Abstract
Many animals use motion vision information to control dynamic behaviors. For example, flying insects must decide whether to pursue a prey or not, to avoid a predator, to maintain their current flight trajectory, or to land. The neural mechanisms underlying the computation of visual motion have been particularly well investigated in the fly optic lobes. However, the descending neurons, which connect the optic lobes with the motor command centers of the ventral nerve cord, remain less studied. To address this deficiency, we describe motion vision sensitive descending neurons in the hoverfly Eristalis tenax. We describe how the neurons can be identified based on their receptive field properties, and how they respond to moving targets, looming stimuli and to widefield optic flow. We discuss their similarities with previously published visual neurons, in the optic lobes and ventral nerve cord, and suggest that they can be classified as target-selective, looming sensitive and optic flow sensitive, based on these similarities. Our results highlight the importance of using several visual stimuli as the neurons can rarely be identified based on only one response characteristic. In addition, they provide an understanding of the neurophysiology of visual neurons that are likely to affect behavior.
Highlights
Many animals rely on visual information for their survival
We found that some descending neurons were selective to the motion of small targets crossing a small part of the visual field (Fig. 1a)
Such target-selective descending neurons (TSDNs) have previously been described in dragonflies, robberflies and hoverflies (Olberg 1981; Gonzalez-Bellido et al 2013; Nicholas et al 2018a)
Summary
Motion vision provides crucial information when navigating through the surroundings, when searching for prey, avoiding predators, defending a territory, and for a myriad of other behaviors. Even in nocturnal insects a large proportion of the brain volume is dedicated to visual processing (Stöckl et al 2016). Many insects have an anterior, cephalic brain which is largely devoted to processing sensory information, and more posterior ganglia in the thorax and abdomen, which generate the motor commands that control, e.g. neck, wing and leg movements. Ascending neurons provide sensory and motor feedback to the brain, whereas descending neurons carry sensory and motor-related information from the brain to central pattern generators in the posterior ganglia
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