Catherine H. Gill

Epileptogenesis and Enhanced Prepulse Inhibition in GABA B1 -Deficient Mice

The recent cloning of two GABA(B) receptor subunits, GABA(B1) and GABA(B2), has raised the possibility that differences in GABA(B) receptor subunit composition may give rise to pharmacologically or functionally distinct receptors. If present, such molecular diversity could permit the selective targeting of GABA(B) receptor subtypes specifically involved in pathologies such as drug addiction, spasticity, pain, and epilepsy. To address these issues we have developed a GABA(B1) subunit knockout mouse using gene targeting techniques. In the brains of GABA(B1) null mice, all pre- and postsynaptic GABA(B) receptor function was absent demonstrating that the GABA(B1) subunit is essential for all GABA(B) receptor-mediated mechanisms. Despite this, GABA(B1) null mice appeared normal at birth, although by postnatal week four their growth was retarded and they developed a generalized epilepsy that resulted in premature death. In addition, GABA(B1) heterozygote animals showed enhanced prepulse inhibition responses compared to littermate controls, suggesting that GABA(B1) deficient mice exhibit increased sensorimotor gating mechanisms. These data suggest that GABA(B) receptor antagonists may be of benefit in the treatment of psychiatric and neurological disorders in which attentional processing is impaired.

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.

SB-334867-A antagonises orexin mediated excitation in the locus coeruleus.

Electrophysiological recordings from identified noradrenergic locus coeruleus (LC) neurones in rat brain slices have revealed that the orexins can cause direct and reversible depolarisation of the postsynaptic membrane. Whilst it is known that the membrane depolarisation produced by orexin-A can triple the firing rate of spontaneously active LC neurones, quantitative pharmacological analysis that determines the receptor subtype(s) mediating the orexinergic response has not yet been performed. Here we demonstrate that the effects of orexin-A are five-fold more potent than orexin-B on LC neuronal excitability. We show further that the orexin receptor antagonist SB-334867-A inhibits the effects of both agonists with pK(B) values similar to those calculated for human OX1 receptors expressed in CHO cells. Finally, we found no evidence for tonic activation of OX1 receptors in LC noradrenergic neurones despite electron microscopic evidence that orexin terminals directly contact these neurones. These data demonstrate that SB-334867-A is a useful tool compound with which to study the physiology of OX1 receptors.

5-HT7 receptors modulate synchronized network activity in rat hippocampus

In the CA3 region of rat hippocampal slices gamma-amino-butyric acid (GABA)(A/B) receptor antagonists induce low frequency bursting activity that was either inhibited (in 21% of slices) or increased by the selective 5-HT receptor agonists 5-carboxy-tryptamine (0.1-1 microM) and 8-hydroxydipropylaminotetralin (8-OH-DPAT). The selective 5-HT1A receptor antagonist N-(2-(4-(2-methoxyphenyl)-1-piperazinyl)ethyl)-N-(2-pyridinyl)cyclohexane carboxamide (WAY 100635) reversed the depression of bursting activity whereas the 5-HT7 receptor antagonist, (R)-3-(2-(2-(4-methylpiperidin-1-yl)-ethyl)pyrrolidine-1-sulfonyl)phenol (SB-269970; 1-10 microM), but not the 5-HT1A, 4 or 6 receptor antagonists WAY100635 (10 microM), SB-204070 (10 microM) and SB-271046 (10 microM), reversed the increase in bursting activity. The apparent -log10 K(D) value (8.4) for the effect of SB-269970 was consistent with a selective action at 5-HT7 receptors. Accompanying the 5-CT-induced increase in bursting frequency there was a shortening of the burst event waveform and a reduction in the after-hyperpolarization following each bursting event both of which were inhibited by SB-269970. These effects appeared to result predominantly from a direct 5-HT(7) receptor-mediated inhibition of a Ca2+ activated K+ channel.

Characterisation of 5‐HT3C, 5‐HT3D and 5‐HT3E receptor subunits: evolution, distribution and function

The 5‐HT3 receptor is a member of the ‘Cys‐loop’ family of ligand‐gated ion channels that mediate fast excitatory and inhibitory transmission in the nervous system. Current evidence points towards native 5‐HT3 receptors originating from homomeric assemblies of 5‐HT3A or heteromeric assembly of 5‐HT3A and 5‐HT3B. Novel genes encoding 5‐HT3C, 5‐HT3D, and 5‐HT3E have recently been described but the functional importance of these proteins is unknown. In the present study, in silico analysis (confirmed by partial cloning) indicated that 5‐HT3C, 5‐HT3D, and 5‐HT3E are not human–specific as previously reported: they are conserved in multiple mammalian species but are absent in rodents. Expression profiles of the novel human genes indicated high levels in the gastrointestinal tract but also in the brain, Dorsal Root Ganglion (DRG) and other tissues. Following the demonstration that these subunits are expressed at the cell membrane, the functional properties of the recombinant human subunits were investigated using patch clamp electrophysiology. 5‐HT3C, 5‐HT3D, and 5‐HT3E were all non‐functional when expressed alone. Co‐transfection studies to determine potential novel heteromeric receptor interactions with 5‐HT3A demonstrated that the expression or function of the receptor was modified by 5‐HT3C and 5‐HT3E, but not 5‐HT3D. The lack of distinct effects on current rectification, kinetics or pharmacology of 5‐HT3A receptors does not however provide unequivocal evidence to support a direct contribution of 5‐HT3C or 5‐HT3E to the lining of the ion channel pore of novel heteromeric receptors. The functional and pharmacological contributions of these novel subunits to human biology and diseases such as irritable bowel syndrome for which 5‐HT3 receptor antagonists have major clinical usage, therefore remains to be fully determined.

