Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:2.7.11.26 (GSK)
6,788 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Highly active antiretroviral therapy (HAART) has made a significant impact on the lives of people living with HIV-1 infection. The incidence of neurologic disease associated with HIV-1 infection of the CNS plummeted between 1996-2000, but unfortunately the number of people currently HIV-1 infected (i.e., prevalence) with associated cognitive impairment has been steadily rising. While the reasons for this may be multifactorial, the implication is clear: there is a pressing need for adjunctive therapy directed at reversing or preventing damage to vulnerable pathways in the central nervous system (CNS) from HIV-1 infection. Using a team of preclinical and clinical investigators, we have focused our efforts on defining how proinflammatory mediators and secretory neurotoxins from HIV-1 disrupt signaling of the survival-regulating enzyme, glycogen synthase kinase 3 beta (GSK-3beta). In a series of studies initiated using in vitro, then in vivo models of HIV-1-associated dementia (HAD), we have demonstrated the ability of the mood stabilizing and anticonvulsant drug, sodium valproate (VPA), that inhibits GSK-3beta activity and other downstream mediators, to reverse HIV-1-induced damage to synaptic pathways in the CNS. Based on these results, we successfully performed pharmacokinetic and safety and tolerability trials with VPA in a cohort of HIV-1-infected patients with neurologic disease. VPA was well tolerated in this population and secondary measures of brain metabolism, as evidenced by an increase in N-acetyl aspartate/creatine (NAA/Cr), further suggested that VPA may improve gray matter integrity in brain regions damaged by HIV-1. These findings highlight the therapeutic potential of GSK-3beta blockade.
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PMID:Glycogen synthase kinase 3 beta (GSK-3 beta) as a therapeutic target in neuroAIDS. 1804 Aug 31

Gateways to Clinical Trials are a guide to the most recent clinical trials in current literature and congresses. The data in the following tables has been retrieved from the Clinical Trials Knowledge Area of Prous Science Intergrity, the drug discovery and development portal, http://integrity.prous.com. This issue focuses on the following selection of drugs: 249553, 2-Methoxyestradiol; Abatacept, Adalimumab, Adefovir dipivoxil, Agalsidase beta, Albinterferon alfa-2b, Aliskiren fumarate, Alovudine, Amdoxovir, Amlodipine besylate/atorvastatin calcium, Amrubicin hydrochloride, Anakinra, AQ-13, Aripiprazole, AS-1404, Asoprisnil, Atacicept, Atrasentan; Belimumab, Bevacizumab, Bortezomib, Bosentan, Botulinum toxin type B, Brivaracetam; Catumaxomab, Cediranib, Cetuximab, cG250, Ciclesonide, Cinacalcet hydrochloride, Curcumin, Cypher; Darbepoetin alfa, Denosumab, Dihydrexidine; Eicosapentaenoic acid/docosahexaenoic acid, Entecavir, Erlotinib hydrochloride, Escitalopram oxalate, Etoricoxib, Everolimus, Ezetimibe; Febuxostat, Fenspiride hydrochloride, Fondaparinux sodium; Gefitinib, Ghrelin (human), GSK-1562902A; HSV-tk/GCV; Iclaprim, Imatinib mesylate, Imexon, Indacaterol, Insulinotropin, ISIS-112989; L-Alanosine, Lapatinib ditosylate, Laropiprant; Methoxy polyethylene glycol-epoetin-beta, Mipomersen sodium, Motexafin gadolinium; Natalizumab, Nimotuzumab; OSC, Ozarelix; PACAP-38, Paclitaxel nanoparticles, Parathyroid Hormone-Related Protein-(1-36), Pasireotide, Pegfilgrastim, Peginterferon alfa-2a, Peginterferon alfa-2b, Pemetrexed disodium, Pertuzumab, Picoplatin, Pimecrolimus, Pitavastatin calcium, Plitidepsin; Ranelic acid distrontium salt, Ranolazine, Recombinant human relaxin H2, Regadenoson, RFB4(dsFv)-PE38, RO-3300074, Rosuvastatin calcium; SIR-Spheres, Solifenacin succinate, Sorafenib, Sunitinib malate; Tadalafil, Talabostat, Taribavirin hydrochloride, Taxus, Temsirolimus, Teriparatide, Tiotropium bromide, Tipifarnib, Tirapazamine, Tocilizumab; UCN-01, Ularitide, Uracil, Ustekinumab; V-260, Vandetanib, Vatalanib succinate, Vernakalant hydrochloride, Vorinostat; YM-155; Zileuton, Zoledronic acid monohydrate.
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PMID:Gateways to clinical trials. 1820 Mar 33

