Molecular study of endo and phytocannabinoids on lipid membranes of different composition

POPC公司 化学 大麻酚 背景(考古学) 内大麻素系统 脂质双层 大麻素受体 生物物理学 双层 亲脂性 生物化学 受体 生物 大麻 医学 精神科 古生物学 兴奋剂
作者
Laura C. Laurella,Albertina G. Moglioni,M. Florencia Martini
出处
期刊:Colloids and Surfaces B: Biointerfaces [Elsevier BV]
卷期号:221: 113020-113020
标识
DOI:10.1016/j.colsurfb.2022.113020
摘要

The discovery of the endocannabinoid system (ECS) dates back only 30 years. Although many research groups have been elucidating its components, location, functions and metabolism, the peculiarities of the compounds considered "neurotransmitters" of ECS generate questions that have not yet been answered or controversies in the literature. In this context, we studied the molecular behaviour of the main endocannabinoid compounds and the main phytocannabinoids in eukaryotic outer and inner model membranes. The high lipophilicity of these compounds gives place to the hypothesis that cannabinoids may reach the molecular targets through the lipid bilayer. This consideration is not only for the cannabinoid receptors but also for other (many) targets that these bioactive molecules modulate (Watkins, 2019; Nelson et al., 2020; Jakowiecki and Filipek, 2016). Given the reported multitarget action of these compounds and the differential behaviour towards the different receptors, studying the properties and dynamics of these cannabinoids in POPC and POPE model membranes become relevant. In this regard, we have studied the differential modulation of the endocannabinoids anandamide and 2-arachidonoyl-glycerol and the phytocannabinoids cannabidiol and trans-Δ9-tetrahydrocannabinol to eukaryotic outer and inner model membranes. Results show that behaviours favour the mobility of the bioactive molecules studied by the external eukaryotic model membrane. As well as, the internal eukaryotic model membrane is less fluid, favouring the stabilisation of folded conformations or the positioning of the molecules in the centre of the bilayer. These results provide relevant evidence that contributes to a deep inside understanding of the behaviour of the primary endogenous ligands of ECS, together with the principal phytocannabinoids of C. sativa.

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