Ultrastructural studies of epidermis keratinization in grass snake embryos Natrix natrix L. (Lepidosauria, Serpentes) during late embryogenesis

The changes and biochemical features of the epidermis that accompany the differentiation and embryonic shedding complex formation in grass snake Natrix natrix L. embryos were studied ultrastructurally and immunocytochemically with two panels of antibodies (AE1, AE3, AE1/AE3; anti-cytokeratin, pan mixture, Lu-5 and PCK-26). All observed changes in the ultrastructure of the cells forming the epidermal layers were associated with the physiological changes that occurred in the embryonic epidermis, such as changing of the manner of nutrition and keratinization leading to the embryonic shedding complex formation. The layers that originated first (basal, outer and inner periderm and clear layer) differentiated very early and rapidly. Rapid differentiation was also observed in the layers that are very important for the functioning of the epidermis in Natrix embryos (oberhäutchen and beta-layers). They started to differentiate at developmental stage IX, and then fused and formed the embryonic shedding complex at developmental stage XI. During the embryonic development of the grass snake the smallest changes appeared in the ultrastructure of the cells in the mesos and alpha-layers because they perform supplementary functions in the process of embryonic molting. They were undifferentiated until the end of embryonic development and started to differentiate just before the first adult molting. AE1/AE3, anti-cytokeratin, pan mixture, Lu-5 and PCK-26 antibodies immunolabeled clear layer, oberhäutchen and beta-layers at the latest phase of developmental stage XI. It should be noted that these antibodies did not immunolabel the alpha-layer until hatching. The presence of alpha-keratin immunolabeling in layers that were keratinized, particularly in the oberhäutchen and beta-layers in embryos, indicated that they were not as hard as in fully mature individuals.     

Allocation of cells to inner cell mass and trophectoderm lineages in preimplantation mouse embryos

Inner cell mass (ICM) and trophectoderm cell lineages in preimplantation mouse embryos were studied by means of iontophoretic injection of horseradish peroxidase (HRP) as a marker. HRP was injected into single blastomeres at the 2- and 8-cell stages and into single outer blastomeres at the 16-cell and late morula (about 22- to 32-cell) stages. After injection, embryos were either examined immediately for localization of HRP (controls) or they were allowed to develop until the blastocyst stage (1 to 3.5 days of culture) and examined for the distribution of labeled cells. In control embryos, HRP was confined to one or two outer blastomeres. In embryos allowed to develop into blastocysts, HRP-labeled progeny were distributed into patches of cells, showing that there is limited intermingling of cells during preimplantation development. A substantial fraction of injected blastomeres contributed descendants to both ICM and trophectoderm (95, 58, 44, and 35% for injected 2-cell, 8-cell, 16-cell, and late morula stages, respectively). Although more than half of the outer cells injected at 16-cell and late morula stages contributed descendants only to trophectoderm (53 and 63%, respectively), some outer cells contributed also to the ICM lineage even at the late morula stage. Although the mechanism for allocation of outer cells to the inner cell lineage is unknown, our observation of adjacent labeled mural trophectoderm and presumptive endoderm cells implicated polarized cell division. This observation also suggests that mural trophectoderm and presumptive endoderm are derived from common immediate progenitors. These cells appear to separate into inner and outer layers during the fifth cleavage division. Our results demonstrate the usefulness of HRP as a cell lineage marker in mouse embryos and show that the allocation of cells to ICM or trophectoderm begins after the 2-cell stage and continues into late cleavage.     

