Brain-wide mapping of neural activity controlling zebrafish exploratory locomotion.

Abstract

In the absence of salient sensory cues to guide behavior, animals must still execute sequences of motor actions in order to forage and explore. How such successive motor actions are coordinated to form global locomotion trajectories is unknown. We mapped the structure of larval zebrafish swim trajectories in homogeneous environments and found that trajectories were characterized by alternating sequences of repeated turns to the left and to the right. Using whole-brain light-sheet imaging, we identified activity relating to the behavior in specific neural populations that we termed the anterior rhombencephalic turning region (ARTR). ARTR perturbations biased swim direction and reduced the dependence of turn direction on turn history, indicating that the ARTR is part of a network generating the temporal correlations in turn direction. We also find suggestive evidence for ARTR mutual inhibition and ARTR projections to premotor neurons. Finally, simulations suggest the observed turn sequences may underlie efficient exploration of local environments.

Department

Description

Provenance

Citation

Published Version (Please cite this version)

10.7554/elife.12741

Publication Info

Dunn, Timothy W, Yu Mu, Sujatha Narayan, Owen Randlett, Eva A Naumann, Eva A Naumann, Chao-Tsung Yang, Alexander F Schier, et al. (2016). Brain-wide mapping of neural activity controlling zebrafish exploratory locomotion. eLife, 5(MARCH2016). p. e12741. 10.7554/elife.12741 Retrieved from https://hdl.handle.net/10161/17284.

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Scholars@Duke

Dunn

Timothy Dunn

Assistant Professor of Biomedical Engineering
Naumann

Eva Aimable Naumann

Assistant Professor of Neurobiology

Education

University of Konstanz, MSc, Biology

Harvard University/Ludwig Maximillian University, Ph.D., Neurobiology

Marie Curie Postdoctoral Fellow, University College London

Postdoctoral Fellow, Harvard University Center for Brain Sciences

The Naumann lab's goal is to understand how neural circuits across the entire brain guide behavior and how individuality manifests within these circuits. To dissect such circuits, we use the genetically accessible, translucent zebrafish to map, monitor, and manipulate neuronal activity. By combining whole-brain imaging, behavioral analysis, functional perturbations, neuroanatomy, we aim to generate brain-scale circuit models of simple behaviors in individual brains. 


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