HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Summary Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Related articles in MI Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Counts, S. E. Articles by Mufson, E. J. Search for Related Content PubMed PubMed Citation Articles by Counts, S. E. Articles by Mufson, E. J.

Galanin in Alzheimer Disease

¹ Department of Neurological Sciences, Rush-Presbyterian-St. Luke’s Medical Center, 2242 West Harrison Street, Chicago, IL 60612,
² Center for Dementia Research, Nathan Kline Institute, Departments of Psychiatry and Physiology & Neuroscience, New York University School of Medicine, 140 Old Orangeburg Road, Orangeburg, NY 10962
³ Department of Biological Sciences, California State University, Los Angeles, 5151 State University Drive, Los Angeles, CA 90032

	SUMMARY

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
Galanin (GAL) and GAL receptors (GALR) are overexpressed in limbic brain regions associated with cognition in Alzheimer disease (AD). The functional consequences of this overexpression are unclear. Because GAL inhibits cholinergic transmission and restricts long-term potentiation in the hippocampus, GAL overexpression may exacerbate clinical features of AD. In contrast, GAL expression increases in response to neuronal injury, and galaninergic hyperinnervation prevents the decreased production of protein phosphatase 1 subtype mRNAs in cholinergic basal forebrain neurons in AD. Thus, GAL may also be neuroprotective for AD. Further elucidation of GAL activity in selectively vulnerable brain regions will help gauge the therapeutic potential of GALR ligands for the treatment of AD.

	INTRODUCTION

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
Galanin (GAL) is distributed throughout the mammalian central nervous system (CNS), where it modulates several ascending neurotransmitter systems, including the cholinergic, noradrenergic, serotoninergic, and neuroendocrine pathways (1–9) . Three G protein–coupled GAL receptors (GALR1, GALR2, and GALR3) signal in a tissue- and cell-specific manner to elicit a wide array of biological and behavioral responses (10–13) .

An important behavioral consequence of GAL activity is the regulation of cognitive function by GALR-mediated actions in the basal forebrain, entorhinal cortex, hippocampus, and amygdala (1 , 2 , 14–26) . In particular, GAL regulates the activity of cholinergic basal forebrain (CBF) neurons that provide the major cholinergic innervation of the cortex and hippocampus (27) and play a key role in memory and attention (15 , 26 , 28–30) . CBF neurons undergo selective degeneration during later stages of Alzheimer disease (AD) that correlates with disease duration and degree of cognitive impairment (31) . We and others have made the striking observation that GAL-containing fibers within the CBF undergo hypertrophy and hyperinnervate surviving CBF neurons in end-stage AD (32–34) . GAL levels are increased throughout the cortex in AD, and GALR binding sites are amplified in the CBF, hippocampus, entorhinal cortex, and amygdala during the course of the disease (20 , 23 , 35–37) . However, the role that GAL overexpression plays in AD is still unclear. GAL inhibits acetylcholine (ACh) release in rodent hippocampal preparations and disrupts cognitive performance in animals (1 , 2 , 15 , 19 , 26 , 38–40) , suggesting that GAL overexpression in AD basal forebrain may hamper ACh-mediated functions of remaining CBF neurons. Hence, excess GAL may exacerbate the cholinergic deficit seen in end-stage AD. On the other hand, GAL promotes neuritogenesis following sensory neuronal injury (41–43) , raising the possibility that increased GAL promotes neuronal survival to combat AD. This review focuses on galaninergic plasticity in brain regions that are associated with cognition in AD and on the therapeutic potential of GALR ligands for the treatment of this debilitating disease.

	GALANIN

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
GAL is a twenty-nine–residue (thirty in humans) peptide cleavage product of preprogalanin (44–46) . The preprogalanin gene has been cloned from several species (47–49), and its promoter contains binding sequences for regulatory factors whose activities are regulated by nerve growth factor (NGF), estrogen, protein kinase C, and adenosine 3’,5’ monophosphate (cAMP) (50–52) . The N-terminal fifteen amino acids of GAL are highly conserved in all species examined—from insects to humans—and are sufficient for high-affinity receptor binding (53–57) . Metabolic studies indicate that the GAL C terminus protects the N-terminal portion from proteolytic attack, resulting in increased bioavailability (58 , 59) .

GAL-immunoreactive (-ir) profiles have been described throughout the mammalian CNS in numerous species (34 , 60–66) . For example, in the mouse brain, GAL-ir neurons and fibers are found in several brain structures important for cognition, including: the cerebral cortex; the lateral and medial septum; vertical and horizontal limbs of the diagonal band of Broca and nucleus basalis of Meynert; the central and medial amygdaloid nuclei; and in the dentate gyrus and CA3 regions of the hippocampus (61 , 65) (Figure 1).

View larger version (18K): [in this window] [in a new window]   Figure 1. Schematic representation of a sagittal section of the mouse brain showing the distribution of GAL immunoreactivity in neurons (filled circles). A5, A5 noradrenergic cells; ac, anterior commissure; AMG, amygdala; AO, anterior olfactory nucleus; AOB, accessory olfactory bulb; BST, bed nucleus of the stria terminalis; C, cerebral cortex; cc, corpus callosum; CE, cerebellum; CL, central lateral thalamic nucleus; CPu, caudate-putamen complex; DB, diagonal band of Broca; G1, glomerular layer of the olfactory bulb; H, hippocampus; Hy, hypothalamus; IC, inferior colliculus; IO, inferior olive; LC, locus coeruleus; LV, lateral ventricle; M, mesencephalic tegment; OB, olfactory bulb; OPT, olivary pretectal nucleus; RF, reticular formation; S, septum; SC, superior colliculus; SO, supraoptic nucleus; Sol, solitary tract nucleus; SOR, retrochiasmatic supraoptic nucleus; SS, superior salivatory nucleus; SuC, subcoreuleus nucleus; Th, thalamus; 10, dorsal motor nucleus of vagus nerve; 12, hypoglossal nucleus.

	GALANIN RECEPTORS

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
The activity of GAL in the CNS is mediated by at least three GALR subtypes termed GALR1, GALR2, and GALR3 [for reviews see (10–13) ]. GALRs are members of the integral membrane, rhodopsin-like G protein–coupled receptor superfamily. GALR subtypes show substantial differences in their primary sequence, distribution, and functional coupling that may contribute to a diverse repertoire of signaling activities in various CNS pathways. Table 1 summarizes GALR subtype-specific expression patterns in brain regions associated with cognition, and Table 2 describes the in vitro activities of the cloned receptors. In general, GALR1 activation reduces cAMP concentrations, opens GIRK channels, or stimulates mitogen-activated protein kinase (MAPK) activity in a pertussis toxin (PTX)-sensitive manner, consistent with GALR1 coupling to G_i/o proteins (79–82) . GALR2 activation increases inositol phosphate hydrolysis, mediates the release of Ca²⁺ into the cytoplasm from intracellular stores, and opens Ca²⁺ -dependent chloride channels in a PTX-resistant manner, indicating that GALR2 couples to G_q/11 proteins (80 , 82–86) . GALR3, like GALR1, elicits an inhibitory response by opening GIRK channels in a PTX-sensitive manner (81 , 85) . Future research aimed at understanding the distribution and activities mediated by endogenous GALR subtypes will be critical for gauging the therapeutic efficacy of various GALR ligands for the amelioration of AD symptoms. The three GALRs are also found extensively in peripheral tissues, including the digestive tract (79 , 85 , 87) , which may pose contraindications for drugs designed to modulate GALR activity in the CNS. Moreover, membrane binding studies demonstrating high affinity binding of GAL(1–15) but not full-length GAL in rat hippocampus (88–90) , and high affinity binding of GAL(3–29) but not GAL(1–15) in rat anterior pituitary (91), suggest the presence of unidentified GALR(s).

	GALANIN IN ALZHEIMER DISEASE

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

View larger version (57K): [in this window] [in a new window]   Figure 2. GAL plasticity in the basal forebrain nucleus basalis in AD. A. Photomicrograph shows a magnocellular cholinergic nucleus basalis neuron immunostained with the CBF neuronal marker p75NTR (brown reaction product) and innervated by GAL-ir fibers (dark blue reaction product) in aged control brain. The GAL-ir parvicellular neuron contacting the CBF neuron is visible. B. The photomicrograph shows striking hyperinnervation of GAL fibers impinging upon a nucleus basalis CBF neuron in AD.

View larger version (77K): [in this window] [in a new window]   Figure 3. Plasticity of GAL binding sites in early and late stage AD. Autoradiograms showing the regional distribution of [125I]-hGAL binding to GALRs in the aged control (A, D) brain as compared to early (B, E) and late stage (C, F) Alzheimer disease. Pseudocolor density maps show changes in [125I]-hGAL labeling in the basal forebrain (A–C), entorhinal cortex (D–F), and amygdala (D–F) during the progression of the disease. There is an increase in labeling in the anterior subfield of the nucleus basalis in late AD (compare C with A and B). In contrast, the entorhinal cortex displays increased expression of GAL binding only in early AD (compare E with D and F). Likewise, GAL binding increases dramatically in the central nucleus and cortico-amygdaloid transition area of the amygdala in early AD and returns to levels similar to controls by late AD. AB, accessory basal nucleus of the amygdala; ac, anterior commissure; BL, basolateral nucleus (amygdala); BNST, bed nucleus of the stria terminalis; CAT, cortico-amygdaloid transition area; Ce, central nucleus (amygdala), Ch4a, anterior cholinergic cell groups of the nucleus basalis; Co, cortical nucleus (amygdala); ENT, entorhinal cortex; Gp, globus pallidus; ic, internal capsule; L, lateral nucleus (amygdala); Pt, putamen. Colorimetric scale (inset) correlates pseudocolor density with [125I]-hGAL binding density.

