Circuits for Action and Cognition: A View from the Superior Colliculus

Basso, Michele A.; May, Paul J.

doi:10.1146/annurev-vision-102016-061234

Cited by 305 publications

(282 citation statements)

References 220 publications

(271 reference statements)

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“…In future work, it will be also be fruitful to further explore how the cell types accessed here contribute to other natural visually-guided behaviors in the mouse such as active predator avoidance, navigation or novel object exploration (Cooper et al, 1998;Park et al, 2018) . Importantly, it is also well established that SC, particularly in higher mammals is required for more complex visuomotor and even cognitive functions, such as spatial selective attention (for recent reviews see (Basso and May, 2017;Krauzlis et al, 2013) . This study begins to clarify our understanding of SC visual processing in this context by identifying specific cell types that are differentially required for aspects of visually-guided locomotor orienting.…”

Section: Conserved Visually-guided Behaviors Supported By Specific Scmentioning

confidence: 99%

“…The SC is a laminated structure, with the superficial SC (sSC) receiving multiple sources of visual input, while the intermediate and deeper layers receive multimodal sensory input, project to a broad range of targets and provide motor output (May, 2006) . Work in rodents and other species studying the physiological properties and visual stimulus encoding of sSC cells has advanced our detailed understanding of structure-function relationships of specific neuron types in the mammalian SC (Basso and May, 2017;Cang et al, 2018;Ito and Feldheim, 2018;Oliveira and Yonehara, 2018) . In particular, the classically defined wide-field (WF) and narrow-field (NF) vertical cell types (Ramón y, Cajal S Translated by Swanson N, 1995) have distinct functional and anatomical properties that indicate they may contribute to unique aspects of early visual processing to drive natural approach behaviors.…”

Section: Introductionmentioning

confidence: 99%

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Defined cell types in superior colliculus make distinct contributions to prey capture behavior in the mouse

Hoy

Bishop

Niell

2019

Preprint

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The superior colliculus (SC) mediates rapid orienting to visual stimuli across species. To determine the specific circuits within the SC that drive orienting and approach behavior toward appetitive stimuli, we explored the role of three genetically defined cell types in mediating prey capture in mice. Chemogenetic inactivation of two classically defined cell types, the wide-field (WF) and narrow-field (NF) vertical neurons, revealed that they are involved in distinct aspects of prey capture. WF neurons were required for rapid prey detection and distant approach initiation, whereas NF neurons were required for continuous and accurate orienting during pursuit. In contrast, prey capture did not require parvalbumin-expressing (PV) neurons that have previously been implicated in fear responses. The visual coding of WF and NF cells in the awake mouse and their projection targets were consistent with their roles in prey detection versus pursuit. Thus, our studies link specific neural circuit connectivity and function with stimulus detection and orienting behavior, providing insight into visuomotor and attentional mechanisms mediated by superior colliculus. Highlights• This study provides the first demonstration of the role of specific cell populations in the superior colliculus in orienting and approach behavior.• A genetically targeted population of wide-field vertical neurons in the superior colliculus is required for rapid prey detection and initiation of long-distance approaches.• A genetically targeted population of narrow-field vertical neurons is required for approach initiation, accurate targeting, and approach continuity.• Visual response properties and projection targets of these cells are consistent with their role in prey capture, linking neural circuit connectivity and function with behavior.

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Section: Conserved Visually-guided Behaviors Supported By Specific Scmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Defined cell types in superior colliculus make distinct contributions to prey capture behavior in the mouse

Hoy

Bishop

Niell

2019

Preprint

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“…Our findings that different populations of SC neurons receive unique patterns of input argue against the view of the SCid as a simple relay and instead support the idea that intrinsic processing gives rise to SCid computations for orienting behavior. Studies examining SCid activity when multiple targets are present (Basso and Wurtz, 1997;McPeek and Keller, 2004;Li and Basso, 2005;Felsen and Mainen, 2008) support a model of SCid function whereby a "competition" takes place between two or more active foci within the colliculus (Basso and May, 2017). While this competition could simply reflect differences in the activity level of different inputs, local inhibitory connectivity within and between the two SCids (Takahashi et al, 2005(Takahashi et al, , 2007(Takahashi et al, , 2010Isa and Hall, 2009;Sooksawate et al, 2011;Ghitani et al, 2014) suggests that active intrinsic SCid processes may be at work.…”

