Author
Listed:
- Tommas J. Ellender
(University of Oxford)
- Sophie V. Avery
(University of Oxford)
- Kashif Mahfooz
(University of Oxford)
- Jakub Scaber
(MRC Weatherall Institute of Molecular Medicine)
- Alexander Klemperer
(University of Oxford)
- Sophie L. Nixon
(University of Oxford)
- Matthew J. Buchan
(University of Oxford)
- Joram J. Rheede
(University of Oxford)
- Aleksandra Gatti
(University of Oxford)
- Cameron Waites
(University of Oxford)
- Hania J. Pavlou
(MRC Weatherall Institute of Molecular Medicine)
- David Sims
(MRC Weatherall Institute of Molecular Medicine)
- Sarah E. Newey
(University of Oxford)
- Colin J. Akerman
(University of Oxford)
Abstract
The mammalian neocortex is characterized by a variety of neuronal cell types and precise arrangements of synaptic connections, but the processes that generate this diversity are poorly understood. Here we examine how a pool of embryonic progenitor cells consisting of apical intermediate progenitors (aIPs) contribute to diversity within the upper layers of mouse cortex. In utero labeling combined with single-cell RNA-sequencing reveals that aIPs can generate transcriptionally defined glutamatergic cell types, when compared to neighboring neurons born from other embryonic progenitor pools. Whilst sharing layer-associated morphological and functional properties, simultaneous patch clamp recordings and optogenetic studies reveal that aIP-derived neurons exhibit systematic biases in both their intralaminar monosynaptic connectivity and the post-synaptic partners that they target within deeper layers of cortex. Multiple cortical progenitor pools therefore represent an important factor in establishing diversity amongst local and long-range fine-scale glutamatergic connectivity, which generates subnetworks for routing excitatory synaptic information.
Suggested Citation
Tommas J. Ellender & Sophie V. Avery & Kashif Mahfooz & Jakub Scaber & Alexander Klemperer & Sophie L. Nixon & Matthew J. Buchan & Joram J. Rheede & Aleksandra Gatti & Cameron Waites & Hania J. Pavlou, 2019.
"Embryonic progenitor pools generate diversity in fine-scale excitatory cortical subnetworks,"
Nature Communications, Nature, vol. 10(1), pages 1-16, December.
Handle:
RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-13206-1
DOI: 10.1038/s41467-019-13206-1
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