Global ETD Search

11	The Na⁺/H⁺ exchanger NHE1 plays a permissive role in regulating early neurite morphogenesis Moniz, David Matthew 05 1900 (has links) The ubiquitously expressed plasma membrane Na⁺/H⁺ exchanger isoform 1 (NHE1) plays an important role in directed cell migration in non-neuronal cells, an effect which requires both the ion translocation and actin cytoskeleton anchoring functions of the protein. In the present study, an analogous role for NHE1 as a modulator of neurite outgrowth was evaluated in vitro utilizing NGF-differentiated PC12 cells as well as mouse neocortical neurons in primary culture. Examined at 3 d.i.v., endogenous NHE1 was found to be expressed in growth cones, where it gave rise to an elevated intracellular pH in actively-extending neurites. Application of the NHE inhibitor cariporide at an NHE1-selective concentration (1 μM) resulted in reductions in neurite extension and elaboration while application of 100 μM cariporide, to inhibit all known plasmalemmal NHE isoforms, failed to exert additional inhibitory effects, suggesting a dominant role for the NHE1 isoform in modulating neurite outgrowth. In addition, whereas transient overexpression of full-length NHE1 enhanced neurite outgrowth in a cariporide-sensitive manner in both NGF-differentiated PC12 cells and WT neocortical neurons, neurite outgrowth was reduced in NGF-differentiated PC12 cells overexpressing NHE1 mutants deficient in either ion translocation activity or actin cytoskeleton anchoring, suggesting that both functional domains of NHE1 are important for modulating neurite elaboration. A role for NHE1 in modulating neurite outgrowth was confirmed in neocortical neurons obtained from NHE1-/- mice which displayed reduced neurite outgrowth when compared to neurons obtained from their NHE1⁺/⁺ littermates. Further, neurite outgrowth in NHE1-/- neurons was rescued by transient overexpression of full-length NHE1 but not with mutant NHE1 constructs again suggesting that both functional domains of NHE1 are important for modulating neurite outgrowth. Finally, the growth promoting effects of netrin-1 but not BDNF or IGF-1 were abolished by cariporide in WT neocortical neurons and while both BDNF and IGF-1 were able to promote neurite outgrowth in NHE1-/- neurons, netrin-1 was unable to elicit this effect. Taken together, these results indicate that NHE1 is a permissive regulator of early neurite morphogenesis and also plays a novel role in netrin-1-stimulated neurite outgrowth. / Medicine, Faculty of / Graduate Neurite outgrowth Axon Dendrite Nhe1 Na⁺/h⁺ exchange Intracellular ph
12	The Receptor Protein Tyrosine Phosphatase-mu Signaling Pathway Differentially Regulates E-cadherin, N-cadherin and R-cadherin-Mediated Axon Outgrowth Oblander, Samantha Anne 21 July 2009 (has links) No description available. E-CADHERIN Neurite Neurite Outgrowth PTP¿¿¿¿ OUTGROWTH R-CADHERIN-MEDIATED RGC
13	STUDIES ON NEURITE OUTGROWTH AND RECEPTOR PHOSPHORYLATION FOLLOWING KAPPA OPIOID RECEPTOR ACTIVATION Chiu, Yi-Ting January 2016 (has links) Kappa opioid receptor (KOPR) is involved in many physiological functions and pharmacological responses such as analgesia, anti-pruritic effect, sedation, motor incoordination and aversion (Simonin et al., 1998; Liu-Chen, 2004). The cellular mechanisms following activation of KOPR involve in part Gi/o protein-dependent pathways (Law et al., 2000). Following KOPR activation, the receptor is phosphorylated and arrestins are recruited. Arrestins mediate agonist-dependent KOPR desensitization, internalization and down-regulation (Liu-Chen, 2004). In recent years, arrestins were found to initiate arrestin-dependent downstream signaling. Thus, agonist-promoted KOPR phosphorylation plays a pivotal role in KOPR regulation and signaling. Previous studies from our lab showed that in Chinese hamster ovary (CHO) cells stably transfected with the human KOPR (hKOPR), U50,488H induced phosphorylation (Li et al., 2002a); however, sites of phosphorylation were not determined. Using LC-MS/MS, our lab recently identified four residues (S356, T357, T363 and S369) to be the sites of U50,488H-promoted phosphorylation in the mouse KOPR (mKOPR) stably expressed in N2A cells (Chen et al., 2016). Antibodies were generated against phosphopeptides and purified and three antibodies were found to have high specificity for the mKOPR