Role of Nestin in Mouse Development

Mohseni, Paria

05 March 2012

Although nestin has served as a marker of neural stem/progenitor cells for close to twenty years, its function is still poorly understood. During development, this intermediate filament protein is expressed in many different progenitors including those of the central nervous system, heart, skeletal muscle and kidney. The adult expression of nestin is mainly restricted to the subependymal zone and dentate gyrus of the brain, the neuromuscular junction and renal podocytes. I have used two approaches of gain of function and loss of function to elucidate the role of nestin in vivo. Although I was able to generate transgenic lines in which the transgene was ubiquitously expressed at the RNA level, over-expression of nestin at the protein level was not achieved possibly due to post transcriptional regulation of this gene. My data from loss of function approach indicates that nestin-deficient mice have impaired coordination. Balance and muscle strength are not affected and there are no apparent anatomical defects. I found that nestin deficiency is compatible with normal development of the central nervous system but results in abnormal clustering of acetylcholine receptors in the neuromuscular junctions, similar to the phenotype described for deficiency of cyclin-dependent kinase 5 (Cdk5) a candidate downstream effector of nestin. In renal podocytes, where both nestin and Cdk5 are normally expressed, we found reduced branching and abnormally contoured podocyte processes. To further connect the phenotype of nestin deficiency to Cdk5, I demonstrated that nestin deficiency can rescue maintenance of acetylcholine receptor clusters in the absence of agrin, similar to Cdk5/agrin double knockouts, indicating that the observed nestin deficiency phenotypes are the consequence of aberrant Cdk5 activity.

Nestin

Neuromuscular junction

Role of Nestin in Mouse Development

Mohseni, Paria

05 March 2012

Although nestin has served as a marker of neural stem/progenitor cells for close to twenty years, its function is still poorly understood. During development, this intermediate filament protein is expressed in many different progenitors including those of the central nervous system, heart, skeletal muscle and kidney. The adult expression of nestin is mainly restricted to the subependymal zone and dentate gyrus of the brain, the neuromuscular junction and renal podocytes. I have used two approaches of gain of function and loss of function to elucidate the role of nestin in vivo. Although I was able to generate transgenic lines in which the transgene was ubiquitously expressed at the RNA level, over-expression of nestin at the protein level was not achieved possibly due to post transcriptional regulation of this gene. My data from loss of function approach indicates that nestin-deficient mice have impaired coordination. Balance and muscle strength are not affected and there are no apparent anatomical defects. I found that nestin deficiency is compatible with normal development of the central nervous system but results in abnormal clustering of acetylcholine receptors in the neuromuscular junctions, similar to the phenotype described for deficiency of cyclin-dependent kinase 5 (Cdk5) a candidate downstream effector of nestin. In renal podocytes, where both nestin and Cdk5 are normally expressed, we found reduced branching and abnormally contoured podocyte processes. To further connect the phenotype of nestin deficiency to Cdk5, I demonstrated that nestin deficiency can rescue maintenance of acetylcholine receptor clusters in the absence of agrin, similar to Cdk5/agrin double knockouts, indicating that the observed nestin deficiency phenotypes are the consequence of aberrant Cdk5 activity.

Nestin

Neuromuscular junction

Transcriptional regulation of the human nicotinic acetylcholine receptor

Nichols, Philip Paul

January 1999

No description available.

612

Maximum likelihood analysis of neuronal spike trains

Emhemmed, Yousef Mohammed

January 1995

No description available.

