Your search keyword '"Electrical Synapses"' showing total 49 results

1. Neuronal Glutamatergic Network Electrically Wired with Silent But Activatable Gap Junctions.

Author

Ixmatlahua, Diana J., Vizcarra, Bianca, Gomez-Lira, Gisela, Romero-Maldonado, Isabel, Ortiz, Franco, Rojas-Piloni, Gerardo, and Gutierrez, Rafael

Subjects

*ELECTRIC circuits, *SYNAPSES

Abstract

It is widely assumed that electrical synapses in the mammalian brain, especially between interneurons, underlie neurona! synchrony. In the hippocampus, principal cells also establish electrical synapses with each other and have also been implicated in network oscillations, whereby the origin of fast electrical activity has been attributed to ectopic spikelets and dendro-dendritic or axo-axonal gap junctions. However, if electrical synapses were in axo-dendritic connections, where chemical synapses occur, the synaptic events would be mixed, having an electrical component preceding the chemical one. This type of communication is less well studied, mainly because it is not easily detected. Moreover, a possible scenario could be that an electrical synapse coexisted with a chemical one, but in a nonconductive state; hence, it would be considered inexistent. Could chemical synapses have a quiescent electrical component? If so, can silent electrical synapses be activated to be detected? We addressed this possibility, and we here report that, indeed, the connexin-36-containing glutamatergic mossy fiber synapses of the rat hippocampus express previously unrecognized electrical synapses, which are normally silent. We reveal that these synapses are pH sensitive, actuate in vitro and in vivo, and that the electrical signaling is bidirectional. With the simultaneous recording of hundreds of cells, we could reveal the existence of an electrical circuit in the hippocampus of adult rats of either sex consisting of principal cells where the nodes are interregional glutamatergic synapses containing silent but ready-to-use gap junctions. [ABSTRACT FROM AUTHOR]

Published

2020

2. Photoreceptive Ganglion Cells Drive Circuits for Local Inhibition in the Mouse Retina

Author

Kathy Zhang, Pouyan Rahmani, Nicholas J. Justice, Hannah Walsh, Jonathan B. Demb, and Joseph Pottackal

Subjects

Male, Retinal Ganglion Cells, 0301 basic medicine, Melanopsin, genetic structures, Interneuron, Corticotropin-Releasing Hormone, Optogenetics, Retina, Amacrine cell, Mice, 03 medical and health sciences, 0302 clinical medicine, Retinal Rod Photoreceptor Cells, medicine, Animals, gamma-Aminobutyric Acid, Research Articles, Neurons, Chemistry, General Neuroscience, Intrinsically photosensitive retinal ganglion cells, Rod Opsins, Excitatory Postsynaptic Potentials, Gap Junctions, Neural Inhibition, Electrophysiological Phenomena, Mice, Inbred C57BL, Amacrine Cells, 030104 developmental biology, medicine.anatomical_structure, Electrical Synapses, Retinal ganglion cell, Synapses, Retinal Cone Photoreceptor Cells, Female, sense organs, Neuroscience, 030217 neurology & neurosurgery, Photoreceptor Cells, Vertebrate

Abstract

Intrinsically photosensitive retinal ganglion cells (ipRGCs) exhibit melanopsin-dependent light responses that persist in the absence of rod and cone photoreceptor-mediated input. In addition to signaling anterogradely to the brain, ipRGCs signal retrogradely to intraretinal circuitry via gap junction-mediated electrical synapses with amacrine cells (ACs). However, the targets and functions of these intraretinal signals remain largely unknown. Here, in mice of both sexes, we identify circuitry that enables M5 ipRGCs to locally inhibit retinal neurons via electrical synapses with a nonspiking GABAergic AC. During pharmacological blockade of rod- and cone-mediated input, whole-cell recordings of corticotropin-releasing hormone-expressing (CRH+) ACs reveal persistent visual responses that require both melanopsin expression and gap junctions. In the developing retina, ipRGC-mediated input to CRH+ACs is weak or absent before eye opening, indicating a primary role for this input in the mature retina (i.e., in parallel with rod- and cone-mediated input). Among several ipRGC types, only M5 ipRGCs exhibit consistent anatomical and physiological coupling to CRH+ACs. Optogenetic stimulation of local CRH+ACs directly drives IPSCs in M4 and M5, but not M1-M3, ipRGCs. CRH+ACs also inhibit M2 ipRGC-coupled spiking ACs, demonstrating direct interaction between discrete networks of ipRGC-coupled interneurons. Together, these results demonstrate a functional role for electrical synapses in translating ipRGC activity into feedforward and feedback inhibition of local retinal circuits.SIGNIFICANCE STATEMENTMelanopsin directly generates light responses in intrinsically photosensitive retinal ganglion cells (ipRGCs). Through gap junction-mediated electrical synapses with retinal interneurons, these uniquely photoreceptive RGCs may also influence the activity and output of neuronal circuits within the retina. Here, we identified and studied an electrical synaptic circuit that, in principle, could couple ipRGC activity to the chemical output of an identified retinal interneuron. Specifically, we found that M5 ipRGCs form electrical synapses with corticotropin-releasing hormone-expressing amacrine cells, which locally release GABA to inhibit specific RGC types. Thus, ipRGCs are poised to influence the output of diverse retinal circuits via electrical synapses with interneurons.

Published

2021

3. Electrical Coupling of Heterotypic Ganglion Cells in the Mammalian Retina

Author

Christian Puller, Elaheh Lotfi, Sabrina Duda, Martin Greschner, Malte T. Ahlers, Christoph Block, and Yousef Arzhangnia

Subjects

Male, Retinal Ganglion Cells, 0301 basic medicine, Cell type, Guinea Pigs, Synaptic Transmission, Retinal ganglion, 03 medical and health sciences, Electrical Synapses, 0302 clinical medicine, medicine, Animals, Research Articles, Retina, Chemistry, General Neuroscience, Gap junction, Ganglion, Cell biology, Coupling (electronics), 030104 developmental biology, medicine.anatomical_structure, Receptive field, Female, sense organs, 030217 neurology & neurosurgery

Abstract

Electrical coupling has been reported to occur only between homotypic retinal ganglion cells, in line with the concept of parallel processing in the early visual system. Here, however, we show reciprocal correlated firing between heterotypic ganglion cells in multielectrode array recordings during light stimulation in retinas of adult guinea pigs of either sex. Heterotypic coupling was further confirmed via tracer spread after intracellular injections of single cells with neurobiotin. Both electrically coupled cell types were sustained ON center ganglion cells but showed distinct light response properties and receptive field sizes. We identified one of the involved cell types as sustained ON α-ganglion cells. The presence of electrical coupling between heterotypic ganglion cells introduces a network motif in which the signals of distinct ganglion cell types are partially mixed at the output stage of the retina.SIGNIFICANCE STATEMENTThe visual information is split into parallel pathways, before it is sent to the brain via the output neurons of the retina, the ganglion cells. Ganglion cells can form electrical synapses between dendrites of neighboring cells in support of lateral information exchange. To date, ganglion-to-ganglion cell coupling is thought to occur only between cells of the same type. Here, however, we show that electrical coupling between different types of ganglion cells exists in the mammalian retina. We provide functional and anatomical evidence that two different types of ganglion cells share information via electrical coupling. This new network motif extends the impact of the heavily studied coding benefits of homotypic coupling to heterotypic coupling across parallel neuronal pathways.

Published

2020

4. Retinal Waves Modulate an Intraretinal Circuit of Intrinsically Photosensitive Retinal Ganglion Cells.

Author

Arroyo, David A., Kirkby, Lowry A., and Feller, Marla B.

Subjects

*NEURAL circuitry, *RETINAL ganglion cells, *GAP junctions (Cell biology), *ELECTROPHYSIOLOGY, *OPTICAL sensors, *PHYSIOLOGICAL effects of dopamine

Abstract

Before the maturation of rod and cone photoreceptors, the developing retina relies on light detection by intrinsically photosensitive retinal ganglion cells (ipRGCs) to drive early light-dependent behaviors. ipRGCs are output neurons of the retina; however, they also form functional microcircuits within the retina itself. Whether ipRGC microcircuits exist during development and whether they influence early light detection remain unknown. Here, we investigate the neural circuit that underlies the ipRGC-driven light response in developing mice.Weuse a combination of calcium imaging, tracer coupling, and electrophysiology experiments to show that ipRGCs form extensive gap junction networks that strongly contribute to the overall light response of the developing retina. Interestingly, we found that gap junction coupling was modulated by spontaneous retinal waves, such that acute blockade of waves dramatically increased the extent of coupling and hence increased the number of light-responsive neurons. Moreover, using an optical sensor, we found that this wave-dependent modulation of coupling is driven by dopamine that is phasically released by retinal waves. Our results demonstrate that ipRGCs form gap junction microcircuits during development that are modulated by retinal waves; these circuits determine the extent of the light response and thus potentially impact the processing of early visual information and light-dependent developmental functions. [ABSTRACT FROM AUTHOR]

Published

2016

5. Activation of Group I and Group II Metabotropic Glutamate Receptors Causes LTD and LTP of Electrical Synapses in the Rat Thalamic Reticular Nucleus.

Author

Zemin Wang, Neely, Ryan, and Landisman, Carole E.

Subjects

*GLUTAMATE receptors, *LONG-term synaptic depression, *LONG-term potentiation, *THALAMIC nuclei, *SYNAPSES

Abstract

Compared with the extensive characterization of chemical synaptic plasticity, electrical synaptic plasticity remains poorly understood. Electrical synapses are strong and prevalent among the GABAergic neurons of the rodent thalamic reticular nucleus. Using paired whole-cell recordings, we show that activation of Group I metabotropic glutamate receptors (mGluRs) induces long-term depression of electrical synapses. Conversely, activation of the Group II mGluR, mGluR3, induces long-term potentiation of electrical synapses. By testing downstream targets, we show that modifications induced by both mGluR groups converge on the same signaling cascade-- adenylyl cyclase to cAMP to protein kinase A-- but with opposing effects. Furthermore, the magnitude of modification is inversely correlated to baseline coupling strength. Thus, electrical synapses, like their chemical counterparts, undergo both strengthening and weakening forms of plasticity, which should play a significant role in thalamocortical function. [ABSTRACT FROM AUTHOR]

Published

2015

6. Intrinsic Sources and Functional Impacts of Asymmetry at Electrical Synapses

Author

Austin J. Mendoza and Julie S. Haas

Subjects

Neurons, Electrical Synapses, General Neuroscience, Synapses, Gap Junctions, General Medicine

Abstract

Electrical synapses couple inhibitory neurons across the brain, underlying a variety of functions that are modifiable by activity. Despite recent advances, many functions and contributions of electrical synapses within neural circuitry remain underappreciated. Among these are the sources and impacts of electrical synapse asymmetry. Using multi-compartmental models of neurons coupled through dendritic electrical synapses, we investigated intrinsic factors that contribute to effective synaptic asymmetry and that result in modulation of spike timing and synchrony between coupled cells. We show that electrical synapse location along a dendrite, input resistance, internal dendritic resistance, or directional conduction of the electrical synapse itself each alter asymmetry as measured by coupling between cell somas. Conversely, we note that asymmetrical gap junction (GJ) conductance can be masked by each of these properties. Furthermore, we show that asymmetry modulates spike timing and latency of coupled cells by up to tens of milliseconds, depending on direction of conduction or dendritic location of the electrical synapse. Coordination of rhythmic activity between two cells also depends on asymmetry. These simulations illustrate that causes of asymmetry are diverse, may not be apparent in somatic measurements of electrical coupling, influence dendritic processing, and produce a variety of outcomes on spiking and synchrony of coupled cells. Our findings highlight aspects of electrical synapses that should always be included in experimental demonstrations of coupling, and when assembling simulated networks containing electrical synapses.

Published

2022

7. Two Functionally Distinct Networks of Gap Junction-Coupled Inhibitory Neurons in the Thalamic Reticular Nucleus.

Author

Seung-Chan Lee, Patrick, Saundra L., Richardson, Kristen A., and Connors, Barry W.

Subjects

*GAP junctions (Cell biology), *CONNEXINS, *CELL junctions, *CELL nuclei, *NEUROSCIENCES, *NEURONS

Abstract

Gap junctions (GJs) electrically couple GABAergic neurons of the forebrain. The spatial organization of neuron clusters coupled by GJs is an important determinant of network function, yet it is poorly described for nearly all mammalian brain regions. Here we used a novel dye-coupling technique to show that GABAergic neurons in the thalamic reticular nucleus (TRN) of mice and rats form two types of GJ-coupled clusters with distinctive patterns and axonal projections. Most clusters are elongated narrowly along functional modules within the plane of the TRN, with axons that selectively inhibit local groups of relay neurons. However, some coupled clusters have neurons arrayed across the thickness of the TRN and target their axons to both first- and higher-order relay nuclei. Dye coupling was reduced, but not abolished, among cells of connexin 36 knock-out mice. Our results suggest that GJs form two distinct types of inhibitory networks that correlate activity either within or across functional modules of the thalamus. [ABSTRACT FROM AUTHOR]

Published

2014

8. Neuronal Somata and Extrasomal Compartments Play Distinct Roles during Synapse Formation between Lymnaea Neurons.

Author

Fenglian Xu, Luk, Collin C., Wiersma-Meems, Ryanne, Baehre, Kelly, Herman, Cameron, Zaidi, Wali, Noelle Wong, and Syed, Naweed I.

