Cellular function given parametric variation in the Hodgkin and Huxley model of excitability

How is reliable physiological function maintained in cells despite considerable variability in the values of key parameters of multiple interacting processes that govern that function? Here, we use the classic Hodgkin–Huxley formulation of the squid giant axon action potential to propose a possible...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 115; no. 35; pp. E8211 - E8218
Main Authors Ori, Hillel, Marder, Eve, Marom, Shimon
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 28.08.2018
SeriesPNAS Plus
Subjects
Action potential
Action Potentials - physiology
Animals
Axons - physiology
Biological Sciences
Capacitance
Deactivation
Decapodiformes
Excitability
Fluctuations
Homeostasis
Inactivation
Ion channels
Kinetics
Lymphoma
Mathematical models
Models, Neurological
Parameter sensitivity
Physiology
PNAS Plus
Process parameters
Proteins
homeostasis
dimensionality reduction
excitability
inactivation
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Summary:How is reliable physiological function maintained in cells despite considerable variability in the values of key parameters of multiple interacting processes that govern that function? Here, we use the classic Hodgkin–Huxley formulation of the squid giant axon action potential to propose a possible approach to this problem. Although the full Hodgkin–Huxley model is very sensitive to fluctuations that independently occur in its many parameters, the outcome is in fact determined by simple combinations of these parameters along two physiological dimensions: structural and kinetic (denoted S and K, respectively). Structural parameters describe the properties of the cell, including its capacitance and the densities of its ion channels. Kinetic parameters are those that describe the opening and closing of the voltage-dependent conductances. The impacts of parametric fluctuations on the dynamics of the system—seemingly complex in the high-dimensional representation of the Hodgkin–Huxley model—are tractable when examined within the S–K plane. We demonstrate that slow inactivation, a ubiquitous activity-dependent feature of ionic channels, is a powerful local homeostatic control mechanism that stabilizes excitability amid changes in structural and kinetic parameters.
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Reviewers: A.D., Centre National de la Recherche Scientifique; and I.S., Hebrew University.
Author contributions: H.O. and S.M. performed research; E.M. and S.M. designed research; S.M. analyzed data; and E.M. and S.M. wrote the paper.
Contributed by Eve Marder, July 7, 2018 (sent for review May 21, 2018; reviewed by Alain Destexhe and Idan Segev)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1808552115