Developmental changes in the regulation of calcium-dependent neurite outgrowth

Intracellular calcium ions (Ca²⁺) have an essential role in the regulation of neurite outgrowth, but how outgrowth is controlled remains largely unknown. In this study, we examined how the mechanisms of neurite outgrowth change during development in chick and mouse dorsal root ganglion neurons. 2APB, a potent inhibitor of inositol 1,4,5-trisphosphate (IP₃) receptors (IP₃R), inhibited neurite outgrowth at early developmental stages, but not at later stages. In contrast, pharmacological inhibition with Ni²⁺, Cd²⁺, or dantrolene revealed that ryanodine receptor (RyR)-mediated Ca²⁺-induced Ca²⁺ release (CICR) was involved in neurite outgrowth at later stage, but not at early stages. The distribution of IP₃R and RyR in growth cones also changed during development. Furthermore, pharmacological inhibition of the Ca²⁺-calmodulin-dependent phosphatase calcineurin with FK506 reduced neurite outgrowth only at early stages. These data suggest that the calcium signaling that regulates neurite outgrowth may change during development from an IP₃R-mediated pathway to a RyR-mediated pathway.     

Constitutively expressed catalytic proteasomal subunits are up-regulated during neuronal differentiation and required for axon initiation, elongation and maintenance

Inhibition of the proteasome by lactacystin, a specific blocker of the catalytic beta-subunits, results in transient neurite outgrowth by neuronal cell lines. Vice versa, as demonstrated in this study, treatment of pheochromocytoma (PC12) cells with nerve growth factor (NGF) or other differentiating agents reduces proteasomal activity. This is accompanied by an increase in mRNA and protein levels of the catalytically active subunits beta1, beta2 and beta5, but not of their inducible counterparts, indicating changes in subunit composition of the proteasome during neuronal differentiation. In contrast to neuronal cell lines, however, pre-treatment of primary neurons with proteasome inhibitors completely prevents axon formation, and lower concentrations of lactacystin (0.5-5 microm) significantly reduce axonal elongation and branching in vitro. Furthermore, established axonal networks degenerate rapidly and long-term survival of peripheral neurons is impaired in the presence of proteasome inhibitors. Axonal pathology is reminiscent of the morphological changes observed in neurodegenerative disorders and supports a crucial role of the constitutive catalytic subunits in axon initiation, maintenance and regeneration.     

Ethanol causes the redistribution of L1 cell adhesion molecule in lipid rafts

Fetal alcohol spectrum disorder is estimated to affect 1% of live births. The similarities between children with fetal alcohol syndrome and those with mutations in the gene encoding L1 cell adhesion molecule (L1) implicates L1 as a target of ethanol developmental neurotoxicity. Ethanol specifically inhibits the neurite outgrowth promoting function of L1 at pharmacologic concentrations. Emerging evidence shows that localized disruption of the lipid rafts reduces L1-mediated neurite outgrowth. We hypothesize that ethanol impairment of the association of L1 with lipid rafts is a mechanism underlying ethanol's inhibition of L1-mediated neurite outgrowth. In this study, we examine the effects of ethanol on the association of L1 and lipid rafts. We show that, in vitro, L1 but not N-cadherin shifts into lipid rafts following treatment with 25 mM ethanol. The ethanol concentrations causing this effect are similar to those inhibiting L1-mediated neurite outgrowth. Increasing chain length of the alcohol demonstrates the same cutoff as that previously shown for inhibition of L1-L1 binding. In addition, in cerebellar granule neurons in which lipid rafts are disrupted with methyl-beta-cyclodextrin, the rate of L1-mediated neurite outgrowth on L1-Fc is reduced to background rate and that this background rate is not ethanol sensitive. These data indicate that ethanol may inhibit L1-mediated neurite outgrowth by retarding L1 trafficking through a lipid raft compartment.     