	POTENTIAL TRIGGERS OF GAL PLASTICITY IN AD

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
The pathophysiological factors that induce GAL plasticity in the AD brain have been a matter of great speculation. In general, the spatio-temporal pattern of GAL overexpression coincides with the degeneration of select neuronal populations during the course of the disease. Limbic areas (e.g., entorhinal cortex and amygdala) that degenerate in the prodromal stage of AD (98 , 99 , 102) are sites that overexpress GAL early in disease (23) , whereas the plastic response occurs during the later stages of AD within the cholinergic system (20 , 32–34) . A parsimonious explanation for these phenomena is that GAL systems hypertrophy in response to neuronal injury. In this regard, observations that GAL plasticity does not occur in the nucleus basalis during the prodromal stage of AD (93) when CBF neurons are preserved (103) suggest that GAL hyperinnervation of the nucleus basalis in end-stage AD is an attempt to rescue degenerating CBF neurons and to maintain cholinergic function. Recently, we tested whether neurochemical lesions of CBF neurons of the horizontal limb–diagonal band (HDB) by the selective cholinergic cell toxin 192IgG–saporin would induce GAL hyperinnervation of this CBF subfield (16) . The immunotoxic lesion caused a 30% loss of cholinergic cells ipsilateral to the lesion. Increased GAL immunoreactivity with a thickening of GAL-ir fibers in both ipsilateral and contralateral HDB subfields was observed as early as one hour and as late as twenty-four weeks after the lesion (Figure 4). The number of cholinergic neurons did not recover to control levels after six months, nor did the density of GAL immunoreactivity decrease to control levels in that same period. These findings of increased local GAL following neurochemical lesioning of the HDB by either the selective cholinergic cell toxin 192IgG–saporin (16) or ibotenic acid (104) support the notion that GAL plasticity is triggered by neuronal damage.

View larger version (149K): [in this window] [in a new window]   Figure 4. GAL innervation of basal forebrain HDB following immunolesion with the selective cholinergic cell toxin 192IgG–saporin. Photomicrograph of ipsilateral lesioned HDB shows p75NTR-ir CBF neurons (brown reaction product; arrowhead) and p75NTR-ir CBF neurons containing heavy deposits of GAL immunoreactivity (dark blue reaction product; arrow). The beaded and punctate dark blue deposits resembling GAL-ir axons and terminals covering some of the p75NTR-ir dendrites are visible. Scale bar = 50 mm.

A final factor underlying GAL plasticity in AD may be related to ApoE genotype, the major genetic risk factor for late-onset sporadic AD (108–110) . Comparison of GAL concentrations in the nucleus basalis between AD subjects carrying at least one apoE4 allele (apoE3,4 or apoE4,4) and AD subjects lacking an apoE4 allele revealed a trend (p = 0.12) for a twofold increase in GAL concentration in the nucleus basalis in the presence of apoE4 (Mufson, unpublished observations). ApoE4 gene dosage is inversely related to choline acetyltransferase (ChAT, the synthetic enzyme for ACh) activity and to ACh binding levels in the hippocampus and temporal cortex of AD cases (111 , 112) . Moreover, the presence of apoE4 is associated with reduced efficacy of cholinesterase inhibitor therapy in AD (112) . Thus, the influence of apoE genotype on cholinergic function may contribute to GAL overexpression in the basal forebrain in AD.

	NEURONAL ORIGIN OF GAL HYPERINNERVATION IN AD

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
The source(s) of GAL hyperinnervation and GALR plasticity in AD remain unclear. For instance, it is unlikely that the few small GAL-ir neurons within the basal forebrain and preoptic area account for the rich galaninergic fiber plexus seen within this region (33 , 34 , 60 , 62) . One potential source of GAL fiber innervation to the basal forebrain may be the locus coeruleus (113 , 114) . The coeruleo-forebrain pathway is well characterized in the mammalian CNS (115) , and GAL-ir cells within the locus coeruleus also exhibit enhanced GAL immunoreactivity in AD (116) . However, the human locus coeruleus does not appear to contain numerous GAL-ir cells (62) . Another source of GAL fibers may emanate from the central nucleus of the amygdala and course through the basal forebrain en route to the substantia innominata, bed nucleus of the stria terminalis, and hypothalamus (34) . Although the cells of origin of this GAL-ir bundle are undetermined, the input may arise from the extended amygdaloid complex, which contains numerous GAL-ir cell bodies (34 , 117) and displays hypertrophy of GAL-ir fibers in AD (Mufson, unpublished observations).

	GAL PLASTICITY AS A DETRIMENTAL FACTOR IN AD

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
The functional consequences of GAL plasticity in AD are of intense interest. The most compelling evidence that GAL overexpression exacerbates the presentation of AD comes from rodent studies showing that GAL inhibits ACh release in the hippocampus and disrupts cognitive performance (1 , 2 , 19 , 26 , 38–40) . GAL inhibits the evoked release of ACh in the ventral hippocampus of the rat in a concentration-dependent manner and blocks the slow cholinergic excitatory post-synaptic potential (EPSP) induced by the release of endogenous ACh onto CA1 pyramidal neurons (1) . Furthermore, administration of GAL into the medial septum–diagonal band complex or ventral hippocampus impairs cognitive performance on several spatial learning and working memory tasks in rats (19 , 26) . GAL interference of cholinergic transmission during these tasks is particularly evident in the presence of muscarinic ACh receptor antagonists or cholinergic immunotoxin lesions (38 , 40 , 77) .

A role for GAL in glutamate-mediated long-term potentiation (LTP) in the hippocampus may also contribute to GAL’s effects on memory. Electrophysiological studies show that GAL restricts LTP at both perforant path-dentate gyrus and Schaffer collateral-CA1 synapses (14 , 18 , 22 , 24) . GAL may impact glutamatergic transmission in the hippocampus by reducing evoked glutamate release (18 , 75 , 78 , 118) . However, a recent study demonstrated that while GAL inhibits LTP at CA1 synapses, it has no effect on ionotropic -amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) or N -methyl-D-aspartate (NMDA) glutamate receptor-mediated EPSPs, suggesting that GAL acts through a postsynaptic GALR to inhibit LTP-related signaling cascades (14) .

The development of transgenic mice that overexpress murine GAL under control of the dopamine ß -hydroxylase promoter (GAL-tg) has facilitated the study of GAL overexpression in the brain (25 , 119) (Table 3). GAL-tg mice display increased GAL fiber density in the basal forebrain and a 3-fold reduction in the number of ChAT-ir neurons in the HDB subfield (25) . In situ hybridization experiments demonstrated a down-regulation of ChAT mRNA per cell within the HDB without a difference in the number of ChAT mRNA-containing HDB cells in GAL-tg mice (119) , suggesting that GAL overexpression in the basal forebrain of GAL-tg mice selectively reduces the expression of the cholinergic neuron phenotype. Spatial navigation testing with the Morris water task in GAL-tg mice showed a complete lack of selective search on the probe trial at eight, sixteen, and twenty-four months of age (25) . GAL-tg mice displayed normal swim speed, swimming patterns across time bins, and visible and hidden platform acquisition. Thus, the GAL-tg mice could perform all of the procedures in the Morris water maze but could not generate a cognitive map of the spatial environment to solve the probe test, the most challenging component of the this task (25 , 119) . The Morris task requires an intact, functioning hippocampus (25) , thus, it seems likely that the mechanisms underlying the observed deficits in GAL-tg mice include inhibitory neuromodulation by GAL in the hippocampus. Along these lines, GAL expression is increased as much as 4-fold in the hippocampus of GAL-tg compared to wild-type (WT) mice (120) , and GAL overexpression reduces glutamate release and restricts LTP at perforant path-dentate gyrus synapses in GAL-tg hippocampal slices (18) . Similarly, transgenic mice that overproduce GAL expressed from a platelet-derived growth factor B promoter (GalOE) had a 4-fold increase in hippocampal GAL and reduced frequency facilitation of field EPSPs—a form of short term synaptic plasticity—at mossy fiber-CA3 synapses in GalOE hippocampal slices (121) (Table 3).

	GAL PLASTICITY AS A NEUROPROTECTIVE FACTOR IN AD

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
An alternative hypothesis is that GAL is neuroprotective in AD. A role for GAL in cholinergic cell survival was demonstrated in a knockout mouse model carrying a targeted loss-of-function mutation in the GAL gene (GAL-KO) (13 , 22) (Table 3). GAL-KO mice show significant decreases in the number of ChAT-ir neurons in the basal forebrain medial septum (MS) and vertical limb–diagonal band (VDB) subfields. Moreover, these areas and the nucleus basalis displayed a significant decrease in the number of neurons expressing TrkA, the high affinity receptor for the cholinergic survival protein NGF (22) . Hence, GAL may act as a trophic factor for CBF neurons during development. On the other hand, preliminary data in our lab has demonstrated that the number of MS and VDB subfield neurons expressing the p75^NTR neurotrophin receptor is similar in WT and GAL-KO mice (122) . Because p75^NTR is a well-established cholinergic marker (123) , these findings suggest that GAL is required for regulating the cholinergic phenotype of basal forebrain neurons during development. GAL-KO mice exhibit age-related decreases in evoked ACh release in the hippocampus, inhibition of LTP in the CA1 region of the hippocampus, and age-dependent behavioral decline in the Morris water maze (22) , indicating an excitatory role for GAL in these animals. Significantly, a recent electrophysio-logical study using rat primary basal forebrain diagonal band cultures showed that exogenous GAL reduced an array of inhibitory K⁺ currents in cholinergic neurons (17) . GAL also increased the excitability of these cells under current-clamp conditions (17) . Thus, GAL overexpression in AD may improve cognition by promoting the survival or cholinergic tone of CBF neurons and by preserving hippocampal LTP.

