The synaptic architecture of layer 5 thick tufted excitatory neurons in mouse visual cortex

Agnes L. Bodor; Casey M. Schneider-Mizell; Chi Zhang; Leila Elabbady; Alex Mallen; Andi Bergeson; Derrick Brittain; Jo Ann Buchanan; Daniel J. Bumbarger; Rachel Dalley; Clare Gamlin; Emily Joyce; Daniel Kapner; Sam Kinn; Gayathri Mahalingam; Sharmishtaa Seshamani; Shelby Suckow; Marc Takeno; Russel Torres; Wenjing Yin; J. Alexander Bae; Manuel A. Castro; Sven Dorkenwald; Akhilesh Halageri; Zhen Jia; Chris Jordan; Nico Kemnitz; Kisuk Lee; Kai Li; Ran Lu; Thomas Macrina; Eric Mitchell; Shanka Subhra Mondal; Shang Mu; Barak Nehoran; Sergiy Popovych; William Silversmith; Nicholas L. Turner; Szi Chieh Yu; William Wong; Jingpeng Wu; Brendan Celii; Luke Campagnola; Stephanie C. Seeman; Tim Jarsky; Naixin Ren; Anton Arkhipov; Jacob Reimer; H. Sebastian Seung; R. Clay Reid; Forrest Collman; Nuno Maçarico da Costa

doi:10.1038/s41593-025-02004-2

The synaptic architecture of layer 5 thick tufted excitatory neurons in mouse visual cortex

Agnes L. Bodor
, Casey M. Schneider-Mizell
, Chi Zhang
, Leila Elabbady
, Alex Mallen
, Andi Bergeson
, Derrick Brittain
, Jo Ann Buchanan
, Daniel J. Bumbarger
, Rachel Dalley
, Clare Gamlin
, Emily Joyce
, Daniel Kapner
, Sam Kinn
, Gayathri Mahalingam
, Sharmishtaa Seshamani
, Shelby Suckow
, Marc Takeno
, Russel Torres
, Wenjing Yin

J. Alexander Bae, Manuel A. Castro, Sven Dorkenwald, Akhilesh Halageri, Zhen Jia, Chris Jordan, Nico Kemnitz, Kisuk Lee, Kai Li, Ran Lu, Thomas Macrina, Eric Mitchell, Shanka Subhra Mondal, Shang Mu, Barak Nehoran, Sergiy Popovych, William Silversmith, Nicholas L. Turner, Szi Chieh Yu, William Wong, Jingpeng Wu, Brendan Celii, Luke Campagnola, Stephanie C. Seeman, Tim Jarsky, Naixin Ren, Anton Arkhipov, Jacob Reimer, H. Sebastian Seung, R. Clay Reid, Forrest Collman, Nuno Maçarico da Costa

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

6 Scopus citations

Abstract

Despite significant progress in characterizing neocortical cell types, a complete understanding of the synaptic connections of individual excitatory cells remains elusive. This study investigates the connectivity of mouse visual cortex thick tufted layer 5 pyramidal cells, also known as extratelencephalic neurons (L5-ETns), using a 1 mm³ publicly available electron microscopy dataset. The analysis reveals that, in their immediate vicinity, L5-ETns primarily establish connections with a group of inhibitory cell types, which, in turn, specifically target the L5-ETns back. The most common excitatory targets of L5-ETns are layer 5 intertelencephalic neurons (L5-ITns) and layer 6 (L6) pyramidal cells, whereas synapses with other L5-ETns are less common. When L5-ETns extend their axons to other cortical regions, they tend to connect more with excitatory cells. Our results highlight a circuit motif where a subclass of excitatory cells forms a subcircuit with specific inhibitory cell types. This is achieved using a publicly available, automated approach for synapse recognition and automated cell typing, offering a framework for exploring the connectivity of other neuron types.

