Defining the role of cerebellar output circuits in food-seeking behaviour

The cerebellum modulates motor learning and coordination, as well as non-motor functions such as motivation and feeding control. Lesion and perturbation in the cerebellum are linked to disruption of feeding behaviour in rodent and human studies, but details about cerebellar-mediated pathways that co...

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Main Author: Ho, Helen Shen Ting
Other Authors: Albert I. Chen
Format: Final Year Project
Language:English
Published: 2018
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Online Access:http://hdl.handle.net/10356/76193
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-761932019-12-10T12:28:14Z Defining the role of cerebellar output circuits in food-seeking behaviour Ho, Helen Shen Ting Albert I. Chen Chen Shen-Hsing Annabel School of Social Sciences DRNTU::Social sciences::Psychology The cerebellum modulates motor learning and coordination, as well as non-motor functions such as motivation and feeding control. Lesion and perturbation in the cerebellum are linked to disruption of feeding behaviour in rodent and human studies, but details about cerebellar-mediated pathways that control feeding is not well defined. The current study utilises molecular genetics and behavioural analysis in mice to examine the contribution of neuronal subpopulations of neurons in the deep cerebellar nuclei (DCN) in food-seeking behaviours and to delineate the circuit elements involved. Viral mapping of the connectivity of the DCN with extra-cerebellar regions revealed that these output neurons are indirectly linked to the arcuate nucleus of the hypothalamus, which is an important modulator of hunger responses. A major target of the DCN, zona incerta, receives cerebellar input and then project to the arcuate nucleus. To examine the functional relevance of this pathway, we have employed a chemogenetic strategy in mice to selectively and acutely manipulate the activity of DCN neurons. The activation of DCN neurons results in appetite loss and reduced food-seeking behaviour in mice, and opposite results are observed when DCN is activated. To determine whether neuronal subpopulations in the DCN differentially regulate feeding, we have correlated the feeding response of manipulated mice to subnuclei of the DCN including IntDL, Lat and IntPC. Together, we defined the connectivity and functional relevance of a pathway linking the cerebellum and hypothalamus, and provide insight into how perturbation of a cerebellar output circuit could lead to disrupted feeding behaviour. Bachelor of Arts in Psychology 2018-11-27T09:05:48Z 2018-11-27T09:05:48Z 2018 Final Year Project (FYP) http://hdl.handle.net/10356/76193 en 42 p. application/pdf
institution Nanyang Technological University
building NTU Library
country Singapore
collection DR-NTU
language English
topic DRNTU::Social sciences::Psychology
spellingShingle DRNTU::Social sciences::Psychology
Ho, Helen Shen Ting
Defining the role of cerebellar output circuits in food-seeking behaviour
description The cerebellum modulates motor learning and coordination, as well as non-motor functions such as motivation and feeding control. Lesion and perturbation in the cerebellum are linked to disruption of feeding behaviour in rodent and human studies, but details about cerebellar-mediated pathways that control feeding is not well defined. The current study utilises molecular genetics and behavioural analysis in mice to examine the contribution of neuronal subpopulations of neurons in the deep cerebellar nuclei (DCN) in food-seeking behaviours and to delineate the circuit elements involved. Viral mapping of the connectivity of the DCN with extra-cerebellar regions revealed that these output neurons are indirectly linked to the arcuate nucleus of the hypothalamus, which is an important modulator of hunger responses. A major target of the DCN, zona incerta, receives cerebellar input and then project to the arcuate nucleus. To examine the functional relevance of this pathway, we have employed a chemogenetic strategy in mice to selectively and acutely manipulate the activity of DCN neurons. The activation of DCN neurons results in appetite loss and reduced food-seeking behaviour in mice, and opposite results are observed when DCN is activated. To determine whether neuronal subpopulations in the DCN differentially regulate feeding, we have correlated the feeding response of manipulated mice to subnuclei of the DCN including IntDL, Lat and IntPC. Together, we defined the connectivity and functional relevance of a pathway linking the cerebellum and hypothalamus, and provide insight into how perturbation of a cerebellar output circuit could lead to disrupted feeding behaviour.
author2 Albert I. Chen
author_facet Albert I. Chen
Ho, Helen Shen Ting
format Final Year Project
author Ho, Helen Shen Ting
author_sort Ho, Helen Shen Ting
title Defining the role of cerebellar output circuits in food-seeking behaviour
title_short Defining the role of cerebellar output circuits in food-seeking behaviour
title_full Defining the role of cerebellar output circuits in food-seeking behaviour
title_fullStr Defining the role of cerebellar output circuits in food-seeking behaviour
title_full_unstemmed Defining the role of cerebellar output circuits in food-seeking behaviour
title_sort defining the role of cerebellar output circuits in food-seeking behaviour
publishDate 2018
url http://hdl.handle.net/10356/76193
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