Molecular Targets for Treating Cognitive Dysfunction in Schizophrenia

doi:10.1093/schbul/sbm074

Schizophrenia Bulletin Advance Access originally published online on July 7, 2007
Schizophrenia Bulletin 2007 33(5):1100-1119; doi:10.1093/schbul/sbm074

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© The Author 2007. Published by Oxford University Press on behalf of the Maryland Psychiatric Research Center. All rights reserved. For permissions, please email: journals.permissions@oxfordjournals.org.

Molecular Targets for Treating Cognitive Dysfunction in Schizophrenia

John A. Gray² and Bryan L. Roth¹^,3
² Department of Psychiatry, University of California, San Francisco, CA
³ Department of Pharmacology, University of North Carolina School of Medicine, 8032 Burnett-Womack, CB # 7365, Chapel Hill, NC 27599-7365

Abstract

Top
Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

Cognitive impairment is a core feature of schizophrenia as deficitsare present in the majority of patients, frequently precedethe onset of other positive symptoms, persist even with successfultreatment of positive symptoms, and account for a significantportion of functional impairment in schizophrenia. While theatypical antipsychotics have produced incremental improvementsin the cognitive function of patients with schizophrenia, overalltreatment remains inadequate. In recent years, there has beenan increased interest in developing novel strategies for treatingthe cognitive deficits in schizophrenia, focusing on amelioratingimpairments in working memory, attention, and social cognition.Here we review various molecular targets that are actively beingexplored for potential drug discovery efforts in schizophreniaand cognition. These molecular targets include dopamine receptorsin the prefrontal cortex, nicotinic and muscarinic acetylcholinereceptors, the glutamatergic excitatory synapse, various serotoninreceptors, and the ${gamma}$ -aminobutyric acid (GABA) system.

Keywords: serotonin / dopamine / glutamate / NMDA / acetylcholine / GABA

	Introduction

Top Abstract Introduction Cholinergic Targets Glutaminergic Targets Dopaminergic Targets Serotonergic Targets Other Neurotransmitter Targets Potential Future Targets Conclusions Funding References

Schizophrenia is characterized by positive symptoms such asdelusions and hallucinations, negative symptoms such as avolitionand flat affect, and cognitive impairments. Although Kraepelin,1with his term "dementia praecox," characterized the relationshipbetween cognitive deficits and schizophrenia nearly a centuryago, effective treatments for these deficits have not been developed.Cognitive dysfunction is estimated to occur in 75%–85%of patients with schizophrenia,2 often precedes the onset ofother symptoms,2 and persists even after other symptoms havebeen effectively treated.3 Indeed, a meta-analysis of cognitivedeficits suggested that indices of cognitive deficits are muchbetter predictors of functional outcome than indices from anyother symptom domain.4 Furthermore, the severity of cognitivedeficits is predictive of poorer medication compliance,5 overalltreatment adherence,6 and increased tendency for relapse infirst-episode patients.7

Until recently, antipsychotic drug development in schizophreniahas focused mainly on developing drugs that reduce the positivesymptoms of schizophrenia,8 and indeed, all the current medicationsappear to be similar in efficacy for reducing positive symptomsin typical patients with schizophrenia.9,10 In a recent meta-analysis,patients treated with typical antipsychotics were actually shownto have small but detectable improvements in several cognitivedomains11; however, due to extrapyramidal side effects, manypatients are also treated with anticholinergic agents that arewell known to impair memory12 and global cognitive ability.13In addition, there is some evidence for the superiority of atypicalantipsychotics, such as olanzapine and risperidone, over typicalsin improving cognitive performance,14–16 though the benefitsare relatively small and have not been consistently reproduced.17Overall, the widespread use of the atypical antipsychotics haslikely offered some cognitive benefit for patients with schizophrenia,18though significant deficits persist, suggesting a need for directivetreatments for enhancing cognition.

Due to the continued need for improved treatment of the cognitiveimpairments in schizophrenia, Wayne Fenton spearheaded the NationalInstitutes of Mental Health's joint academic and industry initiativetermed MATRICS (Measurement and Treatment Research to ImproveCognition in Schizophrenia) to facilitate the development ofbetter treatments targeted at cognition.19 An initial MATRICSconference (http://www.matrics.ucla.edu) identified 7 primarycognitive domains that are crucial for developing targets forthe treatment of cognition in schizophrenia. These domains includedworking memory, speed of processing, verbal learning and memory,attention and vigilance, reasoning and problem solving, visuallearning and memory, and social cognition.20–22 An additionalMATRICS conference (http://www.matrics.ucla.edu) identifiedpharmacologic strategies that hold promise for the treatmentof impaired cognition in schizophrenia. The primary moleculartargets identified included dopamine receptors in the prefrontalcortex, nicotinic and muscarinic acetylcholine receptors, theglutamatergic excitatory synapse, various serotonin receptors,and the ${gamma}$ -aminobutyric acid (GABA) system. Below, we review manyof the molecular targets being studied for potential drug developmentstrategies aimed at enhancing cognition, both generally andspecifically in schizophrenia (table 1).

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Table 1. Molecular Targets for Cognitive Enhancement in Schizophrenia

	Cholinergic Targets

Top Abstract Introduction Cholinergic Targets Glutaminergic Targets Dopaminergic Targets Serotonergic Targets Other Neurotransmitter Targets Potential Future Targets Conclusions Funding References

Acetylcholine is known to play an important role not only inmotor function but also in various domains of cognition, particularlyattention, learning, and memory.23 Indeed, cholinergic dysfunctionhas been shown to be central to the pathophysiology of Alzheimer'sdisease and has also been postulated to contribute to the cognitivedeficits of various neuropsychiatric disorders, including schizophrenia.23The basal cholinergic complex sends widely diffuse afferentsthrough 2 projections: the septohippocampal and the nucleusbasalis of Meynart cortical pathways.24 The septohippocampalpathway is important in working memory processes through hippocampalstorage of intermediate-term memory,25,26 whereas the nucleusbasalis of Meynart cortical pathway is involved in referencememory through long-term information storage in the neocortex.27,28Additionally, a role for acetylcholine in the processes of attentionhas been demonstrated in rats and monkeys.29 Pharmacologically,anticholinergic drugs, like scopolamine, produce learning impairmentsin healthy subjects similar to those of persons with dementia,30while cholinomimetic drugs, like physostigmine, can significantlyenhance the memory functions of healthy individuals.30,31

Although the degeneration of cholinergic neurons in the basalforebrain and the associated loss of cerebral neurotransmissionthat is seen in Alzheimer's disease are absent in schizophrenia,32,33there is evidence of decreased nicotinic34 and muscarinic35acetylcholine receptors in the cortex and hippocampus of individualswith schizophrenia. Interestingly, in patients with schizophrenia,decreased activity of choline acetyltransferase, a biosyntheticenzyme for acetylcholine production, was correlated with poorercognitive functioning as measured by the Clinical Dementia Rating.33In addition, some of the atypical antipsychotics, but not typicalantipsychotics, can increase the release of acetylcholine inthe prefrontal cortex, possibly contributing to their modestenhancement of cognition in schizophrenia.36 Thus, various targetswithin the cholinergic system are being investigated as potentialenhancers of cognition in schizophrenia.

