Induction and improved embryonic development by the nucleus of Pander in associated avian blastoderm parts: influence of delta or gamma ooplasm

After placing in vitro, central subgerminal ooplasm (containing a central nucleus of Pander) from a quail germ disc of a prelaid egg (before symmetrization) on the upper layer of an isolated chicken antisickle, we observed the induction of a radially oriented preneural plate (without interference of chordamesoblast). This observation suggests the primary existence during the period of symmetrization in utero of an until now unknown temporospatially linked "vertical" effect, emanating from the nucleus of Pander, on the parallel (pre)neural plate anlage forming part of the area centralis in the overlying blastoderm. For comparison, we "sandwiched" in vitro a quail sickle endoblast fragment between the deep side of the upper layer of an isolated chicken antisickle region and a central subgerminal ooplasmic mass. This resulted in a colonization of the subgerminal ooplasmic mass by quail sickle endoblast cells followed by improved neurulation and/or gastrulation phenomena. The latter never occurs in the absence of central subgerminal ooplasm. In both types of experiments there seems to exist a common link between the observed induction phenomena: the presence of delta ooplasm in the involved deep structures. Indeed, the nucleus of Pander contains delta ooplasm as well as the structures derived from it, i.e., endophyll with primordial germ cells and sickle endoblast-derived cells after colonization of the neighboring central ooplasm (present study). Therefore, we think that the preneural plate-inducing effect observed after placing a nucleus of Pander on the antisickle region is due to the presence of a factor in the delta ooplasm that diffuses in the neighborhood. The appearance of gastrulation phenomena in the second type of experiment seems to be due to colonization of the more peripheral part of the central subgerminal ooplasm containing the more superficial and peripheral gamma ooplasm in which Rauber's sickle material can develop. This suggests that the kind of involved ooplasm (delta or gamma) can predetermine the inductive activity of the deep structures that contain it: the central part of the nucleus of Pander and/or endophyll for preneurulation phenomena and sickle endoblast (in the presence of central subgerminal ooplasm) for gastrulation and/or neurulation phenomena.     

Dorso-ventral polarity of the zebrafish embryo is distinguishable prior to the onset of gastrulation

We describe a set of observations on developing zebrafish embryos and discuss the main conclusions they allow:(1) the embryonic dorso-ventral polarity axis is morphologically distinguishable prior to the onset of gastrulation; and (2) the involution of deep layer cells starts on the prospective dorsal side of the embryo. An asymmetry can be distinguished in the organization of the blastomeres in the zebrafish blastula at the 30% epiboly stage, in that one sector of the blastoderm is thicker than the other. Dye-labelling experiments with DiI and DiO and histological analysis allow us to conclude that the embryonic shield will form on the thinner side of the blastoderm. Therefore, this side corresponds to the prospective dorsal side of the embryo. Simultaneous injections of dyes on the thinner side of the blastoderm and on the opposite side show that involution of deep layer cells during gastrulation starts at the site at which the embryonic shield will form and extends from here to the prospective ventral regions of the germ ring.     

Xenotransplantation of Human Stem Cells into the Chicken Embryo

The chicken embryo is a classical animal model for studying normal embryonic and fetal development and for xenotransplantation experiments to study the behavior of cells in a standardized in vivo environment. The main advantages of the chicken embryo include low cost, high accessibility, ease of surgical manipulation and lack of a fully developed immune system. Xenotransplantation into chicken embryos can provide valuable information about cell proliferation, differentiation and behavior, the responses of cells to signals in defined embryonic tissue niches, and tumorigenic potential. Transplanting cells into chicken embryos can also be a step towards transplantation experiments in other animal models. Recently the chicken embryo has been used to evaluate the neurogenic potential of human stem and progenitor cells following implantation into neural anlage^1-6. In this video we document the entire procedure for transplanting human stem cells into the developing central nervous system of the chicken embryo. The procedure starts with incubation of fertilized eggs until embryos of the desired age have developed. The eggshell is then opened, and the embryo contrasted by injecting dye between the embryo and the yolk. Small lesions are made in the neural tube using microsurgery, creating a regenerative site for cell deposition that promotes subsequent integration into the host tissue. We demonstrate injections of human stem cells into such lesions made in the part of the neural tube that forms the hindbrain and the spinal cord, and into the lumen of the part of the neural tube that forms the brain. Systemic injections into extraembryonic veins and arteries are also demonstrated as an alternative way to deliver cells to vascularized tissues including the central nervous system. Finally we show how to remove the embryo from the egg after several days of further development and how to dissect the spinal cord free for subsequent physiological, histological or biochemical analyses.     

