about
Neutron and X-ray Crystal Structures of a Perdeuterated Enzyme Inhibitor Complex Reveal the Catalytic Proton Network of the Toho-1 -Lactamase for the Acylation ReactionAtomic structures of the human immunophilin FKBP-12 complexes with FK506 and rapamycinAtomic structure of FKBP-FK506, an immunophilin-immunosuppressant complexInhibition of proteasome activities and subunit-specific amino-terminal threonine modification by lactacystinA photoregulated ligand for the nuclear import receptor karyopherin alpha.The in vivo structure of biological membranes and evidence for lipid domains.Flagellin peptide flg22 gains access to long-distance trafficking in Arabidopsis via its receptor, FLS2.Chemically induced dimerization of dihydrofolate reductase by a homobifunctional dimer of methotrexate.Model-based approaches for the determination of lipid bilayer structure from small-angle neutron and X-ray scattering data.2-Aminoethyl methylphosphonate, a potent and rapidly acting antagonist of GABA(A)-ρ1 receptors.Carbon Nanofiber Arrays: A Novel Tool for Microdelivery of Biomolecules to Plants.In vivo electroretinographic studies of the role of GABAC receptors in retinal signal processing.Subnanometer Structure of an Asymmetric Model Membrane: Interleaflet Coupling Influences Domain Properties.Treatment of gallbladder disease during operations Iraqi Freedom and Enduring Freedom.Neutron crystallographic studies of T4 lysozyme at cryogenic temperature.Lipid bilayer thickness determines cholesterol's location in model membranes.An in vivo imaging-based assay for detecting protein interactions over a wide range of binding affinities.Neurotransmitter analog tethered to a silicon platform for neuro-BioMEMS applications.Hybrid and nonhybrid lipids exert common effects on membrane raft size and morphology.Bacillus subtilis Lipid Extract, A Branched-Chain Fatty Acid Model Membrane.A rapamycin-selective 25-kDa immunophilin.Phosphonic acid analogs of GABA through reductive dealkylation of phosphonic diesters with lithium trialkylborohydrides.Modular microfluidics for point-of-care protein purifications.Asymmetric synthesis and translational competence of L-alpha-(1-cyclobutenyl)glycine.LaPO4 nanoparticles doped with actinium-225 that partially sequester daughter radionuclides.Radical coupling reactions in lignin synthesis: a density functional theory study.Pet food safety: a shared concern.Deoxygenation of Unhindered Alcohols via Reductive Dealkylation of Derived Phosphate Esters.Abc amino acids: design, synthesis, and properties of new photoelastic amino acids.Crystallization and preliminary X-ray diffraction analysis of importin-alpha complexed with NLS peptidomimetics.Inhibition of FKBP rotamase activity by immunosuppressant FK506: twisted amide surrogate.Mechanical Properties of Nanoscopic Lipid DomainsA short total synthesis of (+)-furanomycinA simple, solid-phase binding assay for the nuclear import receptor karyopherin alpha. Part 1: direct bindingA simple, solid-phase binding assay for the nuclear import receptor karyopherin alpha. Part 2: competitive bindingChemical factors that control lignin polymerization
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Q27675553-A065DD0A-602C-4C47-88B2-00CCEEEBD6C2Q27860688-60AF47FD-62FD-4252-9A1E-DC4F9F8DE8B4Q28273179-DB52C7DD-77A2-43A2-92BE-DD71FA97A579Q28300614-2CCECA43-ADC1-4FC3-9A9A-5F680564E3A0Q30763714-4E24E7E2-4564-4B5B-BB5E-C40D176B72EEQ33718955-F73D9417-2042-4ED5-9D7C-FB3D93CE39F6Q33727335-F1DDEF86-9817-4C06-8E74-B5C9C1D68452Q33901080-4AA6A0AA-3EAE-4435-92F2-0007D7895B6EQ34269919-C2A7FCA1-C3DE-4323-811A-72E39D900218Q35586079-B9E7F83F-1D76-4B76-8B8D-3153AA428499Q36000590-0BB2C4DF-73FB-4B03-834C-98C7EAD41EEFQ36068971-36F55AF5-8892-4D7E-8D71-D93172D05019Q37010684-B4914314-F3FA-454E-94B8-4025C99412CAQ37544365-BDD78BE4-88B1-4772-A281-9CF84523B339Q38679588-5AB4EB96-5D1A-4AF0-9386-A39B9C5A22F6Q39228184-0FF6983C-1BD9-43ED-B343-E816EC76385AQ44134875-6B64D8C7-7F20-461F-8C93-96D7AD0E6527Q45047722-18BD64C7-F242-4CF2-B2B4-41892B84E86DQ45337596-3EA341AE-4BA9-4630-BD27-AAE990AE28D0Q47927918-674D97AC-38FD-4F03-B545-E2A616C97CFDQ48182268-9E5F22FE-A351-46B1-84CA-07C2F5D18A34Q48794109-4D511E58-4BA5-4CD3-A523-5151BB92532EQ50438422-DB372D83-A345-42EA-8560-6D517AD9A428Q50790396-7D87676A-02FC-4F16-9D65-CC7702F89398Q53236083-C1422CA7-0C0B-4187-BE83-408F5E220549Q53381682-3694A132-1B83-4168-B70C-574AAE95E818Q53401196-3B5EEA45-A378-4431-9E2C-F97EDAD366B6Q53563483-5E023E19-BE05-42BD-A03F-2D5F7BEC9839Q53587394-D3B1877E-7BA0-4EBE-AF9E-CC105298420FQ53622353-2C103937-AFEE-4958-A1EA-2FC31DDE124FQ54435559-B98BB389-9FFA-4DA0-A9CF-89D31EA5F77FQ59264315-4637F8DC-C744-4417-ABC1-108CB47342DCQ73799964-34231B1C-B4CC-4427-8FE3-0719A59C0517Q73895565-66962867-487E-41D0-AC0E-7A2C61235EADQ73895568-AC90E808-0CD7-4C3A-9837-96D5ED1D98A7Q86955903-33C3AADE-436B-4FFA-BE90-C1374E7D07CE
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description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Robert F Standaert
@fr
Robert F. Standaert
@en
Robert F. Standaert
@es
Robert F. Standaert
@nl
Robert F. Standaert
@sl
type
label
Robert F Standaert
@fr
Robert F. Standaert
@en
Robert F. Standaert
@es
Robert F. Standaert
@nl
Robert F. Standaert
@sl
prefLabel
Robert F Standaert
@fr
Robert F. Standaert
@en
Robert F. Standaert
@es
Robert F. Standaert
@nl
Robert F. Standaert
@sl
P1053
D-9467-2013
P106
P1153
55883876100
P21
P31
P3829
P496
0000-0002-5684-1322