Perisomatic ultrastructure efficiently classifies cells in mouse cortex

Leila Elabbady; Sharmishtaa Seshamani; Shang Mu; Gayathri Mahalingam; Casey M. Schneider-Mizell; Agnes L. Bodor; J. Alexander Bae; Derrick Brittain; Jo Ann Buchanan; Daniel J. Bumbarger; Manuel A. Castro; Sven Dorkenwald; Akhilesh Halageri; Zhen Jia; Chris Jordan; Dan Kapner; Nico Kemnitz; Sam Kinn; Kisuk Lee; Kai Li; Ran Lu; Thomas Macrina; Eric Mitchell; Shanka Subhra Mondal; Barak Nehoran; Sergiy Popovych; William Silversmith; Marc Takeno; Russel Torres; Nicholas L. Turner; William Wong; Jingpeng Wu; Wenjing Yin; Szi Chieh Yu; H. Sebastian Seung; R. Clay Reid; Nuno Maçarico da Costa; Forrest Collman

doi:10.1038/s41586-024-07765-7

Perisomatic ultrastructure efficiently classifies cells in mouse cortex

Leila Elabbady, Sharmishtaa Seshamani, Shang Mu, Gayathri Mahalingam, Casey M. Schneider-Mizell, Agnes L. Bodor, J. Alexander Bae, Derrick Brittain, Jo Ann Buchanan, Daniel J. Bumbarger, Manuel A. Castro, Sven Dorkenwald, Akhilesh Halageri, Zhen Jia, Chris Jordan, Dan Kapner, Nico Kemnitz, Sam Kinn, Kisuk Lee, Kai LiRan Lu, Thomas Macrina, Eric Mitchell, Shanka Subhra Mondal, Barak Nehoran, Sergiy Popovych, William Silversmith, Marc Takeno, Russel Torres, Nicholas L. Turner, William Wong, Jingpeng Wu, Wenjing Yin, Szi Chieh Yu, H. Sebastian Seung, R. Clay Reid, Nuno Maçarico da Costa, Forrest Collman

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

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Abstract

Mammalian neocortex contains a highly diverse set of cell types. These cell types have been mapped systematically using a variety of molecular, electrophysiological and morphological approaches^{1, 2, 3–4}. Each modality offers new perspectives on the variation of biological processes underlying cell-type specialization. Cellular-scale electron microscopy provides dense ultrastructural examination and an unbiased perspective on the subcellular organization of brain cells, including their synaptic connectivity and nanometre-scale morphology. In data that contain tens of thousands of neurons, most of which have incomplete reconstructions, identifying cell types becomes a clear challenge for analysis⁵. Here, to address this challenge, we present a systematic survey of the somatic region of all cells in a cubic millimetre of cortex using quantitative features obtained from electron microscopy. This analysis demonstrates that the perisomatic region is sufficient to identify cell types, including types defined primarily on the basis of their connectivity patterns. We then describe how this classification facilitates cell-type-specific connectivity characterization and locating cells with rare connectivity patterns in the dataset.

Original language	English (US)
Article number	4949
Pages (from-to)	478-486
Number of pages	9
Journal	Nature
Volume	640
Issue number	8058
DOIs	https://doi.org/10.1038/s41586-024-07765-7
State	Published - Apr 10 2025

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Elabbady, L., Seshamani, S., Mu, S., Mahalingam, G., Schneider-Mizell, C. M., Bodor, A. L., Bae, J. A., Brittain, D., Buchanan, J. A., Bumbarger, D. J., Castro, M. A., Dorkenwald, S., Halageri, A., Jia, Z., Jordan, C., Kapner, D., Kemnitz, N., Kinn, S., Lee, K., ... Collman, F. (2025). Perisomatic ultrastructure efficiently classifies cells in mouse cortex. Nature, 640(8058), 478-486. Article 4949. https://doi.org/10.1038/s41586-024-07765-7

@article{dbc330bcf0fc4678bd1930653027836a,

title = "Perisomatic ultrastructure efficiently classifies cells in mouse cortex",

abstract = "Mammalian neocortex contains a highly diverse set of cell types. These cell types have been mapped systematically using a variety of molecular, electrophysiological and morphological approaches1, 2, 3–4. Each modality offers new perspectives on the variation of biological processes underlying cell-type specialization. Cellular-scale electron microscopy provides dense ultrastructural examination and an unbiased perspective on the subcellular organization of brain cells, including their synaptic connectivity and nanometre-scale morphology. In data that contain tens of thousands of neurons, most of which have incomplete reconstructions, identifying cell types becomes a clear challenge for analysis5. Here, to address this challenge, we present a systematic survey of the somatic region of all cells in a cubic millimetre of cortex using quantitative features obtained from electron microscopy. This analysis demonstrates that the perisomatic region is sufficient to identify cell types, including types defined primarily on the basis of their connectivity patterns. We then describe how this classification facilitates cell-type-specific connectivity characterization and locating cells with rare connectivity patterns in the dataset.",

author = "Leila Elabbady and Sharmishtaa Seshamani and Shang Mu and Gayathri Mahalingam and Schneider-Mizell, {Casey M.} and Bodor, {Agnes L.} and Bae, {J. Alexander} and Derrick Brittain and Buchanan, {Jo Ann} and Bumbarger, {Daniel J.} and Castro, {Manuel A.} and Sven Dorkenwald 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 Eric Mitchell and Mondal, {Shanka Subhra} and Barak Nehoran and Sergiy Popovych 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 Seung, {H. Sebastian} and Reid, {R. Clay} and {da Costa}, {Nuno Ma{\c c}arico} and Forrest Collman",