Subjects

*SYNAPSES, *NERVOUS system, *CHOLINERGIC receptors, *CELLULAR signal transduction, *CALCIUM-dependent protein kinase

Abstract

Proper synapse formation is pivotal for all nervous system functions. However, the precise mechanisms remain elusive. Moreover, compared with the neuromuscular junction, steps regulating the synaptogenic program at central cholinergic synapses remain poorly defined. In this study, we identified different roles of neuronal compartments (somal vs extrasomal) in chemical and electrical synaptogenesis. Specifically, the electrically synapsed Lymnaea pedal dorsal A cluster neurons were used to study electrical synapses, whereas chemical synaptic partners, visceral dorsal 4 (presynaptic, cholinergic), and left pedal dorsal 1 (LPeD1; postsynaptic) were explored for chemical synapse formation. Neurons were cultured in a soma-soma or soma-axon configuration and synapses explored electrophysiological. We provide the first direct evidence that electrical synapses develop in a soma-soma, but not soma-axon (removal of soma) configuration, indicating the requirement of gene transcription regulation in the somata of both synaptic partners. In addition, the soma-soma electrical coupling was contingent upon trophic factors present in Lymnaea brain-conditioned medium. Further, we demonstrate that chemical (cholinergic) synapses between soma-soma and soma-axon pairs were indistinguishable, with both exhibiting a high degree of contact site and target cell type specificity. We also provide direct evidence that presynaptic cell contact-mediated, clustering of postsynaptic cholinergic receptors at the synaptic site requires transmitter-receptor interaction, receptor internalization, and a protein kinase C-dependent lateral migration toward the contact site. This study provides novel insights into synaptogenesis between central neurons revealing both distinct and synergistic roles of cell- cell signaling and extrinsic trophic factors in executing the synaptogenic program. [ABSTRACT FROM AUTHOR]

Published

2014

9. Protein Kinase C Enhances Electrical Synaptic Transmission by Acting on Junctional and Postsynaptic Ca2+Currents

Author

Neil S. Magoski, Christopher C. Beekharry, and Yueling Gu

Subjects

0301 basic medicine, Chemistry, General Neuroscience, Voltage clamp, Depolarization, Inhibitory postsynaptic potential, Electrotonic potential, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Electrical Synapses, medicine.anatomical_structure, Postsynaptic potential, Current clamp, medicine, Biophysics, Electrical synapse, 030217 neurology & neurosurgery

Abstract

By synchronizing neuronal activity, electrical transmission influences the coordination, pattern, and/or frequency of firing. In the hemaphroditic marine-snail,Aplysia calfornica, the neuroendocrine bag cell neurons use electrical synapses to synchronize a 30 min afterdischarge of action potentials for the release of reproductive hormone. During the afterdischarge, protein kinase C (PKC) is activated, although its impact on bag cell neuron electrical transmission is unknown. This was investigated here by monitoring electrical synapses between paired cultured bag cell neurons using dual whole-cell recording. Voltage clamp revealed a largely voltage-independent junctional current, which was enhanced by treating with a PKC activator, PMA, before recording. We also examined the transfer of presynaptic action potential-like waveforms (generated in voltage clamp) to the postsynaptic cell (measured in current clamp). For control pairs, the presynaptic spike-like waveforms mainly evoked electrotonic potentials; however, when PKC was triggered, these stimuli consistently produced postsynaptic action potentials. To assess whether this involved changes to postsynaptic responsiveness, single bag cell neurons were injected with junctional-like current mimicking that evoked by a presynaptic action potential. Unlike control neurons, which were less likely to spike, cells in PMA always fired action potentials to the junctional-like current. Furthermore, PKC activation increased a postsynaptic voltage-gated Ca2+current, which was recruited even by modest depolarization associated with an electrotonic potential. Whereas PKC inhibits gap junctions in most systems, bag cell neurons are rather unique, as the kinase potentiates the electrical synapse; in turn, this synergizes with augmented postsynaptic Ca2+current to promote synchronous firing.SIGNIFICANCE STATEMENTElectrical coupling is a fundamental form of communication. For the bag cell neurons ofAplysia, electrical synapses coordinate a prolonged burst of action potentials known as the afterdischarge. We looked at how protein kinase C, which is upregulated with the afterdischarge, influences information transfer across the synapse. The kinase activation increased junctional current, a remarkable finding given that this enzyme is largely considered inhibitory for gap junctions. There was also an augmentation in the ability of a presynaptic neuron to provoke postsynaptic action potentials. This increased excitability was, in part, due to enhanced postsynaptic voltage-dependent Ca2+current. Thus, protein kinase C improves the fidelity of electrotonic transmission and promotes synchronous firing by modulating both junctional and membrane conductances.

Published

2018

10. Cellular Dynamics of Cholinergically Induced α(8 - 13 Hz) Rhythms in Sensory Thalamic Nuclei In Vitro.

Author

Lörincz, Magor L., Crunelli, Vincenzo, and Hughes, Stuart W.

Subjects

*ALPHA rhythm, *ELECTROENCEPHALOGRAPHY, *ACETYLCHOLINE, *CELLS, *THALAMUS, *GAP junctions (Cell biology), *THALAMIC nuclei

Abstract

Although EEG α (8-13 Hz) rhythms are traditionally thought to reflect an "idling" brain state, they are also linked to several important aspects of cognition, perception, and memory. Here we show that reactivating cholinergic input, a key component in normal cognition and memory operations, in slices of the cat primary visual and somatosensory thalamus, produces robust α rhythms. These rhythms rely on activation of muscarinic receptors and are primarily coordinated by activity in the recently discovered, gap junction-coupled subnetwork of high-threshold (HT) bursting thalamocortical neurons. By performing extracellular field recordings in combination with intracellular recordings of these cells, we show that (1) the coupling of HT bursting cells is sparse, with individual neurons typically receiving discernable network input from one or very few additional cells, (2) the phase of oscillatory activity at which these cells prefer to fire is readily modifiable and determined by a combination of network input, intrinsic properties andmembranepolarization, and (3) single HT bursting neurons can potently influence the local network state. These results substantially extend the known effects of cholinergic activation on the thalamus and, in combination with previous studies, show that sensory thalamic nuclei possess powerful and dynamically reconfigurable mechanisms for generating synchronized α activity that can be engaged by both descending and ascending arousal systems. [ABSTRACT FROM AUTHOR]

Published

2008

11. Synchronous Infra-Slow Bursting in the Mouse Accessory Olfactory Bulb Emerge from Interplay between Intrinsic Neuronal Dynamics and Network Connectivity

Author

Shlomo Wagner, Yosef Yarom, and Asaph Zylbertal

Subjects

Male, 0301 basic medicine, Action Potentials, Biology, Network topology, Mice, 03 medical and health sciences, Bursting, 0302 clinical medicine, Calcium imaging, Biological Clocks, Neural Pathways, Connectome, Animals, Premovement neuronal activity, Cortical Synchronization, Research Articles, Neurons, Mechanism (biology), General Neuroscience, Dynamics (mechanics), Network connectivity, Olfactory Bulb, Mice, Inbred C57BL, 030104 developmental biology, Electrical Synapses, Nerve Net, Neuroscience, 030217 neurology & neurosurgery

Abstract

Rhythmic neuronal activity of multiple frequency bands has been described in many brain areas and attributed to numerous brain functions. Among these, little is known about the mechanism and role of infra-slow oscillations, which have been demonstrated recently in the mouse accessory olfactory bulb (AOB). Along with prolonged responses to stimuli and distinct network connectivity, they inexplicably affect the AOB processing of social relevant stimuli. Here, we show that assemblies of AOB mitral cells are synchronized by lateral interactions through chemical and electrical synapses. Using a network model, we demonstrate that the synchronous oscillations in these assemblies emerge from interplay between intrinsic membrane properties and network connectivity. As a consequence, the AOB network topology, in which each mitral cell receives input from multiple glomeruli, enables integration of chemosensory stimuli over extended time scales by interglomerular synchrony of infra-slow bursting. These results provide a possible functional significance for the distinct AOB physiology and topology. Beyond the AOB, this study presents a general model for synchronous infra-slow bursting in neuronal networks.SIGNIFICANCE STATEMENTInfra-slow rhythmic neuronal activity with a very long (>10 s) duration has been described in many brain areas, but little is known about the role of this activity and the mechanisms that produce it. Here, we combine experimental and computational methods to show that synchronous infra-slow bursting activity in mitral cells of the mouse accessory olfactory bulb (AOB) emerges from interplay between intracellular dynamics and network connectivity. In this novel mechanism, slow intracellular Na+dynamics endow AOB mitral cells with a weak tendency to burst, which is further enhanced and stabilized by chemical and electrical synapses between them. Combined with the unique topology of the AOB network, infra-slow bursting enables integration and binding of multiple chemosensory stimuli over a prolonged time scale.

Published

2017

12. Gap Junction–Mediated Signaling from Motor Neurons Regulates Motor Generation in the Central Circuits of LarvalDrosophila

Author

Hiroshi Kohsaka, Akinao Nose, and Teruyuki Matsunaga

Subjects

Central Nervous System, 0301 basic medicine, Neural Inhibition, Nerve Tissue Proteins, Sensory system, In Vitro Techniques, Optogenetics, Biology, Connexins, Animals, Genetically Modified, 03 medical and health sciences, Calcium imaging, Animals, Drosophila Proteins, Research Articles, Motor Neurons, General Neuroscience, Gap junction, Gap Junctions, Membrane Proteins, Motor control, Luminescent Proteins, Electrophysiology, 030104 developmental biology, Electrical Synapses, Larva, Carbenoxolone, Calcium, Drosophila, RNA Interference, Halorhodopsins, Neuroscience, Locomotion

Abstract

In this study, we used the peristaltic crawling ofDrosophilalarvae as a model to study how motor patterns are regulated by central circuits. We built an experimental system that allows simultaneous application of optogenetics and calcium imaging to the isolated ventral nerve cord (VNC). We then investigated the effects of manipulating local activity of motor neurons (MNs) on fictive locomotion observed as waves of MN activity propagating along neuromeres. Optical inhibition of MNs with halorhodopsin3 in a middle segment (A4, A5, or A6), but not other segments, dramatically decreased the frequency of the motor waves. Conversely, local activation of MNs with channelrhodopsin2 in a posterior segment (A6 or A7) increased the frequency of the motor waves. Since peripheral nerves mediating sensory feedback were severed in the VNC preparation, these results indicate that MNs send signals to the central circuits to regulate motor pattern generation. Our results also indicate segmental specificity in the roles of MNs in motor control. The effects of the local MN activity manipulation were lost inshaking-B2(shakB2) orogre2, gap-junction mutations inDrosophila, or upon acute application of the gap junction blocker carbenoxolone, implicating electrical synapses in the signaling from MNs. Cell-type-specific RNAi suggestedshakBandogrefunction in MNs and interneurons, respectively, during the signaling. Our results not only reveal an unexpected role for MNs in motor pattern regulation, but also introduce a powerful experimental system that enables examination of the input–output relationship among the component neurons in this system.SIGNIFICANCE STATEMENTMotor neurons are generally considered passive players in motor pattern generation, simply relaying information from upstream interneuronal circuits to the target muscles. This study shows instead that MNs play active roles in the control of motor generation by conveying information via gap junctions to the central pattern-generating circuits in larvalDrosophila, providing novel insights into motor circuit control. The experimental system introduced in this study also presents a new approach for studying intersegmentally coordinated locomotion. Unlike traditional electrophysiology methods, this system enables the simultaneous recording and manipulation of populations of neurons that are genetically specified and span multiple segments.