Relationship between ectopic germinal vesicle breakdown in Xenopus oocytes and dorsal development of the embryo

The early development of several species involves the segregation of cytoplasmic components into different regions of the egg. In Xenopus zygotes, a 30° rotation displaces the central animal cytoplasm to the future dorsal side of the embryo. To elucidate the role of the central animal cytoplasm in dorsal determination, we induced germinal vesicle breakdown (GVBD) closer to the equator by cold/centrifugation treatment of oocytes. Centrifugation moved the germinal vesicle to the centripetal side; eggs with such displaced GVBD fertilized and began to develop normally. Dorsal embryonic structures tended to develop on the GVBD side of the egg, but displacement of the GVBD was insufficient to rescue dorsal structures in axis-deficient embryos. The labeling of yolk platelets of oocytes with Trypan Blue revealed similar cytoplasmic patterns in control and treated eggs. Furthermore, 67% of treated eggs had Danilchik's swirl, indicative of the dorsal side, on the GVBD side. In conclusion, both the swirl and dorsal development tend to occur on the GVBD side of cold/centrifuged eggs; however, displaced GVBD cannot by itself determine dorsality.     

Expression of a novel cadherin (EP-cadherin) in unfertilized eggs and early Xenopus embryos

Two distinct cadherin cDNA clones of Xenopus laevis were isolated from a stage 17 embryo cDNA library. Analysis of the complete deduced amino acid sequences indicated that one of these molecules is closely homologous to chicken and mouse N-cadherin, while the other displays comparable homology to both E- and P-cadherins and was thus denoted EP-cadherin. This molecule has an apparent relative molecular mass of 125 x 10(3) (compared to approx. 138 x 10(3) or approx. 140 x 10(3) of E-cadherin and N-cadherins, respectively). Northern and Western blot analyses indicated that N-cadherin is first expressed at the neurula stage while EP-cadherin is the only cadherin detected in unfertilized eggs and cleavage stage embryos. Immunolabeling of Xenopus eggs with antibodies prepared against a fusion protein, containing a segment of EP-cadherin, indicated that the protein is highly enriched at the periphery of the animal hemisphere. EP-cadherin was also found in A6 epithelial cells derived from Xenopus kidneys, and was apparently localized in the intercellular adherens junctions.     

Early steps in neural development

We studied early neurulation events in vitro by transplanting quail Hensen's node, central prenodal regions (before the nodus as such develops), or upper layer parts of it on the not yet definitively committed upper layer of chicken anti-sickle regions (of unincubated blastoderms), eventually associated with central blastoderm fragments. We could demonstrate by this quail-chicken chimera technique that after the appearance of a pronounced thickening of the chicken upper layer by the early inductive effect of neighboring endophyll, a floor plate forms by insertion of Hensen's node-derived quail cells into the median part of the groove. This favors, at an early stage, the floor plate "allocation" model that postulates a common origin for notochord and median floor plate cells from the vertebrate's secondary major organizer (Hensen's node in this case). A comparison is made with results obtained after transplantation of similar Hensen's nodes in isolated chicken endophyll walls or with previously obtained results after the use of the grafting procedure in the endophyll walls of whole chicken blastoderms.     

