Arie S. Jacoby

Critical role for GALR1 galanin receptor in galanin regulation of neuroendocrine function and seizure activity

The GALR1 galanin receptor is expressed at high levels within the central nervous system. To determine which specific actions of galanin are mediated by GALR1, we have developed mice with an insertional inactivating mutation within the gene encoding GALR1 (Galr1). Homozygous Galr1-/- mice are viable and capable of breeding. They exhibit no significant difference in growth rate relative to Galr1+/+ controls but have reduced circulating levels of insulin-like growth factor-I (IGF-I) and exhibit spontaneous tonic-clonic seizures. The phenotype of these mice identifies a critical role for GALR1 in neuroendocrine regulation and in mediating the anti-seizure activity of galanin.

Hyperalgesia and increased neuropathic pain-like response in mice lacking galanin receptor 1 receptors.

The neuropeptide galanin may have a role in modulation of nociception, particularly after peripheral nerve injury. The effect of galanin is mediated by at least three subtypes of receptors. In the present study, we assessed the nociceptive sensitivity in mice lacking the galanin receptor 1 gene (Galr1) and the development of neuropathic pain-like behaviours after photochemically induced partial sciatic nerve ischaemic injury. Under basal condition, Galr1 knock-out (Galr1(-/-)) mice had shortened response latency on the hot plate, but not tail flick and paw radiant heat, tests. The mechanical sensitivity was not different between Galr1(-/-) and wild type (Galr1(+/+)) mice, whereas the cold response was moderately enhanced in Galr1(-/-) mice. Both Galr1(-/-) mice and Galr1(+/+) controls developed mechanical and heat hypersensitivity after partial sciatic nerve injury. The duration of such pain-like behaviours was significantly increased in Galr1(-/-). The Galr1(-/-) mice and Galr1(+/+) mice did not differ in their recovery from deficits in toe-spread after sciatic nerve crush. The results provide some evidence for an inhibitory function for the neuropeptide galanin acting on galanin receptor 1 (GALR1) in nociception and neuropathic pain after peripheral nerve injury in mice.

Learning and memory performance in mice lacking the GAL‐R1 subtype of galanin receptor

The neuropeptide galanin induces performance deficits in a wide range of cognitive tasks in rodents. Three G‐protein‐coupled galanin receptor subtypes, designated GAL‐R1, GAL‐R2 and GAL‐R3, have been cloned. The present study examined the role of GAL‐R1 in cognition by testing mice with a null mutation in Galr1 on several different types of learning and memory tasks. Assessments of general health, neurological reflexes, sensory abilities and motor functions were conducted as control measures. Mutant mice were unimpaired in social transmission of food preference and the Morris water maze. In tests of fear conditioning, mutant mice were unimpaired in a delay version of cued fear conditioning. However, mice homozygous for the null mutation were impaired in a trace version of cued fear conditioning. Mutant mice were unimpaired in contextual fear conditioning, whether training was by the delay or trace protocol. General health, neurological reflexes, sensory abilities and motor functions did not differ across genotypes, indicating that the trace fear conditioning deficit was not an artifact of procedural disabilities. The findings of normal performance on several cognitive tasks and a selective deficit in trace cued fear conditioning in homozygous GAL‐R1 mutant mice are discussed in terms of hypothesized roles of the GAL‐R1 subtype. The generally normal phenotype of GAL‐R1 null mutants supports the use of this line for identification of the receptor subtypes that mediate the cognitive deficits produced by exogenous galanin.

Altered hippocampal expression of neuropeptides in seizure-prone GALR1 knockout mice.

Summary:  Purpose: Mice carrying a deletion of the GALR1 galanin receptor have recently showed spontaneous seizure phenotype with 25% penetrance. To better understand the role of neuropeptides, which are known to undergo complex plasticity changes with development of epileptic seizures, we characterized their expression in the hippocampal formation in GALR1‐ knockout (‐KO) mice with or without seizures and in wild‐type (WT) mice.

Molecular cloning and characterisation of the mouse preprogalanin gene.

Using a probe obtained by PCR amplification from mouse genomic DNA, a genomic clone was isolated covering the entire mouse preprogalanin gene. The mouse gene has an exon:intron organisation very similar to that of the rat and human genes. The first exon is noncoding while exons 2-5 carry the coding region. Exon 6 also encodes the stop codon and a polyadenylation signal. The deduced amino-acid sequence of mouse preprogalanin is 94% and 68% identical to the rat and human peptide, respectively. The amino-acid sequence of mouse galanin was confirmed by RT-PCR amplification of mouse brain RNA. The cloning of the mouse galanin gene should allow elucidation of the regulatory characteristics of its promoter and facilitate transgenic approaches to the analysis of galanin gene function in this species.