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

year = "2025",

month = apr,

day = "10",

doi = "10.1038/s41586-024-07765-7",

language = "English (US)",

volume = "640",

pages = "478--486",

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Elabbady, L, Seshamani, S, Mu, S, Mahalingam, G, Schneider-Mizell, CM, Bodor, AL, Bae, JA, Brittain, D, Buchanan, JA, Bumbarger, DJ, Castro, MA, Dorkenwald, S, Halageri, A, Jia, Z, Jordan, C, Kapner, D, Kemnitz, N, Kinn, S, Lee, K, Li, K , Lu, R, Macrina, T, Mitchell, E, Mondal, SS, Nehoran, B, Popovych, S, Silversmith, W, Takeno, M, Torres, R, Turner, NL, Wong, W, Wu, J, Yin, W, Yu, SC, Seung, HS, Reid, RC, da Costa, NM & Collman, F 2025, 'Perisomatic ultrastructure efficiently classifies cells in mouse cortex', Nature, vol. 640, no. 8058, 4949, pp. 478-486. https://doi.org/10.1038/s41586-024-07765-7

TY - JOUR

T1 - Perisomatic ultrastructure efficiently classifies cells in mouse cortex

AU - Elabbady, Leila

AU - Seshamani, Sharmishtaa

AU - Mu, Shang

AU - Mahalingam, Gayathri

AU - Schneider-Mizell, Casey M.

AU - Bodor, Agnes L.

AU - Bae, J. Alexander

AU - Brittain, Derrick

AU - Buchanan, Jo Ann

AU - Bumbarger, Daniel J.

AU - Castro, Manuel A.

AU - Dorkenwald, Sven

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 - Mitchell, Eric

AU - Mondal, Shanka Subhra

AU - Nehoran, Barak

AU - Popovych, Sergiy

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 - Seung, H. Sebastian

AU - Reid, R. Clay

AU - da Costa, Nuno Maçarico

AU - Collman, Forrest

PY - 2025/4/10

Y1 - 2025/4/10

N2 - Mammalian neocortex contains a highly diverse set of cell types. These cell types have been mapped systematically using a variety of molecular, electrophysiological and morphological approaches1, 2, 3–4. Each modality offers new perspectives on the variation of biological processes underlying cell-type specialization. Cellular-scale electron microscopy provides dense ultrastructural examination and an unbiased perspective on the subcellular organization of brain cells, including their synaptic connectivity and nanometre-scale morphology. In data that contain tens of thousands of neurons, most of which have incomplete reconstructions, identifying cell types becomes a clear challenge for analysis5. Here, to address this challenge, we present a systematic survey of the somatic region of all cells in a cubic millimetre of cortex using quantitative features obtained from electron microscopy. This analysis demonstrates that the perisomatic region is sufficient to identify cell types, including types defined primarily on the basis of their connectivity patterns. We then describe how this classification facilitates cell-type-specific connectivity characterization and locating cells with rare connectivity patterns in the dataset.

AB - Mammalian neocortex contains a highly diverse set of cell types. These cell types have been mapped systematically using a variety of molecular, electrophysiological and morphological approaches1, 2, 3–4. Each modality offers new perspectives on the variation of biological processes underlying cell-type specialization. Cellular-scale electron microscopy provides dense ultrastructural examination and an unbiased perspective on the subcellular organization of brain cells, including their synaptic connectivity and nanometre-scale morphology. In data that contain tens of thousands of neurons, most of which have incomplete reconstructions, identifying cell types becomes a clear challenge for analysis5. Here, to address this challenge, we present a systematic survey of the somatic region of all cells in a cubic millimetre of cortex using quantitative features obtained from electron microscopy. This analysis demonstrates that the perisomatic region is sufficient to identify cell types, including types defined primarily on the basis of their connectivity patterns. We then describe how this classification facilitates cell-type-specific connectivity characterization and locating cells with rare connectivity patterns in the dataset.

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U2 - 10.1038/s41586-024-07765-7

DO - 10.1038/s41586-024-07765-7

M3 - Article

C2 - 40205216

AN - SCOPUS:105002972601

SN - 0028-0836

VL - 640

SP - 478

EP - 486

JO - Nature

JF - Nature

IS - 8058

M1 - 4949

ER -

Perisomatic ultrastructure efficiently classifies cells in mouse cortex

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