Reverse Docking Approach Reveals the Negative Effect of Caffeine Toxicity on Glutamate GluR2 Receptor

Q4 Pharmacology, Toxicology and Pharmaceutics

Toxicology International Pub Date : 2023-09-20 DOI:10.18311/ti/2023/v30i3/33446

Hasan Ansari, Prekshi Garg, Radhika Rastogi, Rekha Sharma, Prachi Srivastava

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引用次数: 0

Abstract

In the past decade, the consumption of caffeine has increased exponentially throughout the world. Caffeine is now not only limits to coffee but is present in several desserts and other beverages as well. Caffeine is a psychostimulant that helps in improving your performance but its excessive consumption can also affect the cognitive functions of the Central Nervous System (CNS) negatively. The present research is an attempt to understand the mechanism of caffeine action in blocking central nervous system receptors thereby affecting brain function adversely. The reverse docking approach of computational biology has been implied to visualize the interaction of several neurotransmitter receptors with caffeine. Reverse molecular docking is an approach for determining the effect of a ligand on a range of receptors. The binding energy of the receptors with caffeine is considered for determining the best receptor-ligand complex. A list of 7 different neurotransmitters was identified through a literature study and taken into consideration in the current research. The molecular interaction of the human neuro-receptors was seen with caffeine using AutoDock4.0 to study the impact of caffeine on several biological processes of the human brain. The molecular docking approach identifies glutamate gluR2 receptor to be adversely affected by caffeine toxicity thereby affecting the neurotransmission process in the human nervous system.

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反向对接方法揭示咖啡因毒性对谷氨酸GluR2受体的负面影响

在过去的十年里，全世界咖啡因的消费量呈指数级增长。咖啡因现在不仅限于咖啡，而且存在于几种甜点和其他饮料中。咖啡因是一种精神兴奋剂，有助于提高你的表现，但过量摄入也会对中枢神经系统(CNS)的认知功能产生负面影响。本研究试图了解咖啡因阻断中枢神经系统受体从而对脑功能产生不利影响的机制。计算生物学的反向对接方法已经被用来可视化几种神经递质受体与咖啡因的相互作用。反向分子对接是一种确定配体对一系列受体的作用的方法。受体与咖啡因的结合能被认为是确定最佳受体配体复合物的依据。通过文献研究确定了7种不同的神经递质，并在当前的研究中予以考虑。使用AutoDock4.0观察人类神经受体与咖啡因的分子相互作用，研究咖啡因对人脑几个生物过程的影响。分子对接方法确定了谷氨酸gluR2受体受到咖啡因毒性的不利影响，从而影响人类神经系统的神经传递过程。

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来源期刊

Toxicology International Environmental Science-Health, Toxicology and Mutagenesis

CiteScore

0.60

自引率

0.00%

发文量

期刊介绍： Toxicology International is a peer-reviewed International Research Journal published bi-annually by the Society of Toxicology, India. The Journal is concerned with various disciplines of Toxicology including man, animals, plants and environment and publishes research, review and general articles besides opinions, comments, news-highlights and letters to editor.