Cholinesterases
Cholinesterase inhibitors, such as donepezil and rivastigmine,are currently the main pharmacologic approach to the treatmentof Alzheimer's disease and have been shown to slow the cognitivedecline in this neurodegenerative disease.37 As such, it hasbeen proposed that cholinesterase inhibitors may also be usefulin the treatment of the cognitive dysfunction in schizophrenia.38Acetylcholinesterase and butyrylcholinesterase are present ina wide variety of tissues and are broadly distributed in thebrain. Inhibition of cholinesterases increases the synapticconcentration of acetylcholine, thereby enhancing and prolongingthe action of acetylcholine on both muscarinic and nicotinicreceptors. Therefore, cholinesterase inhibitors act as indirectcholinergic agonists at muscarinic and nicotinic receptors.

Following the administration of atypical antipsychotic treatment,cholinesterase inhibitors can increase the concentration ofacetylcholine in the medial prefrontal cortex by 2- to 3-fold36and have been demonstrated to produce some functional normalizationof brain activity during verbal fluency task performance ofschizophrenic patients characterized by a significant increasein frontal lobe and cingulate activity on functional magneticresonance imaging (fMRI).39 As such, in recent years there havebeen multiple small randomized controlled trials of cholinesteraseinhibitors in patients with schizophrenia, though results havebeen disappointing and inconsistent.40 It has been suggestedthat the lack of consistent effects of cholinesterase inhibitorsmay be due to the high rate of cigarette smoking among patientswith schizophrenia41 and subsequent desensitization of nicotinicreceptors,42 thus rendering increased acetylcholine levels ineffective.43Indeed, galantamine, an acetylcholinesterase inhibitor thatis also an allosteric potentiator of ${alpha}$ ₇ nicotinic receptors,44,45does not cause ${alpha}$ ₇ receptor desensitization and has been shownto enhance cognitive functioning of schizophrenic patients ina 4-week double-blind placebo controlled trial.46 Interestingly,galantamine produced cognitive enhancement in schizophrenicpatients despite the fact that all the patients smoked at least10 cigarettes per day.46 Unfortunately, despite these initialpositive findings, subsequent results with galantamine havebeen mixed.47–49 Thus, while pure cholinesterase inhibitorsmay be of minimal benefit for enhancing cognition in patientswith schizophrenia, possibly due to desensitization of their ${alpha}$ ₇ nicotinic receptors from cigarette smoking, further studymay be warranted with combined acetylcholinesterase inhibitorsand allosteric potentiators of the nicotinic receptor in schizophrenia.However, it is likely that selective agents at various nicotinicand muscarinic receptors may be a more effective approach todeveloping drugs for treatment of the cognitive impairment inschizophrenia.

Nicotinic Receptors
It is well known that the smoking rates in individuals withschizophrenia are significantly higher than in the general population,and some have suggested that these individuals may be "self-medicating"with nicotine.50,51 Indeed, nicotine administration has beenshown to improve various measures of cognition that may easesome of the side effects of antipsychotic medications.51 Forexample, in patients with schizophrenia, a nicotine transdermalpatch could dose dependently reverse haloperidol-induced impairmentsin working memory, attention, and reaction time52 and has beenshown to reduce haloperidol-induced bradykinesia and rigiditycompared with a placebo patch.53 However, other studies havebeen mixed.54 Interestingly, in one study,55 some of the modesteffects of cigarette smoking on clinical and cognitive outcomemeasures could also be improved by smoking denicotinized cigarettes,suggesting that nonnicotine components of cigarette smoke mayalso contribute.55 Overall, while research on nicotinic treatmentof individuals with schizophrenia has shown that, in singleadministrations, nicotine improves some aspects of cognition,additional administrations are not effective due to rapid desensitizationof nicotinic receptors.42 Thus, considerable research is exploringthe potential use of nicotinic agents, particularly partialagonists and allosteric modulators at various nicotinic receptorsubunits that would be less likely to cause rapid receptor desensitization.

Nicotinic acetylcholine receptors are ionotropic receptors witha pentameric structure composed of alpha ( ${alpha}$ ₂ to ${alpha}$ ₉) and beta (ß₂to ß₄) subunits and are expressed at high levels inthe hippocampus, cortex, striatum, and thalamus.34,56 The 2most prevalent nicotinic receptors are the ${alpha}$ ₄ß₂, whichis a high-affinity receptor, and the ${alpha}$ ₇, which is a low-affinitynicotinic receptor, both of which have been shown to have reducednumbers in patients with schizophrenia.34,56 In addition, functionalpolymorphisms exist in the promoter region of the ${alpha}$ ₇ receptorthat have shown genetic linkage in schizophrenia.57,58

The ${alpha}$ ₇ nicotinic receptor subtype is a highly studied targetfor the development of drugs for cognitive enhancement. Studiesin rodents have shown that antagonists at the ${alpha}$ ₇ nicotinic receptorinduce sensory gating deficits similar to those seen in schizophrenia,59a hippocampal phenomenon manifested as an inability to attendappropriately to sensory stimuli.60 Sensory gating deficitsmay strongly impact cognitive performance, and it has been shownthat smoking transiently normalizes these sensory gating deficits.60In addition, agonists at ${alpha}$ ₇ receptors such as 3-2,4-dimethoxybenzylideneanabaseine (DMXB-A) can normalize the auditory gating deficitsin rodents.61 Moreover, DMXB-A had a positive effect on a cognitivebattery in a small proof-of-concept trial in humans,62 and additionalclinical trials of ${alpha}$ ₇ receptor agonists are underway. However,there is concern that long-term use of ${alpha}$ ₇ agonists may inducethe desensitization of nicotinic receptors, leading to a limitedduration of efficacy.63 Thus, further development of ${alpha}$ ₇ receptorpartial agonists (eg, GTS-21) and allosteric potentiators (eg,galantamine) that induce minimal receptor desensitization iswarranted.

In addition to ${alpha}$ ₇ receptors, it has been suggested that ${alpha}$ ₄ß₂nicotinic receptors are involved in cognition.64 Indeed, ${alpha}$ ₄ß₂receptors are considered to represent more than 90% of the high-affinitynicotine-binding sites in the rat brain,65 and decreased levelsof ${alpha}$ ₄ß₂ receptor binding have been found in the hippocampusof patients with schizophrenia.56 Furthermore, agonists of ${alpha}$ ₄ß₂receptors, such as RJR2403 and SIB-1553A, can produce a significantand long-lasting improvement of memory in rats and monkeys.66–68Additionally, ${alpha}$ ₄ß₂ agonists have been shown to stimulatethe release of dopamine, norepinephrine, and acetylcholine inthe hippocampus and frontal cortex in rats.66 Thus, nicotinic ${alpha}$ ₄ß₂ receptor agonists may be of therapeutic benefitfor the treatment of the cognitive deficits in schizophreniaby several mechanisms. In addition to ${alpha}$ ₇ and ${alpha}$ ₄ß₂ receptors,other nicotinic receptors, such as ${alpha}$ ₃- and ${alpha}$ ₆-containing receptors,may be involved in cognitive performance; however, studies arelimited due to the lack of selective agonists and antagonistsfor these receptors.