phosphorylated at S356/T357, T363 and S369, respectively (Chen et al., 2016). Our lab previously showed that while U50,488H promoted robust hKOPR phosphorylation and internalization, etorphine induced little phosphorylation and internalization, although both were potent full agonists in enhancing [35S]GTPγS (Li et al., 2002a; Zhang et al., 2002; Li et al., 2003). Etorphine caused lower levels of KOPR phosphorylation at all the four residues than U50,488H by immunoblotting with the phospho-specific antibodies (Chen et al., 2016). Using the SILAC (stable isotope labeling by amino acids in cell culture) approach, we have found that compared to etorphine, U50,488H promoted higher levels of single phosphorylation at T363 and S369 and double phosphorylation at T363+S369 and T357+S369 as well as triple phosphorylation at S356+T357+S369 (Chen et al., 2016). These results indicate that an above-threshold phosphorylation is required for KOPR internalization. It has been reported that KOPR is involved in neuronal differentiation and neurogenesis. In the first chapter, I focused on whether there are differences in the mechanisms underlying neurite outgrowth induced by U50,488H and etorphine. In the chapter 2, mechanisms of KOPR phosphorylation were characterized in detail using phospho-specific KOPR antibodies. Protein kinase C was found, for the first time, to be involved in agonist-promoted KOPR phosphorylation. The roles of PKC in behavioral effects induced by KOPR agonists in mice were examined. For the chapter 1, in Neuro2a mouse neuroblastoma cells stably transfected with the hKOPR (N2A-3HA-hKOPR), U50,488H robustly induced neurite outgrowth, but etorphine caused outgrowth to a much lower extent. G protein-dependent pathway was found to be involved in the actions of both agonists, but β-arrestin-dependent pathway was not. Inhibition of ERK1/2 phosphorylation decreased neurite outgrowth promoted by both agonists, indicating the roles of MAP kinase cascades in KOPR agonist-induced neuritogenesis. In contrast, β-arrestin2, 14-3-3ζ, GEC1 and Rap1 are not involved in U50,488H- or etorphine-promoted neurite outgrowth. Thus, the two agonists appear to share the same signaling pathways and the difference between two agonists is likely due to the lower efficacy of etorphine. For the chapter 2, U50,488H caused phosphorylation of the mKOPR at S356, T357, T363 and S369 in N2A cells stably transfected with FmK6H (FmK6H-N2A cells). NorBNI abolished U50,488H-induced KOPR phosphorylation at all four residues. GRKs (GRKs2, 3, 5 and 6) and PKCs were involved in U50,488H-mediated KOPR phosphorylation. In addition, PKC also participated in agonist-independent KOPR phosphorylation. This is the first time that PKC was shown to be involved in agonist-induced KOPR phosphorylation. We found that U50,488H caused KOPR phosphorylation at T363 and S369 in the mouse brain and PKC participated in phosphorylation of S369, but not T363, by using the PKC inhibitor chelerythrine (CHL). Thus, we further characterized effects of PKC inhibition on KOPR-mediated behaviors in CD1 mice. PKC was involved in KOPR-mediated sedation, motor incoordination and conditioned place aversion, but not analgesia and anti-scratching effect in mice. Studies in this thesis revealed the mechanisms of KOPR-mediated neurite outgrowth and KOPR-mediated phosphorylation and the involvement of PKC in KOPR-mediated pharmacological effects in vivo. These studies push the frontier of molecular pharmacology of the KOPR, which may be useful for development of KOPR agonists for therapeutic use. / Pharmacology Pharmacology Kappa Opioid Receptor Neurite Outgrowth Receptor Phosphorylation
14	Primary culture of Drosophila larval neurons with morphological analysis using NeuronMetrics Smrt, Richard D., Lewis, Sara A., Kraft, Robert, Restifo, Linda L. 12 1900 (has links) No description available. primary culture axon brain dendrite dissociation image analysis immunofluorescence insect neurite arbor neurite outgrowth neurogenetics software