Additional findings support a role for galanin in neuronal repair. GAL expression increased 120-fold following peripheral nerve injury in dorsal root ganglia (DRG) preparations (43) . GAL promotes neuritogenesis in cultured DRG explants of WT mice and rescues a deficiency in neurite outgrowth observed in DRG explants of GAL-KO mice (41 , 42) . GAL mRNA and protein are also increased near lesions in several rat models of CNS degeneration, including decortication (i.e., cortical transection), lesioning of the entorhinal cortex and ventral hippocampus (124 , 125) , lesioning of the CBF (16 , 104) , and spinal cord axotomy (126) . Thus, increased GAL expression may occur in vulnerable brain regions in response to neuronal damage. Notably, GAL hyperinnervation and GAL binding sites in AD are greatest in the anterior subfields of the basal forebrain where the least amount of neural degeneration occurs, whereas GAL overexpression is least found in the posterior subfields of the basal forebrain where degeneration is greatest (20 , 33 , 95 , 96) .

We have used single cell RNA amplification technology (127–130) to address the genetic consequences of GAL hyperinnervation upon CBF neurons (131) . Using postmortem brain tissue from cognitively intact and end-stage AD subjects, single anterior nucleus basalis neurons immunopositive for the cholinergic p75^NTR in the presence or absence of hyperinnervating GAL-ir fibers [p75^NTR (GAL⁺ ) or p75^NTR (GAL^– ), respectively] were microaspirated and processed for linear RNA amplification. Radiolabeled RNA probes generated from single cells were hybridized to custom-designed cDNA arrays (127–130) (Figure 5A). Expression of protein phosphatases PP1 and PP1 mRNA in p75^NTR (GAL^– ) neurons from AD brains was inhibited compared to phosphatase expression in p75^NTR (GAL^– ) neurons from control brains (Figure 5B). However, GAL-hyperinnervated p75^NTR (GAL⁺ ) neurons do not display decreased expression of PP1 and PP1 mRNA in AD brain (Figure 5A, B). As the reduction of protein phosphatases has been associated with the evolution of neurofibrillary tangle formation (127 , 132 , 133) , this apparent maintenance of PP expression by GAL may be neuroprotective for CBF neurons. However, a thorough analysis of the genetic signature of p75^NTR (GAL^– ) and p75^NTR (GAL⁺ ) neurons will provide a more complete picture of the effects of GAL on gene expression in this cell group.

View larger version (50K): [in this window] [in a new window]   Figure 5. GAL innervation ameliorates down-regulation of protein phosphatase 1 (PP1) subtypes in AD nucleus basalis. Representative gene array (A) and histogram (B) shows a significant down-regulation of protein phosphatases PP1 (10% of control) and PP1 (12% of control) mRNA in p75NTR(GAL–)-ir CBF neurons in AD nucleus basalis, whereas GAL-hyperinnervated p75NTR(GAL+)-ir CBF neurons do not have decreased expression of PP1 or PP1 mRNA in AD. A total of twenty neurons were analyzed from normal control brains (n = 4 brains; 4–6 cells per brain); twenty-six neurons were analyzed from AD brains (n = 6 brains; 4–5 cells per brain) including 17 p75NTR(GAL–)-ir CBF neurons and 9 p75NTR(GAL+)-ir CBF neurons; *, p < 0.01 via ANOVA with Neuman–Keuls post hoc test for multiple comparisons.

	GAL RECEPTORS AS THERAPEUTIC TARGETS FOR AD

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
GALR1, GALR2, and GALR3 mRNAs are found in cell bodies of the rat basal forebrain (138–140) (Table 1). However, very few cholinergic cells in the rat basal forebrain colocalize with GALR1 mRNA (117 , 141) , suggesting that GALR2, GALR3, or both, might mediate postsynaptic GAL effects on CBF neurons. If GALR2 is a postsynaptic receptor on CBF neurons, then augmented GAL input might be coupled to phospholipase C activation, the principal GALR2-mediated pathway identified in cell culture studies (80 , 82 , 84–86) (Table 2). Activation of this pathway may improve cholinergic tone or survival of CBF neurons. Along these lines, the GALR2-specific agonist AR-M1896 (142) (Table 5) promotes neurite outgrowth in GAL-KO DRG explants in a PKC-dependent manner, whereas a GALR1-specific antagonist RWJ-57408 (143) (Table 5) was ineffective at blocking GAL-mediated neuritogenesis (42) . Alternatively, postsynaptic GALR2 or GALR3 may be coupled to adenylyl cyclase inhibition or GIRK activation (82 , 85 , 86) (Table 2), potentially inhibiting cholinergic function. Finally, colocalization studies in rodents do not preclude the possibility that GALR1 is present on human CBF neurons. Future efforts addressing the protein expression patterns (e.g., pre- or postsynaptic) in human AD-related brain regions and the signaling repertoires of native GALR subtypes in these structures will be critical to understanding GAL activity in cognition and the efficacy of targeting GALRs for the treatment of AD.

	CONCLUSIONS

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

Elliott J. Mufson, PhD , is the Alla V. and Solomon Jesmer Chair in Aging and Professor of Neurological Sciences at Rush-Presbyterian-St. Luke’s Medical Center, Chicago, IL. Sonsales de Lacalle, MD, PhD , is Assistant Professor of Biology at California State University, Los Angeles, CA. Stephen D. Ginsberg, PhD , is Assistant Professor in the Departments of Psychiatry, and Physiology and Neuroscience at New York University School of Medicine and the Center for Dementia Research, Nathan Kline Institute, Orangeburg, NY. Sylvia E. Perez, PhD , is Research Assistant Professor of Neurological Sciences at Rush-Presbyterian-St. Luke’s Medical Center, Chicago, IL. Scott E. Counts, PhD , is Research Assistant Professor of Neurological Sciences at Rush-Presbyterian-St. Luke’s Medical Center, Chicago, IL. Address all correspondence to EJM. Email: emufson{at}rush.edu; fax 312-563-3571.

	ACKNOWLEDGMENTS

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 
The authors would like to thank our colleagues we have worked with over the years in exploring the nature of GAL plasticity in AD: M. Basile, W. Benzing, R.P. Bowser, J.N. Crawley, D.C. Deecher, I. Hartonian, J.H. Kordower, D.C. Mash, R.A. Steiner, and D. Wynick. Support for our research is provided by the following grants NIA AG10688, AG 09466, AG14449, TGAG000259, AG19597, NS43939, CA94520, and the Alzheimer’s Association.

	References

TOP Summary Introduction Galanin Galanin Receptors Galanin in Alzheimer Disease Potential Triggers Of GAL... Neuronal Origin of GAL... GAL Plasticity As A... GAL Plasticity As A... GAL Receptors As Therapeutic... Conclusions References

 