Muscarinic Receptors
In addition to the ionotropic nicotinic receptors, numerousstudies have implicated metabotropic muscarinic acetylcholinereceptors in schizophrenia. Muscarinic receptors are G protein–coupledreceptors69 found widely throughout the central nervous systemon both cholinergic and noncholinergic cells where they functionas both autoreceptors and heteroreceptors.70–72 Of the5 genetically distinct subtypes of muscarinic receptors (M₁–M₅),the M₁ receptor has been most closely linked to cognition andschizophrenia.73 Indeed, the M₁ receptor subtype is the mostabundant of the muscarinic receptors in forebrain and hippocampus,74,75brain regions crucial to normal cognitive functions. In addition,decreased M₁ receptor binding has been reported in postmortemstudies of the prefrontal cortex, hippocampus, and striatumfrom patients with schizophrenia,76–78 that is, importantly,not due to chronic antipsychotic treatment.35,77,79 Interestingly,M₁ receptor–deficient mice demonstrate deficits in workingmemory and remote reference memory indicative of impaired hippocampal-corticalinteractions.80 Together, these results suggest that alterationsin central M₁ receptors may have a role in the pathophysiologyof schizophrenia and that M₁ receptor agonists may be beneficialin treating schizophrenia, particularly the cognitive impairments.73

Action at M₁ receptors has been proposed to be a major contributorto the cognition-enhancing effects of clozapine,81 despite thefact that clozapine is an exceedingly weak partial agonist atM₁ and other muscarinic receptors.73,82 Thus, attention hasfocused on various clozapine metabolites including clozapine-N-oxideand N-desmethylclozapine (NDMC). Clozapine-N-oxide is inactivewhile NDMC has actions at many receptors (http://pdsp.med.unc.edu/pdsp.php).82Interestingly, NDMC is the major active metabolic of clozapineand has been reported to be a potent M₁ agonist that preferentiallybinds to M₁ receptors vs clozapine,83 although more comprehensivestudies fail to demonstrate selectivity of NDMC for M₁ receptors.84In addition, NDMC has high affinities for 5-HT_2A and 5-HT_2Creceptors and is a partial agonist at D₂, D₃ receptors85,86and ${delta}$ -opioid receptors,87 suggesting that this metabolite ofclozapine may have antipsychotic and cognition-enhancing propertiesvia a number of mechanisms. Furthermore, NDMC, but not clozapine,increases release of dopamine and acetylcholine in the prefrontalcortex and the hippocampus88 and potentiates NMDA receptor activityin the hippocampus.83 Thus, the cognitive enhancement observedwith clozapine could actually be due to its metabolite NDMCvia an uncertain mechanism.

Indeed, NDMC (ACP-104) and other M₁ receptor agonists are inclinical trials as potential treatments of the cognitive dysfunctionin schizophrenia. Xanomeline, a nonselective M₁ and M₄ muscarinicagonist with potent actions at a variety of additional nonmuscarinicreceptors including 5-HT_1A and 5-HT_2A receptors,89 improvedcognition and psychotic-like symptoms in Alzheimer's disease.90In addition, monotherapy with xanomeline resulted in an improvementof positive symptoms and cognitive function in 20 subjects withschizophrenia91 but was discontinued due to poor tolerability.92The relatively nonselective actions of xanomeline and NMDC ata number of receptors (http://pdsp.med.unc.edu/pdsp.php) shouldengender caution among schizophrenia researchers for embracingpositive data from xanomeline and NMDC studies as being specificallyindicative of a role for M₁ receptors in schizophrenia.

Overall, evidence suggests that M₁ receptor agonists could beuseful in treating various symptom domains in schizophrenia,though the roles of the other muscarinic receptor subtypes areless clear. M₅ receptors, for example, may be relevant to schizophreniaas they are located in the brainstem and midbrain, where theyhave an effect on dopamine release.93 Indeed, xanomeline isalso an antagonist at M₅ receptors, suggesting that blockadeof M₅ may be involved in the benefits seen with xanomeline.94In addition, M₄ receptor knockout mice have impairments of cognitiveperformance and elevated levels of dopamine in the nucleus accumbens,suggesting a potential role for M₄ receptor agonists in treatingboth the positive and cognitive symptoms of schizophrenia.95,96As selective agonists at muscarinic receptor subtypes have beendifficult to develop, positive allosteric modulators are alsobeing explored as potential therapeutic agents.

Glutaminergic Targets

Top
Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

Glutamate is the primary excitatory neurotransmitter for approximately60% of the neurons in the mammalian brain, including all corticalpyramidal neurons,97 and plays a principal role in modulatinglong-term potentiation, a likely key cellular mechanism forlearning and memory.98,99 Glutamate mediates fast excitatorypostsynaptic potentials by acting on 3 ionotropic receptors,which are differentiated based upon sensitivity to the syntheticglutamate derivatives N-methyl-D-aspartate (NMDA), alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionicacid (AMPA), and kainate.100 In addition, glutamate exerts slowermodulatory effects by acting on various G protein–coupledmetabotropic glutamate receptors (mGluRs).101 For example, mGluR2and mGluR3 receptors modulate the release of glutamate, whereasthe mGluR5 receptor potentiates the duration of NMDA receptor–dependentexcitatory postsynaptic potentials.102

It has been hypothesized for decades that some deficiency inNMDA function might play a role in the pathophysiology of schizophrenia.103Since the 1950s, the NMDA receptor antagonists phencyclidine(PCP) and ketamine were known to produce a large range of schizophrenia-likesymptoms including psychotic symptoms, negative symptoms, andcognitive dysfunction,103–105 and it has been suggestedthat augmenting NMDA receptor activity may have therapeuticpotential in schizophrenia.100 Indeed, some of the atypicalantipsychotics, but not typical antipsychotics, have been shownin preclinical models to reverse the effects of ketamine andPCP,106–109 presumably through indirect activation ofNMDA receptors mediated by other neurotransmitter systems.83It is also important to note that a competing hypothesis suggeststhat a hyperactivity of glutamatergic neurotransmission is involvedin the psychopathology of schizophrenia, leading to seeminglycontradictory pharmacologic approaches being explored.100 Indeed,glutamatergic excitotoxicity is thought to be a factor in theneurodegeneration of Alzheimer's disease110 and a weak NMDAreceptor antagonist, memantine, has shown efficacy in slowingcognitive decline in moderate to advanced Alzheimer's disease.111Thus, the glutamate system, especially its NMDA-dependent components,is complex, and while small increases in NMDA-dependent glutamateneurotransmission might be cognitively enhancing, too much activationmay result in neurodegeneration. Fortunately, the glutamatergicexcitatory synapse offers multiple targets for drug developmentto provide the precise level of enhancement to improve cognitionwithout excitotoxicity. Thus, we briefly review below variousapproaches being explored for modulating NMDA receptor neurotransmissionand discuss approaches aimed at other glutamatergic mediators.

