UMLS:C0036341 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0036341 (schizophrenia)
60,220 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Behavioral and neuronal abnormalities observed in mice exhibiting a reduced expression of the dopamine transporter model important aspects of schizophrenia, addiction, and attentional disorders. As the consequences of a chronic hyperdopaminergic tone for striatal output regulation have remained poorly understood, the present experiments were designed to determine the status of striatal interneuronal cholinergic neurotransmission in dopamine transporter knockdown animals. The high-affinity choline transporter represents the rate-limiting step of acetylcholine synthesis and release. Compared with wild type mice, striatal high-affinity choline transporter expression in dopamine transporter knockdown mice was significantly decreased. As in vivo basal striatal acetylcholine release did not differ between the strains, reduced high-affinity choline transporter expression in dopamine transporter knockdown mice was not due to reduced basal cholinergic activity. Furthermore, the proportion of high-affinity choline transporters expressed in plasma membrane-enriched versus vesicular membrane-enriched fractions did not differ from wild type animals, suggesting that changes in intracellular high-affinity choline transporter trafficking were not associated with lower overall levels of striatal high-affinity choline transporters. Synaptosomal choline uptake assays indicated a reduced capacity of striatal high-affinity choline transporters in dopamine transporter knockdown mice, and thus the functional significance of the reduced level of high-affinity choline transporter expression. Likewise, in vivo measures of the capacity of striatal high-affinity choline transporters to clear increases in extracellular choline concentrations, using choline-sensitive microelectrodes, revealed a 37-41% reduction in hemicholinium-sensitive clearance of exogenous choline in dopamine transporter knockdown mice. Furthermore, clearance of potassium-evoked choline signals was reduced in dopamine transporter knockdown mice (1.63+/-0.15 microM/s) compared with wild type animals (2.29+/-0.21 microM/s). Dysregulated striatal cholinergic neurotransmission is hypothesized to disrupt the integration of thalamic and cortical information at spiny projection neurons and thus to contribute to abnormal striatal information processing in dopamine transporter knockdown mice.
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PMID:Reduced expression and capacity of the striatal high-affinity choline transporter in hyperdopaminergic mice. 1667 38

RGS3 and RGS4 are GTPase-activating proteins expressed in the brain and heart that accelerate the termination of G(i/o)- and G(q)-mediated signaling. We report here the determinants mediating selective association of RGS4 with several G protein-coupled receptors (GPCRs) that form macromolecular complexes with neuronal G protein-gated inwardly rectifying potassium (Kir3 or GIRK) channels. Kir3 channels are instrumental in regulating neuronal firing in the central and peripheral nervous system and pacemaker activity in the heart. By using an epitope-tagged degradation-resistant RGS4 mutant, RGS4(C2V), immunoprecipitation of several hemagglutinin-tagged G(i/o)-coupled and G(q)-coupled receptors expressed in Chinese hamster ovary (CHO-K1) cells readily co-precipitated both Kir3.1/Kir3.2a channels and RGS4(C2V). In contrast to RGS4(C2V), the closely related and functionally active RGS3 "short" isoform (RGS3s) did not interact with any of the GPCR-Kir3 channel complexes examined. Deletion and chimeric RGS constructs indicate both the N-terminal domain and the RGS domain of RGS4(C2V) are necessary for association with m2 receptor-Kir3.1/Kir3.2a channel complexes, where the GPCR was found to be the major target for RGS4(C2V) interaction. The functional impact of RGS4(C2V) "precoupling" to the GPCR-Kir3 channel complex versus RGS3s "collision coupling" was a 100-fold greater potency in the acceleration of G protein-dependent Kir3 channel-gating kinetics with no attenuation in current amplitude. These findings demonstrate that RGS4, a highly regulated modulator and susceptibility gene for schizophrenia, can directly associate with multiple GPCR-Kir3 channel complexes and may affect a wide range of neurotransmitter-mediated inhibitory and excitatory events in the nervous and cardiovascular systems.
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PMID:RGS3 and RGS4 differentially associate with G protein-coupled receptor-Kir3 channel signaling complexes revealing two modes of RGS modulation. Precoupling and collision coupling. 1697 24

