Neurological and Endocrine Toxicology Branch, Public Health and Integrated Toxicology Division, Center for Public Health & Environmental Assessment, Office of Research and Development, U.S. Environmental Protection Agency, Research Triangle Park, NC, 27711, USA.
Oak Ridge Institute for Science and Education, U.S. Department of Energy, Oak Ridge, TN, 37831, USA.
Arch Toxicol. 2021 May;95(5):1723-1737. doi: 10.1007/s00204-021-03006-2. Epub 2021 Mar 3.
The sodium-iodide symporter (NIS) mediates the uptake of iodide into the thyroid. Inhibition of NIS function by xenobiotics has been demonstrated to suppress circulating thyroid hormones and perturb related physiological functions. Until recently, few environmental chemicals had been screened for NIS inhibition activity. We previously screened over 1000 chemicals from the ToxCast Phase II (ph1v2 and ph2) libraries using an in vitro radioactive iodide uptake (RAIU) with the hNIS-HEK293T cell line to identify NIS inhibitors. Here, we broaden the chemical space by expanding screening to include the ToxCast e1k library (804 unique chemicals) with initial screening for RAIU at 1 × 10 M. Then 209 chemicals demonstrating > 20% RAIU inhibition were further tested in multiple-concentration, parallel RAIU and cell viability assays. This identified 55 chemicals as active, noncytotoxic RAIU inhibitors. Further cytotoxicity-adjusted potency scoring (with NaClO having a reference score of 200) revealed five chemicals with moderate to strong RAIU inhibition (scored > 100). These data were combined with our previous PhII screening data to produce binary hit-calls for ~ 1800 unique chemicals (PhII + e1k) with and without cytotoxicity filtering. Results were analyzed with a ToxPrint chemotype-enrichment workflow to identify substructural features significantly enriched in the NIS inhibition hit-call space. We assessed the applicability of enriched PhII chemotypes to prospectively predict NIS inhibition in the e1k dataset. Chemotype enrichments derived for the combined ~ 1800 dataset also identified additional enriched features, as well as chemotypes affiliated with cytotoxicity. These enriched chemotypes provide important new information that can support future data interpretation, structure-activity relationship, chemical use, and regulation.
钠碘同向转运体(NIS)介导碘化物进入甲状腺。已经证明,外源性化学物质对 NIS 功能的抑制可抑制循环甲状腺激素并扰乱相关生理功能。直到最近,才对少数环境化学品进行了 NIS 抑制活性筛选。我们之前使用 hNIS-HEK293T 细胞系进行体外放射性碘摄取(RAIU)筛选了 ToxCast Phase II(ph1v2 和 ph2)文库中的 1000 多种化学物质,以鉴定 NIS 抑制剂。在这里,我们通过扩展筛选范围,将 ToxCast e1k 文库(804 种独特的化学物质)纳入其中,初始筛选的 RAIU 浓度为 1×10^-5 M,从而拓宽了化学物质的空间。然后,对 209 种显示出>20%RAIU 抑制作用的化学物质进行了多浓度平行 RAIU 和细胞活力测定。结果鉴定出 55 种化学物质为有效的、非细胞毒性的 RAIU 抑制剂。进一步的细胞毒性调整后效力评分(以 NaClO 的参考评分为 200)显示,有 5 种化学物质具有中度至强的 RAIU 抑制作用(评分>100)。这些数据与我们之前的 PhII 筛选数据相结合,产生了约 1800 种具有和不具有细胞毒性过滤的独特化学物质的二进制命中呼叫(PhII+e1k)。使用 ToxPrint 化学型富集工作流程分析结果,以鉴定 NIS 抑制命中呼叫空间中显著富集的亚结构特征。我们评估了富集的 PhII 化学型在预测 e1k 数据集中 NIS 抑制的适用性。针对组合的~1800 个数据集得出的化学型富集还确定了其他富集特征,以及与细胞毒性相关的化学型。这些富集的化学型提供了重要的新信息,可支持未来的数据解释、结构-活性关系、化学物质使用和监管。
