Galanin N-terminal fragment (1-15) reduces alcohol seeking and alcohol relapse in rats: Involvement of mesocorticolimbic system.

Alcohol Use Disorder (AUD) is among the most prevalent mental illnesses, and due to the low efficacy of the current medication, it is essential to find new biological targets that could modulate alcohol consumption. Since Galanin (1-15) [GAL(1-15)] produces a loss of motivational behaviour by an artificial reinforcer and decreases the preference an alcohol consumption in a voluntary alcohol intake, we have studied the role of GAL(1-15) in alcohol-seeking behaviour and the involvement of the corticomesolimbic system as well as the role of GAL(1-15) in context-induced alcohol relapse. In rats, we have studied GAL(1-15)-effects on alcohol-seeking in self-administration, in fixed-ratio (FR1) and progressive-ratio (PR), and the involvement of GAL receptors using siRNA GALR1 or GALR2 knockdown animals. We have analysed the transcriptional changes of C-Fos, dopamine receptors, GAL receptors and 5HT1A receptors in the corticomesolimbic system. Also, we have examined the effect of GAL(1-15) in context-induced alcohol relapse. GAL(1-15) substantially reduced alcohol-seeking behaviour in the operant self-administration model in an FR1 protocol and at the breaking point in a PR schedule. GALR1and GALR2 were involved in these effects, as indicated by the analysis by GALR2 antagonist and GALR1 and GALR2 knockdown animals. Notably, the mechanism of GAL(1-15)-mediated actions involved changes in C-Fos, Dopamine receptors and 5HT1A expression in the ventral tegmental area, accumbens nucleus and prefrontal cortex. Significantly, GAL(1-15) reduced the context-induced alcohol relapse. These results open up the possibility to use GAL(1-15) as a novel strategy in AUD.

Physiology, signaling, and pharmacology of galanin peptides and receptors: three decades of emerging diversity.

Galanin was first identified 30 years ago as a "classic neuropeptide," with actions primarily as a modulator of neurotransmission in the brain and peripheral nervous system. Other structurally-related peptides-galanin-like peptide and alarin-with diverse biologic actions in brain and other tissues have since been identified, although, unlike galanin, their cognate receptors are currently unknown. Over the last two decades, in addition to many neuronal actions, a number of nonneuronal actions of galanin and other galanin family peptides have been described. These include actions associated with neural stem cells, nonneuronal cells in the brain such as glia, endocrine functions, effects on metabolism, energy homeostasis, and paracrine effects in bone. Substantial new data also indicate an emerging role for galanin in innate immunity, inflammation, and cancer. Galanin has been shown to regulate its numerous physiologic and pathophysiological processes through interactions with three G protein-coupled receptors, GAL1, GAL2, and GAL3, and signaling via multiple transduction pathways, including inhibition of cAMP/PKA (GAL1, GAL3) and stimulation of phospholipase C (GAL2). In this review, we emphasize the importance of novel galanin receptor-specific agonists and antagonists. Also, other approaches, including new transgenic mouse lines (such as a recently characterized GAL3 knockout mouse) represent, in combination with viral-based techniques, critical tools required to better evaluate galanin system physiology. These in turn will help identify potential targets of the galanin/galanin-receptor systems in a diverse range of human diseases, including pain, mood disorders, epilepsy, neurodegenerative conditions, diabetes, and cancer.

Influence of chronic administration of antidepressant drugs on mRNA for galanin, galanin receptors, and tyrosine hydroxylase in catecholaminergic and serotonergic cell-body regions in rat brain.

Activity of locus coeruleus (LC) neurons and release of the peptide galanin (GAL), which is colocalized with norepinephrine (NE) in LC neurons, has been implicated in depression and, conversely, in antidepressant action. The present study examined the influence of chronic administration (for 14days, via subcutaneously-implanted minipump) of antidepressant (AD) drugs representing three different classes (tricyclic [desipramine], selective serotonin reuptake inhibitor [SSRI] [paroxetine], and monoamine oxidase inhibitor [MAOI] [phenelzine]) on mRNA for GAL, GAL receptors (GalR1, GalR2, and GalR3), and tyrosine hydroxylase (TH), the rate-limiting enzyme for NE synthesis, in four brain regions--LC, A1/C1, dorsal raphe (DRN), and ventral tegmentum (VTA) of rats. Consistent with previous findings that chronic administration of AD drugs decreases activity of LC neurons, administration of AD drugs reduced mRNA for both GAL and TH in LC neurons. GAL and TH mRNA in LC neurons was highly correlated. AD drugs also reduced GAL and TH mRNA in A1/C1 and VTA but effects were smaller than in LC. The largest change in mRNA for GAL receptors produced by AD administration was to decrease mRNA for GalR2 receptors in the VTA region. Also, mRNA for GalR2 and GalR3 receptors was significantly (positively) correlated in all three predominantly catecholaminergic brain regions (LC, A1/C1, and VTA). Relative to these three brain regions, unique effects were seen in the DRN region, with the SSRI elevating GAL mRNA and with mRNA for GalR1 and GalR3 being highly correlated in this brain region. The findings show that chronic administration of AD drugs, which produces effective antidepressant action, results in changes in mRNA for GAL, GAL receptors, and TH in brain regions that likely participate in depression and antidepressant effects.