15	MIR, a novel ERM-like protein in the nervous system Olsson, Per-Anders January 2001 (has links) <p>Proteins of the band 4.1 superfamily are characterized by their sequence similarity to the ERM proteins ezrin, radixin and moesin, which are involved in cell motility, adhesion of cells, and signal transduction events. Little is however known of the function of ERM proteins in the nervous system, though an essential role for radixin and moesin in neuronal growth cone motility has been suggested. </p><p> This thesis is focused on the cloning, functional characterization and description of the tissue distribution in rat brain of MIR, a novel member of the band 4.1 superfamily. </p><p> The cDNA of MIR encods a protein of 445 amino acids which is composed of an ERM-homology domain and a RING finger, separated by an interregion. To reveal the cellular function of MIR, PC12 cell lines overexpressing MIR was generated and observed to inhibit NGF stimulated neurite outgrowth. </p><p> To elucidate the signal transduction of MIR by which it exerts its physiological activity, the yeast two-hybrid system was employed to screen for proteins that interact with MIR. A number of interactors known to regulate the cytoskeleton was obtained - among them myosin regulatory light chain-B which controls the actomyosin complex - and a novel type 2 membrane protein denoted NSAP for its similarity to saposin A-D. Overexpressed NSAP induced neurite outgrowth in PC12 cells and enhanced cell adhesion in fibroblasts. </p><p> The tissue distribution of MIR in rat brain, as determined by immunohistochemistry studies, showed that MIR is localized especially to neurons in hippocampus and cerebellum. The chromosomal localization of the MIR gene was assessed to 6p22.3-23, a region lost in the 6p23 deletion syndrome.</p><p> These results suggests that MIR is expressed in neurons in discrete regions of rat brain where it may regulate neurite outgrowth by modulating the cytoskeleton.</p> Neurosciences MIR ERM band 4.1 superfamily MRLC NSAP neurite outgrowth nervous system Neurovetenskap Neurology Neurologi
16	MIR, a novel ERM-like protein in the nervous system Olsson, Per-Anders January 2001 (has links) Proteins of the band 4.1 superfamily are characterized by their sequence similarity to the ERM proteins ezrin, radixin and moesin, which are involved in cell motility, adhesion of cells, and signal transduction events. Little is however known of the function of ERM proteins in the nervous system, though an essential role for radixin and moesin in neuronal growth cone motility has been suggested. This thesis is focused on the cloning, functional characterization and description of the tissue distribution in rat brain of MIR, a novel member of the band 4.1 superfamily. The cDNA of MIR encods a protein of 445 amino acids which is composed of an ERM-homology domain and a RING finger, separated by an interregion. To reveal the cellular function of MIR, PC12 cell lines overexpressing MIR was generated and observed to inhibit NGF stimulated neurite outgrowth. To elucidate the signal transduction of MIR by which it exerts its physiological activity, the yeast two-hybrid system was employed to screen for proteins that interact with MIR. A number of interactors known to regulate the cytoskeleton was obtained - among them myosin regulatory light chain-B which controls the actomyosin complex - and a novel type 2 membrane protein denoted NSAP for its similarity to saposin A-D. Overexpressed NSAP induced neurite outgrowth in PC12 cells and enhanced cell adhesion in fibroblasts. The tissue distribution of MIR in rat brain, as determined by immunohistochemistry studies, showed that MIR is localized especially to neurons in hippocampus and cerebellum. The chromosomal localization of the MIR gene was assessed to 6p22.3-23, a region lost in the 6p23 deletion syndrome. These results suggests that MIR is expressed in neurons in discrete regions of rat brain where it may regulate neurite outgrowth by modulating the cytoskeleton. Neurosciences MIR ERM band 4.1 superfamily MRLC NSAP neurite outgrowth nervous system Neurovetenskap Neurology Neurologi