1. Dutar, P., Lamour, Y. and Nicoll, R. A. Galanin blocks the slow cholinergic EPSP in CA1 pyramidal neurons from ventral hippocampus. Eur. J. Pharmacol. 164 , 355–360 (1989).
   The authors demonstrate that GAL exerts a presynaptic inhibitory effect on cholinergic terminals in the CA1 region of rat hipocampus by blocking the slow cholinergic EPSP induced by the release of endogenous ACh on the pyramidal neurons. This effect was reversible and mimicked by atropine.
2. Fisone, G., Wu, C. F., Consolo, S., Nordstrom, O., Brynne, N., Bartfai, T., Melander, T. and Hokfelt, T. Galanin inhibits acetylcholine release in the ventral hippocampus of the rat: histochemical, autoradiographic, in vivo, and in vitro studies. Proc. Natl. Acad. Sci. U. S. A. 84 , 7339–7343 (1987).
   The authors demonstrate a high density of [¹²⁵I] GAL binding sites in the rat ventral but not dorsal hippocampus that are sensitive to fimbrial and septal transection. Moreover, the authors show for the first time that GAL reduces the evoked release of ACh in a concentation-dependent manner in the vental but not dorsal hippocampus.[Abstract/Free Full Text]
3. Kehr, J., Yoshitake, T., Wang, F. H., Razani, H., Gimenez-Llort, L., Jansson, A., Yamaguchi, M. and Ogren, S. O. Galanin is a potent in vivo modulator of mesencephalic serotonergic neurotransmission. Neuropsychopharmacology 27 , 341–356 (2002)[CrossRef][Medline]
4. Levin, M. C., Sawchenko, P. E., Howe, P. R., Bloom, S. R. and Polak, J. M. Organization of galanin-immunoreactive inputs to the paraventricular nucleus with special reference to their relationship to catecholaminergic afferents. J. Comp. Neurol. 261 , 562–582 (1987).[CrossRef][Medline]
5. Merchenthaler, I. The hypophysiotropic galanin system of the rat brain. Neuroscience 44 , 643–654 (1991).[CrossRef][Medline]
6. Ma, X., Tong, Y. G., Schmidt, R. et al. Effects of galanin receptor agonists on locus coeruleus neurons. Brain Res. 919 , 169–174 (2001).[CrossRef][Medline]
7. Pieribone, V. A., Xu, Z. Q., Zhang, X., Grillner, S., Bartfai, T. and Hokfelt, T. Galanin induces a hyperpolarization of norepinephrine-containing locus coeruleus neurons in the brainstem slice. Neuroscience 64 , 861–874 (1995).[CrossRef][Medline]
8. Xu, Z. Q., Zhang, X., Pieribone, V. A., Grillner, S. and Hokfelt, T. Galanin-5-hydroxytryptamine interactions: electrophysiological, immunohistochemical and in situ hybridization studies on rat dorsal raphe neurons with a note on galanin R1 and R2 receptors. Neuroscience 87 , 79–94 (1998).[CrossRef][Medline]
9. Xu, Z. Q., Tong, Y. G. and Hokfelt, T. Galanin enhances noradrenaline-induced outward current on locus coeruleus noradrenergic neurons. Neuroreport 12 , 1779–1782 (2001).[CrossRef][Medline]
10. Branchek, T. A., Smith, K. E., Gerald, C. and Walker, M. W. Galanin receptor subtypes. Trends Pharmacol. Sci. 21 , 109–117 (2000).[CrossRef][Medline]
11. Counts, S. E., Perez, S. E., Kahl, U., Bartfai, T., Bowser, R. P., Deecher, D. C., Mash, D. C., Crawley, J. N. and Mufson, E. J. Galanin: neurobiologic mechanisms and therapeutic potential for Alzheimer’s disease. CNS Drug Rev. 7 , 445–470 (2001).[Medline]
12. Floren, A., Land, T. and Langel, U. Galanin receptor subtypes and ligand binding. Neuropeptides 34 , 331–337 (2000).[CrossRef][Medline]
13. Wynick, D. and Bacon, A. Targeted disruption of galanin: new insights from knock-out studies. Neuropeptides 36 , 132–144 (2002).[CrossRef][Medline]
14. Coumis, U. and Davies, C. H. The effects of galanin on long-term synaptic plasticity in the CA1 area of rodent hippocampus. Neuroscience 112 , 173–182 (2002).
    This study in rat and mouse hippocampal slices demonstrated that GAL inhibited LTP induced in both apical and basal dendrites of CA1 pyramidal neurons but did not affect long-term depression. The effect on LTP did not appear to be mediated through inhibition of NMDA or metabotropic glutamate receptor function, suggesting that GAL acts downstream of GALR activation—possibly at the level of the kinase regulation—to prevent the establishment of LTP.[CrossRef][Medline]
15. Crawley, J. N. Minireview. Galanin-acetylcholine interactions: relevance to memory and Alzheimer’s disease. Life Sci. 58 , 2185–2199 (1996).[CrossRef][Medline]
16. Hartonian, I., Mufson, E. J. and de Lacalle, S. Long-term plastic changes in galanin innervation in the rat basal forebrain. Neuroscience 115 , 787–795 (2002).[CrossRef][Medline]
17. Jhamandas, J. H., Harris, K. H., MacTavish, D. and Jassar, B. S. Novel excitatory actions of galanin on rat cholinergic basal forebrain neurons: implications for its role in Alzheimer’s disease. J. Neurophysiol. 87 , 696–704 (2002).
    GAL treatment of acutely dissociated rat basal forebrain neurons reduced a suite of potassium currents but not calcium or sodium currents. The authors used single-cell RT-PCR to determined that GAL actions were specific to cholinergic neurons. These in vitro results suggest that GAL may play an excitatory role by augmenting the release of acetylcholine from cholinergic basal forebrain neurons.[Abstract/Free Full Text]
18. Mazarati, A. M., Hohmann, J. G., Bacon, A., Liu, H., Sankar, R., Steiner, R. A., Wynick, D. and Wasterlain, C. G. Modulation of hippocampal excitability and seizures by galanin. J. Neurosci. 20 , 6276–6281 (2000).
    This study used GAL-tg and GAL-KO mice (see Table 3) to demonstrate that overexpression of GAL in GAL-tg mice restricted LTP at perforant path-dentate gyrus synapses, while the absence of GAL in GAL-KO mice promoted LTP. In addition, GAL-KO mice mice showed an increased propensity to develop status epilepticus, while GAL overexpression appeared to act as an anticonvulsant in GAL-tg mice.[Abstract/Free Full Text]
19. McDonald, M. P., Gleason, T. C., Robinson, J. K. and Crawley, J. N. Galanin inhibits performance on rodent memory tasks. Ann. N. Y. Acad. Sci. 863 , 305–322 (1998).[CrossRef][Medline]
20. Mufson, E. J., Deecher, D. C., Basile, M., Izenwasse, S. and Mash, D. C. Galanin receptor plasticity within the nucleus basalis in early and late Alzheimer’s disease: an in vitro autoradiographic analysis. Neuropharmacology 39 , 1404–1412 (2000).
    In this study, [¹²⁵I]GAL binding sites increased in the anterior region of the nucleus basalis in people with end-stage AD while GAL binding sites were lowest in the posterior region. Interestingly, cholinergic cortical projection neurons of the anterior nucleus basalis are relatively spared in AD compared to cholinergic neurons in the posterior nucleus basalis.[CrossRef][Medline]
21. Ogren, S. O., Hokfelt, T., Kask, K., Langel, U. and Bartfai, T. Evidence for a role of the neuropeptide galanin in spatial learning. Neuroscience 51 , 1–5 (1992).
    This is a seminal behavioral study showing that the GAL receptor antagonist M35 (see Table 4) facilitates acquisition of Morris spatial memory task in mice.[CrossRef][Medline]
22. O’Meara, G., Coumis, U., Ma, S. Y. et al. Galanin regulates the postnatal survival of a subset of basal forebrain cholinergic neurons. Proc. Natl. Acad. Sci. U. S. A. 97 , 11569–11574 (2000).
    This is the first report characterizing the GAL-KO mouse (Table 3) and the phenotypic effects of the GAL null mutation on CBF cell loss and impaired cognitive performance.[Abstract/Free Full Text]
23. Perez, S., Basile, M., Mash, D. C. and Mufson, E. J. Galanin receptor over-expression within the amygdala in early Alzheimer’s disease: an in vitro autoradiographic analysis. J. Chem. Neuroanat. 24 , 109–116 (2002).
    This in vitro autoradiographic analysis of [¹²⁵I]GAL binding sites in normal brain and in mild and severe AD shows that GALR binding increases in layer II of the entorhinal cortex and in the central nucleus and cortico-amygdaloid transition area of the amygdala in mild but not severe AD.[CrossRef][Medline]
24. Sakurai, E., Maeda, T., Kaneko, S., Akaike, A. and Satoh, M. Galanin inhibits long-term potentiation at Schaffer collateral-CA1 synapses in guinea-pig hippocampal slices. Neurosci. Lett. 212 , 21–24 (1996).[CrossRef][Medline]
25. Steiner, R. A., Hohmann, J. G., Holmes, A. et al. Galanin transgenic mice display cognitive and neurochemical deficits characteristic of Alzheimer’s disease. Proc. Natl. Acad. Sci. U. S. A. 98 , 4184–4189 (2001).
    This is the first report describing the generation of GAL-tg overexpressing mouse line (see Table 3) that results in increased basal forebrain GAL concentration, cholinergic cell loss, and cognitive impairment.[Abstract/Free Full Text]
26. Wrenn, C. C. and Crawley, J. N. Pharmacological evidence supporting a role for galanin in cognition and affect. Prog. Neuropsychopharmacol. Biol. Psychiatry 25 , 283–299 (2001).
    An excellent review supporting GAL’s role in several forms of learning and as a potential anxiogenic compound.[CrossRef][Medline]
