Structural and functional specializations of human fast-spiking neurons support fast cortical signaling

René Wilbers; Anna A. Galakhova; Stan L.W. Driessens; Tim S. Heistek; Verjinia D. Metodieva; Jim Hagemann; Djai B. Heyer; Eline J. Mertens; Suixin Deng; Sander Idema; Philip C. de Witt Hamer; David P. Noske; Paul van Schie; Ivar Kommers; Guoming Luan; Tianfu Li; Yousheng Shu; Christiaan P.J. de Kock; Huibert D. Mansvelder; Natalia A. Goriounova

doi:10.1126/sciadv.adf0708

Structural and functional specializations of human fast-spiking neurons support fast cortical signaling

René Wilbers, Anna A. Galakhova, Stan L.W. Driessens, Tim S. Heistek, Verjinia D. Metodieva, Jim Hagemann, Djai B. Heyer, Eline J. Mertens, Suixin Deng, Sander Idema, Philip C. de Witt Hamer, David P. Noske, Paul van Schie, Ivar Kommers, Guoming Luan, Tianfu Li, Yousheng Shu, Christiaan P.J. de Kock, Huibert D. Mansvelder, Natalia A. Goriounova

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Fast-spiking interneurons (FSINs) provide fast inhibition that synchronizes neuronal activity and is critical for cognitive function. Fast synchronization frequencies are evolutionary conserved in the expanded human neocortex despite larger neuron-to-neuron distances that challenge fast input-output transfer functions of FSINs. Here, we test in human neurons from neurosurgery tissue, which mechanistic specializations of human FSINs explain their fast-signaling properties in human cortex. With morphological reconstructions, multipatch recordings, and biophysical modeling, we find that despite threefold longer dendritic path, human FSINs maintain fast inhibition between connected pyramidal neurons through several mechanisms: stronger synapse strength of excitatory inputs, larger dendrite diameter with reduced complexity, faster AP initiation, and faster and larger inhibitory output, while Na+ current activation/inactivation properties are similar. These adaptations underlie short input-output delays in fast inhibition of human pyramidal neurons through FSINs, explaining how cortical synchronization frequencies are conserved despite expanded and sparse network topology of human cortex.

Original language	English
Article number	eadf0708
Pages (from-to)	1-15
Number of pages	15
Journal	Science advances
Volume	9
Issue number	41
Early online date	12 Oct 2023
DOIs	https://doi.org/10.1126/sciadv.adf0708
Publication status	Published - 13 Oct 2023

Funding

Funders	Funder number
Not added	024.004.012
European Commission	101093198
Horizon 2020 Framework Programme	945539

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Wilbers, R., Galakhova, A. A., Driessens, S. L. W., Heistek, T. S., Metodieva, V. D., Hagemann, J., Heyer, D. B., Mertens, E. J., Deng, S., Idema, S., de Witt Hamer, P. C., Noske, D. P., van Schie, P., Kommers, I., Luan, G., Li, T., Shu, Y., de Kock, C. P. J., Mansvelder, H. D., & Goriounova, N. A. (2023). Structural and functional specializations of human fast-spiking neurons support fast cortical signaling. Science advances, 9(41), 1-15. Article eadf0708. https://doi.org/10.1126/sciadv.adf0708

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title = "Structural and functional specializations of human fast-spiking neurons support fast cortical signaling",

abstract = "Fast-spiking interneurons (FSINs) provide fast inhibition that synchronizes neuronal activity and is critical for cognitive function. Fast synchronization frequencies are evolutionary conserved in the expanded human neocortex despite larger neuron-to-neuron distances that challenge fast input-output transfer functions of FSINs. Here, we test in human neurons from neurosurgery tissue, which mechanistic specializations of human FSINs explain their fast-signaling properties in human cortex. With morphological reconstructions, multipatch recordings, and biophysical modeling, we find that despite threefold longer dendritic path, human FSINs maintain fast inhibition between connected pyramidal neurons through several mechanisms: stronger synapse strength of excitatory inputs, larger dendrite diameter with reduced complexity, faster AP initiation, and faster and larger inhibitory output, while Na+ current activation/inactivation properties are similar. These adaptations underlie short input-output delays in fast inhibition of human pyramidal neurons through FSINs, explaining how cortical synchronization frequencies are conserved despite expanded and sparse network topology of human cortex.",

