Acid phosphatase activity in the supramedullary neurons of Coris julis (L.).

This work describes the acid phosphatase activity in supramedullary neurons of Coris julis, analyzed by a cytochemical method. The presence of both acid phosphatase-positive and -negative membrane bound granules indicates that only a part of the numerous electrodense granules in the supramedullary neurons can be interpreted as lysosomes. The great number of lysosomes in these large neurons of young animals is indicative of the rapid turnover of cell structures, which may be correlated with the high rate of synthesis. The electrodense granules showing no acid phosphatase activity are postulated to be vesicles containing gastrin/CCK-like peptide or precursors of this neuromediator.     

Ultrastructural features of supramedullary neurons in Crenilabrus quinquemaculatus

The ultrastructural study of the supramedullary neurons in Crenilabrus quinquemaculatus shows that these cells are engaged in intense synthetic activity as is testified by the nuclear morphology, the plentiful rough endoplasmic reticulum and polysomes, and finally the remarkably developed Golgi complexes, many of them active. Moreover the cytoplasm of the supramedullary neurons shows numerous membrane-bounded bodies (1,800-4,000 A) containing electron dense material, more or less finely granular. Research is presently being carried out to establish the meaning of these electron dense bodies.     

Development of respiratory function in perinatal ontogenesis

In development of respiratory function in rats, mice, and other representatives of placental animals there exists the general plan of formation of rhythm: from single contractions of respiratory musculature to formation of bursts and complexes alternating periodically with pauses and apnea intervals and subsequent rhythm stabilization. These peculiarities are closely connected with the states of sleep and wakefulness. A concept is put forward about a certain sequence of functional maturation and ways of regulation of activity of the breathing rhythm pacemaker. At the first stage the autogenic rhythmical activity is determined by pacemaker properties of a part of neurons of the medulla rostral ventrolateral part. It cannot be ruled out that the first respiratory discharges in spinal cord ventral roots might have been a manifestation of the nervous network rhythmogenic properties. The direct sensitivity of central neurons to chemical composition of the medium and to some neuromodulators serves as the first regulatory mechanism. Somewhat later, inhibitory control is established from supramedullary structures, with an increase of the role of peripheral receptors in regulation of respiration.     

Development of respiratory function in perinatal ontogenesis

In development of respiratory function in rats, mice, and other representatives of placental animals there exists the general plan of formation of rhythm: from single contraction of respiratory musculature to formation of bursts and complexes alternating periodically with pauses and apnea intervals and subsequent rhythm stabilization. These peculiarities are closely connected with the states of sleep and consciousness. A concept is put forward about a certain sequence of functional maturation and ways of regulation of activity of the respiratory rhythm central pacemaker. At the first stage the autogenic rhythmical activity is determined by pacemaker properties of a part of neurons of the medulla rostral ventrolateral part. It is not ruled out that the first respiratory discharges in spinal cord ventral roots might have been a manifestation of the nervous network rhythmogenic properties. The direct sensitivity of central neurons to chemical composition if the medium and to some neutomodulators serves as the first regulatory mechanism. Somewhat later, inhibitory control is established from supramedullary structures, with an increase of role of peripheral receptors in regulation of respiration.     

Macroglial cells of the teleost central nervous system: a survey of the main types

Following our previous review of teleost microglia, we focus here on the morphological and histochemical features of the three principal macroglia types in the teleost central nervous system (ependymal cells, astrocyte-like cells/radial glia and oligodendrocytes). This review is concerned with recent literature and not only provides insights into the various individual aspects of the different types of macroglial cells plus a comparison with mammalian glia, but also indicates the several potentials that the neural tissue of teleosts exhibits in neurobiological research. Indeed, some areas of the teleost brain are particularly suitable in terms of the establishment of a “simple” but complete research model (i.e. the visual pathway complex and the supramedullary neuron cluster in puffer fish). The relationships between neurons and glial cells are considered in fish, with the aim of providing an integrated picture of the complex ways in which neurons and glia communicate and collaborate in normal and injured neural tissues. The recent setting up of successful protocols for fish glia and mixed neuron-glia cultures, together with the molecular facilities offered by the knowledge of some teleost genomes, should allow consistent input towards the achievement of this aim.     

