Victoria E. Scott

IDENTIFICATION OF THREE SUBUNITS OF THE HIGH AFFINITY OMEGA -CONOTOXIN MVIIC-SENSITIVE CA2+ CHANNEL

N-, P- and Q-type voltage-dependent Ca2+ channels control neurotransmitter release in the nervous system and are blocked by ω-conotoxin MVIIC. In this study, both a high affinity and a low affinity binding site for ω-conotoxin MVIIC were detected in rabbit brain. The low affinity binding site is shown to be present on the N-type Ca2+ channel. Using optimized conditions for specific labeling of the high affinity ω-conotoxin MVIIC receptor and a panel of subunit specific antibodies, the molecular structure of the high affinity receptor was investigated. We demonstrate for the first time that this receptor is composed of at least α1A, α2δ, and any one of the four brain β subunits. Such association of different β subunits with α1A and α2δ components may produce Ca2+ channels with distinct functional properties, such as P- and Q-type.

BETA SUBUNIT HETEROGENEITY IN N-TYPE CA2+ CHANNELS

The β subunit of the voltage-dependent Ca channel is a cytoplasmic protein that interacts directly with an α subunit, thereby modulating the biophysical properties of the channel. Herein, we demonstrate that the α subunit of the N-type Ca channel associates with several different β subunits. Polyclonal antibodies specific for three different β subunits immunoprecipitated I--conotoxin GVIA binding from solubilized rabbit brain membranes. Enrichment of the N-type Ca channels with an α subunit-specific monoclonal antibody showed the association of β, β, and β subunits. Protein sequencing of tryptic peptides of the 57-kDa component of the purified N-type Ca channel confirmed the presence of the β and β subunits. Each of the β subunits bound to the α subunit interaction domain with similar high affinity. Thus, our data demonstrate important heterogeneity in the β subunit composition of the N-type Ca channels, which may be responsible for some of the diverse kinetic properties recorded from neurons.

Solution structure and mutational analysis of pituitary adenylate cyclase-activating polypeptide binding to the extracellular domain of PAC1-RS.

The pituitary adenylate cyclase-activating polypeptide (PACAP) receptor is a class II G protein-coupled receptor that contributes to many different cellular functions including neurotransmission, neuronal survival, and synaptic plasticity. The solution structure of the potent antagonist PACAP (residues 6′–38′) complexed to the N-terminal extracellular (EC) domain of the human splice variant hPAC1-R-short (hPAC1-RS) was determined by NMR. The PACAP peptide adopts a helical conformation when bound to hPAC1-RS with a bend at residue A18′ and makes extensive hydrophobic and electrostatic interactions along the exposed β-sheet and interconnecting loops of the N-terminal EC domain. Mutagenesis data on both the peptide and the receptor delineate the critical interactions between the C terminus of the peptide and the C terminus of the EC domain that define the high affinity and specificity of hormone binding to hPAC1-RS. These results present a structural basis for hPAC1-RS selectivity for PACAP versus the vasoactive intestinal peptide and also differentiate PACAP residues involved in binding to the N-terminal extracellular domain versus other parts of the full-length hPAC1-RS receptor. The structural, mutational, and binding data are consistent with a model for peptide binding in which the C terminus of the peptide hormone interacts almost exclusively with the N-terminal EC domain, whereas the central region makes contacts to both the N-terminal and other extracellular parts of the receptor, ultimately positioning the N terminus of the peptide to contact the transmembrane region and result in receptor activation.

Identification of critical amino acids involved in α1-β interaction in voltage-dependent Ca2+ channels

In voltage‐dependent Ca2+ channels, the α 1 and β subunits interact via two cytoplasmic regions defined as the Alpha Interaction Domain (AID) and Beta Interaction Domain (BID). Several novel amino acids for that interaction have now been mapped in both domains by point mutations. It was found that three of the nine amino acids in AID and four of the eight BID amino acids tested were essential for the interaction. Whereas the important AID amino acids were clustered around five residues, the important BID residues were more widely distributed within a larger 16 amino acid sequence. The affinity of the AIDA GST fusion protein for the four interacting β 1b BID mutants was not significantly altered compared with the wild‐type β 1b despite the close localization of mutated residues to disruptive BID amino acids. Expression of these interactive β mutants with the full‐length α 1A subunit only slightly modified the stimulation efficiency when compared with the wild‐type β 1b subunit. Our data suggest that non‐disruptive BID sequence alterations do not dramatically affect the β subunit‐induced current stimulation.