Original language	English (US)
Pages (from-to)	1704-1715
Number of pages	12
Journal	Nature neuroscience
Volume	28
Issue number	8
DOIs	https://doi.org/10.1038/s41593-025-02004-2
State	Published - Aug 2025

All Science Journal Classification (ASJC) codes

General Neuroscience

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10.1038/s41593-025-02004-2

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Bodor, A. L., Schneider-Mizell, C. M., Zhang, C., Elabbady, L., Mallen, A., Bergeson, A., Brittain, D., Buchanan, J. A., Bumbarger, D. J., Dalley, R., Gamlin, C., Joyce, E., Kapner, D., Kinn, S., Mahalingam, G., Seshamani, S., Suckow, S., Takeno, M., Torres, R., ... da Costa, N. M. (2025). The synaptic architecture of layer 5 thick tufted excitatory neurons in mouse visual cortex. Nature neuroscience, 28(8), 1704-1715. https://doi.org/10.1038/s41593-025-02004-2

@article{27fe46cb49fa4f3f84cfe347f2227d3c,

title = "The synaptic architecture of layer 5 thick tufted excitatory neurons in mouse visual cortex",

abstract = "Despite significant progress in characterizing neocortical cell types, a complete understanding of the synaptic connections of individual excitatory cells remains elusive. This study investigates the connectivity of mouse visual cortex thick tufted layer 5 pyramidal cells, also known as extratelencephalic neurons (L5-ETns), using a 1 mm3 publicly available electron microscopy dataset. The analysis reveals that, in their immediate vicinity, L5-ETns primarily establish connections with a group of inhibitory cell types, which, in turn, specifically target the L5-ETns back. The most common excitatory targets of L5-ETns are layer 5 intertelencephalic neurons (L5-ITns) and layer 6 (L6) pyramidal cells, whereas synapses with other L5-ETns are less common. When L5-ETns extend their axons to other cortical regions, they tend to connect more with excitatory cells. Our results highlight a circuit motif where a subclass of excitatory cells forms a subcircuit with specific inhibitory cell types. This is achieved using a publicly available, automated approach for synapse recognition and automated cell typing, offering a framework for exploring the connectivity of other neuron types.",

author = "Bodor, \{Agnes L.\} and Schneider-Mizell, \{Casey M.\} and Chi Zhang and Leila Elabbady and Alex Mallen and Andi Bergeson and Derrick Brittain and Buchanan, \{Jo Ann\} and Bumbarger, \{Daniel J.\} and Rachel Dalley and Clare Gamlin and Emily Joyce and Daniel Kapner and Sam Kinn and Gayathri Mahalingam and Sharmishtaa Seshamani and Shelby Suckow and Marc Takeno and Russel Torres and Wenjing Yin and Bae, \{J. Alexander\} and Castro, \{Manuel A.\} and Sven Dorkenwald and Akhilesh Halageri and Zhen Jia and Chris Jordan and Nico Kemnitz and Kisuk Lee and Kai Li and Ran Lu and Thomas Macrina and Eric Mitchell and Mondal, \{Shanka Subhra\} and Shang Mu and Barak Nehoran and Sergiy Popovych and William Silversmith and Turner, \{Nicholas L.\} and Yu, \{Szi Chieh\} and William Wong and Jingpeng Wu and Brendan Celii and Luke Campagnola and Seeman, \{Stephanie C.\} and Tim Jarsky and Naixin Ren and Anton Arkhipov and Jacob Reimer and Seung, \{H. Sebastian\} and Reid, \{R. Clay\} and Forrest Collman and \{da Costa\}, \{Nuno Ma{\c c}arico\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = aug,

doi = "10.1038/s41593-025-02004-2",

language = "English (US)",

volume = "28",

pages = "1704--1715",

journal = "Nature neuroscience",

issn = "1097-6256",

publisher = "Nature Research",

number = "8",

}

Bodor, AL, Schneider-Mizell, CM, Zhang, C, Elabbady, L, Mallen, A, Bergeson, A, Brittain, D, Buchanan, JA, Bumbarger, DJ, Dalley, R, Gamlin, C, Joyce, E, Kapner, D, Kinn, S, Mahalingam, G, Seshamani, S, Suckow, S, Takeno, M, Torres, R, Yin, W, Bae, JA, Castro, MA, Dorkenwald, S, Halageri, A, Jia, Z, Jordan, C, Kemnitz, N, Lee, K, Li, K , Lu, R, Macrina, T, Mitchell, E, Mondal, SS, Mu, S, Nehoran, B, Popovych, S, Silversmith, W, Turner, NL, Yu, SC, Wong, W, Wu, J, Celii, B, Campagnola, L, Seeman, SC, Jarsky, T, Ren, N, Arkhipov, A, Reimer, J, Seung, HS, Reid, RC, Collman, F & da Costa, NM 2025, 'The synaptic architecture of layer 5 thick tufted excitatory neurons in mouse visual cortex', Nature neuroscience, vol. 28, no. 8, pp. 1704-1715. https://doi.org/10.1038/s41593-025-02004-2

TY - JOUR

T1 - The synaptic architecture of layer 5 thick tufted excitatory neurons in mouse visual cortex

AU - Bodor, Agnes L.

