Integration of optic flow into the sky compass network in the brain of the desert locust

Integration of optic flow into the sky compass network in the brain of the desert locust

Flexible orientation through any environment requires a sense of current relative heading that is updated based on self-motion. Global external cues originating from the sky or the earth‘s magnetic field and local cues provide a reference frame for the sense of direction. Locally, optic flow may inf...

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Autori principali: Zittrell, Frederick, Pabst, Kathrin, Carlomagno, Elena, Rosner, Ronny, Pegel, Uta, Endres, Dominik M., Homberg, Uwe
Natura: Articolo
Lingua:inglese
Pubblicazione: Philipps-Universität Marburg 2023
Soggetti:
central complex
desert locust
orientation
head direction
intracellular recordings
optic flow
sky compass
computational model
Tiere (Zoologie)
Zoological sciences
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Riassunto:Flexible orientation through any environment requires a sense of current relative heading that is updated based on self-motion. Global external cues originating from the sky or the earth‘s magnetic field and local cues provide a reference frame for the sense of direction. Locally, optic flow may inform about turning maneuvers, travel speed and covered distance. The central complex in the insect brain is associated with orientation behavior and largely acts as a navigation center. Visual information from global celestial cues and local landmarks are integrated in the central complex to form an internal representation of current heading. However, it is less clear how optic flow is integrated into the central-complex network. We recorded intracellularly from neurons in the locust central complex while presenting lateral grating patterns that simulated translational and rotational motion to identify these sites of integration. Certain types of central-complex neurons were sensitive to optic-flow stimulation independent of the type and direction of simulated motion. Columnar neurons innervating the noduli, paired central-complex substructures, were tuned to the direction of simulated horizontal turns. Modeling the connectivity of these neurons with a system of proposed compass neurons can account for rotation-direction specific shifts in the activity profile in the central complex corresponding to turn direction. Our model is similar but not identical to the mechanisms proposed for angular velocity integration in the navigation compass of the fly Drosophila.
Descrizione del documento:Gefördert durch den Open-Access-Publikationsfonds der UB Marburg.
DOI:10.3389/fncir.2023.1111310

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