Abstract
As a kind of monooxygenase with the function of catalyzing many reactions involved in drug metabolism and synthesis of cholesterol, steroids and other lipids, CYP2J2 is an important member of the cytochrome P450 superfamily. Located at the endoplasmic reticulum, CYP2J2 is responsible for epoxidation of endogenous arachidonic acid in cardiac tissue to produce cis-epoxyeicosatrienoic acids (EETs), which have anti-inflammatory and antifibrinolytic properties, and can protect endothelial cells from ischemic or hypoxic injuries. Some polymorphisms, e.g., CYP2J2 with mutation T143A, R158C, I192N or N404Y, could significantly reduce the metabolism of the arachidonic acid, causing or deteriorating the coronary artery disease. However, so far the detailed mechanism for the mutationinduced dysfunction of arachidonic metabolism is still unknown. To reveal its mechanism, a 3D (three-dimensional) structure for human CYP2J2 was developed, followed by docking the arachidonic acid ligand into the active site of the receptor. It was observed based on the binding mode thus found that Gly486 and Leu378 in the active site of the receptor played a key role in recognizing and positioning the carboxyl group of the ligand via hydrogen bonding interactions, and that any of the aforementioned five mutations might have, either directly or indirectly, impact to their role and hence causing the mutation-induced dysfunction of CYP2J2-mediated arachidonic acid metabolism. It is anticipated that the findings as reported in this review article may stimulate new strategy for finding novel therapeutic approaches to treat coronary artery disease.
Keywords: Arachidonic acid, coronary heart disease, cytochrome P450 2J2, drug metabolism, molecular modeling, polymorphisms, synthesis of cholesterol.
Call for Papers in Thematic Issues
Interaction between drugs and endocrine diseases
The introduction of highly active antiretroviral therapy accelerated studies and our understanding on the interaction between pharmacological therapies and endocrine diseases. Drugs can precipitate endocrine via different mechanisms, including direct alteration of hormone production and secretion, dysregulation of hormonal axis, effects on hormonal transport, receptor-binding, and cellular signalling. Common drug-induced ...read more
Tissue Distribution and Metabolism of Micro- and Nanoparticles and Medical Implants
With the continuous advancement of modern science and engineering, numerous functional materials and active molecules have been developed and utilized in various industrial, medical, and food applications. Many of these can enter the body, either actively or passively, and have significant and intricate impacts on human health. For example, biomaterials ...read more
Related Books
Nanoparticles and Nanocarriers Based Pharmaceutical Formulations
Localized Micro/Nanocarriers for Programmed and On-Demand Controlled Drug Release
Advanced Pharmaceutical and Herbal Nanoscience for Targeted Drug Delivery Systems Part I
Advanced Pharmaceutical and Herbal Nanoscience for Targeted Drug Delivery Systems Part II
Mixed Polymeric Micelles for Osteosarcoma Therapy: Development and Characterization
A Comprehensive Text Book on Self-emulsifying Drug Delivery Systems
Nanomaterials: Evolution and Advancement towards Therapeutic Drug Delivery (Part II)
Nanomaterials: Evolution and Advancement Towards Therapeutic Drug Delivery (Part I)
45