Spinal inhibitory mechanisms controlling somatosensation: maturation and neonatal injury

Brewer, Chelsie L.

02 June 2020

No description available.

Neurology

Pain

Spinal dorsal horn

Neonatal injury

Electrophysiology

Synaptic physiology

Postnatal development

Reserpine-Induced Reduction in Norepinephrine Transporter Function Requires Catecholamine Storage Vesicles

Mandela, Prashant, Chandley, Michelle, Xu, Yao Y., Zhu, Meng Yang, Ordway, Gregory A.

01 May 2010

Treatment of rats with reserpine, an inhibitor of the vesicular monoamine transporter (VMAT), depletes norepinephrine (NE) and regulates NE transporter (NET) expression. The present study examined the molecular mechanisms involved in regulation of the NET by reserpine using cultured cells. Exposure of rat PC12 cells to reserpine for a period as short as 5min decreased [ H]NE uptake capacity, an effect characterized by a robust decrease in the V of the transport of [ H]NE. As expected, reserpine did not displace the binding of [ H]nisoxetine from the NET in membrane homogenates. The potency of reserpine for reducing [ H]NE uptake was dramatically lower in SK-N-SH cells that have reduced storage capacity for catecholamines. Reserpine had no effect on [ H]NE uptake in HEK-293 cells transfected with the rat NET (293-hNET), cells that lack catecholamine storage vesicles. NET regulation by reserpine was independent of trafficking of the NET from the cell surface. Pre-exposure of cells to inhibitors of several intracellular signaling cascades known to regulate the NET, including Ca /Ca -calmodulin dependent kinase and protein kinases A, C and G, did not affect the ability of reserpine to reduce [ H]NE uptake. Treatment of PC12 cells with the catecholamine depleting agent, α-methyl-p-tyrosine, increased [ H]NE uptake and eliminated the inhibitory effects of reserpine on [ H]NE uptake. Reserpine non-competitively inhibits NET activity through a Ca -independent process that requires catecholamine storage vesicles, revealing a novel pharmacological method to modify NET function. Further characterization of the molecular nature of reserpine's action could lead to the development of alternative therapeutic strategies for treating disorders known to be benefitted by treatment with traditional competitive NET inhibitors.

antidepressant

noradrenergic

norepinephrine

norepinephrine transporter

reserpine

secretory vesicle

storage vesicle

synaptic vesicle

Biomedical Sciences

Evolutionary Remodeling In A Visual System Through Extensive Changes In The Synaptic Connectivity Of Homologous Neurons

Shaw, S. R., Moore, D.

01 January 1989

The cellular mechanisms by which nervous systems evolve to match evolutionary changes occurring in the rest of the body remain largely unexplored. In a distal visual neuropil of a previously unexamined ancient dipteran family, Stratiomyidae, homologues of all of the periodic neurons known already from more recent Diptera can be recognized, occupying the same locations within the unit structure. This points to extreme developmental stasis for more than 200 million years, conserving both cell identity and position. The arborizations that some neurons make also have remained conservative, but others show marked differences between families in both size and branching patterns. At the electron-microscopical level, extensive differences in synaptic connectivity are found, some sufficient to radically redefine the systems roles of particular neurons. The findings bear out an earlier prediction that changes in the connectivity matrix linking conserved neurons may have been a major factor in implementing evolutionary change in the nervous system.

dipteran

golgi electron microscopy

insect vision

neural remodeling

synapses

synaptic evolution

Biological Sciences

Inositol Derivatives Modulate Spontaneous Transmitter Release at the Frog Neuromuscular Junction

Brailoiu, Eugen, Miyamoto, Michael D., Dun, Nae J.