Embryonic appearance of rod opsin in the urodele amphibian eye

Notophthalmus (Triturus) viridescens, a urodele amphibian (newt) common to the Eastern United States, is a promising subject for developmental and regeneration studies. We have available a monoclonal antibody shown to be specific in many vertebrates for rod opsin, the membrane apoprotein of the visual pigment rhodopsin. This antibody to an N-terminal epitope, by rigorous biochemical and immunological criteria, recognizes only rod photoreceptor cells of the retina in light-and electron-microscopic immunocytochemistry. To determine the ontogeny and localization of rhodopsin in developing rods as an indicator of function in the embryonic urodele retina, we have utilized this antibody in the immunofluorescence technique on sections of developing N. viridescens. It was applied to serial sections of the eye region of Harrison stage 28 (optic vesicle) through stage 43 (most adult retina histology complete) embryos, and subsequently visualized with biotinylated species antibody followed by extravidin fluorescein isothiocyanate. The first positive reaction to rhodopsin could be detected in two to four cells (total) of the stage 37 embryonic eye, in the region of the central retinal primordium where the photoreceptors will be found. Some indications of retinal outer nuclear and inner plexiform layers could be seen at this time. Later embryonic stages demonstrated increasing numbers of positive cells in the future photoreceptor outer nuclear layer and outer and inner segments, spreading even to the peripheral retina. Nevertheless, by stale 43, no positive cells could be found at the dorsal or ventral retinal margins. Thus, biochemical differentiation of a photoreceptor population in the urodele retina occurs at a stage before retinal histogenesis is complete. The total maturation of retinal rods occurs topographically over a long period until the adult distribution is achieved. Correspondence to: D.S. McDevitt     

Expression of the HB9 homeobox gene concomitant with proliferation accompanying epidermal stratification during development of chick embryonic tarsometatarsal skin

A homeobox gene, HB9, has been isolated from the tarsometatarsal skin of 13-day-old chick embryos using a degenerate RT-PCR-based screening method. In situ hybridization analysis revealed that, during development of chick embryonic skin, the HB9 gene was expressed in epidermal basal cells of the placodes, but not in those of interplacodes, and in the dermal cells under the placodes at 9 days before addition of an intermediate layer by proliferation of the basal cells in the placodes. With the onset of epidermal stratification, the direction of the basal cell mitosis changed, with the axis becoming vertical to the epidermal surface. Placodes and interplacodes form outer and inner scales, respectively, after they have elongated distally (Tanaka S, Kato Y (1983b) J Exp Zool 225: 271–283). During scale ridge elongation at 12–15 days, HB9 was strongly expressed in the epidermis of the outer scale face, where the cell proliferation is more active than in the epidermis of the inner scale face; hence, stratification of the outer scale face is more prominent than that of the inner scale face. After 16 days, when mitotic activity in the epidermal basal cells decreases and the thickness of the epidermis is maintained at a constant level, the HB9 expression decreases with the onset of epidermal keratinization. These results suggest that HB9 may be involved in the proliferation of the epidermal basal cells that accompanies epidermal stratification.     

Change in the developmental fate of the chick optic vesicle from the neural retina to the telencephalon

The forebrain develops into the telencephalon, diencephalon, and optic vesicle (OV). The OV further develops into the optic cup, the inner and outer layers of which develop into the neural retina and retinal pigmented epithelium (RPE), respectively. We studied the change in fate of the OV by using embryonic transplantation and explant culture methods. OVs excised from 10-somite stage chick embryos were freed from surrounding tissues (the surface ectoderm and mesenchyme) and were transplanted back to their original position in host embryos. Expression of neural retina-specific genes, such as Rax and Vsx2 (Chx10), was downregulated in the transplants. Instead, expression of the telencephalon-specific gene Emx1 emerged in the proximal region of the transplants, and in the distal part of the transplants close to the epidermis, expression of an RPE-specific gene Mitf was observed. Explant culture studies showed that when OVs were cultured alone, Rax was continuously expressed regardless of surrounding tissues (mesenchyme and epidermis). When OVs without surrounding tissues were cultured in close contact with the anterior forebrain, Rax expression became downregulated in the explants, and Emx1 expression became upregulated. These findings indicate that chick OVs at stage 10 are bi-potential with respect to their developmental fates, either for the neural retina or for the telencephalon, and that the surrounding tissues have a pivotal role in their actual fates. An in vitro tissue culture model suggests that under the influence of the anterior forebrain and/or its surrounding tissues, the OV changes its fate from the retina to the telencephalon.     

