Mesoscale-duration activated states gate spiking in response to fast rises in membrane voltage in the awake brain

Annabelle C. Singer; Giovanni Talei Franzesi; Suhasa B. Kodandaramaiah; Francisco J. Flores; Jeremy D. Cohen; Albert K. Lee; Christoph Borgers; Craig R. Forest; Nancy J. Kopell; Edward S. Boyden

doi:10.1152/jn.00116.2017

Mesoscale-duration activated states gate spiking in response to fast rises in membrane voltage in the awake brain

Annabelle C. Singer, Giovanni Talei Franzesi, Suhasa B. Kodandaramaiah, Francisco J. Flores, Jeremy D. Cohen, Albert K. Lee, Christoph Borgers, Craig R. Forest, Nancy J. Kopell, Edward S. Boyden

Mechanical Engineering

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

5 Scopus citations

Abstract

Seconds-scale network states, affecting many neurons within a network, modulate neural activity by complementing fast integration of neuron-specific inputs that arrive in the milliseconds before spiking. Nonrhythmic subthreshold dynamics at intermediate timescales, however, are less well characterized. We found, using automated whole cell patch clamping in vivo, that spikes recorded in CA1 and barrel cortex in awake mice are often preceded not only by monotonic voltage rises lasting milliseconds but also by more gradual (lasting tens to hundreds of milliseconds) depolarizations. The latter exert a gating function on spiking, in a fashion that depends on the gradual rise duration: the probability of spiking was higher for longer gradual rises, even when controlled for the amplitude of the gradual rises. Barrel cortex double-autopatch recordings show that gradual rises are shared across some, but not all, neurons. The gradual rises may represent a new kind of state, intermediate both in timescale and in proportion of neurons participating, which gates a neuron’s ability to respond to subsequent inputs. NEW & NOTEWORTHY We analyzed subthreshold activity preceding spikes in hippocampus and barrel cortex of awake mice. Aperiodic voltage ramps extending over tens to hundreds of milliseconds consistently precede and facilitate spikes, in a manner dependent on both their amplitude and their duration. These voltage ramps represent a “mesoscale” activated state that gates spike production in vivo.

Original language	English (US)
Pages (from-to)	1270-1291
Number of pages	22
Journal	Journal of neurophysiology
Volume	118
Issue number	2
DOIs	https://doi.org/10.1152/jn.00116.2017
State	Published - Aug 14 2017

Bibliographical note

Funding Information:
A. C. Singer was funded by the MIT Intelligence Initiative. G. Talei Franzesi was funded by a Friends of the McGovern Institute Fellowship. E. S. Boyden was funded by NIH Director’s Pioneer Award 1DP1NS087724 and Transformative Award 1R01MH103910-01, a New York Stem Cell Foundation-Robertson Award, the Cognitive Rhythms Collaborative funded by NSF DMS 1042134, and NIH Grants 1R01EY023173, 1R01NS067199, and 1R01DA029639. C. Borgers and N. J. Kopell were funded by NIH Grant 1R01 NS067199. S. B. Kodandaramaiah received financial remuneration from Neuromatic Devices for technical consulting services.

Publisher Copyright:
© 2017 the American Physiological Society.

Keywords

Action potential
Barrel cortex
CA1
Hippocampus
Intracellular recording
Network state
Subthreshold dynamics

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title = "Mesoscale-duration activated states gate spiking in response to fast rises in membrane voltage in the awake brain",

abstract = "Seconds-scale network states, affecting many neurons within a network, modulate neural activity by complementing fast integration of neuron-specific inputs that arrive in the milliseconds before spiking. Nonrhythmic subthreshold dynamics at intermediate timescales, however, are less well characterized. We found, using automated whole cell patch clamping in vivo, that spikes recorded in CA1 and barrel cortex in awake mice are often preceded not only by monotonic voltage rises lasting milliseconds but also by more gradual (lasting tens to hundreds of milliseconds) depolarizations. The latter exert a gating function on spiking, in a fashion that depends on the gradual rise duration: the probability of spiking was higher for longer gradual rises, even when controlled for the amplitude of the gradual rises. Barrel cortex double-autopatch recordings show that gradual rises are shared across some, but not all, neurons. The gradual rises may represent a new kind of state, intermediate both in timescale and in proportion of neurons participating, which gates a neuron{\textquoteright}s ability to respond to subsequent inputs. NEW & NOTEWORTHY We analyzed subthreshold activity preceding spikes in hippocampus and barrel cortex of awake mice. Aperiodic voltage ramps extending over tens to hundreds of milliseconds consistently precede and facilitate spikes, in a manner dependent on both their amplitude and their duration. These voltage ramps represent a “mesoscale” activated state that gates spike production in vivo.",

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AU - Flores, Francisco J.

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AU - Lee, Albert K.

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Mesoscale-duration activated states gate spiking in response to fast rises in membrane voltage in the awake brain

Abstract

Bibliographical note

Keywords

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