author = "Ren{\'e} Wilbers and Galakhova, {Anna A.} and Driessens, {Stan L.W.} and Heistek, {Tim S.} and Metodieva, {Verjinia D.} and Jim Hagemann and Heyer, {Djai B.} and Mertens, {Eline J.} and Suixin Deng and Sander Idema and {de Witt Hamer}, {Philip C.} and Noske, {David P.} and {van Schie}, Paul and Ivar Kommers and Guoming Luan and Tianfu Li and Yousheng Shu and {de Kock}, {Christiaan P.J.} and Mansvelder, {Huibert D.} and Goriounova, {Natalia A.}",

year = "2023",

month = oct,

day = "13",

doi = "10.1126/sciadv.adf0708",

language = "English",

volume = "9",

pages = "1--15",

journal = "Science advances",

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Wilbers, R , Galakhova, AA , Driessens, SLW , Heistek, TS, Metodieva, VD, Hagemann, J, Heyer, DB , Mertens, EJ, Deng, S, Idema, S, de Witt Hamer, PC, Noske, DP, van Schie, P, Kommers, I, Luan, G, Li, T, Shu, Y, de Kock, CPJ , Mansvelder, HD & Goriounova, NA 2023, 'Structural and functional specializations of human fast-spiking neurons support fast cortical signaling', Science advances, vol. 9, no. 41, eadf0708, pp. 1-15. https://doi.org/10.1126/sciadv.adf0708

TY - JOUR

T1 - Structural and functional specializations of human fast-spiking neurons support fast cortical signaling

AU - Wilbers, René

AU - Galakhova, Anna A.

AU - Driessens, Stan L.W.

AU - Heistek, Tim S.

AU - Metodieva, Verjinia D.

AU - Hagemann, Jim

AU - Heyer, Djai B.

AU - Mertens, Eline J.

AU - Deng, Suixin

AU - Idema, Sander

AU - de Witt Hamer, Philip C.

AU - Noske, David P.

AU - van Schie, Paul

AU - Kommers, Ivar

AU - Luan, Guoming

AU - Li, Tianfu

AU - Shu, Yousheng

AU - de Kock, Christiaan P.J.

AU - Mansvelder, Huibert D.

AU - Goriounova, Natalia A.

PY - 2023/10/13

Y1 - 2023/10/13

N2 - Fast-spiking interneurons (FSINs) provide fast inhibition that synchronizes neuronal activity and is critical for cognitive function. Fast synchronization frequencies are evolutionary conserved in the expanded human neocortex despite larger neuron-to-neuron distances that challenge fast input-output transfer functions of FSINs. Here, we test in human neurons from neurosurgery tissue, which mechanistic specializations of human FSINs explain their fast-signaling properties in human cortex. With morphological reconstructions, multipatch recordings, and biophysical modeling, we find that despite threefold longer dendritic path, human FSINs maintain fast inhibition between connected pyramidal neurons through several mechanisms: stronger synapse strength of excitatory inputs, larger dendrite diameter with reduced complexity, faster AP initiation, and faster and larger inhibitory output, while Na+ current activation/inactivation properties are similar. These adaptations underlie short input-output delays in fast inhibition of human pyramidal neurons through FSINs, explaining how cortical synchronization frequencies are conserved despite expanded and sparse network topology of human cortex.

AB - Fast-spiking interneurons (FSINs) provide fast inhibition that synchronizes neuronal activity and is critical for cognitive function. Fast synchronization frequencies are evolutionary conserved in the expanded human neocortex despite larger neuron-to-neuron distances that challenge fast input-output transfer functions of FSINs. Here, we test in human neurons from neurosurgery tissue, which mechanistic specializations of human FSINs explain their fast-signaling properties in human cortex. With morphological reconstructions, multipatch recordings, and biophysical modeling, we find that despite threefold longer dendritic path, human FSINs maintain fast inhibition between connected pyramidal neurons through several mechanisms: stronger synapse strength of excitatory inputs, larger dendrite diameter with reduced complexity, faster AP initiation, and faster and larger inhibitory output, while Na+ current activation/inactivation properties are similar. These adaptations underlie short input-output delays in fast inhibition of human pyramidal neurons through FSINs, explaining how cortical synchronization frequencies are conserved despite expanded and sparse network topology of human cortex.

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SN - 2375-2548

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JO - Science advances

JF - Science advances

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M1 - eadf0708

ER -

Structural and functional specializations of human fast-spiking neurons support fast cortical signaling

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