Molecular Determinants of Species-Specific Activation or Blockade of TRPA1 Channels

TRPA1 is an excitatory, nonselective cation channel implicated in somatosensory function, pain, and neurogenic inflammation. Through covalent modification of cysteine and lysine residues, TRPA1 can be activated by electrophilic compounds, including active ingredients of pungent natural products (e.g., allyl isothiocyanate), environmental irritants (e.g., acrolein), and endogenous ligands (4-hydroxynonenal). However, how covalent modification leads to channel opening is not understood. Here, we report that electrophilic, thioaminal-containing compounds [e.g., CMP1 (4-methyl-N-[2,2,2-trichloro-1-(4-nitro-phenylsulfanyl)-ethyl]-benzamide)] covalently modify cysteine residues but produce striking species-specific effects [i.e., activation of rat TRPA1 (rTRPA1) and blockade of human TRPA1 (hTRPA1) activation by reactive and nonreactive agonists]. Through characterizing rTRPA1 and hTRPA1 chimeric channels and point mutations, we identified several residues in the upper portion of the S6 transmembrane domains as critical determinants of the opposite channel gating: Ala-946 and Met-949 of rTRPA1 determine channel activation, whereas equivalent residues of hTRPA1 (Ser-943 and Ile-946) determine channel block. Furthermore, side-chain replacements at these critical residues profoundly affect channel function. Therefore, our findings reveal a molecular basis of species-specific channel gating and provide novel insights into how TRPA1 respond to stimuli.

Activation of TRPA1 Channels by the Fatty Acid Amide Hydrolase Inhibitor 3′-Carbamoylbiphenyl-3-yl cyclohexylcarbamate (URB597)

As a member of the transient receptor potential (TRP) ion channel superfamily, the ligand-gated ion channel TRPA1 has been implicated in nociceptive function and pain states. The endogenous ligands that activate TRPA1 remain unknown. However, various agonists have been identified, including environmental irritants (e.g., acrolein) and ingredients of pungent natural products [e.g., allyl isothiocyanate (ITC), cinnamaldehyde, allicin, and gingerol]. In general, these agents are either highly reactive, nonselective, or not potent or efficacious, significantly limiting their utilities in the study of TRPA1 channel properties and biological functions. In a search for novel TRPA1 agonists, we identified 3′-carbamoylbiphenyl-3-yl cyclohexylcarbamate (URB597), a potent and systemically active inhibitor of fatty acid amide hydrolase (FAAH). This enzyme is responsible for anandamide degradation and therefore has been pursued as an antinociceptive and antiepileptic drug target. Using Ca2+ influx assays and patch-clamp techniques, we demonstrated that URB597 could activate heterologously expressed human and rat TRPA1 channels, whereas two other FAAH inhibitors (i.e., URB532 and Compound 7) had no effect. When applied to inside-out membrane patches expressing rat TRPA1, URB597 elicited single-channel activities with a unitary conductance of 40 pS. Furthermore, URB597 activated TRPA1 channels endogenously expressed in a population of rat dorsal root ganglion neurons that also responded to ITC. In contrast to its effect on TRPA1, URB597 inhibited TRPM8 and had no effects on TRPV1 or TRPV4. Thus, we conclude that URB597 is a novel agonist of TRPA1 and probably activates the channel through a direct gating mechanism.

A peripherally acting, selective T-type calcium channel blocker, ABT-639, effectively reduces nociceptive and neuropathic pain in rats

Activation of T-type Ca²⁺ channels contributes to nociceptive signaling by facilitating action potential bursting and modulation of membrane potentials during periods of neuronal hyperexcitability. The role of T-type Ca²⁺ channels in chronic pain is supported by gene knockdown studies showing that decreased Ca(v)3.2 channel expression results in the loss of low voltage-activated (LVA) currents in dorsal root ganglion (DRG) neurons and attenuation of neuropathic pain in the chronic constriction injury (CCI) model. ABT-639 is a novel, peripherally acting, selective T-type Ca²⁺ channel blocker. ABT-639 blocks recombinant human T-type (Ca(v)3.2) Ca²⁺ channels in a voltage-dependent fashion (IC₅₀ = 2 μM) and attenuates LVA currents in rat DRG neurons (IC₅₀ = 8 μM). ABT-639 was significantly less active at other Ca²⁺ channels (e.g. Ca(v)1.2 and Ca(v)2.2) (IC₅₀ > 30 μM). ABT-639 has high oral bioavailability (%F = 73), low protein binding (88.9%) and a low brain:plasma ratio (0.05:1) in rodents. Following oral administration ABT-639 produced dose-dependent antinociception in a rat model of knee joint pain (ED₅₀ = 2 mg/kg, p.o.). ABT-639 (10-100 mg/kg, p.o.) also increased tactile allodynia thresholds in multiple models of neuropathic pain (e.g. spinal nerve ligation, CCI, and vincristine-induced). [corrected]. ABT-639 did not attenuate hyperalgesia in inflammatory pain models induced by complete Freunds adjuvant or carrageenan. At higher doses (e.g. 100-300 mg/kg) ABT-639 did not significantly alter hemodynamic or psychomotor function. The antinociceptive profile of ABT-639 provides novel insights into the role of peripheral T-type (Ca(v)3.2) channels in chronic pain states.