27. Mesulam, M. M., Mufson, E. J., Levey, A. I. and Wainer, B. H. Cholinergic innervation of cortex by the basal forebrain: Cytochemistry and cortical connections of the septal area, diagonal band nuclei, nucleus basalis (substantia innominata), and hypothalamus in the rhesus monkey. J. Comp. Neurol. 214 , 170–197 (1983).[CrossRef][Medline]
28. Bartus, R. T., Dean, R. L. 3rd, Beer, B. and Lippa, A. S. The cholinergic hypothesis of geriatric memory dysfunction. Science 217 , 408–414 (1982).[Abstract/Free Full Text]
29. Baxter, M. G. and Chiba, A. A. Cognitive functions of the basal forebrain. Curr. Opin. Neurobiol. 9 , 178–183 (1999).[CrossRef][Medline]
30. Mufson, E. J., Kahl, U., Bowser, R., Mash, D. C., Kordower, J. H. and Deecher, D. C. Galanin expression within the basal forebrain in Alzheimer’s disease. Comments on therapeutic potential. Ann. N. Y. Acad. Sci. 863 , 291–304 (1998).[CrossRef][Medline]
31. Wilcock, G. K., Esiri, M. M., Bowen, D. M. and Smith, C. C. Alzheimer’s disease. Correlation of cortical choline acetyltransferase activity with the severity of dementia and histological abnormalities. J. Neurol. Sci. 57 , 407–417 (1982).[CrossRef][Medline]
32. Bowser, R., Kordower, J. H. and Mufson, E. J. A confocal microscopic analysis of galaninergic hyperinnervation of cholinergic basal forebrain neurons in Alzheimer’s disease. Brain Pathol. 7 , 723–730 (1997).
    Confocal microscopy suggests that direct synaptic contacts occur between GAL-containing fibers and CBF neurons in normal-aged humans and that this phenotype is enhanced in AD.[Medline]
33. Chan-Palay, V. Galanin hyperinnervates surviving neurons of the human basal nucleus of Meynert in dementias of Alzheimer’s and Parkinson’s disease: A hypothesis for the role of galanin in accentuating cholinergic dysfunction in dementia. J. Comp. Neurol. 273 , 543–557 (1988).
    This is the first report using immunocytochemistry in human basal forebrain to show that GAL is intimately associated with cholinergic circuitry in the nucleus basalis and thus could function as a powerful modulator of CBF function. Moreover, this study demonstrates for the first time that GAL axons undergo hypertrophy and hyperinnervate cholinergic neurons in end-stage AD.[CrossRef][Medline]
34. Mufson, E. J., Cochran, E., Benzing, W. and Kordower, J. H. Galaninergic innervation of the cholinergic vertical limb of the diagonal band (Ch2) and bed nucleus of the stria terminalis in aging, Alzheimer’s disease and Down’s syndrome. Dementia 4 , 237–250 (1993).
35. Gabriel, S. M., Bierer, L. M., Davidson, M., Purohit, D. P., Perl, D. P. and Harotunian, V. Galanin-like immunoreactivity is increased in the postmortem cerebral cortex from patients with Alzheimer’s disease. J. Neurochem. 62 , 1516–1523 (1994).[Medline]
36. Deecher, D. C., Mash, D. C., Staley, J. K. and Mufson, E. J. Characterization and localization of galanin receptors in human entorhinal cortex. Regul. Pept. 73 , 149–159 (1998).[CrossRef][Medline]
37. Rodriguez-Puertas, R., Nilsson, S., Pascual, J., Pazos, A. and Hokfelt, T. 125I-galanin binding sites in Alzheimer’s disease: increases in hippocampal subfields and a decrease in the caudate nucleus. J. Neurochem. 68 , 1106–1113 (1997).[Medline]
38. McDonald, M. P., Willard, L. B., Wenk, G. L. and Crawley, J. N. Coadministration of galanin antagonist M40 with a muscarinic M1 agonist improves delayed nonmatching to position choice accuracy in rats with cholinergic lesions. J. Neurosci. 18 , 5078–5085 (1998).[Abstract/Free Full Text]
39. Palazzi, E., Felinska, S., Zambelli, M., Fisone, G., Bartfai, T. and Consolo, S. Galanin reduces carbachol stimulation of phosphoinositide turnover in rat ventral hippocampus by lowering Ca²⁺ influx through voltage-sensitive Ca²⁺ channels. J. Neurochem. 56 , 739–747 (1991).
40. Robinson, J. K. and Crawley, J. N. Intraseptal galanin potentiates scopolamine impairment of delayed nonmatching to sample. J. Neurosci. 13 , 5119–5125 (1993).[Abstract]
41. Holmes, F. E., Mahoney, S., King, V. R., Bacon, A., Kerr, N. C., Pachnis, V., Curtis, R., Priestley, J. V. and Wynick, D. Targeted disruption of the galanin gene reduces the number of sensory neurons and their regenerative capacity. Proc. Natl. Acad. Sci. U. S. A. 97 , 11563–11568 (2000).[Abstract/Free Full Text]
42. Mahoney, S. A., Hosking, R., Farrant, S. et al. The second galanin receptor GalR2 plays a key role in neurite outgrowth from adult sensory neurons. J. Neurosci. 23 , 416–421 (2003).[Abstract/Free Full Text]
43. Villar, M. J., Cortes, R., Theodorsson, E., Wiesenfeld-Hallin, Z., Schalling, M., Fahrenkrug, J., Emson, P. C. and Hokfelt, T. Neuropeptide expression in rat dorsal root ganglion cells and spinal cord after peripheral nerve injury with special reference to galanin. Neuroscience 33 , 587–604 (1989).
    It is reported that sciatic nerve transection in rats induced an increase in the number of cell bodies expressing GAL immunoreactivity in the ganglia, and that the GAL levels rise about 120-fold. Thus, GAL plasticity may occur in response to neuronal injury. Two later reports by Holmes et al (2000) and Mahoney et al (2003) have shown that GAL promoted neuritogenesis in cultured DRG explants of WT mice and rescued a deficiency in neurite outgrowth observed in DRG explants of GAL-KO mice.[CrossRef][Medline]
44. Tatemoto, K., Rokaeus, A., Jornvall, H., McDonald, T. J. and Mutt, V. Galanin - a novel biologically active peptide from porcine intestine. FEBS Lett. 164 , 124–128 (1983).
    This paper describes the original isolation of GAL peptide from porcine intestinal extracts.[CrossRef][Medline]
45. Bersani, M., Johnsen, A. H., Hojrup, P., Dunning, B. E., Andreasen, J. J. and Holst, J. J. Human galanin: Primary structure and identification of two molecular forms. FEBS Lett. 283 , 189–194 (1991).[CrossRef][Medline]
46. Evans, H. F. and Shine, J. Human galanin: molecular cloning reveals a unique structure. Endocrinology 129 , 1682–1684 (1991).[Abstract/Free Full Text]
47. Kaplan, L. M., Spindel, E. R., Isselbacher, K. J. and Chin, W. W. Tissue-specific expression of the rat galanin gene. Proc. Natl. Acad. Sci. U. S. A. 85 , 1065–1069 (1988).[Abstract/Free Full Text]
48. Rokaeus, A. and Waschek, J. A. Primary sequence and functional analysis of the bovine galanin gene promoter in human neuroblastoma cells. DNA Cell Biol. 13 , 845–855 (1994).[Medline]
49. Vrontakis, M. E., Peden, L. M., Duckworth, M. L. and Friesen, H. G. Isolation and characterization of a complementary DNA (galanin) clone from estrogen-induced pituitary tumor messenger RNA. J. Biol. Chem. 262 , 16755–16758 (1987).[Abstract/Free Full Text]
50. Corness, J. D., Burbach, J. P. and Hokfelt, T. The rat galanin-gene promoter: response to members of the nuclear hormone receptor family, phorbol ester and forskolin. Brain Res. Mol. Brain Res. 47 , 11–23 (1997).[Medline]
51. Howard, G., Peng, L. and Hyde, J. F. An estrogen receptor binding site within the human galanin gene. Endocrinology 138 , 4649–4656 (1997).[Abstract/Free Full Text]
52. Rokaeus, A., Jiang, K., Spyrou, G. and Waschek, J. A. Transcriptional control of the galanin gene. Tissue-specific expression and induction by NGF, protein kinase C, and estrogen. Ann. N. Y. Acad. Sci. 863 , 1–13 (1998).
    This is an interesting review article that examines transcriptional control mechanisms for GAL using chimeric bovine GAL/luciferase reporter assay in cultured cells and transgenic mice. The studies reveal that enhancer and silencer sequences are involved in conferring cell- and tissue-specific expression of GAL elicited by nerve growth factor, protein kinase C, and estrogen.[CrossRef][Medline]
53. Amiranoff, B., Lorinet, A. M., Yanaihara, N. and Laburthe, M. Structural requirement for galanin action in the pancreatic beta cell line Rin m 5F. Eur. J. Pharmacol. 163 , 205–207 (1989).[CrossRef][Medline]
54. Bartfai, T., Hokfelt, T. and Langel, U. Galanin—a neuroendocrine peptide. Crit. Rev. Neurobiol. 7 , 229–274 (1993).[Medline]
55. Fisone, G., Berthold, M., Bedecs, K. et al. N-terminal galanin-(1-16) fragment is an agonist at the hippocampal galanin receptor. Proc. Natl. Acad. Sci. U. S. A. 86 , 9588–9591 (1989).[Abstract/Free Full Text]
56. Girotti, P., Bertorelli, R., Fisone, G., Land, T., Langel, U., Consolo, S. and Bartfai, T. N-terminal galanin fragments inhibit the hippocampal release of acetylcholine in vivo. Brain Res. 612 , 258–262 (1993).[CrossRef][Medline]
57. Korolkiewicz, R. P., Konstanski, Z., Rekowski, P., Ruczynski, J., Szyk, A., Grzybowska, M., Korolkiewicz, K. Z. and Petrusewicz, J. Actions of several substituted short analogues of porcine galanin on isolated rat fundus strips: a structure-activity relationship. J. Physiol. Pharmacol. 52 , 127–136 (2001).[Medline]
58. Bedecs, K., Langel, U. and Bartfai, T. Metabolism of galanin and galanin (1-16) in isolated cerebrospinal fluid and spinal cord membranes from rat. Neuropeptides 29 , 137–143 (1995).[CrossRef][Medline]