Enteric neurons show a primary cilium

The primary cilium is a non‐motile cilium whose structure is 9+0. It is involved in co‐ordinating cellular signal transduction pathways, developmental processes and tissue homeostasis. Defects in the structure or function of the primary cilium underlie numerous human diseases, collectively termed ciliopathies. The presence of single cilia in the central nervous system (CNS) is well documented, including some choroid plexus cells, neural stem cells, neurons and astrocytes, but the presence of primary cilia in differentiated neurons of the enteric nervous system (ENS) has not yet been described in mammals to the best of our knowledge. The enteric nervous system closely resembles the central nervous system. In fact, the ultrastructure of the ENS is more similar to the CNS ultrastructure than to the rest of the peripheral nervous system. This research work describes for the first time the ultrastructural characteristics of the single cilium in neurons of rat duodenum myenteric plexus, and reviews the cilium function in the CNS to propose the possible role of cilia in the ENS cells.     

Differentiation of the zebrafish enteric nervous system and intestinal smooth muscle

Development of the enteric nervous system is critical for normal functioning of the digestive system. In vertebrates, enteric precursors originate from the neural crest and migrate into the digestive system. Enteric neurons enable the digestive system to sense and respond to local conditions without the need for central nervous system input. Here we describe major steps in differentiation of the zebrafish enteric nervous system. During migration and neural differentiation of enteric precursors, we identify regions of the enteric nervous system in different phases of differentiation. Early in migration, a small group of anterior enteric neurons are first to form. This is followed by an anterior to posterior wave of enteric neural differentiation later in the migratory phase. Enteric precursors continue proliferating and differentiating into the third day of embryogenesis. nNOS neurons form early while serotonin neurons form late toward the end of enteric neural differentiation. Numbers of enteric neurons increase gradually except during periods of circular and longitudinal intestinal smooth muscle differentiation.     

Neurotransmitters and neuropeptides in the developing human central nervous system. A review

This is a review on the ontogenesis of major neurotransmitters and neuropeptides in the developing human central nervous system. In general, the molecules under study appeared early in development, usually in the first trimester. Cholinergic neurons were found to be present around the time of neuropeptide formation. The newly formed neuropeptidergic fibers extended towards the cholinergic centers where both might interact. In the major centers of the central nervous system, neuropeptides were also noted to colocalize with various neurotransmitters. For example, in the facial nucleus, enkepahlin and substance P fibers coexisted with cholinergic and catecholaminergic neurons, suggesting complex interactions. In the interpeduncular nucleus, peptidergic neurons acting as interneurons clearly modulated the afferent input to this nucleus. In the hippocampus and in sensory organs such as the retina, there were indications that neuropeptides and gamma-amino butyric acid coexisted. We hypothesize that interactions of neurotransmitters and peptides in neurons and fibers early in development play an indispensable role in the morphogenesis of the human central nervous system.     

Immunostaining to Visualize Murine Enteric Nervous System Development

The enteric nervous system is formed by neural crest cells that proliferate, migrate and colonize the gut. Following colonization, neural crest cells must then differentiate into neurons with markers specific for their neurotransmitter phenotype. Cholinergic neurons, a major neurotransmitter phenotype in the enteric nervous system, are identified by staining for choline acetyltransferase (ChAT), the synthesizing enzyme for acetylcholine. Historical efforts to visualize cholinergic neurons have been hampered by antibodies with differing specificities to central nervous system versus peripheral nervous system ChAT. We and others have overcome this limitation by using an antibody against placental ChAT, which recognizes both central and peripheral ChAT, to successfully visualize embryonic enteric cholinergic neurons. Additionally, we have compared this antibody to genetic reporters for ChAT and shown that the antibody is more reliable during embryogenesis. This protocol describes a technique for dissecting, fixing and immunostaining of the murine embryonic gastrointestinal tract to visualize enteric nervous system neurotransmitter expression.     