Lithium and valproic acid (VPA) are two primary drugs used to treat bipolar mood disorder and have frequently been used in combination to treat bipolar patients resistant to monotherapy with either drug. Lithium, a glycogen synthase kinase-3 (GSK-3) inhibitor, and VPA, a histone deacetylase (HDAC) inhibitor, have neuroprotective effects. The present study was undertaken to demonstrate synergistic neuroprotective effects when both drugs were coadministered. Pretreatment of aging cerebellar granule cells with lithium or VPA alone provided little or no neuroprotection against glutamate-induced cell death. However, copresence of both drugs resulted in complete blockade of glutamate excitotoxicity. Combined treatment with lithium and VPA potentiated serine phosphorylation of GSK-3 alpha and beta isoforms and inhibition of GSK-3 enzyme activity. Transfection with GSK-3alpha small interfering RNA (siRNA) and/or GSK-3beta siRNA mimicked the ability of lithium to induce synergistic protection with VPA. HDAC1 siRNA or other HDAC inhibitors (phenylbutyrate, sodium butyrate or trichostatin A) also caused synergistic neuroprotection together with lithium. Moreover, combination of lithium and HDAC inhibitors potentiated beta-catenin-dependent, Lef/Tcf-mediated transcriptional activity. An additive increase in GSK-3 serine phosphorylation was also observed in mice chronically treated with lithium and VPA. Together, for the first time, our results demonstrate synergistic neuroprotective effects of lithium and HDAC inhibitors and suggest that GSK-3 inhibition is a likely molecular target for the synergistic neuroprotection. Our results may have implications for the combined use of lithium and VPA in treating bipolar disorder. Additionally, combined use of both drugs may be warranted for clinical trials to treat glutamate-related neurodegenerative diseases.
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PMID:Synergistic neuroprotective effects of lithium and valproic acid or other histone deacetylase inhibitors in neurons: roles of glycogen synthase kinase-3 inhibition. 1832 1

Neurofibrillary tangles (NFTs), comprising human intracellular microtubule-associated protein tau, are one of the hallmarks of tauopathies, including Alzheimer's disease. Recently, a report that caspase-cleaved tau is present in NFTs has led to the hypothesis that the mechanisms underlying NFT formation may involve the apoptosis cascade. Here, we show that adenoviral infection of tau into COS-7 cells induces activation of c-jun N-terminal kinase (JNK), followed by excessive phosphorylation of tau and its cleavage by caspase. However, JNK activation alone was insufficient to induce sodium dodecyl sulfate (SDS)-insoluble tau aggregation and additional phosphorylation by GSK-3beta was required. In SH-SY5Y neuroblastoma cells, overexpression of active JNK and GSK-3beta increased caspase-3 activation and cytotoxicity more than overexpression of tau alone. Taken together, these results indicate that, although JNK activation may be a primary inducing factor, further phosphorylation of tau is required for neuronal death and NFT formation in neurodegenerative diseases, including those characterized by tauopathy.
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PMID:Active c-jun N-terminal kinase induces caspase cleavage of tau and additional phosphorylation by GSK-3beta is required for tau aggregation. 1854 Aug 81

Free fatty acids (FFAs) are proposed to play a pathogenic role in both peripheral and hepatic insulin resistance. We have examined the effect of saturated FFA on insulin signalling (100 nM) in two hepatocyte cell lines. Fao hepatoma cells were treated with physiological concentrations of sodium palmitate (0.25 mM) (16:0) for 0.25-48 h. Palmitate decreased insulin receptor (IR) protein and mRNA expression in a dose- and time-dependent manner (35% decrease at 12 h). Palmitate also reduced insulin-stimulated IR and IRS-2 tyrosine phosphorylation, IRS-2-associated PI 3-kinase activity, and phosphorylation of Akt, p70 S6 kinase, GSK-3 and FOXO1A. Palmitate also inhibited insulin action in hepatocytes derived from wild-type IR (+/+) mice, but was ineffective in IR-deficient (-/-) cells. The effects of palmitate were reversed by triacsin C, an inhibitor of fatty acyl CoA synthases, indicating that palmitoyl CoA ester formation is critical. Neither the non-metabolized bromopalmitate alone nor the medium chain fatty acid octanoate (8:0) produced similar effects. However, the CPT-1 inhibitor (+/-)-etomoxir and bromopalmitate (in molar excess) reversed the effects of palmitate. Thus, the inhibition of insulin signalling by palmitate in hepatoma cells is dependent upon oxidation of fatty acyl-CoA species and requires intact insulin receptor expression.
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PMID:Saturated fatty acids inhibit hepatic insulin action by modulating insulin receptor expression and post-receptor signalling. 1871 97

