Functional connectomics reveals general wiring rule in mouse visual cortex.
Zhuokun DingPaul G FaheyStelios PapadopoulosEric Y WangBrendan CeliiChristos PapadopoulosAlexander B KuninAndersen ChangJiakun FuZhiwei DingSaumil PatelKayla PonderJ Alexander BaeAgnes L BodorDerrick BrittainJoAnn BuchananDaniel J BumbargerManuel A CastroErick CobosSven DorkenwaldLeila ElabbadyAkhilesh HalageriZhen JiaChris JordanDan KapnerNico KemnitzSam KinnKisuk LeeKai LiRan LuThomas MacrinaGayathri MahalingamEric MitchellShanka Subhra MondalShang MuBarak NehoranSergiy PopovychCasey M Schneider-MizellWilliam M SilversmithMarc M TakenoRussel TorresNicholas L TurnerWilliam WongJingpeng WuWenjing YinSzi-Chieh YuEmmanouil FroudarakisFabian H SinzH Sebastian SeungForrest CollmanNuno Maçarico da CostaR Clay ReidEdgar Y WalkerXaq PitkowJacob ReimerAndreas Savas ToliasPublished in: bioRxiv : the preprint server for biology (2023)
To understand how the neocortex underlies our ability to perceive, think, and act, it is important to study the relationship between circuit connectivity and function. Previous research has shown that excitatory neurons in layer 2/3 of the primary visual cortex of mice with similar response properties are more likely to form connections. However, technical challenges of combining synaptic connectivity and functional measurements have limited these studies to few, highly local connections. Utilizing the millimeter scale and nanometer resolution of the MICrONS dataset, we studied the connectivity-function relationship in excitatory neurons of the mouse visual cortex across interlaminar and interarea projections, assessing connection selectivity at the coarse axon trajectory and fine synaptic formation levels. A digital twin model of this mouse, that accurately predicted responses to arbitrary video stimuli, enabled a comprehensive characterization of the function of neurons. We found that neurons with highly correlated responses to natural videos tended to be connected with each other, not only within the same cortical area but also across multiple layers and visual areas, including feedforward and feedback connections, whereas we did not find that orientation preference predicted connectivity. The digital twin model separated each neuron's tuning into a feature component (what the neuron responds to) and a spatial component (where the neuron's receptive field is located). We show that the feature, but not the spatial component, predicted which neurons were connected at the fine synaptic scale. Together, our results demonstrate the "like-to-like" connectivity rule generalizes to multiple connection types, and the rich MICrONS dataset is suitable to further refine a mechanistic understanding of circuit structure and function.