Initial appearance and regional distribution of the neuron-glia cell adhesion molecule in the chick embryo

This study represents a global survey of the times of the first appearance of the neuron-glia cell adhesion molecule (Ng-CAM) in various regions and on particular cells of the chick embryonic nervous system. Ng-CAM, originally characterized by means of an in vitro binding assay between glial cells and brain membrane vesicles, first appears in development at the surface of early postmitotic neurons. By 3 d in the chick embryo, the first neurons detected by antibodies to Ng-CAM are located in the ventral neural tube; these precursors of motor neurons emit well-stained fibers to the periphery. To identify locations of appearance of Ng-CAM in the peripheral nervous system (PNS), we used a monoclonal antibody called NC-1 that is specific for neural crest cells in early embryos to show the presence of numerous crest cells in the neuritic outgrowth from the neural tube; neither these crest cells nor those in ganglion rudiments bound anti-Ng-CAM antibodies. The earliest neurons in the PNS stained by anti-Ng-CAM appeared by 4 d of development in the cranial ganglia. At later stages and progressively, all the neurons and neurities of the PNS were found to contain Ng-CAM both in vitro and in vivo. Many central nervous system (CNS) neurons also showed Ng-CAM at these later stages, but in the CNS, the molecule was mostly associated with neuronal processes (mainly axons) rather than with cell bodies; this regional distribution at the neuronal cell surface is an example of polarity modulation. In contrast to the neural cell adhesion molecule and the liver cell adhesion molecule, both of which are found very early in derivatives of more than one germ layer, Ng-CAM is expressed only on neurons of the CNS and the PNS during the later epoch of development concerned with neural histogenesis. Ng-CAM is thus a specific differentiation product of neuroectoderm. Ng-CAM was found on developing neurons at approximately the same time that neurofilaments first appear, times at which glial cells are still undergoing differentiation from neuroepithelial precursors. The present findings and those of previous studies suggest that together the neural cell adhesion molecule and Ng-CAM mediate specific cellular interactions during the formation of neuronal networks by means of modulation events that govern their prevalence and polarity on neuronal cell surfaces.     

Expression and function of the neurotransmitter serotonin during development of the Helisoma nervous system

Exogenous serotonin has been shown to evoke a neuron-selective inhibition of neurite outgrowth and synaptogenesis in identified Helisoma neurons in vitro. We demonstrate here that serotonin is present in the embryonic nervous system of Helisoma and can act as a regulator of neuronal development in vivo. Serotonin-like immunoreactivity was first observed in neurons at an early stage of nervous system development (E20). Throughout embryogenesis, the number of serotonin-immunoreactive neurons increased in a stereotypic pattern that was unique for each type of ganglion. Strikingly, the number of serotonin-immunoreactive neurons continued to increase throughout adult life. Transient perturbation of endogenous serotonin levels during embryogenesis had profound effects on the development of specific identified neurons. Embryos treated with 5,7-dihydroxytryptamine and raised to maturity showed aberrations in neuronal morphology, neuronal dye coupling, and strength of electrical synaptic connections. These effects were restricted to neurons known to be sensitive to the growth-inhibitory effects of serotonin in vitro. These results support the hypothesis that neurotransmitters are an important class of regulatory factors during normal development of the nervous system.     

Glial cells: basic components of clusters of supramedullary neurons in pufferfish

In this paper a cytochemical and ultrastructural study of clustered supramedullary neurons (SN) of Tetraodon fluviatilis (Tetraodontiformes) is presented. SN are large-sized nerve cells that have a high metabolic rate and are intensely engaged in protein biosynthesis. The SN are completely surrounded by two types of glial cell, which have been ultrastructurally, histochemically and immunohistochemically identified as astrocyte-like cells and microglial cells. The glial cells are located very close to the SN and sometimes contact them, which suggests that they do not only provide mechanical support but are also trophic for the SN and serve their functioning. We consider these glial cells as a constitutive and functional part of the cluster of SN, and therefore propose that the SN cluster constitute a suitable model to study in detail the morphological and functional relationships between neurons and glial cells in Anamnia.     

Perineurium in the Drosophila (Diptera : Drosophilidae) embryo and its role in the blood-brain/nerve barrier

A monolayer of perineurial cells overlies glia and neurons, and this stratum of the central nervous system is the principal site of the Drosophila (Diptera : Drosophilidae) blood-brain barrier. Perineurial cells are bonded together by pleated-sheet septate junctions that are the anatomical correlate of the vertebrate tight junction. The blood-brain barrier maintains the ionic homeostasis necessary for proper nerve function. It was known that a functioning blood-brain barrier is present in mature (Stage 17) Drosophila embryos, but the genesis of this barrier was not known. We surveyed the central nervous system of late stage embryos (15 through 17) to determine when perineurial cells could first be detected. These cells take their place in (on) the central nervous system and are joined together by pleated-sheet septate junctions, during Stage 17. Those septate junctions are quickly occlusive to lanthanum tracer. This development step occurs during the same time as when chemical synapses first become functional. Such concurrent maturation is far from coincidental, because partitioning nerves and their synapses from hemolymph (with its variable ionic constitution) are essential for normal electrophysiology. We discuss details of the germ line derivation of perineurial cells, their first detection in the embryonic central nervous system, their functional properties, and the polygonal cell-packing pattern seen in the larval central nervous system.     