59. Land, T., Langel, U. and Bartfai, T. Hypothalamic degradation of galanin(1-29) and galanin(1-16): Identification and characterization of the peptidolytic products. Brain Res. 558 , 245–250 (1991).
60. Benzing, W. C., Kordower, J. H. and Mufson, E. J. Galanin immunoreactivity within the primate basal forebrain: evolutionary change between monkeys and apes. J. Comp. Neurol. 336 , 31–39 (1993).[CrossRef][Medline]
61. Cheung, C. C., Hohmann, J. G., Clifton, D. K. and Steiner, R. A. Distribution of galanin messenger RNA-expressing cells in murine brain and their regulation by leptin in regions of the hypothalamus. Neuroscience 103 , 423–432 (2001).[CrossRef][Medline]
62. Kordower, J. H. and Mufson, E. J. Galanin-like immunoreactivity within the primate basal forebrain: differential staining patterns between humans and monkeys. J. Comp. Neurol. 294 , 281–292 (1990).[CrossRef][Medline]
63. Kordower, J. H., Le, H. K. and Mufson, E. J. Galanin immunoreactivity in the primate central nervous system. J. Comp. Neurol. 319 , 479–500 (1992).[CrossRef][Medline]
64. Melander, T., Hokfelt, T. and Rokaeus, A. Distribution of galaninlike immunoreactivity in the rat central nervous system. J. Comp. Neurol. 248 , 475–517 (1986).[CrossRef][Medline]
65. Perez, S. E., Wynick, D., Steiner, R. A. and Mufson, E. J. Distribution of galaninergic immunoreactivity in the brain of the mouse. J. Comp. Neurol. 434 , 158–185 (2001).[CrossRef][Medline]
66. Skofitsch, G. and Jacobowitz, D. M. Immunohistochemical mapping of galanin-like neurons in the rat central nervous system. Peptides 6 , 509–546 (1985).[CrossRef][Medline]
67. Wiesenfeld-Hallin, Z., Xu, X. J., Hao, J. X. and Hokfelt, T. The behavioural effects of intrathecal galanin on tests of thermal and mechanical nociception in the rat. Acta Physiol .Scand. 147 , 457–458 (1993).[Medline]
68. Xu, X. J., Hokfelt, T., Bartfai, T. and Wiesenfeld-Hallin, Z. Galanin and spinal nociceptive mechanisms: recent advances and therapeutic implications. Neuropeptides 34 , 137–147 (2000).[CrossRef][Medline]
69. Hokfelt, T., Xu, Z. Q., Shi, T. J., Holmberg, K. and Zhang, X. Galanin in ascending systems. Focus on coexistence with 5-hydroxytryptamine and noradrenaline. Ann. N. Y. Acad. Sci. 863 , 252–263 (1998).[CrossRef][Medline]
70. Fuxe, K., Ogren, S. O., Jansson, A., Cintra, A., Harfstrand, A. and Agnati, L. F. Intraventricular injections of galanin reduces 5-HT metabolism in the ventral limbic cortex, the hippocampal formation and the fronto-parietal cortex of the male rat. Acta Physiol. Scand. 133 , 579–581 (1988).[Medline]
71. Ericson, E. and Ahlenius, S. Suggestive evidence for inhibitory effects of galanin on mesolimbic dopaminergic neurotransmission. Brain Res. 822 , 200–209 (1999).[CrossRef][Medline]
72. Gopalan, C., Tian, Y., Moore, K. E. and Lookingland, K. J. Neurochemical evidence that the inhibitory effect of galanin on tuberoinfundibular dopamine neurons is activity dependent. Neuroendocrinology 58 , 287–293 (1993).[CrossRef][Medline]
73. Nordstrom, O., Melander, T., Hokfelt, T., Bartfai, T. and Goldstein, M. Evidence for an inhibitory effect of the peptide galanin on dopamine release from the rat median eminence. Neurosci. Lett. 73 , 21–26 (1987).[CrossRef][Medline]
74. Counts, S. E., McGuire, S. O., Sortwell, C. E., Crawley, J. N., Collier, T. J. and Mufson, E. J. Galanin inhibits tyrosine hydroxylase expression in midbrain dopaminergic neurons. J. Neurochem. 83 , 442–451 (2002).[CrossRef][Medline]
75. Ben-Ari, Y. Galanin and Glibenclamide Modulate the Anoxic Release of Glutamate in Rat CA3 Hippocampal Neurons. Eur. J. Neurosci. 2 , 62–68 (1990).[CrossRef][Medline]
76. Ogren, S. O., Kehr, J. and Schott, P. A. Effects of ventral hippocampal galanin on spatial learning and on in vivo acetylcholine release in the rat. Neuroscience 75 , 1127–1140 (1996).[CrossRef][Medline]
77. Robinson, J. K., Zocchi, A., Pert, A. and Crawley, J. N. Galanin microinjected into the medial septum inhibits scopolamine-induced acetylcholine overflow in the rat ventral hippocampus. Brain Res. 709 , 81–87 (1996).[CrossRef][Medline]
78. Zini, S., Roisin, M. P., Langel, U., Bartfai, T. and Ben-Ari, Y. Galanin reduces release of endogenous excitatory amino acids in the rat hippocampus. Eur. J. Pharmacol. 245 , 1–7 (1993).[CrossRef][Medline]
79. Habert-Ortoli, E., Amiranoff, B., Loquet, I., Laburthe, M. and Mayaux, J. F. Molecular cloning of a functional human galanin receptor. Proc. Natl. Acad. Sci. U. S. A. 91 , 9780–9783 (1994).[Abstract/Free Full Text]
80. Smith, K. E., Forray, C., Walker, M. W., Jones, K. A., Tamm, J. A., Bard, J., Branchek, T. A., Linemeyer, D. L. and Gerald, C. Expression cloning of a rat hypothalamic galanin receptor coupled to phosphoinositide turnover. J. Biol. Chem. 272 , 24612–24616 (1997).
    This study details the cloning of rat GALR2 and shows that activation of GALR2 results in increased inositol phospholipid turnover and intracellular calcium levels in stably transfected Chinese hamster ovary cells and in calcium-activated chloride currents in Xenopus oocytes. Thus, rat GALR2 is primarily coupled to the activation of phospholipase C in vitro.[Abstract/Free Full Text]
81. Smith, K. E., Walker, M. W., Artymyshyn, R. et al. Cloned human and rat galanin GALR3 receptors. Pharmacology and activation of G-protein inwardly rectifying K+ channels. J. Biol. Chem. 273 , 23321–23326 (1998).
    Cloning of the rat GALR3 receptor is reported. In Xenopus oocytes, activation of rat and human GALR3 co-expressed with potassium channel subunits GIRK1 and GIRK4 resulted in inward K⁺ currents characteristic of G_i/G_o-coupled receptors. These data suggest that GALR3 signaling pathways resemble those of GALR1 in that both can activate potassium channels linked to the regulation of neurotransmitter release.[Abstract/Free Full Text]
82. Wang, S., Hashemi, T., Fried, S., Clemmons, A. L. and Hawes, B. E. Differential intracellular signaling of the GalR1 and GalR2 galanin receptor subtypes. Biochemistry 37 , 6711–6717 (1998).
    GALR1 and GALR2-expressing Chinese hamster ovary (CHO) cell lines were developed to determine the repertoire of G protein coupling. GALR1 appears to activate only the G_i pathway. By contrast, GALR2 is capable of stimulating signaling which is consistent with activation of G_o, G_q/G₁₁, and G_i. These differential signaling profiles for GALR1 and GALR2 may regulate the diverse physiological functions of GAL.[CrossRef][Medline]
83. Wang, S., Hashemi, T., He, C., Strader, C. and Bayne, M. Molecular cloning and pharmacological characterization of a new galanin receptor subtype. Mol. Pharmacol. 52 , 337–343 (1997).[Abstract/Free Full Text]
84. Wittau, N., Grosse, R., Kalkbrenner, F., Gohla, A., Schultz, G. and Gudermann, T. The galanin receptor type 2 initiates multiple signaling pathways in small cell lung cancer cells by coupling to G(q), G(i) and G(12) proteins. Oncogene 19 , 4199–4209 (2000).[CrossRef][Medline]
85. Kolakowski, L. F., Jr., O’Neill, G. P., Howard, A. D. et al. Molecular characterization and expression of cloned human galanin receptors GALR2 and GALR3. J. Neurochem. 71 , 2239–2251 (1998).[Medline]
86. Fathi, Z., Battaglino, P. M., Iben, L. G. et al. Molecular characterization, pharmacological properties and chromosomal localization of the human GALR2 galanin receptor. Brain Res. Mol. Brain Res. 58 , 156–169 (1998).[Medline]
87. Pham, T., Guerrini, S., Wong, H., Reeve, J., Jr. and Sternini, C. Distribution of galanin receptor 1 immunoreactivity in the rat stomach and small intestine. J. Comp. Neurol. 450 , 292–302 (2002).[CrossRef][Medline]
88. Hedlund, P. B., Yanaihara, N. and Fuxe, K. Evidence for specific N-terminal galanin fragment binding sites in the rat brain. Eur. J. Pharmacol. 224 , 203–205 (1992).[CrossRef][Medline]
89. Hedlund, P. B., Finnman, U. B., Yanaihara, N. and Fuxe, K. Galanin-(1-15), but not galanin-(1-29), modulates 5-HT1A receptors in the dorsal hippocampus of the rat brain: possible existence of galanin receptor subtypes. Brain Res. 634 , 163–167 (1994).
90. Xu, Z. Q., Ma, X., Soomets, U., Langel, U. and Hokfelt, T. Electrophysiological evidence for a hyperpolarizing, galanin (1-15)-selective receptor on hippocampal CA3 pyramidal neurons. Proc. Natl. Acad. Sci. U. S. A. 96 , 14583–14587 (1999).[Abstract/Free Full Text]
91. Wynick, D., Smith, D. M., Ghatei, M., Akinsanya, K., Bhogal, R., Purkiss, P., Byfield, P., Yanaihara, N. and Bloom, S. R. Characterization of a high-affinity galanin receptor in the rat anterior pituitary: absence of biological effect and reduced membrane binding of the antagonist M15 differentiate it from the brain/gut receptor. Proc. Natl. Acad. Sci. U. S. A. 90 , 4231–4235 (1993).[Abstract/Free Full Text]
92. Beal, M. F., MacGarvey, U. and Swartz, K. J. Galanin immunoreactivity is increased in the nucleus basalis of Meynert in Alzheimer’s disease. Ann. Neurol. 28 , 157–161 (1990).
