An unsupervised map of excitatory neuron dendritic morphology in the mouse visual cortex

Marissa A. Weis; Stelios Papadopoulos; Laura Hansel; Timo Lüddecke; Brendan Celii; Paul G. Fahey; Eric Y. Wang; J. Alexander Bae; Agnes L. Bodor; Derrick Brittain; Jo Ann Buchanan; Daniel J. Bumbarger; Manuel A. Castro; Forrest Collman; Nuno Maçarico da Costa; Sven Dorkenwald; Leila Elabbady; Akhilesh Halageri; Zhen Jia; Chris Jordan; Dan Kapner; Nico Kemnitz; Sam Kinn; Kisuk Lee; Kai Li; Ran Lu; Thomas Macrina; Gayathri Mahalingam; Eric Mitchell; Shanka Subhra Mondal; Shang Mu; Barak Nehoran; Sergiy Popovych; R. Clay Reid; Casey M. Schneider-Mizell; H. Sebastian Seung; William Silversmith; Marc Takeno; Russel Torres; Nicholas L. Turner; William Wong; Jingpeng Wu; Wenjing Yin; Szi Chieh Yu; Jacob Reimer; Philipp Berens; Andreas S. Tolias; Alexander S. Ecker

doi:10.1038/s41467-025-58763-w

An unsupervised map of excitatory neuron dendritic morphology in the mouse visual cortex

Marissa A. Weis, Stelios Papadopoulos, Laura Hansel, Timo Lüddecke, Brendan Celii, Paul G. Fahey, Eric Y. Wang, J. Alexander Bae, Agnes L. Bodor, Derrick Brittain, Jo Ann Buchanan, Daniel J. Bumbarger, Manuel A. Castro, Forrest Collman, Nuno Maçarico da Costa, Sven Dorkenwald, Leila Elabbady, Akhilesh Halageri, Zhen Jia, Chris JordanDan Kapner, Nico Kemnitz, Sam Kinn, Kisuk Lee, Kai Li, Ran Lu, Thomas Macrina, Gayathri Mahalingam, Eric Mitchell, Shanka Subhra Mondal, Shang Mu, Barak Nehoran, Sergiy Popovych, R. Clay Reid, Casey M. Schneider-Mizell, H. Sebastian Seung, William Silversmith, Marc Takeno, Russel Torres, Nicholas L. Turner, William Wong, Jingpeng Wu, Wenjing Yin, Szi Chieh Yu, Jacob Reimer, Philipp Berens, Andreas S. Tolias, Alexander S. Ecker

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

2 Scopus citations

Abstract

Neurons in the neocortex exhibit astonishing morphological diversity, which is critical for properly wiring neural circuits and giving neurons their functional properties. However, the organizational principles underlying this morphological diversity remain an open question. Here, we took a data-driven approach using graph-based machine learning methods to obtain a low-dimensional morphological “bar code” describing more than 30,000 excitatory neurons in mouse visual areas V1, AL, and RL that were reconstructed from the millimeter scale MICrONS serial-section electron microscopy volume. Contrary to previous classifications into discrete morphological types (m-types), our data-driven approach suggests that the morphological landscape of cortical excitatory neurons is better described as a continuum, with a few notable exceptions in layers 5 and 6. Dendritic morphologies in layers 2–3 exhibited a trend towards a decreasing width of the dendritic arbor and a smaller tuft with increasing cortical depth. Inter-area differences were most evident in layer 4, where V1 contained more atufted neurons than higher visual areas. Moreover, we discovered neurons in V1 on the border to layer 5, which avoided deeper layers with their dendrites. In summary, we suggest that excitatory neurons’ morphological diversity is better understood by considering axes of variation than using distinct m-types.