NMDA Receptors
NMDA glutamate receptors are ligand-gated ion channels witha primary glutamate-binding site and an allosteric glycine-bindingsite.100 Interestingly, the opening of the NMDA channel appearsto require both glutamate and glycine binding, with glycinebinding affecting channel open time and desensitization ratebut not inducing channel opening itself.100 In addition, NMDAreceptor activity can be allosterically modulated by multipleother substances, including Mg²⁺, polyamines, and protons.112Thus, while direct agonists of the glutamate-binding site ofthe NMDA receptor may not be clinically feasible due to therisk of excess excitation and neurotoxicity, the allostericsites on the NMDA receptor complex, particularly the glycine-bindingsite, are promising targets for drug development. Indeed, chronictreatment of rodents with glycine has not been found to induceexcitotoxicity.113,114

Compounds that target the glycine site of the NMDA receptorcomplex have been studied in multiple small clinical trials.These include glycine115 and D-serine,116 which are endogenousagonists at the glycine site of the NMDA receptor complex; D-alanine;and D-cycloserine, an antituberculosis drug that also bindsto the glycine modulatory site where it functions as a partialagonist.117 In most of these studies, the test compound wasadministered along with either a typical or atypical antipsychotic,and there appears to be significant effects at reducing negativesymptoms and cognitive impairment in patients with schizophrenia.118Of the 4 agents, D-cycloserine has been the least efficacious,likely due to it being a partial agonist that acts as an antagonistat high doses. Interestingly, when used concurrently with clozapine,glycine119 and D-serine120 have been reported to be ineffectivewhile D-cycloserine seemed to worsen symptoms,121 possibly becauseclozapine may already enhance glycine and glutamate neurotransmission.Overall, agonists at the glycine allosteric site of the NMDAglutamate receptor hold promise in the treatment of the negativeand cognitive symptoms of schizophrenia, possibly as an augmentationof currently existing antipsychotics. A potential limitationof targeting the glycine modulatory site is that the glycinesite is probably half-saturated during physiologic conditions,suggesting that treatments targeting the glycine site wouldtheoretically only be able to effectively double NMDA neurotransmission.118In addition, both glycine and D-serine must be given at gram-leveldoses to significantly elevate central nervous system levels,and attempts to modify glycine or D-serine to produce syntheticglycine-site agonists, have, thus far, been unsuccessful. Thus,indirect approaches to activate NMDA receptors are being explored,such as increasing extracellular glycine and glutamate and bymodulating AMPA receptors and mGluRs.

Glycine Transporters
An indirect approach being explored to boost NMDA activity viathe glycine allosteric site is to increase synaptic glycineby inhibiting the glycine transporter. The glycine transporters,GlyT1 and GlyT2, have been identified on both neuronal and glialcells in the central nervous system, where they are suggestedto control the extracellular concentration of glycine.122 Thus,blockade of glycine transporters is predicted to increase extracellularglycine and thus enhance NMDA receptor neurotransmission. Indeed,preclinical data suggest that inhibition of glycine reuptakerepresents a feasible approach to enhance NMDA receptor activityand possibly be therapeutic in schizophrenia.100 For example,selective, high-affinity inhibitors of the glycine transporter,including Org-24598, N-[3-(4'-fluorophenyl)-3-(4'-phenylphenoxy)propyl]sarcosine, and SSR-504734, have been found to reverse PCP-inducedhyperactivity and dopaminergic hyperreactivity in rodents.123,124Furthermore, the glycine transport inhibitor glycyldodecylamideattenuated PCP-induced hyperactivity more potently than administrationof glycine.125,126

Clinical trials to date, however, have only studied the low-potencyglycine transport inhibitor sarcosine (N-methyl glycine). Ina clinical trial of sarcosine added to the stable antipsychoticregimen of patient with schizophrenia, there was a highly significantreduction in negative symptoms, along with smaller but significantreductions in positive and cognitive symptoms.127 Interestingly,a subsequent study with patients on clozapine found no improvementof symptoms with the addition of sarcosine, a result similarto studies with the NMDA glycine site agonists.128 These resultsstrongly suggest a role of glycine transport inhibitors in thetreatment of schizophrenia, though results of trials with selective,high-potency inhibitors are anticipated.

AMPA/Kainate Receptors
Another glutamatergic approach to drug development for cognitiveenhancement in schizophrenia has been the development of compoundsthat stimulate AMPA and kainate glutamate receptors. AMPA andkainate receptors mediate the majority of the fast glutamatergicsignaling in the brain, and AMPA receptors work heavily in concertwith NMDA receptors.100 AMPA receptors provide the primary depolarizationnecessary to activate NMDA receptors, while NMDA receptors arerequired for proper incorporation of AMPA receptors into thepostsynaptic membrane, a process involved in synaptic plasticity.129Thus, activation of AMPA receptors is likely critically importantfor learning and memory; however, direct AMPA agonists are unlikelyto be therapeutically useful as AMPA receptors rapidly desensitizeafter stimulation.130

In an attempt to avoid desensitization of AMPA receptors, allostericpotentiators of AMPA receptor function, a class of compoundstermed ampakines, are being studied as potential treatmentsfor enhancing cognition in schizophrenia.131,132 Indeed, ampakineshave been shown to enhance glutamatergic transmission and facilitatelong-term potentiation in rodents.133,134 Furthermore, ampakinesimprove performance in rodents on a variety of memory tasksincluding spatial mazes135,136 and learned fear137 and havebeen shown to be effective in reducing age-associated memorydeficits in rats.138 In a clinical trial of schizophrenia patientson clozapine, coadministration of the ampakine CX-516 yieldedsignificant improvements in memory and attention;139 however,a trial of CX-516 as monotherapy in schizophrenia showed noclear beneficial effects.140 Importantly, higher potency ampakinesare currently under clinical development as both monotherapyfor schizophrenia and adjunctive treatment for cognitive dysfunction,though results of trials are not yet available. A higher potencyampakine, farampator, has been tested in healthy elderly volunteersand improved short-term memory but appeared to impair episodicmemory,141 and thus, it remains unclear if modulation of AMPAreceptors has therapeutic value in the treatment of the cognitivedysfunction in schizophrenia although this is a highly activearea of current research.

Metabotropic Glutamate Receptors
Agents acting at mGluRs, which serve to regulate glutamatergicneurotransmission both pre- and postsynaptically, are currentlyin preclinical development for treatment of the cognitive dysfunctionin schizophrenia. There are 8 subtypes of mGluRs (mGluR1–8)which are categorized into 3 groups according to their secondmessenger-coupling and ligand-binding profiles with group Ireceptors (mGluR1 and mGluR5) primarily being studied for cognitiveenhancement in schizophrenia.102 Group I receptors, particularlymGluR5, function predominantly to potentiate both presynapticglutamate release and postsynaptic NMDA neurotransmission,142and mGluR5 receptors show significant colocalization with NMDAreceptors in cortical pyramidal neurons.143 Together, thesefindings suggest that mGluR5 agonism may enhance NMDA activityand improve memory and cognition.142 Indeed, selective mGluR5agonists were found to inhibit PCP-induced dopamine releasein the rodent prefrontal cortex.144 Direct mGluR5 agonists,however, are likely to induce receptor desensitization limitingtheir therapeutic usefulness. Thus, selective allosteric potentiatorsof mGluRs have recently been developed and hold promise as therapeuticagents.145,146 Indeed, preliminary positive results with anmGluR2/3 agonist in phase II trials have been reported (http://www.prnewswire.com/cgi-bin/micro_stories.pl?ACCT=916306&TICK=LLY&STORY=/www/story/12-07-2006/0004487009&EDATE=Dec+7,+2006).

