Darren Smart

The endogenous lipid anandamide is a full agonist at the human vanilloid receptor (hVR1).

The endogenous cannabinoid anandamide was identified as an agonist for the recombinant human VR1 (hVR1) by screening a large array of bioactive substances using a FLIPR‐based calcium assay. Further electrophysiological studies showed that anandamide (10 or 100 μM) and capsaicin (1 μM) produced similar inward currents in hVR1 transfected, but not in parental, HEK293 cells. These currents were abolished by capsazepine (1 μM). In the FLIPR anandamide and capsaicin were full agonists at hVR1, with pEC50 values of 5.94±0.06 (n=5) and 7.13±0.11 (n=8) respectively. The response to anandamide was inhibited by capsazepine (pKB of 7.40±0.02, n=6), but not by the cannabinoid receptor antagonists AM630 or AM281. Furthermore, pretreatment with capsaicin desensitized the anandamide‐induced calcium response and vice versa. In conclusion, this study has demonstrated for the first time that anandamide acts as a full agonist at the human VR1.

TRPV3 is a temperature-sensitive vanilloid receptor-like protein

Vanilloid receptor-1 (VR1, also known as TRPV1) is a thermosensitive, nonselective cation channel that is expressed by capsaicin-sensitive sensory afferents and is activated by noxious heat, acidic pH and the alkaloid irritant capsaicin. Although VR1 gene disruption results in a loss of capsaicin responses, it has minimal effects on thermal nociception. This and other experiments—such as those showing the existence of capsaicin-insensitive heat sensors in sensory neurons—suggest the existence of thermosensitive receptors distinct from VR1. Here we identify a member of the vanilloid receptor/TRP gene family, vanilloid receptor-like protein 3 (VRL3, also known as TRPV3), which is heat-sensitive but capsaicin-insensitive. VRL3 is coded for by a 2,370-base-pair open reading frame, transcribed from a gene adjacent to VR1, and is structurally homologous to VR1. VRL3 responds to noxious heat with a threshold of about 39 °C and is co-expressed in dorsal root ganglion neurons with VR1. Furthermore, when heterologously expressed, VRL3 is able to associate with VR1 and may modulate its responses. Hence, not only is VRL3 a thermosensitive ion channel but it may represent an additional vanilloid receptor subunit involved in the formation of heteromeric vanilloid receptor channels.

Ethanol elicits and potentiates nociceptor responses via the vanilloid receptor-1.

The vanilloid receptor-1 (VR1) is a heat-gated ion channel that is responsible for the burning sensation elicited by capsaicin. A similar sensation is reported by patients with esophagitis when they consume alcoholic beverages or are administered alcohol by injection as a medical treatment. We report here that ethanol activates primary sensory neurons, resulting in neuropeptide release or plasma extravasation in the esophagus, spinal cord or skin. Sensory neurons from trigeminal or dorsal root ganglia as well as VR1-expressing HEK293 cells responded to ethanol in a concentration-dependent and capsazepine-sensitive fashion. Ethanol potentiated the response of VR1 to capsaicin, protons and heat and lowered the threshold for heat activation of VR1 from ∼42°C to ∼34°C. This provides a likely mechanistic explanation for the ethanol-induced sensory responses that occur at body temperature and for the sensitivity of inflamed tissues to ethanol, such as might be found in esophagitis, neuralgia or wounds.

SB-334867-A: THE FIRST SELECTIVE OREXIN-1 RECEPTOR ANTAGONIST

The pharmacology of various peptide and non‐peptide ligands was studied in Chinese hamster ovary (CHO) cells stably expressing human orexin‐1 (OX1) or orexin‐2 (OX2) receptors by measuring intracellular calcium ([Ca2+]i) using Fluo‐3AM. Orexin‐A and orexin‐B increased [Ca2+]i in CHO‐OX1 (pEC50=8.38±0.04 and 7.26±0.05 respectively, n=12) and CHO‐OX2 (pEC50=8.20±0.03 and 8.26±0.04 respectively, n=8) cells. However, neuropeptide Y and secretin (10 pM – 10 μM) displayed neither agonist nor antagonist properties in either cell‐line. SB‐334867‐A (1‐(2‐Methyylbenzoxanzol‐6‐yl)‐3‐[1,5]naphthyridin‐4‐yl‐urea hydrochloride) inhibited the orexin‐A (10 nM) and orexin‐B (100 nM)‐induced calcium responses (pKB=7.27±0.04 and 7.23±0.03 respectively, n=8), but had no effect on the UTP (3 μM)‐induced calcium response in CHO‐OX1 cells. SB‐334867‐A (10 μM) also inhibited OX2 mediated calcium responses (32.7±1.9% versus orexin‐A). SB‐334867‐A was devoid of agonist properties in either cell‐line. In conclusion, SB‐334867‐A is a non‐peptide OX1 selective receptor antagonist.