Published

2017

13. Neurogliaform Neurons Form a Novel Inhibitory Network in the Hippocampal CA1 Area.

Author

Price, Christopher J., Cauli, Bruno, Kovacs, Endre R., Kulik, Akos, Lambolez, Bertrand, Shigemoto, Ryuichi, and Capogna, Marco

Subjects

*NEURONS, *NERVOUS system, *CELLS, *NEURAL transmission, *GABA, *NERVES, *NEURAL circuitry, *SYNAPSES, *MESSENGER RNA, *PARTICLES (Nuclear physics)

Abstract

We studied neurogliaform neurons in the stratum lacunosum moleculare of the CA1 hippocampal area. These interneurons have short stellate dendrites and an extensive axonal arbor mainly located in the stratum lacunosum moleculare. Single-cell reverse transcription-PCR showed that these neurons were GABAergic and that the majority expressed mRNA for neuropeptide Y. Most neurogliaform neurons tested were immunoreactive for α-actinin-2, and many stratum lacunosum moleculare interneurons coexpressed α-actinin-2 and neuropeptide Y. Neurogliaform neurons received monosynaptic, DNQX-sensitive excitatory input from the perforant path, and 40 Hz stimulation of this input evoked EPSCs displaying either depression or initial facilitation, followed by depression. Paired recordings performed between neurogliaform neurons showed that 85% of pairs were electrically connected and 70% were also connected via GABAergic synapses. Injection of sine waveforms into neurons during paired recordings resulted in transmission of the waveforms through the electrical synapse. Unitary IPSCs recorded from neurogliaform pairs readily fatigued, had a slow decay, and had a strong depression of the synaptic response at a 5 Hz stimulation frequency that was antagonized by the GABAB antagonist (2S)-3-[[ (1S)-1-(3,4- dichlorophenyl)ethyl]amino-2-hydroxypropyl](phenylmethyl) phosphinic acid (CGP55845). The amplitude of the first IPSC during the 5 Hz stimulation was also increased by CGP55845, suggesting a tonic inhibition of synaptic transmission. A small unitary GABAB-mediated IPSC could also be detected, providing the first evidence for such a component between GABAergic interneurons. Electron microscopic localization of the GABAB1 subunit at neurogliaform synapses revealed the protein in both presynaptic and postsynaptic membranes. Our data disclose a novel interneuronal network well suited for modulating the flow of information between the entorhinal cortex and CA1 hippocampus. [ABSTRACT FROM AUTHOR]

Published

2005

14. Dendrodendritic Electrical Synapses between Mammalian Retinal Ganglion Cells.

Author

Hidaka, Soh, Akahori, Yasushi, and Kurosawa, Yoshikazu

Subjects

*IMMUNOCYTOCHEMISTRY, *ELECTRON microscopy, *CONNEXINS, *SYNCHRONIZATION, *DENDRITES

Abstract

Electrical synapses between α-type ganglion cells were detected using combined techniques of dual patch-clamp recordings, intracellular labeling, electron microscopy, and channel subunit connexin immunocytochemistry in the albino rat retina. After intracellular injection of Neurobiotin into α-cells of inner (ON-center) and outer (OFF-center) ramifying types, measurement of tracer coupling resulted in a preferentially homologous occurrence among cells of the same morphological type (n = 19 of 24). In high-voltage as well as conventional electron microscopic analysis, direct dendrodendritic gap junctions (average size, 0.86 µm long) were present in contact sites between tracer-coupled α-cells. In simultaneous dual whole-cell recordings from pairs of neighboring α-cells, these cells generated TTX-sensitive sustained spiking against extrinsic current injection, and bidirectional electrical synapses (maximum coupling coefficient, 0.32) with symmetrical junction conductance (average, 1.35 nS) were observed in pairs with cells of the same morphological type. Precise temporal synchronization of spike activity (average time delay, 2.7 msec) was detected when depolarizing currents were simultaneously injected into the pairs. To address whether physiologically identified electrical synapses constitute gap junctional connectivity between cell pairs, identified neuronal connexin36 immunoreactivity was undertaken in Lucifer yellow-labeled cell pairs after patch-clamp recordings. All α-cells expressed connexin36, and confocal laser-scanning imaging demonstrated that connexin36 is primarily located at dendritic crossings between electrically coupled cells (seven sites in a pair, on average). These results give conclusive evidence for electrical synapses via dendrodendritic gap junctions involving connexin36 in a retinal ganglion cells of the same physiological type. [ABSTRACT FROM AUTHOR]

Published

2004

15. Electrical Coupling among Irregular-Spiking GABAergic Interneurons Expressing Cannabinoid Receptors.

Author

Galarreta, Mario, Erdélyi, Ferenc, Szabó, Gábor, and Hestrin, Shaul

Subjects

*G proteins, *CANNABINOIDS, *GABA, *INTERNEURONS, *COGNITION

Abstract

Anatomical studies have shown that the G-protein-coupled cannabinoid receptor-1 (CB1) is selectively expressed in a subset of GABAergic interneurons. It has been proposed that these cells regulate rhythmic activity and play a key role mediating the cognitive actions of marijuana and endogenous cannabinoids. However, the physiology, anatomy, and synaptic connectivity of neocortical CB1-expressing interneurons remain poorly studied. We identified a population of CB1-expressing interneurons in layer II/III in mouse neocortical slices. These cells were multipolar or bitufied, had a widely extending axon, and exhibited a characteristic pattern of irregular spiking (IS) in response to current injection. CB1-expressing-IS (CB1-IS) cells were inhibitory, establishing GABAA receptor-mediated synapses onto pyramidal cells and other CB1-IS cells. Recently, electrical coupling among other classes of cortical interneurons has been shown to contribute to the generation of rhythmic synchronous activity in the neocortex. We therefore tested whether CB1-IS interneurons are interconnected via electrical synapses using paired recordings. We found that 90% (19 of 21 pairs) of simultaneously recorded pairs of CB1-IS cells were electrically coupled. The average coupling coefficient was ∼6%. Signaling through electrical synapses promoted coordinated firing among CB1-IS cells. Together, our results identify a population of electrically coupled CB1-IS GABAergic interneurons in the neocortex that share a unique morphology and a characteristic pattern of irregular spiking in response to current injection. The synaptic interactions of these cells may play an important role mediating the cognitive actions of cannabinoids and regulating coherent neocortical activity. [ABSTRACT FROM AUTHOR]

Published

2004

16. Retinal Waves Modulate an Intraretinal Circuit of Intrinsically Photosensitive Retinal Ganglion Cells

Author

Marla B. Feller, Lowry A. Kirkby, and David A. Arroyo

Subjects

Retinal Ganglion Cells, 0301 basic medicine, Light, Dopamine, Inbred C57BL, Eye, Medical and Health Sciences, Transgenic, Mice, chemistry.chemical_compound, 0302 clinical medicine, nicotinic acetylcholine receptor, retinal waves, Evoked Potentials, gamma-Aminobutyric Acid, ipRGCs, Neurotransmitter Agents, Transcription Factor Brn-3A, biology, General Commentary, electrical synapses, General Neuroscience, Gap junction, Gap Junctions, Articles, medicine.anatomical_structure, Rhodopsin, Neurological, CNiFER, amacrine, Tyrosine 3-Monooxygenase, 1.1 Normal biological development and functioning, developing retina, Biotin, Mice, Transgenic, In Vitro Techniques, Retina, gap junction, 03 medical and health sciences, Calcium imaging, Underpinning research, medicine, Animals, Humans, Eye Disease and Disorders of Vision, Neurology & Neurosurgery, Psychology and Cognitive Sciences, Intrinsically photosensitive retinal ganglion cells, Infant, Newborn, Rod Opsins, Neurosciences, Infant, Retinal, Dihydro-beta-Erythroidine, Newborn, Retinal waves, Mice, Inbred C57BL, Coupling (electronics), 030104 developmental biology, Animals, Newborn, chemistry, biology.protein, sense organs, Nerve Net, Neuroscience, Photic Stimulation, 030217 neurology & neurosurgery

Abstract

UnlabelledBefore the maturation of rod and cone photoreceptors, the developing retina relies on light detection by intrinsically photosensitive retinal ganglion cells (ipRGCs) to drive early light-dependent behaviors. ipRGCs are output neurons of the retina; however, they also form functional microcircuits within the retina itself. Whether ipRGC microcircuits exist during development and whether they influence early light detection remain unknown. Here, we investigate the neural circuit that underlies the ipRGC-driven light response in developing mice. We use a combination of calcium imaging, tracer coupling, and electrophysiology experiments to show that ipRGCs form extensive gap junction networks that strongly contribute to the overall light response of the developing retina. Interestingly, we found that gap junction coupling was modulated by spontaneous retinal waves, such that acute blockade of waves dramatically increased the extent of coupling and hence increased the number of light-responsive neurons. Moreover, using an optical sensor, we found that this wave-dependent modulation of coupling is driven by dopamine that is phasically released by retinal waves. Our results demonstrate that ipRGCs form gap junction microcircuits during development that are modulated by retinal waves; these circuits determine the extent of the light response and thus potentially impact the processing of early visual information and light-dependent developmental functions.Significance statementLight-dependent functions in early development are mediated by intrinsically photosensitive retinal ganglion cells (ipRGCs). Here we show that ipRGCs form an extensive gap junction network with other retinal neurons, including other ipRGCs, which shapes the retina's overall light response. Blocking cholinergic retinal waves, which are the primary source of neural activity before maturation of photoreceptors, increased the extent of ipRGC gap junction networks, thus increasing the number of light-responsive cells. We determined that this modulation of ipRGC gap junction networks occurs via dopamine released by waves. These results demonstrate that retinal waves mediate dopaminergic modulation of gap junction networks to regulate pre-vision light responses.

Published

2016

17. Synaptic Organization of the Neuronal Circuits of the Claustrum

Author

Juhyun Kim, Solange P. Brown, Richard H. Roth, and Chanel J. Matney

Subjects

Male, 0301 basic medicine, Mice, Transgenic, Sensory system, Optogenetics, Inhibitory postsynaptic potential, Basal Ganglia, Mice, 03 medical and health sciences, Organ Culture Techniques, 0302 clinical medicine, Basal ganglia, Animals, Neurons, biology, General Neuroscience, Articles, Claustrum, Mice, Inbred C57BL, 030104 developmental biology, Electrical Synapses, nervous system, Synapses, biology.protein, Excitatory postsynaptic potential, Female, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin

Abstract

The claustrum, a poorly understood subcortical structure located between the cortex and the striatum, forms widespread connections with almost all cortical areas, but the cellular organization of claustral circuits remains largely unknown. Based primarily on anatomical data, it has been proposed that the claustrum integrates activity across sensory modalities. However, the extent to which the synaptic organization of claustral circuits supports this integration is unclear. Here, we used paired whole-cell recordings and optogenetic approaches in mouse brain slices to determine the cellular organization of the claustrum. We found that unitary synaptic connections among claustrocortical (ClaC) neurons were rare. In contrast, parvalbumin-positive (PV) inhibitory interneurons were highly interconnected with both chemical and electrical synapses. In addition, ClaC neurons and PV interneurons formed frequent synaptic connections. As suggested by anatomical data, we found that corticoclaustral afferents formed monosynaptic connections onto both ClaC neurons and PV interneurons. However, the responses to cortical input were comparatively stronger in PV interneurons. Consistent with this overall circuit organization, activation of corticoclaustral afferents generated monosynaptic excitatory responses as well as disynaptic inhibitory responses in ClaC neurons. These data indicate that recurrent excitatory circuits within the claustrum alone are unlikely to integrate across multiple sensory modalities. Rather, this cellular organization is typical of circuits sensitive to correlated inputs. Although single ClaC neurons may integrate corticoclaustral input from different cortical regions, these results are consistent with more recent proposals implicating the claustrum in detecting sensory novelty or in amplifying correlated cortical inputs to coordinate the activity of functionally related cortical regions.SIGNIFICANCE STATEMENTThe function of the claustrum, a brain nucleus found in mammals, remains poorly understood. It has been proposed, based primarily on anatomical data, that claustral circuits play an integrative role and contribute to multimodal sensory integration. Here we show that the principal neurons of the claustrum, claustrocortical (ClaC) projection neurons, rarely form synaptic connections with one another and are unlikely to contribute to broad integration within the claustrum. We show that, although single ClaC neurons may integrate corticoclaustral inputs carrying information for different sensory modalities, the synaptic organization of ClaC neurons, local parvalbumin-positive interneurons within the claustrum, and cortical afferents is also consistent with recent proposals that the claustrum plays a role in detecting salient stimuli or amplifying correlated cortical inputs.

