Abstract
Gaze stabilization compensates for movements of the head or external environment to minimize image blurring, which is critical for visually-guided behaviors. Multisensory information is used to stabilize the visual scene on the retina via the vestibulo-ocular (VOR) and optokinetic (OKR) reflexes. While the organization of neuronal circuits underlying VOR is well described across vertebrates, less is known about the contribution and evolutionary origin of the OKR circuits. Moreover, the integration of these two sensory modalities is still poorly understood. Here, we developed a novel experimental model, the isolated lamprey eye-brain-labyrinth preparation, to analyze the neuronal pathways underlying visuo-vestibular integration which allowed electrophysiological recordings while applying vestibular stimulation using a moving platform, coordinated with visual stimulation via two screens. We show that lampreys exhibit robust visuo-vestibular integration, with optokinetic information processed in the pretectum and integrated with vestibular inputs at several subcortical levels. The enhanced eye movement response to multimodal stimulation favored the vestibular response at increased velocities. The optokinetic signals can be downregulated from tectum. Additionally, saccades are present in the form of nystagmus. The lamprey represents the oldest living group of vertebrates, thus all basic components of the visuo-vestibular control of gaze were present already at the dawn of vertebrate evolution.
Competing Interest Statement
The authors have declared no competing interest.