| Project Detail |
Mapping connectivity of neuronal networks for cognition Intelligent behaviour relies on internal models for simulation and planning, with place and grid cells in the hippocampal-entorhinal system forming cognitive maps of environments. Recent discoveries of numerous place cells in the zebrafish telencephalon have advanced understanding of these mechanisms. The ERC-funded COGNECTOMICS project will employ volume electron microscopy and transcriptomic profiling to map neural connectivity at the synaptic level in small brains. It will study how interactions among specific neuron subsets contribute to the functional properties of place cells and how network structures influence population activity. The project will also examine the development and maturation of neuronal circuits and investigate the role of cognitive maps in behaviours linked to internally generated predictions. Intelligent behavior is based on internal models of the world that enable mental simulations and strategic planning. A leading model to study such “cognitive maps” are networks of place cells and grid cells in the mammalian hippocampal-entorhinal system. These neurons are active at defined locations and collectively represent a physical environment as a low-dimensional topographic map in neural activity space. However, a mechanistic understanding of the underlying computations and their biological implementation remains elusive. Using new methods for brain-wide activity imaging during behavior, members of our team discovered an abundance of place cells in the telencephalon of zebrafish. We will combine this approach with volume electron microscopy to reconstruct large-scale connectivity in the same brains at synaptic resolution and with transcriptomic profiling to identify molecular cell types, taking advantage of small brain size. The joint analysis of network connectivity and population dynamics will allow us to determine how functional properties of place cells are established by interactions between specific subsets of neurons across brain areas, and how network structure constrains population activity to topographically organized attractor manifolds. The results will disambiguate computational models that make conflicting assumptions about network connectivity. We will further explore the emergence of cell types during development and the concomitant structural and functional maturation of neuronal circuits. The relevance of cognitive maps for neuronal computations and behaviors involving internally generated predictions will be explored by activity measurements in a virtual reality and by functional manipulations of genetically targeted neurons. Capitalizing on the unique combination of expertise among team members, this project is expected to fundamentally advance our mechanistic understanding of biological and potentially artificial intelligence. |
