Structural, Genetic and Physiological Analysis of the Juxtamembrane Region of Drosophila neuronal-Synaptobrevin

DeMill, Colin Don Malcolm

08 January 2014

Synaptic transmission requires the fusion of neurotransmitter containing vesicles with the neuron's plasma membrane in a temporally restrictive manner. In Drosophila, this challenge is accomplished in part by the SNARE protein neuronal-Synaptobrevin (n-Syb). The juxtamembrane region of this molecule, linking the cytosolic SNARE motif and transmembrane region, is hypothesized to play a functional role in facilitating membrane fusion. This short, 10 amino acid, segment contains numerous charged residues and one conserved tryptophan residue. Its short rigid structure may be important in transducing force during SNARE complex assembly. Tryptophan residues, common in membrane proteins, are often observed at the membrane-water interface. It was hypothesized that this conserved tryptophan residue was important for anchoring and positioning n-Syb in the membrane. Proteins produced with tryptophan mutated were tested for anchoring and stability in a membrane model using NMR spectroscopy. Experiments testing depth of insertion using exposure to oxygen, a paramagnetic species, and exchange with deuterium demonstrated that tryptophan anchored n-Syb in the membrane. To test a potential functional role for the juxtamembrane region of n-Syb in synaptic transmission, a reverse genetic approach was employed. Wild-type and mutant P-element clones were made using the genomic sequence of n-syb including the endogenous promoter. n-Syb was found to be expressed, integrate and orient correctly in the membrane of Drosophila S2 cells. Transgenic Drosophila, produced via P-element transformation, were also found to produce transgenic protein. Transgenic expression of wild-type n-syb was found to restore an n-syb hypomorphic mutant from severe motor impairment and limited lifespan to wild-type levels. Synaptic transmission was assessed in 3rd instar larval preparations of mutant and wild-type transgenics. Mutation of the tryptophan residue and insertion of a short flexible linker were both found to inhibit synaptic transmission, while insertion of a long flexible linker was not.

neuronal-Synaptobrevin

SNARE protein

Juxtamembrane region

Synaptic transmission

0719

0317

0307

Expression and function of Rab3 interacting molecules and clarin-1 in inner hair cells

Oshima-Takago, Tomoko

12 March 2013

No description available.

570

Synapse

Inner hair cell

Active zone

Usher syndrome

Synaptic transmission

Calcium channel

Biologie (PPN619462639)

Úloha TRPV1 receptorů v chemokinem CCL2 indukované modulaci nociceptivního synaptického přenosu na míšní úrovni / The role of TRPV1 receptors in chemokine CCL2 induced modulation of nociceptive synaptic transmission at spinal cord level

Adámek, Pavel

January 2014

Modulation of nociceptive synaptic transmission in the spinal cord dorsal horn is a significant mechanism in the development and maintenance of different pathological pain states. Accumulating evidence indicates that the TRPV1 (transient receptor potential vanilloid 1) receptor and chemokine CCL2 (C-C motif ligand 2) may play a critical role in this process. The aim of this diploma thesis was to investigate the CCL2 induced modulation of nociceptive synaptic transmission in the dorsal horn of spinal cord and the role of the TRPV1 receptors. To investigate this aim patch-clamp recordings of spontaneous and miniature excitatory postsynaptic currents (sEPSC, mEPSC) from superficial dorsal horn neurons in acute rat lumbar spinal cord slices were used. After acute application of CCL2 on the slice preparation from naïve animals, a frequency increase of both sEPSC and mEPSC was present. This CCL2 induced increase in both sEPSC and mEPSC frequency was prevented by the TRPV1 receptor antagonist SB366791 application. No changes were observed in the amplitudes of sEPSC or mEPSC after application of the CCL2, SB366791, or co-application of CCL2 and SB366791. This suggests that the observed changes were mediated predominantly by presynaptic mechanisms. The preliminary results indicate that after chronic constriction...