Galanin and spinal pain mechanisms: past, present, and future.

Since the discovery of galanin in 1983, one of the most frequently suggested physiological function for this peptide is pain modulation at the level of the spinal cord. This notion, initially based on the preferential distribution of galanin in dorsal spinal cord, has been supported by results from a large number of morphological, molecular, and functional studies. It is generally agreed that spinally applied galanin produces a biphasic, dose-dependent effect on spinal nociception through activation of GalR1 (inhibitory) or GalR2 (excitatory) receptors. Galanin also appears to have an endogenous inhibitory role, particularly after peripheral nerve injury when the synthesis of galanin is increased in sensory neurons. In recent years, small molecule ligands of galanin receptors have been developed, which may lead to the development of analgesic drugs, which affects the galanin system at the spinal cord level.

Neuroprotective role for galanin in Alzheimer's disease.

Galanin (GAL) and GAL receptors (GALR) are overexpressed in degenerating brain regions associated with cognitive decline in Alzheimer's disease (AD). The functional consequences of GAL plasticity in AD are unclear. GAL inhibits cholinergic transmission in the hippocampus and impairs spatial memory in rodent models, suggesting that GAL overexpression exacerbates cognitive impairment in AD. By contrast, gene expression profiling of individual cholinergic basal forebrain (CBF) neurons aspirated from AD tissue revealed that GAL hyperinnervation positively regulates mRNAs that promote CBF neuronal function and survival. GAL also exerts neuroprotective effects in rodent models of neurotoxicity. These data support the growing concept that GAL overexpression preserves CBF neuron function, which may in turn delay the onset of symptoms of AD. Further elucidation of GAL activity in selectively vulnerable brain regions will help gauge the therapeutic potential of GALR ligands in the treatment of AD.

Effects of galanin on monoaminergic systems and HPA axis: Potential mechanisms underlying the effects of galanin on addiction- and stress-related behaviors.

Like a number of neuropeptides, galanin can alter neural activity in brain areas that are important for both stress-related behaviors and responses to drugs of abuse. Accordingly, drugs that target galanin receptors can alter behavioral responses to drugs of abuse and can modulate stress-related behaviors. Stress and drug-related behaviors are interrelated: stress can promote drug-seeking, and drug exposure and withdrawal can increase activity in brain circuits involved in the stress response. We review here what is known about the ability of galanin and galanin receptors to alter neuronal activity, and we discuss potential mechanisms that may underlie the effects of galanin on behaviors involved in responses to stress and addictive drugs. Understanding the mechanisms underlying galanin's effects on neuronal function in brain regions related to stress and addiction may be useful in developing novel therapeutics for the treatment of stress- and addiction-related disorders.

Galanin potentiates supramaximal caerulein-stimulated pancreatic amylase secretion via its action on somatostatin secretion.