01 January 2003

One of the consequences of G-protein-coupled receptor activation is stimulation of phosphoinositol metabolism, leading to the generation of IP 3 and its metabolites 1,3,4,5-tetrakisphosphate (IP4) and inositol 1,2,3,4,5,6-hexakisphosphate (IP6). Previous reports indicate that high inositol polyphosphates (IP4 and IP6) are involved in clathrin-coated vesicular recycling. In this study, we examined the effects of IP4 and IP6 on spontaneous transmitter release in the form of miniature endplate potentials (MEPP) and on enhanced vesicular recycling by high K+ at frog motor nerve endings. In resting conditions, IP4 and IP6 delivered intracellularly via liposomes, caused concentration-dependent increases in MEPP frequency and amplitude. Pretreatment with the protein kinase A (PKA) inhibitor H-89 or KT 5720 reduced the IP4-mediated MEPP frequency increase by 60% and abolished the IP6-mediated MEPP frequency increases as well as the enhancement in MEPP amplitude. Pretreatment with antibodies against phosphatidylinositol 3-kinase (PI 3-K), enzyme also associated with clathrin-coated vesicular recycling, did not alter the IP4 and IP6-mediated MEPP frequency increases, but reduced the MEPP amplitude increase by 50%. In our previous reports, IP3, but not other second messengers releasing Ca2+ from internal Ca2+ stores, is able to enhance the MEPP amplitude. In order to dissociate the effect of Ca2+ release vs. metabolism to IP4 and IP 6, we evaluated the effects of 3-deoxy-3-fluoro-inositol 1,4,5-trisphosphate (3F-IP3), which is not converted to IP 4 or IP6. 3F-IP3 produced an increase then decrease in MEPP frequency and a decrease in MEPP amplitude. In elevated vesicle recycling induced by high K+-Ringer solution, IP4 and IP6 have similar effects, except decreasing MEPP frequency at a higher concentration (10-4 M). We conclude that (1) high inositol polyphosphates may represent a link between IP3 and cAMP pathways; (2) the IP3-induced increase of MEPP amplitude is likely to be due to its high inositol metabolites; (3) PI 3-K is not involved in the IP 4 and IP6-mediated MEPP frequency increases, but may be involved in MEPP size.

inositol phosphates

liposomal delivery

phosphatidylinositol 3-kinase

quantal transmitter release

synaptic vesicle

Calmodulin Increases Transmitter Release by Mobilizing Quanta at the Frog Motor Nerve Terminal

Brailoiu, Eugen, Miyamoto, Michael D., Dun, Nae J.

01 January 2002

1. The role of calmodulin (CaM) in transmitter release was investigated using liposomes to deliver CaM and monoclonal antibodies against CaM (antiCaM) directly into the frog motor nerve terminal. 2. Miniature endplate potentials (MEPPs) were recorded in a high K+ solution, and effects on transmitter release were monitored using estimates of the quantal release parameters m (number of quanta released), n (number of functional transmitter release sites), p (mean probability of release), and vars p (spatial variance in p). 3. Administration of CaM, but not heat-inactivated CaM, encapsulated in liposomes (1000 units ml-1) produced an increase in m (25%) that was due to an increase in n. MEPP amplitude was not altered by CaM. 4. Administration of antiCaM, but not heat-inactivated antiCaM, in liposomes (50 μl ml-1) produced a progressive decrease in m (40%) that was associated with decreases in n and p. MEPP amplitude was decreased (15%) after a 25 min lag time, suggesting a separation in time between the decreases in quantal release and quantal size. 5. Bath application of the membrane-permeable CaM antagonist W7 (28 μM) produced a gradual decrease in m (25%) that was associated with a decrease in n. W7 also produced a decrease in MEPP amplitude that paralleled the decrease in m. The decreases in MEPP size and m produced by W7 were both reversed by addition of CaM. 6. Our results suggest that CaM increases transmitter release by mobilizing synaptic vesicles at the frog motor nerve terminal.

calmodulin

electrophysiology

neuromuscular junction

neurotransmitter secretion

quantal transmitter release

synaptic vesicles

Regulation of Local Translation, Synaptic Plasticity, and Cognitive Function by CNOT7

McFleder, Rhonda L.