Dopaminergic Targets

Top
Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

Dopamine projections to the prefrontal cortex comprising themesocortical dopamine system are essential for normal cognition.147,148Thus, it has been hypothesized that decreased dopaminergic neurotransmissionin the prefrontal cortex contributes to the cognitive deficitsobserved in schizophrenia, especially those related to executivefunctions and working memory.149–151 Indeed, postmortemand in vivo imaging studies have linked prefrontal dopaminedysfunction to cognitive impairment,151,152 and various studieshave demonstrated that direct and indirect dopamine agonistscan improve prefrontal cortex cognitive functions in humans.153,154However, it seems that precise regulation of prefrontal dopaminergictone is essential as, in addition to insufficient dopamine,excessive prefrontal dopamine (eg, resulting from acute stress)may be deleterious to cognition.155–157 Thus, dopaminefunction in the prefrontal cortex seems to follow an "inverted-U"dose-response curve whereby increases or decreases from an optimallevel result in cognitive impairment.158 Additionally, indirectdopamine agonists could potentially exacerbate psychosis byincreasing neurotransmission at mesolimbic dopamine D₂ receptors.

D₁ Receptors
Dopamine D₁ receptors are expressed at high levels on the distaldendrites of pyramidal neurons in the prefrontal cortex thatare thought to be involved in working memory processes.158,159Indeed, evidence suggests an important role of dopamine D₁ receptorsin the cognitive dysfunction of schizophrenia.138 For example,there is a decreased level of D₁ receptor–like bindingin the prefrontal cortex of drug-naive patients with schizophreniaas measured with positron emission tomography imaging, and thisdecrease was found to be correlated with the severity of negativesymptoms and cognitive dysfunction but not with the severityof positive symptoms.160 In addition, in nonhuman primates,chronic blockade of D₂ receptors results in a downregulationof D₁ receptors in the prefrontal cortex and consequently producessevere impairments in working memory.161 This downregulationof D₁ receptors may explain why long-term treatment with typicalantipsychotics can contribute to the cognitive dysfunction inschizophrenia. Thus, significant efforts are underway to examinethe possible role of D₁ receptor agonists in treating cognitivedysfunction in schizophrenia. Indeed, low doses of selectiveD₁ agonists, such as dihydrexidine, A77636 [GenBank] , and SKF81297, havecognition-enhancing actions in nonhuman primates,162–164and short-term administration of the D₁ selective agonist, ABT-431,reversed the cognitive deficits in monkeys treated chronicallywith a D₂ receptor antagonist.161

Although novel compounds that, directly or indirectly, stimulateD₁ receptors may be of immense value in treating cognitive deficitsin schizophrenia, several potential pitfalls may need to beovercome. First, D₁ receptor activity follows the "inverted-U"dose-response curve, where either too little or too much D₁stimulation impairs working memory.158 In addition, chronictreatment with a D₁ agonist may actually lead to the downregulationof D₁ receptors which could, potentially, worsen cognition inthe long term. Thus, an optimized level of D₁ receptor activationat the apex of the "inverted-U" may be required to obtain maximalcognitive benefits,157 which may be accomplished by partialagonists or an intermittent pattern of administration.161,165An additional obstacle is the powerful hypotensive effects ofdirect-acting D₁ agonists on peripheral D₁ receptors,166 whichmay necessitate the use of indirect D₁-activating agents suchas catechol-O-methyltransferase (COMT) inhibitors (see below).

D₄ Receptors
The high affinity of clozapine for dopamine D₄ receptors ledto speculation that D₄ receptors may be clozapine's "magic receptor."167Clinical trials of selective D₄ antagonists, however, have notdemonstrated any appreciable efficacy in the treatment of acuteschizophrenia,168–170 though it is possible that D₄ receptorblockade in collaboration with action at other neurotransmitterreceptors may be clinically beneficial. Indeed, studies of thephysiological roles for the D₄ receptor are finding that D₄receptors may play an important role in impulsivity and workingmemory.171

The mechanism by which D₄ blockade could improve cognition isnot fully known,172 though D₄ receptors are present on bothpyramidal neurons and GABA-producing interneurons in the prefrontalcortex and hippocampus,173 areas important for cognitive function.Studies have demonstrated that activation of D₄ receptors decreasesNMDA receptor activity in the hippocampus174 and inhibits glutamatergicsignaling in the prefrontal cortex.175 Additionally, D₄ receptorknockout mice show enhanced activity of cortical pyramidal neurons,an effect mimicked in wild-type mice by administration of theD₄ antagonist PNU-101387G.175 Together, these results suggestthat D₄ antagonism may be a valuable approach to improve cognitionin schizophrenia. Indeed, the D₄ antagonist NDG96-1 was reportedto reverse PCP-induced deficits in object retrieval tasks inmonkeys,172 and another D₄ antagonist, PNU-101387G, reverseddeficits in the delayed response task induced by the pharmacologicstressor FG7142 (a benzodiazepine inverse agonist).176 Interestingly,PCP-induced cognitive deficits are exacerbated by haloperidol,suggesting that strong blockade of other dopamine receptorsmay counter the beneficial effects of D₄ blockade on cognitivefunctioning.172

Seemingly contradictory evidence also suggests that D₄ receptoragonists may improve cognitive function. For example, the selectiveD₄ agonist A-412997 showed dose-dependent improvement in socialrecognition in rats, a model of short-term memory,177 and theD₄ agonist PD168077 was shown to facilitate memory consolidationof an inhibitory avoidance learned response in mice.178 Theseeffects have been hypothesized to be due to D₄ receptor modulationof inhibitory GABAergic signaling in the prefrontal cortex.179Indeed, the D₄ agonist PD168077 reduces GABA_A inhibitory currentsin pyramidal neurons, which could be blocked by the D₄ antagonistL-745870 as well as clozapine.179 Thus, in contrast to D₄ antagonist–inducedenhancement of NMDA currents in the hippocampus, D₄ agonistsmay suppress GABA_A inhibitory currents in the prefrontal cortexand thereby indirectly enhance cortical excitability. Takentogether, D₄ receptor–selective agents may be valuablein the treatment of the cognitive deficits in schizophrenia,though a balance between D₄ receptor modulation of prefrontalGABA_A and hippocampal NMDA receptors may be necessary.

