Aplysia Locomotion: Network and Behavioral Actions of GdFFD, a D-Amino Acid-Containing Neuropeptide.

Chao-Yu Yang,Elizabeth C Cropper,Ye Wang,Ting-Ting Chen,Jonathan V Sweedler,Ke Yu,Jian Jing,Yan-Nan Su,Itamar Livnat,Klaudiusz R Weiss,Ferdinand S Vilim,Dan-Dan Liu,Shao-Zhong Yang,Song-An Chen,Zheng-Yang Wang,Riccardo Mozzachiodi

doi:10.1371/journal.pone.0147335

Abstract

One emerging principle is that neuromodulators, such as neuropeptides, regulate multiple behaviors, particularly motivated behaviors, e.g., feeding and locomotion. However, how neuromodulators act on multiple neural networks to exert their actions remains poorly understood. These actions depend on the chemical form of the peptide, e.g., an alternation of L- to D- form of an amino acid can endow the peptide with bioactivity, as is the case for the Aplysia peptide GdFFD (where dF indicates D-phenylalanine). GdFFD has been shown to act as an extrinsic neuromodulator in the feeding network, while the all L-amino acid form, GFFD, was not bioactive. Given that both GdFFD/GFFD are also present in pedal neurons that mediate locomotion, we sought to determine whether they impact locomotion. We first examined effects of both peptides on isolated ganglia, and monitored fictive programs using the parapedal commissural nerve (PPCN). Indeed, GdFFD was bioactive and GFFD was not. GdFFD increased the frequency with which neural activity was observed in the PPCN. In part, there was an increase in bursting spiking activity that resembled fictive locomotion. Additionally, there was significant activity between bursts. To determine how the peptide-induced activity in the isolated CNS is translated into behavior, we recorded animal movements, and developed a computer program to automatically track the animal and calculate the path of movement and velocity of locomotion. We found that GdFFD significantly reduced locomotion and induced a foot curl. These data suggest that the increase in PPCN activity observed in the isolated CNS during GdFFD application corresponds to a reduction, rather than an increase, in locomotion. In contrast, GFFD had no effect. Thus, our study suggests that GdFFD may act as an intrinsic neuromodulator in the Aplysia locomotor network. More generally, our study indicates that physiological and behavioral analyses should be combined to evaluate peptide actions.

Highlights

Expression of most, if not all, behaviors is regulated by neuromodulators, such as neuropeptides [1]
Previous work has shown that pedal ganglia contain the central pattern generator for locomotion [29,30,31], and the cerebral ganglion contains command-like and modulatory neurons that can influence the expression of locomotor activity [40, 41]
The locomotor activity was monitored by parapedal commissural nerve (PPCN or P10) that innervates the posterior part of the foot, and was shown previously to exhibit bursting activity in phase with locomotion, and apparently represents motoneuronal activity [29,30,31, 41,42,43] (Figs 4A, 5A and 6A)

Summary

Introduction

Expression of most, if not all, behaviors is regulated by neuromodulators, such as neuropeptides [1]. Prior research entails evaluating actions of neuromodulators in a single neural circuit. Neuromodulators often affect multiple behaviors [4, 5, 10,11,12,13]. It is poorly understood how a neuromodulator may act in distinct neural circuits to affect more than one behavior. We sought to examine actions of neuropeptide GdFFD on Aplysia locomotor network. GdFFD has been previously shown to act as an extrinsic neuromodulator in the feeding network [27]

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Results

Discussion

Conclusion