Spatial aspects of neural induction in Xenopus laevis

A monoclonal antibody, 2G9, has been identified and characterised as a marker of neural differentiation in Xenopus. The epitope is present throughout the adult central nervous system and in peripheral nerves. Staining is first detected in embryos at stage 21 in the thoracic region. By stage 29 it stains the whole central nervous system, except the tail tip. The epitope is present in a 65K Mr protein, and includes sialic acid. The antibody also reacts with neural tissue in mice and axolotls and newts. 2G9 was used to show that both notochord and somites are capable of neural induction, and the stimulus is present as late as stage 22. Attempts to demonstrate the induction of nervous system by developing nervous system (homoiogenetic induction) were unsuccessful. The view that the lateral extent of the nervous system might be determined by that of the inductive stimulus is discussed. Neural induction was detected as early as stage 10 and occurs in embryos without gastrulation and without cell division from stage 7 1/2.     

Pituitary adenylate cyclase-activating polypeptide type 1 (PAC1) receptor is expressed during embryonic development of the earthworm

Pituitary adenylate cyclase activating polypeptide (PACAP)-like molecules have been shown to be present in cocoon albumin and in Eisenia fetida embryos at an early developmental stage (E1) by immunocytochemistry and radioimmunoassay. Here, we focus on detecting the stage at which PAC1 receptor (PAC1R)-like immunoreactivity first appears in germinal layers and structures, e.g., various parts of the central nervous system (CNS), in developing earthworm embryos. PAC1R-like immunoreactivity was revealed by Western blot and Far Western blot as early as the E2 developmental stage, occurring in the ectoderm and later in specific neurons of the developing CNS. Labeled CNS neurons were first seen in the supraesophageal ganglion (brain) and subsequently in the subesophageal and ventral nerve cord ganglia. Ultrastructurally, PAC1Rs were located mainly on plasma membranes and intracellular membranes, especially on cisternae of the endoplasmic reticulum. Therefore, PACAP-like compounds probably influence the differentiation of germinal layers (at least the ectoderm) and of some neurons and might act as signaling molecules during earthworm embryonic development.     

The Loss of the Expression of α Catenin, the 102 kD Cadherin Associated Protein, in Central Nervous Tissues during Development

A monoclonal antibody specific for α catenin, the 102kD cadherin-associated protein, has been characterized and used to describe the expression and distribution pattern of α catenin in adult mice and mouse embryos. This monoclonal antibody recognized an epitope in the middle part of the α catenin molecule of various vertebrate species, and bound to neither vinculin nor αN catenin, which are cytoskeletal proteins with sequence similarity to α catenin. At the early mouse embryo stage (neurulae stage) α catenin was expressed and concentrated at cell-to-cell contact sites together with various types of cadherins in all tissues. In embryos at 12.5 days of gestation, the α catenin expression was gradually diminished selectively in central nervous tissues such as brain and spinal cord, and in most of the adult central nervous tissues the α catenin expression was hardly detected. In adult non-nervous tissues most of the cells examined expressed α catenin. Especially in well-polarized tissues such as epithelial cells, α catenin appeared to be highly concentrated at cell-to-cell adherens junctions where cadherins act as adhesion molecules.
This loss of α catenin expression in central nervous tissues was observed not only in mice but also in other vertebrate species such as fish and newt, suggesting that this phenomenon has important implications from the view point of nervous tissue development.     

Frog lim-1-like protein is expressed predominantly in the nervous tissue, gonads, and early embryos of the bivalve mollusc Mytilus galloprovincialis