Identification and characterisation of SB-366791, a potent and selective vanilloid receptor (VR1/TRPV1) antagonist

Vanilloid receptor-1 (TRPV1) is a non-selective cation channel, predominantly expressed by peripheral sensory neurones, which is known to play a key role in the detection of noxious painful stimuli, such as capsaicin, acid and heat. To date, a number of antagonists have been used to study the physiological role of TRPV1; however, antagonists such as capsazepine are somewhat compromised by non-selective actions at other receptors and apparent modality-specific properties. SB-366791 is a novel, potent, and selective, cinnamide TRPV1 antagonist isolated via high-throughput screening of a large chemical library. In a FLIPR-based Ca(2+)-assay, SB-366791 produced a concentration-dependent inhibition of the response to capsaicin with an apparent pK(b) of 7.74 +/- 0.08. Schild analysis indicated a competitive mechanism of action with a pA2 of 7.71. In electrophysiological experiments, SB-366791 was demonstrated to be an effective antagonist of hTRPV1 when activated by different modalities, such as capsaicin, acid or noxious heat (50 degrees C). Unlike capsazepine, SB-366791 was also an effective antagonist vs. the acid-mediated activation of rTRPV1. With the aim of defining a useful tool compound, we also profiled SB-366791 in a wide range of selectivity assays. SB-366791 had a good selectivity profile exhibiting little or no effect in a panel of 47 binding assays (containing a wide range of G-protein-coupled receptors and ion channels) and a number of electrophysiological assays including hippocampal synaptic transmission and action potential firing of locus coeruleus or dorsal raphe neurones. Furthermore, unlike capsazepine, SB-366791 had no effect on either the hyperpolarisation-activated current (I(h)) or Voltage-gated Ca(2+)-channels (VGCC) in cultured rodent sensory neurones. In summary, SB-366791 is a new TRPV1 antagonist with high potency and an improved selectivity profile with respect to other commonly used TRPV1 antagonists. SB-366791 may therefore prove to be a useful tool to further study the biology of TRPV1.

Cannabinoid CB2 receptor activation inhibits mechanically evoked responses of wide dynamic range dorsal horn neurons in naïve rats and in rat models of inflammatory and neuropathic pain

Peripheral cannabinoid 2 receptors (CB2 receptors) modulate immune responses and attenuate nociceptive behaviour in models of acute and persistent pain. The aim of the present study was to investigate whether peripheral CB2 receptors modulate spinal processing of innocuous and noxious responses and to determine whether there are altered roles of CB2 receptors in models of persistent pain. Effects of local administration of the CB2 receptor agonist JWH‐133 (5 and 15 µg/50 µL) on mechanically evoked responses of spinal wide dynamic range (WDR) neurons in noninflamed rats, rats with carrageenan‐induced hindpaw inflammation, sham operated rats and spinal nerve‐ligated (SNL) rats were determined in anaesthetized rats in vivo. Mechanical stimulation (von Frey filaments, 6–80 g) of the peripheral receptive field evoked firing of WDR neurons. Mechanically evoked responses of WDR neurons were similar in noninflamed, carrageenan‐inflamed, sham‐operated and SNL rats. Intraplantar injection of JWH‐133 (15 µg), but not vehicle, significantly (P < 0.05) inhibited innocuous and noxious mechanically evoked responses of WDR neurons in all four groups of rats. In many cases the selective CB2 receptor antagonist, SR144528 (10 µg/50 µL), attenuated the inhibitory effects of JWH‐133 (15 µg) on mechanically evoked WDR neuronal responses. The CB1 receptor antagonist, SR141716A, did not attenuate the inhibitory effects of JWH‐133 on these responses. Intraplantar preadministration of JWH‐133 also inhibited (P < 0.05) carrageenan‐induced expansion of peripheral receptive fields of WDR dorsal horn neurons. This study demonstrates that activation of peripheral CB2 receptors attenuates both innocuous‐ and noxious‐evoked responses of WDR neurons in models of acute, inflammatory and neuropathic pain.

1,3-Biarylureas as Selective Non-peptide Antagonists of the Orexin-1 Receptor

This communication reports SARs for the first orexin-1 receptor antagonist series of 1-aryl-3-quinolin-4-yl and 1-aryl-3-naphthyridin-4-yl ureas. One of these compounds, 31 (SB-334867), has excellent selectivity for the orexin-1 receptor, blood-brain barrier permeability and shows in vivo activity following ip dosing.

