Cortical activity is tightly regulated to support adaptive behavior, but the mechanisms underlying this regulation are unclear. In this project, we will investigate how cortical activity is regulated in vivo, directly at the site of synaptic input Dendrites actively process synaptic input using voltage-gated ion channels and NMDA receptors. We recently showed that these mechanisms support dendritic spiking in awake mice. These dendritic spikes propagate to the soma as depolarizations that can trigger conventional axonal spikes, and thus represent a layer of computational processing that contributes to neuronal selectivity. A recently elucidated circuit motif involving neuromodulation and dendrite-targeting interneurons could play a key role in regulating dendritic spiking during sensory processing and behavior. Here, we use dendritic patch clamp recordings, optogenetics, and new multiphoton imaging technology to interrogate this circuit motif, its effects on dendritic spiking, and its activity during sensory processing and behavior. Since dendritic spiking is an essential component of synaptic integration in cortical circuitry, and dysfunctional synaptic integration is implicated in complex psychiatric and neurological disorders, results from this project can eventually contribute to new therapeutic strategies.
Many disorders of brain function result from altered cortical circuitry. It is difficult to address these diseases without a more sophisticated understanding of its functional principles. The proposed studies will elucidate mechanisms of cortical activity modulation. The results will provide cellular and circuit-level insights into mechanisms that regulate cortical circuitry during behavior, and can eventually contribute to understanding pathological brain states.
Yu, Yiyi; Hira, Riichiro; Stirman, Jeffrey N et al. (2018) Mice use robust and common strategies to discriminate natural scenes. Sci Rep 8:1379 |
Townsend, Leah B; Smith, Spencer L (2017) Genotype- and sex-dependent effects of altered Cntnap2 expression on the function of visual cortical areas. J Neurodev Disord 9:2 |
Wallace, Michael L; van Woerden, Geeske M; Elgersma, Ype et al. (2017) Ube3a loss increases excitability and blunts orientation tuning in the visual cortex of Angelman syndrome model mice. J Neurophysiol 118:634-646 |
Smith, Ikuko T; Townsend, Leah B; Huh, Ruth et al. (2017) Stream-dependent development of higher visual cortical areas. Nat Neurosci 20:200-208 |
Ji, Na; Freeman, Jeremy; Smith, Spencer L (2016) Technologies for imaging neural activity in large volumes. Nat Neurosci 19:1154-64 |
Harris, Kenneth D; Quiroga, Rodrigo Quian; Freeman, Jeremy et al. (2016) Improving data quality in neuronal population recordings. Nat Neurosci 19:1165-74 |
Stirman, Jeffrey N; Smith, Ikuko T; Kudenov, Michael W et al. (2016) Wide field-of-view, multi-region, two-photon imaging of neuronal activity in the mammalian brain. Nat Biotechnol 34:857-62 |
Stirman, Jeffrey; Townsend, Leah B; Smith, Spencer (2016) A touchscreen based global motion perception task for mice. Vision Res 127:74-83 |