31 July 2017

Local translation of mRNAs in dendrites is vital for synaptic plasticity and learning and memory. Tight regulation of this translation is key to preventing neurological disorders resulting from aberrant local translation. Here we find that CNOT7, the major deadenylase in eukaryotic cells, takes on the distinct role of regulating local translation in the hippocampus. Depletion of CNOT7 from cultured neurons affects the poly(A) state, localization, and translation of dendritic mRNAs while having little effect on the global neuronal mRNA population. Following synaptic activity, CNOT7 is rapidly degraded resulting in polyadenylation and a change in the localization of its target mRNAs. We find that this degradation of CNOT7 is essential for synaptic plasticity to occur as keeping CNOT7 levels high prevents these changes. This regulation of dendritic mRNAs by CNOT7 is necessary for normal neuronal function in vivo, as depletion of CNOT7 also disrupts learning and memory in mice. We utilized deep sequencing to identify the neuronal mRNAs whose poly(A) state is governed by CNOT7. Interestingly these mRNAs can be separated into two distinct populations: ones that gain a poly(A) tail following CNOT7 depletion and ones that surprisingly lose their poly(A) tail following CNOT7 depletion. These two populations are also distinct based on the lengths of their 3’ UTRs and their codon usage, suggesting that these key features may dictate how CNOT7 acts on its target mRNAs. This work reveals a central role for CNOT7 in the hippocampus where it governs local translation and higher cognitive function.

CNOT7

deadenylation

polyadenylation

local translation

synaptic plasticity

Biochemistry

Molecular and Cellular Neuroscience

Astrocyte-Neuron Interactions Regulate Nervous System Assembly and Function: A Dissertation

Muthukumar, Allie

08 January 2015

Astrocytes densely infiltrate the brain and intimately associate with synaptic structures. In the past 20 years, they have emerged as critical regulators of both synapse assembly and synapse function. During development, astrocytes modulate the formation of new synapses, and later, control refinement of synaptic connections in response to activity dependent cues. In a mature nervous system, astrocytes modulate synapse function through a variety of mechanisms. These include ion buffering, neurotransmitter uptake and the release of molecules that activate synaptic receptors. Through such roles, astrocytes shape the structure and function of neuronal circuits. However, how astrocytes and synapses reciprocally communicate during circuit assembly remains an unanswered question in the field. The vast majority of our understanding of astrocyte biology has come from studies conducted in mammals, where it is challenging to dissect molecular mechanisms with cell type specificity. Drosophila melanogaster is a less established model system for studying astrocyteneuron interactions, but its vast array of genetic tools and rapid life cycle promises great potential for precisely targeted manipulations. My thesis work has utilized Drosophila melanogaster to investigate the reciprocal nature of astrocyte-synapse communication. First, I characterized Drosophila late metamorphosis as a developmental stage in which astrocyte-synapse associations can be studied. My work demonstrates that during this time, when the adult Drosophila nervous system is being assembled, synapse formation relies on the coordinated infiltration of astrocyte membranes into the neuropil. Next, I show that in a reciprocal manner, neural activity can shape astrocyte biology during this time as well and impart long lasting effects on neuronal circuit function. In particular expression of the astrocyte GABA transporter (GAT) is modulated in an activity-dependent manner via astrocytic GABABR1/2 receptor signaling. Inhibiting astrocytic GABABR1/2 signaling strongly suppresses hyperexcitability in a Drosophila seizure model, vii arguing this pathway is important for modulating excitatory/inhibitory balance in vivo. Finally, utilizing the ease of the Drosophila system, I performed a reverse genetic screen to identify additional astrocyte factors involved in modulating excitatory-inhibitory neuronal balance.