Nociceptin induced inhibition of K+ evoked glutamate release from rat cerebrocortical slices

Nociceptin, an endogenous ligand for the orphan receptor ORL1, has recently been described. In this study we have shown that nociception inhibits 46 mM K+‐stimulated glutamate release from rat perfused cerebrocortical slices with an IC50 of 51 nM. At 100 nM the inhibition amounted to 68 ± 14% and was naloxone (10 μm)‐insensitive excluding an activation of μ, δ and κ opioid receptors. These data demonstrate the functional coupling of ORL1 in glutamatergic neurones and implicates a role for nociceptin in glutamatergic neurotransmission.

'Entourage' effects of N-acyl ethanolamines at human vanilloid receptors. Comparison of effects upon anandamide-induced vanilloid receptor activation and upon anandamide metabolism

The abilities of a series of saturated N‐acyl ethanolamines and related compounds to affect the ability of anandamide (AEA) to produce a Ca2+ influx into human embryonic kidney cells expressing the human vanilloid receptor (hVR1‐HEK293 cells) has been investigated. The C3:0, C4:0, C6:0 and C10:0 ethanolamides neither affected basal Ca2+‐influx, nor the influx in response to a submaximal concentration of AEA (1 μM). In contrast, the C12:0, C17:0, C18:0 ethanolamides and the monounsaturated compound oleoylethanolamide (C18:1) greatly potentiated the response to AEA. Palmitoylethanolamide (C16:0) produced both a response per se and an augmentation of the response to AEA. Lauroylethanolamide (C12:0) produced a leftward shift in the dose‐response curve for AEA. EC50 values for AEA to produce Ca2+ influx into hVR1‐HEK293 cells were 1.8, 1.5, 1.1 and 0.22 μM in the presence of 0, 1, 3 and 10 μM lauroylethanolamide, respectively. Lauroylethanolamide did not affect the dose – response curves to capsaicin. Palmitoylethylamide was synthesized and found to be a mixed‐type inhibitor (Ki(slope) 4.1 μM, Ki(intercept) 66 μM) of [3H]‐AEA metabolism by rat brain membranes. The ‐amide, ‐ethylamide, ‐isopropylamide, ‐butylamide, ‐cyclohexamide and ‐trifluoromethyl ketone analogues of palmitoylethanolamide had little or no effect on the Ca2+ influx response to 1 μM AEA. There was no obvious relation between the abilities of the compounds to enhance the Ca2+ influx response to 1 μM AEA into hVR1‐HEK293 cells and to prevent the hydrolysis of AEA by rat brain membranes. It is concluded that although palmitoylethanolamide has entourage‐like effects at VR1 receptors expressed on hVR1‐HEK293 cells, other N‐acyl ethanolamines have even more dramatic potentiating effects. It is possible that they may play an important role under conditions where their synthesis is increased, such as in severe inflammation.

Characterization using FLIPR of rat vanilloid receptor (rVR1) pharmacology

The vanilloid receptor (VR1) is a ligand‐gated ion channel, which plays an important role in nociceptive processing. Therefore, a pharmacological characterization of the recently cloned rat VR1 (rVR1) was undertaken. HEK293 cells stable expressing rVR1 (rVR1‐HEK293) were loaded with Fluo‐3AM and then incubated at 25°C for 30 min with or without various antagonists or signal transduction modifying agents. Then intracellular calcium concentrations ([Ca2+]i) were monitored using FLIPR, before and after the addition of various agonists. The rank order of potency of agonists (resiniferatoxin (RTX)>capsaicin>olvanil>PPAHV) was as expected, and all were full agonists. The potencies of capsaicin and olvanil, but not RTX or PPAHV, were enhanced at pH 6.4 (pEC50 values of 7.47±0.06, 7.16±0.06, 8.19±0.06 and 6.02±0.03 respectively at pH 7.4 vs 7.71±0.05, 7.58±0.14, 8.10±0.05 and 6.04±0.08 at pH 6.4). Capsazepine, isovelleral and ruthenium red all inhibited the capsaicin (100 nM)‐induced Ca2+ response in rVR1‐HEK293 cells, with pKB values of 7.52±0.08, 6.92±0.11 and 8.09±0.12 respectively (n=6 each). The response to RTX and olvanil were also inhibited by these compounds. None displayed any agonist‐like activity. The removal of extracellular Ca2+ abolished, whilst inhibition of protein kinase C with chelerythrine chloride (10 μM) partially (∼20%) inhibited, the capsaicin (10 μM)‐induced Ca2+ response. However, tetrodotoxin (3 μM), nimodipine (10 μM), ω‐GVIA conotoxin (1 μM), thapsigargin (1 μM), U73122 (3 μM) or H‐89 (3 μM) had no effect on the capsaicin (100 nM)‐induced response. In conclusion, the recombinant rVR1 stably expressed in HEK293 cells acts as a ligand‐gated Ca2+ channel with the appropriate agonist and antagonist pharmacology, and therefore is a suitable model for studying the effects of drugs at this receptor.