The drug discovery process centers around finding and optimizing novel compounds active at therapeutic targets. This process involves direct and indirect measures of how compounds affect the behavior of the target in question. The sheer number of compounds that must be tested poses problems for classes of ion channel targets for which direct functional measurements (e.g., traditional patch-clamping) are too cumbersome and indirect measurements (e.g., Ca(2+)-sensitive dyes) lack sufficient sensitivity or require unacceptable compromises. We present an optimized process for obtaining large numbers of direct electrophysiological measurements (two-electrode voltage-clamp) from Xenopus oocytes using a combination of automated oocyte handling, efficient and flexible liquid delivery, parallel operation, and powerful integrated data analysis. These improvements have had a marked impact, increasing the contribution electrophysiology makes in optimizing lead compound series and the discovery of new ones. The design of the system is detailed along with examples of data generated in support of lead optimization and discovery.
Although techniques such as (86)Rb(+) flux provide a sensitive measure of K(+) channel activity, the relatively short half-life and high-energy emission, together with the quantities of radioactive material generated, hinder the usefulness of flux-based formats in high throughput screening efforts. This study elaborates on the utilization of flame atomic absorption spectrometry (AAS) techniques for a nonradioactive rubidium efflux assay for large conductance Ca(2+)-activated K(+) channels (BK(Ca)) channels. Utilizing human embryonic kidney (HEK293) cells expressing the BK(Ca) alpha subunit, a 96-well cell-based nonradioactive rubidium efflux screen for channel openers and inhibitors was established. Known BK(Ca) channel openers, including NS1608, NS1619, and NS-8, activated rubidium efflux with EC(50) values ranging from 1 to 4 microM in both radioactive and nonradioactive efflux formats. Compounds such as iberiotoxin, paxilline, and charybdotoxin inhibited rubidium efflux responses evoked by the BK(Ca) channel opener NS1608 in both radioactive and nonradioactive efflux formats. The IC(50) values of the inhibitors in AAS format were comparable to those derived from (86)Rb(+) efflux assays. The present studies show that the pharmacological profiles of BK(Ca) channels assessed by AAS compare well with those obtained using the (86)Rb(+) efflux assay, and support the utility of nonradioactive efflux format for higher throughput screening campaigns for novel K(+) channel modulators.
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