Catechol-O-methyltransferase
COMT is a postsynaptic enzyme that methylates and thereby deactivatessynaptically released catecholamines, particularly dopamine.180Historically, monoamine oxidase was considered the primary enzymefor the initial deactivation of synaptic dopamine,181 thoughmounting evidence suggests that COMT may be especially importantfor the breakdown of dopamine, particularly in the prefrontalcortex.182 For example, COMT knockout mice show increased baselinelevels of dopamine, but not other catecholamines such as norepinephrine,specifically in the frontal cortex.183 In addition, the COMTknockout mice also showed enhanced memory performance,183 suggestinga potential role of COMT inhibition in improving cognition.Indeed, a selective, reversible inhibitor of COMT, tolcapone,has been reported to improve working memory in rodents184 andhas been shown to improve cognitive dysfunction in patientswith advanced Parkinson's disease,185 though use is limiteddue to a risk of liver failure.186 Other COMT inhibitors arecurrently being investigated for treatment of the cognitivedysfunction in schizophrenia.

Interestingly, a common single nucleotide polymorphism in thegene encoding COMT, Val158Met, results in the transcriptionof a variant of the COMT enzyme with approximately 40% lessenzymatic activity in humans.187 The reduced COMT enzymaticactivity associated with the Met variant presumably resultsin greater availability of dopamine in the prefrontal cortexand, thus, may improve cognition, hypotheses supported by findingsfrom the COMT knockout mice,183 and an fMRI study in humans.188Furthermore, the COMT locus at chromosome 22q11 has been identifiedas a susceptibility locus for schizophrenia in several linkagestudies189,190 and 2 meta-analyzes,189,191 though this remainscontroversial.192–194 However, accumulating evidence predictsthat patients with schizophrenia who have the Met allele mayhave improved cognitive response to clozapine.195 Interestingly,a recent proof-of-concept experiment in normal human subjectstreated with tolcapone demonstrated significant improvementson measures of executive function and verbal episodic memoryin individuals with a Val/Val genotype but a diminished performanceof individuals with the Met/Met genotype.196 Thus, overall,the potential of pharmacologic inhibition of COMT in the long-termtreatment of the cognitive dysfunction in schizophrenia remainsto be determined.

Serotonergic Targets

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Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

5-HT_2A Receptors
5-HT_2A receptors are particularly abundant in the pyramidalneurons from cortical layer V,197 where they have been describedto colocalize with NMDA glutamate receptors,198,199 suggestinga role in modulating cognitive functions. Indeed, studies havedemonstrated that 5-HT_2A receptors interact with postsynapticdensity protein 95, a protein involved in anchoring NMDA receptorsto postsynaptic densities,200 and it has been suggested thatactivation of 5-HT_2A receptors increases the release of glutamateonto pyramidal cells.201 Interestingly, the selective 5-HT_2Areceptor antagonist M100907 blocked the cognition-impairingeffects of MK-801, an NMDA receptor antagonist.202,203 Similarfindings have been reported for another 5-HT_2A antagonist AC-90179.204Taken together, these studies suggest an intimate associationbetween NMDA and 5-HT_2A receptors and imply that drugs withpotent 5-HT_2A antagonistic actions may prove beneficial at improvingcognition in schizophrenia, perhaps by normalizing NMDA receptorfunctioning.203

In addition, 5-HT_2A receptors are located on dopaminergic neuronsin the ventral tegmental area,205 where they may modulate dopamineneuronal activity.206 Indeed, it is likely that a predominantrole of 5-HT_2A receptors in antipsychotic action is to modulatedopaminergic tone, particularly along the mesocortical pathway.206–208For example, clozapine, olanzapine, and ziprasidone, but nothaloperidol or risperidone, can preferentially augment dopamineand norepinephrine release in the prefrontal cortex relativeto the subcortical areas.209 In rats, however, repeated administrationof the selective 5-HT_2A antagonist M100907 can alter the activityof midbrain dopamine neurons in rats, though there is disagreementas to whether cortical dopamine levels are potentiated210 orinhibited.211 Thus, it has been hypothesized that the ultimateeffect of 5-HT_2A antagonists on dopaminergic neurotransmissionmight be to stabilize it.208,212

Clinical studies with selective 5-HT_2A receptor compounds havealso demonstrated a role of 5-HT_2A receptors in cognitive functioningin schizophrenia. For example, in a study of 30 hospitalizedpatients with schizophrenia, administration of mianserin, a5-HT_2A/2C and ${alpha}$ ₂-adrenergic antagonist, improved scores on theAutomated Neuropsychological Assessment Metrics at 4 weeks,though no significant improvement was found on the WisconsinCard Sorting Test.213 These results suggest that 5-HT_2A receptorantagonism may improve cognitive function in schizophrenia,214,215though additional clinical studies are needed. However, becausenearly all approved atypical antipsychotic drugs have potent5-HT_2A antagonist actions, it is unlikely that adding on a drugwith potent 5-HT_2A antagonism will provide any significant boostingof cognition in treated patients.212 The potential cognition-enhancingeffects resulting from 5-HT_2A receptor antagonism with the currentlyavailable atypical antipsychotics may be masked by other drugactions, such as anticholinergic effects, known to cause cognitiveimpairment.216

5-HT_1A Receptors
5-HT_1A receptors are densely concentrated in the hippocampus,lateral septum, amygdala, and cortical limbic areas, as wellas both the dorsal and median raphe nuclei.217,218 On rapheneurons, 5-HT_1A receptors function as somatic autoreceptorsproviding inhibitory feedback control of 5-HT release.219 However,the highest concentrations of 5-HT_1A receptors are on corticaland hippocampal pyramidal neurons220 suggesting a role of 5-HT_1Areceptors in mediating cognitive functions. 5-HT_1A receptorson cortical pyramidal neurons are colocalized with 5-HT_2A receptors,221though while 5-HT_2A receptor activation is excitatory, 5-HT_1Areceptor activation inhibits pyramidal neurons.222

Because they act on different locations of the receptors, both5-HT_1A partial agonists and full antagonists have shown a positiveeffect on cognitive activity in animals.223 Thus, 5-HT_1A partialagonists, presumably acting on pyramidal neurons, improve cognitionin animals, while 5-HT_1A antagonists also improve cognition,probably by acting at the raphe autoreceptors.208,223 Indeed,atypical antipsychotic drugs modestly enhance cognition, andseveral atypical antipsychotic drugs have 5-HT_1A partial agonistactions (eg, aripiprazole, clozapine, olanzapine, ziprasidone,quetiapine),224,225 while others are 5-HT_1A antagonists (eg,risperidone and sertindole).224 Preclinical experiments alsoshow that both 5-HT_1A partial agonists and antagonists can improvecognition. For example, intraprefrontal infusion of 8-OH-DPAT,a nonselective 5-HT_1A agonist, improved visual-spatial attentionand decreased impulsivity in rats,226 while WAY100635, a 5-HT_1Aantagonist, blocked the deleterious effects of MK-801 and NMDAantagonist in rats.227 Thus, the preclinical literature is mixedregarding whether 5-HT_1A agonists or antagonists enhance cognition.