Galanin receptor-1 knockout mice exhibit spontaneous epilepsy, abnormal EEGs and altered inhibition in the hippocampus.

Galanin is a widely-distributed neuropeptide that acts as an endogenous anticonvulsant. We have recently generated a galanin receptor type 1 knockout mouse (Galr1(-/-)) that develops spontaneous seizures. Our aim here was to characterize the seizures by making electroencephalogram (EEG) recordings from this animal, and also to elucidate the cellular basis of its epileptic phenotype by studying the neurophysiology of CA1 pyramidal neurons in acute hippocampal slices. EEGs showed that major seizures had a partial onset with secondary generalization, and that paroxysms of spike-and-slow waves occurred and were associated with hypoactivity. The interictal EEG was also abnormal, with a marked excess of spike-and-slow waves. Slice experiments showed that resting potential, input resistance, intrinsic excitability, paired-pulse facilitation of excitatory and inhibitory postsynaptic currents (EPSCs and IPSCs), stimulus--response plots for EPSCs, and several properties of spontaneous miniature EPSCs and IPSCs were all unchanged in the mutant mouse compared with wildtype. However, the frequency of miniature IPSCs was significantly reduced in the mutants. These results suggest that impaired synaptic inhibition in the hippocampus may contribute to the local onset of seizures in the Galr1(-/-) mouse.

Flexor reflex excitability in mice lacking galanin receptor galanin-R1

This study was conducted to examine the excitability of the nociceptive flexor reflex and its sensitization by repetitive stimulation of C-fibers in anesthetized mice that lack the galanin-R1 receptor. Repetitive stimulation of C-fibers induced a gradual increase in reflex magnitude during the stimulation (wind-up), and a subsequent increase in spinal reflex excitability (central sensitization). This occurred in GAL-R1 -/-, GAL-R1 +/-, and +/+ wild-type controls, with no significant differences observed between genotypes. Intrathecal administration of galanin markedly blocked the sensitization following the repetitive stimulation in all three groups. No differences between wild-type or galanin-R1 receptor knockout mice were seen. These results confirm previous studies in rats, showing that intrathecal galanin reduces the central sensitization following wind-up. The present data indicate that this effect is probably mediated by receptors other than GAL-R1.

Phenotypic analysis ofGalr1 knockout mice reveals a role for GALR1 galanin receptor in modulating seizure activity but not nerve regeneration

The GALR1 galanin receptor is expressed at high levels within the central nervous system and is hypothesised to play a significant role in many of the central actions of galanin. To determine which specific actions of galanin are mediated by GALR1, we have developed mice that carry an insertional inactivating mutation within the first coding exon of the gene encoding GALR1 (Galr1). HomozygousGalr1 −/− mice are viable. Both male and female mice exhibit reduced circulating levels of insulin-like growth factor-I (IGF-I) but no significant difference in growth rate relative toGalr1 +/+ controls. Female homozygousGalr1 −/− mice are capable of breeding and nursing offspring. Functional recovery after sciatic nerve crush is not significantly different inGalr1 −/− mice relative toGalr1 +/+ controls, indicating that GALR1 does not mediate the nerve regenerative effects of galanin. However, homozygousGalr1 −/− mice exhibit spontaneous seizures, identifying a critical role for GALR1 in mediating the anti-seizure activity of galanin.

Involvement of galanin receptors 1 and 2 in the modulation of mouse vagal afferent mechanosensitivity

It is established that the gut peptide galanin reduces neuronal excitability via galanin receptor subtypes GALR1 and GALR3 and increases excitability via subtype GALR2. We have previously shown that galanin potently reduces mechanosensitivity in the majority of gastro‐oesophageal vagal afferents, and potentiates sensitivity in a minority. These actions may have implications for therapeutic inhibition of gut afferent signalling. Here we investigated which galanin receptors are likely to mediate these effects. We performed quantitative RT‐PCR on RNA from vagal (nodose) sensory ganglia, which indicated that all three GALR subtypes were expressed at similar levels. The responses of mouse gastro‐oesophageal vagal afferents to graded mechanical stimuli were investigated before and during application of galanin receptor ligands to their peripheral endings. Two types of vagal afferents were tested: tension receptors, which respond to circumferential tension, and mucosal receptors which respond only to mucosal stroking. Galanin induced potent inhibition of mechanosensitivity in both types of afferents. This effect was totally lost in mice with targeted deletion of Galr1. The GALR1/2 agonist AR‐M961 caused inhibition of mechanosensitivity in Galr1+/+ mice, but this was reversed to potentiation in Galr1−/− mice, indicating a minor role for GALR2 in potentiation of vagal afferents. We observed no functional evidence of GALR3 involvement, despite its expression in nodose ganglia. The current study highlights the complex actions of galanin at different receptor subtypes exhibiting parallels with the function of galanin in other systems.