Évaluation de l’impact de l’usage régulier de cannabis sur le fonctionnement rétinien par la mesure de l’électrorétinogramme / Evaluation of the impact of the regular cannabis use on the retinal functioning by the measure of the electroretinography

Schwitzer, Thomas

07 November 2016

Un des obstacles majeurs de la recherche en neurosciences est la difficulté d’accéder de manière directe au fonctionnement du cerveau afin de comprendre les mécanismes biologiques à l’origine des dysfonctionnements cérébraux dans les troubles psychiatriques. En tant qu’extension anatomique et développementale du système nerveux central, la rétine pourrait permettre d’offrir un accès indirect aux fonctions neurologiques cérébrales. Ainsi, l’investigation de la fonction rétinienne apporte l’unique opportunité d’étudier de manière objective un réseau neuronal complexe présentant des similarités avec celui du cerveau. Le cannabis est une substance neurotoxique identifiée comme modulant la transmission synaptique cérébrale par l’intermédiaire du système cannabinoïde mais les mécanismes précis à l’origine de ces anomalies sont peu connus. La première partie de ce travail consiste à présenter les bases neurobiologiques et les hypothèses physiopathologiques justifiant l’étude de la fonction rétinienne chez les usagers de cannabis, en se basant sur la présence du système cannabinoïde dans la rétine et son implication dans la régulation de la libération synaptique de neurotransmetteurs. La seconde partie discute l’intérêt de l’étude de la fonction rétinienne dans la recherche en psychiatrie avec des méthodes électrophysiologiques. Enfin, la dernière partie présente les dysfonctions rétiniennes présentes chez les usagers de cannabis, après un usage aigu ou régulier, évaluées par les techniques électrophysiologiques comme l’électrorétinogramme. Toutes ces données renforcent la pertinence de la rétine comme site d’investigation du cerveau et ouvrent éventuellement la perspective au développement de marqueurs fonctionnels / One of major obstacles in neuroscience research is the difficulty of directly accessing the brain function to understand the biological mechanisms underlying brain dysfunctions in psychiatric disorders. As an anatomical and developmental extension of the central nervous system, the retina could afford to offer an indirect access to brain neurological functions. Investigating the retinal function provides the unique opportunity to study in an objective way a complex neuronal network which shares similar properties with the brain. Cannabis is a neurotoxic substance identified as modulating brain synaptic transmission through the cannabinoid system, but the precise mechanisms underpinning these anomalies are poorly understood. The first part of this work is dedicated to present the neurobiological basis and pathophysiological hypotheses justifying the study of retinal function in cannabis users and is based on the presence of the cannabinoid system in the retina and its involvement in the regulation of synaptic neurotransmission. The second part discusses the interest of the study of retinal function with electrophysiological methods in psychiatric research. The last part presents the retinal dysfunctions detected in cannabis users, after acute or regular use, and assessed by electrophysiological techniques such as electroretinogram. All these data reinforce the relevance of the retina as a site of brain investigation and possibly open the prospect for the development of functional markers

Rétine

Électrorétinogramme

Cannabis

Cannabinoïdes

Transmission synaptique

Retina

Electroretinography

Cannabis

Cannabinoids

Synaptic transmission

613.835

617.730 7547

Synaptic transmission in rat globus pallidus: an electrophysiological, immunocytochemical and behavioral study. / CUHK electronic theses & dissertations collection

January 2004

Chen Lei. / "February 2004." / Thesis (Ph.D.)--Chinese University of Hong Kong, 2004. / Includes bibliographical references (p. 124-161). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Mode of access: World Wide Web. / Abstracts in English and Chinese.