Astrocytes

Synapses

Synaptic Transmission

Drosophila melanogaster

Neurons

Dissertations, UMMS

Developmental Neuroscience

Molecular and Cellular Neuroscience

Neuroscience and Neurobiology

A Novel Communication Mechanism Between the Presynapse and Postsynapse Through Exosomes: A Dissertation

Korkut, Ceren

10 August 2012

The minimal element of the nervous system, the synapse, is a plastic structure that has the ability to change in response to various internal and external factors. This property of the synapse underlies complex behaviors such as learning and memory. However, the exact molecular and cellular mechanisms involved in this process are not fully understood. To understand the mechanisms that regulate synapse development and plasticity I took advantage of a powerful model system, the Drosophila larval neuromuscular junction (NMJ). In this system, both anterograde and retrograde signaling pathways critical for coordinated synapse development and plasticity have been documented. An anterograde WNT/Wingless (Wg) signaling pathway plays a crucial role in both developmental and activity-dependent synaptic plasticity at the NMJ. Presynaptic motor neuron terminals secrete highly hydrophobic Wg, which travels to relatively distant postsynaptic sites where it activates a signal transduction pathway required for postsynaptic development. In the first half of my thesis I unraveled a previously unrecognized cellular mechanism by which Wg is shuttled to postsynaptic sites. In this mechanism Wg rides on secreted microvesicles or exosomes that contain a dedicated WNT secretion factor, the WNT-binding transmembrane protein, Evenness Interrupted/Wntless/Sprinter (Evi/Wls/Srt). To our knowledge, this was the first in vivo study demonstrating that neurons release exosomes, which are involved in trans-synaptic communication. Moreover, this was the first study showing that hydrophobic WNT signals are transported to the extracellular space on exosomes to reach WNT-receptor containing target cells. Retrograde signals are also critical during development and plasticity of synaptic connections. These signals function to adjust the activity of presynaptic cells according to postsynaptic cell outputs, to maintain synaptic function within a dynamic range. However, the mechanisms that trigger the release of retrograde signals and the role of presynaptic cells in this signaling event are not clear. In the second half of my thesis, I provided evidence that a crucial component of retrograde signaling at the fly NMJ, Synaptotagmin-4 (Syt4), is transmitted to the postsynaptic cell through anterograde delivery of Syt4 via exosomes. Drosophila Syt4 is known to reside on postsynaptic vesicles at the NMJ and function as a calcium sensor to release a retrograde signal upon synaptic activity. This event is required for coordinated maturation of the presynaptic terminal. We demonstrated that retrograde Syt4 function in postsynaptic muscle is required for activity-dependent presynaptic growth. However, surprisingly, Syt4 protein was not synthesized in postsynaptic muscles. Instead, Syt4 was produced in motorneurons and transferred to postsynaptic muscle cells via exosome secretion by presynaptic cells. The above study provided evidence for a presynaptic control of postsynaptic retrograde signaling through exosomal transfer of an essential retrograde signaling component. In summary, this body of work reveals a novel mechanism of trans-synaptic communication through exosomes. While intercellular communication through exosomes had been demonstrated during antigen presentation in the immune system, our studies were the first to substantiate this mode of communication in the nervous system. Thus, these studies provide a significantly deeper and novel understanding of the mechanisms underlying synapse development and plasticity.

Synapses

Synaptic Transmission

Exosomes

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Nervous System

Neuroscience and Neurobiology

The molecular anatomy of synaptic vesicle recycling at the hair cell ribbon synapse

Richter, Katharina Natalia

15 August 2019

No description available.

570

Inner hair cells

Auditory system

Synaptic vesicle recycling

Ribbon synapse

Glyoxal fixation

CosiQuant

Biologie (PPN619462639)

BMS-708163 and Nilotinib restore synaptic dysfunction in human embryonic stem cell-derived Alzheimer’s disease models / BMS-708163とNilotinibはヒト胚性幹細胞由来アルツハイマー病モデル細胞におけるシナプス機能障害を改善させる

Nishioka, Hisae

23 January 2018

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第20811号 / 医科博第82号 / 新制||医科||6(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 長船 健二, 教授 妻木 範行, 教授 村井 俊哉 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Alzheimer's disease

Presenilin 1

Cellular disease model

Synaptic dysfunction

BMS-708163

Nilotinib

491