In vitro formation of the "S" layer, a unique component of the fertilization envelope in Xenopus laevis eggs

The extracellular matrix (ECM) of unfertilized Xenopus laevis eggs consists of an elaborate filamentous network in the perivitelline space (PS) and a thick fibrillar vitelline envelope (VE), with a thin layer of horizontal filaments (HF) separating the two. At fertilization this ECM is converted into the fertilization envelope (comprised of the fertilization (F) layer and altered VE), and a third layer, the smooth (S) layer, is formed at the upper boundary of the PS (Larabell and Chandler, 1988). In this report, we use quick-freeze, deep-etch, rotary-shadow electron microscopy to show that an intact S layer can be formed in vitro by incubation of unfertilized eggs in an exudate obtained from cortical granules. Within 5 min numerous 36-nm-diameter particles assemble in a highly ordered array at the microvillar tips. These particles appear to "melt" and to form patches of smooth material and within 10 min one continuous sheet has formed. The presence of the VE is required for formation of the S layer, and we suggest that the HF layer is the site of assembly.     

Interaction of central subgerminal ooplasm with the elementary tissues (endophyll, Rauber's sickle and upper layer) of unincubated avian blastoderms in culture

By placing a central subgerminal ooplasmic mass over isolated parts (alone or in association) of unincubated avian blastoderms and culture, we obtained an improvement in, or in some cases restoration of normal development. The evolution of small rectangular fragments (isolates) excised from different regions of the unincubated blastoderm was observed in association or not with subgerminal ooplasm. The only type of differentiation that was clearly distinguished in these isolates (taken from the caudocentral area centralis region) was a so-called 'primary neurula' formed by the endophyll and an associated thickened upper layer. In the present study, we also demonstrate that after removal of the area centralis from an unincubated caudal blastoderm quadrant, the upper layer (UL) and endophyll can no longer be restored from the associated subgerminal ooplasm (and form a miniature embryo), as is the case after removal of the endophyll alone. A deep layer (containing the endophyll) reformed during the migration of Rauber's sickle-derived cells into the neighbouring central subgerminal ooplasm only in the presence of the upper layer. This suggests that the upper layer has an early influence on the cells containing the original central deep ooplasm (delta ooplasm) to form the endophyll. The present study offers supplementary arguments in favour of the hypothesis that the endophyll is an inductor of preneurulation.     

Vimentin expression in oocytes, eggs and early embryos of Xenopus laevis

Immunocytochemical studies using a monoclonal anti-porcine vimentin antibody reveal a well-organized pattern of staining in Xenopus laevis oocytes, eggs and early embryos. The positions of Xenopus vimentin and desmin in two-dimensional (2D) polyacrylamide gels were first established by immunoblotting of muscle Triton extracts with anti-intermediate filament antibodies (anti-IFA), which cross-react with all intermediate filament proteins (IFPs). The anti-porcine vimentin reacts with vimentin and desmin in muscle 2D immunoblots, but only reacts with one polypeptide in oocyte blots in the position predicted for vimentin (Mr 55 x 10(3), pI 5.6). Using an anti-sense probe derived from a Xenopus vimentin genomic clone in RNase protection assays, we show that expression of vimentin begins in previtellogenic oocytes. The level of expression remains constant throughout oogenesis and in unfertilized eggs. These data suggest that vimentin is expressed in oocytes and eggs. Most interestingly, the immunocytochemical results also show that vimentin is present in the germ plasma of oocytes, eggs and early embryos. It is therefore possible that vimentin has an important role in the formation or behaviour of early germ line cells.     

Deep cytoplasmic rearrangements during early development in Xenopus laevis

The egg of the frog Xenopus is cylindrically symmetrical about its animal-vegetal axis before fertilization. Midway through the first cell cycle, the yolky subcortical cytoplasm rotates 30 degrees relative to the cortex and plasma membrane, usually toward the side of the sperm entry point. Dorsal embryonic structures always develop on the side away from which the cytoplasm moves. Details of the deep cytoplasmic movements associated with the cortical rotation were studied in eggs vitally stained during oogenesis with a yolk platelet-specific fluorescent dye. During the first cell cycle, eggs labelled in this way develop a complicated swirl of cytoplasm in the animal hemisphere. This pattern is most prominent on the side away from which the vegetal yolk moves, and thus correlates in position with the prospective dorsal side of the embryo. Although the pattern is initially most evident near the egg's equator or marginal zone, extensive rearrangements associated with cleavage furrowing (cytoplasmic ingression) relocate portions of the swirl to vegetal blastomeres on the prospective dorsal side.     