Original language	English (US)
Article number	3361
Journal	Nature communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-58763-w
State	Published - Dec 2025

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/s41467-025-58763-w

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Weis, M. A., Papadopoulos, S., Hansel, L., Lüddecke, T., Celii, B., Fahey, P. G., Wang, E. Y., Bae, J. A., Bodor, A. L., Brittain, D., Buchanan, J. A., Bumbarger, D. J., Castro, M. A., Collman, F., da Costa, N. M., Dorkenwald, S., Elabbady, L., Halageri, A., Jia, Z., ... Ecker, A. S. (2025). An unsupervised map of excitatory neuron dendritic morphology in the mouse visual cortex. Nature communications, 16(1), Article 3361. https://doi.org/10.1038/s41467-025-58763-w

@article{ee9595077dc04940a0a67cbb732e9e04,

title = "An unsupervised map of excitatory neuron dendritic morphology in the mouse visual cortex",

abstract = "Neurons in the neocortex exhibit astonishing morphological diversity, which is critical for properly wiring neural circuits and giving neurons their functional properties. However, the organizational principles underlying this morphological diversity remain an open question. Here, we took a data-driven approach using graph-based machine learning methods to obtain a low-dimensional morphological “bar code” describing more than 30,000 excitatory neurons in mouse visual areas V1, AL, and RL that were reconstructed from the millimeter scale MICrONS serial-section electron microscopy volume. Contrary to previous classifications into discrete morphological types (m-types), our data-driven approach suggests that the morphological landscape of cortical excitatory neurons is better described as a continuum, with a few notable exceptions in layers 5 and 6. Dendritic morphologies in layers 2–3 exhibited a trend towards a decreasing width of the dendritic arbor and a smaller tuft with increasing cortical depth. Inter-area differences were most evident in layer 4, where V1 contained more atufted neurons than higher visual areas. Moreover, we discovered neurons in V1 on the border to layer 5, which avoided deeper layers with their dendrites. In summary, we suggest that excitatory neurons{\textquoteright} morphological diversity is better understood by considering axes of variation than using distinct m-types.",

author = "Weis, {Marissa A.} and Stelios Papadopoulos and Laura Hansel and Timo L{\"u}ddecke and Brendan Celii and Fahey, {Paul G.} and Wang, {Eric Y.} and Bae, {J. Alexander} and Bodor, {Agnes L.} and Derrick Brittain and Buchanan, {Jo Ann} and Bumbarger, {Daniel J.} and Castro, {Manuel A.} and Forrest Collman and {da Costa}, {Nuno Ma{\c c}arico} and Sven Dorkenwald and Leila Elabbady and Akhilesh Halageri and Zhen Jia and Chris Jordan and Dan Kapner and Nico Kemnitz and Sam Kinn and Kisuk Lee and Kai Li and Ran Lu and Thomas Macrina and Gayathri Mahalingam and Eric Mitchell and Mondal, {Shanka Subhra} and Shang Mu and Barak Nehoran and Sergiy Popovych and Reid, {R. Clay} and Schneider-Mizell, {Casey M.} and Seung, {H. Sebastian} and William Silversmith and Marc Takeno and Russel Torres and Turner, {Nicholas L.} and William Wong and Jingpeng Wu and Wenjing Yin and Yu, {Szi Chieh} and Jacob Reimer and Philipp Berens and Tolias, {Andreas S.} and Ecker, {Alexander S.}",

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

year = "2025",

month = dec,

doi = "10.1038/s41467-025-58763-w",

language = "English (US)",

volume = "16",

journal = "Nature communications",

issn = "2041-1723",

publisher = "Nature Research",

number = "1",

}

Weis, MA, Papadopoulos, S, Hansel, L, Lüddecke, T, Celii, B, Fahey, PG, Wang, EY, Bae, JA, Bodor, AL, Brittain, D, Buchanan, JA, Bumbarger, DJ, Castro, MA, Collman, F, da Costa, NM, Dorkenwald, S, Elabbady, L, Halageri, A, Jia, Z, Jordan, C, Kapner, D, Kemnitz, N, Kinn, S, Lee, K, Li, K , Lu, R, Macrina, T, Mahalingam, G, Mitchell, E, Mondal, SS, Mu, S, Nehoran, B, Popovych, S, Reid, RC, Schneider-Mizell, CM, Seung, HS, Silversmith, W, Takeno, M, Torres, R, Turner, NL, Wong, W, Wu, J, Yin, W, Yu, SC, Reimer, J, Berens, P, Tolias, AS & Ecker, AS 2025, 'An unsupervised map of excitatory neuron dendritic morphology in the mouse visual cortex', Nature communications, vol. 16, no. 1, 3361. https://doi.org/10.1038/s41467-025-58763-w

TY - JOUR

T1 - An unsupervised map of excitatory neuron dendritic morphology in the mouse visual cortex

AU - Weis, Marissa A.