Histochemical study of the development of the phytomelan layer in the seed coat ofGasteria verrucosa (Mill.) H. Duval

Summary In this study we document the development of the phytomelan layer in the outer epidermis of the outer integument ofGasteria verrucosa. Phytomelan has been described as a black, melanin-like substance which is chemically very inert. Using histochemical techniques we show that phytomelan development in the cell wall can be divided into three stages. The first stage is deposition of a callosic layer against the tangential wall, with simultaneous thickening of the adjacent parts of the radial walls. The second stage is the conversion of this callosic wall, which we call a tertiary wall, into a noncallosic inner and outer layer. The inner layer stains predominantly for cellulose and a little for pectin. The outer layer is of unknown composition, since it did not react with the stains that were used. In the third stage the outer tertiary layer becomes black, the phytomelan. The callosic wall deposited in the first developmental stage seems to function as a carbohydrate source and as a mould for the tertiary cell wall. The conversion of the callose in the second stage might be the result of penetration of substances which react with callose. All the components for phytomelan seem to be present in the outer layer before the conversion. Phenolics might be involved in this second conversion.Abbreviations DAP days after pollination - PAS periodic acid Schiff's reagent - PEG polyethylene glycol     

An examination of surface epithelium structures of the embryo across the genus Poeciliopsis (Poeciliidae)

In viviparous, teleost fish, with postfertilization maternal nutrient provisioning, embryonic structures that facilitate maternal‐fetal nutrient transfer are predicted to be present. For the family Poeciliidae, only a handful of morphological studies have explored these embryonic specializations. Here, we present a comparative morphological study in the viviparous poeciliid genus, Poeciliopsis . Using microscopy techniques, we examine the embryonic surface epidermis of Poeciliopsis species that vary in their level of postfertilization maternal nutrient provisioning and placentation across two phylogenetic clades and three independent evolutionary origins of placentation. We focus on surface features of the embryo that may facilitate maternal‐fetal nutrient transfer. Specifically, we studied cell apical‐surface morphology associated with the superficial epithelium that covers the body and sac (yolk and pericardial) of embryos at different developmental stages. Scanning electron microscopy revealed common surface epithelial cells across species, including pavement cells with apical‐surface microridges or microvilli and presumed ionocytes and/or mucus‐secreting cells. For three species, in the mid‐stage embryos, the surface of the body and sac were covered in microvillus epithelium. The remaining species did not display microvillus epithelium at any of the stages examined. Instead, their epithelium of the body and sac were composed of cells with apical‐surface microridges. For all species, in the late stage embryos, the surface of the body proper was composed of apical‐surface microridges in a “fingerprint‐like arrangement.” Despite the differences in the surface epithelium of embryos across Poeciliopsis species and embryonic developmental stages, this variation was not associated with the level of postfertilization maternal nutrient provisioning. We discuss these results in light of previous morphological studies of matrotrophic, teleost fish, phylogenetic relationships of Poeciliopsis species, and our earlier comparative microscopy work on the maternal tissue of the Poeciliopsis placenta.     

Light and scanning microscopic studies of integument differentiation in the grass snake Natrix natrix L. (Lepidosauria,Serpentes) during embryogenesis

We analysed the differentiation of body cover in the grass snake (Natrix natrix L.) over the full length of the embryo's body at each developmental stage. Based on investigations using both light and scanning electron microscopes, we divided the embryonic development of the grass snake integument into four phases. The shape of the epidermal cells changes first on the caudal and ventral parts of the embryo, then gradually towards the rostral and dorsal areas. In stage V on the ventral side of the embryo the gastrosteges are formed from single primordia, but on the dorsal side the epidermis forms the scale primordia in stage VII. This indicates that scalation begins on the ventral body surface, and spreads dorsally. The appearance of melanocytes between the cells of the stratum germinativum in stage VII coincides with changes in embryo colouration. The first dermal melanocytes were detected in stage XI so in this stage the definitive skin pattern is formed. In the same stage the epidermis forms the first embryonic shedding complex and the periderm layer begins to detach in small, individual flakes. This process coincides with rapid growth of the embryos.     