In a few well-known cases, the biological consequences of the disruption of lim-1 homeodomain (HD) genes have demonstrated the important roles of these genes in vertebrate development, especially in the nervous tissue, kidney, and gonads. Functional assay approaches require information not only about lim-1 gene organization, but also about properties and tissue localization of Lim-1 proteins. Although lim-1 genes have been identified in certain phyla of invertebrates, no information is available on Lim-1 proteins and genes in bivalve molluscs. Our study represents the beginning stage of identification of the Lim-1-related proteins in marine bivalves. Using antibodies against the C-terminal region of the Xenopus laevis Lim-1 protein, we describe cross-reactive antigen patterns in adults and early embryos of the mussel Mytilus galloprovincialis, as well as in sea urchin and chick embryos. In adult mussels, nervous ganglia and gonads display the most prominent Lim-1 immunoreactivity. Further, the antibodies verified the prediction that mussel Lim-1 antigens, like Lim-1 HD proteins in general, can be localized in the nucleus. Moreover, antibody detection allowed us to identify the Lim-1-like antigens in unfertilized mature eggs, as well as in very early embryos of bivalve molluscs and sea urchins (Strongylocentrotus purpuratus). In mussel eggs and embryos, Lim-1 antigens are expressed in multiple forms (40, 45, and 65 kDa), as detected by SDS-PAGE followed by Western blot. Taken together, the observations emphasize the conservation of the Lim-1 protein expression pattern in the nervous tissue and gonads of different animal groups, and demonstrate that Lim-1-like polypeptides can be maternally accumulated in eggs and, therefore, are present in very early embryos before zygotic expression of the genes begins.     

Developmental profile of three enolase isozymes in rat brain determination from one-cell embryo to adult brain

Levels of three enolase isozymes (αα, αγ and γγ) were determined in rat tissues from one-cell embryo to adult brain with a sensitive enzyme immunoassay system. Each embryo of the early stage (gestational age, 0–3 days) contained about 5 × 10^?17 mol of αα enolase. The nervous system-specific αγ and γγ enolases would be detected in the embryos of 6–8 days, which contain no histologically recognizable neurones. The 8-day embryos contained 4.3 × 10^?17 and 3.4 × 10^?16 mol of αγ and γγ enolases. Amounts of all the three enolases were increased with growth of the embryo. The nervous system-specific enolases (αγ and γγ) in the brain kept increasing until 1–2 months of postnatal age, whereas the αα enolase level in the brain was relatively constant after the 15-day embryo through the adult rat.     

Expression of protein kinase C genes during ontogenic development of the central nervous system.

We have analyzed the RNA expression of three protein kinase C (PKC) genes (alpha, beta, and gamma) in human and murine central nervous systems during embryonic-fetal, perinatal, and adult life. Analysis of human brain poly(A)+ RNA indicates that expression of PKC alpha and beta genes can be detected as early as 6 weeks postconception, undergoes a gradual increase until 9 weeks postconception, and reaches its highest level in the adult stage, and that the PKC gamma gene, although not expressed during embryonic and early fetal development, is abundantly expressed in the adult period. Similar developmental patterns were observed in human spinal cord and medulla oblongata. A detailed analysis of PKC gene expression during mammalian ontogeny was performed on poly(A)+ RNA from the brain cells of murine embryos at different stages of development and the brain cells of neonatal and adult mice. The ontogenetic patterns were similar to those observed for human brain. Furthermore, we observed that the expression of PKC gamma is induced in the peri- and postnatal phases. These results suggest that expression of PKC alpha, beta, and gamma genes possibly mediates the development of central neuronal functions, and expression of PKC gamma in particular may be involved in the development of peri- and postnatal functions.     

Regulation and role of PDGF receptor alpha-subunit expression during embryogenesis.

The platelet-derived growth factor receptor alpha-subunit (PDGFR alpha) is the form of the PDGF receptor that is required for binding of PDGF A-chain. Expression of PDGFR alpha within the early embryo is first detected as the mesoderm forms, and remains characteristic of many mesodermal derivatives during later development. By 9.5 days of development, embryos homozygous for the Patch mutation (a deletion of the PDGFR alpha) display obvious growth retardation and deficiencies in mesodermal structures, resulting in the death of more than half of these embryos. Mutant embryos that survive this first critical period are viable until a new set of defects become apparent in most connective tissues. For example, the skin is missing the dermis and connective tissue components are reduced in many organs. By this stage, expression of PDGFR alpha mRNA is also found in neural crest-derived mesenchyme, and late embryonic defects are associated with both mesodermal and neural crest derivatives. Except for the neural crest, the lens and choroid plexus, PDGFR alpha mRNA is not detected in ectodermal derivatives until late in development in the central nervous system. Expression is not detected in any embryonic endodermal derivative at any stage of development. These results demonstrate that PDGFR alpha is differentially expressed during development and that this expression is necessary for the development of specific tissues.     