Schizophrenia is a chronic mental illness affecting 0.4% of the population. Existing antipsychotic drugs are mainly used to treat positive symptoms such as hallucinations but have only poor effects on negative symptoms such as cognitive deficits or depression. TREK and TRAAK channels are two P domain background potassium channels activated by polyunsaturated fatty acids and mechanical stress. TREK but not TRAAK channels are regulated by Gs- and Gq-coupled pathways. The inactivation of the TREK-1 but not the TRAAK channel in mice results in a depression-resistant phenotype. In addition, it has been shown that antidepressants such as fluoxetine or paroxetine directly inhibit TREK channel activity. Here we show that different antipsychotic drugs directly inhibit TREK currents with IC(50) values of approximately 1 to approximately 20 microM. No effect is seen on TRAAK channel activity. We conclude that TREK channels might be involved in the therapeutic action of antipsychotics or in their secondary effects. Furthermore, TREK channels could play a role in the pathophysiology of psychiatric disorders such as depression and schizophrenia.
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PMID:Antipsychotics inhibit TREK but not TRAAK channels. 1722 6

Continuous ingestion of phencyclidine (PCP) in humans produces long-lasting schizophrenic-like cognitive dysfunction. Although a malfunction of dopaminergic and/or glutamatergic neurotransmission is implicated in the etiology of schizophrenia, involvement of the dopaminergic-glutamatergic neurotransmission in the cognitive dysfunction induced by repeated PCP treatment is minor. We demonstrated that mice treated with PCP (10 mg/kg/day s.c.) for 14 days displayed an impairment of latent learning in a water-finding task and of learning-associated phosphorylation of Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) and NR1 in the prefrontal cortex even after drug withdrawal. The infusion of a CaMKII inhibitor and NR1 antisense oligonucleotide into the prefrontal cortex produced an impairment of latent learning and decrease of learning-associated phosphorylation of CaMKII, which were observed in the PCP-treated mice. Exogenous NMDA-induced CaMKII activation was not observed in slices of the prefrontal cortex prepared from mice treated repeatedly with PCP. The potentiation of NMDA receptor function by the infusion of glycine into the prefrontal cortex ameliorated these impairments in mice treated repeatedly with PCP. The high potassium-stimulated release of dopamine from the prefrontal cortex was less extensive in the PCP-treated than saline-treated mice. The infusion of a dopamine-D1 receptor agonist into the prefrontal cortex attenuated the impairment of latent learning and decrease of learning-associated NR1 phosphorylation in the PCP-treated mice, suggesting a functional linkage between glutamatergic and dopaminergic signaling. These findings indicate that repeated PCP treatment impairs latent learning through a prefrontal cortical dysfunction of NMDA-CaMKII signaling, which is associated with dopaminergic hypofunction.
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PMID:Involvement of a dysfunctional dopamine-D1/N-methyl-d-aspartate-NR1 and Ca2+/calmodulin-dependent protein kinase II pathway in the impairment of latent learning in a model of schizophrenia induced by phencyclidine. 1734 53

Calcium-activated potassium channels modulate calcium signaling cascades and membrane potential in both excitable and non-excitable cells. In this article we will review the physiological properties, the structure activity relationships of the existing peptide and small molecule modulators and the therapeutic importance of the three small-conductance channels KCa2.1-KCa2.3 (a.k.a. SK1-SK3) and the intermediate-conductance channel KCa3.1 (a.k.a. IKCa1). The apamin-sensitive KCa2 channels contribute to the medium afterhyperpolarization and are crucial regulators of neuronal excitability. Based on behavioral studies with apamin and on observations made in several transgenic mouse models, KCa2 channels have been proposed as targets for the treatment of ataxia, epilepsy, memory disorders and possibly schizophrenia and Parkinson's disease. In contrast, KCa3.1 channels are found in lymphocytes, erythrocytes, fibroblasts, proliferating vascular smooth muscle cells, vascular endothelium and intestinal and airway epithelia and are therefore regarded as targets for various diseases involving these tissues. Since two classes of potent and selective small molecule KCa3.1 blocker, triarylmethanes and cyclohexadienes, have been identified, several of these postulates have already been validated in animal models. The triarylmethane ICA-17043 is currently in phase III clinical trials for sickle cell anemia while another triarylmethane, TRAM-34, has been shown to prevent vascular restenosis in rats and experimental autoimmune encephalomyelitis in mice. Experiments showing that a cyclohexadiene KCa3.1 blocker reduces infarct volume in a rat subdural hematoma model further suggest KCa3.1 as a target for the treatment of traumatic and possibly ischemic brain injury. Taken together KCa2 and KCa3.1 channels constitute attractive new targets for several diseases that currently have no effective therapies.
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PMID:Modulators of small- and intermediate-conductance calcium-activated potassium channels and their therapeutic indications. 1758 55

