Endocannabinoids and Fear-Related Behavior in Mice Selectively Bred for High or Low Alcohol Preference.

Alcohol use disorders (AUDs) have a high incidence of co-morbidity with stress-related psychopathologies, such as post-traumatic stress disorder (PTSD). Genetic and pharmacological studies support a prominent role for the endocannabinoid system (ECS) in modulating stress-related behaviors relevant to AUDs and PTSD. Mouse lines selectively bred for high (HAP) and low (LAP) alcohol preference show reproducible differences in fear-potentiated startle (FPS), a model for PTSD-related behavior. The first experiment in this study assessed levels of the endocannabinoids, anandamide (AEA) and sn-2 arachidonylglycerol (2-AG), in the prefrontal cortex (PFC), amygdala (AMG), and hippocampus (HIP) of male and female HAP1 and LAP1 mice following the expression of FPS to determine whether ECS responses to conditioned-fear stress (FPS) were correlated with genetic propensity toward high or low alcohol preference. The second experiment examined effects of a cannabinoid receptor type 1 agonist (CP55940) and antagonist (rimonabant) on the expression of FPS in HAP1 and LAP1 male and female mice. The estrous cycle of females was monitored throughout the experiments to determine if the expression of FPS differed by stage of the cycle. FPS was greater in male and female HAP1 than LAP1 mice, as previously reported. In both experiments, LAP1 females in diestrus displayed greater FPS than LAP1 females in metestrus and estrus. In the AMG and HIP, AEA levels were greater in male fear-conditioned HAP1 mice than LAP1 mice. There were no line or sex differences in effects of CP55940 or rimonabant on the expression of FPS. However, surprisingly, evidence for anxiogenic effects of prior treatment with CP55940 were seen in all mice during the third drug-free FPS test. These findings suggest that genetic differences in ECS function in response to fear-conditioning stress may underlie differences in FPS expression in HAP1 and LAP1 selected lines.

The external gate of the human and Drosophila serotonin transporters requires a basic/acidic amino acid pair for 3,4-methylenedioxymethamphetamine (MDMA) translocation and the induction of substrate efflux.

The substituted amphetamine, 3,4-methylenedioxy-methamphetamine (MDMA, ecstasy), is a widely used drug of abuse that induces non-exocytotic release of serotonin, dopamine, and norepinephrine through their cognate transporters as well as blocking the reuptake of neurotransmitter by the same transporters. The resulting dramatic increase in volume transmission and signal duration of neurotransmitters leads to psychotropic, stimulant, and entactogenic effects. The mechanism by which amphetamines drive reverse transport of the monoamines remains largely enigmatic, however, promising outcomes for the therapeutic utility of MDMA for post-traumatic stress disorder and the long-time use of the dopaminergic and noradrenergic-directed amphetamines in treatment of attention-deficit hyperactivity disorder and narcolepsy increases the importance of understanding this phenomenon. Previously, we identified functional differences between the human and Drosophila melanogaster serotonin transporters (hSERT and dSERT, respectively) revealing that MDMA is an effective substrate for hSERT but not dSERT even though serotonin is a potent substrate for both transporters. Chimeric dSERT/hSERT transporters revealed that the molecular components necessary for recognition of MDMA as a substrate was linked to regions of the protein flanking transmembrane domains (TM) V through IX. Here, we performed species-scanning mutagenesis of hSERT, dSERT and C. elegans SERT (ceSERT) along with biochemical and electrophysiological analysis and identified a single amino acid in TM10 (Glu394, hSERT; Asn484, dSERT, Asp517, ceSERT) that is primarily responsible for the differences in MDMA recognition. Our findings reveal that an acidic residue is necessary at this position for MDMA recognition as a substrate and serotonin releaser.

Assessing cholesterol storage in live cells and C. elegans by stimulated Raman scattering imaging of phenyl-Diyne cholesterol.

