Genetic dissection of neuornal cell types and circuits in the cerebral cortex: from transcription mechanisms to motor control - Josh Huang

Thursday, January 17, 2019

12:00 pm

Clark Center Auditorium Map

Sponsored by:
Wu Tsai Neurosciences Institute

Wu Tsai Neurosciences Institute Seminar Series Presents

Genetic dissection of neuornal cell types and circuits in the cerebral cortex: from transcription mechanisms to motor control

Z. Josh Huang, PhD

Charles Robertson Professor of Neuroscience,

Cold Spring Harbor Laboratory

Host: Ivan Soltesz


An enduring challenge in neuroscience is to decipher the cellular basis underlying the functional architecture of the cerebral cortex that processes information and guides intelligent behavior. Despite its immense cellular complexity, fundamental aspects of cortical organization (e.g., major inter-areal processing streams, output channels, and local circuit templates) are stereotypic among individuals of the same species and are conserved across mammals. These basic network scaffolds and circuit modules are implemented by a large set of cardinal types of glutamatergic projection neurons (forming myriad processing streams and output channels) and GABAergic interneurons (forming local connectivity motifs), which are reliably generated through developmental programs rooted in the genome. These first principles provide the basis for a genetic dissection of cortical organization through systematic screening and fate mapping of its major circuit elements - a successful approach to neural circuits in Drosophila and the vertebrate spinal cord. The overarching theme of my research is to understand general principles underlying the assembly and organization of cortical circuitry by integrating multi-faceted studies of neuron types in the functional context of motor control in the mouse. In this talk, I will present 1) a summary on the systematic genetic targeting of glutamatergic projection neurons and GABAergic interneurons, 2) a discovery that GABAergic neuron types can be defined by their synaptic communication properties encoded in key transcriptional signatures, 3) progress in understanding a chandelier - pyramidal neuron microcircuit module, 4) recent findings on the functional organization and developmental trajectory of distinct pyramidal neuron types in controlling dexterous forelimb-orofacial movements. 

Thursday, January 17, 2019
12:00 pm – 1:00 pm
Clark Center Auditorium Map

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