Glycine-receptors in the vertebrate central nervous system

Evidence for the existence of glycine-receptors in the vertebrate central nervous system (CNS) has been reviewed and analyzed. Biochemical studies have supported iontophoretic findings that such receptors exist in several regions of the CNS. Subcellular studies on the displacement of 3H-strychnine binding by glycine and on the effects of strychnine on 3H-glycine binding have revealed that strychnine does not interact directly with glycine-receptors, lending support to studies performed in situ. Approaches toward glycine-receptors remain limited due to the inavailability of a specific glycine-antagonist.     

Diverse roles for VEGF-A in the nervous system

Vascular endothelial growth factor A (VEGF-A) is best known for its essential roles in blood vessel growth. However, evidence has emerged that VEGF-A also promotes a wide range of neuronal functions, both in vitro and in vivo, including neurogenesis, neuronal migration, neuronal survival and axon guidance. Recent studies have employed mouse models to distinguish the direct effects of VEGF on neurons from its indirect, vessel-mediated effects. Ultimately, refining our knowledge of VEGF signalling pathways in neurons should help us to understand how the current use of therapeutics targeting the VEGF pathway in cancer and eye disease might be expanded to promote neuronal health and nerve repair.     

Axon guidance in the vertebrate central nervous system

The development of connections in the central nervous system depends on the ability of the tips of growing axons to find their appropriate, often distant, target field. Factors that regulate axon outgrowth may be distinct from those that influence direction finding. Tissue culture methods have helped to distinguish between possible in vivo mechanisms and, in some cases, have identified candidate molecules.     

Pattern formation in the vertebrate nervous system.

In recent years, the classical approaches of experimental embryology have been used in combination with more modern techniques to investigate aspects of neurogenesis. This combination has advanced our knowledge of several areas of neuronal development, including the lineages of neuronal precursors, the segmentation of the nervous system, and the patterning of the neural tube.     

Emerging biological roles for erythropoietin in the nervous system

Erythropoietin mediates an evolutionarily conserved, ancient immune response that limits damage to the heart, the nervous system and other tissues following injury. New evidence indicates that erythropoietin specifically prevents the destruction of viable tissue surrounding the site of an injury by signalling through a non-haematopoietic receptor. Engineered derivatives of erythropoietin that have a high affinity for this receptor have been developed, and these show robust tissue-protective effects in diverse preclinical models without stimulating erythropoiesis. A recent successful proof-of-concept clinical trial that used erythropoietin to treat human patients who had suffered a stroke encourages the evaluation of both this cytokine and non-erythropoietic derivatives as therapeutic agents to limit tissue injury.     

Mechanisms of ventral patterning in the vertebrate nervous system

Dorsoventral patterning of the neural tube has a crucial role in shaping the functional organization of the CNS. It is well established that hedgehog signalling plays a key role in specifying ventral cell types throughout the neuroectoderm, and major progress has been made in elucidating how hedgehog signalling works in this ventral specification. In addition, other molecular pathways, including nodal, retinoic acid and fibroblast growth factor signalling, have been identified as important molecular cues for ventral patterning of the spinal cord, telencephalon and eye. Here, we discuss recent advances in this field, highlighting the emerging interplay of these signalling pathways in the molecular specification of ventral patterning at different rostrocaudal levels of the CNS.     

Plasticity and stem cells in the vertebrate nervous system

How and when do vertebrate neural precursor cells choose their fates? While some studies suggest a series of commitments on the road to fate choice, many recent experiments indicate that precursor fate choices can often be changed. Additionally, the identification of common gene control mechanisms in precursors suggest that these cells share fundamental properties throughout development.     

