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. 2021 May;13(5):903-915.
doi: 10.1002/dta.3024. Epub 2021 Mar 28.

A cell-free bioassay for the detection of androgens

Elliot R Cooper  1 Gillian Hughes  1   2 Alexia Kauff  1   2 Emma Sutherland  1 Zoe Ashley  1 Alison K Heather  1   2
Affiliations

A cell-free bioassay for the detection of androgens

Elliot R Cooper et al. Drug Test Anal. 2021 May.

Erratum in

  • A cell-free bioassay for the detection of androgens.
    Cooper ER, Hughes G, Kauff A, Sutherland E, Ashley Z, Heather AK. Cooper ER, et al. Drug Test Anal. 2022 Jan;14(1):196. doi: 10.1002/dta.3166. Epub 2021 Oct 18. Drug Test Anal. 2022. PMID: 34664413 No abstract available.

Abstract

Androgens remain abused performance-enhancing drugs in sports. Technologies based on mass spectrometry can detect all forms of androgens but fail if the androgen represents a novel structure. A bioassay detects androgens based on function rather than structure. To date, there has been limited adoption of cell-based in vitro bioassays as a screening tool for nontargeted androgen detection because they require expert personnel and specialized equipment to perform. We now describe the development of a cell-free version of an androgen in vitro bioassay. Stage 1 involved in vitro transcription/translation reactions (IVTT) using a DNA template encoding an enhancer/androgen response element (ARE) regulatory region upstream of a minimal promoter that drives expression of a reporter protein. The assay detected testosterone across the concentration range of 106.7 to 0.0144 ng/ml (3.7 × 10-7 to 5 × 10-11 M), with an EC50 of 6.63 ng/ml (23 nM). To reduce complexity, Stages 2-4 of development included just in vitro transcription (IVT) reactions, whereby the output was an RNA molecule. Stage 2 involved directly labelling the RNA molecule with fluorophore-labelled nucleotide triphosphates, Stage 3 involved reverse transcription-polymerase chain reaction (PCR) of the RNA molecule, and Stage 4 utilized an RNA aptamer, Mango II, as its RNA output. The Stage 4 product detected testosterone across the range of 106.7-0.0001 ng/ml (3.7 × 10-7 to 5 × 10-13 M), with an EC50 of 0.04 ng/ml (0.155 nM). Further to this, we show that the Stage 4 product can detect other androgenic molecules. Relative to cell-based bioassays, the Stage 4 product is easy to perform and could be developed into a routine, high-throughput, nontargeted androgen screen.

Keywords: androgens; bioassay; in vitro transcription; sports doping.

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References

REFERENCES

    1. Agency WA-D. Advanced analytical findings recorded by accredited laboratories. 2018.
    1. Joseph JF, Parr MK. Synthetic androgens as designer supplements. Curr Neuropharmacol. 2015;13(1):89-100.
    1. Cooper ER, McGrath KC, Heather AK. In vitro androgen bioassays as a detection method for designer androgens. Sensors (Basel). 2013;13(2):2148-2163.
    1. Bailey K, Yazdi T, Masharani U, Tyrrell B, Butch A, Schaufele F. Advantages and limitations of androgen receptor-based methods for detecting anabolic androgenic steroid abuse as performance enhancing drugs. PLoS One. 2016;11(3):e0151860.
    1. Houtman CJ, Sterk SS, Sterk SS, et al. Detection of anabolic androgenic steroid abuse in doping control using mammalian reporter gene bioassays. Anal Chim Acta. 2009;637(1-2):247-258.

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