Asymmetric expression of antivin/lefty1 in the early chick embryo

Mammalian lefty and zebrafish antivin, highly related to lefty, are shown to be expressed asymmetrically and involved in the specification of the left body side of early embryos. We isolated a chick homologue of the antivin/lefty1 cDNA and studied its expression pattern during early chick development. We found that antivin/lefty1 is expressed asymmetrically on the left side of the prospective floorplate, notochord and lateral plate mesoderm of the chick embryo.     

SOX8 expression during chick embryogenesis

We have isolated the SOX8 gene from the chicken embryo. This gene shows a high degree of sequence homology to SOX9 and SOX10. Detailed analysis of SOX8 expression by whole-mount in situ shows a dynamic and restricted expression pattern during chick development. SOX8 is expressed in the somitic derivative, the dermomyotome, the developing heart, pancreas, enteric neurone system, limb and the neural tube. This is the first detailed expression analysis of SOX8 in any species     

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.     

L-glutamate activated membrane conductivity in spinal cord neurons during early chick embryogenesis

Transient and steady-state components of L-glutamate-activated membrane currents were investigated using intracellular perfusion, voltage clamp, and concentration clamp techniques in spinal cord neurons of 6–11 day chick embryos. Hill's coefficient was found to equal 1 for transient and 2 for steady-state components. It was shown that the L-glutamate-activated receptors are present, which appear in the membrane of spinal neurons at the early stages of development.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 19, No. 2, pp. 251–258, March–April, 1987.     

Stage-specific gene expression in early chick embryo

Inhibition of DNA replication by aphidicolin in the chick morula interferes with its progression to a normal blastula and prevents induction of the first morphogenetic cell movements of primitive streak formation. Embryos in aphidicolin synthesize some polypeptides typical of blastula but do not display all the characteristic features of morula to blastula transition. Inhibition of DNA replication interferes with the sequential synthesis of maternally coded polypeptides and with the activation of the embryonic genome in the chick embryo.     

Differential expression of aortic and lung elastin genes during chick embryogenesis

The ratios of tropoelastin b to a were measured in chick aorta and lung during embryogenesis. The rates of tropoelastin a and b synthesis were determined in short-term organ culture. The results demonstrated that in lung tissue the ratio of the two tropoelastins remained essentially constant. Each of the tropoelastins comprised 50% of the total elastin synthesis. In the aortic tissue, tropoelastin b represented 70% of the total elastin in the 11- to 13-day embryos and increased to 91% by Day 16. These observations seen in the organ culture system were paralleled in measurements of functional mRNAs coding for the two proteins. Measurements of functional tropoelastin mRNAs from both lung and aortic tissues were performed in a mRNA-dependent rabbit reticulocyte lysate system. Although the changes in the abundance of the tropoelastin mRNAs revealed the same trend as that seen in the organ culture data, the magnitude of the tropoelastin b to a ratio in the aortic organ culture was twice that determined in the cell-free translation of aortic mRNAs. The data obtained from both cell-free translations and organ culture experiments demonstrate that there is a differential expression of elastin genes during aorta development which is significantly different from that found in developing lung.     

Developmental patterning of carbohydrate antigens during early embryogenesis of the chick: expression of antigens of the poly-N-acetyllactosamine series

This report describes a striking temporal and spatial patterning of specific carbohydrate sequences in the developing chick embryo. By using oligosaccharide sequence-specific monoclonal antibodies as immunohistochemical reagents in conjunction with neuraminidase, it was possible to visualize the occurrence, as well as the changes in distribution, of oligosaccharides of the poly-N-acetyllactosamine series. These were (a) long-chain unbranched sequences reactive with anti-i Den, (b) long-chain branched sequences reactive with anti-I Step and (c) short-chain branched sequences reactive with anti-I Ma and (d) their sialylated forms. The salient observations with serial sections of embryos from the unincubated to the 17th stage were as follows. (1) A pronounced anteroposterior patterning appeared during neuroectodermal development, such that the long-chain unbranched and long-chain branched sequences, which were abundant on the ectoderm of the earlier stages, were replaced by short-chain branched sialo-oligosaccharides in the developing brain and anterior neural tube. (2) A striking anteroposterior and mediolateral patterning developed in the subectodermal extracellular spaces. The long-chain linear and short-chain non-sialylated sequences demarcated regions favourable for migration of the lateral plate mesoderm. (3) A distinction was made between the dorsal and ventral routes of the trunk neural crest in that the extracellular matrix of the dorsal route only was associated with long-chain linear and short-chain sialylated branched sequences. (4) A circumscribed perinotochordal distribution of the short-chain sialylated branched sequences was observed in the region of the future centra of the vertebrae. (5) An abundance of long-chain linear and long-chain sialylated branched structures was detected in primordial germ cells which permitted their identification during migration. These observations suggest that oligosaccharides of the poly-N-acetyllactosamine series may have roles as short-range, region-specific information factors during morphogenetic events that take place in the developing embryo, and they open the way to the search for recognition proteins (e.g. endogenous lectins) specific for each of these oligosaccharide structures.     