612

A Genetic Analysis of the MicroRNA miR-133b in the Mammalian Nervous System

Heyer, Mary Patricia

January 2011

<p>The development and function of the nervous system relies on complex regulation of gene expression programs. MicroRNAs (miRNAs) are small RNAs that have diverse functions in mammalian development and disease. In concert with the RNA-induced silencing complex, miRNAs repress translation by binding to target mRNAs. The nervous system contains the largest proportion of miRNAs, yet few have been functionally characterized <italic>in vivo</italic>. </p><p>miR-133b is a highly conserved miRNA embedded in the sequence of 7H4, a noncoding RNA that is enriched at the neuromuscular junction (NMJ), a large synapse that is essential for eliciting muscle contraction and movement. I have found that, like 7H4, miR-133b expression is enriched at the NMJ and upregulated postnatally, coinciding with important events in synaptic maturation, including synaptic growth and elimination. Knockdown of miR-133b in postnatal muscle by electroporation of modified antisense oligonucleotides gave rise to abnormally large synapses, indicating a role for miR-133b in synaptic maturation. To specifically remove miR-133b <italic>in vivo</italic>, I generated a mouse containing a targeted deletion of the miR-133b stemloop. NMJ maturation and synapse elimination proceeded normally in miR-133b knockout mice, suggesting that miR-133b may have other functions at the synapse. The expression of 7H4 and miR-133b is upregulated following nerve transection, consistent with a role in synaptic regeneration. Indeed, NMJ reinnervation is delayed in miR-133b KO mice following nerve crush, but not nerve cut. These data suggest that miR-133b may have a specific protective function at the synapse that could be relevant to disease states, including amyotrophic lateral sclerosis (ALS), where NMJ denervation occurs following motor neuron cell death. However, loss of miR-133b did not affect survival or disease progression in the SOD1(G93A) mouse model, differentiating its role from that of miR-206, another miRNA found in 7H4.</p><p>miR-133b has recently been proposed to regulate the development and maintenance of midbrain dopaminergic (mDA) neurons. mDA neurons have critical functions in the control of movement and emotion, and their degeneration leads to motor and cognitive defects in Parkinson's disease. miR-133b is enriched in the midbrain and regulates mDA neuron differentiation <italic>in vitro</italic> by targeting Pitx3, a transcription factor required for appropriate development of substantia nigra DA neurons. However, the function of miR-133b in the intact midbrain has not been determined. miR-133b KO mice have normal numbers of midbrain dopaminergic neurons during development and aging. Moreover, dopamine neurotransmitter levels are unchanged in the striatum and other brain regions, while expression of dopaminergic genes including Pitx3 is also unaffected. Finally, miR-133b null mice display normal motor coordination and activity, suggesting that miR-133b does not play a significant role in the development or maintenance of the mDA neuron population.</p> / Dissertation

Neurosciences

microRNA

Midbrain

Neuromuscular Junction

The role of the cytoskeleton in AChR clustering

Dobbins, G. Clement

January 2007

Thesis (Ph. D.)--University of Alabama at Birmingham, 2007. / Title from first page of PDF file (viewed Feb. 6, 2008). Includes bibliographical references (p. 81-92).

Evaluation of neuromuscular transmission in organophosphorus pesticide toxicity

Dissanayake, Kosala Nimanthi

January 2015

Organophosphorus (OP) pesticide toxicity is a global health problem. Respiratory failure due to neuromuscular transmission dysfunction accounts for about 300,000 deaths annually in rural Asia. However, the clinical manifestation is complex, and described in terms of acute, intermediate, and chronic syndromes. The underlying mechanism of toxicity is still unclear. OP pesticides contain inhibitors of acetylcholinesterase (AChE), for example dimethoate, emulsified in an organic solvent, typically cyclohexanone. A hypothesized mechanism is initial excitotoxicity through inhibition of acetylcholinesterase followed by failure of neuromuscular synaptic transmission. I tested this electrophysiologically in vitro by measuring properties of spontaneous miniature endplate potentials (MEPPs) and evoked endplate potentials (EPPs) in isolated sciatic nerve/flexor digitorum brevis muscles from mice, bathed in HEPES-buffered mammalian physiological saline (MPS). Muscle action potentials were abolished with μ-conotoxin (2μM). First, we tested the effects of plasma taken from Göttingen minipigs instilled orally (isofluorane anaesthesia) with a formulated pesticide (2.5ml/kg) whose active ingredient is dimethoate dissolved in cyclohexanone. This plasma abolished evoked synaptic transmission and increased spontaneous MEPP frequency within 60-180 minutes of bath application. However plasma from minipigs instilled with dimethoate alone produced no failure of transmission. Plasma contained either pesticide or dimethoate significantly increased the half decay time of EPPs. However, pesticide-plasma also contained the metabolites omethoate (100μM) and cyclohexanol (5 mM). We found that bath application of omethoate alone caused a potent dose-dependent increase in EPP decay time. Cyclohexanol (5 mM) also increased EPP decay time but it also decreased both the excitability of axons and MEPP amplitude. In combination, omethoate and cyclohexanol produced greater disruption of neuromuscular transmission than either dimethoate or cyclohexanone, alone or in combination and this was particularly evident in isometric tension recordings, in which prolonged after-contraction and slow relaxation were observed during and immediately following tetanic stiumuation in the presence of omethoate and cyclohexanol. Voltage-clamp recordings of endplate currents (EPC) partially supported the EPP observations. Surprisingly, cyclohexanol-treated preparations showed no significant increase in EPC and MEPC decay time. However, there was some evidence of activity-dependent decline in MEPC amplitude in cyclohexanol while quantal content in these preparations showed evidence of an increase suggesting a homeostatic response in evoked transmitter release with cyclohexanol treatment. Analysis of presynaptic currents in cyclohexanol treated preparations also revealed preliminary evidence of sensitivity to cyclohexanol compared to control preparations. Finally, I tested the effects NMJ transmission of 24hr exposure to OP pesticide and its metabolites using a novel organ culture system, utilising a mouse mutant (WldS) with a slow nerve degeneration phenotype. After incubation of 24 hrs with MPS + pesticides and metabolites, these muscles showed significant reduction in function (response to nerve stimuli with EPP/action potential ± MEPPs) compared to control cultures. Together, the data indicate that failure of neuromuscular transmission by pesticide-plasma cannot be explained solely by dimethoate-mediated inhibition of acetylcholinesterase. Rather, a combination of metabolic breakdown products exerts potent, harmful presynaptic and postsynaptic effects. Either blocking the metabolic conversion of the constituents of OP pesticides, or transiently blocking their effects on receptors may therefore be an effective strategy for treatment of OP pesticide toxicity.