AU - Papadopoulos, Stelios

AU - Hansel, Laura

AU - Lüddecke, Timo

AU - Celii, Brendan

AU - Fahey, Paul G.

AU - Wang, Eric Y.

AU - Bae, J. Alexander

AU - Bodor, Agnes L.

AU - Brittain, Derrick

AU - Buchanan, Jo Ann

AU - Bumbarger, Daniel J.

AU - Castro, Manuel A.

AU - Collman, Forrest

AU - da Costa, Nuno Maçarico

AU - Dorkenwald, Sven

AU - Elabbady, Leila

AU - Halageri, Akhilesh

AU - Jia, Zhen

AU - Jordan, Chris

AU - Kapner, Dan

AU - Kemnitz, Nico

AU - Kinn, Sam

AU - Lee, Kisuk

AU - Li, Kai

AU - Lu, Ran

AU - Macrina, Thomas

AU - Mahalingam, Gayathri

AU - Mitchell, Eric

AU - Mondal, Shanka Subhra

AU - Mu, Shang

AU - Nehoran, Barak

AU - Popovych, Sergiy

AU - Reid, R. Clay

AU - Schneider-Mizell, Casey M.

AU - Seung, H. Sebastian

AU - Silversmith, William

AU - Takeno, Marc

AU - Torres, Russel

AU - Turner, Nicholas L.

AU - Wong, William

AU - Wu, Jingpeng

AU - Yin, Wenjing

AU - Yu, Szi Chieh

AU - Reimer, Jacob

AU - Berens, Philipp

AU - Tolias, Andreas S.

AU - Ecker, Alexander S.

PY - 2025/12

Y1 - 2025/12

N2 - Neurons in the neocortex exhibit astonishing morphological diversity, which is critical for properly wiring neural circuits and giving neurons their functional properties. However, the organizational principles underlying this morphological diversity remain an open question. Here, we took a data-driven approach using graph-based machine learning methods to obtain a low-dimensional morphological “bar code” describing more than 30,000 excitatory neurons in mouse visual areas V1, AL, and RL that were reconstructed from the millimeter scale MICrONS serial-section electron microscopy volume. Contrary to previous classifications into discrete morphological types (m-types), our data-driven approach suggests that the morphological landscape of cortical excitatory neurons is better described as a continuum, with a few notable exceptions in layers 5 and 6. Dendritic morphologies in layers 2–3 exhibited a trend towards a decreasing width of the dendritic arbor and a smaller tuft with increasing cortical depth. Inter-area differences were most evident in layer 4, where V1 contained more atufted neurons than higher visual areas. Moreover, we discovered neurons in V1 on the border to layer 5, which avoided deeper layers with their dendrites. In summary, we suggest that excitatory neurons’ morphological diversity is better understood by considering axes of variation than using distinct m-types.

AB - Neurons in the neocortex exhibit astonishing morphological diversity, which is critical for properly wiring neural circuits and giving neurons their functional properties. However, the organizational principles underlying this morphological diversity remain an open question. Here, we took a data-driven approach using graph-based machine learning methods to obtain a low-dimensional morphological “bar code” describing more than 30,000 excitatory neurons in mouse visual areas V1, AL, and RL that were reconstructed from the millimeter scale MICrONS serial-section electron microscopy volume. Contrary to previous classifications into discrete morphological types (m-types), our data-driven approach suggests that the morphological landscape of cortical excitatory neurons is better described as a continuum, with a few notable exceptions in layers 5 and 6. Dendritic morphologies in layers 2–3 exhibited a trend towards a decreasing width of the dendritic arbor and a smaller tuft with increasing cortical depth. Inter-area differences were most evident in layer 4, where V1 contained more atufted neurons than higher visual areas. Moreover, we discovered neurons in V1 on the border to layer 5, which avoided deeper layers with their dendrites. In summary, we suggest that excitatory neurons’ morphological diversity is better understood by considering axes of variation than using distinct m-types.

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U2 - 10.1038/s41467-025-58763-w

DO - 10.1038/s41467-025-58763-w

M3 - Article

C2 - 40204760

AN - SCOPUS:105002983106

SN - 2041-1723

VL - 16

JO - Nature communications

JF - Nature communications

IS - 1

M1 - 3361

ER -

An unsupervised map of excitatory neuron dendritic morphology in the mouse visual cortex

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