Developmental patterning of the carbohydrate antigen FC10.2 during early embryogenesis in the chick

An oligosaccharide antigen (FC10.2), formerly described only in mammalian cells and secreted glycoproteins, has been detected and found to display striking temporal and spatial patterning in the chick during early embryonic development. This antigen is expressed on type 1 chains, which are isomers of oligosaccharides of the poly-N-acetyllactosamine series (type 2 chains). Immunoreactivities before and after neuraminidase treatment of serial sections of chick embryos during the first 17 stages of development indicate that the FC10.2 structure occurs predominantly in the sialylated form (S-FC10.2). The FC10.2 and S-FC10.2 antigens are prominent markers of the primordial germ cells, being strongly expressed by these cells from the pre-primitive streak stage onwards. S-FC10.2 is also a clear marker of the pronephric duct from its first appearance. Initially present over the entire apical surface of the ectoderm, antigenicity diminishes in an antero-posterior direction as neurulation proceeds. A unique pattern for a carbohydrate antigen is displayed by cells of the primitive streak; antigenicity is lost with de-epithelialisation and ingression, but is regained in a pericellular distribution on the mesoderm cells that emerge from the primitive streak. Thereafter, successive changes in expression and distribution of FC10.2 and S-FC10.2 are features of mesodermal tissues, particularly during somitogenesis. These antigens are prominent components of the extracellular matrix around the notochord and sclerotome cells. They are also prominent posteriorly in the subectodermal region, ceasing abruptly at the lateral limits of the embryo proper. Although no absolute correlations can yet be made, several features of the distribution of these antigens suggest that they may be integral components of, or ligands for, cell adhesion molecules.     

Syndecan-2

The members of the Syndecan family of heparan sulfate proteoglycans play diverse roles in cell adhesion and cell communication by serving as co-receptors for both cell-signaling and extracellular matrix molecules. Syndecan-2 has been implicated in the formation of specialized membrane domains and functions as a direct link between the extracellular environment and the organization of the cortical cytoplasm. Recent studies have shown that syndecan-2 is required for angiogenesis, possibly by serving as a co-receptor for vascular endothelial growth factor, and cell-to-cell signaling during development of left-right asymmetry. This unique combination of activities suggests that syndecan-2 can function as a potential drug target for the development of multi-functional, anti-cancer therapeutics.     

2 unusual cases of early embryogenesis]

Two unusual cases of early embryogenesis are described: a giant cleaving egg and the presence of two generations of embryos in the genital tract of a female--at the stage of implantation and at the stage of two blastomeres. The ability of development of the second generation was tested in vitro experiments.     

Developmental expression of zebrafish emx1 during early embryogenesis

Emx family homeobox genes, Emx1 and Emx2, play an essential role in rostral brain development in mammalian embryos. Here we report a zebrafish emx family gene, emx1, which is more similar to the mouse Emx1 gene than the previously reported zebrafish emx1 gene; we propose to rename that gene emx3. The expression of emx1 is first detected around the 10-somite stage in the pineal gland (epiphysis) primodium in the developing anterior brain and in the pronephric primodium within the intermediate mesoderm. emx1 expression in the epiphysis has not been reported in other species. Expression in the epiphysis is suppressed at 23 h post-fertilization (hpf) in the floating head (flh) mutant, in which development of the epiphysis is impaired. Subsequently, emx1 is expressed in the telencephalon, as reported in mammals, and can be detected in the olfactory placode and in a small group of cells in the forebrain at 25 hpf. In the mesoderm, emx1 expression is gradually concentrated in the posterior pronephric duct during somitogenesis, and becomes expressed predominantly in the urogenital opening at 25 hpf. Thus, emx1 displays a unique expression pattern that is distinct from the patterns of emx2 and emx3.     