    This study examined neurochemical markers for neuropeptides, amino acid neurotransmitters, and monoaminergic neurotransmitters in postmortem samples of the nucleus basalis in control and AD brain. Among several findings, it was determined that ChAT activity was significantly reduced in the nucleus basalis but that GAL immunoreactivity was significantly increased twofold in the patients with AD. There were no significant changes in substance P, somatostatin, or neuropeptide Y immunoreactivity.[CrossRef][Medline]
93. Counts, S. E., Chen1, E.-Y., Ikonomovic, M. D. et al. Galanin plasticity within the nucleus basalis in people with mild cognitive impairment Soc. Neurosci. (2002).
94. Kohler, C. and Chan-Palay, V. Galanin receptors in the post-mortem human brain. Regional distribution of 125I-galanin binding sites using the method of in vitro receptor autoradiography. Neurosci. Lett. 120 , 179–182 (1990).[CrossRef][Medline]
95. Mufson, E. J., Bothwell, M. and Kordower, J. H. Loss of nerve growth factor receptor-containing neurons in Alzheimer’s disease: a quantitative analysis across subregions of the basal forebrain. Exp. Neurol. 105 , 221–232 (1989).[CrossRef][Medline]
96. Vogels, O. J., Broere, C. A., ter Laak, H. J., ten Donkelaar, H. J., Nieuwenhuys, R. and Schulte, B. P. Cell loss and shrinkage in the nucleus basalis Meynert complex in Alzheimer’s disease. Neurobiol. Aging 11 , 3–13 (1990).[CrossRef][Medline]
97. Amaral, D. G. Memory: anatomical organization of candidate brain regions, in Handbook of Physiology Section 1: The Nervous System V Higher Functions of the Brain, Part 1 (Mountcastle, V. B., Plum, F. and Geiger, S. R. eds) pp 211-294 American Physiological Society, Bethesda, MD (1987).
98. Gomez-Isla, T., Price, J. L., McKeel, D. W., Jr., Morris, J. C., Growdon, J. H. and Hyman, B. T. Profound loss of layer II entorhinal cortex neurons occurs in very mild Alzheimer’s disease. J. Neurosci. 16 , 4491–4500 (1996).[Abstract/Free Full Text]
99. Kordower, J. H., Chu, Y., Stebbins, G. T., DeKosky, S. T., Cochran, E. J., Bennett, D. and Mufson, E. J. Loss and atrophy of layer II entorhinal cortex neurons in elderly people with mild cognitive impairment. Ann. Neurol. 49 , 202–213 (2001).[CrossRef][Medline]
100. Amaral, D. G. Amygdalohippocampal and amygdalocortical projections in the primate brain, in Excitatory amino acids and epilepsy (Schwartz, R. and Ben-Ari, Y. eds) pp 3-17 Plenum Press, New York (1986).
101. Pitkanen, A., Pikkarainen, M., Nurminen, N. and Ylinen, A. Reciprocal connections between the amygdala and the hippocampal formation, perirhinal cortex, and postrhinal cortex in rat. A review. Ann. N. Y. Acad. Sci. 911 , 369–391 (2000).[Medline]
102. Vereecken, T. H., Vogels, O. J. and Nieuwenhuys, R. Neuron loss and shrinkage in the amygdala in Alzheimer’s disease. Neurobiol. Aging 15 , 45–54 (1994).[CrossRef][Medline]
103. Gilmor, M. L., Erickson, J. D., Varoqui, H., Hersh, L. B., Bennett, D. A., Cochran, E. J., Mufson, E. J. and Levey, A. I. Preservation of nucleus basalis neurons containing choline acetyltransferase and the vesicular acetylcholine transporter in the elderly with mild cognitive impairment and early Alzheimer’s disease. J. Comp. Neurol. 411 , 693–704 (1999).[CrossRef][Medline]
104. de Lacalle, S., Kulkarni, S. and Mufson, E. J. Plasticity of galaninergic fibers following neurotoxic damage within the rat basal forebrain: initial observations. Exp. Neurol. 146 , 361–366 (1997).[CrossRef][Medline]
105. Kowall, N. W. and Beal, M. F. Galanin-like immunoreactivity is present in human substantia innominata and in senile plaques in Alzheimer’s disease. Neurosci. Lett. 98 , 118–123 (1989).[CrossRef][Medline]
106. Diez, M., Koistinaho, J., Kahn, K., Games, D. and Hokfelt, T. Neuropeptides in hippocampus and cortex in transgenic mice overexpressing V717F beta-amyloid precursor protein—initial observations. Neuroscience 100 , 259–286 (2000).[CrossRef][Medline]
107. Braak, H. and Braak, E. Neuropathological stageing of Alzheimer-related changes. Acta Neuropathol. (Berl.)82 , 239–259 (1991).[CrossRef][Medline]
108. Corder, E. H., Saunders, A. M., Strittmatter, W. J., Schmechel, D. E., Gaskell, P. C., Small, G. W., Roses, A. D., Haines, J. L. and Pericak-Vance, M. A. Gene dose of apolipoprotein E type 4 allele and the risk of Alzheimer’s disease in late onset families. Science 261 , 921–923 (1993).[Abstract/Free Full Text]
109. Strittmatter, W. J., Saunders, A. M., Schmechel, D., Pericak-Vance, M., Enghild, J., Salvesen, G. S. and Roses, A. D. Apolipoprotein E: high-avidity binding to beta-amyloid and increased frequency of type 4 allele in late-onset familial Alzheimer disease. Proc. Natl. Acad. Sci. U. S. A. 90 , 1977–1981 (1993).[Abstract/Free Full Text]
110. Strittmatter, W. J. and Roses, A. D. Apolipoprotein E and Alzheimer’s disease. Annu. Rev. Neurosci. 19 , 53–77 (1996).[CrossRef][Medline]
111. Allen, S. J., MacGowan, S. H., Tyler, S., Wilcock, G. K., Robertson, A. G., Holden, P. H., Smith, S. K. and Dawbarn, D. Reduced cholinergic function in normal and Alzheimer’s disease brain is associated with apolipoprotein E4 genotype. Neurosci. Lett. 239 , 33–36 (1997).[CrossRef][Medline]
112. Poirier, J., Delisle, M. C., Quirion, R. et al. Apolipoprotein E4 allele as a predictor of cholinergic deficits and treatment outcome in Alzheimer disease. Proc. Natl. Acad. Sci. U. S. A. 92 , 12260–12264 (1995).[Abstract/Free Full Text]
113. Xu, Z. Q., Shi, T. J. and Hokfelt, T. Galanin/GMAP- and NPY-like immunoreactivities in locus coeruleus and noradrenergic nerve terminals in the hippocampal formation and cortex with notes on the galanin-R1 and -R2 receptors. J. Comp. Neurol. 392 , 227–251 (1998).[CrossRef][Medline]
114. Holets, V. R., Hokfelt, T., Rokaeus, A., Terenius, L. and Goldstein, M. Locus coeruleus neurons in the rat containing neuropeptide Y, tyrosine hydroxylase or galanin and their efferent projections to the spinal cord, cerebral cortex and hypothalamus. Neuroscience 24 , 893–906 (1988).[CrossRef][Medline]
115. Nieuwenhuys, R. Chemoarchitecture of the brain. Springer Press, Berlin (1985).
116. Chan-Palay, V. Alterations in the locus coeruleus in dementias of Alzheimer’s and Parkinson’s disease. Prog. Brain Res. 88 , 625–630 (1991).[Medline]
117. Miller, M. A., Kolb, P. E., Planas, B. and Raskind, M. A. Few cholinergic neurons in the rat basal forebrain coexpress galanin messenger RNA. J. Comp. Neurol. 391 , 248–258 (1998).[CrossRef][Medline]
118. Kinney, G. A., Emmerson, P. J. and Miller, R. J. Galanin receptor-mediated inhibition of glutamate release in the arcuate nucleus of the hypothalamus. J. Neurosci. 18 , 3489–3500 (1998).[Abstract/Free Full Text]
119. Crawley, J. N., Mufson, E. J., Hohmann, J. G. et al. Galanin overexpressing transgenic mice. Neuropeptides 36 , 145–156 (2002).
     This a recent and comprehensive review of GAL transgenic mice (GAL-tg and GalOE; see Table 3).[CrossRef][Medline]
120. Wrenn, C. C., Marriott, L. K., Kinney, J. W., Holmes, A., Wenk, G. L. and Crawley, J. N. Galanin peptide levels in hippocampus and cortex of galanin-overexpressing transgenic mice evaluated for cognitive performance. Neuropeptides 36 , 413–426. (2002).[CrossRef][Medline]
121. Kokaia, M., Holmberg, K., Nanobashvili, A. et al. Suppressed kindling epileptogenesis in mice with ectopic overexpression of galanin Proc. Natl. Acad. Sci. U.S.A. 98 , 14006–14011 (2001).
     These data provide evidence that ectopic overexpression of the neuropeptide galanin can dampen the development of epilepsy by means of receptor-mediated action, at least partly by reducing glutamate release from mossy fibers.[Abstract/Free Full Text]
122. Ma, S.Y., Wynick, D., and Mufson, E.J. Differential loss of ChAT and p75-NTR containing basal forebrain neurons in mice deficient in galanin Soc. Neurosci. (1999).
123. Mufson, E. J., Bothwell, M., Hersh, L. B. and Kordower, J. H. Nerve growth factor receptor immunoreactive profiles in the normal, aged human basal forebrain: colocalization with cholinergic neurons. J. Comp. Neurol. 285 , 196–217 (1989).[CrossRef][Medline]
124. Cortes, R., Villar, M. J., Verhofstad, A. and Hokfelt, T. Effects of central nervous system lesions on the expression of galanin: a comparative in situ hybridization and immunohistochemical study. Proc. Natl. Acad. Sci. U. S. A. 87 , 7742–7746 (1990).[Abstract/Free Full Text]
125. Harrison, P. S. and Henderson, Z. Quantitative evidence for increase in galanin-immunoreactive terminals in the hippocampal formation following entorhinal cortex lesions in the adult rat. Neurosci. Lett. 266 , 41–44 (1999).[CrossRef][Medline]
126. Zhang, X., Verge, V. M., Wiesenfeld-Hallin, Z., Piehl, F. and Hokfelt, T. Expression of neuropeptides and neuropeptide mRNAs in spinal cord after axotomy in the rat, with special reference to motoneurons and galanin. Exp. Brain Res. 93 , 450–461 (1993).[Medline]
