Abstract
Anandamide, originally described as an endocannabinoid, is the main representative molecule of a new class of signaling lipids including endocannabinoids and N-acyl-related molecules, eicosanoids, and fatty acids. Bioactive lipids regulate neuronal excitability by acting on G-protein-coupled receptors (such as CB1) but also directly modulate various ionic conductances including voltage-activated T-type calcium channels (T-channels). However, little is known about the properties and the specificity of this new class of molecules on their various targets. In this study, we have investigated the chemical determinants involved in anandamide-induced inhibition of the three cloned T-channels: Ca(V)3.1, Ca(V)3.2, and Ca(V)3.3. We show that both the hydroxyl group and the alkyl chain of anandamide are key determinants of its effects on T-currents. As follows, T-currents are also inhibited by fatty acids. Inhibition of the three Ca(V)3 currents by anandamide and arachidonic acid does not involve enzymatic metabolism and occurs in cell-free inside-out patches. Inhibition of T-currents by fatty acids and N-acyl ethanolamides depends on the degree of unsaturation but not on the alkyl chain length and consequently is not restricted to eicosanoids. Inhibition increases for polyunsaturated fatty acids comprising 18-22 carbons when cis-double bonds are close to the carboxyl group. Therefore the major natural (food-supplied) and mammalian endogenous fatty acids including gamma-linolenic acid, mead acid, and arachidonic acid as well as the fully polyunsaturated omega3-fatty acids that are enriched in fish oil eicosapentaenoic and docosahexaenoic acids are potent inhibitors of T-currents, which possibly contribute to their physiological functions.
Highlights
CaV3.2 currents share typical properties of native T-channels, while CaV3.3 currents display unusually slow inactivation kinetics, which are characteristic of specific neurons [1,2,3]
We show that both the alkyl chain of anandamide and the hydroxyl present in its head group are primarily responsible for T-current inhibition
Polyunsaturated fatty acids and N-acyl ethanolamides are signaling molecules implicated in a multitude of physiological and pathophysiological events, including cardiac and neuronal excitability [31, 33, 40, 42], cardioprotection and neuroprotection from ischemic and epileptic episodes (31, 34 –36, 40), inflammation, and pain [32, 39]
Summary
CaV3.2 currents share typical properties of native T-channels, while CaV3.3 currents display unusually slow inactivation kinetics, which are characteristic of specific neurons [1,2,3]. Anandamide (N-arachidonoyl ethanolamide, AEA) belongs to a new major class of small lipid messengers, including endocannabinoids and N-acyl-related molecules, eicosanoids, and fatty acids (22, 28 –32) These bio-active lipids are involved in a multitude of physiological and pathophysiological events, including neuronal excitability [22, 23, 31, 33], sleep [34], epilepsy and neuroprotection (34 –37), inflammation and pain [28, 29, 32, 38, 39], as well as cardiovascular modulation (40 – 42), fertilization, and cell cycle progression [38, 43, 44]. We provide the first detailed analysis of the chemical determinants involved in anandamide-induced inhibition of CaV3 T-channels
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