Electrical compartmentalization in neurons (Wybo et al 2019)

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"The dendritic tree of neurons plays an important role in information processing in the brain. While it is thought that dendrites require independent subunits to perform most of their computations, it is still not understood how they compartmentalize into functional subunits. Here, we show how these subunits can be deduced from the properties of dendrites. We devised a formalism that links the dendritic arborization to an impedance-based tree graph and show how the topology of this graph reveals independent subunits. This analysis reveals that cooperativity between synapses decreases slowly with increasing electrical separation and thus that few independent subunits coexist. We nevertheless find that balanced inputs or shunting inhibition can modify this topology and increase the number and size of the subunits in a context-dependent manner. We also find that this dynamic recompartmentalization can enable branch-specific learning of stimulus features. Analysis of dendritic patch-clamp recording experiments confirmed our theoretical predictions."
1 . Wybo WAM, Torben-Nielsen B, Nevian T, Gewaltig MO (2019) Electrical Compartmentalization in Neurons. Cell Rep 26:1759-1773.e7 [PubMed]
Model Information (Click on a link to find other models with that property)
Model Type: Synapse; Neuron or other electrically excitable cell;
Brain Region(s)/Organism:
Cell Type(s):
Gap Junctions:
Simulation Environment: NEURON (web link to model); Python (web link to model); C or C++ program (web link to model);
Model Concept(s): Detailed Neuronal Models; Influence of Dendritic Geometry; Synaptic Integration; Synaptic Plasticity;
Implementer(s): Wybo, Willem A.M. ;
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