We report a cholesterol imaging method using rationally synthesized phenyl-diyne cholesterol (PhDY-Chol) and stimulated Raman scattering (SRS) microscope. The phenyl-diyne group is biologically inert and provides a Raman scattering cross section that is 88 times larger than the endogenous C = O stretching mode. SRS microscopy offers an imaging speed that is faster than spontaneous Raman microscopy by three orders of magnitude, and a detection sensitivity of 31 µM PhDY-Chol (~1,800 molecules in the excitation volume). Inside living CHO cells, PhDY-Chol mimics the behavior of cholesterol, including membrane incorporation and esterification. In a cellular model of Niemann-Pick type C disease, PhDY-Chol reflects the lysosomal accumulation of cholesterol, and shows relocation to lipid droplets after HPßCD treatment. In live C. elegans, PhDY-Chol mimics cholesterol uptake by intestinal cells and reflects cholesterol storage. Together, our work demonstrates an enabling platform for study of cholesterol storage and trafficking in living cells and vital organisms.

4-Aminocyclopentane-1,3-diols as platforms for diversity: synthesis of anandamide analogs.

Starting from cyclopentadiene, two racemic mixtures of 4-aminocyclopentane-1,3-diols were prepared in 8 steps and characterized. Structure determination proved the anticipated trans-orientation of the two oxygen atoms with respect to the plane of the ring. The fragment-like new compounds are small and hydrophilic, devoid of rotatable bonds, and offer stereochemically defined attachment points for substituents. Thus, these platforms for diversity are suitable starting points for the construction of combinatorial libraries of lead-like 4-amidocyclopentane-1,3-diols or natural product analogs. As a proof of concept, cyclopentanoid anandamide analogs were prepared using these molecular platforms and evaluated as tools for the investigation of unresolved issues in the molecular biology of anandamide.

Systems-scale analysis reveals pathways involved in cellular response to methamphetamine.

BACKGROUND: Methamphetamine (METH), an abused illicit drug, disrupts many cellular processes, including energy metabolism, spermatogenesis, and maintenance of oxidative status. However, many components of the molecular underpinnings of METH toxicity have yet to be established. Network analyses of integrated proteomic, transcriptomic and metabolomic data are particularly well suited for identifying cellular responses to toxins, such as METH, which might otherwise be obscured by the numerous and dynamic changes that are induced. METHODOLOGY/RESULTS: We used network analyses of proteomic and transcriptomic data to evaluate pathways in Drosophila melanogaster that are affected by acute METH toxicity. METH exposure caused changes in the expression of genes involved with energy metabolism, suggesting a Warburg-like effect (aerobic glycolysis), which is normally associated with cancerous cells. Therefore, we tested the hypothesis that carbohydrate metabolism plays an important role in METH toxicity. In agreement with our hypothesis, we observed that increased dietary sugars partially alleviated the toxic effects of METH. Our systems analysis also showed that METH impacted genes and proteins known to be associated with muscular homeostasis/contraction, maintenance of oxidative status, oxidative phosphorylation, spermatogenesis, iron and calcium homeostasis. Our results also provide numerous candidate genes for the METH-induced dysfunction of spermatogenesis, which have not been previously characterized at the molecular level. CONCLUSION: Our results support our overall hypothesis that METH causes a toxic syndrome that is characterized by the altered carbohydrate metabolism, dysregulation of calcium and iron homeostasis, increased oxidative stress, and disruption of mitochondrial functions.

Effects of the novel endocannabinoid uptake inhibitor, LY2183240, on fear-potentiated startle and alcohol-seeking behaviors in mice selectively bred for high alcohol preference.

RATIONALE: Alcohol-use disorders often occur together with anxiety disorders in humans which may be partly due to common inherited genetic factors. Evidence suggests that the endocannabinoid system (ECS) is a promising therapeutic target for the treatment of individuals with anxiety and/or alcohol-use disorders. OBJECTIVES: The present study assessed the effects of a novel endocannabinoid uptake inhibitor, LY2183240, on anxiety- and alcohol-seeking behaviors in a unique animal model that may represent increased genetic risk to develop co-morbid anxiety and alcohol-use disorders in humans. Mice selectively bred for high alcohol preference (HAP) show greater fear-potentiated startle (FPS) than mice selectively bred for low alcohol preference (LAP). We examined the effects of LY2183240 on the expression of FPS in HAP and LAP mice and on alcohol-induced conditioned place preference (CPP) and limited-access alcohol drinking behavior in HAP mice. RESULTS: Repeated administration of LY2183240 (30 mg/kg) reduced the expression of FPS in HAP but not LAP mice when given prior to a second FPS test 48 h after fear conditioning. Both the 10 and 30 mg/kg doses of LY2183240 enhanced the expression of alcohol-induced CPP and this effect persisted in the absence of the drug. LY2183240 did not alter limited-access alcohol drinking behavior, unconditioned startle responding, or locomotor activity. CONCLUSIONS: These findings suggest that ECS modulation influences both conditioned fear and conditioned alcohol reward behavior. LY2183240 may be an effective pharmacotherapy for individuals with anxiety disorders, such as post-traumatic stress disorder, but may not be appropriate for individuals with co-morbid anxiety and alcohol-use disorders.

