Connecting single-cell transcriptomes to projectomes in mouse visual cortex.
Staci A SorensenNathan W GouwensYun WangMatthew MalloryAgata BudzilloRachel DalleyBrian LeeOlga GlikoHsien-Chi KuoXiuli KuangRusty MannLeila AhmadiniaLauren AlfilerFahimeh BaftizadehKatherine BakerSarah BannickDarren BertagnolliKris BickleyPhil BohnDillan BrownJasmine BombenKrissy BrounerChao ChenKai ChenMaggie ChvilicekForrest C CollmanTanya L DaigleTim DawesRebecca de FratesNick DeeMaxwell DeParteeTom EgdorfLaila El-HifnawiRachel EnstromChristina KouskoutiColin FarrellRohan GalaAndrew GlombClare R GamlinAmanda GaryJeff GoldyHong GuKristen HadleyMichael J HawrylyczAlex HenryDiJon HillKarla E HirokawaZili HuangKatelyn JohnsonZoe JuneauSara KebedeLisa KimChangkyu LeePhil LesnarAnan LiAndrew GlombYaoyao LiElizabeth LiangKatie LinkMichelle MaxwellMedea McGrawDelissa A McMillenMukora AliceLindsay NgThomas OchoaAaron OldreDaniel ParkChristina Alice PomZoran PopovichLydia PotekhinaRam RajanbabuShea RansfordMelissa RedingAugustin RuizDavid SandmanLa' Akea SivertsKimberly A SmithMichelle StoecklinJosef SulcMichael TieuJonathan T TingJessica TrinhSara VargasDave VumbacoMiranda WalkerMicheal WangAdrian Andreas WannerJack WatersGrace WilliamsJulia WilsonWei XiongEd S LeinJim BergBrian E KalmbachShenqin YaoHui GongQingming LuoLydia NgUygar SümbülTim JarskyZizhen YaoBosiljka TasicHongkui ZengPublished in: bioRxiv : the preprint server for biology (2023)
The mammalian brain is composed of diverse neuron types that play different functional roles. Recent single-cell RNA sequencing approaches have led to a whole brain taxonomy of transcriptomically-defined cell types, yet cell type definitions that include multiple cellular properties can offer additional insights into a neuron's role in brain circuits. While the Patch-seq method can investigate how transcriptomic properties relate to the local morphological and electrophysiological properties of cell types, linking transcriptomic identities to long-range projections is a major unresolved challenge. To address this, we collected coordinated Patch-seq and whole brain morphology data sets of excitatory neurons in mouse visual cortex. From the Patch-seq data, we defined 16 integrated morpho-electric-transcriptomic (MET)-types; in parallel, we reconstructed the complete morphologies of 300 neurons. We unified the two data sets with a multi-step classifier, to integrate cell type assignments and interrogate cross-modality relationships. We find that transcriptomic variations within and across MET-types correspond with morphological and electrophysiological phenotypes. In addition, this variation, along with the anatomical location of the cell, can be used to predict the projection targets of individual neurons. We also shed new light on infragranular cell types and circuits, including cell-type-specific, interhemispheric projections. With this approach, we establish a comprehensive, integrated taxonomy of excitatory neuron types in mouse visual cortex and create a system for integrated, high-dimensional cell type classification that can be extended to the whole brain and potentially across species.