Salvia macilenta exhibits antiglycating activity and protects PC12 cells against H2O2-induced apoptosis

Salvia macilenta is a member of the genus Salvia (Laminaceae) whose antioxidant activity and neuroprotective effect has been shown previously. The present study aimed to examine the antiglycating and antiapoptotic abilities of methanolic extract of this plant. Moreover, the effect of S. macilenta on neurite outgrowth and complexity after exposure to H₂O₂ has been studied. Base on our results, S. macilenta has antiglycating activity and protects PC12 cells against oxidative stress-induced apoptotic cell death, as examined by Hoechst staining and Western blot analysis of caspase-3, Bax, Bcl-2 and PARP. We further showed that S. macilenta decreased neurite growth and complexity impairment in differentiated PC12 cells exposed to oxidative stress. It caused a decrease in cell body area, neurite width, and the proportion of bipolar cells, while significantly increasing neurite length, the number of primary neurites per cell and the ratio of nodes to primary neuritis. All around, the mentioned results open a new horizon for future works to use this plant as a potential neuroprotective agent.     

Somatic and axonal LIGHT signaling elicit degenerative and regenerative responses in motoneurons,respectively

A receptor–ligand interaction can evoke a broad range of biological activities in different cell types depending on receptor identity and cell type‐specific post‐receptor signaling intermediates. Here, we show that the TNF family member LIGHT, known to act as a death‐triggering factor in motoneurons through LT‐βR, can also promote axon outgrowth and branching in motoneurons through the same receptor. LIGHT‐induced axonal elongation and branching require ERK and caspase‐9 pathways. This distinct response involves a compartment‐specific activation of LIGHT signals, with somatic activation‐inducing death, while axonal stimulation promotes axon elongation and branching in motoneurons. Following peripheral nerve damage, LIGHT increases at the lesion site through expression by invading B lymphocytes, and genetic deletion of Light significantly delays functional recovery. We propose that a central and peripheral activation of the LIGHT pathway elicits different functional responses in motoneurons.     

Matrix metalloproteinase 2 and membrane type 1 matrix metalloproteinase co‐regulate axonal outgrowth of mouse retinal ganglion cells

Restoration of correct neural activity following central nervous system (CNS) damage requires the replacement of degenerated axons with newly outgrowing, functional axons. Unfortunately, spontaneous regeneration is largely lacking in the adult mammalian CNS. In order to establish successful regenerative therapies, an improved understanding of axonal outgrowth and the various molecules influencing it, is highly needed. Matrix metalloproteinases (MMPs) constitute a family of zinc‐dependent proteases that were sporadically reported to influence axon outgrowth. Using an ex vivo retinal explant model, we were able to show that broad‐spectrum MMP inhibition reduces axon outgrowth of mouse retinal ganglion cells (RGCs), implicating MMPs as beneficial factors in axonal regeneration. Additional studies, using more specific MMP inhibitors and MMP‐deficient mice, disclosed that both MMP‐2 and MT1‐MMP, but not MMP‐9, are involved in this process. Furthermore, administration of a novel antibody to MT1‐MMP that selectively blocks pro‐MMP‐2 activation revealed a functional co‐involvement of these proteinases in determining RGC axon outgrowth. Subsequent immunostainings showed expression of both MMP‐2 and MT1‐MMP in RGC axons and glial cells. Finally, results from combined inhibition of MMP‐2 and β1‐integrin were suggestive for a functional interaction between these molecules. Overall, our data indicate MMP‐2 and MT1‐MMP as promising axonal outgrowth‐promoting molecules.

     

Axon targeting of the alpha 7 nicotinic receptor in developing hippocampal neurons by Gprin1 regulates growth

Cholinergic signaling plays an important role in regulating the growth and regeneration of axons in the nervous system. The α7 nicotinic receptor (α7) can drive synaptic development and plasticity in the hippocampus. Here, we show that activation of α7 significantly reduces axon growth in hippocampal neurons by coupling to G protein‐regulated inducer of neurite outgrowth 1 (Gprin1), which targets it to the growth cone. Knockdown of Gprin1 expression using RNAi is found sufficient to abolish the localization and calcium signaling of α7 at the growth cone. In addition, an α7/Gprin1 interaction appears intimately linked to a Gαo, growth‐associated protein 43, and CDC42 cytoskeletal regulatory pathway within the developing axon. These findings demonstrate that α7 regulates axon growth in hippocampal neurons, thereby likely contributing to synaptic formation in the developing brain.