17	Roles of mammalian Scribble in polarity signaling, virus offense and cell-fate determination Wigerius, Michael January 2010 (has links) Mammalian Scribble is a target for proteins encoded by human papilloma virus, retro- and flaviviruses. Tick-borne encephalitis virus (TBEV) is a flavivirus that have evolved distinct strategies to escape antiviral responses. Information of how flaviviruses intrude on cell integrity comes from understanding of the roles that host-factors play when they interfere with viruses. The first part of this thesis describes a novel interaction between the TBEVNS5 protein and Scribble. The importance of the interaction was demonstrated by RNAi-mediated depletion of Scribble, which prevented suppression of JAK-STAT signaling by NS5. Together, these results define Scribble as a novel target for NS5. TBEV is known to cause central nervous system disease TBE in humans that can lead to cognitive dysfunction. A unifying theme in CNS related diseases are defects in neuronal extensions. We therefore addressed the effects of TBEV expression in PC12 cell differentiation, which is characterized by extensive neurite growth. Our data show that TBEVNS5 suppresses neurite outgrowth through the Rho GTPase Rac1. These findings provide evidence that Rac1 is an indirect target of NS5 in neurite inhibition. Scribble was recently implicated in spine morphogenesis. Thus, we tested the role of Scribble in neurite elongation. Depletion of Scribble in PC12 cells, reduced neurite density but increased length of those remaining. Moreover, Scribble bound components in the Ras/ERK cascade in a growth factor dependent manner. Together, these results demonstrate that Scribble controls neurite elongation by scaffolding MAPK components. Moreover, as loss of dendritic spines, actin-rich protrusions on neurons, is a feature in cognitive dysfunction we speculate that cognitive dysfunction in TBE might involve disturbed Scribble expression by NS5. We also investigated the binding between NS1 of Influenza A virus and Scribble. The PDZ domains of Scribble are usually selective for specific C-terminal motifs in proteins. Because NS1 has a canonical PDZ motif we tested if binding to Scribble depends on this motif. We found that Scribble binds NS1; the association is dependent on the NS1 C-terminus that is recognized by PDZ3-4 of Scribble. Together, these results suggest that Scribble is a target for the H5N1 NS1 protein / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: In press. Paper 3: Manuscript. Paper 4: Manuscript. cell polarity scribble tbev RhoGTPase jak-stat mapk neurite outgrowth influenza a virus Biochemistry Biokemi
18	Modulation of neural plasticity by the ADAMTSs (a disintegrin and metalloproteinase with thrombospondin motifs) Hamel, Michelle Grace 01 June 2006 (has links) Aggregating proteoglycans (PG) bearing chondroitin sulfate (CS) side chains are well-known inhibitors of neural plasticity and associate with hyaluronan and tenascin-R to form a complex of extracellular matrix (ECM) in the central nervous system (CNS). Little is known about whether proteolytic cleavage of the core protein affects neural plasticity. Several members of the ADAMTS (a disintegrin and metalloproteinase with thrombospondin motifs) family of metalloproteinases are glutamyl-endopeptidases that cleave aggregating PGs. Our initial studies determined that neural cultures secrete a brevican-containing matrix, and that these neural cultures also produced ADAMTS4, a protease that cleaves brevican. Furthermore, this brevican-containing matrix in astrocytes could be modulated by treatment with transforming growth factor beta (TGFbeta) through the inhibition of the activity of the ADAMTSs.Once it was established that neural cultures produce a brevican-rich matrix, we s ought to utilize this matrix to determine whether cleavage of aggregating PGs, especially brevican, by the ADAMTSs influences neurite outgrowth in cultured neurons. Transfection of rat neurons with ADAMTS4 cDNA induced longer neurites, and interestingly, this effect proved to be independent of the proteolytic action of the ADAMTSs. Addition of recombinant ADAMTS4 or ADAMTS5 protein to immature neuronal cultures similarly enhanced neurite extension, an action dependent on the activation of extracellular signal-related kinase (ERK)1/2 (MAP kinase 42/44), resulting in the first evidence that ADAMTSs may induce intracellular signaling events. Studies of dendritic spine morphology and levels of synaptic proteins in response to ADAMTS4 treatment were also undertaken. Neuronal cultures treated with ADAMTS4 showed increased length of dendritic spines and increased percent of immature spines detected. A concurrent decrease in post-synaptic protein staining was detected on the neurites of yo ung neurons overexpressing ADAMTS4 or expressing proteolytically-inactive mutant ADAMTS4 protein. Thus, ADAMTS4 may promote plasticity in neurons in vitro by preventing the formation, maturation, and/or stabilization of synapses. Overall, these experiments provide evidence that implicate the ADAMTSs as mediators of neural plasticity, and while primarily known only as proteases, these studies demonstrate that the ADAMTSs exert actions distinct from these proteolytic properties that require the induction of intracellular signaling events. Neurite outgrowth Dendritic spine Proteoglycan Extracellular matrix Protease American Studies Arts and Humanities
