Len Cleary scite author profile

1. The tail withdrawal reflex is mediated by a monosynaptic circuit composed of tail sensory and motor neurons, but there appear to be additional neuronal elements that also contribute to the reflex. A newly identified interneuron, called LP117, was located in the pleural ganglion. This neuron formed a parallel excitatory pathway between sensory and motor neurons. The distinguishing feature of LP117 was its ability to elicit a long-lasting (5-100 s) excitatory postsynaptic potential (EPSP) in the motor neuron. 2. Intracellular labeling of LP117 revealed axons projecting to the cerebral and abdominal as well as the pedal ganglia. Simultaneous intracellular recordings confirmed the widely divergent output of LP117 to tentacle motor neurons in the cerebral ganglion, as well as to gill, siphon, and ink motor neurons in the abdominal ganglion. 3. Also receiving input were abdominal neurons L29, which excites LFs motor neurons and facilitates LE sensory neurons, and L25, which is part of the pattern-generating network underlying respiratory pumping. Thus LP117 appears to be a neural element important for the conduction of information about tail stimulation to ganglia that are not innervated by tail sensory neurons themselves. Moreover, the divergent outputs suggest that LP117 is an element of a neural circuit underlying defensive arousal. 4. LP117 produced slow EPSPs in several motor neurons. The long time course of the EPSP could prolong the burst in the motor neuron produced by LP117 itself as well as increase the effectiveness of coincident synaptic input. This suggests that an important function of this interneuron is to extend the duration of the response to tail stimulation in the motor neuron. This could account for the relatively long time course of the motor neuron response to tail stimulation compared with that of the sensory neuron. 5. Sensitization is a form of nonassociative learning that produces changes in the amplitude and duration of reflex responses. It seems unlikely that all of these changes can be attributed to enhanced amplitude of the sensory-motor synapse, however. Therefore LP117 may itself be a site of plasticity for reflexes elicited by tail stimulation.

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Long-term structural remodeling in Aplysia sensory neurons requires de novo protein synthesis during a critical time period

O'Leary

Byrne

Cleary

1995

J. Neurosci.

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Long-term sensitization training induces persistent changes in both electrophysiological properties and specific structural features of sensory neurons in Aplysia californica. Previously, we found that transient elevation of intracellular cAMP could also modify these features in sensory neurons located in the pleural ganglion. In the present study we examined the role of protein synthesis in structural remodeling induced by cAMP. When applied during the intracellular injection of cAMP, anisomycin blocked increases in both the number of varicosities and the number of branch points in single sensory neurons. Exposure to anisomycin during different time periods, from as early as 12 hr prior to cAMP injection to periods as late as 15 hr after, indicated that the requirement for protein synthesis starts at the time of cAMP injection and extends for at least seven hours afterwards. Because it is metabolized rapidly, cAMP probably triggers a cascade of protein synthesis whose products continue to be synthesized for several hours after cAMP levels have returned to baseline. Thus, the present results suggest that the induction of long-term structural changes in sensory neurons has an extended but finite requirement for protein synthesis.

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Inositol trisphosphate and activators of protein kinase C modulate membrane currents in tail motor neurons of Aplysia

Sawada

Cleary

Byrne

1989

Journal of Neurophysiology

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1. We have investigated how activation of the inositol lipid second messenger pathway may contribute to modulation of membrane currents in tail motor neurons of Aplysia. Specifically, we examined the effects of injected inositol 1,4,5-trisphosphate (IP3) and analogues of diacylglycerol (DAG), both of which are products of the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2). 2. Injection of IP3 produced an outward current associated with an apparent increase in membrane conductance. Ion substitution experiments, the sensitivity of the response to low concentrations of TEA and its attenuation by intracellular injections of EGTA suggest that the current produced by injection of IP3 is a calcium-activated K+ current (IK,Ca). 3. The response to IP3 was mimicked by intracellular injection of Ca2+. Injection of Ca2+ produced an outward current that was associated with an apparent increase in input conductance of the membrane. The same manipulations that affected the response to IP3 (see above) also affected the response to injections of Ca2+. 4. Injections of activators of protein kinase C (PKC) produced a relatively slow inward current. The inward current has not been fully analyzed, but it does not appear to be due to the actions of any single conventional ion channel. 5. Activators of PKC attenuated responses to subsequent injections of IP3 indicating that one component of PIP2 hydrolysis can attenuate the other. 6. The results suggest that hydrolysis of inositol phospholipids is a mechanism for regulation of membrane properties in tail motor neurons of Aplysia.

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Neural Mechanisms Underlying Sensitization of a Defensive Reflex in Aplysia

Cleary¹,

Baxter²,

Nazif³

et al. 1991

The Biological Bulletin

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Len Cleary

Role of interneurons in defensive withdrawal reflexes in Aplysia.

Identification and characterization of a multifunction neuron contributing to defensive arousal in Aplysia

Long-term structural remodeling in Aplysia sensory neurons requires de novo protein synthesis during a critical time period

Inositol trisphosphate and activators of protein kinase C modulate membrane currents in tail motor neurons of Aplysia

Neural Mechanisms Underlying Sensitization of a Defensive Reflex in Aplysia

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