Conformational flexibility of transmembrane helix VII of the human serotonin transporter impacts ion dependence and transport.

The serotonin transporter (SERT) regulates the serotonin concentration in the synapse and is a target of several antidepressant and psychostimulant drugs. Previous work suggested that the middle transmembrane helices (TMHs) of the biogenic amine transporters (TMHs) play a role in substrate and ion recognition. We focused our present studies on exploring the role of TMH VII in transporter function and ion recognition. Residues divergent between human SERT and Drosophila SERT (hSERT and dSERT, respectively) were identified and mutated in hSERT to the corresponding identity in dSERT. hSERT mutants V366S, M370L, S375A, and T381S exhibited a decrease in transport capacity. To further explore the role of these residues in the transport process, we generated cysteine mutants at multiple positions. Pretreatment with [2-(trimethylammonium)ethyl] methanethiosulfonate (MTSET) caused a decrease in transport of [(3)H]5-HT in the V366C and M370C mutants. The hSERT V366S, M370L, and M370C mutations also altered the sodium and chloride dependence for substrate transport. Interpretation of our results in the context of a homology model of SERT based on the crystal structure of the Aquifex aeolicus leucine transporter suggests flexibility in the conformation of TMH VII that impacts ion dependence and substrate transport.

Activation of TRPC6 channels promotes endocannabinoid biosynthesis in neuronal CAD cells.

Calcium influx activates biosynthesis of the endogenous cannabinoids 2-arachidonyl glycerol (2-AG) and anandamide (AEA). The calcium channel involved with endocannabinoid synthesis and release in neurons is still unknown. The canonical TRP (TRPC) channels are calcium-permeable channels that are a homology-based subdivision of the broader class of TRP channels. TRPC3, 6, and 7 are G-protein-gated non-selective cation channels that have been localized to lipid rafts and shown to colocalize with caveolin 1. Because endocannabinoid synthesis has been found to occur "on demand" in a calcium-dependent manner and has been linked to lipid rafts, we explored the potential role of transient receptor potential (TRP) channels in this process. Previously, we observed that after metabolism AEA and arachidonic acid (ArA) can be recycled into new endocannabinoid molecules. Consistent with these previous findings, we found that Cath.a differentiated (CAD) cells pretreated with radiolabeled ArA exhibited a robust increase in 2-AG release in response to TRPC stimulation with the diacylglycerol (DAG) analogue, 1-oleoyl-2-acetyl-sn-glycerol (OAG). Furthermore, cells pretreated with [(3)H]AEA produced a significant amount of AEA and 2-AG upon stimulation of TRPC channels. This process was not mediated through protein kinase C activation. Reverse transcriptase-polymerase chain reaction (RT-PCR) analysis revealed that only TRPC6 was present in the CAD cells. siRNA-induced knockdown of TRPC6 in the CAD cells abolished OAG-stimulated production of the endocannabionids. This evidence suggests that TRPC6 may be capable of promoting endocannabinoid synthesis in neuronal cells.

Lipidomic metabolism analysis of the endogenous cannabinoid anandamide (N-arachidonylethanolamide).