Neural transmission

Globus pallidus

Electrophysiology

Immunocytochemistry

Synaptic Transmission

Globus Pallidus

Electrophysiology

Immunohistochemistry

gamma-Aminobutyric Acid--physiology

Genetic and functional analysis of synaptic CA²⁺ dynamics in Drosophila

Xing, Xiaomin

01 December 2014

Ca²⁺ influx is one of the critical events that trigger synaptic vesicular release, and the accumulation of residual free Ca²⁺ in synapses is also important for activity-dependent synaptic plasticity. Ca²⁺ imaging with fluorescence indicators (synthetic or genetically encoded) is a powerful approach to monitor Ca²⁺ levels in neurons and synapses. Although accumulating studies in vertebrate systems have been carried out to demonstrate the role of Ca²⁺ in synaptic transmission and plasticity, most of these studies rely on pharmacological methods to infer the molecular mechanism, with less emphasis on forward genetic analysis. The Drosophila neuromuscular junction (NMJ) is a powerful neurogenetic platform for studying synaptic transmission, because of the availability of many mutations. However, not many mutations have been analyzed with Ca²⁺ imaging. Besides, although Genetically Encoded Ca²⁺ Indicators (GECIs) including GCaMPs are increasingly popular as the tool to identify neuronal circuits activated by certain stimuli or mediating particular behaviors, the physiological and functional interpretation of neuronal Ca²⁺ transients reported by GECIs remain obscure. By expressing GCaMPs in NMJ synapses, I characterized a spectrum of genetic mutations including sodium channel alleles parats¹, parabss¹, potassium channel mutations Shaker (ShM, Sh¹²⁰), Shab³, ether-a-go-go (eag¹, eag⁴pm), and double mutant eag¹ Sh¹²⁰. Drosophila NMJs contain at least three different types of synapses, which include glutamatergic tonic motor synapse type Ib, phasic motor synapse type Is, and modulatory octopaminergic synapse type II. In this study, I found that the ion channel mutations did not uniformly alter the Ca²⁺ dynamics in type Ib, Is and II synapses. Based on genetic dissection and pharmacological analyses, I concluded that the excitability type I and type II synapses are differentially regulated by various ion channels, and that ion channels mainly influence the influx of Ca²⁺ upon membrane depolarization but not the subsequent clearance. I also attempted to interpret the significance of synaptic Ca²⁺ transients by correlating Ca²⁺ imaging with electrophysiological recordings. One important gap in the application of GCaMP indicators is its postsynaptic physiological relevance. Correlation of synaptic GCaMP Ca²⁺ transients with postsynaptic currents simultaneously recorded by focal extracellular recording indicated that Ca²⁺ transients reported by GCaMPs were slow, and did not reflect immediate synaptic transmission. Rather, the kinetics of synaptic Ca²⁺ transients was temporally correlated with short-term synaptic plasticity such as facilitation and depression. The hyperexcitable ion channel mutations Sh and parabss¹ enhanced the synaptic Ca²⁺ transient amplitudes as well as depression. Type Is synapses of hyperexcitable mutations such as eag¹ Sh¹²⁰ and parabss¹ often displayed single stimulus pulse-evoked Ca²⁺ transients, which were induced by high frequency repetitive firing of action potentials. Such Ca²⁺ transients were correlated with supernumerary peaks of postsynaptic currents. Based on the slow kinetics and the correlation with short-term plasticity, I conclude that GCaMP Ca²⁺ signals better reflect the accumulation of cytosolic residual Ca²⁺. The spontaneous Ca²⁺ waves in larval motor neurons were well correlated with high frequency nerve action potentials, suggesting that accumulation of residual Ca²⁺ occurs in larval crawling. Overall, this study provided important information about the different excitability control and Ca²⁺ clearance mechanisms in different synapses, and examined how membrane excitability controls the influx and accumulation of synaptic cytosolic residual Ca2+, as indicated by GCaMPs. Further, by correlating synaptic Ca²⁺ dynamics with electrophysiology, this study also investigated how to interpret GCaMP Ca²⁺ signals in the context of facilitation and depression, establishing a basis for an integrated approach of studying short-term synaptic plasticity from complementary physiological signals.

activity-dependent plasticity

Calcium imaging

ion channel

octopamine

synaptic transmission

Biology

GABA-, glycine- and glutamate-induced currents in rat medial preoptic neurons : functional interactions and modulation by capsaicin

