Interference with Systemic Negative Feedback Regulation as a Potential Mechanism for Nonmonotonic Dose-Responses of Endocrine-Disrupting Chemicals

Zhenzhen Shi, Shuo Xiao, Qiang Zhang
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Abstract

Background: Endocrine-disrupting chemicals (EDCs) often exhibit nonmonotonic dose-response (NMDR) relationships, posing significant challenges to health risk assessment and regulations. Several molecular mechanisms operating locally in cells have been proposed, including opposing actions via different receptors, mixed-ligand heterodimer formation, and receptor downregulation. Systemic negative feedback regulation of hormone homeostasis, which is a common feature of many endocrine systems, has also been invoked as a mechanism; however, whether and how exactly such global feedback structure may underpin NMDRs is poorly understood. Objectives: We hypothesize that an EDC may compete with the endogenous hormone for receptors (i) at the central site to interfere with the feedback regulation thus altering the physiological hormone level, and (ii) at the peripheral site to disrupt the hormone action; this dual-action may oppose each other, producing nonmonotonic endocrine effects. The objective here is to explore - through computational modeling - how NMDRs may arise through this potential mechanism and the relevant biological variabilities that enable susceptibility to nonmonotonic effects. Methods: We constructed a dynamical model of a generic hypothalamic-pituitary-endocrine (HPE) axis with negative feedback regulation between a pituitary hormone and a terminal effector hormone (EH). The effects of model parameters, including receptor binding affinities and efficacies, on NMDR were examined for EDC agonists and antagonists. Monte Carlo human population simulations were then conducted to systemically explore biological parameter conditions that engender NMDR. Results: When an EDC interferes sufficiently with the central feedback action of EH, the net endocrine effect at the peripheral target site can be opposite to what is expected of an agonist or antagonist at low concentrations. J/U or Bell-shaped NMDRs arise when the EDC has differential binding affinities and/or efficacies, relative to EH, for the peripheral and central receptors. Quantitative relationships between these biological variabilities and associated distributions were discovered, which can distinguish J/U and Bell-shaped NMDRs from monotonic responses. Conclusions: The ubiquitous negative feedback regulation in endocrine systems can act as a universal mechanism for counterintuitive and nonmonotonic effects of EDCs. Depending on key receptor kinetic and signaling properties of EDCs and endogenous hormones, some individuals may be more susceptible to these complex endocrine effects.
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干扰系统负反馈调节是干扰内分泌的化学品产生非单调剂量反应的潜在机制
背景:干扰内分泌的化学品(EDCs)通常表现出非单调剂量-反应(NMDR)关系,给健康风险评估和监管带来了巨大挑战。有人提出了几种在细胞局部发挥作用的分子机制,包括通过不同受体产生相反的作用、混合配体异二聚体的形成以及受体下调。激素平衡的系统负反馈调节是许多内分泌系统的共同特征,也被援引为一种机制;然而,人们对这种全局反馈结构是否以及如何确切地支撑 NMDR 还知之甚少。我们的目标是我们假设,EDC 可能会与内源性激素竞争受体:(i) 在中枢部位干扰反馈调节,从而改变生理激素水平;(ii) 在外周部位干扰激素作用;这种双重作用可能会相互抵消,产生非单调的内分泌效应。本文的目的是通过计算建模探索 NMDR 是如何通过这种潜在机制产生的,以及导致易受非单调效应影响的相关生物变异性。方法:我们构建了一个下丘脑-垂体-内分泌(HPE)轴的动态模型,该模型在垂体激素和末端效应激素(EH)之间具有负反馈调节作用。针对 EDC 激动剂和拮抗剂,研究了模型参数(包括受体结合亲和力和效率)对 NMDR 的影响。然后进行了蒙特卡罗人类群体模拟,以系统地探索产生 NMDR 的生物参数条件。研究结果当 EDC 充分干扰 EH 的中枢反馈作用时,外周靶点的净内分泌效应可能与低浓度激动剂或拮抗剂的预期效应相反。当 EDC 对外周和中枢受体的结合亲和力和/或效力与 EH 不同时,就会出现 J/U 或钟形 NMDR。我们发现了这些生物变异性和相关分布之间的定量关系,它们可以将 J/U 和钟形 NMDR 与单调反应区分开来。结论内分泌系统中无处不在的负反馈调节是 EDCs 产生反直觉和非单调效应的普遍机制。根据 EDCs 和内源性激素的关键受体动力学和信号特性,有些人可能更容易受到这些复杂的内分泌效应的影响。
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