Integration of retinal inputs by distinct collicular cell types

Animals have a diverse set of behaviors that are triggered by specific sensory stimuli, such as motion or looming. In the visual system, this process begins in the retina where the visual scene is divided into nearly 40 parallel information channels before reaching the brain. In the mouse, the superior colliculus is one of the main recipients of retinal output and it mediates tractable visually-guided behaviors such as eye movement, orienting or escaping behaviors. However, it remains unknown how visual signals from individual retinal ganglion cell types are processed by neurons in the superior colliculus to achieve specific computations relevant to behaviors.
To answer this question, we used transgenic mouse lines in which specific types of retino-recipient neurons of the superior colliculus are labeled with Cre recombinase, enabling their monitorization and manipulation. We have established a surgical procedure to record calcium transients from Cre-labeled cells using in vivo two-photon imaging during visual stimulation, and we are categorizing the visual response properties of individual collicular cell types. Using retrograde trans-synaptic viral tracing initiated from Cre-labeled collicular cell types, we have performed two-photon calcium imaging of the labeled presynaptic retinal ganglion cell network. With this approach we are relating the activity of neurons to the activity of connected neuronal networks, and evaluating the degree of convergence and divergence in retino-collicular connectivity. Our work has revealed that one of the collicular cell types examined displays at least three different types of visual responses, possibly suggesting that this cell type can be subdivided in distinct subclasses. In addition, this study disclosed a high degree of convergence in the retino-collicular projections investigated, with 10 retinal ganglion cell types projecting to a single collicular type in an 'unbiased' manner. Lastly, we have investigated the role of individual collicular cell types in a set of visual motor behaviors by ablating specific collicular cells and have identified one cell type whose ablation leads to deficits in looming behaviour, limiting the timely detection of approaching predators from above. In contrast, these cells do not seem to control orienting movements, such as head and eye movements. By linking cell types, circuits and computations, this work will provide mechanistic insight into the circuit basis for parallel processing of visual information and various visual functions in the healthy system, and could disclose novel therapeutic targets for visual motor diseases.

We have confirmed that a set of mouse lines that we had identified contain Cre recombinase labelled cells in the superficial layers of the superior colliculus, the visual layers. We investigated the morphology of these cells and we have established a protocol to image visual responses from these cells in vivo. We have confirmed that one genetically-labelled cell types that had not been investigated previously is light-sensitive and we are classifying the visual responses from a genetically-labelled cell type previously described. We have determined the downstream brain targets of several genetically-defined collicular cells and we have examined the contribution of several cell types to visual motor behaviours, having identified a narrow-field cell that is involved in escape (defensive) behavior, but not in orienting behaviours.
Further, we recorded and classified the visual responses of the presynaptic retinal network of a single collicular cell type, and our results suggest a high degree of convergence in a single collicular cell that could, therefore, cover visual processing of a wide range of stimuli. Overall, we performed most of the experiments initially proposed and keep working to complete all the experiments. We have extended some of the goals of the initial project by performing investigations that we had not proposed on our application.

This project enabled us to relate visual responses to genetically-identified cell types and to unravel connectivity principles within the visual system, advancing our understanding of how the nervous system processes sensory information. We expect to complete the experiments and data analysis and submit a research manuscript for publication in an open access high impact scientific journal in order to disseminate our research results. By advancing our understanding of the cellular networks in the healthy visual system, this project could contribute to the identification of cellular targets for therapy in visual motor disfunction.