Published

2016

18. Direct Evidence for Daily Plasticity of Electrical Coupling between Rod Photoreceptors in the Mammalian Retina

Author

Christophe P. Ribelayga and Nan Ge Jin

Subjects

Male, 0301 basic medicine, genetic structures, Circadian clock, Action Potentials, Adaptation (eye), Biology, Synaptic Transmission, Mice, 03 medical and health sciences, 0302 clinical medicine, Retinal Rod Photoreceptor Cells, Night vision, Animals, Cells, Cultured, Neuronal Plasticity, General Neuroscience, Gap junction, Gap Junctions, Articles, Anatomy, Circadian Rhythm, Coupling (electronics), Light intensity, 030104 developmental biology, Electrical Synapses, Biophysics, Female, sense organs, Nerve Net, 030217 neurology & neurosurgery

Abstract

Rod photoreceptors are electrically coupled through gap junctions. Coupling is a key determinant of their light response properties, but whether rod electrical coupling is dynamically regulated remains elusive and controversial. Here, we have obtained direct measurements of the conductance between adjacent rods in mouse retina and present evidence that rod electrical coupling strength is dependent on the time of day, the lighting conditions, and the mouse strain. Specifically, we show in CBA/Ca mice that under circadian conditions, the rod junctional conductance has a median value of 98 pS during the subjective day and of 493 pS during the subjective night. In C57BL/6 mice, the median junctional conductance between dark-adapted rods is ∼140 pS, regardless of the time in the circadian cycle. Adaptation to bright light decreases the rod junctional conductance to ∼0 pS, regardless of the time of day or the mouse strain. Together, these results establish the high degree of plasticity of rod electrical coupling over the course of the day. Estimates of the rod coupling strength will provide a foundation for further investigations of rod interactions and the role of rod coupling in the ability of the visual system to anticipate, assimilate, and respond to the daily changes in ambient light intensity.SIGNIFICANCE STATEMENTMany cells in the CNS communicate via gap junctions, or electrical synapses, the regulation of which remains largely unknown. Here, we show that the strength of electrical coupling between rod photoreceptors of the retina is regulated by the time of day and the lighting conditions. This mechanism may help us understand some key aspects of day and night vision as well as some visual malfunctions.

Published

2016

19. Newly Identified Electrically Coupled Neurons Support Development of theDrosophilaGiant Fiber Model Circuit

Author

Tyler Kennedy and Kendal Broadie

Subjects

electrical synapse, Interneuron, Upstream and downstream (transduction), Green Fluorescent Proteins, Innexin, Biology, Nervous System, Animals, Genetically Modified, circuit map, 03 medical and health sciences, Electrical Synapses, 0302 clinical medicine, Dextrins, medicine, Animals, Drosophila Proteins, Electrical synapse, Axon, 030304 developmental biology, Neurons, 0303 health sciences, Microscopy, Confocal, Rhodamines, General Neuroscience, Giant fiber, General Medicine, New Research, innexin, medicine.anatomical_structure, nervous system, 8.1, Sensory and Motor Systems, Drosophila, Ganglia, Neuron, Nerve Net, Neuroscience, 030217 neurology & neurosurgery

Abstract

TheDrosophilagiant fiber (GF) escape circuit is an extensively studied model for neuron connectivity and function. Researchers have long taken advantage of the simple linear neuronal pathway, which begins at peripheral sensory modalities, travels through the central GF interneuron (GFI) to motor neurons, and terminates on wing/leg muscles. This circuit is more complex than it seems, however, as there exists a complex web of coupled neurons connected to the GFI that widely innervates the thoracic ganglion. Here, we define four new neuron clusters dye coupled to the central GFI, which we name GF coupled (GFC) 1–4. We identify new transgenic Gal4 drivers that express specifically in these neurons, and map both neuronal architecture and synaptic polarity. GFC1–4 share a central site of GFI connectivity, the inframedial bridge, where the neurons each form electrical synapses. Targeted apoptotic ablation of GFC1 reveals a key role for the proper development of the GF circuit, including the maintenance of GFI connectivity with upstream and downstream synaptic partners. GFC1 ablation frequently results in the loss of one GFI, which is always compensated for by contralateral innervation from a branch of the persisting GFI axon. Overall, this work reveals extensively coupled interconnectivity within the GF circuit, and the requirement of coupled neurons for circuit development. Identification of this large population of electrically coupled neurons in this classic model, and the ability to genetically manipulate these electrically synapsed neurons, expands the GF system capabilities for the nuanced, sophisticated circuit dissection necessary for deeper investigations into brain formation.

Published

2018

20. Synergy between Electrical Coupling and Membrane Properties Promotes Strong Synchronization of Neurons of the Mesencephalic Trigeminal Nucleus

Author

James I. Nagy, Sebastian Curti, Alberto E. Pereda, and Gregory Hoge

Subjects

Synaptic Membranes, Cell Communication, In Vitro Techniques, Biology, Trigeminal Nuclei, Connexins, Article, Synchronization, Membrane Potentials, Rats, Sprague-Dawley, Mice, Electrical Synapses, Mesencephalon, Mesencephalic trigeminal nucleus, medicine, Animals, Rats, Wistar, Meclofenamic Acid, Mice, Knockout, General Neuroscience, Gap junction, Brain, Gap Junctions, Molecular Imaging, Rats, Mice, Inbred C57BL, Coupling (electronics), Electrophysiology, Membrane, medicine.anatomical_structure, Neuroscience, Nucleus

Abstract

Electrical synapses are known to form networks of extensively coupled neurons in various regions of the mammalian brain. The mesencephalic trigeminal (MesV) nucleus, formed by the somata of primary afferents originating in jaw-closing muscles, constitutes one of the first examples supporting the presence of electrical synapses in the mammalian CNS; however, the properties, functional organization, and developmental emergence of electrical coupling within this structure remain unknown. By combining electrophysiological, tracer coupling, and immunochemical analysis in brain slices of rat and mouse, we found that coupling is mostly restricted to pairs or small clusters of MesV neurons. Electrical transmission is supported by connexin36 (Cx36)-containing gap junctions at somato-somatic contacts where only a small proportion of channels appear to be open (∼0.1%). In marked contrast with most brain structures, coupling among MesV neurons increases with age, such that it is absent during early development and appears at postnatal day 8. Interestingly, the development of coupling parallels the development of intrinsic membrane properties responsible for repetitive firing in these neurons. We found that, acting together, sodium and potassium conductances enhance the transfer of signals with high-frequency content via electrical synapses, leading to strong spiking synchronization of the coupled neurons. Together, our data indicate that coupling in the MesV nucleus is restricted to mostly pairs of somata between which electrical transmission is supported by a surprisingly small fraction of the channels estimated to be present, and that coupling synergically interacts with specific membrane conductances to promote synchronization of these neurons.

Published

2012

21. Gap Junction Expression Is Required for Normal Chemical Synapse Formation

Author

Krista L. Todd, William B. Kristan, and Kathleen A. French

Subjects

Neurons, Nervous system, Analysis of Variance, Chemical synapse, Ephaptic coupling, General Neuroscience, Synaptogenesis, Gap junction, Excitatory Postsynaptic Potentials, Gap Junctions, Biology, Article, Electrophysiology, medicine.anatomical_structure, Electrical Synapses, Mauthner cell, Leeches, Synapses, Silent synapse, medicine, Animals, Neuroscience, In Situ Hybridization

Abstract

Electrical and chemical synapses provide two distinct modes of direct communication between neurons, and the embryonic development of the two is typically not simultaneous. Instead, in both vertebrates and invertebrates, gap junction-based electrical synapses arise before chemical synaptogenesis, and the early circuits composed of gap junction-based electrical synapses resemble those produced later by chemical synapses. This developmental sequence from electrical to chemical synapses has led to the hypothesis that, in developing neuronal circuits, electrical junctions are necessary forerunners of chemical synapses. Up to now, it has been difficult to test this hypothesis directly, but we can identify individual neurons in the leech nervous system from before the time when synapses are first forming, so we could test the hypothesis. Using RNA interference, we transiently reduced gap junction expression in individual identified neurons during the 2–4 d when chemical synapses normally form. We found that the expected chemical synapses failed to form on schedule, and they were still missing months later when the nervous system was fully mature. We conclude that the formation of gap junctions between leech neurons is a necessary step in the formation of chemical synaptic junctions, confirming the predicted relation between electrical synapses and chemical synaptogenesis.

Published

2010

22. Variability of Distribution of Ca2+/Calmodulin-Dependent Kinase II at Mixed Synapses on the Mauthner Cell: Colocalization and Association with Connexin 35

Author

Smaranda Ene, Srikant Nannapaneni, Angus C. Nairn, Carmen E. Flores, Alberto E. Pereda, and Roger Cachope

Subjects

Glutamatergic, Electrical Synapses, Mauthner cell, General Neuroscience, Ca2+/calmodulin-dependent protein kinase, Gap junction, Connexin, Long-term potentiation, Neurotransmission, Biology, Cell biology

Abstract

In contrast to chemical transmission, few proteins have been shown associated with gap junction-mediated electrical synapses. Mixed (electrical and glutamatergic) synaptic terminals on the teleost Mauthner cell known as “Club endings” constitute because of their unusual large size and presence of connexin 35 (Cx35), an ortholog of the widespread mammalian Cx36, a valuable model for the study of electrical transmission. Remarkably, both components of their mixed synaptic response undergo activity-dependent potentiation. Changes in electrical transmission result from interactions with colocalized glutamatergic synapses, the activity of which leads to the activation of Ca2+/calmodulin-dependent kinase II (CaMKII), required for the induction of changes in both forms of transmission. However, the distribution of this kinase and potential localization to electrical synapses remains undetermined. Taking advantage of the unparalleled experimental accessibility of Club endings, we explored the presence and intraterminal distribution of CaMKII within these terminals. Here we show that (1) unlike other proteins, both CaMKII labeling and distribution were highly variable between contiguous contacts, and (2) CaMKII was not restricted to the periphery of the terminals, in which glutamatergic synapses are located, but also was present at the center in which gap junctions predominate. Accordingly, double immunolabeling indicated that Cx35 and CaMKII were colocalized, and biochemical analysis showed that these proteins associate. Because CaMKII characteristically undergoes activity-dependent translocation, the observed variability of labeling likely reflects physiological differences between electrical synapses of contiguous Club endings, which remarkably coexist with differing degrees of conductance. Together, our results indicate that CaMKII should be considered a component of electrical synapses, although its association is nonobligatory and likely driven by activity.

Published

2010

23. ADAM22, A Kv1 Channel-Interacting Protein, Recruits Membrane-Associated Guanylate Kinases to Juxtaparanodes of Myelinated Axons

Author

Elior Peles, Alma L. Burlingame, Juan A. Oses-Prieto, Yasuhiro Ogawa, James S. Trimmer, Ido Horresh, Matthew N. Rasband, Dies Meijer, and Moon Young Kim

Subjects

Scaffold protein, Silver Staining, Guanylate kinase, Immunoprecipitation, Cell Adhesion Molecules, Neuronal, Green Fluorescent Proteins, Mice, Transgenic, Nerve Tissue Proteins, Biology, Nerve Fibers, Myelinated, complex mixtures, Rats, Sprague-Dawley, Mice, Electrical Synapses, Paranodal junction, mental disorders, Disintegrin, Animals, Cell adhesion molecule, General Neuroscience, ADAM22, Intracellular Signaling Peptides and Proteins, Membrane Proteins, Guanylate Kinase, Axon initial segment, Axons, Rats, Cell biology, ADAM Proteins, nervous system, Shaker Superfamily of Potassium Channels, biology.protein

Abstract

Clustered Kv1 K+channels regulate neuronal excitability at juxtaparanodes of myelinated axons, axon initial segments, and cerebellar basket cell terminals (BCTs). These channels are part of a larger protein complex that includes cell adhesion molecules and scaffolding proteins. To identify proteins that regulate assembly, clustering, and/or maintenance of axonal Kv1 channel protein complexes, we immunoprecipitated Kv1.2 α subunits, and then used mass spectrometry to identify interacting proteins. We found that a disintegrin and metalloproteinase 22 (ADAM22) is a component of the Kv1 channel complex and that ADAM22 coimmunoprecipitates Kv1.2 and the membrane-associated guanylate kinases (MAGUKs) PSD-93 and PSD-95. When coexpressed with MAGUKs in heterologous cells, ADAM22 and Kv1 channels are recruited into membrane surface clusters. However, coexpression of Kv1.2 with ADAM22 and MAGUKs does not alter channel properties. Among all the known Kv1 channel-interacting proteins, only ADAM22 is found at every site where Kv1 channels are clustered. Analysis ofCaspr-null mice showed that, like other previously described juxtaparanodal proteins, disruption of the paranodal junction resulted in redistribution of ADAM22 into paranodal zones. Analysis ofCaspr2-,PSD-93-,PSD-95-, and doublePSD-93/PSD-95-null mice showed ADAM22 clustering at BCTs requires PSD-95, but ADAM22 clustering at juxtaparanodes requires neither PSD-93 nor PSD-95. In direct contrast, analysis ofADAM22-null mice demonstrated juxtaparanodal clustering of PSD-93 and PSD-95 requires ADAM22, whereas Kv1.2 and Caspr2 clustering is normal inADAM22-null mice. Thus, ADAM22 is an axonal component of the Kv1 K+channel complex that recruits MAGUKs to juxtaparanodes.

