昼夜节律和多巴胺的数学模型。

Q1 Mathematics
Ruby Kim, Michael C Reed
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引用次数: 12

摘要

背景:交叉上核(SCN)是哺乳动物的主要昼夜节律(24小时)时钟,控制着重要的生理功能,如睡眠-觉醒周期、激素节律和神经递质调节。实验结果表明,其中一些功能相互影响昼夜节律,形成一个高度复杂的网络。在时钟的下游产物中,孤儿核受体REV-ERB和ROR特别有趣,因为它们协调调节核心时钟电路。最近的实验证据表明,REV-ERB和ROR不仅对脂质代谢至关重要,而且还参与多巴胺(DA)的合成和降解,这可能对帕金森病和情绪障碍等疾病具有重要的临床意义。方法:我们创建了一个由微分方程组成的数学模型,该方程表达了昼夜节律变量如何受到光的影响,REV-ERB和ROR如何反馈到时钟,以及REV-ERB, ROR和BMAL1-CLOCK如何影响多巴胺能系统。该模型的结构是基于实验学家的发现。结果:我们将我们的模型预测与时钟组件在不同光暗条件下和存在遗传扰动的实验数据进行了比较。我们的模型结果与REV-ERB和ROR的实验结果一致,并允许我们预测实验中看到的酪氨酸羟化酶和单胺氧化酶的昼夜变化。通过将我们的模型与现存的多巴胺合成、释放和再摄取模型联系起来,我们能够预测细胞外DA和同型香草酸的昼夜振荡,这与实验观察结果吻合得很好。结论:数学模型的预测与广泛的实验观察相一致。我们的计算表明,实验员提出的REV-ERB、ROR和BMAL1-CLOCK影响DA系统的机制足以解释在多巴胺能变量中观察到的昼夜节律振荡。我们的数学模型可以用于进一步研究哺乳动物生物钟对多巴胺能系统的影响。该模型还可用于预测生物钟的扰动如何破坏多巴胺能系统,并可能用于寻找改善这些破坏的药物靶点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A mathematical model of circadian rhythms and dopamine.

A mathematical model of circadian rhythms and dopamine.

A mathematical model of circadian rhythms and dopamine.

A mathematical model of circadian rhythms and dopamine.

Background: The superchiasmatic nucleus (SCN) serves as the primary circadian (24hr) clock in mammals and is known to control important physiological functions such as the sleep-wake cycle, hormonal rhythms, and neurotransmitter regulation. Experimental results suggest that some of these functions reciprocally influence circadian rhythms, creating a highly complex network. Among the clock's downstream products, orphan nuclear receptors REV-ERB and ROR are particularly interesting because they coordinately modulate the core clock circuitry. Recent experimental evidence shows that REV-ERB and ROR are not only crucial for lipid metabolism but are also involved in dopamine (DA) synthesis and degradation, which could have meaningful clinical implications for conditions such as Parkinson's disease and mood disorders.

Methods: We create a mathematical model consisting of differential equations that express how the circadian variables are influenced by light, how REV-ERB and ROR feedback to the clock, and how REV-ERB, ROR, and BMAL1-CLOCK affect the dopaminergic system. The structure of the model is based on the findings of experimentalists.

Results: We compare our model predictions to experimental data on clock components in different light-dark conditions and in the presence of genetic perturbations. Our model results are consistent with experimental results on REV-ERB and ROR and allow us to predict the circadian variations in tyrosine hydroxylase and monoamine oxidase seen in experiments. By connecting our model to an extant model of dopamine synthesis, release, and reuptake, we are able to predict circadian oscillations in extracellular DA and homovanillic acid that correspond well with experimental observations.

Conclusions: The predictions of the mathematical model are consistent with a wide variety of experimental observations. Our calculations show that the mechanisms proposed by experimentalists by which REV-ERB, ROR, and BMAL1-CLOCK influence the DA system are sufficient to explain the circadian oscillations observed in dopaminergic variables. Our mathematical model can be used for further investigations of the effects of the mammalian circadian clock on the dopaminergic system. The model can also be used to predict how perturbations in the circadian clock disrupt the dopaminergic system and could potentially be used to find drug targets that ameliorate these disruptions.

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来源期刊
Theoretical Biology and Medical Modelling
Theoretical Biology and Medical Modelling MATHEMATICAL & COMPUTATIONAL BIOLOGY-
自引率
0.00%
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0
审稿时长
6-12 weeks
期刊介绍: Theoretical Biology and Medical Modelling is an open access peer-reviewed journal adopting a broad definition of "biology" and focusing on theoretical ideas and models associated with developments in biology and medicine. Mathematicians, biologists and clinicians of various specialisms, philosophers and historians of science are all contributing to the emergence of novel concepts in an age of systems biology, bioinformatics and computer modelling. This is the field in which Theoretical Biology and Medical Modelling operates. We welcome submissions that are technically sound and offering either improved understanding in biology and medicine or progress in theory or method.
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