(+)-Dapoxetine hydrochloride, (R)-Etodolac; Abatacept, ABT-510, Adalimumab, Agatolimod sodium, Alemtuzumab, Alvocidib hydrochloride, Aminolevulinic acid methyl ester, Aripiprazole, AS01B, AS02B, AS02V, Azacitidine; Becatecarin, Bevacizumab, Bevirimat, Bortezomib, Bremelanotide; CAIV-T, Canfosfamide hydrochloride, CHR-2797, Ciclesonide, Clevidipine; Darbepoetin alfa, Decitabine, Degarelix acetate, Dendritic cell-based vaccine, Denosumab, Desloratadine, DMXB-Anabaseine, Duloxetine hydrochloride, Dutasteride; Ecogramostim, Eicosapentaenoic acid/docosahexaenoic acid, Eletriptan, Enzastaurin hydrochloride, Erlotinib hydrochloride, Escitalopram oxalate, Etoricoxib, Everolimus, Ezetimibe, Ezetimibe/simvastatin; Ferumoxytol, Fesoterodine fumarate, Fulvestrant; Gefitinib, GM-CSF DNA, GSK-690693; H5N1 avian flu vaccine, Hepatitis B hyperimmunoglobulin, Human Fibroblast Growth Factor 1, Hypericin-PVP; Icatibant acetate, Iclaprim, Immunoglobulin intravenous (human), Ipilimumab, ISS-1018; L19-IL-2, Lapuleucel-T, Laropiprant, Liposomal doxorubicin, LP-261, Lumiracoxib, LY-518674; MDV-3100, MGCD-0103, Mirabegron, MyoCell; NASHA/Dx, Niacin/laropiprant; O6-Benzylguanine, Ocrelizumab, Olmesartan medoxomil, Omalizumab; P-276-00, Paclitaxel nanoparticles, Paclitaxel nanoparticles, Padoporfin, Paliperidone, PAN-811, Pegaptanib octasodium, Pegfilgrastim, Pemetrexed disodium, PF-00299804, Pimecrolimus, Prasugrel, Pregabalin; Reolysin, Rimonabant, Rivaroxaban, Rosuvastatin calcium; Satraplatin, SCH-697243,Selenite sodium, Silodosin, Sorafenib, Sunitinib malate; Talarozole, Taxus, Temsirolimus, Tocilizumab, Tolevamer potassium sodium, Tremelimumab, TTP-889; Uracil; V-260, Valsartan/amlodipine besylate, Vardenafil hydrochloride hydrate, Varenicline tartrate, Varespladib, Vitespen, Voclosporin, VX-001; Xience V; Zotarolimus-eluting stent.
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PMID:Gateways to clinical trials. 1880 98