AU - Schneider-Mizell, Casey M.

AU - Zhang, Chi

AU - Elabbady, Leila

AU - Mallen, Alex

AU - Bergeson, Andi

AU - Brittain, Derrick

AU - Buchanan, Jo Ann

AU - Bumbarger, Daniel J.

AU - Dalley, Rachel

AU - Gamlin, Clare

AU - Joyce, Emily

AU - Kapner, Daniel

AU - Kinn, Sam

AU - Mahalingam, Gayathri

AU - Seshamani, Sharmishtaa

AU - Suckow, Shelby

AU - Takeno, Marc

AU - Torres, Russel

AU - Yin, Wenjing

AU - Bae, J. Alexander

AU - Castro, Manuel A.

AU - Dorkenwald, Sven

AU - Halageri, Akhilesh

AU - Jia, Zhen

AU - Jordan, Chris

AU - Kemnitz, Nico

AU - Lee, Kisuk

AU - Li, Kai

AU - Lu, Ran

AU - Macrina, Thomas

AU - Mitchell, Eric

AU - Mondal, Shanka Subhra

AU - Mu, Shang

AU - Nehoran, Barak

AU - Popovych, Sergiy

AU - Silversmith, William

AU - Turner, Nicholas L.

AU - Yu, Szi Chieh

AU - Wong, William

AU - Wu, Jingpeng

AU - Celii, Brendan

AU - Campagnola, Luke

AU - Seeman, Stephanie C.

AU - Jarsky, Tim

AU - Ren, Naixin

AU - Arkhipov, Anton

AU - Reimer, Jacob

AU - Seung, H. Sebastian

AU - Reid, R. Clay

AU - Collman, Forrest

AU - da Costa, Nuno Maçarico

PY - 2025/8

Y1 - 2025/8

N2 - Despite significant progress in characterizing neocortical cell types, a complete understanding of the synaptic connections of individual excitatory cells remains elusive. This study investigates the connectivity of mouse visual cortex thick tufted layer 5 pyramidal cells, also known as extratelencephalic neurons (L5-ETns), using a 1 mm3 publicly available electron microscopy dataset. The analysis reveals that, in their immediate vicinity, L5-ETns primarily establish connections with a group of inhibitory cell types, which, in turn, specifically target the L5-ETns back. The most common excitatory targets of L5-ETns are layer 5 intertelencephalic neurons (L5-ITns) and layer 6 (L6) pyramidal cells, whereas synapses with other L5-ETns are less common. When L5-ETns extend their axons to other cortical regions, they tend to connect more with excitatory cells. Our results highlight a circuit motif where a subclass of excitatory cells forms a subcircuit with specific inhibitory cell types. This is achieved using a publicly available, automated approach for synapse recognition and automated cell typing, offering a framework for exploring the connectivity of other neuron types.

AB - Despite significant progress in characterizing neocortical cell types, a complete understanding of the synaptic connections of individual excitatory cells remains elusive. This study investigates the connectivity of mouse visual cortex thick tufted layer 5 pyramidal cells, also known as extratelencephalic neurons (L5-ETns), using a 1 mm3 publicly available electron microscopy dataset. The analysis reveals that, in their immediate vicinity, L5-ETns primarily establish connections with a group of inhibitory cell types, which, in turn, specifically target the L5-ETns back. The most common excitatory targets of L5-ETns are layer 5 intertelencephalic neurons (L5-ITns) and layer 6 (L6) pyramidal cells, whereas synapses with other L5-ETns are less common. When L5-ETns extend their axons to other cortical regions, they tend to connect more with excitatory cells. Our results highlight a circuit motif where a subclass of excitatory cells forms a subcircuit with specific inhibitory cell types. This is achieved using a publicly available, automated approach for synapse recognition and automated cell typing, offering a framework for exploring the connectivity of other neuron types.

UR - https://www.scopus.com/pages/publications/105012187231

UR - https://www.scopus.com/pages/publications/105012187231#tab=citedBy

U2 - 10.1038/s41593-025-02004-2

DO - 10.1038/s41593-025-02004-2

M3 - Article

C2 - 40721677

AN - SCOPUS:105012187231

SN - 1097-6256

VL - 28

SP - 1704

EP - 1715

JO - Nature neuroscience

JF - Nature neuroscience

IS - 8

ER -

The synaptic architecture of layer 5 thick tufted excitatory neurons in mouse visual cortex

Abstract

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