The expression of epidermal antigens in Xenopus laevis

Five kinds of monoclonal antibodies that are specific for the epidermis of Xenopus embryos were produced. Epidermis-specific antibodies were used to investigate the spatial and temporal expressions of epidermal antigens during embryonic and larval development. The cells that were recognized by the antibodies at the larval stage are as follows: all of the outer epidermal cells and cement gland cells were recognized by the antibody termed XEPI-1, all of the outer and inner epidermal cells, except the cement gland cells, were recognized by XEPI-2 antibody, the large mucus granules and the apical side of the outer epidermal cells, except for the ciliated epidermal cells, were recognized by XEPI-3 antibody, the large mucus granules and basement membrane were recognized by XEPI-4 antibody, and the small mucus granules contained in the outer epidermal cells as well as extracellular matrices were recognized by the antibody termed XEPI-5. All of the epidermal antigens, except XEPI-4, were first detected in the epidermal region of the late gastrula or early neurula. The XEPI-4 antigen was first detected in stage-26 tail-bud embryos. None of these antigens were expressed by the neural tissues at any time during embryonic development. Only the XEPI-2 antigen continued to be expressed after metamorphosis, while the expression of the other antigens disappeared during or before metamorphosis. The specificity of the antibodies allowed us to classify the epidermal cells into four types in early epidermal development. The four types of epidermal cells are (1) the outer epidermal cells that contain small mucus granules, (2) the ciliated epidermal cells, (3) the outer epidermal cells that contain large mucus granules and (4) the inner sensorial cells.     

Selective Degradation of Specific Components of Fertilization Coat and Differentiation of Hatching Gland Cells during the Two Phase Hatching of Bufo japonicus Embryos

The embryonic hatching process in the toad, Bufo japonicus , consists of two phases: rupture of the outer jelly strings at stage 20 (neural tube) and an escape from the inner jelly layers and fertilization coat (FC) of individual embryos at stage 23 (tailbud). SDS-PAGE analyses of FCs revealed that, of the eight major protein bands, two components with 58 K and 62 K in molecular weight gradually decreased from stage 18–19 on and totally disappeared at stage 22. When the FCs were treated with a hatching medium prepared by culturing denuded prehatching embryos, both 58 K and 62 K components of the FCs were solubilized, and in the solubilized materials 18 K and 31 K components appeared. Electron microscopy showed that a meshwork of filament bundles present in the FCs before stage 17 became dissociated at stage 19–20, and completely disappeared at stage 23, just before the hatching of embryos. Hatching gland cells (HGCs), an epidermal cell with numerous secretory granules, were first identified at stage 19, and underwent active secretion of the granules during stage 19–23. These results indicate that the hydrolytic degradation of 58K and 62 K components in FCs effected by the hatching enzyme constitutes the basic mechanism of embryonic hatching during both the first and second phases.     

The segregation of inner and outer cells in porcine embryos follows a different pattern compared to the segregation in mouse embryos

The mammalian blastocyst consists of an inner cell mass (ICM) enclosed by the trophectoderm. The origin of these two cell populations lies in the segregation of inner and outer cells in the early morula. In the present study, the segregation of inner and outer cells has been studied in porcine embryos and is compared with segregation in mouse embryos. For this, nuclei of inner and outer cells were differentially labelled with two fluorochromes after partial complement-mediated lysis of the outer cells. In porcine and mouse embryos compaction and the first appearance of inner cells occur at different stages of development. In porcine embryos compaction was observed as early as the 4-cell stage, while in mouse embryos compaction occurred in the 8-cell stage. The first inner cells segregated in porcine embryos which were in the transition from four to eight cells and inner cells were added during two subsequent cell cycles. In mouse embryos inner cells segregated predominantly during the fourth cleavage division. From the results obtained we conclude that the segregation of inner and outer cells follows a different pattern in mouse and in porcine embryos.     

Developmental rate and allocation of transgenic cells in rabbit chimeric embryos

The objective of this study was to compare developmental capacity of rabbit chimeric embryos and the allocation of the EGFP gene expression to the embryoblast (ICM) or embryonic shield. We produced chimeric embryos (TR< >N) by synchronous transfer of two or three blastomeres at the 16-cell stage from transgenic (TR) into normal host embryos (N) at the same stage. In the control group, two to three non-transgenic blastomeres were used to produce chimeric embryos. The TR embryos were produced by microinjection of EGFP into both pronuclei of fertilized rabbit eggs. The developmental rate and allocation of EGFP-positive cells of the reconstructed chimeric embryos was controlled at blastocyst (96 h PC) and embryonic shield (day 6) stage. All chimeric embryos (120/120, 100%) developed up to blastocyst stage. Using fluorescent microscope, we detected green signal (EGFP expression). In 90 chimeric (TR< >N) embryos (75%). Average total number of cells in chimeric embryos at blastocyst stage was 175+/-13.10, of which 58+/-2.76 cells were found in the ICM area. The number of EGFP-positive cells in the ICM area was 24+/-5.02 (35%). After the transfer of 50 chimeric rabbit embryos at the 16-cell stage, 20 embryos (40%) were flushed from five recipients on day 6 of pregnancy, of which five embryos (25%) were EGFP positive at the embryonic shield stage. Our results demonstrate that transgenic blastomeres in synchronous chimeric embryos reconstructed from TR embryos have an ability to develop and colonize ICM and embryonic shield area.     