Published

2010

24. ZO-1 and the Spatial Organization of Gap Junctions and Glutamate Receptors in the Outer Plexiform Layer of the Mammalian Retina

Author

Christian Puller, Silke Haverkamp, Ulrike Janssen-Bienhold, and Luis Pérez de Sevilla Müller

Subjects

Outer plexiform layer, Connexin, Septate junctions, Retinal Horizontal Cells, Biology, Connexins, Retina, Tight Junctions, Adherens junction, Mice, medicine, Animals, Eye Proteins, Tight junction, General Neuroscience, Gap junction, Gap Junctions, Membrane Proteins, Articles, Adherens Junctions, Dendrites, Desmosomes, Phosphoproteins, Cell biology, Mice, Inbred C57BL, Macaca fascicularis, medicine.anatomical_structure, Electrical Synapses, Receptors, Glutamate, Zonula Occludens-1 Protein, Rabbits, sense organs

Abstract

Information processing in the retina starts at the first synaptic layer, where photoreceptors and second-order neurons exhibit a complex architecture of glutamatergic and electrical synapses. To investigate the composition of this highly organized synaptic network, we determined the spatial relationship of zonula occludens-1 (ZO-1) with different connexins (Cx) and glutamate receptor (GluR) subunits in the outer plexiform layer (OPL) of rabbit, mouse, and monkey retinas. ZO-1 is well known as an intracellular component of tight and adherens junctions, but also interacts with various connexins at gap junctions. We found ZO-1 closely associated with Cx50 on dendrites of A-type horizontal cells in rabbit, and with Cx57 at dendro-dendritic gap junctions of mouse horizontal cells. The spatial arrangement of ZO-1 at the giant gap-junctional plaques in rabbit was particularly striking. ZO-1 formed a clear margin around the large Cx50 plaques instead of being colocalized with the connexin staining. Our finding suggests the involvement of ZO-1 in the composition of tight or adherens junctions around gap-junctional plaques instead of interacting with connexins directly. Furthermore, gap junctions were found to be clustered in close proximity to GluRs at the level of desmosome-like junctions, where horizontal cell dendrites converge before invaginating the cone pedicle. Based on this distinct spatial organization of gap junctions and GluRs, it is tempting to speculate that glutamate released from the photoreceptors may play a role in modulating the conductance of electrical synapses in the OPL.

Published

2009

25. Electrical Coupling of Lobula Plate Tangential Cells to a Heterolateral Motion-Sensitive Neuron in the Fly

Author

Alexander Borst and Juergen Haag

Subjects

Sensory Receptor Cells, Connection (vector bundle), Motion Perception, Biotin, Biology, Functional Laterality, Synapse, Electrical Synapses, Postsynaptic potential, Neural Pathways, Reaction Time, medicine, Animals, Diptera, General Neuroscience, Gap junction, Brain, Motion detection, Articles, Synaptic Potentials, Electric Stimulation, medicine.anatomical_structure, Brain Hemisphere, Neuron, Nerve Net, Neuroscience, Photic Stimulation

Abstract

Many motion-sensitive tangential cells of the lobula plate in blowflies are well described with respect to their visual response properties and the connectivity among them. In addition to extensive connections between tangential cells within the lobula plate of one brain hemisphere, there exist many connections between the two hemispheres. Most of these connections have been found for neurons sensitive to horizontal motion. For neurons sensitive to vertical motion, however, only the connection of vertical sensitive cells (VS cells) and a cell (V1 cell) projecting to the other hemisphere has been demonstrated thus far. The ability to identify the presynaptic and postsynaptic cells as well as the good accessibility has made this specific synapse a model for graded transmission of synapses. However, the exact type of synapse, electrical or chemical, is not known. Investigating the connectivity between VS cells 1–3 and the V1 cell by means of dual recordings, we find that the VS cells are coupled via electrical synapses to the V1 cell. The results were confirmed by visualizing dye coupling between VS cells and V1.

Published

2008

26. Noradrenergic Modulation of Electrical Coupling in GABAergic Networks of the Hippocampus

Author

Veronika Zsiros and Gianmaria Maccaferri

Subjects

Action Potentials, Hippocampus, Biology, Rats, Sprague-Dawley, Adenylyl cyclase, Norepinephrine, chemistry.chemical_compound, Interneurons, Animals, gamma-Aminobutyric Acid, Forskolin, General Neuroscience, Gap junction, Gap Junctions, Articles, Chemical synaptic transmission, Electric Stimulation, Rats, Coupling (electronics), Electrical Synapses, Animals, Newborn, chemistry, GABAergic, Nerve Net, Neuroscience

Abstract

Noradrenergic modulation of cortical circuits is involved in information processing, regulation of higher functions, and prevention of epileptic activity. Here, we studied the effects of noradrenaline on the functional connectivity of GABAergic networks of the hippocampus and show that electrical synapses between interneurons are a novel target of noradrenergic modulationin vitro. Application of noradrenaline or of the selective β-adrenergic agonist isoproterenol decreased gap junction-based coupling in paired recordings from stratum lacunosum-moleculare interneurons by ∼40%. Similar results were obtained after pharmacological stimulation of the adenylyl cyclase with forskolin. In contrast, the adenylyl cyclase antagonist MDL12330A [cis-N-(2-phenylcyclopentyl)azacyclotridec-1-en-2-amine] or the specific protein kinase A (PKA) inhibitor H89 (N-[2-(p-bromocinnamyl-amino)ethyl]-5-isoquinolinesulfonamide dihydrochloride) enhanced the basal strength of coupling by ∼30%. In addition, PKA-mediated phosphorylation was critical for both isoproterenol- and forskolin-dependent regulation of coupling, because inclusion of the PKA antagonist KT5720 [(9S,10R,12R)-2,3,9,10,11,12-hexahydro-10-hydroxy-9-methyl-1-oxo-9,12-epoxy-1H-diindolo[1,2,3-fg:3′,2′,1′-kl]pyrrolo[3,4-i][1,6]benzodiazocine-10-carboxylicacid hexyl ester] in the recording pipettes prevented modulation.Lastly, we studied the effects of β-adrenergic modulation on mixed polysynaptic transmission within the GABAergic network. Isoproterenol depressed propagation of GABAAreceptor-mediated synaptic currents, but did not change significantly direct GABAergic input, indicating that regulation of electrical coupling adds flexibility to the information flow generated by chemical synapses.In conclusion, activation of β-adrenergic receptors in stratum lacunosum-moleculare GABAergic networks reduces electrical synaptic transmission via a cAMP/PKA signaling cascade, and affects the degree of synaptic divergence within the circuit. We propose that this dynamic modulation and interplay between electrical and chemical synaptic transmission in GABAergic networks contributes to the tuning of memory processesin vivo, and prevents hypersynchronous activity.

Published

2008

27. Bistable Network Behavior of Layer I Interneurons in Auditory Cortex

Author

Theoden I. Netoff, Elliott B. Merriam, and Matthew I. Banks

Subjects

Male, Patch-Clamp Techniques, Bistability, Video Recording, In Vitro Techniques, Biology, Auditory cortex, Inhibitory postsynaptic potential, Article, Mice, Interneurons, medicine, Animals, gamma-Aminobutyric Acid, Auditory Cortex, Neocortex, Quantitative Biology::Neurons and Cognition, General Neuroscience, Gap Junctions, Depolarization, Electrophysiology, Coupling (electronics), Electrical Synapses, medicine.anatomical_structure, Synapses, Mice, Inbred CBA, Female, Neuroscience

Abstract

GABAergic interneurons in many areas of the neocortex are mutually connected via chemical and electrical synapses. Previous computational studies have explored how these coupling parameters influence the firing patterns of interneuronal networks. These models have predicted that the stable states of such interneuronal networks will be either synchrony (near zero phase lag) or antisynchrony (phase lag near one-half of the interspike interval), depending on network connectivity and firing rates. In certain parameter regimens, the network can be bistable, settling into either stable state depending on the initial conditions. Here, we investigated how connectivity parameters influence spike patterns in paired recordings from layer I interneurons in brain slices from juvenile mice. Observed properties of chemical and electrical synapses were used to simulate connections between uncoupled cells via dynamic clamp. In uncoupled pairs, action potentials induced by constant depolarizing currents had randomly distributed phase differences between the two cells. When coupled with simulated chemical (inhibitory) synapses, however, these pairs exhibited a bimodal firing pattern, tending to fire either in synchrony or in antisynchrony. Combining electrical with chemical synapses, prolonging τDecayof inhibitory connections, or increasing the firing rate of the network all resulted in enhanced stability of the synchronous state. Thus, electrical and inhibitory synaptic coupling constrain the relative timing of spikes in a two-cell network to, at most, two stable states, the stability and precision of which depend on the exact parameters of coupling.

Published

2005

28. The Retrograde Spread of Synaptic Potentials and Recruitment of Presynaptic Inputs

Author

Brian L. Antonsen, Jens Herberholz, and Donald H. Edwards

Subjects

Diagnostic Imaging, Male, Time Factors, Biotin, Astacoidea, Behavioral/Systems/Cognitive, In Vitro Techniques, Biology, Stimulus (physiology), Synaptic Transmission, Membrane Potentials, Postsynaptic potential, Physical Stimulation, medicine, Animals, Evoked Potentials, Neurons, Afferent Pathways, General Neuroscience, Dextrans, Dose-Response Relationship, Radiation, Neural Inhibition, Depolarization, Axons, Ganglia, Invertebrate, Antidromic, Electrical Synapses, medicine.anatomical_structure, nervous system, Command neuron, Synapses, Excitatory postsynaptic potential, Female, Neuron, Nerve Net, Neuroscience

Abstract

Lateral excitation is a mechanism for amplifying coordinated input to postsynaptic neurons that has been described recently in several species. Here, we describe how a postsynaptic neuron, the lateral giant (LG) escape command neuron, enhances lateral excitation among its presynaptic mechanosensory afferents in the crayfish tailfan. A lateral excitatory network exists among electrically coupled tailfan primary afferents, mediated through central electrical synapses. EPSPs elicited in LG dendrites as a result of mechanosensory stimulation spread antidromically back through electrical junctions to unstimulated afferents, summate with EPSPs elicited through direct afferent-to-afferent connections, and contribute to recruitment of these afferents. Antidromic potentials are larger if the afferent is closer to the initial input on LG dendrites, which could create a spatial filtering mechanism within the network. This pathway also broadens the temporal window over which lateral excitation can occur, because of the delay required for EPSPs to spread through the large LG dendrites. The delay allows subthreshold inputs to the LG to have a priming effect on the lateral excitatory network and lowers the threshold of the network in response to a second, short-latency stimulus. Retrograde communication within neuronal pathways has been described in a number of vertebrate and invertebrate species. A mechanism of antidromic passage of depolarizing current from a neuron to its presynaptic afferents, similar to that described here in an invertebrate, is also present in a vertebrate (fish). This raises the possibility that short-term retrograde modulation of presynaptic elements through electrical junctions may be common.

Published

2005

29. Electrical Synapses between Dopaminergic Neurons of the Substantia Nigra Pars Compacta

Author

Laurent Venance, Jacques Glowinski, Marie Vandecasteele, Centre interdisciplinaire de recherche en biologie (CIRB), Labex MemoLife, École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Collège de France (CdF (institution))-Ecole Superieure de Physique et de Chimie Industrielles de la Ville de Paris (ESPCI Paris), Université Paris sciences et lettres (PSL)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Chaire Neuropharmacologie (INSERM U114), and Collège de France (CdF (institution))

Subjects

electrical synapse, connexin, Dopamine, [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Models, Neurological, Action Potentials, Substantia nigra, In Vitro Techniques, paired recordings, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, dopaminergic neuron, medicine, Animals, substantia nigra pars compacta, gap junctions, 030304 developmental biology, Neurons, 0303 health sciences, Chemistry, Pars compacta, General Neuroscience, Dopaminergic, Depolarization, Rat brain, Rats, Substantia Nigra, Coupling (electronics), Electrical Synapses, nervous system, Neuroscience, 030217 neurology & neurosurgery, Cellular/Molecular, medicine.drug

Abstract

International audience; Spatiotemporal properties of dopamine release play a major role both in striatal and nigral physiology because dopamine is released from nerve terminals and dendrites of nigrostriatal dopaminergic (DA) neurons. Pioneering work revealed gap junctional communication (assessed by dye-coupling experiments) between DA cells in the substantia nigra pars compacta (SNc). However, direct evidence of functional electrical synapses between DA neurons is still lacking. In this study, gap junctional communication between DA neurons was investigated in rat brain slices. Tracer coupling was observed in postnatal day 5 (P5) to P10 and P15-P25 rats. Dual whole-cell patch-clamp recordings revealed that 96% of DA neurons were coupled by electrical synapses in P7-P10 rats, and 20% were coupled in P17-P21 rats. These electrical synapses were mainly symmetrical and displayed strong low-pass filtering properties. When spontaneous firing activity was monitored, no significant synchronization was observed. Nevertheless, an efficient modulation of the spontaneous firing frequency of the postsynaptic cell occurred during injection of hyperpolarizing and depolarizing currents in the coupled presynaptic cell. Together, these observations demonstrate the existence of a fast communication between SNc DA neurons through electrical synapses.