Interaction at dopamine D4 receptors may improve cognitive function, which is highly impaired in individuals with schizophrenia, but comparative studies of recent antipsychotics in cellular models of D4 receptor activation are lacking. Here, we report the in-vitro profile of over 30 ligands at recombinant hD4.4 receptors. In [35S]GTPgammaS binding experiments using membranes of CHO-hD4.4 cells, apomorphine, preclamol and the selective D4 agonists, ABT724, CP226269, Ro-10-5824 and PD168077, behaved as partial agonists (Emax 20-60% vs. dopamine), whereas L745870 and RBI257, displayed antagonist properties. The 'conventional' antipsychotic, haloperidol and the 'atypicals', clozapine and risperidone, exhibited antagonist properties, while 'third generation' compounds bifeprunox, SLV313 and F15063, acted as partial agonists (10-30%). Aripiprazole and SSR181507 slightly stimulated [35S]GTPgammaS binding at micromolar concentrations. In Xenopus laevis oocytes co-expressing hD4.4 receptors with G-protein-coupled inwardly rectifying potassium (GIRK) channels, apomorphine, preclamol, ABT724, CP226269, and PD168077 stimulated GIRK currents (Emax 70-80%). The 5-HT1A receptor ligands, WAY100635 and flibanserin, also exhibited partial agonist activity (30% and 15%, respectively). Haloperidol, clozapine, olanzapine and nemonapride did not stimulate GIRK currents, whereas aripiprazole, bifeprunox, SLV313 and F15063, but not SSR181507, exhibited partial agonism (Emax 20-35%). In-vitro responses depended on experimental conditions: increasing NaCl concentration (30 mm to 100 mm) reduced agonist efficacy in [35S]GTPgammaS binding, whereas decreasing the amount of hD4.4 cRNA injected into oocytes (from 2.0 to 0.5 ng/oocyte) reduced agonist efficacy of several compounds. These data indicate that, unlike conventional or 'atypical' antipsychotics, several 'third generation' agents display D4 receptor partial agonism that may be sufficient to influence physiological D4 receptor activity in vivo.
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PMID:Agonist and antagonist properties of antipsychotics at human dopamine D4.4 receptors: G-protein activation and K+ channel modulation in transfected cells. 1789 83

Potassium (K+) channels are the most heterogeneous and widely distributed class of ion channels. K(+) channels are dynamic pore-forming transmembrane proteins known to play important roles in all cell types underlying both normal and pathophysiological functions. Essential for such diverse physiological processes as nerve impulse propagation, muscle contraction, cellular activation and the secretion of biologically active molecules, various K(+) channels are recognized as potential therapeutic targets in the treatment of multiple sclerosis, Alzheimer's disease, Parkinson's disease, epilepsy, stroke, brain tumors, brain/spinal cord ischemia, pain and schizophrenia, migraine, as well as cardiac arrhythmias, pulmonary hypertension, diabetes, cervical cancer, urological diseases and sepsis. In addition to their importance as therapeutic targets, certain K(+) channels are gaining attention for their beneficial roles in anesthesia, neuroprotection and cardioprotection. The K(+) channel gene families (subdividing into multiple subfamilies) include voltage-gated (K(v): K(v)1-K(v)12 or KCNA-KCND, KCNF-KCNH, KCNQ, KCNS), calcium-activated (K(Ca): K(Ca)1-K(Ca)5 or KCNM-KCNN), inwardly rectifying (K(ir): K(ir)1-K(ir)7 or KCNJ) and background/leak or tandem 2-pore (K(2P): K(2P)1-K(2P)7, K(2P)9-K(2P)10, K(2P)12-K(2P)13, K(2P)15-K(2P)18 or KCNK) K(+) channels. Worldwide, the pharmaceutical industry is actively developing better strategies for targeting ion channels, in general, and K(+) channels, in particular, already generating over $6 billion in sales per annum from drugs designed to block or modulate ion channel function. This review provides an overview of recent patents on emerging K(+) channel blockers and activators (openers) with potential for development as new and improved nervous system therapeutic agents.
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PMID:Potassium channel blockers and openers as CNS neurologic therapeutic agents. 1822 Dec 32

