Neural mechanisms of grouping behavior Restricted; Files Only

Abstract

Highly social, group-living species have the ability to accomplish impressive feats. For many species, including humans, interactions with groups occur on a daily basis. Behaviors that may be exhibited during group interactions can range from affiliative to aggressive or cooperative to simply tolerant. For this dissertation, grouping behavior is broadly defined as any type of behavior that occurs in groups, focusing not only on the behavior of the group as a whole unit but also on individuals within the group. Although there are numerous species that live in large groups, we know surprisingly little about the neurobiological mechanisms underlying grouping behaviors in mammalian species. We can further our understanding of why and how animals display the dazzling array of grouping behaviors we observe in the wild by examining how neural mechanisms facilitates basic drives such as the preference to affiliate with large groups and the ability to exhibit social recognition. To study mammalian grouping behavior and relevant underlying neural mechanisms, I used the spiny mouse (Acomys dimidiatus). I have previously shown that spiny mice prefer affiliating in large groups, indiscriminately approach any conspecific, regardless of context, and exhibit high degrees of prosociality and low levels of aggression. In this dissertation, I examine how neural mechanisms facilitate the preference to affiliate with a large group as well as how these circuits allow an animal to distinguish between different types of conspecifics within a group. In Chapter 1 I use immediate early gene studies, neural tracing techniques, and circuit-specific chemogenetic manipulations to identify a neural circuit involved in the modulation of peer group size preferences. In Chapter 2 I then examine differences in spiny mice behavior with distinct types or conspecifics and neural processing of kinship and familiarity during dyadic interactions. Together, this body of work provides new insight to a growing field on the neuroscience of grouping behavior.

Table of Contents

General Introduction. 11

References. 15

1      CHAPTER I. Cingulate to septal circuitry facilitates the preference to affiliate with large peer groups. 20

Summary. 21

Introduction. 22

Results. 24

Discussion. 41

STAR Methods. 45

KEY RESOURCES TABLE. 51

Supplementary Material 52

References. 59

2      CHAPTER II. Biased brain and behavioral responses towards kin in males of a communally breeding species. 71

Author’s contribution and acknowledgement of reproduction. 72

Abstract 73

Introduction. 74

Results. 77

Discussion. 85

Materials and methods. 92

Supplementary Materials. 98

References. 101

General Discussion. 114

Summary of Findings. 115

Social Context influences grouping behavior. 116

The lateral septum bridges social recognition and group preferences. 117

Conclusion. 118

References 118

About this Dissertation

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School	Laney Graduate School
Department	Psychology
Subfield / Discipline	Neuroscience and Animal Behavior
Degree	Ph.D.
Submission	Dissertation
Language	English
Research Field	Biology, Neuroscience
Stichwort	Grouping Behavior Spiny Mice Anterior Cingulate Cortex Lateral Septum
Committee Chair / Thesis Advisor	Dr. Aubrey Kelly, Emory University
Committee Members	Dr. Malavika Murugan, Emory University Dr. Daniel Dilks, Emory University Dr. Donna Maney, Emory University Dr. Joseph Manns, Emory University

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