Clinical data in humans are equally mixed. For example, activating5-HT_1A receptors with a single dose of tandospirone, a 5-HT_1Apartial agonist, diminished explicit memory function228 in dementedpatients, though chronic administration of tandospirone enhancedverbal memory in patients with schizophrenia.229,230 Interestingly,the 5-HT_1A agonist NAE-086 actually induced hallucinations andnightmares in normal individuals after repeated doses,231 suggestingthat 5-HT_1A agonists may not be tolerated well in schizophrenicindividuals. Taken together, these results demonstrate thatadditional clinical studies are needed but suggest that 5-HT_1Areceptors may need to be differently modulated to optimallyenhance cognition in various pathologic conditions (ie, dementiavs schizophrenia) and that 5-HT_1A partial agonists with a highlevel of efficacy may present a significant risk of exacerbatingpositive symptoms in schizophrenia.231

5-HT₄ Receptors
Serotonin 5-HT₄ receptors are found at high densities in thehippocampus, frontal cortex, and amygdala, suggesting a roleof these receptors in cognitive functions.232,233 Indeed, 5-HT₄receptors have been shown to be markedly decreased in patientswith Alzheimer's disease.234 In addition, 5-HT₄ receptor agonistshave shown promise in the treatment of cognitive impairmentby enhancing cholinergic transmission in the hippocampus.212,235For example, a 5-HT₄ receptor partial agonist, SL65.0155, improvedlearning and memory performance in chemically induced rat modelof amnesia,236 and this improvement may be due in part to lengtheningof the excitatory postsynaptic potential in hippocampal CA1pyramidal neurons.237 Interestingly, a recent study also showedthat the activation of 5-HT₄ receptors in a neuronal cultureinhibited the secretion of ß-amyloid peptide and enhancedneuronal survival.238 Thus, while 5-HT₄ receptor–selectiveagonists are mostly being studied for their role in the treatmentof Alzheimer's disease, they may also be of benefit in the treatmentof the cognitive dysfunction in schizophrenia.

5-HT₆ Receptors
Several atypical antipsychotics, including clozapine and olanzapine,and some tricyclic antidepressants, such as amoxapine, amitriptyline,and clomipramine, were found to have high affinity for 5-HT₆receptors239–241 prompting significant efforts to understandits possible role in schizophrenia and other neuropsychiatricdisorders. When antisense oligonucleotides were used to decreasethe level of 5-HT₆ receptor expression in rats, the rats exhibitedan increased number of yawns and stretches that could be blockedby atropine, suggesting a role of the 5-HT₆ receptor in thecontrol of cholinergic neurotransmission.242,243 In addition,the selective 5-HT₆ receptor antagonist SB-271046 has been shownto improve memory retention in the water maze test of spatiallearning and memory.244,245 Thus, it appears likely that 5-HT₆receptors may have an important future role in the treatmentof cognitive deficits in neuropsychiatric illnesses such asAlzheimer's disease and schizophrenia.212

5-HT₇ Receptors
The 5-HT₇ receptor exhibits a distinct distribution in the centralnervous system with relatively high levels in the thalamus,hypothalamus, and hippocampus and lower levels in the cortexand amygdala.246–248 In addition to possible roles inregulating circadian rhythms and sleep,249–251 5-HT₇ receptorsmay also have an important role in hippocampus-dependent functionssuch as learning and memory.252 For example, 5-HT₇ receptorknockout mice have been found to exhibit a specific impairmentin contextual fear conditioning in which the animal learns toassociate the environment with an aversive stimulus, a processgenerally believed to require the hippocampus.253 Electrophysiologicalstudies have also shown that 5-HT₇ receptor activation modulatesthe excitability and intracellular signaling of pyramidal neuronsin the CA1 region of the hippocampus.254,255 Additionally, in5-HT₇ receptor knockout mice, there is a reduced ability toinduce long-term potentiation in the CA1 region of the hippocampus.253Together, these findings suggest an important role for the 5-HT₇receptor in hippocampus-dependent functions, including learningand memory.252 Thus, selective 5-HT₇ receptor activators mightprove therapeutically useful for the treatment of the cognitivedysfunction of schizophrenia.212

Other Neurotransmitter Targets

Top
Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

${alpha}$ ₂-Adrenergic Receptors
The central noradrenergic system projects from the locus ceruleusto the prefrontal cortex where ${alpha}$ ₂-adrenergic receptors appearto play an important role in cognitive functioning.256 Indeed,treatment with the ${alpha}$ ₂-adrenergic receptor agonists, clonidineand guanfacine, has been shown to improve cognitive performancewithout exacerbating positive symptoms in small trials of patientswith schizophrenia.257,258 In addition, patients randomizedto risperidone plus guanfacine showed significant improvementon tasks of working memory and attention compared with patientsreceiving typical antipsychotics plus guanfacine.258 However,clozapine and other atypicals have potent antagonist propertiesat ${alpha}$ ₂-adrenergic receptors,259 which may contribute to the atypicalityof atypicals by preferentially enhancing dopaminergic transmissionin the frontal cortex over subcortical dopaminergic pathways.260Indeed, combined treatment of a typical antipsychotic with thehighly selective ${alpha}$ ₂-adrenergic receptor antagonist, idazoxan,has been reported to produce a profile of antipsychotic activitysimilar to clozapine.261 Thus, as ${alpha}$ ₂-adrenergic receptor activitymay be important in developing new drugs for schizophrenia thatcan improve cognition, balancing ${alpha}$ ₂-adrenergic receptor activityto achieve both antipsychotic and procognitive efficacy maybe challenging.

GABA_A Receptors
Appropriately synchronized GABA neurotransmission in the dorsolateralprefrontal cortex is required for adequate working memory,262suggesting that impairments in GABA-mediated inhibition couldcontribute to the cognitive impairments in schizophrenia. Indeed,postmortem studies have shown reduced GABAergic transmissionin schizophrenia.263–265 In addition, recent observations266,267have noted decreases in messenger RNA levels for glutamic aciddecarboxylase 67, the synthetic enzyme for GABA, selectivelyin the prefrontal cortex of patients with schizophrenia. Interestingly,a recent study revealed that GABA alterations in the dorsolateralprefrontal cortex of schizophrenic patients may be restrictedto certain cell classes, such as the chandelier cells, whichsynchronize the activation of pyramidal neurons via GABA_A receptorsubtypes.268 Thus, the use of new benzodiazepine-like agents—selectivefor the ${alpha}$ ₂ subunit of the GABA_A receptor—in cognitive disorderscould be both interesting and revealing. Indeed, there is evidencethat reduced GABA neurotransmission in chandelier cells maybe secondary to altered NMDA receptor function and could representa "final common pathway" of prefrontal dysfunction in schizophrenia.269Thus, drugs targeted to mitigate the disturbances in inhibitionmight be particularly effective in improving cognitive performancein schizophrenia. For example, positive allosteric modulatorsselective for GABA_A receptors containing ${alpha}$ ₂ subunits (eg, a GABA_A ${alpha}$ ₂-selective benzodiazepine) may improve working memory functionin schizophrenia.270 However, drugs that directly activate ${alpha}$ ₂-containingGABA_A receptors independent of the presence of GABA may disruptthe critical synchronization of this circuit and impair workingmemory.269 In addition, activation of GABA_A receptors containingother subunits (eg, ${alpha}$ ₁ or ${alpha}$ ₅), such as by currently availablebenzodiazepines, may impair cognitive function. Indeed, a recentstudy in healthy volunteers showed that, contrary to lorazepam,a GABA_A ${alpha}$ ₂/ ${alpha}$ ₃ subtype–selective partial agonist, TPA023,caused no detectable memory impairment.271

