THE REGULATION AND PACKAGING OF SYNAPTIC VESICLES RELATED TO RECRUITMENT WITHIN CRAYFISH AND FRUIT FLY NEUROMUSCULAR JUNCTIONS: VARIATIONS IN LOW- AND HIGH-OUTPUT TERMINALS

Wu, Wenhui

01 January 2013

Glutamate is the main excitatory neurotransmitter in the CNS and at the neuromuscular junctions (NMJs) of invertebrate. The characteristic similarities to CNS glutamatergic synapses in vertebrate and the anatomical simplicity of invertebrate NMJs favor the investigation of glutamatergic synaptic functions in this system. This dissertation mainly aimed to physiologically separate two functional vesicle groups, the reserve pool (RP) and readily releasable pool (RRP) within presynaptic nerve terminals of Procambarus Clarkii and Drosophila melanogaster. This was addressed in part by blocking the vesicular glutamate transporter (VGlut) with bafilomycin A1. Various frequencies of motor nerve stimulation, exposure time, and concentration of bafilomycin A1 were examined. The low-output tonic opener NMJs in crayfish exposed to 4μM bafilomycin A1 and 20Hz continuous stimulation decreased the EPSP amplitude to 50% in ∼30min with controls lasting 3h. After activity and bafilomycin A1-induced synaptic depression, the EPSPs were rapidly revitalized by serotonin (5-HT, 1μM) in the crayfish preparations. The 5-HT action can be blocked almost completely with a PLC inhibitor, but partially with a cAMP activator. The higher output synapses of the larval Drosophila NMJ when stimulated at 1Hz or 5Hz and exposed to 4μM of bafilomycin A1 showed a depression rate of 50% within ∼10min with controls lasting ∼40min. After low frequency depression and/or exposure to bafilomycin A1 a burst of higher frequency (10Hz) can recruit vesicles from the RP to the RRP. Physiological differences in low- (tonic like) and high-output (phasic like) synapses match many of the expected anatomical features of these terminals, part of this dissertation highlights physiological differences and differential modulation and/or extent of the vesicles in a RP for maintaining synaptic output during evoked depression of the RRP in crayfish abdomen extensor preparation. With the use of bafilomycin A1, the tonic terminal is fatigue resistant due to a large RRP, whereas the phasic depresses rapidly upon continuous stimulation. Upon depression of the tonic terminal, 5-HT has a large RP to act on to recruit vesicles to the RRP; whereas, the phasic terminal, 5-HT can recruit RP vesicles to the RRP prior to synaptic depression but not after depression.

neuromuscular junctions

reserve pool

readily releasable pool

bafilomycin A1

5-HT

Biology

Neuroscience and Neurobiology

Physiology

A Quantitative Description of the Interaction of Enhancement and Depression of Transmitter Release at the Neuromuscular Junction

Holohean, Alice Marie

21 December 2007

Synaptic transmission alters the strength of the postsynaptic potential, through a process called short-term synaptic plasticity (STP). In this study, endplate potentials (EPPs) from the frog neuromuscular junction were used to resolve and quantify the presynaptic components involved in enhancement and depression of transmitter release during repetitive stimulation under normal quantal release conditions (2 mM Ca2+, 1mM Mg2+). During trains of stimulation given between 10 - 200 Hz, the amplitude of the EPPs first increased then decreased; a maximum increase of 77% was produced after 2-4 stimuli. EPP amplitudes began to increase at ~ 20 Hz, were maximal at ~ 55 Hz, and thereafter, decreased as the rate of stimulation increased. The integrated total release after 25 stimuli was little changed across frequencies between 10 - 100 Hz. EPPs ran down in two phases: a fast phase, attributed to the depletion of a readily releasable pool (RRP) of synaptic vesicles, followed by a slow phase, attributed to the depletion of vesicles from a depot pool (DP). Depletion of the readily releasable pool of synaptic vesicles (RRP) was determined by quantifying release under the fast and slow time rundowns and subtracting the number of vesicles associated with mobilization to the RRP from the total number of vesicles released during stimulation trains of 50 impulses. Impulses were delivered at 12 different rates ranging from 50 to 200 /s. Estimates of the number of vesicles released from the RRP increased with frequency of stimulation until maximal depletion levels of 5500 - 6000 vesicles were reached at stimulation rates between 90-130/s, assuming a control quantal content of 200 vesicles released per impulse. Depletion was less at lower frequencies when the number of stimuli delivered was identical. When the RRP maximally depleted, release was inversely related to stimulation rate, as would be expected if mobilization from the depot pool was the sole determinate of release during the slow phase. An equation constructed from four known components of enhancement and two components of depression - the depletion of vesicles from a readily releasable pool (RRP) and from the depot pool (DP) that refills the RRP, was used to fit and then simulate EPPs obtained during trains using different patterns of stimulation and varying amounts of extracellular Ca2+; the decay time constant parameters of enhancement, numerically derived from the observed data, were fixed at tau ~ 46, 220, 1600, and 20000 ms. The number of components of enhancement necessary to approximate the data decreased, from four in low (0.14 - 0.2mM) extracellular Ca2+, to one (tau ~ 46 ms) in 2.0 mM extracellular Ca2+, but four components of enhancement were necessary to fit the data when the amplitude of the EPP was not depressed below the control amplitude. This model was able to predict within ~ 3 % EPP amplitudes over a 10-fold range of frequency and Ca2+ concentration.

