Eye movements in chameleons are not truly independent – evidence from simultaneous monocular tracking of two targets

Katz, Hadas Ketter; Lustig, Avichai; Lev-Ari, Tidhar; Nov, Yuval; Rivlin, Ehud; Katzir, Gadi

doi:10.1242/jeb.113084

Cited by 17 publications

(8 citation statements)

References 37 publications

(61 reference statements)

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“…Thus, the stable relative alignment of the two eyes during approach likely reflects stabilization of the head itself. While several species with laterally-placed eyes use convergent eye movements during prey capture to create a wider binocular field [16][17][18][19] , our results show that mice do not utilize this strategy during prey capture. These results suggest that the 40 degree binocular zone is sufficient for tracking centrally located objects.…”

Section: Discussionmentioning

confidence: 65%

“…How then do animals with laterally placed eyes target prey directly in front of them, especially when these targets can rapidly move in and out of the narrow binocular field? This could require the ability to modulate the amount of binocular overlap, through directed lateral eye movements, to generate a wider binocular field, such as in the case of cuttlefish [16] , fish [17] , many birds [18] , and chameleons [19] . In fact, these animals specifically rotate their eyes inward before striking prey, thereby creating a larger binocular zone.…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of gaze control during prey capture in freely moving mice

Michaiel

Abe

Niell

2020

Preprint

102

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Many studies of visual processing are conducted in unnatural conditions, such as head-and gaze-fixation.As this radically limits natural exploration of the visual environment, there is much less known about how animals actively use their sensory systems to acquire visual information in natural, goal-directed contexts.Recently, prey capture has emerged as an ethologically relevant behavior that mice perform without training, and that engages vision for accurate orienting and pursuit. However, it is unclear how mice target their gaze during such natural behaviors, particularly since, in contrast to many predatory species, mice have a narrow binocular field and lack foveate vision that would entail fixing their gaze on a specific point in the visual field. Here we measured head and bilateral eye movements in freely moving mice performing prey capture. We find that the majority of eye movements are compensatory for head movements, thereby acting to stabilize the visual scene. During head turns, however, these periods of stabilization are interspersed with non-compensatory saccades that abruptly shift gaze position. Analysis of eye movements relative to the cricket position shows that the saccades do not preferentially select a specific point in the visual scene. Rather, orienting movements are driven by the head, with the eyes following in coordination to sequentially stabilize and recenter the gaze. These findings help relate eye movements in the mouse to other species, and provide a foundation for studying active vision during ethological behaviors in the mouse.

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Section: Discussionmentioning

confidence: 65%

Section: Introductionmentioning

confidence: 99%

Dynamics of gaze control during prey capture in freely moving mice

Michaiel

Abe

Niell

2020

Preprint

102

View full text Add to dashboard Cite

show abstract

“…How then do animals with laterally placed eyes target prey directly in front of them, especially when these targets can rapidly move in and out of the narrow binocular field? This could require the modulation of the amount of binocular overlap, through directed lateral eye movements, to generate a wider binocular field, such as in the case of cuttlefish ( Feord et al, 2020 ), fish ( Bianco et al, 2011 ), many birds ( Martin, 2009 ), and chameleons ( Katz et al, 2015 ). In fact, these animals specifically rotate their eyes nasally before striking prey, thereby creating a larger binocular zone.…”

Section: Introductionmentioning

confidence: 99%

Dynamics of gaze control during prey capture in freely moving mice

Michaiel

Abe

Niell

2020

eLife

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Many studies of visual processing are conducted in constrained conditions such as head- and gaze-fixation, and therefore less is known about how animals actively acquire visual information in natural contexts. To determine how mice target their gaze during natural behavior, we measured head and bilateral eye movements in mice performing prey capture, an ethological behavior that engages vision. We found that the majority of eye movements are compensatory for head movements, thereby serving to stabilize the visual scene. During movement, however, periods of stabilization are interspersed with non-compensatory saccades that abruptly shift gaze position. Notably, these saccades do not preferentially target the prey location. Rather, orienting movements are driven by the head, with the eyes following in coordination to sequentially stabilize and recenter the gaze. These findings relate eye movements in the mouse to other species, and provide a foundation for studying active vision during ethological behaviors in the mouse.

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“…The high degree of similarity of the fovea and the horizontal streak among the six species studied here suggests that these are conserved topographic features of the retina across ecological niches and that they are likely shared by other Ctenophorus species. While independent eye movements in chameleons (Hews, Castellano, & Hara, ; Watt & Joss, ) and the lateralization of visually mediated behaviors in lizards has received some attention (Katz et al, ; Ott, ), the relevance of specific retinal regions and therefore the regions of the visual field which they subtend remains poorly understood. This novel information on the topographic specialization of neuron density in the retina of Ctenophorus species provides a solid anatomical foundation for future behavioral experiments exploring visually mediated behaviors across the visual field.…”

Section: Discussionmentioning

confidence: 99%

Retinal topography and microhabitat diversity in a group of dragon lizards

Nagloo

Coimbra

Hoops

et al. 2019

J of Comparative Neurology

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The well‐studied phylogeny and ecology of dragon lizards and their range of visually mediated behaviors provide an opportunity to examine the factors that shape retinal organization. Dragon lizards consist of three evolutionarily stable groups based on their shelter type, including burrows, shrubs, and rocks. This allows us to test whether microhabitat changes are reflected in their retinal organization. We examined the retinae of three burrowing species (Ctenophorus pictus, C. gibba, and C. nuchalis), and three species that shelter in rock crevices (C. ornatus, C. decresii, and C. vadnappa). We used design‐based stereology to sample both the photoreceptor array and neurons within the retinal ganglion cell layer to estimate areas specialized for acute vision. All species had two retinal specializations mediating enhanced spatial acuity: a fovea in the retinal center and a visual streak across the retinal equator. Furthermore, all species featured a dorsoventrally asymmetric photoreceptor distribution with higher photoreceptor densities in the ventral retina. This dorsoventral asymmetry may provide greater spatial summation of visual information in the dorsal visual field. Burrow‐dwelling species had significantly larger eyes, higher total numbers of retinal cells, higher photoreceptor densities in the ventral retina, and higher spatial resolving power than rock‐dwelling species. C. pictus, a secondary burrow‐dwelling species, was the only species that changed burrow usage over evolutionary time, and its retinal organization revealed features more similar to rock‐dwelling species than other burrow‐dwelling species. This suggests that phylogeny may play a substantial role in shaping retinal organization in Ctenophorus species compared to microhabitat occupation.

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Eye movements in chameleons are not truly independent – evidence from simultaneous monocular tracking of two targets

Cited by 17 publications

References 37 publications

Dynamics of gaze control during prey capture in freely moving mice

Dynamics of gaze control during prey capture in freely moving mice

Dynamics of gaze control during prey capture in freely moving mice

Retinal topography and microhabitat diversity in a group of dragon lizards

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