Circuit Mechanisms Governing Local vs. Global Motion Processing in Mouse Visual Cortex

Rasmussen, Rune; Yonehara, Keisuke

doi:10.3389/fncir.2017.00109

Cited by 7 publications

(6 citation statements)

References 99 publications

(165 reference statements)

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“…Perception of visual motion is critical for animal survival, underlying behaviors such as visually guided navigation, pursuit of prey, and avoidance of threats. Although neurons selective for visual motion arise early in the visual system, extensive research in primates has shown that perception of coherent global motion independent of local motion relies on processing in specialized regions of visual cortex 1 , 2 . Although mouse visual cortical neurons are known to be well-tuned for coherent visual motion 3 , 4 , and vision plays an important role in navigation 5 , mesoscale cortical processing of coherent motion is poorly understood in the mouse.…”

Section: Introductionmentioning

confidence: 99%

Distributed and retinotopically asymmetric processing of coherent motion in mouse visual cortex

Sit

Goard

2020

Nat Commun

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Perception of visual motion is important for a range of ethological behaviors in mammals. In primates, specific visual cortical regions are specialized for processing of coherent visual motion. However, whether mouse visual cortex has a similar organization remains unclear, despite powerful genetic tools available for measuring population neural activity. Here, we use widefield and 2-photon calcium imaging of transgenic mice to measure mesoscale and cellular responses to coherent motion. Imaging of primary visual cortex (V1) and higher visual areas (HVAs) during presentation of natural movies and random dot kinematograms (RDKs) reveals varied responsiveness to coherent motion, with stronger responses in dorsal stream areas compared to ventral stream areas. Moreover, there is considerable anisotropy within visual areas, such that neurons representing the lower visual field are more responsive to coherent motion. These results indicate that processing of visual motion in mouse cortex is distributed heterogeneously both across and within visual areas.

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Section: Introductionmentioning

confidence: 99%

Distributed and retinotopically asymmetric processing of coherent motion in mouse visual cortex

Sit

Goard

2020

Nat Commun

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“…Accumulating evidence suggests that areas RL and A are part of the PPC in mice 15 , 16 , 17 , 18 —a key nexus of sensorimotor integration that is involved in decision making during spatial navigation, 38 the encoding of body posture, 39 global motion analysis, 40 , 41 and representations of spatial information. 42 Intriguingly, more than 50% of neurons in the RL area are multi-sensory in mice, integrating both tactile and visual sensory inputs.…”

Section: Discussionmentioning

confidence: 99%

Binocular integration of retinal motion information underlies optic flow processing by the cortex

et al. 2021

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Summary Locomotion creates various patterns of optic flow on the retina, which provide the observer with information about their movement relative to the environment. However, it is unclear how these optic flow patterns are encoded by the cortex. Here, we use two-photon calcium imaging in awake mice to systematically map monocular and binocular responses to horizontal motion in four areas of the visual cortex. We find that neurons selective to translational or rotational optic flow are abundant in higher visual areas, whereas neurons suppressed by binocular motion are more common in the primary visual cortex. Disruption of retinal direction selectivity in Frmd7 mutant mice reduces the number of translation-selective neurons in the primary visual cortex and translation- and rotation-selective neurons as well as binocular direction-selective neurons in the rostrolateral and anterior visual cortex, blurring the functional distinction between primary and higher visual areas. Thus, optic flow representations in specific areas of the visual cortex rely on binocular integration of motion information from the retina.

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“…In conclusion, our study not only yields behavioral evidence of motion integration in rodents, but also provides solid grounding for future investigations aimed at dissecting the neuronal circuits underlying integration of local motion cues into global motion percepts. In fact, as highlighted in a recent perspective (Rasmussen and Yonehara, 2017), a behavioral task involving direction discrimination of gratings and plaids is a necessary ingredient of future experiments aimed at establishing a correlational and/or causal link between patternlike responses observed in rodent visual cortex and integrated motion perception.…”

Section: Discussionmentioning

confidence: 99%

Rats spontaneously perceive global motion direction of drifting plaids

Matteucci

Zattera

Marotti

et al. 2021

Preprint

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Computing global motion direction of extended visual objects is a hallmark of primate high-level vision. Although neurons selective for global motion have also been found in mouse visual cortex, we still do not know whether rodents can combine multiple motion signals into global, integrated percepts. Here, we trained two groups of rats to discriminate motion direction of either gratings or plaids (i.e., superpositions of two gratings) and we tested whether these visual patterns were able to prime rat perception consistently with an integrated representation of plaid direction. We found that, depending on the identity of the training stimuli, rats displayed either a shared representation of gratings and plaids based on global motion, or a non-shared one. As shown by computational modeling, these findings are consistent with the existence of a population of pattern-like cells, playing a functional role similar to that demonstrated in primates.

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Circuit Mechanisms Governing Local vs. Global Motion Processing in Mouse Visual Cortex

Cited by 7 publications

References 99 publications

Distributed and retinotopically asymmetric processing of coherent motion in mouse visual cortex

Distributed and retinotopically asymmetric processing of coherent motion in mouse visual cortex

Binocular integration of retinal motion information underlies optic flow processing by the cortex

Rats spontaneously perceive global motion direction of drifting plaids

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