127. Ginsberg, S. D., Schmidt, M. L., Crino, P. B., Eberwine, J. H., Lee, V. M.-Y. and Trojanowski, J. Q. Molecular pathology of Alzheimer’s disease and related disorders, in Neurodegenerative and Age-related Changes in Structure and Function of Cerebral Cortex (Peters, A. and Morrison, J. H. eds) pp 603-653 Kluwer Academic/Plenum, New York (1999).
128. Hemby, S. E., Trojanowski, J. Q. and Ginsberg, S. D. Neuron-specific age-related decreases in dopamine receptor subtype mRNAs. J. Comp. Neurol. 456 , 176–183. (2003).[CrossRef][Medline]
129. Eberwine, J., Kacharmina, J. E., Andrews, C. et al. mRna expression analysis of tissue sections and single cells. J. Neurosci. 21 , 8310–8314 (2001).[Free Full Text]
130. Mufson, E. J., Counts, S. E. and Ginsberg, S. D. Gene expression profiles of cholinergic nucleus basalis neurons in Alzheimer’s disease. Neurochem. Res 27 , 1035–1048 (2002).[CrossRef][Medline]
131. Mufson, E.J. and Ginsberg, S.D. Expression profile of cholinergic basal forebrain neurons in mild Alzheimer’s disease using gene arrays Soc. Neurosci. 83.5 (2000).
132. Trojanowski, J. Q. and Lee, V. M. Phosphorylation of paired helical filament tau in Alzheimer’s disease neurofibrillary lesions: focusing on phosphatases. Faseb J. 9 , 1570–1576 (1995).[Abstract]
133. Vogelsberg-Ragaglia, V., Schuck, T., Trojanowski, J.Q., and Lee, V. M. PP2A mRNA expression is quantitatively decreased in Alzheimer’s disease hippocampus. Exp. Neurol. 168 , 402–412 (2001).[CrossRef][Medline]
134. Jacoby, A. S., Hort, Y. J., Constantinescu, G., Shine, J. and Iismaa, T. P. Critical role for GALR1 galanin receptor in galanin regulation of neuroendocrine function and seizure activity. Brain Res. Mol. Brain Res. 107 , 195–200 (2002).[Medline]
135. Mazarati, A. and Wasterlain, C. G. Anticonvulsant effects of four neuropeptides in the rat hippocampus during self-sustaining status epilepticus. Neurosci. Lett. 331 , 123–127 (2002).[CrossRef][Medline]
136. Saar, K., Mazarati, A. M., Mahlapuu, R. et al. Anticonvulsant activity of a nonpeptide galanin receptor agonist. Proc. Natl. Acad. Sci. U. S. A. 99 , 7136–7141 (2002).
     This describes the development of galnon, the first systemically active nonpeptide galanin agonist. Intrahippocampal injection of galnon shortened the duration of self-sustaining status epilepticus in rats, confirming its agonist properties in vivo. Galnon inhibited adenylate cyclase activity, and pretreatment of rats with antisense peptide nucleic acid targeted to GALR 1 mRNA abolished the effect of galnon, suggesting mediation of its anticonvulsant properties through this receptor subtype.[Abstract/Free Full Text]
137. Wasterlain, C. G., Mazarati, A. M., Naylor, D. et al. Short-term plasticity of hippocampal neuropeptides and neuronal circuitry in experimental status epilepticus. Epilepsia 43 , 20–29 (2002).
138. O’Donnell, D., Ahmad, S., Wahlestedt, C. and Walker, P. Expression of the novel galanin receptor subtype GALR2 in the adult rat CNS: distinct distribution from GALR1. J. Comp. Neurol. 409 , 469–481 (1999).[CrossRef][Medline]
139. Mennicken, F., Hoffert, C., Pelletier, M., Ahmad, S. and O’Donnell, D. Restricted distribution of galanin receptor 3 (GalR3) mRNA in the adult rat central nervous system. J. Chem. Neuroanat. 24 , 257–268 (2002).[CrossRef][Medline]
140. Hohmann, J. G., Jurus, A., Teklemichael, D. N., Matsumoto, A. M., Clifton, D. K. and Steiner, R. A. Distribution and regulation of galanin receptor 1 messenger RNA in the forebrain of wild type and galanin-transgenic mice. Neuroscience 117 , 105–117 (2003).[CrossRef][Medline]
141. Miller, M. A., Kolb, P. E. and Raskind, M. A. GALR1 galanin receptor mRNA is co-expressed by galanin neurons but not cholinergic neurons in the rat basal forebrain. Brain Res. Mol. Brain Res. 52 , 121–129 (1997).[Medline]
142. Liu, H. X., Brumovsky, P., Schmidt, R., Brown, W., Payza, K., Hodzic, L., Pou, C., Godbout, C. and Hokfelt, T. Receptor subtype-specific pronociceptive and analgesic actions of galanin in the spinal cord: selective actions via GalR1 and GalR2 receptors. Proc. Natl. Acad. Sci. U. S. A. 98 , 9960–9964 (2001).
     This report describes the generation of AR-M1896 and AR-M961 (see Table 5) and their application in studies of a rat neuropathic pain model. Using the differential agonist properties of the two compounds the authors conclude that low doses of GAL have a nociceptive role at the spinal cord level mediated by GALR2 receptors, whereas the antiallodynic effect of high-dose galanin on neuropathic pain is mediated by the GALR1 receptors. The ongoing development of GAL ligands will be useful in determining GALR subtype-specific activities in vivo.[Abstract/Free Full Text]
143. Scott, M. K., Ross, T. M., Lee, D. H. et al. 2,3-Dihydro-dithiin and -dithiepine-1,1,4,4-tetroxides: small molecule non-peptide antagonists of the human galanin hGAL-1 receptor. Bioorg. Med. Chem. 8 , 1383–1391 (2000).[CrossRef][Medline]
144. Davis, K. L., Thal, L. J., Gamzu, E. R. et al. A double-blind, placebo-controlled multicenter study of tacrine for Alzheimer’s disease. The Tacrine Collaborative Study Group. N. Engl. J. Med. 327 , 1253–1259 (1992).[Abstract]
145. Farlow, M., Gracon, S. I., Hershey, L. A., Lewis, K. W., Sadowsky, C. H. and Dolan-Ureno, J. A controlled trial of tacrine in Alzheimer’s disease. The Tacrine Study Group. JAMA 268 , 2523–2529 (1992).[Abstract/Free Full Text]
146. Krall, W. J., Sramek, J. J. and Cutler, N. R. Cholinesterase inhibitors: a therapeutic strategy for Alzheimer disease. Ann. Pharmacother. 33 , 441–450 (1999).[Abstract]
147. Lopez, O. L., Becker, J. T., Wisniewski, S., Saxton, J., Kaufer, D. I. and DeKosky, S. T. Cholinesterase inhibitor treatment alters the natural history of Alzheimer’s disease. J. Neurol. Neurosurg. Psychiatry. 72 , 310–314 (2002).[Abstract/Free Full Text]
148. Bartfai, T., Langel, U., Bedecs, K. et al. Galanin-receptor ligand M40 peptide distinguishes between putative galanin-receptor subtypes. Proc. Natl. Acad. Sci. U. S. A. 90 , 11287–11291 (1993).[Abstract/Free Full Text]
149. Crawley, J. N., Robinson, J. K., Langel, U. and Bartfai, T. Galanin receptor antagonists M40 and C7 block galanin-induced feeding. Brain Res. 600 , 268–272 (1993).[CrossRef][Medline]
150. Gu, Z. F., Rossowski, W. J., Coy, D. H., Pradhan, T. K. and Jensen, R. T. Chimeric galanin analogs that function as antagonists in the CNS are full agonists in gastrointestinal smooth muscle. J. Pharmacol. Exp. Ther. 266 , 912–918 (1993).[Abstract/Free Full Text]
151. Heuillet, E., Bouaiche, Z., Menager, J. et al. The human galanin receptor: ligand-binding and functional characteristics in the Bowes melanoma cell line. Eur. J. Pharmacol. 269 , 139–147 (1994).[CrossRef][Medline]
152. Takahashi, T., Belvisi, M. G. and Barnes, P. J. Modulation of neurotransmission in guinea-pig airways by galanin and the effect of a new antagonist galantide. Neuropeptides 26 , 245–251 (1994).[CrossRef][Medline]
153. Chu, M., Mierzwa, M., Truumees, R. and al., e. A new fungal metabolite, Sch 202596, with inhibitory activity in the galanin receptor GALR1 assay. Tetrahedron Lett. 38 , 6111–6114 (1997).[CrossRef]
154. Samama, P., Griffiths, S., Ohlmeyer, M. and Webb, M. L. Non-peptide ligands of the Gal R1 receptor. Neuropeptides 33 , 311 (1999).
155. Tadashi, K. and Ohmori, O. Studies toward the total synthesis of Sch 202596, an antagonist of the galanin receptor subtype GalR1: synthesis of geodin, the spirocoumaranone subunit of Sch 202596. Tetrahedron Lett. 41 , 465–469 (2000).[CrossRef]
156. Waters, S. M. and Krause, J. E. Distribution of galanin-1, -2 and -3 receptor messenger RNAs in central and peripheral rat tissues. Neuroscience 95 , 265–271 (2000).[CrossRef][Medline]
157. Borowsky, B., Walker, M. W., Huang, L. Y., Jones, K. A., Smith, K. E., Bard, J., Branchek, T. A. and Gerald, C. Cloning and characterization of the human galanin GALR2 receptor. Peptides 19 , 1771–1781 (1998).[CrossRef][Medline]
158. Fathi, Z., Cunningham, A. M., Iben, L. G. et al. Cloning, pharmacological characterization and distribution of a novel galanin receptor. Brain Res. Mol. Brain Res. 51 , 49–59 (1997).[Medline]
159. Xu, X. J., Wiesenfeld-Hallin, Z., Langel, U., Bedecs, K. and Bartfai, T. New high affinity peptide antagonists to the spinal galanin receptor. Br. J. Pharmacol. 116 , 2076–2080 (1995).[Medline]
160. Arletti, R., Benelli, A., Cavazzuti, E. and Bertolini, A. Galantide improves social memory in rats. Pharmacol. Res. 35 , 317–319 (1997).[CrossRef][Medline]

Related articles in MI:

Sites of interest on the World Wide Web—edited by David Siderovski

MI 2003 3: 171. [Full Text]  

This Article Summary Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Related articles in MI Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Counts, S. E. Articles by Mufson, E. J. Search for Related Content PubMed PubMed Citation Articles by Counts, S. E. Articles by Mufson, E. J.