Faculty Opinions recommendation of Optic flow stimuli update anterodorsal thalamus head direction neuronal activity in rats.

Abstract Background Salmonids return to the river where they were born in a phenomenon known as mother-river migration. The underpinning of migration has been extensively examined, particularly regarding the behavioral correlations of external environmental cues such as the scent of the mother-river and geomagnetic compass. However, neuronal underpinning remains elusive, as there have been no biologging techniques suited to monitor neuronal activity in the brain of large free-swimming fish. In this study, we developed a wireless biologging system to record extracellular neuronal activity in the brains of free-swimming salmonids. Results Using this system, we recorded multiple neuronal activities from the telencephalon of trout swimming in a rectangular water tank. As proof of principle, we examined the activity statistics for extracellular spike waveforms and timing. We found cells firing maximally in response to a specific head direction, similar to the head direction cells found in the rodent brain. The results of our study suggest that the recorded signals originate from neurons. Conclusions We anticipate that our biologging system will facilitate a more detailed investigation into the neural underpinning of fish movement using internally generated information, including responses to external cues.

Download Full-text

Behavioral Correlates of Neuronal Activity Recorded as Single-Units: Promises and Pitfalls as Illustrated by the Rodent Head Direction Cell Signal

Electrophysiological Recording Techniques - Neuromethods ◽

10.1007/978-1-60327-202-5_6 ◽

2010 ◽

pp. 127-167 ◽

Cited By ~ 1

Author(s):

Robert W. Stackman

Keyword(s):

Neuronal Activity ◽

Single Units ◽

Head Direction ◽

Behavioral Correlates ◽

Head Direction Cell ◽

Cell Signal

Download Full-text

Spatial representability of neuronal activity

10.1101/2021.08.08.455535 ◽

2021 ◽

Author(s):

Danil Akhtiamov ◽

Anthony G. Cohn ◽

Yuri Alexander Dabaghian

Keyword(s):

Visual Field ◽

Neuronal Activity ◽

Place Cells ◽

Configuration Spaces ◽

Trial And Error ◽

Head Direction ◽

Head Direction Cells ◽

Spiking Activity

A common approach to interpreting spiking activity is based on identifying the firing fields---regions in physical or configuration spaces that elicit responses of neurons. Common examples include hippocampal place cells that fire at preferred locations in the navigated environment, head direction cells that fire at preferred orientations of the animal's head, view cells that respond to preferred spots in the visual field, etc. In all these cases, firing fields were discovered empirically, by trial and error. We argue that the existence and a number of properties of the firing fields can be established theoretically, through topological analyses of the neuronal spiking activity.

Download Full-text

Cerebellar Control of a Unitary Head Direction Sense

10.1101/2021.07.08.451624 ◽

2021 ◽

Author(s):

Mehdi Fallahnezhad ◽

Julia Le Mero ◽

Xhensjana Zenelaj ◽

Jean Vincent ◽

Christelle Rochefort ◽

...

Keyword(s):

Neuronal Activity ◽

Navigation System ◽

Brain Regions ◽

Neural Representation ◽

Head Direction ◽

Temporal Coordination ◽

Attractor Network ◽

Cell Structures ◽

Brain States ◽

The Stability

Head direction (HD) cells, key neuronal elements in the mammalian's navigation system, are hypothesized to act as a continuous attractor network, in which temporal coordination between cell members is maintained under different brain states or external sensory conditions, resembling a unitary neural representation of direction. Whether and how multiple identified HD signals in anatomically separate HD cell structures are part of a single and unique attractor network is currently unknown. By manipulating the cerebellum, we identified pairs of thalamic and retrosplenial HD cells that lose their temporal coordination in the absence of external sensory drive, while the neuronal coordination within each of these brain regions remained intact. Further, we show that distinct cerebellar mechanisms are involved in the stability of direction representation depending on external sensory conditions. These results put forward a new role for the cerebellum in mediating stable and coordinated HD neuronal activity toward a unitary thalamocortical representation of direction.

Download Full-text

Passive Transport Disrupts Directional Path Integration by Rat Head Direction Cells

Journal of Neurophysiology ◽

10.1152/jn.00346.2003 ◽

2003 ◽

Vol 90 (5) ◽

pp. 2862-2874 ◽

Cited By ~ 67

Author(s):

Robert W. Stackman ◽

Edward J. Golob ◽

Joshua P. Bassett ◽

Jeffrey S. Taube

Keyword(s):

Optic Flow ◽

Path Integration ◽

Efference Copy ◽

The Novel ◽

Head Direction ◽

Passive Transport ◽

Novel Environment ◽

Preferred Direction ◽

Idiothetic Cues ◽

Familiar Environment

A subset of neurons in the rat limbic system encodes head direction (HD) by selectively discharging when the rat points its head in a preferred direction in the horizontal plane. The preferred firing direction is sensitive to the location of landmark cues, as well as idiothetic or self-motion cues (i.e., vestibular, motor efference copy, proprioception, and optic flow). Previous studies have shown that the preferred firing direction remains relatively stable (average shift ± 18°) after the rat walks from a familiar environment into a novel one, suggesting that without familiar landmarks, the preferred firing direction can be maintained using idiothetic cues, a process called directional path integration. This study repeated this experiment and manipulated the idiothetic cues available to the rat as it moved between the familiar and novel environment. Motor efference copy/proprioceptive cues were disrupted by passively transporting the animal between the familiar and novel environment. Darkening the room as the animal moved to the novel environment eliminated optic flow cues. HD cell preferred firing directions shifted in the novel environment by an average of 30° after locomotion from the familiar environment with the room lights off; by an average of 70° after passive transport from the familiar environment with the room lights on; and by an average of 67° after passive transport with the room lights off. These findings are consistent with the view that motor efference copy/proprioception cues are important for maintaining the preferred firing direction of HD cells under conditions requiring path integration.

Download Full-text