Galanin inhibits pancreatic amylase secretion from mouse lobules induced by physiological concentrations of caerulein via an insulin-dependent mechanism. We aimed to determine the effect and elucidate the mechanism of action of exogenous galanin on pancreatic amylase secretion induced by supramaximal concentrations of caerulein. Amylase secretion from isolated murine pancreatic lobules was measured. Lobules were coincubated with galanin (10(-12)-10(-7) M) and caerulein (10(-7) M). Lobules were preincubated with atropine (10(-5) M), tetrodotoxin (10(-5) M), diazoxide (10(-7) M), or the galanin antagonist galantide (10(-12)-10(-7) M) for 30 min followed by incubation with caerulein alone, or combined with galanin (10(-12) M). Lobules were also coincubated with combinations of galanin (10(-12) M), caerulein, octreotide (10(-12)-10(-7) M) or cyclo-(7-aminoheptanoyl-Phe-D-Trp-Lys-Thr[BZL]), a somatostatin receptor antagonist (10(-9) M). Amylase secretion was expressed as percent of total lobular amylase. Caerulein stimulated amylase secretion to 124% of control. Diazoxide pretreatment abolished the caerulein-stimulated amylase secretion, whereas atropine or tetrodotoxin caused a partial inhibition. Galanin (10(-12)-10(-7) M) potentiated caerulein-stimulated amylase secretion to 160% of control. Preincubation with a combination of atropine and diazoxide abolished the potentiating effect of galanin, indicating muscarinic receptor and insulin mediation. Preincubation with galantide abolished the galanin effect, implying galanin receptor involvement. Coincubation with caerulein, galanin, and octreotide significantly reduced the potentiating effect galanin. However, coincubation with the somatostatin receptor antagonist, alone or in combination with galanin, significantly increased caerulein-stimulated amylase secretion to a level comparable to the galanin potentiation. Taken together, these data suggest that, at supramaximal caerulein concentrations, galanin acts via its receptors to further increase caerulein-stimulated amylase secretion by inhibiting the caerulein-induced release of somatostatin.

The galanin peptide family: receptor pharmacology, pleiotropic biological actions, and implications in health and disease.

The galanin peptide family consists of the "parental" galanin, galanin-message-associated peptide (GMAP) which derives from the same peptide precursor gene product as galanin, galanin-like peptide (GALP) encoded by a different gene, and the recently discovered peptide alarin which is encoded by a splice variant of the GALP gene. The galanin receptor family currently comprises 3 members, GalR1, GalR2, and GalR3, which are all G-protein-coupled receptors. This review will provide an overview of the comprehensive, pharmacological characterization of endogenous and synthetic galanin receptor ligands and their interactions with the galanin receptors, a summary of the various (pleiotropic) biological actions of galanin and GALP (and alarin), and briefly discuss the implications of pathological changes for health and disease and potential clinical therapeutics. Since its discovery more than 20 years ago, a large number of putative physiological functions have been ascribed to galanin, and active research still continues to validate these functions and determine their importance for physiology and pathology. Since the more recent identification of GALP, considerable research has identified functions for this peptide in the central nervous system (CNS), but the identity of its preferred, native receptor is still unknown. Little is known of the role of alarin apart from evidence of its expression and a vasoactive action in the skin. The wide range of functions of the galanin peptide family indicates an essential role for galanin signaling in "mind and body homeostasis" and a potential therapeutic efficacy in a variety of human diseases, particularly epilepsy, Alzheimer's disease, and diabetes.

The brain galanin receptors: targets for novel antidepressant drugs.

Our present view that the mood disorders involve dysfunction of monoaminergic system is a result of important clinical and preclinical observations over the past 40 years. The therapeutic efficacy of drugs such as the tricyclic antidepressants (TCAs), monoamine oxidase inhibitors, selective serotonin reuptake inhibitors (SSRIs) and lately of SNRIs (serotonin and norepinephrine reuptake inhibitors) helped to shape our view that mood regulation involves the monoaminergic systems in some way. It is thus little surprising when the neuropeptide, galanin, is discovered to coexist with norepinephrine (NE) in locus coeruleus (LC) neurons and with serotonin (5-HT) in the dorsal raphe nucleus (DRN) neurons, a link between galanin mediated signaling and mood regulation is sought. Galanin receptors are expressed in brain structures that are involved in the regulation of mood such as frontal cortex, amygdala, hypothalamus, LC, DRN and hippocampus. It is almost an accident of research fate that the potent effects of galanin on cognitive performance and seizure threshold have led galanin research to focus on the hippocampus where the neuropeptide is present in cholinergic and noradrenergic afferents and where the receptor density is much lower than in the monoaminergic nuclei. Hopefully it is not too late to report on the recent inroads into the roles of galanin and of galanin receptor subtypes 2 and 3 (GalR2 and GalR3) in mood regulation in animal models as well as in human patients with major depression. A body of existing data suggests that GalR2 signaling leads to antidepressant-like, anticonvulsant and neurogenesis-promoting effects, a spectrum of activities that are commonly associated with efficacious antidepressants. Similarly, GalR3 antagonists exhibit anxiolytic and antidepressant-like activity, another clinically useful combination for the treatment of mood disorders. Since both GalR2 and GalR3 are G-protein coupled receptors (GPCRs), a favorite target class for drug development, we believe that the pace of developing galaninergic antidepressants will increase significantly from now on.

