Effects of Sesamin, the Major Furofuran Lignan of Sesame Oil, on the Amplitude and Gating of Voltage-Gated Na + and K + Currents

Sesamin (SSM) and sesamolin (SesA) are the two major furofuran lignans of sesame oil and they have been previously noticed to exert various biological actions. However, their modulatory actions on different types of ionic currents in electrically excitable cells remain largely unresolved. The presen...

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Published in:Molecules (Basel, Switzerland) Switzerland), 2020-07, Vol.25 (13), p.3062
Main Authors: Kuo, Ping-Chung, Kao, Zi-Han, Lee, Shih-Wei, Wu, Sheng-Nan
Format: Article
Language:English
Subjects:
Adenoma - drug therapy
Adenoma - metabolism
Adenoma - pathology
Animals
Antioxidants - pharmacology
Brain tumors
Channel gating
Channel opening
Channels
current kinetics
Dioxoles - pharmacology
erg-mediated K+ current
Hyperpolarization
Inactivation
Ion Channel Gating
Ion currents
Kinetics
Lignans
Lignans - pharmacology
M-type K+ current
Na+ current
Nervous system
Pituitary
Pituitary Neoplasms - drug therapy
Pituitary Neoplasms - metabolism
Pituitary Neoplasms - pathology
Potassium channels (voltage-gated)
Potassium Channels, Voltage-Gated - metabolism
Potassium currents
Rats
Reaction kinetics
Sesame oil
Sesame Oil - chemistry
sesamin
sesamolin
Sodium
Sodium channels (voltage-gated)
Tumor Cells, Cultured
Voltage-Gated Sodium Channels - metabolism
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Summary:Sesamin (SSM) and sesamolin (SesA) are the two major furofuran lignans of sesame oil and they have been previously noticed to exert various biological actions. However, their modulatory actions on different types of ionic currents in electrically excitable cells remain largely unresolved. The present experiments were undertaken to explore the possible perturbations of SSM and SesA on different types of ionic currents, e.g., voltage-gated Na currents ( ), -mediated K currents ( ), M-type K currents ( ), delayed-rectifier K currents ( ) and hyperpolarization-activated cation currents ( ) identified from pituitary tumor (GH ) cells. The exposure to SSM or SesA depressed the transient and late components of with different potencies. The IC value of SSM needed to lessen the peak or sustained was calculated to be 7.2 or 0.6 μM, while that of SesA was 9.8 or 2.5 μM, respectively. The dissociation constant of SSM-perturbed inhibition on , based on the first-order reaction scheme, was measured to be 0.93 μM, a value very similar to the IC for its depressant action on sustained . The addition of SSM was also effective at suppressing the amplitude of resurgent . The addition of SSM could concentration-dependently inhibit the amplitude with an IC value of 4.8 μM. SSM at a concentration of 30 μM could suppress the amplitude of , while at 10 μM, it mildly decreased the amplitude. However, the addition of neither SSM (10 μM) nor SesA (10 μM) altered the amplitude or kinetics of in response to long-lasting hyperpolarization. Additionally, in this study, a modified Markovian model designed for -encoded (or Na 1.6) channels was implemented to evaluate the plausible modifications of SSM on the gating kinetics of Na channels. The model demonstrated herein was well suited to predict that the SSM-mediated decrease in peak , followed by increased current inactivation, which could largely account for its favorable decrease in the probability of the open-blocked over open state of Na channels. Collectively, our study provides evidence that highlights the notion that SSM or SesA could block multiple ion currents, such as and , and suggests that these actions are potentially important and may participate in the functional activities of various electrically excitable cells in vivo.
ISSN:1420-3049
1420-3049
DOI:10.3390/molecules25133062