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Integrating EM and Patch-seq data: Synaptic connectivity and target specificity of predicted Sst transcriptomic types.

Clare R GamlinCasey M Schneider-MizellMatthew MalloryLeila ElabbadyNathan W GouwensG WilliamsMukora AliceRachel DalleyAgnes L BodorDerrick BrittainJoAnn BuchananD BumbargerD KapnerSam KinnGayathri MahalingamSharmishtaa SeshamaniMarc M TakenoRussel M TorresW YinPhilip R NicovichJ Alexander BaeM A CastroSven DorkenwaldA HalageriZ JiaC JordanNico KemnitzK LeeK LiR LuThomas MacrinaE MitchellS S MondalS MuBarak NehoranS PopovychWilliam M SilversmithNicholas L TurnerW WongJingpeng WuS YuJim BergTim JarskyB LeeH Sebastian SeungHongkui ZengR Clay ReidForrest C CollmanNuno Maçarico da CostaStaci A Sorensen
Published in: bioRxiv : the preprint server for biology (2023)
Neural circuit function is shaped both by the cell types that comprise the circuit and the connections between those cell types 1 . Neural cell types have previously been defined by morphology 2, 3 , electrophysiology 4, 5 , transcriptomic expression 6-8 , connectivity 9-13 , or even a combination of such modalities 14-16 . More recently, the Patch-seq technique has enabled the characterization of morphology (M), electrophysiology (E), and transcriptomic (T) properties from individual cells 17-20 . Using this technique, these properties were integrated to define 28, inhibitory multimodal, MET-types in mouse primary visual cortex 21 . It is unknown how these MET-types connect within the broader cortical circuitry however. Here we show that we can predict the MET-type identity of inhibitory cells within a large-scale electron microscopy (EM) dataset and these MET-types have distinct ultrastructural features and synapse connectivity patterns. We found that EM Martinotti cells, a well defined morphological cell type 22, 23 known to be Somatostatin positive (Sst+) 24, 25 , were successfully predicted to belong to Sst+ MET-types. Each identified MET-type had distinct axon myelination patterns and synapsed onto specific excitatory targets. Our results demonstrate that morphological features can be used to link cell type identities across imaging modalities, which enables further comparison of connectivity in relation to transcriptomic or electrophysiological properties. Furthermore, our results show that MET-types have distinct connectivity patterns, supporting the use of MET-types and connectivity to meaningfully define cell types.
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