Molecular cloning,expression and partial characterization of Xksy,Xenopus member of the Sky family of receptor tyrosine kinases

We isolated a cDNA encoding the Xenopus member of Sky/Axl/Mer receptor tyrosine kinase family (referred as Sky family), termed Xksy. The predicted Xksy protein has conserved structural characteristics of the Sky family: an unique extracellular domain of two immunoglobulin (Ig)-like repeats, two fibronectin type III (FNIII)-like repeats and an intracellular tyrosine kinase. Homology analysis of Xksy showed the highest identity to mammalian Sky protein. In contrast to the predominant expression of sky mRNA in the adult mammalian nervous system, Northern blot analysis showed ubiquitous expression of a single 5.2-kb Xksy mRNA in tissues of the adult Xenopus. RNase protection assays revealed that, during development, Xksy mRNA is expressed from mid neurulation stage. Levels increase through the tadpole stage and become restricted to the head region in embryos by stage 40. Whole-mount in situ hybridization analyses revealed that expression of Xksy is localized to the nervous system of the tadpole stage, including origins of sensory organs and branchial arches. When a chimeric receptor (EGFR-Xksy), composed of the extracellular region of epidermal growth factor (EGF) receptor and the transmembrane/intracellular regions of Xksy, was expressed in a doxycycline repressive manner in HEK 293 cells, EGF-stimulus without doxycycline induced tyrosine phosphorylation of the chimeric receptor and evoke morphological changes. EGF treatment also induced growth modifications of EGFR-Xksy cells. And doxycycline pre-treatment eliminated these activities. These findings suggest that Xksy may play an important role in growth, differentiation and the accurate migration of cells during embryogenesis and early neural development.     

NKD, a developmentally regulated tachykinin receptor in Drosophila.

A number of neuropeptides have been described which are present in the insect nervous system. The physiological role of these neuropeptides has not yet been clarified. We have characterized a Drosophila melanogaster cDNA coding for a protein, NKD, whose sequence resembles that of mammalian G protein-coupled neuropeptide receptors. This protein shows 38% homology with the mammalian tachykinin NK3 receptor within the transmembrane domain region. Stable cell lines expressing this cDNA are responsive to Locusta migratoria tachykinin but not to other peptides of the tachykinin family. The expression of this gene is detected principally in adult fly heads, but also in the adult body and in embryos. Interestingly, NKD mRNA is detected at very early stages of Drosophila embryonic development (3 h) and reaches the highest level of expression at 12-16 h, a time which correlates with the period of major neuronal development. In situ hybridization experiments demonstrate that NKD is expressed in the central nervous system, as well as in subsets of neurons in each segment of the developing ventral ganglia. The cytological localization of this gene is at position 86C on the Drosophila third chromosome.     

Neogenin and repulsive guidance molecule signaling in the central nervous system

The repulsive guidance molecule (RGM) is a membrane-bound protein that was originally identified as an axon guidance molecule in the visual system. Functional studies have revealed that it has roles in axon guidance and laminar patterning in Xenopus and chick embryos, and in controlling cephalic neural tube closure in mouse embryos. The recent identification of neogenin as a receptor for RGM has provided evidence of the diverse functions of this ligand-receptor pair. Re-expression of RGM is observed after injury in the adult human and rat central nervous systems. Inhibition of RGM enhances growth of injured axons and promotes functional recovery after spinal cord injury in rats. Thus, re-expression of embryonic repulsive cues in adult tissues contributes to failure of axon regeneration in the central nervous system.     