Published

2005

30. Dendrodendritic Electrical Synapses between Mammalian Retinal Ganglion Cells

Author

Soh Hidaka, Yasushi Akahori, and Yoshikazu Kurosawa

Subjects

Retinal Ganglion Cells, Patch-Clamp Techniques, Confocal, Action Potentials, Biotin, Connexin, In Vitro Techniques, Biology, Retinal ganglion, Connexins, Electricity, Chlorocebus aethiops, Animals, Patch clamp, Rats, Wistar, Microscopy, Confocal, General Neuroscience, Gap junction, Gap Junctions, Depolarization, Dendrites, Immunohistochemistry, Rats, Coupling (electronics), Microscopy, Electron, Electrical Synapses, COS Cells, Biophysics, Neuroscience, Cellular/Molecular

Abstract

Electrical synapses between α-type ganglion cells were detected using combined techniques of dual patch-clamp recordings, intracellular labeling, electron microscopy, and channel subunit connexin immunocytochemistry in the albino rat retina. After intracellular injection of Neurobiotin into α-cells of inner (ON-center) and outer (OFF-center) ramifying types, measurement of tracer coupling resulted in a preferentially homologous occurrence among cells of the same morphological type (n= 19 of 24). In high-voltage as well as conventional electron microscopic analysis, direct dendrodendritic gap junctions (average size, 0.86 μm long) were present in contact sites between tracer-coupled α-cells. In simultaneous dual whole-cell recordings from pairs of neighboring α-cells, these cells generated TTX-sensitive sustained spiking against extrinsic current injection, and bidirectional electrical synapses (maximum coupling coefficient, 0.32) with symmetrical junction conductance (average, 1.35 nS) were observed in pairs with cells of the same morphological type. Precise temporal synchronization of spike activity (average time delay, 2.7 msec) was detected when depolarizing currents were simultaneously injected into the pairs. To address whether physiologically identified electrical synapses constitute gap junctional connectivity between cell pairs, identified neuronal connexin36 immunoreactivity was undertaken in Lucifer yellow-labeled cell pairs after patch-clamp recordings. All α-cells expressed connexin36, and confocal laser-scanning imaging demonstrated that connexin36 is primarily located at dendritic crossings between electrically coupled cells (seven sites in a pair, on average). These results give conclusive evidence for electrical synapses via dendrodendritic gap junctions involving connexin36 in α retinal ganglion cells of the same physiological type.

Published

2004

31. Small Clusters of Electrically Coupled Neurons Generate Synchronous Rhythms in the Thalamic Reticular Nucleus

Author

Barry W. Connors, Carole E. Landisman, and Michael A. Long

Subjects

Periodicity, Action Potentials, Cell Communication, Behavioral/Systems/Cognitive, Biology, Receptors, Metabotropic Glutamate, Inhibitory postsynaptic potential, Rats, Sprague-Dawley, Postsynaptic potential, medicine, Animals, Electrical synapse, Cells, Cultured, Neurons, Membrane potential, Thalamic reticular nucleus, Intralaminar Thalamic Nuclei, General Neuroscience, Electric Conductivity, Excitatory Postsynaptic Potentials, Gap Junctions, Chemical synaptic transmission, Rats, medicine.anatomical_structure, Electrical Synapses, Metabotropic glutamate receptor, Synapses, Neuroscience

Abstract

The inhibitory neurons of the thalamic reticular nucleus (TRN) contribute to the generation of widespread oscillations in the thalamocortical system. Some TRN neurons are interconnected by electrical synapses, and here we tested the possibility that electrical synapses mediate rhythmic synchrony in juvenile rats. Both the incidence and strength of electrical coupling between pairs of TRN neurons were a steep function of intersomatic distance, and coupling was absent at distances >40 μm. Presynaptic spike bursts evoked much larger electrical postsynaptic potentials than did single presynaptic spikes. Activation of metabotropic glutamate receptors (mGluRs) with a bath-applied agonist or an endogenous ligand released during tetanic stimulation induced robust rhythms of the subthreshold membrane potential, with a mean frequency of ∼10 Hz. In the absence of fast chemical synaptic transmission, subthreshold rhythms and the action potentials that they evoked were well synchronized between closely spaced, electrically coupled pairs; rhythms in noncoupled cells were not synchronized. The results suggest that electrical synapses can coordinate spindle-frequency rhythms among small clusters of mGluR-activated TRN cells.

Published

2004

32. Selective Impairment of Hippocampal Gamma Oscillations in Connexin-36 Knock-Out MouseIn Vivo

Author

György Buzsáki, Kenneth D. Harris, Sheriar G. Hormuzdi, Derek L. Buhl, and Hannah Monyer

Subjects

Male, Rapid eye movement sleep, Action Potentials, Connexin, Hippocampus, Motor Activity, Hippocampal formation, Electroencephalography, Biology, Article, Connexins, Mice, Biological Clocks, medicine, Animals, Mice, Knockout, Behavior, Animal, medicine.diagnostic_test, Pyramidal Cells, General Neuroscience, Gap junction, Signal Processing, Computer-Assisted, Electrodes, Implanted, Electrical Synapses, Knockout mouse, Sleep, Neuroscience

Abstract

The physiological roles of neuronal gap junctions in the intact brain are not known. The recent generation of the connexin-36 knock-out (Cx36 KO) mouse has offered a unique opportunity to examine this problem. Recentin vitrorecordings in Cx36 KO mice suggested that Cx36 gap junction contributes to various oscillatory patterns in the theta (∼5–10 Hz) and gamma (∼30–80 Hz) frequency ranges and affects certain aspects of high-frequency (>100 Hz) patterns. However, the relevance of these pharmacologically induced patterns to the intact brain is not known. We recorded field potentials and unit activity in the CA1 stratum pyramidale of the hippocampus in the behaving wild-type (WT) and Cx36 KO mice. Fast-field “ripple” oscillations (140–200 Hz) were present in both WT and KO mice and did not differ significantly in power, intraepisode frequency, or probability of occurrence. Thus, fast-field oscillations either may not require electrical synapses or may be mediated by a hitherto unknown class of gap junctions. Theta oscillations, recorded during either wheel running or rapid eye movement sleep, were not different either. However, the power in the gamma frequency band and the magnitude of theta-phase modulation of gamma power were significantly decreased in KO mice compared with WT controls during wheel running. This suggests that Cx36 interneuronal gap junctions selectively contribute to gamma oscillations.

Published

2003

33. Dendro-Dendritic Interactions between Motion-Sensitive Large-Field Neurons in the Fly

Author

Alexander Borst and Juergen Haag

Subjects

media_common.quotation_subject, Motion Perception, Motion (geometry), Dendrite, In Vitro Techniques, Biology, Inhibitory postsynaptic potential, medicine, Animals, Contrast (vision), Visual Pathways, Calcium Signaling, ARTICLE, Fluorescent Dyes, media_common, Neurons, Communication, business.industry, Diptera, General Neuroscience, Motion detection, Dendrites, Electrophysiology, medicine.anatomical_structure, Electrical Synapses, Receptive field, Synapses, Female, Visual Fields, business, Neuroscience, Photic Stimulation

Abstract

For visual course control, flies rely on a set of motion-sensitive neurons called lobula plate tangential cells (LPTCs). Among these cells, the so-called CH (centrifugal horizontal) cells shape by their inhibitory action the receptive field properties of other LPTCs called FD (figure detection) cells specialized for figure-ground discrimination based on relative motion. Studying the ipsilateral input circuitry of CH cells by means of dual-electrode and combined electrical-optical recordings, we find that CH cells receive graded input from HS (large-field horizontal system) cells via dendro-dendritic electrical synapses. This particular wiring scheme leads to a spatial blur of the motion image on the CH cell dendrite, and, after inhibiting FD cells, to an enhancement of motion contrast. This could be crucial for enabling FD cells to discriminate object from self motion.

Published

2002

34. Electrical Synapses in the Thalamic Reticular Nucleus

Author

Michael A. Long, Michael Beierlein, Barry W. Connors, Michael R. Deans, Carole E. Landisman, and David L. Paul

Subjects

Heterozygote, Thalamus, Action Potentials, In Vitro Techniques, Biology, Inhibitory postsynaptic potential, Connexins, Rats, Sprague-Dawley, Mice, medicine, Animals, ARTICLE, Mice, Knockout, Neurons, Thalamic reticular nucleus, Intralaminar Thalamic Nuclei, General Neuroscience, Homozygote, Gap junction, Gap Junctions, Electric Stimulation, Rats, Coupling (electronics), medicine.anatomical_structure, Electrical Synapses, nervous system, Cerebral cortex, Thalamic Nuclei, Synapses, Forebrain, Neuroscience

Abstract

Neurons of the thalamic reticular nucleus (TRN) provide inhibitory input to thalamic relay cells and generate synchronized activity during sleep and seizures. It is widely assumed that TRN cells interact only via chemical synaptic connections. However, we show that many neighboring pairs of TRN neurons in rats and mice are electrically coupled. In paired-cell recordings, electrical synapses were able to mediate close correlations between action potentials when the coupling was strong; they could modulate burst-firing states even when the coupling strength was more modest. Electrical synapses between TRN neurons were absent in mice with a null mutation for the connexin36 (Cx36) gene. Surprisingly, inhibitory chemical synaptic connections between pairs of neurons were not observed, although strong extracellular stimuli could evoke inhibition in single TRN neurons. We conclude that Cx36-dependent gap junctions play an important role in the regulation of neural firing patterns within the TRN. When combined with recent observations from the cerebral cortex, our results imply that electrical synapses are a common mechanism for generating synchrony within networks of inhibitory neurons in the mammalian forebrain.

Published

2002

35. Two Functionally Distinct Networks of Gap Junction-Coupled Inhibitory Neurons in the Thalamic Reticular Nucleus

Author

Barry W. Connors, Seung-Chan Lee, Kristen A. Richardson, and Saundra L. Patrick

Subjects

Thalamus, Biology, Inhibitory postsynaptic potential, Connexins, Rats, Sprague-Dawley, Mice, Electrical Synapses, Interneurons, medicine, Animals, GABAergic Neurons, Thalamic reticular nucleus, Intralaminar Thalamic Nuclei, General Neuroscience, Gap junction, Neural Inhibition, Articles, Axons, Rats, Mice, Inbred C57BL, medicine.anatomical_structure, nervous system, Forebrain, GABAergic, Neuron, Neuroscience

Abstract

Gap junctions (GJs) electrically couple GABAergic neurons of the forebrain. The spatial organization of neuron clusters coupled by GJs is an important determinant of network function, yet it is poorly described for nearly all mammalian brain regions. Here we used a novel dye-coupling technique to show that GABAergic neurons in the thalamic reticular nucleus (TRN) of mice and rats form two types of GJ-coupled clusters with distinctive patterns and axonal projections. Most clusters are elongated narrowly along functional modules within the plane of the TRN, with axons that selectively inhibit local groups of relay neurons. However, some coupled clusters have neurons arrayed across the thickness of the TRN and target their axons to both first- and higher-order relay nuclei. Dye coupling was reduced, but not abolished, among cells of connexin36 knock-out mice. Our results suggest that GJs form two distinct types of inhibitory networks that correlate activity either within or across functional modules of the thalamus.