     

The Neuroplastin adhesion molecules: key regulators of neuronal plasticity and synaptic function

The Neuroplastins Np65 and Np55 are neuronal and synapse‐enriched immunoglobulin superfamily molecules that play important roles in a number of key neuronal and synaptic functions including, for Np65, cell adhesion. In this review we focus on the physiological roles of the Neuroplastins in promoting neurite outgrowth, regulating the structure and function of both inhibitory and excitatory synapses in brain, and in neuronal and synaptic plasticity. We discuss the underlying molecular and cellular mechanisms by which the Neuroplastins exert their physiological effects and how these are dependent upon the structural features of Np65 and Np55, which enable them to bind to a diverse range of protein partners. In turn this enables the Neuroplastins to interact with a number of key neuronal signalling cascades. These include: binding to and activation of the fibroblast growth factor receptor; Np65 trans‐homophilic binding leading to activation of p38 MAPK and internalization of glutamate (GluR1) receptor subunits; acting as accessory proteins for monocarboxylate transporters, thus affecting neuronal energy supply, and binding to GABA_A α1, 2 and 5 subunits, thus regulating the composition and localization of GABA_A receptors. An emerging theme is the role of the Neuroplastins in regulating the trafficking and subcellular localization of specific binding partners. We also discuss the involvement of Neuroplastins in a number of pathophysiological conditions, including ischaemia, schizophrenia and breast cancer and the role of a single nucleotide polymorphism in the human Neuroplastin (NPTN) gene locus in impairment of cortical development and cognitive functions.

     

Diamine Oxidase Induces Neurite Outgrowth in Chick Dorsal Root Ganglia by a Nonenzymatic Mechanism

Abstract: The enzyme diamine oxidase (DAO) catalyzes the oxidative deamination of histamine, diamines, and polyamines. DAO has been localized to several tissues, including thymus, kidney, intestine, seminal vesicles, placenta, and pregnancy plasma. DAO is not constitutively expressed in the mammalian brain, but it becomes detectable following focal injury. Although the physiologic role of DAO remains unknown, the observation that it is present at the interface between rapidly dividing and quiescent cells in several tissues suggests that it might be involved in regulating cell division or differentiation at tissue boundaries. In addition, the observation that DAO is expressed in the brain following injury suggests that the protein might play a role in the CNS response to focal neuronal damage. To test that hypothesis, we assessed the ability of purified DAO to alter the pattern of neuronal differentiation and nerve growth in vitro. In chick dorsal root ganglion explant cultures, purified porcine DAO induced neurite outgrowth in the low nanomolar range. Addition of aminoguanidine, which inhibits DAO enzyme activity, did not inhibit the protein's neurotrophic activity. These findings suggest that DAO can function as a neurotrophic ligand independent of its enzymatic activity.     

Generation and Culture of Blood Outgrowth Endothelial Cells from Human Peripheral Blood

Historically, the limited availability of primary endothelial cells from patients with vascular disorders has hindered the study of the molecular mechanisms underlying endothelial dysfunction in these individuals. However, the recent identification of blood outgrowth endothelial cells (BOECs), generated from circulating endothelial progenitors in adult peripheral blood, may circumvent this limitation by offering an endothelial-like, primary cell surrogate for patient-derived endothelial cells. Beyond their value to understanding endothelial biology and disease modeling, BOECs have potential uses in endothelial cell transplantation therapies. They are also a suitable cellular substrate for the generation of induced pluripotent stem cells (iPSCs) via nuclear reprogramming, offering a number of advantages over other cell types. We describe a method for the reliable generation, culture and characterization of BOECs from adult peripheral blood for use in these and other applications. This approach (i) allows for the generation of patient-specific endothelial cells from a relatively small volume of adult peripheral blood and (ii) produces cells that are highly similar to primary endothelial cells in morphology, cell signaling and gene expression.