Voluntary exercise is motivated by ghrelin, possibly related to the central reward circuit.

Hiroharu Mifune,Yuji Tajiri,Kento Hara,Takahiro Sato,Yusuke Sakai,Masayasu Kojima,Yoshihiro Nishi,Yukie Kawahara,Ryouichi Mitsuzono,Akinori Nishi,Tatsuyuki Kakuma

doi:10.1530/joe-19-0213

Abstract

We previously reported that voluntary exercise contributed to the amelioration of abnormal feeding behavior with a concomitant restoration of ghrelin production in a rat model of obesity, suggesting a possible relationship between exercise and appetite-regulating hormones. Ghrelin is known to be involved in the brain reward circuits via dopamine neurons related to motivational properties. We investigated the relevance of ghrelin as an initiator of voluntary exercise as well as feeding behavior. The plasma ghrelin concentration fluctuates throughout the day with its peak at the beginning of the dark period in the wild-type (WT) mice with voluntary exercise. Although predominant increases in wheel running activity were observed accordant to the peak of plasma ghrelin concentration in the WT mice, those were severely attenuated in the ghrelin-knockout (GKO) mice under either ad libitum or time-restricted feeding. A single injection of ghrelin receptor agonist brought about and reproduced a marked enhancement of wheel running activity, in contrast to no effect by the continuous administration of the same drug. Brain dopamine levels (DAs) were enhanced after food consumption in the WT mice under voluntary exercise. Although the acceleration of DAs were apparently blunted in the GKO mice, they were dramatically revived after the administration of ghrelin receptor agonist, suggesting the relevance of ghrelin in the reward circuit under voluntary exercise. These findings emphasize that the surge of ghrelin plays a crucial role in the formation of motivation for the initiation of voluntary exercise possibly related to the central dopamine system.

Highlights

It is well known that exercise in itself has several benefits in terms of health and fitness (Patterson & Levin 2008, HaskellLuevano et al 2009), as well as neural and cognitive effects (Cotman & Engesser-Cesar 2002), in both humans and laboratory animals
The total amount of voluntary exercise activity during dark period was markedly reduced in GKO-Ex mice compared to that in WT-Ex mice (Fig. 2C)
Voluntary exercise activity was dominantly observed at the beginning of the dark period and was severely attenuated in GKO mice under ad libitum feeding

Summary

Introduction

It is well known that exercise in itself has several benefits in terms of health and fitness (Patterson & Levin 2008, HaskellLuevano et al 2009), as well as neural and cognitive effects (Cotman & Engesser-Cesar 2002), in both humans and laboratory animals. Food restriction and regular exercise are the two major established strategies for the prevention and treatment of obesity, which is currently recognized as a serious burden throughout the world. 244:1 is often associated with physical inactivity and disrupted life rhythms, including binge and night eating (Marcus & Wildes 2014), which makes the treatment of obesity more complicated and weight reduction less attainable. Exercise is recommended for the purpose of weight reduction through the increment of energy expenditure, it is generally difficult for most obese subjects to continue regular exercise for long periods of time. It is important to explore the putative mechanisms for producing the motivation to perform and adhere to exercise, especially in obese subjects

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