Dragonfly Neurons Selectively Attend to Targets Within Natural Scenes

Dragonfly Neurons Selectively Attend to Targets Within Natural Scenes

Aerial predators, such as the dragonfly, determine the position and movement of their prey even when both are moving through complex, natural scenes. This task is likely supported by a group of neurons in the optic lobe which respond to moving targets that subtend less than a few degrees. These Smal...

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Bibliographic Details
Published in:Frontiers in cellular neuroscience Vol. 16; p. 857071
Main Authors: Evans, Bernard John Essex, O'Carroll, David Charles, Fabian, Joseph Mahandas, Wiederman, Steven D
Format: Journal Article
Language:English
Published: Switzerland Frontiers Research Foundation 05-04-2022
Frontiers Media S.A
Subjects:
Biologi
Biological Sciences
Cellular Neuroscience
dragonfly (Anisoptera)
electrophysiology
Firing pattern
natural images (NI)
Natural Sciences
Naturvetenskap
Neurons
Optic lobe
Predators
Prey
selective attention
Velocity
vision science
Visual discrimination
Zoologi
Zoology
vision science
dragonfly (Anisoptera)
natural images (NI)
electrophysiology
selective attention
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Summary:Aerial predators, such as the dragonfly, determine the position and movement of their prey even when both are moving through complex, natural scenes. This task is likely supported by a group of neurons in the optic lobe which respond to moving targets that subtend less than a few degrees. These Small Target Motion Detector (STMD) neurons are tuned to both target size and velocity, whilst also exhibiting facilitated responses to targets traveling along continuous trajectories. When presented with a pair of targets, some STMDs generate spiking activity that represent a competitive selection of one target, as if the alternative does not exist (i.e., selective attention). Here, we describe intracellular responses of CSTMD1 (an identified STMD) to the visual presentation of targets embedded within cluttered, natural scenes. We examine CSTMD1 response changes to target contrast, as well as a range of target and background velocities. We find that background motion affects CSTMD1 responses via the competitive selection between features within the natural scene. Here, robust discrimination of our artificially embedded "target" is limited to scenarios when its velocity is matched to, or greater than, the background velocity. Additionally, the background's direction of motion affects discriminability, though not in the manner observed in STMDs of other flying insects. Our results highlight that CSTMD1's competitive responses are to those features best matched to the neuron's underlying spatiotemporal tuning, whether from the embedded target or other features in the background clutter. In many scenarios, CSTMD1 responds robustly to targets moving through cluttered scenes. However, whether this neuronal system could underlie the task of competitively selecting slow moving prey against fast-moving backgrounds remains an open question.
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Specialty section: This article was submitted to Cellular Neurophysiology, a section of the journal Frontiers in Cellular Neuroscience
Reviewed by: David Deutsch, University of Haifa, Israel; Mark A. Frye, University of California, Los Angeles, United States
Edited by: Almut Kelber, Lund University, Sweden
ISSN:1662-5102
1662-5102
DOI:10.3389/fncel.2022.857071