A-to-I RNA editing has mainly been found in various receptors and ion channels in the central nervous system, including the serotonin 2C receptor, glutamate receptor, GABA receptor, and potassium channel. Interestingly, most of them are suggested to be involved in the pathophysiology of major mental disorders such as schizophrenia, bipolar disorder, and major depression. Here we review studies examining the relationship between the serotonin 2C receptor and major mental disorders.
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PMID:[RNA editing of serotonin 2C receptor and major mental disorders]. 1837 71

Synaptic strengthening produced by epileptiform activity may contribute to seizure progression and cognitive impairment in epilepsy. Agents that limit this form of plasticity may have therapeutic benefit. Neuregulin is an endogenous growth factor that is released at synapses in an activity dependent manner and can suppress long term potentiation (LTP). Alterations in neuregulin signaling have been associated with schizophrenia. A role for neuregulin in epilepsy has not been explored. We used field potential recordings to examine the role of neuregulin in regulating synaptic strengthening following epileptiform activity in hippocampal slices. Neuregulin had no effect on basal synaptic transmission, isolated NMDA field potentials or GABAergic inhibition on CA1 pyramidal neurons. However, it reversed LTP at CA1 synapses. Brief exposure to 10 mM potassium chloride produced epileptiform bursting and potentiation of CA1 synapses and suppressed the subsequent induction of LTP. Neuregulin reversed high K(+)-induced synaptic strengthening, enabling LTP induction after neuregulin washout. In this manner neuregulin preserved the dynamic range of synaptic responses and plasticity after epileptiform activity. These results indicate that LTP and high K(+)-induced synaptic strengthening share a common neuregulin-sensitive mechanism. By opposing synaptic strengthening caused by epileptiform activity, we suggest that neuregulin may reduce the generation and spread of seizures as well as memory deficits associated with epilepsy.
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PMID:Neuregulin blocks synaptic strengthening after epileptiform activity in the rat hippocampus. 1838

Administration of certain drugs (for example, antiarrhythmics, antihistamines, antibiotics, antipsychotics) may occasionally affect myocardial repolarization and cause prolongation of the QT interval. We performed a whole genome association study of drug-induced QT prolongation after 14 days of treatment in a phase 3 clinical trial evaluating the efficacy, safety and tolerability of a novel atypical antipsychotic, iloperidone, in patients with schizophrenia. We identified DNA polymorphisms associated with QT prolongation in six loci, including the CERKL and SLCO3A1 genes. Each single nucleotide polymorphism (SNP) defined two genotype groups associated with a low mean QT change (ranging from -0.69 to 5.67 ms depending on the SNP) or a higher mean QT prolongation (ranging from 14.16 to 17.81 ms). The CERKL protein is thought to be part of the ceramide pathway, which regulates currents conducted by various potassium channels, including the hERG channel. It is well established that inhibition of the hERG channel can prolong the QT interval. SLCO3A1 is thought to play a role in the translocation of prostaglandins, which have known cardioprotective properties, including the prevention of torsades de pointes. Our findings also point to genes involved in myocardial infarction (PALLD), cardiac structure and function (BRUNOL4) and cardiac development (NRG3). Results of this pharmacogenomic study provide new insight into the clinical response to iloperidone, developed with the goal of directing therapy to those patients with the optimal benefit/risk ratio.
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PMID:Whole genome association study identifies polymorphisms associated with QT prolongation during iloperidone treatment of schizophrenia. 1852 Oct 91

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