Galanin and its receptors in neurological disorders.

Galanin is a highly inducible neuropeptide, showing distinct up-regulation after pathological disturbance within the nervous system. Significant increase in galanin expression is observed after peripheral nerve injury, in the basal forebrain in Alzheimer's disease (AD), during neuronal development, and after stimulation with estrogen, while seizure activity deplete galanin in the hippocampus. A wide distribution of galanin and its receptors is seen in the nervous system, often in co-localization with classical neurotransmitters and other neuromodulators. Galanin acts predominantly as an inhibitory, hyperpolarizing neuromodulator on neurotransmitter and glucose-induced insulin release and stimulates growth hormone and prolactin secretion. Galanin has been implicated in several higher order physiological functions including cognition, feeding, nociception, mood regulation, and neuroendocrine modulation. The effects of galanin are mediated via three G protein-coupled receptors with different functional coupling. Moderate to low pharmacological effects are seen by galanin under physiological conditions, in contrast to its dramatic effects on the nervous system after neuronal disturbance. This pathophysiological heavy function of the galaninergic system renders it an interest for disorders such as AD, depression, and epilepsy in terms of side effects. Some properties of the galaninergic system are of particular importance in the context of neurodegeneration. Galanin is highly inducible, 10- to 100-fold, upon nerve injury, whereas most neuropeptides are induced 1.5- to 2-fold. Galanin is strongly neurotrophic during development as well as subsequent to injury. Whereas other neurotrophic neuropeptides like VIP and PACAP activate cAMP synthesis, galanin suppresses its synthesis, yet it is a strong neurotrophic as well as neuroprotective agent. As we delineate which galanin receptor subtype mediates neuroprotective and neurotrophic effects and which mediates synaptic inhibition, pharmacological use of receptor- selective galaninergic ligands for treatment in neurodegenerative diseases are coming closer.

Expression of galanin receptor messenger RNAs in different regions of the rat gastrointestinal tract.

Galanin effects are mediated by three G-protein-coupled receptors: galanin receptor 1 (GalR1), GalR2 and GalR3. We quantified mRNA levels of GalR1, GalR2 and GalR3 in the rat stomach, small and large intestine using real-time RT-PCR. All three GalR mRNAs were detected throughout the gut at different levels. GalR1 and GalR2 mRNA levels were higher in the large than in the small intestine. GalR2 mRNA was most abundant in the stomach. GalR3 mRNA levels were generally quite low. The differential regional distribution of GalRs suggests that the complex effects of galanin in the gut are the result of activating multiple receptor subtypes, whose density, subtype and signaling vary along the gastrointestinal tract.

Regulation of feeding by galnon.

Galanin is a neuropeptide that has been implicated in multiple bioactivities, inter alia eating disorders. In this study, we have examined the effects of galnon, a novel low molecular weight galanin receptor ligand. Previous studies have shown that galnon acts as a systemically active, blood-brain barrier crossing agonist on galanin signaling both in vitro and in vivo, inhibiting pentylenetetrazole-induced seizures. Here, intracerebroventricular (10-20 microg) and intraperitoneal (1.5-5 mg/kg) administration of galnon induced a strong, dose-dependent reduction of food intake in rats and mice. This reduction in feeding occurred without reducing general activity and was shown to be attenuated by an intracerebroventricular administration of M35, a peptide galanin antagonist. These data demonstrate that galnon is a promising tool for studies of the involvement of galanin in feeding disorders and other behavioral processes.

Novel G protein-coupled receptors as pain targets.

G protein-coupled receptors (GPCRs) and their ligands play a number of important roles in the modulation of acute and chronic pain. Indeed, opioid and cannabinoid ligands are of established therapeutic value for pain management, and further exploitation of the specific GPCR subtypes (delta-opioid, CB1 and CB2) for these ligands may yield more selective, potent analgesics with favorable side effects. More recent identification of a number of other GPCRs involved in pain pathways (eg, sensory neuron specific receptors) and selective ligands that modulate pain transmission, has highlighted further therapeutic opportunities. A further challenge to understanding pain modulation and an additional dimension for targeting analgesia is the discovery of GPCR heteromerization and accessory and regulatory proteins, such as regulator of G protein-signaling proteins, involved in expression and regulation of GPCR.