Teresa K. Aman scite author profile

The ␤ subunits of voltage-gated Na channels (Scnxb) regulate the gating of pore-forming ␣ subunits, as well as their trafficking and localization. In heterologous expression systems, ␤1, ␤2, and ␤3 subunits influence inactivation and persistent current in different ways. To test how the ␤4 protein regulates Na channel gating, we transfected ␤4 into HEK (human embryonic kidney) cells stably expressing Na V 1.1. Unlike a free peptide with a sequence from the ␤4 cytoplasmic domain, the full-length ␤4 protein did not block open channels. Instead, ␤4 expression favored open states by shifting activation curves negative, decreasing the slope of the inactivation curve, and increasing the percentage of noninactivating current. Consequently, persistent current tripled in amplitude. Expression of ␤1 or chimeric subunits including the ␤1 extracellular domain, however, favored inactivation. Coexpressing Na V 1.1 and ␤4 with ␤1 produced tiny persistent currents, indicating that ␤1 overcomes the effects of ␤4 in heterotrimeric channels. In contrast, ␤1 C121W , which contains an extracellular epilepsy-associated mutation, did not counteract the destabilization of inactivation by ␤4 and also required unusually large depolarizations for channel opening. In cultured hippocampal neurons transfected with ␤4, persistent current was slightly but significantly increased. Moreover, in ␤4-expressing neurons from Scn1b and Scn1b/Scn2b null mice, entry into inactivated states was slowed. These data suggest that ␤1 and ␤4 have antagonistic roles, the former favoring inactivation, and the latter favoring activation. Because increased Na channel availability may facilitate action potential firing, these results suggest a mechanism for seizure susceptibility of both mice and humans with disrupted ␤1 subunits.

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Impaired Motor Function in Mice With Cell-Specific Knockout of Sodium ChannelScn8a(Na_V1.6) in Cerebellar Purkinje Neurons and Granule Cells

Levin

Khaliq²,

Aman³

et al. 2006

Journal of Neurophysiology

120

117

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The Scn8a gene encodes the voltage-gated Na channel alpha subunit Na(V)1.6, which is widely expressed throughout the nervous system. Global null mutations that eliminate Scn8a in all cells result in severe motor dysfunction and premature death, precluding analysis of the physiological role of Na(V)1.6 in different neuronal types. To test the effect of cerebellar Na(V)1.6 on motor coordination in mice, we used the Cre-lox system to eliminate Scn8a expression exclusively in Purkinje neurons (Purkinje KO) and/or granule neurons (granule KO). Whereas granule KO mice had only minor behavioral defects, adult Purkinje KO mice exhibited ataxia, tremor, and impaired coordination. These disorders were exacerbated in double mutants lacking Scn8a in both Purkinje and granule cells (double KO). In Purkinje cells isolated from adult Purkinje KO and double KO but not granule KO mice, the ratio of resurgent-to-transient tetrodotoxin- (TTX)-sensitive Na current amplitudes decreased from approximately 15 to approximately 5%. In cerebellar slices, Purkinje cell spontaneous and maximal firing rates were reduced 10-fold and twofold relative to control in Purkinje KO and double KO but not granule KO mice. Additionally, short-term plasticity of high-frequency parallel fiber EPSCs was altered relative to control in Purkinje KO and double KO but not granule KO mice. These data suggest that the specialized kinetics of Purkinje Na channels depend directly on Scn8a expression. The loss of these channels leads to a decrease in Purkinje cell firing rates as well as a modification of the synaptic properties of afferent parallel fibers, with the ultimate consequence of disrupting motor behavior.

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The HCN channel voltage sensor undergoes a large downward motion during hyperpolarization

Dai

Aman

DiMaio

et al. 2019

Nat Struct Mol Biol

106

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Voltage-gated ion channels (VGICs) contain positively-charged residues within the S4 helix of the voltage-sensing domain (VSD) that are displaced in response to changes in transmembrane voltage, promoting conformational changes that open the pore. Pacemaker HCN channels are unique among VGICs because their open probability is increased by membrane hyperpolarization rather than depolarization. Here we measured the precise movement of the S4 helix of a sea urchin HCN channel using transition metal ion fluorescence resonance energy transfer (tmFRET). We show that the S4 undergoes a significant (~10 Å) downward movement in response to membrane hyperpolarization. Furthermore, by applying distance constraints determined from tmFRET experiments to Rosetta modeling, we reveal that the C-terminal part of the S4 helix exhibits an unexpected tilting motion during hyperpolarization activation. These data provide a long-sought glimpse of the hyperpolarized state of a functioning VSD and also a framework for understanding the dynamics of reverse gating in HCN channels.

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Subunit Dependence of Na Channel Slow Inactivation and Open Channel Block in Cerebellar Neurons

Aman

Raman

2007

Biophysical Journal

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Purkinje and cerebellar nuclear neurons both have Na currents with resurgent kinetics. Previous observations, however, suggest that their Na channels differ in their susceptibility to entering long-lived inactivated states. To compare fast inactivation, slow inactivation, and open-channel block, we recorded voltage-clamped, tetrodotoxin-sensitive Na currents in Purkinje and nuclear neurons acutely isolated from mouse cerebellum. In nuclear neurons, recovery from all inactivated states was slower, and open-channel unblock was less voltage-dependent than in Purkinje cells. To test whether specific subunits contributed to this differential stability of inactivation, experiments were repeated in Na(V)1.6-null (med) mice. In med Purkinje cells, recovery times were prolonged and the voltage dependence of open-channel block was reduced relative to control cells, suggesting that availability of Na(V)1.6 is quickly restored at negative potentials. In med nuclear cells, however, currents were unchanged, suggesting that Na(V)1.6 contributes little to wild-type nuclear cells. Extracellular Na(+) prevented slow inactivation more effectively in Purkinje than in nuclear neurons, consistent with a resilience of Na(V)1.6 to slow inactivation. The tendency of nuclear Na channels to inactivate produced a low availability during trains of spike-like depolarization. Hyperpolarizations that approximated synaptic inhibition effectively recovered channels, suggesting that increases in Na channel availability promote rebound firing after inhibition.

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Teresa K. Aman

Regulation of Persistent Na Current by Interactions between β Subunits of Voltage-Gated Na Channels

Impaired Motor Function in Mice With Cell-Specific Knockout of Sodium ChannelScn8a(Na_V1.6) in Cerebellar Purkinje Neurons and Granule Cells

The HCN channel voltage sensor undergoes a large downward motion during hyperpolarization

Subunit Dependence of Na Channel Slow Inactivation and Open Channel Block in Cerebellar Neurons

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Teresa K. Aman

Regulation of Persistent Na Current by Interactions between β Subunits of Voltage-Gated Na Channels

Impaired Motor Function in Mice With Cell-Specific Knockout of Sodium ChannelScn8a(NaV1.6) in Cerebellar Purkinje Neurons and Granule Cells

The HCN channel voltage sensor undergoes a large downward motion during hyperpolarization

Subunit Dependence of Na Channel Slow Inactivation and Open Channel Block in Cerebellar Neurons

Contact Info

Product

Resources

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Impaired Motor Function in Mice With Cell-Specific Knockout of Sodium ChannelScn8a(Na_V1.6) in Cerebellar Purkinje Neurons and Granule Cells