Elucidation of pathways involved with lipid metabolism has been limited by analytical challenges associated with detection and structure identification. A discovery-based mass spectrometry lipidomic approach has been applied to identify metabolites of the endogenous cannabinoid anandamide (N-arachidonylethanolamide). Previously, a model system was established to show that anandamide can be recycled by cells to form new endocannabinoids suggesting recycling of the arachidonate carbon chain. We hypothesized that distinct cellular pathways exist to direct the anandamide-derived arachidonate chain into a specific set of metabolites, different from the metabolite pool that is comprised of non-anandamide-derived arachidonic acid. Using stable isotope encoding and liquid chromatography-mass spectrometry, we identified a distinct pool of lipid metabolites derived from exogenous anandamide or arachidonic acid in RBL-2H3 cells. We discovered that arachidonic acid-derived metabolites were primarily comprised of the eicosanoid lipid class, whereas anandamide-derived arachidonic acid, in addition to eicosanoids, was metabolized into diradylglycerols, fatty acid amides, sterols, and glycerophospholipids. From the list of anandamide metabolites of particular interest was 1-O-arachidonyl-sn-glycero-3-phosphocholine. Furthermore, we determined that while 1-O-arachidonyl-sn-glycero-3-phosphocholine may be a metabolite of anandamide, the sn-2 compound was more abundant in mouse brain tissue. Overall, our results provide a novel approach to study the metabolic fate of endocannabinoids and fatty acid-derived signaling molecules.

Structural analysis of the extracellular entrance to the serotonin transporter permeation pathway.

Neurotransmitter transporters are responsible for removal of biogenic amine neurotransmitters after release into the synapse. These transporters are the targets for many clinically relevant drugs, such as antidepressants and psychostimulants. A high resolution crystal structure for the monoamine transporters has yet to be solved. We have developed a homology model for the serotonin transporter (SERT) based on the crystal structure of the leucine transporter (LeuT(Aa)) from Aquifex aeolicus. The objective of the present studies is to identify the structural determinants forming the entrance to the substrate permeation pathway based on predictions from the SERT homology model. Using the substituted cysteine accessibility method, we identified residues predicted to reside at the entrance to the substrate permeation pathway that were reactive with methanethiosulfonate (MTS) reagents. Of these residues, Gln(332) in transmembrane helix (TMH) VI was protected against MTS inactivation in the presence of serotonin. Surprisingly, the reactivity of Gln(332) to MTS reagents was enhanced in the presence of cocaine. Bifunctional MTS cross-linkers also were used to examine the distances between helices predicted to form the entrance into the substrate and ion permeation pathway. Our studies suggest that substrate and ligand binding may induce conformational shifts in TMH I and/or VI, providing new opportunities to refine existing homology models of SERT and related monoamine transporters.

Organized trafficking of anandamide and related lipids.

N-arachidonylethanolamide (anandamide or AEA) is an endogenous long-chain fatty acid ethanolamide with activity at both the cannabinoid 1 (CB(1)) and cannabinoid 2 (CB(2)) receptors, as well as the transient receptor potential vanilloid 1 (TRPV1) receptor. Whereas the mechanisms for both AEA biosynthesis and metabolism are fairly well established, the manner by which AEA is accumulated into cells remains controversial. The overwhelming majority of scientific reports indicate that this lipid neuromodulator is taken into cells via a facilitated process. Some reports have suggested that AEA uptake occurs by facilitated diffusion. Recent evidence indicates that AEA uptake may occur via endocytosis, contesting the premise that passive diffusion is the mechanism by which AEA transverses the plasma membrane. This chapter serves as an introduction to the endocannabinoid field with an emphasis on the various proposed mechanisms for the cellular uptake of endocannabinoids and other related hydrophobic molecules.

Inactivation and biotransformation of the endogenous cannabinoids anandamide and 2-arachidonoylglycerol.

The cannabinoid field is currently an active research area. Anandamide (AEA) and 2-arachidonoylglycerol (2-AG) are the most characterized endogenous cannabinoids (also known as endocannabinoids). These neuromodulators have been implicated in various physiologically relevant phenomena, including mood (Witkin et al., 2005), the immune response (Ashton, 2007), appetite (Kirkham and Tucci, 2006), reproduction (Wang et al., 2006), spasticity (Pertwee, 2002), and pain (Hohmann and Suplita, 2006). Pharmacological manipulation of AEA and 2-AG signaling should prove to have significant therapeutic applications in disorders linked to endocannabinoid signaling. One way to alter endocannabinoid signaling is to regulate the events responsible for termination of the endocannabinoid signal-cellular uptake and metabolism. However, to pharmacologically exploit AEA and/or 2-AG signaling in this way, we must first gain a better understanding of the proteins and mechanisms governing these processes. This review serves as an introduction to the endocannabinoid system with an emphasis on the proteins and events responsible for the termination of AEA and 2-AG signaling.

