Optogenetic manipulation of medullary neurons in the locust optic lobe

The locust is a widely used animal model for studying sensory processing and its relation to behavior. Due to the lack of genomic information, genetic tools to manipulate neural circuits in locusts are not yet available. We examined whether Semliki Forest virus is suitable to mediate exogenous gene expression in neurons of the locust optic lobe. We subcloned a channelrhodopsin variant and the yellow fluorescent protein Venus into a Semliki Forest virus vector and injected the virus into the optic lobe of locusts ( Schistocerca americana). Fluorescence was observed in all injected optic lobes. Most neurons that expressed the recombinant proteins were located in the first two neuropils of the optic lobe, the lamina and medulla. Extracellular recordings demonstrated that laser illumination increased the firing rate of medullary neurons expressing channelrhodopsin. The optogenetic activation of the medullary neurons also triggered excitatory postsynaptic potentials and firing of a postsynaptic, looming-sensitive neuron, the lobula giant movement detector. These results indicate that Semliki Forest virus is efficient at mediating transient exogenous gene expression and provides a tool to manipulate neural circuits in the locust nervous system and likely other insects.NEW & NOTEWORTHY Using Semliki Forest virus, we efficiently delivered channelrhodopsin into neurons of the locust optic lobe. We demonstrate that laser illumination increases the firing of the medullary neurons expressing channelrhodopsin and elicits excitatory postsynaptic potentials and spiking in an identified postsynaptic target neuron, the lobula giant movement detector neuron. This technique allows the manipulation of neuronal activity in locust neural circuits using optogenetics.

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Optogenetic manipulation of medullary neurons in the locust optic lobe

10.1101/334003 ◽

2018 ◽

Author(s):

Hongxia Wang ◽

Richard B. Dewell ◽

Markus U. Ehrengruber ◽

Eran Segev ◽

Jacob Reimer ◽

...

Keyword(s):

Gene Expression ◽

Neural Circuits ◽

Optic Lobe ◽

Fluorescent Protein ◽

Semliki Forest Virus ◽

Yellow Fluorescent Protein ◽

Movement Detector ◽

Laser Illumination ◽

Exogenous Gene ◽

Medullary Neurons

AbstractLocust is a widely used animal model for studying sensory processing and its relation to behavior. Due to the lack of genomic information, genetic tools to manipulate neural circuits in locusts are not yet available. We examined whether Semliki Forest virus is suitable to mediate exogenous gene expression in neurons of the locust optic lobe. We subcloned a channelrhodopsin variant and the yellow fluorescent protein Venus into a Semliki Forest virus vector and injected the virus into the optic lobe of locusts (Schistocerca americana). Fluorescence was observed in all injected optic lobes. Most neurons that expressed the recombinant proteins were located in the first two neuropils of the optic lobe, the lamina and medulla. Extracellular recordings demonstrated that laser illumination increased the firing rate of medullary neurons expressing channelrhodopsin. The optogenetic activation of the medullary neurons also triggered firing of a postsynaptic, looming-sensitive neuron, the Lobula Giant Movement Detector (LGMD). These results indicate that Semliki Forest virus is efficient at mediating transient exogenous gene expression and provides a tool to manipulate neural circuits in the locust nervous system and likely other insects.New and NoteworthyUsing Semliki Forest virus, we efficiently delivered channelrhodopsin into neurons of the locust optic lobe. We demonstrate that laser illumination increases the firing of the medullary neurons expressing channelrhodopsin and of an identified postsynaptic target neuron, the LGMD neuron. This technique allows to manipulate the neuronal activity in locust neural circuits using optogenetics.

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Connexions Between a Movement-Detecting Visual Interneurone and Flight Motoneurones of a Locust

Journal of Experimental Biology ◽

10.1242/jeb.86.1.87 ◽

1980 ◽

Vol 86 (1) ◽

pp. 87-97

Author(s):

PETER SIMMONS

Keyword(s):

Movement Detector ◽

Excitatory Postsynaptic Potentials ◽

Schistocerca Americana ◽

Postsynaptic Potentials ◽

Contralateral Movement ◽

Contralateral Eye ◽

Stimulation Of

Both of the descending contralateral movement detector (DCMD) neurones of Schistocerca americana gregaria, which respond to stimulation of the contralateral eye or to loud noises, mediate excitatory postsynaptic potentials in most ipsilateral flight motoneurones.

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Single‐Cell Screening: Single‐Cell Immunoblotting based on a Photoclick Hydrogel Enables High‐Throughput Screening and Accurate Profiling of Exogenous Gene Expression (Adv. Mater. 22/2021)

Advanced Materials ◽

10.1002/adma.202170172 ◽

2021 ◽

Vol 33 (22) ◽

pp. 2170172

Author(s):

Shanhe Li ◽

Ze Wen ◽

Behafarid Ghalandari ◽

Tianhao Zhou ◽

Antony R. Warden ◽

...

