Velocity storage mechanism drives a cerebellar clock for predictive eye velocity control

Predictive motor control is ubiquitously employed in animal kingdom to achieve rapid and precise motor action. In most vertebrates large, moving visual scenes induce an optokinetic response (OKR) control of eye movements to stabilize vision. In goldfish, the OKR was found to be predictive after a pr...

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Bibliographic Details
Published in:Scientific reports 2020-04, Vol.10 (1), p.6944-6944, Article 6944
Main Authors: Miki, Shuntaro, Urase, Kohei, Baker, Robert, Hirata, Yutaka
Format: Article
Language:English
Subjects:
631/378/2617/1346
631/378/2617/1368
631/378/2629/1779
631/378/2632/1368
Animals
Brain stem
Brain Stem - physiology
Carassius auratus
Carps - metabolism
Carps - physiology
Cerebellum
Cerebellum - physiology
Eye
Eye Movements - physiology
Goldfish - metabolism
Goldfish - physiology
Humanities and Social Sciences
Motion detection
Motor task performance
multidisciplinary
Nystagmus
Nystagmus, Optokinetic - physiology
Optokinetic response
Oryzias - metabolism
Oryzias - physiology
Science
Science (multidisciplinary)
Velocity
Vestibular system
Zebrafish - metabolism
Zebrafish - physiology
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Summary:Predictive motor control is ubiquitously employed in animal kingdom to achieve rapid and precise motor action. In most vertebrates large, moving visual scenes induce an optokinetic response (OKR) control of eye movements to stabilize vision. In goldfish, the OKR was found to be predictive after a prolonged exposure to temporally periodic visual motion. A recent study showed the cerebellum necessary to acquire this predictive OKR (pOKR), but it remained unclear as to whether the cerebellum alone was sufficient. Herein we examined different fish species known to share the basic architecture of cerebellar neuronal circuitry for their ability to acquire pOKR. Carps were shown to acquire pOKR like goldfish while zebrafish and medaka did not, demonstrating the cerebellum alone not to be sufficient. Interestingly, those fish that acquired pOKR were found to exhibit long-lasting optokinetic after nystagmus (OKAN) as opposed to those that didn’t. To directly manipulate OKAN vestibular-neurectomy was performed in goldfish that severely shortened OKAN, but pOKR was acquired comparable to normal animals. These results suggest that the neuronal circuitry producing OKAN, known as the velocity storage mechanism (VSM), is required to acquire pOKR irrespective of OKAN duration. Taken together, we conclude that pOKR is acquired through recurrent cerebellum-brainstem parallel loops in which the cerebellum adjusts VSM signal flow and, in turn, receives appropriately timed eye velocity information to clock visual world motion.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-020-63641-0