Membrane microdomains and metabolic pathways that define anandamide and 2-arachidonyl glycerol biosynthesis and breakdown.

Anandamide (AEA) and 2-arachidonyl glycerol (2-AG), endogenous ligands for the CB1 and CB2 cannabinoid receptors, are referred to as endocannabinoids because they mimic the actions of delta9-tetrahydrocannabinol (Delta9-THC), a plant-derived cannabinoid. The processes by which AEA and 2-AG are biosynthesized, released, taken up by cells and hydrolyzed have been of much interest as potential therapeutic targets. In this review we will discuss the progress that has been made to characterize the primary pathways for AEA and 2-AG formation and breakdown as well as the role that specialized membrane microdomains known as lipid rafts play in these processes. Furthermore we will review the recent advances made to track and detect AEA in biological matrices.

Mechanisms for recycling and biosynthesis of endogenous cannabinoids anandamide and 2-arachidonylglycerol.

The mechanisms of endogenous cannabinoid biosynthesis are not completely understood. We hypothesized that anandamide could be recycled by the cell to form new endocannabinoid molecules and released into the extracellular space. We determined that new endocannabinoids derived from exogenous anandamide or arachidonic acid were synthesized and released from RBL-2H3 cells in response to ionomycin. Treatment of RBL-2H3 cells with nystatin and progesterone, agents that disrupt organization of lipid raft/caveolae, resulted in the attenuation of anandamide and 2-arachidonyl glycerol synthesis and/or release in response to stimulation with ionomycin suggesting a role for these membrane microdomains in endocannabinoid biosynthesis. Furthermore, anandamide synthesis may be independent of N-acyl phosphatidylethanolamine phospholipase D as expression of the enzyme was not detected in RBL-2H3 cells. We also established that extracellular calcium is necessary for endocannabinoid biosynthesis because release of intracellular calcium stores alone does not promote endocannabinoid biosynthesis. Next, we examined the role of calcium as a 'switch' to activate the synthesis of anandamide and simultaneously reduce uptake. Indeed, [(3)H] anandamide uptake was reduced in the presence of calcium. Our findings suggest a mechanism indicative of calcium-modulated activation of anandamide synthesis and simultaneous termination of uptake.

Helix XI contributes to the entrance of the serotonin transporter permeation pathway.

The sodium-dependent transporters for dopamine, norepinephrine, and serotonin that regulate neurotransmission, also translocate the neurotoxin 1-methyl-4-phenylpyridinium (MPP(+)). Previous studies implicated residues in transmembrane helix (TMH) XI of DAT as important sites for MPP(+) transport. We examined the importance of TMH XI residues F551 and F556 for MPP(+) translocation by human SERT. Mutations at hSERT F556, but not F551, reduced both 5-HT and MPP(+) transport compared to wild type. However, F556S/hSERT showed a reduction in surface expression explaining the decrease of transport activity for 5-HT, but did not account for the decrease in MPP(+) transport observed. Cysteine mutants at those positions confirmed the accessibility of hSERT/F556 to different methanethiosulfonate (MTS) reagents, suggesting its presence in a hydrophilic environment of the protein. In the presence of MTSET, current induced by 5-HT and MPP(+) was inhibited at the F556C mutant. In agreement with our homology model of SERT, based on the leucine transporter (LeuT(Aa)) from Aquifex aeolicus structure, these results are consistent with the hypothesis that a portion of TMH XI lines the entrance into the substrate permeation pathway.

RNA interference-mediated knockdown of dynamin 2 reduces endocannabinoid uptake into neuronal dCAD cells.