Pharmacological characterisation of the orexin receptor subtype mediating postsynaptic excitation in the rat dorsal raphe nucleus.

Electrophysiological recordings from dorsal raphe nucleus (DRN) neurones in rat brain slices have revealed that the orexins can cause direct and reversible depolarisation of the postsynaptic membrane. Whilst it is known that the membrane depolarisation produced by orexin-A can dramatically increase the firing rate of DRN neurones, quantitative pharmacological analysis that determines the receptor subtype mediating the orexinergic response has not yet been performed. Here, we demonstrate that the rank order of potencies of orexin receptor agonists to excite serotonergic DRN neurones is orexin-A=orexin-B>SB-668875-DM. In contrast, the rank order of potency of these agonists to excite noradrenergic locus coreleus (LC) neurones is orexin-A>orexin-B>SB-668875-DM. We show further that the orexin receptor antagonist, SB-334867-A, inhibits the effects of orexin-A in the LC and DRN with pKB values of 6.93 and 5.84, respectively, values similar to those calculated for human OX1 (7.27) and OX2 (5.60) receptors expressed in CHO cells. These data suggest a differential role for OX1 and OX2 receptors in stimulating distinct populations of monoaminergic neurones in the rat CNS with OX2 receptors exhibiting a more pronounced functional significance in serotonergic neurones and OX1 in noradrenergic neurones.Electrophysiological recordings from dorsal raphe nucleus (DRN) neurones in rat brain slices have revealed that the orexins can cause direct and reversible depolarisation of the postsynaptic membrane. Whilst it is known that the membrane depolarisation produced by orexin-A can dramatically increase the firing rate of DRN neurones, quantitative pharmacological analysis that determines the receptor subtype mediating the orexinergic response has not yet been performed. Here, we demonstrate that the rank order of potencies of orexin receptor agonists to excite serotonergic DRN neurones is orexin-A = orexin-B > SB-668875-DM. In contrast, the rank order of potency of these agonists to excite noradrenergic locus coreleus (LC) neurones is orexin-A > orexin-B > SB-668875-DM. We show further that the orexin receptor antagonist, SB-334867-A, inhibits the effects of orexin-A in the LC and DRN with pKB values of 6.93 and 5.84, respectively, values similar to those calculated for human OX1 (7.27) and OX2 (5.60) receptors expressed in CHO cells. These data suggest a differential role for OX1 and OX2 receptors in stimulating distinct populations of monoaminergic neurones in the rat CNS with OX2 receptors exhibiting a more pronounced functional significance in serotonergic neurones and OX1 in noradrenergic neurones.

Characterization of the human HCN1 channel and its inhibition by capsazepine

The human hyperpolarization‐activated cyclic nucleotide‐gated 1 (hHCN1) subunit was heterologously expressed in mammalian cell lines (CV‐1 and CHO) and its properties investigated using whole‐cell patch‐clamp recordings. Activation of this recombinant channel, by membrane hyperpolarization, generated a slowly activating, noninactivating inward current. The pharmacological properties of hHCN1‐mediated currents resembled those of native hyperpolarization‐activated currents (Ih), that is, blockade by Cs+ (99% at 5 mM), ZD 7288 (98% at 100 μM) and zatebradine (92% at 10 μM). Inhibition of the hHCN1‐mediated current by ZD 7288 was apparently independent of prior channel activation (i.e. non‐use‐dependent), whereas that induced by zatebradine was use‐dependent. The VR1 receptor antagonist capsazepine inhibited hHCN1‐mediated currents in a concentration‐dependent (IC50=8 μM), reversible and apparently non‐use‐dependent manner. This inhibitory effect of capsazepine was voltage‐independent and associated with a leftward shift in the hHCN1 activation curve as well as a dramatic slowing of the kinetics of current activation. Elevation of intracellular cAMP or extracellular K+ significantly enhanced aspects of hHCN1 currents. However, these manipulations did not significantly affect the capsazepine‐induced inhibition of hHCN1. The development of structural analogues of capsazepine may yield compounds that could selectively inhibit HCN channels and prove useful for the treatment of neurological disorders where a role for HCN channels has been described.

Mechanisms contributing to the exacerbated epileptiform activity in hippocampal slices of GABAB1 receptor subunit knockout mice

The recently developed GABAB1 receptor subunit knockout (GABAB1 -/-) mouse displays complete loss of GABAB receptor function and develops complex generalized epilepsies including absence type, audiogenic as well as spontaneous generalized seizures with electrographic spike-wave discharge signatures. To gain insight into the cellular mechanisms contributing to the generation and maintenance of this epileptic phenotype we have compared epileptiform activity induced in hippocampal slices obtained from GABAB1 -/- and wild type (GABAB1 +/+) littermates. Deletion of the GABAB1 receptor subunit had no effect on a range of passive membrane properties of CA3 pyramidale neurones, non-synaptic epileptiform field bursting and spreading depression recorded in 6mM K+/Ca2+-free medium, and inter-ictal synaptically-induced epileptiform activity induced by 100 microM 4-aminopyridine (4-AP). In contrast, synaptic epileptiform activity induced by 10 microM bicuculline, removal of extracellular Mg2+ or addition of 10 microM oxotremorine was enhanced in GABAB1 -/- slices. Acute blockade of GABAB receptors using a selective antagonist only partly mimicked these effects. It is suggested that the exaggerated in vitro epileptiform activity is caused by both acute and chronic consequences of the loss of GABAB receptor function in vivo. Specifically, enhancement of N-methyl-d-aspartate (NMDA) receptor triggered synaptic processes, arising from the loss of the GABAB receptor-mediated inhibitory postsynaptic potential (IPSP, together with a possible promotion of depolarising IPSPs due to the removal of GABAB autoreceptor function) is likely to underlie these effects.