616.8

COMPARATIVE STUDY ON DROSOPHILA LARVAL LOCOMOTION AND NEUROMUSCULAR JUNCTION MORPHOLOGY

Yang, Emma Yunyi

19 August 2013

No description available.

Biology

Neuromuscular Junction

Locomotion

Drosophila

Genetic factors influencing the peripheral nervous system in health and disease

Comley, Laura Helen

January 2011

Lower motor neurons of the peripheral nervous system are responsible for innervating skeletal muscle and controlling all voluntary movements of the body. Degeneration of motor neurons underlies conditions such as amyotrophic lateral sclerosis and spinal muscular atrophy. The identification of genetic factors that influence the form and function of the peripheral nervous system in vivo will be important for our understanding of the neuromuscular system in health and disease. Here, I have studied the effects of three different genes and their respective protein products on the peripheral nervous system: yellow fluorescent protein (YFP), apolipoprotein E (apoE) and Ercc1 (excision repair cross-complementing group 1). YFP has been used as a reporter protein in many fields of research, including as a powerful tool for visualising neurons in mice. It is used under the assumption that it is biologically inert. However, my findings have revealed that YFP expressed in neurons in mice is not inert: it induces a cell stress response at both the RNA and the protein level and alters the time course of dying-back neuropathy. ApoE is a lipid transport protein with three distinct isoforms in humans (apoE2, apoE3 and apoE4), which are known to differentially affect risk and outcome in a number of central nervous system disorders. However, the effects of different apoE isoforms on the peripheral nervous system have yet to be established. I have shown that apoE4 delays peripheral nerve regeneration and subsequent neuromuscular junction reinnervation compared to apoE3, in the absence of any effects on normal form or function, degeneration or developmental plasticity. Ercc1 protein is involved in several DNA repair systems. Ercc1Δ/- mice have reduced levels of functional Ercc1 protein, which leads to a reduced life span and motor abnormalities, potentially due to a build of up DNA damage. Here I have shown that Ercc1Δ/- mice also have increased abnormalities at the neuromuscular junction (an early pathological target in neurodegeneration) with age. These findings contribute significantly to our understanding of the influence of specific genes on the form and function of the peripheral nervous system in health and disease.

616.8

Modulation of Synaptic Vesicle Pools by Serotonin and the Spatial Organization of Vesicle Pools at the Crayfish Opener Neuromuscular Junction

Bilkey, Jessica

01 May 2015

The crayfish claw opener neuromuscular junction (NMJ) is a biological model for studying presynaptic neuromodulation by serotonin and synaptic vesicle recycling. Serotonin acts on crayfish axon terminals to increase the release of the neurotransmitter glutamate, but a complete understanding of its mechanisms of action are unknown. In order to sustain enhanced neurotransmission over long periods of time, it was hypothesized that serotonin recruits (activates) a population of previously non-recycling vesicles to become releasable and contribute to neurotransmission. To determine if serotonin activates a distinct population of synaptic vesicles, FM1-43 fluorescence unloading experiments were performed on crayfish excitatory opener axon terminals. These experiments could not resolve a serotonin-activated population of synaptic vesicles, but instead revealed that synaptic vesicles change behaviour in axon terminals independent of serotonin, with vesicles becoming less likely to exocytose and unload FM1-43 dye over time. The change in behaviour was hypothesized to be due to conversion of vesicles from a recycling (releasable) status to a reserve (reluctant to release) status. Synaptic vesicle pool localization was then tested using photoconversion of FM1-43 and transmission electron microscopy techniques. The spatial location of FM1-43-labeled vesicles fixed 2 minutes following 20 Hz stimulation did not reveal retention of vesicles specifically near release sites and the distribution of FM1-43-labeled vesicles was not significantly different between early (2 min) and late (180 min) time points. Terminals fixed 30 seconds following stimulation, however, contained numerous endosome-like structures - the most frequently observed structures resembled large vesicles, which were the equivalent of 2-5 regular vesicle sizes. These results suggest that crayfish axon terminals recycle vast amounts of membrane in response to sustained 20-Hz stimulation and endocytosis appears to occur via multiple routes with the most common being through large vesicle intermediates. / Graduate

serotonin

Crayfish neuromuscular junction

synaptic vesicle pools