As activation of GABA_A receptors containing ${alpha}$ ₅ subunits, suchas by currently available benzodiazepines, may impair cognitivefunction and cause sedation, inhibitors of these receptors havebeen hypothesized to enhance cognition. Indeed, functionallyselective inverse agonists at ${alpha}$ ₅-containing GABA_A receptors havebeen demonstrated to enhance performance in animal models ofcognition,272–274 apparently without lowering the seizurethreshold as seen with nonselective GABA_A inverse agonists.274,275In addition, ${alpha}$ ₅ subunit knockout mice demonstrate increased hippocampalactivity due to the release of tonic GABAergic inhibition.276Thus, antagonists or inverse agonists at ${alpha}$ ₅-containing GABA_Areceptors may hold promise in the treatment of the cognitivedysfunction in schizophrenia.

Neurosteroids and Sigma Receptors
The sigma ( ${sigma}$ ) receptor was initially designated as a subtypeof opioid receptors277 but was later found to be a distinctpharmacological entity due to lack of binding of the classicalopiate receptor antagonists naloxone and naltrexone.278 Indeed,when the ${sigma}$ 1 receptor was isolated and cloned, it was found tohave no structural similarity to the opioid receptors.279 Thefunctions of these receptors are poorly understood and endogenousligands have yet to be identified, though it has been proposedthat steroid hormones (eg, progesterone and testosterone), drugsof abuse (eg, cocaine, heroin, PCP), and psychiatric drugs (haloperidol,imipramine, and sertraline) may interact with ${sigma}$ receptors.280,281In addition, it is well documented that ${sigma}$ 1 receptor ligands increasethe NMDA receptor response in the hippocampus,282–284suggesting a role in enhancing cognition. Indeed, ${sigma}$ 1 receptoragonists can reverse the memory impairments induced by the NMDAantagonists MK-801 in rodents.285

Neurosteroids, such as dehydroepiandrosterone (DHEA) and allopregnanolone,have been implicated in neuroprotection286–288 and enhancementof NMDA receptor neurotransmission,287,289,290 possibly throughinteraction with ${sigma}$ 1 receptors,290 suggesting therapeutic potentialfor enhancing cognition in schizophrenia. Consistent with theenhancement of NMDA neurotransmission, DHEA can enhance memoryin rodents.291–294 In humans, a double-blind study ofDHEA as an adjunct to antipsychotic treatment in chronic schizophrenicpatients with prominent negative symptoms suggests some efficacyat improving negative symptoms, especially in women,295 thoughfurther studies are needed. Thus, neurosteroids may have therapeuticpotential for improving the cognitive deficits observed in schizophrenia,though long-term treatment with steroids is problematic. Inaddition, while the contribution of ${sigma}$ receptor agonism to theactions of neurosteroids is not entirely known, highly selective ${sigma}$ receptor agonists are needed and hold therapeutic promise.

Potential Future Targets

Top
Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

There are a number of additional largely theoretical pharmacotherapeuticapproaches for the treatment of cognition and schizophrenia.For example, significant progress has been made in recent yearson elucidating various susceptibility genes in schizophrenia,including dysbindin, neuregulin 1, COMT, DISC1, and others.296Interestingly, many of these genes appear to be related to thecontrol of synaptic plasticity and glutamate transmission (particularlyNMDA receptor function) and thus may allow for hypothesis-drivenapproaches for developing of actual disease-modifying drugsfor schizophrenia and cognitive disorders.297 Another strategyinvolves the role of neurotrophic factors in the pathophysiologyof schizophrenia and the theory that schizophrenia may involvea neurodegenerative process.298 Neurotrophic factors, such asbrain-derived neurotrophic factor, may play a role in neuronaland glial differentiation, proliferation, and regeneration andinfluence synaptic organization, neurotransmitter synthesis,and the maintenance of synaptic plasticity.299,300 Thus, strategiesto enhance neurotrophic factor action may be able to preventprogression of schizophrenia.

Altering neurotransmitter signaling by targeting intracellularsignaling cascades has long been suggested to be a future approachto novel therapeutic agents.301 Though there has been concernabout the feasibility of this approach, lithium is a signaltransduction modifier that has been used safely for decades.Some targets being investigated include protein kinase C isoformsand glycogen synthase kinase 3.302 In addition, subtype-selectivephosphodiesterase (PDE) inhibitors, particularly at PDE10A,are actively being explored for the treatment of various symptomdomains in schizophrenia.303 Another interesting approach atthe receptor level would be developing ligands that differentiallyactivate the various signaling pathways mediated by a singlereceptor, a process termed "functional selectivity".304 Indeed,functional selectivity has been described in serotonin, opioid,dopamine, vasopressin, and adrenergic receptor systems304 andmay be initiated by different ligand-induced conformationalstates, as shown for the ß₂-adrenergic receptor.305Thus, the possibility of selecting or designing novel ligandsthat differentially activate only a subset of receptor functionsis intriguing as an approach to drug discovery that may optimizetherapeutic action.

Conclusions

Top
Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

Cognitive dysfunction is a major feature of schizophrenia thatcontributes significantly to the long-term functional impairmentthat patients experience. While the past half-century of antipsychoticdevelopment has had a profound effect on the treatment of schizophrenia,the cognitive deficits in schizophrenia have been insufficientlyaddressed. Therefore, it is critical to continue the pursuitof diverse molecular targets for discovering new pharmacotherapeuticagents for the treatment of schizophrenia. For the past 20 years,psychopharmacologic research in schizophrenia has aimed forthe development of new antipsychotic drugs with a more rapidonset of action, lower risk of side effects, and improved efficacyin the domains of negative and cognitive symptoms from a singlecompound. Currently, however, it seems unlikely that a singledrug will have the desired effect across all these domains,and thus, optimal treatment of schizophrenia will likely relyon individualized polypharmacy and augmentation strategies.The ultimate goal, of course, will be the development of "curetherapeutics"297 which will require significant advances inour understanding of the underlying pathophysiology of schizophrenia,highlighting the need for continued basic research efforts atidentifying and validating diverse and novel molecular targets.

Funding

Top
Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

National Institutes of Health (RO1MH61887 to B.R., RO1MH57635to B.R.); National Institute of Mental Health (NO1MH32004 toB.R.).

Footnotes

¹ To whom correspondence should be addressed; tel: 919-966-7535, fax: 919-966-5640, e-mail: bryan_roth{at}med.unc.edu.

References

Top
Abstract
Introduction
Cholinergic Targets
Glutaminergic Targets
Dopaminergic Targets
Serotonergic Targets
Other Neurotransmitter Targets
Potential Future Targets
Conclusions
Funding
References

Kraepelin E. Dementia Praecox and Paraphrenia [1919] (1971) New York, NY: Robert E. Krieger.