Defective adult oligodendrocyte and Schwann cell development, pigment pattern, and craniofacial morphology in puma mutant zebrafish having an alpha tubulin mutation

The processes of myelination remain incompletely understood but are of profound biomedical importance owing to the several dysmyelinating and demyelinating disorders known in humans. Here, we analyze the zebrafish puma mutant, isolated originally for pigment pattern defects limited to the adult stage. We show that puma mutants also have late-arising defects in Schwann cells of the peripheral nervous system, locomotor abnormalities, and sex-biased defects in adult craniofacial morphology. Using methods of positional cloning, we identify a critical genetic interval harboring two alpha tubulin loci, and we identify a chemically induced missense mutation in one of these, tubulin alpha 8-like 3a (tuba8l3a). We demonstrate tuba8l3a expression in the central nervous system (CNS), leading us to search for defects in the development of oligodendrocytes, the myelinating cells of the CNS. We find gross reductions in CNS myelin and oligodendrocyte numbers in adult puma mutants, and these deficits are apparent already during the larval-to-adult transformation. By contrast, analyses of embryos and early larvae reveal a normal complement of oligodendrocytes that nevertheless fail to localize normal amounts of myelin basic protein (mbp) mRNA in cellular processes, and fail to organize these processes as in the wild-type. This study identifies the puma mutant as a valuable model for studying microtubule-dependent events of myelination, as well as strategies for remyelination in the adult.     

Localization of glutamate-like immunoreactive neurons in the central and peripheral nervous system of the adult and developing pond snail, Lymnaea stagnalis

We investigated the distribution and projection patterns of central and peripheral glutamate-like immunoreactive (GLU-LIR) neurons in the adult and developing nervous system of Lymnaea. Altogether, 50-60 GLU-LIR neurons are present in the adult central nervous system. GLU-LIR labeling is shown in the interganglionic bundle system and at the varicosities in neuropil of the central ganglia. In the periphery, the foot, lip, and tentacle contain numerous GLU-LIR bipolar sensory neurons. In the juvenile Lymnaea, GLU-LIR elements at the periphery display a pattern of distribution similar to that seen in adults, whereas labeled neurons increase in number in the different ganglia of the central nervous system from juvenile stage P1 up to adulthood. During embryogenesis, GLU-LIR innervation can be detected first at the 50% stage of embryonic development (the E50% stage) in the neuropil of the cerebral and pedal ganglia, followed by the emergence of labeled pedal nerve roots at the E75% stage. Before hatching, at the E90% stage, a few GLU-LIR sensory cells can be found in the caudal foot region. Our findings indicate a wide range of occurrence and a broad role for glutamate in the gastropod nervous system; hence they provide a basis for future studies on glutamatergic events in networks underlying different behaviors.     

Membrane glycoproteins immunologically related to the human insulin receptor are associated with presumptive neuronal territories and developing neurones in Drosophila melanogaster

We have generated a monoclonal antibody (Mab E1C) that recognizes the differentiated nervous system in Drosophila embryos. At the cellular blastoderm stage, Mab E1C behaves as a general ectodermal marker but, in subsequent stages, it also labels the mesoderm. As neurogenesis takes place, staining increases within the neuromeres and is almost exclusively restricted to the nervous tissue by the time neuronal differentiation is completed. In third instar larvae, Mab E1C stains the central nervous system (CNS) as well as the imaginal discs which display a staining pattern related to their degree of neuronal differentiation. No labelling can be detected in adult brains or ovaries. Western blots are consistent with this developmental profile and allow the characterization of a major glycoprotein of 135 X 10(3) Mr (135K) which cosediments with a membrane fraction prepared from embryos. Additional glycoproteins (100K and 80K) are extracted from embryo homogenates by immunoaffinity procedures. In larvae, the 100K polypeptide is not detected. The properties of the 135K and 100K components are highly reminiscent of the molecular pattern of the Drosophila insulin receptor homologue (Petruzzelli et al. (1985) J. biol. Chem. 250, 16072-16075). It is shown that a Mab directed against the human insulin receptor stains the same cells as Mab E1C in imaginal discs and in the CNS. Moreover, this Mab cross-reacts with the 135K and 100K components of the embryonic antigen E1C.     

