about
Phosphorylation of the actin binding protein Drebrin at S647 is regulated by neuronal activity and PTENDephosphorylation of 2,3-bisphosphoglycerate by MIPP expands the regulatory capacity of the Rapoport-Luebering glycolytic shuntThe mood stabiliser lithium suppresses PIP3 signalling in Dictyostelium and human cells.Lithium and bipolar mood disorder: the inositol-depletion hypothesis revisitedAn intersection of the cAMP/PKA and two-component signal transduction systems in DictyosteliumGlycogen synthase kinase-3 is required for efficient Dictyostelium chemotaxis.Lithium inhibits glycogen synthase kinase-3 by competition for magnesium.Genetic control of lithium sensitivity and regulation of inositol biosynthetic genes.Search for a common mechanism of mood stabilizers.Cell-cell adhesion and signal transduction during Dictyostelium development.Signal transduction in development: holding the key.Neurodevelopment and mood stabilizers.Biological interaction of living cells with COSAN-based synthetic vesiclesThe interaction of glycogen synthase kinase-3 (GSK-3) with the cell cycle.Cell polarity and Dictyostelium development.A prehistory of cell adhesion.A molecular cell biology of lithium.Modeling psychiatric disorders: from genomic findings to cellular phenotypesA systematic investigation of the protein kinases involved in NMDA receptor-dependent LTD: evidence for a role of GSK-3 but not other serine/threonine kinasesDifferent CHD chromatin remodelers are required for expression of distinct gene sets and specific stages during development of Dictyostelium discoideum.Regulation of nucleosome positioning by a CHD Type III chromatin remodeler and its relationship to developmental gene expression in DictyosteliumProlyl oligopeptidase, inositol phosphate signalling and lithium sensitivity.Glycogen synthase kinase-3 enhances nuclear export of a Dictyostelium STAT protein.Improved screening for oligonucleotide-directed mutant M13 phage.Regulation of Dictyostelium morphogenesis by cAMP-dependent protein kinase.Identification of the Axin and Frat binding region of glycogen synthase kinase-3.GSK-3 activity in neocortical cells is inhibited by lithium but not carbamazepine or valproic acid.Proteomic and microarray analyses of the Dictyostelium Zak1-GSK-3 signaling pathway reveal a role in early development.Loss of a prolyl oligopeptidase confers resistance to lithium by elevation of inositol (1,4,5) trisphosphate.Evaluation of the effects of propylisopropylacetic acid (PIA) on neuronal growth cone morphology.Signal transduction and Dictyostelium development.Methanol and acriflavine resistance in Dictyostelium are caused by loss of catalase.Glycogen synthase kinase-3 inhibition by lithium and beryllium suggests the presence of two magnesium binding sites.Receptor-dependent and tyrosine phosphatase-mediated inhibition of GSK3 regulates cell fate choice.Optimization and in situ detection of Escherichia coli beta-galactosidase gene expression in Dictyostelium discoideum.Two peptidase activities decrease in treated bipolar disorder not schizophrenic patients.Valproate decreases inositol biosynthesis.Three- and four-dimensional visualization of cell migration using optical coherence tomography.Curcumin and derivatives function through protein phosphatase 2A and presenilin orthologues in Dictyostelium discoideum.A myb-related protein required for culmination in Dictyostelium.
P50
Q24317335-BFD72512-C451-412F-A1C3-4449F101C3EBQ24321715-57AC8F98-8E88-49FE-B4AB-F15978EF143AQ24652181-556DF484-E3D5-48FE-BDCA-2450E0EA3F93Q28294604-2E3109CA-FC3E-4D40-B08C-3AD8FEE37DC7Q28769588-3F554702-3A1A-4529-9E91-CDCCADD7E5B2Q30495773-3772494F-CCF6-4AE2-BC4A-371C8D3A09CCQ31855623-5E53EE18-99C1-4853-9AB1-A2A6DFF1A2DAQ33612296-11188F0F-DAF6-4BD2-80B1-BC456C4BE288Q34208871-8DAF7BA3-CDD4-49ED-8D1E-457F395879F1Q34495332-97FEF53F-CD5A-4476-B72B-312ECFE5B0A1Q34611283-D322589F-BA27-4395-A30B-DF01B1314E16Q35207368-62F7F370-28B1-4C2F-AAAA-135070FDCF0DQ35542862-9C05D97D-A22C-4432-A8C0-42AC4465AF87Q35573746-C0481C0C-9694-4914-BB75-6CDB7043C759Q35602960-BA41B8F2-C143-4EA8-8315-4FC76D0BE2A7Q35885599-107E2B7D-AD83-4EFC-BE1F-E2C00E5BEFAAQ35922883-0851BEF5-272A-4C59-A393-587952E05AB7Q37199033-36757739-33D1-4DB2-AFFB-582B4B9720D9Q37274100-34EDB5D9-A02C-48E8-B672-723821FDA055Q37358729-E509B682-7B1F-44CF-A6F0-9D7819E384ACQ37735511-C0D760E2-0C89-4F4D-9F23-15A7CFCB72F3Q37827530-3EBC5A65-8736-472D-AF82-883D2828062EQ39749869-200F81B7-6D2A-4EF0-BB37-02DA60D18B07Q40546718-B74054F1-71B0-4DF0-9EB3-1D36DE4409F5Q40712680-E0C1E5C3-8D02-41E8-B48B-A5BE20CCA4DBQ40768816-F0CA8E48-5D12-4C3A-BB56-94F00FF086A1Q41774375-41545845-54A1-40C8-8308-A47675DFA3AEQ41883884-3F51E4A8-548B-409A-A789-430B9C11B199Q42121009-446EED58-68CD-464A-9380-E98576CCFC91Q42736674-CA8046F3-49F4-4855-A08C-731974E5E8DAQ43636230-EABB89FB-80ED-4CF7-A452-4E7F44FFC051Q43848697-6D2C68EB-1C92-4787-92EE-71809F486158Q43858813-764496C4-8EAA-4DAB-9323-6C03FFE16A36Q44199564-D33A2858-8AF6-4ED1-8A73-49D7916C6EA1Q44268021-479A1E6D-D810-4368-B065-08038309BE7AQ44789682-C8D70D03-10E2-4A83-ACD2-33401EF20869Q45171168-52972D45-052B-4B73-A580-4B89536439F6Q45224950-F5A3966A-7EE6-4136-9A92-317987F84990Q47552746-21932729-3156-4BD3-9725-0A5BBB75DA68Q47962853-F947FA54-4AB8-4DEF-BDC1-0E7680AAD355
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Adrian J Harwood
@ast
Adrian J Harwood
@en
Adrian J Harwood
@es
Adrian J Harwood
@nl
type
label
Adrian J Harwood
@ast
Adrian J Harwood
@en
Adrian J Harwood
@es
Adrian J Harwood
@nl
altLabel
Adrian J Harwood
@en
prefLabel
Adrian J Harwood
@ast
Adrian J Harwood
@en
Adrian J Harwood
@es
Adrian J Harwood
@nl
P106
P21
P31
P496
0000-0003-3124-5169