Further studies on thermal treatment of two-cell stage embryos to produce complete embryonic stem-cell-derived mice by cell-aggregation methods

Employing aggregation techniques with two embryonic sources, one from two-cell stage embryos treated by thermal stimulation and the other from mouse embryonic stem (ES) cells that had been obtained from a feeder layer, simple and most effective methods of producing a complete generation of mice from ES cells were explored. Although thermal treatment affected embryos at various developmental stages, the embryos at the two-cell stage of development were selected because of the remarkably reduced number of cells present in the inner cell mass (ICM) at blastocyst stage after thermal conditioning. Under these conditions, a combination of thermally treated host embryos and an aggregated ES cell-clump was found to produce a high rate of live newborns by natural delivery. That the newborns were completely derived from ES cells was checked by two criteria: microsatellite analysis and coat color analysis. Importantly, all of these mice were healthy and fertile. The aggregation techniques reported here might well be applied to other animal species whose ES cells form stable colonies on a feeder layer.     

Development of the salivary glands in embryos of Ixodes ricinus (Acari: Ixodidae)

We examined Ixodes ricinus embryos between 18 and 28 days of development with light, scanning and transmission electron microscopy. The differences in inner structure attested to establish three successive developmental stages: days 18–20, day 23, and days 26–28. Between 18 and 20 days the embryos are at early stages of organogenesis. Salivary glands cannot be identified at that stage. In 23-day-old embryos salivary glands are already outlined but the structure of alveoles is still different from that in larvae in which the embryonic development has been completed. Gland cells start to form alveoles and become active between 26 and 28 days of the development. This revised version was published online in July 2006 with corrections to the Cover Date.     

Morphogenesis of rat cranial meninges

Summary The meninges of albino Wistar rat embryos, aged between the 11th embryonic day (ED) and birth, were sectioned using a specially constructed device. This technique permits optimal microanatomical preservation of all tissues covering the convexity of the brain: skin, muscle, cartilage or bone, and the meninges. At ED11, the zone situated between the epidermis and the brain is occupied by a mesenchymal network. At ED12, part of this delicate network develops as a dense outer cellular layer, while the remainder retains its reticular appearance, thus forming an inner layer (the future meningeal tissue). At ED13, the dura mater starts to differentiate. At ED14, the bony anlage of the skull can be identified, and along with the proceeding maturation of dura mater some fibrillar structures resembling skeletal muscle fibers appear in the developing arachnoid space. At ED15–17, a primitive interface zone — dura mater/ arachnoid — is formed, comprised by an outer electronlucent and an inner electron-dense layer marking the outer aspect of the arachnoidal space. At ED18–19, the innermost cellular row of the inner durai layer transforms into neurothelium, which is separated from the darker arachnoidal cells by an electron-dense band. The arachnoidal trabecular zone with the leptomeningeal cells is formed at ED19. By the end of the prenatal period (ED20–21), its innermost part organizes into an inner arachnoidal layer and an outer and inner pial layer. The results from this study indicate (i) that dura mater and leptomeninges develop from an embryonic network of connective tissue-forming cells, and (ii) that the formation of cerebrospinal fluid (CSF)-containing spaces accompanies the differentiation of the meningeal cellular layers.     