19	Biologically plausible models of neurite outgrowth Kiddie, Gregor A. C. January 2011 (has links) The growth of a neuronal dendritic tree depends on the neuron’s internal state and the environment within which it is situated. Different types of neuron develop dendritic trees with specific characteristics, such as the average number of terminal branches and the average length of terminal and intermediate segments. A key aspect of the growth process is the construction of the microtubule cytoskeleton within the dendritic tree. Neurite elongation requires assembly of microtubules from free tubulin at the growth cone. The stability of microtubule bundles is an important factor in determining how likely it is for a growth cone to split to form new daughter branches. Microtubule assembly rates and bundle stability are controlled by microtubule-associated proteins, principally MAP2 in dendrites. Extending previous work (Hely et al, J. Theor. Biol. 210:375-384, 2001) I have developed a mathematical model of neurite outgrowth in which elongation and branching rates are determined by the phosphorylation state of MAP2 at the tips of each terminal branch. Tubulin and MAP2 are produced in the cell body and transported along the neurite by a combination of diffusion and active transport. Microtubule (dis)assembly at neurite tips is a function of tubulin concentration. The rate of assembly depends on the amount of unphosphorylated MAP2 bound to the microtubules and linking them together. Phosphorylation of MAP2 destroys its linking capability and destabilises the microtubule bundles. Each terminal has a probability of branching that depends on the phosphorylation of MAP2 which, in turn, is a function of calcium concentration. Results from this model show that changes in the (de)phosphorylation rates of MAP2 affect the topology of the final dendritic tree. Higher phosphorylation promotes branching and results in trees with many short terminal branches and relatively long intermediate segments. Reducing phosphorylation promotes elongation and inhibits branching. 612.8
20	Biomimetic Orientated Total Synthesis of Neovibsane Natural Products and Comparison of Synthetic Neovibsanes on Neurite Outgrowth Promotion in PC12 Cells Annette Chen Unknown Date (has links) Neovibsanin A and B are natural products which induced neurite outgrowth in PC12 cells. They belong in the neovibsane class under the rare vibsane natural product family, whose structures are characterized by polycyclic, polyoxygenated cores. Based on a proposed biosynthesis, the synthetic strategy towards neovibsanin A and B involved synthesizing a key enone intermediate. Initial investigation using this intermediate lead to the total synthesis of 2-O-methylneovibsanin H. Crucial to this concise synthesis was an acid-catalyzed, one-pot, four-step cascade reaction. Modifying the reaction condition leads to a different five-step cascade pathway, resulting in the total synthesis of 4,5-bis-epi-neovibsanin A and B. The synthetic trials and tribulations encountered on the road to these final compounds are explored. It is envisaged that other related neovibsane natural products may arise based on this synthetic sequence. 4,5-Bis-epi-neovibsanin A and B, as well as several other structural analogues collected during the synthesis, were biologically assayed using NGF-stimulated PC12 cells. All compounds induced a significant proportion of neurons to extend neurite processes compared to control cultures. The structure-activity relationship studies indicated that the tricyclic core, as well as the 3,3-dimethylacroyl enol ester side chain, may be responsible for promoting a biological response. neovibsanin a neovibsanin b 2-O-methylneovibsanin h biological activity neurite outgrowth natural product total synthesis

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