The thermal energetics of an incubated chicken egg

I incubated chicken eggs using an artificial brood patch, which enabled me to measure the energy required to keep chicken eggs, 16–19 days old, warmer than the ambient air. To keep brood patch temperature (i.e. at the egg surface-brood patch interface) 9.4°C warmer than the ambient air, living chicken eggs require on average 541 mW, of which 403 mW is supplied by the parent, the remainder being supplied by the embryo. Killing the embryo reduces the power required to only 322 mW for the same elevation of the brood patch temperature, all of it supplied by the brood patch. Killing the embryo causes central egg temperature to decline by about 2.0°C. Contrary to widely held opinion, it is embryonic circulation, not embryonic metabolism that is the most important cause of elevated temperature of incubated eggs. The implications of this for incubation energetics are discussed.     

Sea urchin egg hyaline layer: evidence for the localization of hyalin on the unfertilized egg surface

The sea urchin embryo hyaline layer is an extracellular investment which develops within 20 min postinsemination of Strongylocentrotus purpuratus eggs and contains a single calcium-precipitable subunit termed hyalin. Other ultrastructural and biochemical studies have suggested that hyalin is localized in the cortical granules. We have examined the hypothesis that hyalin is a cell surface protein of the unfertilized egg using vectorial lactoperoxidase-catalyzed radioiodination. Extracts of labeled unfertilized eggs contained several labeled proteins, one of which was electrophoretically indistinguishable from authentic hyalin isolated by each of three different procedures. Pronase digestion of labeled unfertilized eggs removed 75% of the label, but the labeled hyalin-like molecule was still present in whole cell extracts. Upon insemination, pronase-digested, labeled eggs formed an apparently normal hyaline layer and whole cell extracts contained the labeled hyalin-like molecule. Denuded, labeled eggs were inseminated and the hyaline layer was selectively solubilized in calcium- and magnesium-free artificial seawater. Labeled hyalin was purified from this crude hyalin preparation to constant specific radioactivity and apparent homogeneity as shown by gel electrophoresis. These data strongly suggest that hyalin or a precursor is a cell surface protein of the unfertilized sea urchin egg.     

Immunoelectron Microscopic Demonstration of Cortical Granule Lectins in Coelomic, Unfertilized and Fertilized Eggs of Xenopus laevis

Immunoelectron microscopic studies demonstrated cortical granule lectins (CGLs) in coelomic, unfertilized and fertilized eggs of Xenopus laevis . An antiserum raised against purified cortical granule lectin 1 specifically reacted with the CGLs in immunoblotting and agar diffusion tests. When ultrathin sections were treated with the antiserum and protein A-gold solution, gold particles, indicating antigenic sites, were seen over cortical granules of coelomic and unfertilized eggs, and over the perivitelline space, the vitelline coat and the condensed region of the fertilization layer of fertilized eggs. The pre-fertilization layer immediately adjacent to the outer margin of the vitelline coat in unfertilized eggs was free from gold particles. These observations suggest that released CGLs permeate through the vitelline coat of fertilized eggs and interact with the pre-fertilization layer mainly at the outer margin of the vitelline coat, resulting in formation of the fertilization layer which acts as a block to polyspermy.     

Purification of a novel, nucleoplasmin-like protein from somatic nuclei.

We have purified a nucleoplasmin-like protein from the nuclei of somatic Xenopus laevis cells. This protein possesses a number of the distinctive features of nucleoplasmin isolated from oocytes or unfertilized eggs. The protein is recognized by both monoclonal and polyclonal antisera raised against egg nucleoplasmin. The protein has an oligomeric structure, which must be heated in SDS to completely dissociate, is acidic, phosphorylated and efficiently promotes the in vitro formation of chromatin. We have partially characterized this novel protein and because of its resemblance to nucleoplasmin isolated from oocytes or unfertilized eggs we have named this protein nucleoplasmin S.     