Keyword(s):

Gene Expression ◽

Single Cell ◽

High Throughput ◽

High Throughput Screening ◽

Exogenous Gene

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Excitatory postsynaptic potentials recorded from regular-spiking cells in layers II/III of rat sensorimotor cortex

Journal of Neurophysiology ◽

10.1152/jn.1992.67.3.728 ◽

1992 ◽

Vol 67 (3) ◽

pp. 728-737 ◽

Cited By ~ 31

Author(s):

G. G. Hwa ◽

M. Avoli

Keyword(s):

Nmda Receptor Antagonist ◽

Short Latency ◽

Neuronal Membrane ◽

Dependent Manner ◽

Excitatory Postsynaptic Potentials ◽

Normal Medium ◽

Postsynaptic Potentials ◽

Extracellular Stimuli ◽

Relationship Of

1. Intracellular recording techniques were used to investigate the physiological and pharmacological properties of stimulus-induced excitatory postsynaptic potentials (EPSPs) recorded in regular-spiking cells located in layers II/III of rat sensorimotor cortical slices maintained in vitro. 2. Depending on the strength of the extracellular stimuli, a pure EPSP or an EPSP-inhibitory postsynaptic potential sequence was observed under perfusion with normal medium. The EPSPs displayed short latency of onset [2.4 +/- 0.7 (SD) ms] and were able to follow repetitive stimulation (tested less than or equal to 5 Hz). Variation of the membrane potential (Vm) revealed two types of voltage behavior for the short-latency EPSP. The first type decreased in amplitude with depolarization and increased in amplitude with hyperpolarization. In contrast, the second type behaved anomalously by increasing and decreasing in size after depolarization and hyperpolarization, respectively. 3. Several experimental procedures were carried out to investigate the mechanism underlying the anomalous voltage behavior of the EPSP. Results indicated that this type of Vm dependency could be mimicked by an intrinsic response evoked by a brief pulse of depolarizing current and could be abolished by N-(2,6-dimethylphenylcarbamoylmethyl)triethylammonium bromide (50 mM). Furthermore, the EPSP was not sensitive to the N-methyl-D-aspartate (NMDA) receptor antagonist 3-((+-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonate (CPP, 10 microM). Thus the anomalous voltage relationship of the neuronal membrane. 4. The involvement of non-NMDA receptors in excitatory synaptic transmission was investigated with their selective antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 1-10 microM). This drug greatly reduced or completely blocked the EPSP in a dose-dependent manner (1-10 microM). The IC50 for the CNQX effect was approximately 2 microM. In the presence of CNQX (10 microM) and glycine (10 microM), synaptic stimulation failed to elicit firing of action potential. However, a CPP-sensitive EPSP was observed. 5. When synaptic inhibition was reduced by low concentration of bicuculline methiodide (BMI, 1-2 microM), extracellular stimulation revealed late EPSPs (latency to onset: 10-30 ms) that were not discernible in normal medium. Similar to the short-latency EPSP, the Vm dependency displayed by this late EPSP could be modified by inward membrane rectifications. The late EPSP appeared to be polysynaptic in origin because 1) its latency of onset was long and variable and 2) it failed to follow repetitive stimuli delivered at a frequency that did not depress the short-latency EPSP.(ABSTRACT TRUNCATED AT 400 WORDS)

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Simultaneous recording of presynaptic spikes and excitatory postsynaptic potentials from monosynaptically connected hippocampal neurons

Neuroscience Letters ◽

10.1016/0304-3940(89)90481-3 ◽

1989 ◽

Vol 103 (1) ◽

pp. 34-38 ◽

Cited By ~ 5

Author(s):

Satsuki Sawada ◽

Haruyuki Kamiya ◽

Chosaburo Yamamoto

Keyword(s):

Hippocampal Neurons ◽

Simultaneous Recording ◽

Excitatory Postsynaptic Potentials ◽

Postsynaptic Potentials

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A new muscle receptor organ in the antenna of the rock lobster Palinurus vulgaris : mechanical, muscular and proprioceptive organization of the two proximal joints J0 and J1

Proceedings of the Royal Society of London Series B Biological Sciences ◽

10.1098/rspb.1983.0028 ◽

1983 ◽

Vol 218 (1210) ◽

pp. 95-110 ◽

Cited By ~ 6

Keyword(s):

Anterior Part ◽

Proximal Part ◽

The Other ◽

Chordotonal Organ ◽

Excitatory Postsynaptic Potentials ◽

Rock Lobster ◽

Postsynaptic Potentials ◽

Muscle Receptor ◽

Physiological Properties ◽

Receptor Organ

(i) Following previous work on the morphological and physiological properties of the two distal joints (J2, J3) of the atenna of the rock lobster Palinurus vulgaris , the mechanical, muscular and proprioceptive organization of the two proximal joints between the antennal segments S1 and S2 (J1) and between S1 and the cephalothorax (J0) have now been studied. (ii) Articulated by two classical condyles, J1 moves in a mediolateral plane. One external rotator muscle (ER) and three internal rotator muscles (IR1, IR2, IR3) subserve its movements. J0 is articulated by two different systems: a classical ventrolateral condyle and a complex sliding system constituted by special cuticular structures on the dorsomedial side of the S1 segment and on the rostrum between the two antennae. J0 moves in the dorsoventral plane by means of a levator muscle (Lm) and a depressor muscle (Dm). A third muscle, the lateral tractor muscle (LTm), associated with J0 and lying obliquely across S1, may modulate the level of friction between the S1 segment and the rostrum. (iii) Proprioception in J1 is achieved by a muscle receptor organ AMCO-J1 (antennal myochordotonal organ for the J1 joint) associating a small accessory muscle (S1.am) located in the proximal part of the S1 segment and a chordotonal organ inserted proximally on the S1.am muscle and distally on the S2 segment. J0 proprioception is ensured by a simple chordotonal organ (CO-J0) located in the anterior part of the cephalothorax. (iv) The S1.am muscle is innervated by three motoneurons characterized by their very small diameters and inducing respectively tonic excitatory postsynaptic potentials, phasic excitatory postsynaptic potentials and inhibitory postsynaptic potentials. Anatomical and physiological observations suggest functional correlation between S1.am and IR1 motor innervation. (v) Mechanical and muscular organization of J0 and J1 are compared with that of the other joints of the antenna. The properties of the AMCO-J1 proprioceptor are discussed in relation to the other muscle receptor organs described in crustaceans.

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