Expression of alpha 1 integrin, a laminin-collagen receptor, during myogenesis and neurogenesis in the avian embryo.

In this study, we have examined the spatiotemporal distribution of the alpha 1 integrin subunit, a putative laminin and collagen receptor, in avian embryos, using immunofluorescence microscopy and immunoblotting techniques. We used an antibody raised against a gizzard 175 x 10(3) M(r) membrane protein which was described previously and which we found to be immunologically identical to the chicken alpha 1 integrin subunit. In adult avian tissues, alpha 1 integrin exhibited a very restricted pattern of expression; it was detected only in smooth muscle and in capillary endothelial cells. In the developing embryo, alpha 1 integrin subunit expression was discovered in addition to smooth muscle and capillary endothelial cells, transiently, in both central and peripheral nervous systems and in striated muscles, in association with laminin and collagen IV. alpha 1 integrin was practically absent from most epithelial tissues, including the liver, pancreas and kidney tubules, and was weakly expressed by tissues that were not associated with laminin and collagen IV. In the nervous system, alpha 1 integrin subunit expression occurred predominantly at the time of early neuronal differentiation. During skeletal muscle development, alpha 1 integrin was expressed on myogenic precursors, during myoblast migration, and in differentiating myotubes. alpha 1 integrin disappeared from skeletal muscle cells as they became contractile. In visceral and vascular smooth muscles, alpha 1 integrin appeared specifically during early smooth muscle cell differentiation and, later, was permanently expressed after cell maturation. These results indicate that (i) the expression pattern of alpha 1 integrin is consistent with a function as a laminin/collagen IV receptor; (ii) during avian development, expression of the alpha 1 integrin subunit is spatially and temporally regulated; (iii) during myogenesis and neurogenesis, expression of alpha 1 integrin is transient and correlates with cell migration and differentiation.     

The larval nervous system of the penis worm Priapulus caudatus (Ecdysozoa)

The origin and extreme diversification of the animal nervous system is a central question in biology. While most of the attention has traditionally been paid to those lineages with highly elaborated nervous systems (e.g. arthropods, vertebrates, annelids), only the study of the vast animal diversity can deliver a comprehensive view of the evolutionary history of this organ system. In this regard, the phylogenetic position and apparently conservative molecular, morphological and embryological features of priapulid worms (Priapulida) place this animal lineage as a key to understanding the evolution of the Ecdysozoa (i.e. arthropods and nematodes). In this study, we characterize the nervous system of the hatching larva and first lorica larva of the priapulid worm Priapulus caudatus by immunolabelling against acetylated and tyrosinated tubulin, pCaMKII, serotonin and FMRFamide. Our results show that a circumoral brain and an unpaired ventral nerve with a caudal ganglion characterize the central nervous system of hatching embryos. After the first moult, the larva attains some adult features: a neck ganglion, an introvert plexus, and conspicuous secondary longitudinal neurites. Our study delivers a neuroanatomical framework for future embryological studies in priapulid worms, and helps illuminate the course of nervous system evolution in the Ecdysozoa.     

Introduction of DNA into chick embryos by in ovo electroporation

Gene transfer by in ovo electroporation has been applied to the study of developmental biology, especially to central nervous system (CNS) development. Plasmids are injected into the neural tube of stage 10 chick embryos, and a 25-V 25-msec square pulse is applied five times. Since DNA moves toward the anode, the cathode side of the neural tube is transfected, and the cathode side is used as the control. Expression of translation product of the introduced DNA is observed 2 h after electroporation, peaks around 20 h after electroporation and then weakens. Expression is transient when plasmids are used as expression vectors, but they are very suitable for studying early developmental events (e.g., gene expression cascades or interactions). Misexpression of Pax-5 is shown as an example.