The collagen of the vertebrate peripheral nervous system

Summary Nerves and ganglia from a variety of fish, amphibian, reptilian and mammalian species were studied by optical and electron microscopy. Observations using the Picrosirius-polarization method strongly suggest that two different types of collagen fibers are present in the connective tissues of nerves and ganglia. Electron microscopy of nerves and ganglia showed the presence of two different collagen fibril populations, distinguishable on the basis of diameter, located in different compartments of these structures. Thicker fibrils are present in nerve and ganglionic epineurium. Thinner fibrils are present in the endoneurium, surrounding nerve fibers and ganglionic cells, and between the concentric layers of perineurial cells. These results were consistently observed in all species studied and very probably represent a general phenomenon in vertebrates.This work was aided by a grant from the Fundação de Amparo à Pesquisa do Estado de São Paulo     

Segmentation and the development of the vertebrate nervous system

1. Recent experiments on the development of neural segmentation in chick embryos are reviewed. 2. Segmentation of the spinal peripheral nerves is governed by a subdivision of the somite-derived sclerotome into anterior and posterior halves. Migrating neural crest cells and outgrowing motor axons are confined to the anterior sclerotome as a result, in part, of inhibitory interactions with posterior sclerotome cells. 3. The sclerotomal distribution of certain molecules known to influence growing nerve cells in vitro, namely laminin, fibronectin, N-CAM, N-Cadherin and J1/tenascin/cytotactin, suggest that these molecules play no critical role in determining the preference of nerve cells for anterior sclerotome. 4. Peanut agglutinin (PNA) recognises cell surface-associated components on posterior cells which, when incorporated into liposomes, cause the abrupt collapse of sensory growth cones in vitro. The PNA receptor(s) may be inhibitory for nerve cells in vivo. 5. The chick hindbrain epithelium is segmented early in its development. Each branchiomotor nucleus in the series of cranial nerves V, VII and IX derives from a pair of segments lying in register with an adjacent branchial arch. Neurogenesis of motor and reticular axons begins in alternate segments, suggesting parallels with insect pattern formation.     

The phylogenic expression of plasmolipin in the vertebrate nervous system

Plasmolipin is a plasma membrane proteolipid is a major myelin membrane component (Cochary et al., 1990). In this study we report the phylogenic expression of plasmolipin in the vertebrate nervous system. Using Western blot analysis with polyclonal antibodies, we have analyzed membrane fractions, including myelin, from elasmobranchs, teleosts, amphibians, reptiles, birds and mammals. On the basis of immune detection, plasmolipin appears to be restricted to the mammalian nervous system. Comparison of the central and peripheral nervous systems of mammals showed only minor differences in the level of plasmolipin in these two regions. Within mammals, little quantitative differences were observed when rat, human and bovine membrane fractions were compared. The late evolutionary expression of plasmolipin which results in its restriction to mammals makes it unique among the (major) myelin proteins. The potential physiologic significance of these data are discussed.Abbreviations EDTA Ethylene diamine N.,NN tetracetic acid - EGTA Ethylene glycol bis-(B-Aminoethyl Ether) N,,NN tetracetic acid - MES ([N-Morpholino] ethane sulfonic acid) DCCD, N, Dicyclohexyl carbodiimide     

Development of trophic interactions in the vertebrate peripheral nervous system

During embryogenesis, the neurons of vertebrate sympathetic and sensory ganglia become dependent on neurotrophic factors, derived from their targets, for survival and maintenance of differentiated functions. Many of these interactions are mediated by the neurotrophins NGF, BDNF, and NT3 and the receptor tyrosine kinases encoded by genes of thetrk family. Both sympathetic and sensory neurons undergo developmental changes in their responsiveness to NGF, the first neurotrophin to be identified and characterized. Subpopulations of sensory neurons do not require NGF for survival, but respond instead to BDNF or NT3 with enhanced survival. In addition to their classic effects on neuron survival, neurotrophins influence the differentiation and proliferation of neural crest-derived neuronal precursors. In both sympathetic and sensory systems, production of neurotrophins by target cells and expression of neurotrophin receptors by neurons are correlated temporally and spatially with innervation patterns. In vitro, embryonic sympathetic neurons require exposure to environmental cues, such as basic FGF and retinoic acid to acquire neurotrophin-responsiveness; in contrast, embryonic sensory neurons acquire neurotrophin-responsiveness on schedule in the absence of these molecules.     