Published

2014

36. Molecular and Functional Diversity of Neural Connexins in the Retina

Author

Roberto Bruzzone, U. Janssen-Bienhold, Bruce J. Nicholson, M. Kremer, Miduturu Srinivas, I. M. Skerrett, A. Stang, Rolf Dermietzel, D. Gomes, Reto Weiler, G. Paputsoglu, and D. C. Spray

Subjects

Carps, Patch-Clamp Techniques, Microinjections, Molecular Sequence Data, Xenopus, Gene Expression, Connexin, Connexins, Retina, Xenopus laevis, medicine, Animals, RNA, Messenger, Patch clamp, Cloning, Molecular, ARTICLE, Eye Proteins, Zebrafish, Cells, Cultured, Conserved Sequence, In Situ Hybridization, Neurons, biology, Reverse Transcriptase Polymerase Chain Reaction, General Neuroscience, Gap junction, Gap Junctions, Zebrafish Proteins, biology.organism_classification, Connexin 26, Electrophysiology, medicine.anatomical_structure, Electrical Synapses, Organ Specificity, Connexin 43, Synapses, Oocytes, Biophysics, Female, Sequence Alignment, Neuroscience

Abstract

Electrical synapses (gap junctions) in neuronal circuits have become a major focus in the study of network properties such as synchronization and oscillation (Galarreta and Hestrin, 1999;Gibson et al., 1999). Despite the recent progress made in unraveling the contribution of gap junctions to network behavior, little is known about the molecular composition of the junctional constituents. By cloning gap junction proteins [connexins (Cxs)] from zebrafish retina and through functional expression, we demonstrate that the retina possesses a high degree of connexin diversity, which may account for differential functional properties of electrical synapses. Three new Cxs, designated as zebrafish Cx27.5 (zfCx27.5), zfCx44.1, and zfCx55.5, and the carp ortholog of mammalian Cx43 were cloned. Byin situhybridization andin situRT-PCR, we demonstrate that the four fish connexin mRNAs show differential localization in the retina. Transient functional expression in pairedXenopusoocytes and in the neuroblastoma N2A cell line indicate an extreme range of electrophysiological properties of these connexins in terms of voltage dependence and unitary conductance. For instance, the new zfCx44.1 exhibited high sensitivity to voltage-induced closure with currents decaying rapidly for transjunctional potentials >10 mV, whereas zfCx55.5 channels showed an opposite voltage dependence in response to voltage steps of either polarity. Moreover, although zfCx44.1 channels showed unitary conductance as high as any previously reported for junctional channels (nearly 300 pS), zfCx55.5 and zfCx27.5 exhibited much lower unitary conductances (

Published

2000

37. Rectifying Electrical Synapses Can Affect the Influence of Synaptic Modulation on Output Pattern Robustness

Author

Eve Marder and Gabrielle J. Gutierrez

Subjects

Neurons, Periodicity, Synaptic pharmacology, Nerve net, General Neuroscience, Models, Neurological, Articles, Neurotransmission, Biology, Inhibitory postsynaptic potential, Synaptic Transmission, Membrane Potentials, Synapse, medicine.anatomical_structure, Electrical Synapses, medicine, Biological neural network, Animals, Computer Simulation, Neuron, Nerve Net, Neuroscience

Abstract

Rectifying electrical synapses are commonplace, but surprisingly little is known about how rectification alters the dynamics of neuronal networks. In this study, we use computational models to investigate how rectifying electrical synapses change the behavior of a small neuronal network that exhibits complex rhythmic output patterns. We begin with an electrically coupled circuit of three oscillatory neurons with different starting frequencies, and subsequently add two additional neurons and inhibitory chemical synapses. The five-cell model represents a pattern-generating neuronal network with two simultaneous rhythms competing for the recruitment of a hub neuron. We compare four different configurations of rectifying synapse placement and polarity, and we investigate how rectification changes the functional output of this network. Rectification can have a striking effect on the network's sensitivity to alterations of the strengths of the chemical synapses in the network. For some configurations, the rectification makes the circuit dynamics remarkably robust against changes in synaptic strength compared with the nonrectifying case. Based on our findings, we predict that modulation of rectifying electrical synapses could have functional consequences for the neuronal circuits that express them.

Published

2013

38. Mutations in shaking-B prevent electrical synapse formation in the Drosophila giant fiber system

Author

Marian B Wilkin, Jane A. Davies, Kevin G. Moffat, Jonathan P. Bacon, Pauline Phelan, Madoka Nakagawa, and Cahir J. O'Kane

Subjects

Interneuron, Recombinant Fusion Proteins, Commissural Interneurons, Molecular Sequence Data, Synaptogenesis, Nerve Tissue Proteins, Innexin, Biology, Connexins, Animals, Genetically Modified, chemistry.chemical_compound, Nerve Fibers, Escape Reaction, Interneurons, Morphogenesis, medicine, Animals, Drosophila Proteins, Visual Pathways, Amino Acid Sequence, Electrical synapse, Motor Neurons, Lucifer yellow, General Neuroscience, Metamorphosis, Biological, Pupa, Gap junction, Gap Junctions, Articles, Drosophila melanogaster, Enhancer Elements, Genetic, medicine.anatomical_structure, Electrical Synapses, chemistry, Larva, Synapses, Neuroscience

Abstract

The giant fiber system (GFS) is a simple network of neurons that mediates visually elicited escape behavior in Drosophila. The giant fiber (GF), the major component of the system, is a large, descending interneuron that relays visual stimuli to the motoneurons that innervate the tergotrochanteral jump muscle (TTM) and dorsal longitudinal flight muscles (DLMs). Mutations in the neural transcript from the shaking-B locus abolish the behavioral response by disrupting transmission at some electrical synapses in the GFS. This study focuses on the role of the gene in the development of the synaptic connections. Using an enhancer-trap line that expresses lacZ in the GFs, we show that the neurons develop during the first 30 hr of metamorphosis. Within the next 15 hr, they begin to form electrical synapses, as indicated by the transfer of intracellularly injected Lucifer yellow. The GFs dye-couple to the TTM motoneuron between 30 and 45 hr of metamorphosis, to the peripherally synapsing interneuron that drives the DLM motoneurons at approximately 48 hr, and to giant commissural interneurons in the brain at approximately 55 hr. Immunocytochemistry with shaking-B peptide antisera demonstrates that the expression of shaking-B protein in the region of GFS synapses coincides temporally with the onset of synaptogenesis; expression persists thereafter. The mutation shak-B2, which eliminates protein expression, prevents the establishment of dye coupling shaking-B, therefore, is essential for the assembly and/or maintenance of functional gap junctions at electrical synapses in the GFS.

Published

1996

39. Only a Minority of the Inhibitory Inputs to Cerebellar Golgi Cells Originates from Local GABAergic Cells

Author

Mark D. Eyre and Zoltan Nusser

Subjects

0303 health sciences, Cerebellum, GABAA receptor, General Neuroscience, General Medicine, Biology, Inhibitory postsynaptic potential, gamma-Aminobutyric acid, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Electrical Synapses, medicine, GABAergic, Axon, Glycine receptor, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology, medicine.drug

Abstract

Cerebellar Golgi cells (GoCs) efficiently control the spiking activity of granule cells through GABAAreceptor-mediated tonic and phasic inhibition. Recent experiments provided compelling evidence for the extensive interconnection of GoCs through electrical synapses, but their chemical inhibitory synaptic inputs are debated. Here, we investigated the GABAergic synaptic inputs of GoCs usingin vitroelectrophysiology and quantitative light microscopy (LM) and electron microscopy (EM). We characterized GABAAreceptor-mediated IPSCs in GoCs and Lugaro cells (LuCs), and found that IPSCs in GoCs have lower frequencies, smaller amplitudes, and much slower decay kinetics. Pharmacological and LM immunolocalization experiments revealed that GoCs express α3, whereas LuCs express α1 subunit-containing GABAAreceptors. The selective expression and clustered distribution of the α3 subunit in GoCs allowed the quantitative analysis of GABAergic synapses on their dendrites in the molecular layer (ML). EM and LM experiments in rats, and wild-type and GlyT2-GFP transgenic mice revealed that only one third of axon terminals establishing GABAergic synapses on GoC dendrites contain GlyT2, ruling out LuCs, globular cells, and any noncortical glycinergic inputs as major inhibitory sources. We also show that axon terminals of stellate/basket cells very rarely innervate GlyT2-GFP-expressing GoCs, indicating that only a minority of the inhibitory inputs to GoCs in the ML originates from local interneurons, and the majority of their inhibitory inputs exclusively releases GABA.

Published

2016

40. Self-recognition: a constraint on the formation of electrical coupling in neurons [published erratum appears in J Neurosci 1994 Jun;14(6):following table of contents]

Author

Peter Guthrie, V. Rehder, Stanley B. Kater, Robert Edward Lee, and Marc F. Schmidt

Subjects

Helisoma, biology, Neurite, General Neuroscience, Gap junction, biology.organism_classification, Cell junction, Synapse, medicine.anatomical_structure, Electrical Synapses, medicine, Biophysics, Neuron, Growth cone, Neuroscience

Abstract

Electrical coupling between specific neurons is important for proper function of many neuronal circuits. Identified cultured neurons from the snail Helisoma show a strong correlation between electrical coupling and presence of gap junction plaques in freeze-fracture replicas. Gap junction plaques, however, were never seen between overlapping neurites from a single neuron, even though those same neurites formed gap junctions with neurites from another essentially identical identified neuron. This observation suggests that a form of self-recognition inhibits reflexive gap junction formation between sibling neurites. When one or both of those growth cones had been physically isolated from the neuronal cell body, both electrical coupling and gap junction plaques, between growth cones from the same neuron, were observed to form rapidly (within 30 min). Thus, inhibition of electrical coupling between sibling neurites apparently depends on cytoplasmic continuity between neurites, and not the molecular composition of neurite membrane. The formation of gap junctions is not likely due to the isolation process; rather, the physical isolation appears to release an inhibition of reflexive gap junction formation. These data demonstrate the existence of a previously unknown constraint on the formation of electrical synapses.

Published

1994

41. Induction of High-Frequency Oscillations in a Junction-Coupled Network

Author

Shin-Hua Tseng, Shih-Rung Yeh, and Li-Yun Tsai

Subjects

Male, Patch-Clamp Techniques, Refractory period, Models, Neurological, Action Potentials, Escape response, Biology, In Vitro Techniques, GABA Antagonists, Computer Science::Emerging Technologies, Postsynaptic potential, medicine, Animals, Picrotoxin, Computer Simulation, Patch clamp, Electrical synapse, Catfishes, Neurons, Quantitative Biology::Neurons and Cognition, General Neuroscience, Gap junction, Gap Junctions, Dose-Response Relationship, Radiation, Neural Inhibition, Articles, Electric Stimulation, Electrical Synapses, medicine.anatomical_structure, Spike (software development), Female, Ganglia, Nerve Net, Neuroscience

Abstract

Rhythmic oscillations of up to 600 Hz in grouped neurons frequently occur in the brains of animals. These high-frequency oscillations can be sustained in calcium-free conditions and may be blocked by gap junction blockers, implying a key role for electrical synapses in oscillation generation. Mathematical theories have been developed to demonstrate oscillations mediated by electrical synapses without chemical modulation; however, these models have not been verified in animals. Here we report that oscillations of up to 686 Hz are induced by paired spikes of short spike intervals (SIs) in a junction-coupled network. To initiate oscillations, it was essential that the second spike was elicited during the relative refractory period. The second spike suffered from slow propagation speed and failure to transmit through a low-conductance junction. Thus, at the spike initiation site, paired spikes of short SIs triggered one transjunctional spike in the postsynaptic neuron. At distant synaptic sites, two transjunctional spikes were produced as the SI increased during spike propagation. Consequently, spike collision of these asymmetrical transjunctional spikes occurred in the interconnected network. The remaining single spike reverberated in a network serving as an oscillator center. Paired-spike-induced oscillations were modeled by computer simulation and verified electrophysiologically in a network that mediates the tail-flip escape response of crayfish.

Published

2008

42. Electrical Synapses Mediate Signal Transmission in the Rod Pathway of the Mammalian Retina

Author

Margaret Lin Veruki and Espen Hartveit

Subjects

Cell type, Periodicity, Patch-Clamp Techniques, genetic structures, Biology, Synaptic Transmission, Retina, Membrane Potentials, Postsynaptic potential, Retinal Rod Photoreceptor Cells, Culture Techniques, medicine, Animals, ARTICLE, Membrane potential, Subthreshold conduction, General Neuroscience, Gap junction, Electric Conductivity, Conductance, Excitatory Postsynaptic Potentials, Gap Junctions, Anatomy, Rats, Electrical Synapses, medicine.anatomical_structure, Amacrine Cells, Synapses, Biophysics, Retinal Cone Photoreceptor Cells, sense organs

Abstract

In the retina, AII (rod) amacrine cells are essential for integrating rod signals into the cone pathway. In addition to being interconnected via homologous gap junctions, these cells make extensive heterologous gap junctions with ON-cone bipolar cells (BCs). These gap junctions are the pathway for transfer of rod signals to the ON-system. To investigate the functional properties of these gap junctions, we performed simultaneous whole-cell recordings from pairs of AII amacrine cells and ON-cone bipolar cells in the in vitro slice preparation of the rat retina. We demonstrate strong electrical coupling with symmetrical junction conductance (approximately 1.2 nS) and very low steady-state voltage sensitivity. However, signal transmission is more effective in the direction from AII amacrine cells to ON-cone bipolar cells than in the other direction. This functional rectification can be explained by a corresponding difference in membrane input resistance between the two cell types. Signal transmission has low-pass filter characteristics with increasing attenuation and phase shift for increasing stimulus frequency. Action potentials in AII amacrine cells evoke distinct electrical postsynaptic potentials in ON-cone bipolar cells. Strong and temporally precise synchronization of subthreshold membrane potential fluctuations are commonly observed.