Karlsson, Urban

January 2007

The medial preoptic nucleus (MPN) of the hypothalamus plays a major role in many functions involved in maintaining bodily homeostasis, such as thermoregulation and osmoregulation, as well as in the control of complex behaviours, e.g. sexual behaviour. A fundamental basis for the control and execution of these functions is the synaptic communication between neurons of the MPN. However, the functional properties of the synapses involved are largely unknown. The present thesis is a study of ligand-gated ion channels involved in the pre- and post-synaptic aspects of neuronal communication in the MPN of rat. The aim was to clarify synaptic properties in the MPN, to identify the major channel types involved and to obtain a better understanding of their functional properties. By fast application of agonists to isolated neurons, it was first demonstrated that all neurons responded to glutamate with currents mediated by α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors, and a majority of neurons also with currents mediated by N-Methyl-D-aspartate (NMDA) receptors. All neurons also responded to γ-aminobutyric acid (GABA) and glycine with currents mediated by GABAA receptors and glycine receptors, respectively. These findings show that fast-acting excitatory and inhibitory amino-acid transmitters are most likely important for communication between hypothalamic neurons. Application of agonists to isolated neurons revealed cross-talk, detected as an apparent cross-desensitization, between the responses to GABA and those to glycine. Parallel analysis of current and conductance, using gramicidin-perforated patches to avoid perturbing intracellular chloride concentration, showed that the cross-talk was not dependent on a direct interaction between the receptors as previously suggested, but was a consequence of the change in the intracellular chloride concentration during receptor activation. Strengthened by a computer model, the analysis also showed that the current decay in the presence of GABA or glycine was mainly due to a change in the chloride driving force and that receptor desensitization played a minor role only. The role of thermo-sensitive transient receptor potential TRPV1 channels in the regulation of glutamate- and GABA-mediated transmission was studied in the slice preparation, where much of the synaptic connections between neurons are preserved. It was shown that application of the TRPV1 agonist capsaicin increased the frequency of excitatory AMPA receptor- mediated as well as inhibitory GABAA receptor-mediated postsynaptic currents. This effect was partly presynaptic and demonstrates that TRP channels play a role in regulating synaptic transmission in the MPN. The results imply that such mechanisms may possibly contribute to the thermoregulation by MPN neurons.

medial preoptic nucleus

synaptic transmission

glutamate

GABA

glycine

TRPV1

Physiology

Fysiologi

Neural circuits engaged in mastication and orofacial nociception

Athanassiadis, Tuija,

January 2009

Diss. (sammanfattning) Umeå : Umeå universitet, 2009. / Härtill 3 uppsatser.

Inhibitory synpatic transmission in striatal neurons after transient cerebral ischemia

Li, Yan.

January 2009

Thesis (Ph.D.)--Indiana University, 2009. / Title from screen (viewed on December 1, 2009). Department of Anatomy and Cell Biology, Indiana University-Purdue University Indianapolis (IUPUI). Advisor(s): Zao C. Xu, Feng C. Zhou, Charles R. Yang, Theodore R. Cummins. Includes vitae. Includes bibliographical references (leaves 115-135).

Control of Neurotransmitter Release Properties by Presynaptic Calcium

Thanawala, Monica Shishir

06 June 2014

Presynaptic terminals of neurons are optimized for neurotransmitter release, which is tightly controlled by presynaptic calcium. Here, we evaluate the role of calcium influx through voltage-gated calcium channels (VGCCs) in regulating the initial vesicular release probability (p) and the number of vesicles available for release by action potentials (effective RRP) at the calyx of Held synapse in mice. Two established methods of estimating effective RRP size and p reveal that both are calcium dependent. Reducing calcium influx by blocking R-type (VGCCs) or P/Q-type VGCCs also reduces EPSC amplitude via p and effective RRP size. Furthermore, activation of gamma-aminobutryic acid class B (GABAB) receptors, which reduces presynaptic calcium by regulating VGCCs without other significant effects on release, also reduces the effective RRP size and p. These findings suggest that the calcium dependence of RRP size may influence the manner in which certain neuromodulators affect neurotransmitter release.

Neurosciences

Cellular biology

Biophysics

neurotransmitter release

presynaptic calcium

presynaptic properties

synaptic transmission