Developmental regulation of axon branching in the vertebrate nervous system

During nervous system development, axons generate branches to connect with multiple synaptic targets. As with axon growth and guidance, axon branching is tightly controlled in order to establish functional neural circuits, yet the mechanisms that regulate this important process are less well understood. Here, we review recent advances in the study of several common branching processes in the vertebrate nervous system. By focusing on each step in these processes we illustrate how different types of branching are regulated by extracellular cues and neural activity, and highlight some common principles that underlie the establishment of complex neural circuits in vertebrate development.     

Chordate origins of the vertebrate central nervous system.

Fine structural, computerized three-dimensional (3D) mapping of cell connectivity in the amphioxus nervous system and comparative molecular genetic studies of amphioxus and tunicates have provided recent insights into the phylogenetic origin of the vertebrate nervous system. The results suggest that several of the genetic mechanisms for establishing and patterning the vertebrate nervous system already operated in the ancestral chordate and that the nerve cord of the proximate invertebrate ancestor of the vertebrates included a diencephalon, midbrain, hindbrain, and spinal cord. In contrast, the telencephalon, a midbrain-hindbrain boundary region with organizer properties, and the definitive neural crest appear to be vertebrate innovations.     

Stabilizing the regionalisation of the developing vertebrate central nervous system

During embryonic development, a number of tissues are patterned by their subdivision into domains with distinct regional identity. An important question is how sharp interfaces are established and maintained between adjacent domains despite the potential for scrambling due to cell intermingling during tissue growth. Two mechanisms have been found to underlie the maintenance of sharp interfaces: the specific restriction of cell mixing across boundaries, or the switching of identity of cells that cross between domains. We review the evidence for these mechanisms at distinct boundaries in the developing vertebrate central nervous system, and discuss what is known about their molecular mediators.     

Functional roles of microglia in the central nervous system

Microglia, a type of perineuronal glial cells in the central nervous system, have been suggested to play various important roles in normal and pathologic brains. In this article, first, we described the association or roles of activated microglia in injury and various brain diseases, and subsequently, summarized microglia-derived physiologically active molecules which will affect the neuronal survival and neuronal growth, and glial function, and finally, discussed the molecular mechanism of microglial activation.     

Lipofection of cDNAs in the embryonic vertebrate central nervous system.

Neurons from the embryonic brain of Xenopus were transfected in vivo with a vector expressing luciferase cDNA using a simple lipofection procedure. Luciferase activity was monitored quantitatively, and the protein was immunolocalized in whole-mount embryonic brains. Luciferase-expressing neurons were often intensely labeled, displaying a Golgi-like filling of their dendrites, axons, and growth cones. Luciferase expression could be targeted to the retina by simply removing the skin epidermis covering the area and exposing the whole embryo to the DNA-lipofectin mixture. Luciferase activity in transfected embryos rose to peak values during the first 48 hr posttransfection and was still detectable 28 days later. Cotransfection experiments in which embryonic nervous tissue was exposed simultaneously to two different genes, luciferase and chloramphenicol acetyl-transferase, showed that transfected cells coexpressed the two genes at an extremely high frequency (85%-100%). This offers the possibility of targeting functionally significant genes along with benign reporter genes in the developing CNS.     

Amphibian sympathetic ganglia as a model system for investigating regeneration in the vertebrate peripheral nervous system

1. The paravertebral sympathetic ganglion of the bullfrog serves as an excellent experimental system in which to study the response of vertebrate neurones to axotomy and the mechanisms associated with regeneration. 2. Various types of lesions to the axons (axotomy) of these neurones promote distinct and reproducible changes in the electrophysiological properties of the cell bodies which are not a consequence of changes in cell body morphology. 3. The axotomy-induced increase in spike width and decrease in the amplitude of the action potential after-hyperpolarization may allow an increase in Ca2+ influx and thereby promote regrowth. 4. The axotomy-induced decrease in after-hyperpolarization duration may reflect the disconnection of the neurone with its target and the loss of available nerve growth factor (NGF) from the target. 5. Experiments with NGF antibodies provide evidence that an NGF-like substances serves to maintain the normal electrophysiological characteristics of amphibian sympathetic neurones.