Central Pituitary Adenylate Cyclase 1 Receptors Modulate Nociceptive Behaviors in Both Inflammatory and Neuropathic Pain States

UNLABELLED The pituitary adenylate cyclase-activating polypeptide type 1 receptor (PAC(1)-R) is a member of the 7-transmembrane domain, group 2 G-protein coupled receptor family. PAC(1)-Rs modulate neurotransmission and neurotrophic actions and have been implicated in both pronociception and antinociception. To better understand the role of PAC(1)-Rs in pain, PACAP 6-38, a PAC(1)-R antagonist, was evaluated in several inflammatory and neuropathic pain models after intrathecal (i.t.) administration. PACAP 6-38 potently reduced mechanical allodynia in a neuropathic spinal nerve ligation model (77% +/- 15% maximal effect at 12 nmol, P < .01) and was also effective in reducing thermal hyperalgesia in the carrageenan model of inflammatory pain (89% +/- 17% maximal effect at 12 nmol, P < .01). Although nociceptive responses were also attenuated with PACAP 6-38 in a dose-dependent manner in models of chronic inflammatory and persistent pain, no effects on motor performance were observed at analgesic doses. Taken together, these data demonstrate that blockade of the PAC(1)-R/PACAP complex by PACAP 6-38 can effectively attenuate thermal hyperalgesia and mechanical allodynia associated with inflammatory and neuropathic pain states. These results further emphasize that at the level of the spinal cord, PAC(1)-R activation is pronociceptive. PERSPECTIVE This article presents the analgesic profile generated by the blockade, at the spinal cord level, of the PAC-1 receptor by a potent peptide antagonist. This comprehensive data set demonstrates that if small molecule PAC-1 receptor antagonists could be identified, they would potentially produce broad-spectrum analgesia in both inflammatory and neuropathic pain states.

Discovery and SAR of hydrazide antagonists of the pituitary adenylate cyclase-activating polypeptide (PACAP) receptor type 1 (PAC1-R)

Potent small molecule antagonists for the PAC(1)-R have been discovered. Previously known antagonists for the PAC(1)-R were slightly truncated peptide ligands. The hydrazides reported here are the first small molecule antagonists ever reported for this class B GPCR.

A high throughput fluorescent assay for measuring the activity of fatty acid amide hydrolase

Fatty acid amide hydrolase (FAAH) is the enzyme responsible for the rapid degradation of fatty acid amides such as the endocannabinoid anandamide. Inhibition of FAAH activity has been suggested as a therapeutic approach for the treatment of chronic pain, depression and anxiety, through local activation of the cannabinoid receptor CB1. We have developed a high throughput screening assay for identification of FAAH inhibitors using a novel substrate, decanoyl 7-amino-4-methyl coumarin (D-AMC) that is cleaved by FAAH to release decanoic acid and the highly fluorescent molecule 7-amino-4-methyl coumarin (AMC). This assay gives an excellent signal window for measuring FAAH activity and, as a continuous assay, inherently offers improved sensitivity and accuracy over previously reported endpoint assays. The assay was validated using a panel of known FAAH inhibitors and purified recombinant human FAAH, then converted to a 384 well format and used to screen a large library of compounds (>600,000 compounds) to identify FAAH inhibitors. This screen identified numerous novel FAAH inhibitors of diverse chemotypes. These hits confirmed using a native FAAH substrate, anandamide, and had very similar rank order potency to that obtained using the D-AMC substrate. Collectively these data demonstrate that D-AMC can be successfully used to rapidly and effectively identify novel FAAH inhibitors for potential therapeutic use.