Section: Discussionmentioning

confidence: 94%

“…The SC is critical for a wide range of functions, ranging from spatial attention to multisensory integration to adaptive behavioral responses (Dean et al, 1989;Stein and Stanford, 2008;Gandhi and Katnani, 2011;Krauzlis et al, 2013;Basso and May, 2017). Its intricate internal circuitry is organized into seven cytoarchitechtonically-defined layers composed of excitatory and inhibitory neurons each with diverse projection patterns (Edwards, 1977;Mize, 1992;Olivier et al, 1998Olivier et al, , 2000Pettit et al, 1999;Takahashi et al, 2005Takahashi et al, , 2007Takahashi et al, , 2010Isa and Hall, 2009;Sooksawate et al, 2011;Ghitani et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

“…The superior colliculus (SC) is a highly conserved midbrain structure critical for orienting behavior (Basso and May, 2017), as well as other associated functions such as spatial attention (Krauzlis et al, 2013) and multisensory integration (Stein and Stanford, 2008). The SC is organized into a superficial visual layer, which receives projections from the retina (Apter, 1945) and descending inputs from the neocortex (Kawamura et al, 1974), and intermediate and deep layers (SCid) that receive widespread input from several cortical and subcortical regions (Sparks and Hartwich-Young, 1989).…”

Section: Introductionmentioning

confidence: 99%

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Monosynaptic Inputs to Excitatory and Inhibitory Neurons of the Intermediate and Deep Layers of the Superior Colliculus

Doykos

Gilmer

Person

et al. 2019

Preprint

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The intermediate and deep layers of the midbrain superior colliculus (SC) are a key locus for several critical functions, including spatial attention, multisensory integration and behavioral responses. While the SC is known to integrate input from a variety of brain regions, progress in understanding how these inputs contribute to SC-dependent functions has been hindered by the paucity of data on innervation patterns to specific types of SC neurons. Here, we use G-deleted rabies virus-mediated monosynaptic tracing to identify inputs to excitatory and inhibitory neurons of the intermediate and deep SC. We observed stronger and more numerous projections to excitatory than inhibitory SC neurons. However, a subpopulation of excitatory neurons thought to mediate behavioral output received weaker inputs, from far fewer brain regions, than the overall population of excitatory neurons. Additionally, extrinsic inputs tended to target rostral excitatory and inhibitory SC neurons more strongly than their caudal counterparts, and commissural SC neurons tended to project to similar rostrocaudal positions in the other SC. Our findings support the view that active intrinsic processes are critical to SCdependent functions, and will enable the examination of how specific inputs contribute to these functions.

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Motor Output from the Brain and Spinal Cord

Berkowitz

2020

Encyclopedia of Life Sciences

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All skeletal muscles are controlled by activation and inhibition of motor neurons in the spinal cord and brainstem. Motor neurons integrate information from a wide variety of sources in the brain and spinal cord. Simple limb reflexes and basic patterns of limb movements, including locomotion, are coordinated by spinal cord interneurons and sensory neurons. Descending inputs from the reticular formation, the vestibular nuclei and the superior colliculus in the brainstem are important in the control of automatic, axial, postural and locomotor movements. Descending inputs from several areas of the cerebral cortex and from the red nucleus are important in the control of voluntary, distal limb and fine movements. The basal ganglia in the basal forebrain and the cerebellum in the hindbrain are involved in the modification and learning of movements. These structures act indirectly on motor output, via outputs through the thalamus to widespread areas of the cerebral cortex. Key Concepts All voluntary movements involve motor neurons in the spinal cord and brainstem that cause contraction of skeletal muscles. Neurons in many areas of the brain and spinal cord are active at overlapping times to control voluntary movements. The spinal cord can produce coordinated movements of the limbs, such as locomotion, as well as simple reflexes. The superior colliculus can trigger orienting movements, especially of the eyes and head. Voluntary limb movements involve neurons in several parts of the cerebral cortex, including especially the frontal lobe, which project axons to the spinal cord. Cortical movement control signals are modified by loops to and from the basal ganglia and the cerebellum, going through the thalamus. The basal ganglia modify the speed and amplitude of movements and contribute to learning new movement sequences. The cerebellum adapts movements to altered sensory feedback and may also contribute to a wide variety of other functions, including memory, language and emotion. Patients with movement disorders may in the future be able to control a limb or prosthetic device with ‘their thoughts’, via a brain–machine interface that monitors the activity of some of their cortical neurons.

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Circuits for Action and Cognition: A View from the Superior Colliculus

Cited by 305 publications

References 220 publications

Defined cell types in superior colliculus make distinct contributions to prey capture behavior in the mouse

Defined cell types in superior colliculus make distinct contributions to prey capture behavior in the mouse

Monosynaptic Inputs to Excitatory and Inhibitory Neurons of the Intermediate and Deep Layers of the Superior Colliculus

Motor Output from the Brain and Spinal Cord

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