Connectomic comparison of mouse and human cortex

Sahil Loomba; Jakob Straehle; Vijayan Gangadharan; Natalie Heike; Abdelrahman Khalifa; Alessandro Motta; Niansheng Ju; Meike Sievers; Jens Gempt; Hanno S. Meyer; Moritz Helmstaedter

doi:10.1126/science.abo0924

Connectomic comparison of mouse and human cortex

Sahil Loomba, Jakob Straehle, Vijayan Gangadharan, Natalie Heike, Abdelrahman Khalifa, Alessandro Motta, Niansheng Ju, Meike Sievers, Jens Gempt, Hanno S. Meyer, Moritz Helmstaedter

Department of Neurosurgery

Research output: Contribution to journal › Article › peer-review

100 Scopus citations

Abstract

The human cerebral cortex houses 1000 times more neurons than that of the cerebral cortex of a mouse, but the possible differences in synaptic circuits between these species are still poorly understood. We used three-dimensional electron microscopy of mouse, macaque, and human cortical samples to study their cell type composition and synaptic circuit architecture. The 2.5-fold increase in interneurons in humans compared with mice was compensated by a change in axonal connection probabilities and therefore did not yield a commensurate increase in inhibitory-versus-excitatory synaptic input balance on human pyramidal cells. Rather, increased inhibition created an expanded interneuron-to-interneuron network, driven by an expansion of interneuron-targeting interneuron types and an increase in their synaptic selectivity for interneuron innervation. These constitute key neuronal network alterations in the human cortex.

Original language	English
Article number	eabo0924
Journal	Science
Volume	377
Issue number	6602
DOIs	https://doi.org/10.1126/science.abo0924
State	Published - 8 Jul 2022

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AU - Loomba, Sahil

AU - Straehle, Jakob

AU - Gangadharan, Vijayan

AU - Heike, Natalie

AU - Khalifa, Abdelrahman

AU - Motta, Alessandro

AU - Ju, Niansheng

AU - Sievers, Meike

AU - Gempt, Jens

AU - Meyer, Hanno S.

AU - Helmstaedter, Moritz

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AB - The human cerebral cortex houses 1000 times more neurons than that of the cerebral cortex of a mouse, but the possible differences in synaptic circuits between these species are still poorly understood. We used three-dimensional electron microscopy of mouse, macaque, and human cortical samples to study their cell type composition and synaptic circuit architecture. The 2.5-fold increase in interneurons in humans compared with mice was compensated by a change in axonal connection probabilities and therefore did not yield a commensurate increase in inhibitory-versus-excitatory synaptic input balance on human pyramidal cells. Rather, increased inhibition created an expanded interneuron-to-interneuron network, driven by an expansion of interneuron-targeting interneuron types and an increase in their synaptic selectivity for interneuron innervation. These constitute key neuronal network alterations in the human cortex.

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Connectomic comparison of mouse and human cortex

Abstract

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