The precise mechanism by which the cellular uptake of the endocannabinoid anandamide (AEA) occurs has been the source of much debate. In the current study, we show that neuronal differentiated CAD (dCAD) cells accumulate anandamide by a process that is inhibited in a dose-dependent manner by N-(4-hydroxyphenyl)arachidonylamide (AM404). We also show that dCAD cells express functional fatty acid amide hydrolase, the enzyme primarily responsible for anandamide metabolism. Previous data from our laboratory indicated that anandamide uptake occurs by a caveolae-related endocytic mechanism in RBL-2H3 cells. In the current study, we show that anandamide uptake by dCAD cells may also occur by an endocytic process that is associated with detergent-resistant membrane microdomains or lipid rafts. Nystatin and progesterone pretreatment of dCAD cells significantly inhibited anandamide accumulation. Furthermore, RNA interference (RNAi)-mediated knockdown of dynamin 2, a protein involved in endocytosis, blocked the internalization of the fluorescently labeled anandamide analog SKM 4-45-1 ([3',6'-bis(acetyloxy)-3-oxospiro[isobenzofuran-1(3H),9'-[9H]xanthen-5-yl]-2-[[1-oxo-5Z,8Z,11Z,14Z-eicosatetraenyl]amino]ethyl ester carbamic acid). RNAi-mediated knockdown of the beta2 subunit of the clathrin-associated activator protein 2 complex had no effect on SKM 4-45-1 internalization. We were surprised to find that dynamin 2 knockdown in dCAD cells did not affect [3H]AEA uptake. However, dynamin 2 knockdown caused a significant increase in the overall levels of intact [3H]AEA associated with the cells, suggesting that trafficking of [3H]AEA to FAAH had been disrupted. This finding may be the result of an accumulation of the anandamide carrier protein in detergent-resistant membranes after dynamin 2 knockdown. Our studies provide evidence that the cellular uptake of anandamide may occur by a dynamin 2-dependent, caveolae-related endocytic process in dCAD cells.

Comparative molecular field analysis using selectivity fields reveals residues in the third transmembrane helix of the serotonin transporter associated with substrate and antagonist recognition.

The human serotonin transporter (hSERT) regulates the spatial and temporal actions of serotonin (5-HT) neurotransmission by removing 5-HT from the synapse. Previous studies have identified residues in the third transmembrane helix (TMH) that may be important for substrate translocation or antagonist recognition. We identified hSERT residues in TMH III that are divergent from Drosophila SERT and used species-scanning mutagenesis to generate reciprocal mutants. Transport inhibition assays suggest that the potency of substituted amphetamines was decreased for the hSERT mutants A169D, I172M, and S174M. In addition, there was a loss of potency for several antidepressants and 3-phenyltropane analogs for the I172M mutant. These results suggest that residues in TMH III may contribute to antagonist recognition. We carried out comparative molecular field analyses using selectivity fields to directly visualize the mutation-induced effects of antagonist potency for antidepressants, 3-phenyltropane analogs, and amphetamines. The hSERT I172M selectivity field analysis for the 3-phenyltropane analogs revealed that electrostatic interactions resulted in decreased potency. The amphetamine and antidepressant selectivity field analyses reveal the observed decreases in potencies for the hSERT I172M mutant are due to a change in tertiary structure of the hSERT protein and are not due to disruption of a direct binding site. Finally, the hSERT mutant A169D displayed altered kinetics for sodium binding, indicating that this residue may lie near the putative sodium binding site. A SERT homology model developed from the Aquifex aeolicus leucine transporter structure provides a structural context for further interpreting the results of the TMH III mutations.

1-Methylpyridinium-4-(4-phenylmethanethiosulfonate) iodide, MTS-MPP+, a novel scanning cysteine accessibility method (SCAM) reagent for monoamine transporter studies.

A novel substituted cysteine accessibility method (SCAM) reagent was developed for monoamine uptake transporters. The new reagent, MTS-MPP(+), was a derivative of the neurotoxin and transporter substrate MPP(+). MTS-MPP(+) labeled cysteine residues introduced into the serotonin transporter protein. Although it did not prove to be a substrate, as is MPP(+), it appears to label cysteine residues lining the permeation pore of the transporter more readily than currently available nonspecific SCAM reagents.