Effect of gravity on the interaction between the avian germ and neighbouring ooplasm in inverted egg yolk balls

The developmental capacities of an avian germ (from before symmetrization to the moment of laying) are strongly diminished after inversion of its egg yolk ball followed by culture in egg white. Our present experiments show that even when the avian germ is completely horizontally inverted (without an upper or lower border) below its egg yolk ball before symmetrization, symmetrization and gastrulation phenomena take place. The germ grows slower and becomes smaller than after normal incubation. After culture of inverted unincubated germs, localized on freshly laid eggs, the closure of the neural tube is impaired and it remains open over a long distance. Although a primitive streak (PS) develops, mesoderm migration (mainly from the lateral part of the area pellucida) is also impaired. On sections through the germinal disc one can see the abnormal upward migration into the depth of the ooplasm and yolk of cells from the germ wall and the development of large cellular extensions encircling the yolk globules. Most prominent is the loss of contact between the superficial cell layers and the deep layer elements (junctional endoblast and yolk endoblast in the area opaca). Large areas without deep layer elements (even visible on surface micrographs) develop in the area vasculosa and area vitellina interna. The margin of overgrowth grows and extends normally over the egg yolk ball. An autoradiographic study after labelling of the yolk layers in inverted egg yolks reveals that mainly compression of the peripheral subgerminal and perigerminal ooplasm takes place. This suggests that the compression by the neighbouring yolk and upwards growth of cells are at the origin of the impaired development. After return to the normal upward orientation of the germ on the topmost part of the egg yolk ball, a more or less pronounced restoration to normal development takes place (depending on the duration of the inversion period and the age of the germ).     

A genetic screen for zygotic embryonic lethal mutations affecting cuticular morphology in the wasp Nasonia vitripennis

We have screened for zygotic embryonic lethal mutations affecting cuticular morphology in Nasonia vitripennis (Hymenoptera; Chalcidoidea). Our broad goal was to investigate the use of Nasonia for genetically surveying conservation and change in regulatory gene systems, as a means to understand the diversity of developmental strategies that have arisen during the course of evolution. Specifically, we aim to compare anteroposterior patterning gene functions in two long germ band insects, Nasonia and Drosophila. In Nasonia, unfertilized eggs develop as haploid males while fertilized eggs develop as diploid females, so the entire genome can be screened for recessive zygotic mutations by examining the progeny of F1 females. We describe 74 of >100 lines with embryonic cuticular mutant phenotypes, including representatives of coordinate, gap, pair-rule, segment polarity, homeotic, and Polycomb group functions, as well as mutants with novel phenotypes not directly comparable to those of known Drosophila genes. We conclude that Nasonia is a tractable experimental organism for comparative developmental genetic study. The mutants isolated here have begun to outline the extent of conservation and change in the genetic programs controlling embryonic patterning in Nasonia and Drosophila.     

Rauber's sickle and not the caudal marginal zone induces a primitive streak, blood vessels, blood cell formation and coelomic vesicles in avian blastoderms

By using the quail-chicken chimera technique, we studied the reactivity and the eventual developmental or inducing capacities of the avian caudal marginal zone (in comparison with Rauber's sickle), when associated in vitro with different avian blastoderm components. If a fragment of quail sickle endoblast is placed on the caudal marginal zone of a whole unincubated chicken blastoderm, then a secondary miniature embryo will develop in this caudal marginal zone. The primitive streak and accompanying neural plate of the secondary embryo are directed peripherally into the caudal germ wall, away from Rauber's sickle. Thus, the 'mirror image development' indicates that the upper layer of the caudal marginal zone can react in the same way as the upper layer of the area centralis, because of the presence of sickle endoblast. A quail Rauber's sickle fragment placed on an isolated anti-sickle region always induces a primitive streak directed centrally. After prolonged culture, blood vessels and associated coelomic vesicles are formed. By contrast if a quail caudal marginal zone is placed on an isolated chicken anti-sickle region, the primitive streak, blood vessels and coelomic vesicles do not form. Thus, in contrast to the inducing effect of Rauber's sickle, the caudal marginal zone has no inducing effect by itself, even in the absence of the dominating effect of Rauber's sickle.