(-)-Epigallocatechin gallate, 501516, 89-12; Abatacept, Adalimumab, Adefovir dipivoxil, AG-701, Agatolimod sodium, Alefacept, Aliskiren fumarate, Apixaban, Atazanavir sulfate, Atrasentan, Axitinib; BI-1744-CL, BIBF-1120, BIBW-2992, Bortezomib; Carboxyamidotriazole, Caspofungin acetate, CBP-501, Cediranib, Ceftobiprole, Certolizumab pegol, Cetuximab, Cholesteryl hydrophobized polysaccharide-Her2 protein complex, CHP-NY-ESO-1, Cypher; Dalbavancin, Dalcetrapib, Daptomycin, Darapladib, Deferasirox, Deforolimus, Denosumab, DNA-HIV-C, Dovitinib, DR-5001, Dronedarone hydrochloride, DT388IL3; E75, EC-17/EC-90, Ecogramostim, Efungumab, Entecavir, EP HIV-1090, EP-2101, Everolimus, Ezetimibe, Ezetimibe/simvastatin; Faropenem daloxate, Fluticasone furoate, Fondaparinux sodium, Fospropofol disodium, Fulvestrant; Golimumab, GSK-089, GW-590735; HO/03/03, hTERT572, hTERT572Y; Iloperidone; Immunoglobulin intravenous (human), Ispinesib mesylate, Istradefylline, Ixabepilone; JR-031, JX-594; KLH; Laropiprant, Lecozotan hydrochloride, Lenalidomide, Lestaurtinib, Linezolid; MGCD-0103, MK-0646, MVA-BN Measles; NI-0401, Niacin/laropiprant, NSC-719239, NYVAC-C; Ospemifene; Paliperidone palmitate, PAN-811, PCV7, Pegfilgrastim, Peginterferon alfa-2a, PEGirinotecan, Perifosine, Pertuzumab, PF-00299804, Picoplatin, Pimavanserin tartrate, Pitavastatin calcium, Pomalidomide, Prasterone, Pratosartan, Prucalopride, PSMA27/pDOM, Pyridoxal phosphate; QS-21, Quercetin; Rebimastat, Rimonabant, Rolofylline, Romidepsin, Rosuvastatin calcium, RTS,S/SBAS2; SCH-530348, SN-29244, Soblidotin, Sodium dichloroacetate, Solifenacin succinate, Sorafenib, Spheramine, SU-6668, Succinobucol; Taranabant, Taxus, Telaprevir, Telavancin hydrochloride, Telbivudine, Tenofovir disoproxil fumarate, Tigecycline, Tiotropium bromide, Tocilizumab, Triphendiol; UC-781, Udenafil, UNIL-025; V-5 Immunitor, Valsartan/amlodipine besylate, Varenicline tartrate, Velafermin, Vernakalant hydrochloride, Vinflunine, Vitespen, Vorinostat, VX-001; Xience V, XRP-0038; Yttrium Y90 Epratuzumab; Z-360, Ziconotide, Ziprasidone hydrochloride, Zotarolimus, Zotarolimus-eluting stent.
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PMID:Gateways to clinical trials. July-August 2008. 1885 47

Gateways to Clinical Trials are a guide to the most recent clinical trials in current literature and congresses. The data in the following tables has been retrieved from the Clinical Trials Knowledge Area of Prous Science Integrity, the drug discovery and development portal, http://integrity.prous.com.This issue focuses on the following selection of drugs: ABT-263, AC-2307, Aclidinium bromide, Adefovir dipivoxil, ADH-1, Agatolimod sodium, Alefacept, Aliskiren fumarate, Aminolevulinic acid methyl ester, Anakinra, Apaziquone, Aprepitant, Aripiprazole, ASM-8, Atiprimod hydrochloride, AVE-0277, AVE-1642, AVE-8062, Axitinib, Azacitidine, AZD-0530; Bazedoxifene acetate, Bevacizumab, Bexarotene, BI-2536, Biphasic insulin aspart, BMS-387032, BMS-663513, Bortezomib, BQ-123, Brivanib alaninate, BSI-201; Caspofungin acetate, CDX-110, Cetuximab, Ciclesonide, CR-011, Cypher; Daptomycin, Darbepoetin alfa, Dasatinib, Decitabine, Deferasirox, Denosumab, Dexlansoprazole, Dexmethylphenidate hydrochloride, DNA-Hsp65 vaccine, Dovitinib, Drotrecogin alfa (activated), DTaP-HBV-IPV/Hibvaccine, DTaP-IPV-HB-PRP-T, Duloxetine hydrochloride, Dutasteride; Ecogramostim, Elacytarabine, Emtricitabine, Endothelin, Entecavir, Eplivanserin fumarate, Escitalopram oxalate, Everolimus, Ezetimibe, Ezetimibe/simvastatin; Farletuzumab, Fesoterodine fumarate, Fibrin sealant (human), Fulvestrant; Gefitinib, Gemtuzumab ozogamicin, Glufosfamide, GSK-1562902A; Hib-TT; Imatinib mesylate, IMC-11F8, Imidazoacridinone, IMP-321, INCB-18424, Indiplon, Indisulam, INNO-406, Irinotecan hydrochloride/Floxuridine, ITF-2357, Ixabepilone; KRN-951; Lasofoxifene tartrate; Lenalidomide, LGD-4665, Lonafarnib, Lubiprostone, Lumiliximab; MDX-1100, Melan-A/MART-1/gp100/IFN-alfa, Methyl-CDDO, Metreleptin, MLN-2704, Mycophenolic acid sodium salt; Na-ASP-2, Naproxcinod, Nilotinib hydrochloride monohydrate, NPI-2358; Oblimersen sodium, Odanacatib; Paclitaxel nanoparticles, PAN-811, Panobinostat, PBI-1402, PC-515, Peginterferon alfa-2a, Peginterferon alfa-2b, Pemetrexed disodium, Perillyl alcohol, Perphenazine 4-aminobutyrate, PeviPRO/breast cancer, PF-03814735, PHA-739358, Pimecrolimus, Plitidepsin, Posaconazole, Prasterone, Prasugrel, Pregabalin, Prucalopride, PRX-08066; rAAV2-TNFR:Fc, Ranelic acid distrontium salt, Ranibizumab, rCD154-CLL, Retapamulin, RTS,S/SBAS2, rV-PSA-TRICOM/rF-PSA-TRICOM; SG-2000, Sinecatechins, Sirolimus-eluting stent, Sorafenib, SP-1640, Strontium malonate, Succinobucol, Sunitinib malate; Taxus, Teduglutide, Telavancin hydrochloride, Telbivudine, Telmisartan/hydrochlorothiazide, Tenofovir disoproxil fumarate, Tenofovir disoproxil fumarate/emtricitabine, Tocilizumab; Ustekinumab; V-5 Immunitor, Voriconazole, Vorinostat; Xience V, XL-184, XL-647, XL-765; Y-39983, Zibotentan.
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PMID:Gateways to clinical trials. 1898 83

