Neural Correlates of Pavlovian Conditioning in Components of the Neural Network Supporting Ciliary Locomotion in Hermissenda

doi:10.1101/lm.58603

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LEARNING & MEMORY 10:209-216
©2003 by Cold Spring Harbor Laboratory Press; ISSN 1072-0502/03 $5.00

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Research Paper
Neural Correlates of Pavlovian Conditioning in Components of the Neural Network Supporting Ciliary Locomotion in Hermissenda

Terry Crow¹ and Lian-Ming Tian

Department of Neurobiology and Anatomy, University of Texas Medical School, Houston, Texas 77030

Pavlovian conditioning in Hermissenda consists of pairing light, the conditioned stimulus (CS) with activation of statocyst haircells, the unconditioned stimulus (US). Conditioning producesCS-elicited foot shortening and inhibition of light-elicitedlocomotion, the two conditioned responses (CRs). Conditioningcorrelates have been identified in the primary sensory neurons(photoreceptors) of the CS pathway, interneurons that receive monosynaptic input from identified photoreceptors, and putativepedal motor neurons. While cellular mechanisms of acquisitionproduced by the synaptic interaction between the CS and USpathways are well-documented, little is known about the mechanismsresponsible for the generation or expression of the CR. Herewe show that in conditioned animals light reduced tonic firingof ciliary activating pedal neurons (VP1) below their pre-CSbaseline levels. In contrast, pseudorandom controls expresseda significant increase in CS-elicited tonic firing of VP1 ascompared to pre-CS baseline activity. Identified interneuronsin the visual pathway that have established polysynaptic connectionswith VP1 were examined in conditioned animals and pseudorandomcontrols. Depolarization of identified type I_e interneuronswith extrinsic current elicited a significant increase in IPSPs recorded in VP1 pedal neurons of conditioned animals as comparedwith pseudorandom controls. Conditioning also enhanced intrinsicexcitability of type I_e interneurons of conditioned animalsas compared to pseudorandom controls. Light evoked a modestincrease in IPSP frequency in VP1 of conditioned preparationsand a significant decrease in IPSP frequency in VP1 of pseudorandomcontrols. Our results show that a combination of synaptic facilitationand intrinsic enhanced excitability in identified componentsof the CS pathway may explain light-elicited inhibition oflocomotion in conditioned animals.

Received January 6, 2003; accepted in revised form March 19, 2003.

Corresponding author.

^¹ EMAIL terry.crow{at}uth.tmc.edu.

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