Published

2002

43. Synchronization of Motor Neurons during Locomotion in the Neonatal Rat: Predictors and Mechanisms

Author

Ole Kiehn and Matthew C. Tresch

Subjects

Serotonin, N-Methylaspartate, Dopamine, Population, Action Potentials, Biology, In Vitro Techniques, Motor Activity, Biological Clocks, Synchronization (computer science), medicine, Animals, ARTICLE, education, Motor Neurons, education.field_of_study, General Neuroscience, Gap junction, Motor neuron, Spinal cord, Rats, Coupling (electronics), medicine.anatomical_structure, Electrical Synapses, nervous system, Animals, Newborn, Spinal Cord, Neuroscience, Locomotion, medicine.drug

Abstract

We describe here the robust synchronization of motor neurons at a millisecond time scale during locomotor activity in the neonatal rat. Action potential activity of motor neuron pairs was recorded extracellularly using tetrodes during locomotor activity in the in vitro neonatal rat spinal cord. Approximately 40% of motor neuron pairs recorded in the same spinal segment showed significant synchronization, with the duration of the central peak in cross-correlograms between motor neurons typically ranging between approximately 30 and 100 msec. The percentage of synchronized motor neuron pairs was considerably higher for pairs with similar locomotor-related activity and strong rhythmic modulation. We also found synchronization between the activities of different motor pools, even if located several segments apart. Such distant synchronization was abolished in the absence of chemical synapses, although local coupling between motor neurons persisted. On the other hand, both local and distant coupling between motor neurons were preserved after antagonism of gap junction coupling between motor neurons. These results demonstrate that motor neuron activity is strongly synchronized at a millisecond time scale during the production of locomotor activity in the neonatal rat. These results also demonstrate that chemical synaptic inputs, in addition to electrical synapses, contribute to this synchronization, suggesting the existence of multiple mechanisms underlying motor neuron synchronization in the neonatal rat. The fast synchronization described here might be involved in activity-dependent processes during development or in the coordination of individual motor neurons into a functional population underlying behavior.

Published

2002

44. The shaking-B(2) Mutation Disrupts Electrical Synapses in a Flight Circuit in AdultDrosophila

Author

Rodney K. Murphey and James R. Trimarchi

Subjects

Nervous system, Stimulation, Biology, Mecamylamine, medicine.disease_cause, medicine, Animals, Nervous System Physiological Phenomena, Drosophila, Motor Neurons, Mutation, Dye coupling, Afferent Pathways, Electromyography, General Neuroscience, fungi, Articles, biology.organism_classification, Electric Stimulation, Electrical Synapses, medicine.anatomical_structure, Drosophila melanogaster, nervous system, Flight, Animal, Synapses, Cholinergic, Neuroscience, medicine.drug

Abstract

Theshaking-B2mutation was used to analyze synapses between haltere afferents and a flight motoneuron in adultDrosophila. We show that the electrical synapses among many neurons in the flight circuit are disrupted inshaking-B2flies, suggesting thatshaking-Bexpression is required for electrical synapses throughout the nervous system. In wild-type flies haltere afferents are dye-coupled to the first basalar motoneuron, and stimulation of these afferents evokes electromyograms from the first basalar muscle with short latencies. Inshaking-B2flies dye coupling between haltere afferents and the motoneuron is abolished, and afferent stimulation evokes electromyograms at abnormally long latencies. Intracellular recordings from the motoneuron confirm that the site of the defect inshaking-B2flies is at the synapses between haltere afferents and the flight motoneuron. The nicotinic cholinergic antagonist mecamylamine blocks the haltere-to-flight motoneuron synapses inshaking-B2flies but does not block those synapses in wild-type flies. Together, these results show that the haltere-to-flight motoneuron synapses comprise an electrical component that requiresshaking-Band a chemical component that is likely to be cholinergic.

Published

1997

45. Activation of Group I and Group II Metabotropic Glutamate Receptors Causes LTD and LTP of Electrical Synapses in the Rat Thalamic Reticular Nucleus.

Author

Wang Z, Neely R, and Landisman CE

Subjects

Animals, Animals, Newborn, Electric Stimulation, Electrical Synapses drug effects, Excitatory Amino Acid Agents pharmacology, Female, In Vitro Techniques, Long-Term Potentiation drug effects, Long-Term Synaptic Depression drug effects, Male, Patch-Clamp Techniques, Rats, Rats, Sprague-Dawley, Electrical Synapses physiology, Long-Term Potentiation physiology, Long-Term Synaptic Depression physiology, Receptors, Metabotropic Glutamate metabolism, Thalamic Nuclei cytology

Abstract

Compared with the extensive characterization of chemical synaptic plasticity, electrical synaptic plasticity remains poorly understood. Electrical synapses are strong and prevalent among the GABAergic neurons of the rodent thalamic reticular nucleus. Using paired whole-cell recordings, we show that activation of Group I metabotropic glutamate receptors (mGluRs) induces long-term depression of electrical synapses. Conversely, activation of the Group II mGluR, mGluR3, induces long-term potentiation of electrical synapses. By testing downstream targets, we show that modifications induced by both mGluR groups converge on the same signaling cascade--adenylyl cyclase to cAMP to protein kinase A--but with opposing effects. Furthermore, the magnitude of modification is inversely correlated to baseline coupling strength. Thus, electrical synapses, like their chemical counterparts, undergo both strengthening and weakening forms of plasticity, which should play a significant role in thalamocortical function., (Copyright © 2015 the authors 0270-6474/15/337616-10$15.00/0.)

Published

2015

46. Two functionally distinct networks of gap junction-coupled inhibitory neurons in the thalamic reticular nucleus.

Author

Lee SC, Patrick SL, Richardson KA, and Connors BW

Subjects

Animals, Axons metabolism, Axons physiology, Connexins genetics, Connexins metabolism, Electrical Synapses metabolism, GABAergic Neurons cytology, GABAergic Neurons metabolism, Interneurons cytology, Interneurons metabolism, Interneurons physiology, Intralaminar Thalamic Nuclei physiology, Mice, Mice, Inbred C57BL, Neural Inhibition, Rats, Rats, Sprague-Dawley, Gap Junction delta-2 Protein, Electrical Synapses physiology, GABAergic Neurons physiology, Intralaminar Thalamic Nuclei cytology

Abstract

Gap junctions (GJs) electrically couple GABAergic neurons of the forebrain. The spatial organization of neuron clusters coupled by GJs is an important determinant of network function, yet it is poorly described for nearly all mammalian brain regions. Here we used a novel dye-coupling technique to show that GABAergic neurons in the thalamic reticular nucleus (TRN) of mice and rats form two types of GJ-coupled clusters with distinctive patterns and axonal projections. Most clusters are elongated narrowly along functional modules within the plane of the TRN, with axons that selectively inhibit local groups of relay neurons. However, some coupled clusters have neurons arrayed across the thickness of the TRN and target their axons to both first- and higher-order relay nuclei. Dye coupling was reduced, but not abolished, among cells of connexin36 knock-out mice. Our results suggest that GJs form two distinct types of inhibitory networks that correlate activity either within or across functional modules of the thalamus., (Copyright © 2014 the authors 0270-6474/14/3413170-13$15.00/0.)

Published

2014

47. Neuronal somata and extrasomal compartments play distinct roles during synapse formation between Lymnaea neurons.

Author

Xu F, Luk CC, Wiersma-Meems R, Baehre K, Herman C, Zaidi W, Wong N, and Syed NI

Subjects

Acetylcholine pharmacology, Animals, Benzophenanthridines pharmacology, Brain metabolism, Cells, Cultured, Culture Media, Conditioned pharmacology, Dendrites drug effects, Enzyme Inhibitors pharmacology, Ganglia, Invertebrate cytology, Ganglionic Blockers pharmacology, Hexamethonium pharmacology, Hydrazones pharmacology, Lymnaea cytology, Neurons drug effects, Patch-Clamp Techniques, Presynaptic Terminals drug effects, Presynaptic Terminals metabolism, Protein Transport drug effects, Receptors, Nicotinic metabolism, Synapses drug effects, Synaptic Potentials drug effects, Synaptic Potentials physiology, Dendrites physiology, Neurons cytology, Synapses classification, Synapses physiology

Abstract

Proper synapse formation is pivotal for all nervous system functions. However, the precise mechanisms remain elusive. Moreover, compared with the neuromuscular junction, steps regulating the synaptogenic program at central cholinergic synapses remain poorly defined. In this study, we identified different roles of neuronal compartments (somal vs extrasomal) in chemical and electrical synaptogenesis. Specifically, the electrically synapsed Lymnaea pedal dorsal A cluster neurons were used to study electrical synapses, whereas chemical synaptic partners, visceral dorsal 4 (presynaptic, cholinergic), and left pedal dorsal 1 (LPeD1; postsynaptic) were explored for chemical synapse formation. Neurons were cultured in a soma-soma or soma-axon configuration and synapses explored electrophysiologically. We provide the first direct evidence that electrical synapses develop in a soma-soma, but not soma-axon (removal of soma) configuration, indicating the requirement of gene transcription regulation in the somata of both synaptic partners. In addition, the soma-soma electrical coupling was contingent upon trophic factors present in Lymnaea brain-conditioned medium. Further, we demonstrate that chemical (cholinergic) synapses between soma-soma and soma-axon pairs were indistinguishable, with both exhibiting a high degree of contact site and target cell type specificity. We also provide direct evidence that presynaptic cell contact-mediated, clustering of postsynaptic cholinergic receptors at the synaptic site requires transmitter-receptor interaction, receptor internalization, and a protein kinase C-dependent lateral migration toward the contact site. This study provides novel insights into synaptogenesis between central neurons revealing both distinct and synergistic roles of cell-cell signaling and extrinsic trophic factors in executing the synaptogenic program., (Copyright © 2014 the authors 0270-6474/14/3411304-12$15.00/0.)

Published

2014

48. Insulin promotes electrical coupling between cultured sympathetic neurons

Author

Alan L. Willard, Paul H. Patterson, and Eve J. Wolinsky

Subjects

Neurons, Superior cervical ganglion, Ganglia, Sympathetic, General Neuroscience, Rodentia, Articles, Biology, Blood Physiological Phenomena, Culture Media, Electrophysiology, Tissue culture, Chemically defined medium, medicine.anatomical_structure, Electrical Synapses, Cell culture, Synapses, medicine, Animals, Insulin, Neuron, Neuroscience, Cells, Cultured, Acetylcholine, medicine.drug

Abstract

Placing neurons in tissue culture is one way to study how environmental factors affect their differentiation. Replacement of serum- supplementation of the culture medium with defined ingredients extends the experimenter's control of the culture environment; however it also introduces additional potential influences. In this report, we confirm the observation of Higgins and Burton (Higgins, D., and H. Burton (1982) Neuroscience 7:2241–2253) of increased frequency of electrical coupling in serum-free compared to serum-supplemented cultures of rat sympathetic neurons. In addition, experiments were performed to determine whether this effect results from the removal of serum or from the addition of the defined medium components to the culture environment. The results of testing individual ingredients of the defined medium recipe adapted for use on sympathetic neurons (Bottenstein, J.E., and G. H. Sato (1979) Proc. Natl. Acad. Sci. U. S. A. 76:514–517) show that insulin is capable of inducing electrical coupling in serum-free cultures. Thus, the formation of electrical synapses by sympathetic neurons can be hormonally regulated.

Published

1985

49. Formation of electrical synapses between isolated, cultured Helisoma neurons requires mutual neurite elongation

Author

SB Kater, RD Hadley, and DA Bodnar

Subjects

Nervous system, Snails, Cell Separation, Neurite elongation, Synapse, Neural Pathways, medicine, Animals, Cells, Cultured, Helisoma, Neurons, biology, General Neuroscience, Articles, biology.organism_classification, Axons, Electrophysiology, Kinetics, medicine.anatomical_structure, Electrical Synapses, nervous system, Cell culture, Synapses, Ganglia, Neuron, Non-spiking neuron, Neuroscience, Cell Division

Abstract

Our previous experiments have suggested the hypothesis that conjoint active neuronal outgrowth may be necessary for formation of new electrical synapses between identified neurons of adult Helisoma buccal ganglia. This growth dependence hypothesis now has been tested by examining the responses of individual pairs of neurons in isolation from the influences of the ganglionic environment. Isolated cell culture of identified neurons (neuron 5) showed that: (i) neurons growing in cell culture undergo a predictable sequence of morphological changes culminating in a stable morphological state (i.e., growth stops); (ii) contact between actively growing neurons in cell culture results in the formation of electrical connections, just as in ganglia; and (iii) when an actively growing neuron encounters a neuron that is morphologically stable, electrical connections do not form or are very weak, even though strong connections are made between pairs of actively growing neurons in the same culture. These results establish that processes closely associated with growth are required for formation of electrical synapses between these neurons.

Published

1985