The microtubule-associated protein tau, in a hyperphosphorylated form, aggregates into insoluble paired-helical filaments (PHFs) in Alzheimer's disease (AD) and other tauopathies. In AD, there is approximately 8 mol of phosphate per mole of tau distributed among approximately 30 PHF phosphorylation sites as compared to 2-3 mol of phosphate per mole in normal brain. In AD, kinases such as glycogen synthase kinase-3beta (GSK-3beta) are believed to be involved in the generation of hyperphosphorylated tau. However, the functional consequences of hyperphosphorylation on the microtubule binding and polymerization of tau are not well understood. To address this question, we have generated pseudohyperphosphorylation mutants consisting of six and seven sites in the proline-rich region and carboxy terminus of tau by amino acid substitution. In addition, several single, double, and triple pseudophosphorylation mutants were also generated. Pseudophosphorylation of tau decreases its affinity for microtubules, and pseudohyperphosphorylated forms of tau do not have significantly decreased levels of microtubule binding as compared to single and double sites. Three pseudohyperphosphorylated forms of tau with altered sodium dodecyl sulfate-polyacrylamide gel electrophoresis migration have a greater effect on its inducer-mediated polymerization, slowing the rate of nucleation and elongation. On the basis of the observations that pseudohyperphosphorylated tau has decreased affinity for microtubules and reduced inducer-initiated rates of nucleation and polymerization, we propose that this combination could be the cause of the increased cytotoxicity of hyperphosphorylated tau in Alzheimer's disease and also explain the potentially beneficial role of tau polymerization and NFT formation.
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PMID:Pseudohyperphosphorylation causing AD-like changes in tau has significant effects on its polymerization. 1945 90

Medulloblastomas are the most frequent malignant brain tumors in children. Sunitinib is an oral multitargeted tyrosine kinase inhibitor used in clinical trials as an antiangiogenic agent for cancer therapy. In this report, we show that sunitinib induced apoptosis and inhibited cell proliferation of both a short-term primary culture (VC312) and an established cell line (Daoy) of human medulloblastomas. Sunitinib treatment resulted in the activation of caspase-3 and cleavage of poly(ADP-ribose) polymerase and upregulation of proapoptotic genes, Bak and Bim, and inhibited the expression of survivin, an antiapoptotic protein. Sunitinib treatment also downregulated cyclin E, cyclin D2, and cyclin D3 and upregulated p21Cip1, all of which are involved in regulating cell cycle. In addition, it inhibited phosphorylation of signal transducer and activator of transcription 3 (STAT3) and AKT (protein kinase B) in the tumor cells. Dephosphorylation of STAT3 (Tyr(705)) induced by sunitinib was helped by a reduction in activities of Janus-activated kinase 2 and Src. Additionally, sodium vanadate, an inhibitor of protein tyrosine phosphatases, partially blocked the inhibition of phosphorylated STAT3 by sunitinib. Loss of phosphorylated AKT after sunitinib treatment was accompanied by decreased phosphorylation of downstream proteins glycogen synthase kinase-3beta and mammalian target of rapamycin. Expression of a constitutively activated STAT3 mutant or myristoylated AKT partially blocked the effects of sunitinib in these tumor cells. Sunitinib also inhibited the migration of medulloblastoma tumor cells in vitro. These findings suggest the potential use of sunitinib for the treatment of pediatric medulloblastomas.
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PMID:Sunitinib induces apoptosis and growth arrest of medulloblastoma tumor cells by inhibiting STAT3 and AKT signaling pathways. 2005 26


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