Rubidium Efflux Assay for the Determination of Calcium Activated Potassium Channel Activity

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Published: 2020-08-07
DOI: https://doi.org/10.46545/aijbls.v2i1.208
Keywords:
Rubidium efflux, Flame atomic absorption spectrometry, BKα channel, HEK293 cells, NS1619, 50mM and 80mM KBS.

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Zainab Gambo Ibrahim
Abubakar Tafawa Balewa University, Nigeria
Hussein A Saad Elrewey
University of Bradford, United Kingdom

Abstract

 


Rubidium efflux assay using flame atomic absorption spectrometry is employed in analyzing potassium channel activity. Calibration using standards of known R  concentrations (10 - 100µM) in tubes was done at the beginning and end of each analysis. R  standard curves were constructed from the data obtained from the analysis of the R standards in both the tubes and 96 well plates. HEK293 cells expressing the alpha subunit of BK channel were incubated with R  for 4 hours after which the cells were washed and then treated with higher concentrations of KBS (50mM / 80mM) or NS1619 (0.003 - 100µM) for 10 minutes. The supernatant was removed and the cells lysed with 0.1%v/v triton. The percentage efflux was then determined from values obtained after analyzing the supernatant and lysate using flame atomic absorption spectrometer. The results showed that there was consistency during each analysis as the R  standard curves constructed from the data obtained overlapped with no significant difference indicating precise calibration and internal validation. For the loaded cells (un-treated), the average concentration of R   in the supernatant was 14.47µM while that in the lysate was 56.24µM and statistical analysis showed there was a significant difference with p<0.0001. The treated cells with higher concentrations of KBS in comparison with 5.4mM KBS gave a percentage increase in R efflux of 47.8% for50mM KBS with significant different of p<0.0001 and 80.11% increase with significant different of p<0.05 for 80mM KBS. The treated cells with 0.1, 0.01 and 0.003µM NS1619 gave a percentage increase in efflux of 13.98%, 29.95% and 23.69% respectively. This research indicated the viability of using flame atomic absorption spectrometry for rubidium efflux assay to test for compounds activating effect on BK channel.

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Issue

Vol. 2 No. 1 (2020)

Section

Original Articles/Review Articles/Case Reports/Short Communications
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Author Biographies

Zainab Gambo Ibrahim, Abubakar Tafawa Balewa University, Nigeria

Department of Clinical Pharmacology and Therapeutics

Faculty of Basic Clinical Sciences, College of Medical Sciences

Abubakar Tafawa Balewa University, Bauchi, Nigeria

Hussein A Saad Elrewey, University of Bradford, United Kingdom

Institute of Cancer Therapeutics

University of Bradford, United Kingdom

And

Faculty of pharmacy, University of Benghazi, State of Libya

How to Cite

Rubidium Efflux Assay for the Determination of Calcium Activated Potassium Channel Activity. (2020). American International Journal of Biology and Life Sciences , 2(1), 18-27. https://doi.org/10.46545/aijbls.v2i1.208
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