Gaze stabilization in mantis shrimp in response to angled stimuli

• Published in: Journal of Comparative Physiology Vol. 205; no. 4; pp. 515 - 527
• Main Authors: Daly, Ilse M., How, Martin J., Partridge, Julian C., Roberts, Nicholas W.
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.08.2019; Springer Nature B.V
• Subjects: Animal Physiology; Animals; Biomedical and Life Sciences; Circuits; Cues; Eye; Eye (anatomy); Eye movements; Eye Movements - physiology; Fixation, Ocular - physiology; Invertebrates; Life Sciences; Motion detection; Motion perception; Motion Perception - physiology; Neural networks; Neurosciences; Original Paper; Penaeidae - physiology; Shellfish; Stabilization; Stomatopoda; Vision; Visual system; Yaw; Zoology; Stomatopod; Gaze stabilisation; Optokinesis; Motion detection; Eye movements
• ISSN: 0340-7594; 1432-1351; 1432-1351
• DOI: 10.1007/s00359-019-01341-5

Gaze stabilization is a fundamental aspect of vision and almost all animals shift their eyes to compensate for any self-movement relative to the external environment. When it comes to mantis shrimp, however, the situation becomes complicated due to the complexity of their visual system and their range of eye movements. The stalked eyes of mantis shrimp can independently move left and right, and up and down, whilst simultaneously rotating about the axis of the eye stalks. Despite the large range of rotational freedom, mantis shrimp nevertheless show a stereotypical gaze stabilization response to horizontal motion of a wide-field, high-contrast stimulus. This response is often accompanied by pitch (up-down) and torsion (about the eye stalk) rotations which, surprisingly, have no effect on the performance of yaw (side-to-side) gaze stabilization. This unusual feature of mantis shrimp vision suggests that their neural circuitry for detecting motion is radially symmetric and immune to the confounding effects of torsional self-motion. In this work, we reinforce this finding, demonstrating that the yaw gaze stabilization response of the mantis shrimp is robust to the ambiguous motion cues arising from the motion of striped visual gratings in which the angle of a grating is offset from its direction of travel.