Multiscale modeling shows that dielectric differences make NaV channels faster than KV channels

The generation of action potentials in excitable cells requires different activation kinetics of voltage-gated Na (NaV) and K (KV) channels. NaV channels activate much faster and allow the initial Na+ influx that generates the depolarizing phase and propagates the signal. Recent experimental results suggest that the molecular basis for this kinetic difference is an amino acid side chain located in the gating pore of the voltage sensor domain, which is a highly conserved isoleucine in KV channels but an equally highly conserved threonine in NaV channels. Mutagenesis suggests that the hydrophobicity of this side chain in Shaker KV channels regulates the energetic barrier that gating charges cross as they move through the gating pore and control the rate of channel opening. We use a multiscale modeling approach to test this hypothesis. We use high-resolution molecular dynamics to study the effect of the mutation on polarization charge within the gating pore. We then incorporate these results in a lower-resolution model of voltage gating to predict the effect of the mutation on the movement of gating charges. The predictions of our hierarchical model are fully consistent with the tested hypothesis, thus suggesting that the faster activation kinetics of NaV channels comes from a stronger dielectric polarization by threonine (NaV channel) produced as the first gating charge enters the gating pore compared with isoleucine (KV channel).

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Multi-scale modeling shows that dielectric differences make NaV channels faster than KV channels

10.1101/2020.05.11.088559 ◽

2020 ◽

Author(s):

Luigi Catacuzzeno ◽

Luigi Sforna ◽

Fabio Franciolini ◽

Robert S. Eisenberg

Keyword(s):

Side Chain ◽

Amino Acid Side Chain ◽

Excitable Cells ◽

Activation Kinetics ◽

Voltage Gated ◽

Multi Scale ◽

Scale Modeling ◽

Multi Scale Modeling ◽

Kinetics Of ◽

Gating Charges

AbstractThe generation of action potentials in excitable cells requires different activation kinetics of voltage gated Na (NaV) and K (KV) channels. NaV channels activate much faster and allow the initial Na+ influx that generates the depolarizing phase and propagates the signal. Recent experimental results suggest that the molecular basis for this kinetic difference is an amino acid side chain located in the gating pore of the voltage sensor domain, which is a highly conserved isoleucine in KV channels, but an equally highly conserved threonine in NaV channels. Mutagenesis suggests that the hydrophobicity of this side chain in Shaker KV channels regulates the energetic barrier that gating charges need to overcome to move through the gating pore, and ultimately the rate of channel opening. We use a multi-scale modeling approach to test this hypothesis. We use high resolution molecular dynamics to study the effect of the mutation on polarization charge within the gating pore. We then incorporate these results in a lower resolution model of voltage gating to predict the effect of the mutation on the movement of gating charges. The predictions of our hierarchical model are fully consistent with the tested hypothesis, thus suggesting that the faster activation kinetics of NaV channels comes from a stronger dielectric polarization by threonine (NaV channel) produced as the first gating charge enters the gating pore, compared to isoleucine (KV channel).eTOC SummaryVoltage-gated Na+ channels activate faster than K+ channels in excitable cells. Catacuzzeno et al. develop a model that shows how the dielectric properties of a divergent side-chain produce this difference in speed.

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Interaction Profiles of Amino Acid Side-Chain Analog Pairs within Membrane Environments

Biophysical Journal ◽

10.1016/j.bpj.2013.11.2791 ◽

2014 ◽

Vol 106 (2) ◽

pp. 499a

Author(s):

Vahid Mirjalili ◽

Michael Feig

Keyword(s):

Amino Acid ◽

Side Chain ◽

Amino Acid Side Chain

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Amino acid side-chain populations in aqueous and saline solution: Bis-penicillamine enkephalin

Biopolymers ◽

10.1002/bip.360321205 ◽

1992 ◽

Vol 32 (12) ◽

pp. 1623-1629 ◽

Cited By ~ 11

Author(s):

Paul E. Smith ◽

B. Montgomery Pettitt

Keyword(s):

Amino Acid ◽

Saline Solution ◽

Side Chain ◽

Amino Acid Side Chain

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Energy barriers of proton transfer reactions between amino acid side chain analogs and water fromab initio calculations

Journal of Computational Chemistry ◽

10.1002/jcc.20442 ◽

2006 ◽

Vol 27 (13) ◽

pp. 1534-1547 ◽

Cited By ~ 8

Author(s):

Elena Herzog ◽

Tomaso Frigato ◽

Volkhard Helms ◽

C. Roy D. Lancaster

Keyword(s):

Amino Acid ◽

Proton Transfer ◽

Transfer Reactions ◽

Side Chain ◽

Amino Acid Side Chain ◽

Energy Barriers ◽

Proton Transfer Reactions

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Mixing state and compositional effects on CCN activity and droplet growth kinetics of size-resolved CCN in an urban environment

Atmospheric Chemistry and Physics ◽

10.5194/acp-12-10239-2012 ◽

2012 ◽

Vol 12 (21) ◽

pp. 10239-10255 ◽

Cited By ~ 40

Author(s):

L. T. Padró ◽

R. H. Moore ◽

X. Zhang ◽

N. Rastogi ◽

R. J. Weber ◽

...

Keyword(s):

Chemical Composition ◽

Water Soluble ◽

Anthropogenic Sources ◽

Droplet Growth ◽

Mixing State ◽

Aerosol Composition ◽

Activation Kinetics ◽

Aerosol Mixing State ◽

Kinetics Of ◽

Ccn Activity

Abstract. Aerosol composition and mixing state near anthropogenic sources can be highly variable and can challenge predictions of cloud condensation nuclei (CCN). The impacts of chemical composition on CCN activation kinetics is also an important, but largely unknown, aspect of cloud droplet formation. Towards this, we present in-situ size-resolved CCN measurements carried out during the 2008 summertime August Mini Intensive Gas and Aerosol Study (AMIGAS) campaign in Atlanta, GA. Aerosol chemical composition was measured by two particle-into-liquid samplers measuring water-soluble inorganic ions and total water-soluble organic carbon. Size-resolved CCN data were collected using the Scanning Mobility CCN Analysis (SMCA) method and were used to obtain characteristic aerosol hygroscopicity distributions, whose breadth reflects the aerosol compositional variability and mixing state. Knowledge of aerosol mixing state is important for accurate predictions of CCN concentrations and that the influence of an externally-mixed, CCN-active aerosol fraction varies with size from 31% for particle diameters less than 40 nm to 93% for accumulation mode aerosol during the day. Assuming size-dependent aerosol mixing state and size-invariant chemical composition decreases the average CCN concentration overprediction (for all but one mixing state and chemical composition scenario considered) from over 190–240% to less than 20%. CCN activity is parameterized using a single hygroscopicity parameter, κ, which averages to 0.16 ± 0.07 for 80 nm particles and exhibits considerable variability (from 0.03 to 0.48) throughout the study period. Particles in the 60–100 nm range exhibited similar hygroscopicity, with a κ range for 60 nm between 0.06–0.076 (mean of 0.18 ± 0.09). Smaller particles (40 nm) had on average greater κ, with a range of 0.20–0.92 (mean of 0.3 ± 0.12). Analysis of the droplet activation kinetics of the aerosol sampled suggests that most of the CCN activate as rapidly as calibration aerosol, suggesting that aerosol composition exhibits a minor (if any) impact on CCN activation kinetics.

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