The carbohydrates of secretory granules and the glycocalyx in developing mucoid cells

Summary Complex carbohydrates in secretory granules and at the apical cell surface of mouse gastric mucoid cells were studied during embryogenesis and in the early postnatal period by various cytochemical methods; the periodic acid-thiocarbohydrazide-silver proteinate (PA-TCH-SP) and tannic acid-uranyl acetate (TA-UA) procedures made neutral mucosubstances (NMS) visible, whereas the hexose residues of glycoconjugates were identified using WGA-, RCA II- and ConA-ferritin. The glycocalyx was stained with ruthenium red (RR). During differentiation of the embryonic mucoid cells the number of secretory granules increased in parallel to the increase in their carbohydrate component. NMS-stainable parts in secretory granules also had binding sites for the conjugates RCA II- and WGA-ferritin, but the binding of ConA could not be identified. The increasing quantity of NMS in secretory granules was correlated with the increased amount of PA-TCH-SP and TA-UA positive substances in the apical glycocalyx only in 14- and 18-day-old embryos. The observed uniform affinity for RR and lectin conjugates in all analysed developmental stages remains to be explained.     

A scanning electron microscope study of ectodermal differentiations in the caudal mantle epithelium of embryos and juveniles of Loligo vulgaris,Loligo forbesi and Sepia officinalis

Summary

The mantle epithelium of embryos and early juveniles of the squids Loligo vulgaris and Loligo forbesi and the cuttlefish Sepia officinalis was studied using scanning electron microscopy. In embryos of L. vulgaris and L. forbesi, previously undescribed epidermal structures were found. They are missing in S. officinalis embryos. These so-called “extruding structures” are located near Hoyle's organ and first appear at stage XIII of Naef. At the same embryonic stage, Hoyle's organ starts to differentiate and “uniform-type” ciliated cells become visible in the epidermis of both L. vulgaris and L. forbesi. Directly after hatching the epidermis of the species examined starts to slough off and finally the extruding structures, Hoyle's organ and both types of ciliated cells of the mantle epithelium disappear. The function of the extruding structures remains obscure.     

Differential expression of lectin receptors in germ layers of the mouse egg cylinder and teratocarcinomas

Receptors for three lectins with restricted specificities, namely fucose-binding protein of Lotus tetragonolobus (FBP), peanut agglutinin (PNA) and Dolichos biflorus agglutinin (DBA), were distinctively located in 6- and 7-day mouse embryos and in embryoid bodies of teratocarcinoraa OTT6050 grown in vivo. Thus, FBP reacted mainly with the inner cells (embryonic ectoderm and teratocarcinoma stem cells), DBA reacted with the outer cells (endoderm) and PNA reacted with all the germ layers including mesoderm. Upon in vitro culture of the embryoid bodies, the exposed stem cells express DBA receptors. Since the receptors for the three lectins in teratocarcinomas are known to be carried by the large carbohydrate chains characteristic of early embryonic cells, the present result suggests that terminal structure of the large carbohydrates is altered according to the direction of the differentiation or to the position of the cells in embryos and in teratocarcinomas.     

Evaluation of anionic histological dyes as co-injectable cell markers in pre-implantation mouse embryos

The enzyme horseradish peroxidase (HRP) is a widely used microinjectable cell marker for studying cell position, lineage, and migration in many kinds of animal embryos. Marked cells are easily identified because they darken when exposed to a chromophore and an HRP substrate such as hydrogen peroxide. This assay, however, requires cytochemical fixation. Thus, when HRP-marked cells need to be identified prior to fixation, visible co-injectants such as dyes and fluorescent substances have been used with HRP. Fluorescent substances have limitations because their excitation could be harmful to the marked cells. Visible but non-fluorescent co-injectants, however, would permit visualization of HRP-marked cells without inflicting such damage. We tested the compatibility of several histological dyes and electrolytic carriers with HRP iontophoresed as a cell marker in 2-cell mouse embryos. The dyes tested were Evans Blue, Cibacron Blue F3GA, Fast Green FCF, and Patent Blue Violet; the electrolytic carriers were KCl, K2SO4, CH3CO2K, and KH2PO4. The combination found most useful was Patent Blue Violet in K2SO4. Survival of embryos incubated to the blastocyst stage following injection with HRP + Patent Blue Violet in K2SO4 at the 2-cell stage was significantly greater than that of embryos injected with any other dye. Although the proportion of embryos undergoing the 8-cell-to-morula transition was somewhat decreased by this treatment, the proportion of embryos reaching the blastocyst stage was comparable to that in the uninjected (control) group. Our results indicate that Patent Blue Violet is a useful, HRP-co-injectable dye for short-term cell marking in preimplantation mouse embryos.