopodia limb bud dorsal mesoderm can induce ridges at stage 22 but is unaffected by the gene, genetically normal dorsal limb bud mesoderm may also be able to induce ridges after stage 17. To test this possibility we grafted stages 14–18 flank ectoderm to normal limb bud dorsal mesoderm and found that mesoderm from stages 17 through 20 was able to induce a ridge and subsequently dorsal digits developed. Limbs with duplicate digits were similar to eudiplopodia limbs. In other experiments, stage 18, 19, and 20 leg bud dorsal ectoderm did not form ridges when grafted to leg bud dorsal mesoderm of the same stage, indicating a lack of response to the mesoderm. Finally, the inductive capacity of limb bud mesoderm appeared to be reduced compared to mesoderm at pre-limb bud stages. These experiments demonstrate a spatially generalized potential in limb bud dorsal mesoderm to induce ridges during the stages when the apical ridge is induced. The determination of where the ridge will form and the acquired inability of limb bud dorsal ectoderm to respond to induction by underlying mesoderm are necessary early pattern forming events which assure that a single proximodistal limb axis will form.     

TMS evidence for the involvement of the right occipital face area in early face processing

Extensive research has demonstrated that several specialized cortical regions respond preferentially to faces. One such region, located in the inferior occipital gyrus, has been dubbed the occipital face area (OFA). The OFA is the first stage in two influential face-processing models, both of which suggest that it constructs an initial representation of a face, but how and when it does so remains unclear. The present study revealed that repetitive transcranial magnetic stimulation (rTMS) targeted at the right OFA (rOFA) disrupted accurate discrimination of face parts but had no effect on the discrimination of spacing between these parts. rTMS to left OFA had no effect. A matched part and spacing discrimination task that used house stimuli showed no impairment. In a second experiment, rTMS to rOFA replicated the face-part impairment but did not produce the same effect in an adjacent area, the lateral occipital cortex. A third experiment delivered double pulses of TMS separated by 40 ms at six periods after stimulus presentation during face-part discrimination. Accuracy dropped when pulses were delivered at 60 and 100 ms only. These findings indicate that the rOFA processes face-part information at an early stage in the face-processing stream.     

Ectodermal-derived Endothelin1 is required for patterning the distal and intermediate domains of the mouse mandibular arch

Morphogenesis of the vertebrate head relies on proper dorsal-ventral (D-V) patterning of neural crest cells (NCC) within the pharyngeal arches. Endothelin-1 (Edn1)-induced signaling through the endothelin-A receptor (Ednra) is crucial for cranial NCC patterning within the mandibular portion of the first pharyngeal arch, from which the lower jaw arises. Deletion of Edn1, Ednra or endothelin-converting enzyme in mice causes perinatal lethality due to severe craniofacial birth defects. These include homeotic transformation of mandibular arch-derived structures into more maxillary-like structures, indicating a loss of NCC identity. All cranial NCCs express Ednra whereas Edn1 expression is limited to the overlying ectoderm, core paraxial mesoderm and pharyngeal pouch endoderm of the mandibular arch as well as more caudal arches. To define the developmental significance of Edn1 from each of these layers, we used Cre/loxP technology to inactivate Edn1 in a tissue-specific manner. We show that deletion of Edn1 in either the mesoderm or endoderm alone does not result in cellular or molecular changes in craniofacial development. However, ectodermal deletion of Edn1 results in craniofacial defects with concomitant changes in the expression of early mandibular arch patterning genes. Importantly, our results also both define for the first time in mice an intermediate mandibular arch domain similar to the one defined in zebrafish and show that this region is most sensitive to loss of Edn1. Together, our results illustrate an integral role for ectoderm-derived Edn1 in early arch morphogenesis, particularly in the intermediate domain.     

Morphofunctional aspects of the head capsule topography in Aculeata (Hymenoptera)]

According to degree of segmental fusion insect head is the most integrated part of the body. Head skeleton subdivides into capsule and skeleton of appendages. Exo- and endoskeleton (tentorium) of head capsule have complex segmental origin. Marked margins are generally absent between such traditionally discriminated capsule parts as clypeus, frons, vertex, occiput, genae, etc. Relative position to marked structures (appendages, eyes, ocelli, occipital foramen and etc.) defines the capsule parts, but homologization of last ones is complicated both by absence of substantive functions and complex segmental origin. Based on the technological point of view author characterizes head capsule construction in Aculeata. Capsule parts were studied as components of six technological systems associated with the head: maxillolabial, antennal, pharyngeal, optical, cranio-articulate and mandibular. Spatial relations, named by I.I. Schmalhausen as topographical co-ordinations, integrate head systems. Therefore relative position of the capsule parts incorporated in such systems is unvaried under any reconstruction. At the same time varieties of their forms and proportions reflect on form and topography of capsule as a whole. Comparative analysis of the capsule construction in Bethyloidea, Formicoidea, Sphecoidea, Vespoidea, Pompiloidea and Scolioidea has shown that many differences are determined by mutual modification of technological systems. In particular the increase in head elevation related with reconstruction of cranio-articulate system is accompanied with the shift of antennae to anterior end of the head. The capsule construction in Aculeata considered to be represented by hypognathous, prognathous and hypo-prognathous morphological types that determine head orientation towards longitudinal body axis. The role of topographical co-ordinations in formation of prognathous or hypognathous condition of the head in Aculeata is discussed.     

Gene expression pattern of Claudin-1 during chick embryogenesis

Claudins are a family of proteins that are localized to tight junctions at the apical surface of epithelial cell layers. Over 24 family members have been identified in vertebrates. Despite being well-studied with respect to their function in tight junction selectivity and permeability, the embryonic expression patterns of most claudin family members have not been thoroughly investigated. Here, we report the cloning and expression pattern of a novel chick claudin family member that is most closely related to human claudin-1. Chick claudin-1 was expressed throughout the ectoderm of stage 4-6 chick embryos. Claudin-1 expression was particularly high in the neural epithelium and open neural tube, but decreased as the neural tube closed. High levels of claudin-1 expression were also observed in the developing otic vesicle, nasal placode, ectodermal component of the pharyngeal arches, and in the apical ectodermal ridge of the limb bud from stage 17 onwards. Claudin-1 expression was also detected in scleral papillae, feather buds and migrating primordial germ cells. Lower levels of claudin-1 expression were observed in the endoderm, the ventral pharynx, and several of its derivatives including the bronchi, developing lung epithelium, esophagus, and gut. Claudin-1 expression was detected in the nephric duct and the mesonephros, which are epithelialized derivatives of the intermediate mesoderm, but not in any other mesodermal derivates, including the heart, somites and developing muscle. With the exception of the migrating primordial germ cells and the primitive streak, all other tissues that expressed significant levels of claudin-1 were epithelialized.     

An analysis of the fate of the chick wing bud apical ectodermal ridge in culture

Stages 20 and 25 chick apical ectodermal ridge have been cultured in nutrient medium containing fetal bovine serum and the tissues have been examined for dying cells at 0, 6, 12, 18, and 24 hr. By 12 hr, an average of 43% of the cells were dying. By 24 hr, stage 20 ridge had lost its integrity and stage 25 ridge contained an average of 50% dying cells. These results are in agreement with the observations of R. L. Searls and E. Zwilling (1964, Dev. Biol. 9, 38-55) on isolated stage 20 ridge. In subsequent experiments, ridge ectoderm was cultured in serum-containing medium to which insulin (5 micrograms/ml), transferrin (5 micrograms/ml), and selenium (5 ng/ml) or insulin (5 micrograms/ml) had been added. Under these conditions the ectoderms remained viable even after 24 hr in vitro.