P2X(3) receptor expression at early stage of mouse embryogenesis

In this study we examined the expression of P2X(3) receptor in mouse embryos from E9.5 to E14.5 using immunohistochemistry. We found a uniform labeling in the developing trigeminal and dorsal root ganglia (DRG), while adult DRG and trigeminal ganglia expressed P2X(3) only in small-diameter neurons. In the brainstem, the mesencephalic trigeminal and facial motor nuclei were immunoreactive for P2X(3). P2X(3) was also transiently expressed in the developing brain, and precursors of spinal motor neurons. We also detected immunolabeling in the paravertebral sympathetic chain ganglia, in the sympathoadrenal cells and in non-neural tissues including testis, epidermis, wall of the aorta, as well as in subepidermal structures and mesenchymal tissues of limbs, branchial arches and tail.     

CEPU-1 expression in the early embryonic chick brain

We describe the expression pattern of CEPU-1, a cell adhesion molecule of the immunoglobulin superfamily, in the early chick embryo brain. An initially broad domain of expression, encompassing forebrain, midbrain and anterior hindbrain, is subsequently narrowed down to a ring-shaped domain at the midbrain-hindbrain boundary, co-localizing precisely with the expression of Wnt1 at the isthmus. In addition, CEPU-1 is expressed in the dorsal aspect of rhombomere 4 and its emigrating neural crest cells. Later in development, we also find CEPU-1 expression in other parts of the developing nervous system such as sensory ganglia and in the ventral aspect of forebrain, midbrain and hindbrain.     

The expression and posttranslational modification of a neuron-specific beta-tubulin isotype during chick embryogenesis

Five beta-tubulin isotypes are expressed differentially during chicken brain development. One of these isotypes is encoded by the gene c beta 4 and has been assigned to an isotypic family designated as Class III (beta III). In the nervous system of higher vertebrates, beta III is synthesized exclusively by neurons. A beta III-specific monoclonal antibody was used to determine when during chick embryogenesis c beta 4 is expressed, the cellular localization of beta III, and the number of charge variants (isoforms) into which beta III can be resolved by isoelectric focusing. On Western blots, beta III is first detectable at stages 12-13. Thereafter, the relative abundance of beta III in brain increases steadily, apparently in conjunction with the rate of neural differentiation. The isotype was not detectable in non-neural tissue extracts from older embryos (days 10-14) and hatchlings. Western blots of protein separated by two-dimensional gel electrophoresis (2D-PAGE) reveal that the number of beta III isoforms increases from one to three during neural development. This evidence indicates that beta III is a substrate for developmentally regulated, multiple-site posttranslational modification. Immunocytochemical studies reveal that while c beta 4 expression is restricted predominantly to the nervous system, it is transiently expressed in some embryonic structures. More importantly, in the nervous system, immunoreactive cells were located primarily in the non-proliferative marginal zone of the neural epithelia. Regions containing primarily mitotic neuroblasts were virtually unstained. This localization pattern indicates that c beta 4 expression occurs either during or immediately following terminal mitosis, and suggests that beta III may have a unique role during early neuronal differentiation and neurite outgrowth.     

Differential expression of Eya1 and Eya2 during chick early embryonic development

Eyes absent is essential for compound eye formation in Drosophila. Its mammalian homologues of Eya are involved in the development of sensory organs, skeletal muscles and kidneys. Mutations of EYA1 in human cause branchio-oto-renal syndrome, with abnormalities in branchial derivatives, ear and kidney. For an insight into the function of Eya1 and Eya2 in early development, we performed whole-mount in situ hybridization and compared the expression patterns of these two genes in the developing chick embryos. Eya1 was first expressed in the primitive streak at Hamburger and Hamilton stage 4 (HH4) and appeared in the ectoderm and head mesenchyme distinct from migrating neural crest cells at HH6-HH11. At HH15 and HH17, the olfactory, otic and vagal/nodose placodes and cranial ganglia were positive for Eya1. In contrast, Eya2 was already expressed in the endoderm at HH4, and appeared in the endoderm and prospective placodal region at HH6-HH11. Eya2 expression was observed in pharyngeal clefts and pouches as well as cranial placodes at HH15 and HH17. These results indicate differential expression of Eya1 and Eya2, both spatially and temporally, in chick during early development. The expression patterns are somewhat different from those of other species such as Xenopus, zebrafish and mouse. The results suggest distinct and unique functions for Eya1 and Eya2 in early chick development.