Integrating bits and pieces: synapse structure and formation in Drosophila embryos

During the development of the nervous system, numerous neurons connect to form complex networks. In order to build a functional network each neuron has to establish contacts with appropriate target cells, and at these contacts synapses of the right quality and strength have to be formed. Gaining insight into the mechanisms underlying this complex development is an important step towards a better understanding of how the nervous system is formed and behaviour generated. One model system in which synapse formation can be studied at the morphological, physiological and molecular level is that of the fruitfly Drosophila, and insights gained from Drosophila embryos are reviewed here. The first part of this review deals with the neuromuscular junction as the best-known synaptic contact in Drosophila. It describes: (1) its structure, (2) mechanisms underlying the formation of the neuromuscular cell junction and the arborisation of the presynaptic terminal, and (3) our present understanding of signal-dependent and -independent processes during synapse formation at the neuromuscular junction. The last part of this review deals with the question of how particular neurons can adopt specific synaptic properties, stating as an example the development of the neural lineage of NB7-3, which gives rise to two serotonergic neurons.     

Immunocytochemical identification of serotoninergic neurons in planaria <Emphasis Type="Italic">Girardia tigrina</Emphasis>

Flatworms occupy an important position among simple organisms, which were first in the evolution having bilateral symmetry and centralized nervous system. This paper provides evidence of the presence of a biogenic amine serotonin in free-living flatworms planarians Girardia tigrina (Turbellaria, Platyhelminthes). Using immunohistochemical method, fluorescence and confocal laser scanning microscopy, we have identified serotonin neurons and their fibers using planarian whole-mount preparations and got important information about distribution of serotoninergic components in their body. Information on the number and size of serotonin-immunopositive neurons in the brain ganglion of G. tigrina and on the distribution density of serotoninergic neurons in the central nervous system of worms is presented for the first time. The published data concerning the serotoninergic signalization in flatworms are briefly overviewed.     

Pioneer neurons: A basis or limiting factor of lophotrochozoa nervous system diversity?

It has been demonstrated by us and other authors that first nervous cells in developing larvae from various trochozoan groups differentiate at the periphery. These pioneer neurons are distinguished by the set of characters. They are located outside the forming central ganglia; outgrowing fibers of central neurons use their processes as a “scaffolding” transmitter expression in these neurons is transient. On the one hand, pioneer neurons mark the “frame” of the adult nervous system and thus play a limiting role. On the other hand, pioneering navigation provides possible mechanisms for evolutional plasticity of the nervous system in adults. In addition, pioneer neurons can underlie functional adaptation of trochophore animals, which minimizes fitness decrease during the transition from the larval to the adult form during metamorphosis.     

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.     

Distribution of tachykinin-related neuropeptide in the developing central nervous system of the moth Spodoptera litura

Neuropeptides with similarities to vertebrate tachykinins, designated tachykinin-related peptides (TRPs), have been identified in several insect species. In this investigation we have utilized an antiserum raised to one of the locust TRPs, locustatachykinin-I (LomTK-I), to determine the distribution pattern of LomTK-like immunoreactive (LTKLI) neurons in the developing nervous system of the moth Spodoptera litura. A number of LTKLI neurons could be followed from the larval to the adult nervous system: a set of median neurosecretory cells (MNCs) in the brain, a pair of brain descending neurons and a few sets on neurons in the ventral nerve cord. The distribution of LTKLI neurons in the adult brain is very similar to that seen in other insect species with prominent arborizations in the central body, antennal lobes, mushroom body calyces, optic lobe neuropils and other distinct neuropil areas in the protocerebrum and tritocerebrum. A new finding is the presence of LTKLI neurosecretory cells with axon terminals in the anterior aorta and corpora cardiaca, suggesting for the first time a neurohormonal role of tachykinin-related peptide(s) in insects. During postembryonic development the number of LTKLI neurons in the ventral nerve cord decreases somewhat, whereas the number increases in the brain. Thus the functional roles of TRPs may change to some extent during development.