Thyroid Hormone Receptor Agonistic and Antagonistic Activity of Newly Synthesized Dihydroxylated Polybrominated Diphenyl Ethers: An In Vitro and In Silico Coactivator Recruitment Study.

Toxics Pub Date : 2024-04-11 DOI:10.3390/toxics12040281

Mengtao Zhang, Jianghong Shi, Bing Li, Hui Ge, Huanyu Tao, Jiawei Zhang, Xiaoyan Li, Zongwei Cai

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Abstract

Dihydroxylated polybrominated diphenyl ethers (DiOH-PBDEs) could be the metabolites of PBDEs of some organisms or the natural products of certain marine bacteria and algae. OH-PBDEs may demonstrate binding affinity to thyroid hormone receptors (TRs) and can disrupt the functioning of the systems modulated by TRs. However, the thyroid hormone disruption mechanism of diOH-PBDEs remains elusive due to the absence of diOH-PBDEs standards. This investigation explores the potential disruptive effects of OH/diOH-PBDEs on thyroid hormones via competitive binding and coactivator recruitment with TRα and TRβ. At levels of 5000 nM and 25,000 nM, 6-OH-BDE-47 demonstrated significant recruitment of steroid receptor coactivator (SRC), whereas none of the diOH-PBDEs exhibited SRC recruitment within the range of 0.32-25,000 nM. AutoDock CrankPep (ADCP) simulations suggest that the conformation of SRC and TR-ligand complexes, particularly their interaction with Helix 12, rather than binding affinity, plays a pivotal role in ligand agonistic activity. 6,6'-diOH-BDE-47 displayed antagonistic activity towards both TRα and TRβ, while the antagonism of 3,5-diOH-BDE-100 for TRα and TRβ was concentration-dependent. 3,5-diOH-BDE-17 and 3,5-diOH-BDE-51 exhibited no discernible agonistic or antagonistic activities. Molecular docking analysis revealed that the binding energy of 3,3',5-triiodo-L-thyronine (T3) surpassed that of OH/diOH-PBDEs. 3,5-diOH-BDE-100 exhibited the highest binding energy, whereas 6,6'-diOH-BDE-47 displayed the lowest. These findings suggest that the structural determinants influencing the agonistic and antagonistic activities of halogen phenols may be more intricate than previously proposed, involving factors beyond high-brominated PBDEs or hydroxyl group and bromine substitutions. It is likely that the agonistic or antagonistic propensities of OH/diOH-PBDEs are instigated by protein conformational changes rather than considerations of binding energy.

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新合成的二羟基多溴联苯醚的甲状腺激素受体激动剂和拮抗剂活性：体外和硅学辅助激活剂招募研究》。

二羟基多溴联苯醚（DiOH-PBDEs）可能是某些生物体内多溴联苯醚的代谢物，也可能是某些海洋细菌和藻类的天然产物。羟基多溴二苯醚可能与甲状腺激素受体（TRs）有亲和力，并能破坏受TRs调节的系统的功能。然而，由于目前还没有二OH-多溴联苯醚的标准，因此二OH-多溴联苯醚对甲状腺激素的干扰机制仍然难以确定。本研究探讨了 OH/diOH-PBDEs 通过与 TRα 和 TRβ 的竞争性结合和辅助激活剂招募对甲状腺激素的潜在破坏作用。在 5000 nM 和 25,000 nM 的水平上，6-OH-BDE-47 显示出显著的类固醇受体辅激活剂（SRC）募集作用，而在 0.32-25,000 nM 的范围内，没有一种二OH-多溴二苯醚显示出 SRC 募集作用。AutoDock CrankPep（ADCP）模拟表明，SRC 和 TR 配体复合物的构象，特别是它们与螺旋 12 的相互作用，而不是结合亲和力，在配体激动活性中起着关键作用。6,6'-二OH-BDE-47对TRα和TRβ都显示出拮抗活性，而3,5-二OH-BDE-100对TRα和TRβ的拮抗作用与浓度有关。3,5-二氧-BDE-17和3,5-二氧-BDE-51没有表现出明显的激动或拮抗活性。分子对接分析表明，3,3',5-三碘-L-吡ronine（T3）的结合能超过了 OH/diOH-PBDEs 的结合能。3,5-二OH-BDE-100的结合能最高，而6,6'-二OH-BDE-47的结合能最低。这些研究结果表明，影响卤素酚的激动和拮抗活性的结构决定因素可能比以前提出的更为复杂，涉及到高溴多溴联苯醚或羟基和溴取代之外的因素。OH/二OH-多溴联苯醚的激动或拮抗倾向可能是由蛋白质构象变化而不是结合能引起的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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