Synaptic Transmission

Short Term Plasticity

Neuromuscular Junction

Facilitation

Augmentation

Depression

Model

Frog

F1

F2

Synaptic Plasticity

Readily Releasable Pool

Synaptic Vesicles

Reserve Pool

Mobilization

Identification de nouveaux régulateurs de la synaptogénèse GABAergique à la jonction neuromusculaire du nématode Caenorhabditis elegans / Identification of novel regulators of GABAergic synaptogenesis at neuromuscular junction of C. elegans

Gueydan, Marine

14 October 2019

Afin d’identifier de nouveaux régulateurs impliqués dans le contrôle du nombre des RGABAs à la synapse, nous avons utilisé la jonction neuromusculaire GABAergique du nématode Caenorhabditis elegans comme système modèle. Après mutagénèse aléatoire d’une souche knock-in exprimant les RGABAs tagués avec une protéine fluorescente (TagRFP), nous avons isolé plusieurs mutants présentant des défauts de localisation des récepteurs. Nous avons mis au point une nouvelle stratégie, basée sur l’analyse bio-informatique de données issues du séquençage du génome entier (WGS), en combinant identification et cartographie des mutations causales sans étape préalable de cartographie génétique. Sur 36 mutants analysés, nous avons retrouvé plusieurs gènes connus pour leur rôle dans la synaptogénèse GABAergique, validant ainsi notre approche. Nous avons initié la caractérisation fonctionnelle d’un nouveau gène candidat, provisoirement appelé nsp-3, qui code pour une protéine transmembranaire hautement conservée au cours de l’évolution. L’absence de nsp-3 induit la localisation ectopique de RGABAs au sein du muscle. Les récepteurs ectopiques colocalisent partiellement avec des marqueurs endosomaux. Des données d’électrophysiologie combinées à des analyses quantitatives du nombre de récepteurs synaptiques, montrent que NSP-3 régule la formation d’un pool de réserve de récepteurs sous-synaptiques. Des données pharmacologiques montrent que le recrutement de ce pool est essentiel dans la plasticité synaptique de la JNM GABAergique après un traitement aigu à l’aldicarbe, un inhibiteur de l’acétylcholine estérase (AChE). L’observation d’un reporteur transcriptionnel montre que nsp-3 est exprimé dans la plupart des tissus du vers. Des expériences de sauvetage phénotypique tissu-spécifiques et des données de colocalisation in vivo suggèrent que NSP-3 agit dans le muscle, à l’interface RE-Golgi, où elle régule le trafic des RGABAAs vers la surface. Cette étude décrit un rôle des nonaspanines dans un nouveau processus cellulaire où elles régulent le trafic des RGABAAs à la jonction neuromusculaire de C. elegans / To identify novel genes and mechanisms involved in the formation and regulation of inhibitory synapses, we used the inhibitory GABAergic neuromuscular junction of the nematode C. elegans as a genetically tractable model. After random mutagenesis of a knock-in strain expressing fluorescently tagged GABAA receptors (GABAAR), we screened for mutants with abnormal fluorescence pattern in vivo. We analyzed 36 mutant strains using a novel whole-genome sequencing strategy to simultaneously map and identify causative mutation without any prior time-consuming genetic mapping. We undertook the functional characterization of a non-characterized gene, tentatively named nsp-3, which encodes an evolutionarily conserved transmembrane protein. nsp-3 deletion using CRISPR technology causes ectopic localization of GABAAR in intracellular compartments of the muscle cell. We found partial colocalization of these ectopic receptors with endosomal markers. Interestingly, we observed a 50 % decrease of GABAAR at synapses while we saw no change in GABA neurotransmission by electrophysiology. These and additional data predict the presence of a subsynaptic pool of GABAARs, which is depleted in the absence of NSP-3. Additional pharmacological data set suggests that this pool of receptors is recruited for GABAergic synaptic plasticity upon acute aldicarb (acetylcholine esterase inhibitor) treatment. A transcriptional reporter of endogenous nsp-3 expression detected expression in most tissues of the worm. Tissue-specific rescue experiments and colocalization data show that NSP-3 functions in muscles at ER-Golgi interface to regulate GABAARs trafficking to cell surface. Our data identified a novel function of the nonaspanins in the traffic of neurotransmitter receptors in the nervous system

Récepteurs du GABA

Jonction neuromusculaire

Nonaspanines

C. elegans

Plasticité synaptique

Pool de réserve des récepteurs du GABA

GABA receptors

Neuromuscular junction

Nonaspanines

Neurotransmitter receptor trafficking

C. elegans

Synaptic plasticity

Reserve pool of GABA receptors

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