Cell type diversity in the neocortex The ability to link molecularly identified neurons with their function during behavior requires monitoring the activity of these cell types in vivo. Condylis et al . developed a platform for population functional imaging with spatial transcriptomics. Using newly acquired transcriptomic cell census data from the Allen Institute for Brain Science, the authors studied the function of cell types in primary somatosensory cortex in mice performing a tactile working memory task. Task-related properties of both excitatory and inhibitory neurons continued to differentiate as they were segregated into increasingly discrete molecular types. A new excitatory cell type, Baz1a, formed a sensory-driven circuit hub that orchestrates local sensory processing in superficial layers of the neocortex. This approach opens new venues for exploring information processing in the brain. —PRS
Information processing in the neocortex is carried out by neuronal circuits composed of different cell types. Recent census of the neocortex using single cell transcriptomic profiling has uncovered more than 100 putative cell types which subdivide major classes of excitatory and inhibitory neurons into distinct subclasses. The extent to which this molecular classification predicts distinct functional roles during behavior is unclear. Here, we combined population recordings using two-photon calcium imaging with spatial transcriptomics using multiplexed fluorescent in situ hybridization to achieve dense functional and molecular readout of cortical circuits during behavior. We characterized task-related responses across major transcriptomic neuronal subclasses and types in layer 2/3 of primary somatosensory cortex as mice performed a tactile working memory task. We find that as neurons are segregated into increasingly discrete molecular types, their task-related properties continue to differentiate. We identify an excitatory cell type, Baz1a, that is highly driven by tactile stimuli. Baz1a neurons homeostatically maintain stimulus responsiveness during altered sensory experience and show persistent enrichment of subsets of immediately early genes including Fos. Measurements of functional and anatomical connectivity reveal that upper layer 2/3 Baz1a neurons preferentially innervate somatostatin-expressing inhibitory neurons. We propose that this connection motif reflects a sensory-driven circuit hub that orchestrates local sensory processing in superficial layers of the neocortex.
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