about
Direct visualization of the microtubule lattice seam both in vitro and in vivo3D structure of eukaryotic flagella/cilia by cryo-electron tomographyα- and β-Tubulin Lattice of the Axonemal Microtubule Doublet and Binding Proteins Revealed by Single Particle Cryo-Electron Microscopy and TomographyStructural and enzymatic properties of the AAA protein Drg1p from Saccharomyces cerevisiae. Decoupling of intracellular function from ATPase activity and hexamerization.Cartwheel architecture of Trichonympha basal bodyCryo-electron tomography of motile cilia and flagellaMolecular architecture of inner dynein arms in situ in Chlamydomonas reinhardtii flagella.Asymmetry of inner dynein arms and inter-doublet links in Chlamydomonas flagellaVesicles as soft templates for the enzymatic polymerization of aniline.Magnetic field alignable domains in phospholipid vesicle membranes containing lanthanides.Nucleotide-induced global conformational changes of flagellar dynein arms revealed by in situ analysis.Comparative structural analysis of eukaryotic flagella and cilia from Chlamydomonas, Tetrahymena, and sea urchins.Functionalized low-density lipoprotein nanoparticles for in vivo enhancement of atherosclerosis on magnetic resonance images.3D structural analysis of flagella/cilia by cryo-electron tomography.Translocation pathway of protein substrates in ClpAP protease.Cryoelectron tomography of radial spokes in cilia and flagella.Axonemal radial spokes: 3D structure, function and assembly.Polarity and asymmetry in the arrangement of dynein and related structures in the Chlamydomonas axonemeRevisiting the supramolecular organization of photosystem II in Chlamydomonas reinhardtii.Structural biology of cytoplasmic and axonemal dyneins.Axoneme Structure from Motile Cilia.Three-dimensional mass density mapping of cellular ultrastructure by ptychographic X-ray nanotomography.A simple and fast approach for missing-wedge invariant classification of subtomograms extracted from filamentous structures.General and specific promotions of flagellar assembly by a flagellar nucleoside diphosphate kinase.Cholesterol-diethylenetriaminepentaacetate complexed with thulium ions integrated into bicelles to increase their magnetic alignability.Cholesterol increases the magnetic aligning of bicellar disks from an aqueous mixture of DMPC and DMPE-DTPA with complexed thulium ions.Cholesterol attenuates and prevents bilayer damage and breakdown in lipoperoxidized model membranes. A spin labeling EPR study.Novel type of bicellar disks from a mixture of DMPC and DMPE-DTPA with complexed lanthanides.pH-sensitive vesicles containing a lipidic beta-amino acid with two hydrophobic chains.Structure of the E. coli signal recognition particle bound to a translating ribosome.Vesicles from docosahexaenoic acid.The two actin-binding regions on the myosin heads of cardiac muscle.Proposal of alignment-independent classification of electron microscopic images with helical symmetry and its application to reconstituted thin filaments os skeletal muscle.Calcium induced change in three-dimensional structure of thin filaments of rabbit skeletal muscle as revealed by cryo-electron microscopy.Molecular details of Bax activation, oligomerization, and membrane insertion.Visualization of substrate binding and translocation by the ATP-dependent protease, ClpXP.Methods for Generating Highly Magnetically Responsive Lanthanide-Chelating Phospholipid Polymolecular Assemblies.Temperature-sensitive nonionic vesicles prepared from Span 80 (sorbitan monooleate).Molecular engineering of lanthanide ion chelating phospholipids generating assemblies with a switched magnetic susceptibility.Vesicle Origami: Cuboid Phospholipid Vesicles Formed by Template-Free Self-Assembly.
P50
Q24673052-03700E27-EDD8-4950-8849-4C2B84728225Q27015053-09C650E5-E4D1-421C-8400-F5C6D26DCCA1Q27701651-D6AE86B6-104B-41DF-BCD9-0B57BC3DC42BQ27932034-FCA8B541-5EEB-4437-AB0B-9D7DE8C9474EQ28271184-FFCB4C61-9CE0-40BA-9C79-EBBCFB25C37BQ30619433-7C7FD04E-9875-4D32-977D-156AAD300760Q33386682-698B3976-2DB9-4BA3-8B2B-6A60089A00D2Q33492150-E815513F-7DCC-4C2E-93B0-A3F862BD707EQ33492538-B66D77EC-0B2D-41E4-AAD6-25DB25BBD870Q33519134-1B07E118-2272-4E41-B472-76C5829F3222Q33572779-1BA42758-EC81-48CE-9392-0D5F61A3D88AQ34190606-606153B2-58E3-4F9F-8CE2-ED3210D501CAQ34449601-0D882FA8-B273-4D6B-9BF6-263C16D1F1CCQ34623994-789769F7-01EE-4B41-9CC5-FAAF2CEC4124Q35243928-8EC64B4F-E379-4E4C-9231-DF26FFD90A9DQ35670638-37D62D28-446F-46FD-8260-D13AA035E943Q36060051-64D28EC1-3625-4E70-AD68-FD2910B2AB3AQ36205308-244DD8B3-924C-4B04-838C-4709E23D30ACQ36225843-429ACF5E-70A5-479C-88EC-53FCCE446885Q38016045-D2A09A6A-8ECD-44C8-829E-B5E86016E4F3Q38948108-7B25EE64-9734-4E43-8AA3-926B8F803978Q38953111-C2A1C605-5B19-4BC0-BC0E-6D71E41DE525Q39493930-C570F876-8F87-418A-9B2A-3DEB9D4864FDQ41596548-078E2803-6F9B-4AFE-A7D8-8B8213E6BF08Q41609896-B6F93BCC-2961-421E-9A11-9D0B7E5FB5B0Q41613155-7B36E3B9-EB0D-4774-BAE5-45010F208625Q41615694-009C1D83-86AB-41C4-9F6B-EEA74C2336E6Q41619050-2CE89560-6AD1-4854-A9FF-B5AE47299980Q41623421-FA376686-F619-41CE-B419-FC60971FCCD8Q41625398-40704ED6-94BF-4746-88A0-65399C0174F3Q41625943-0A76366C-64C4-4596-8238-49074E1479C3Q41630258-CD224E2E-BEAD-45EF-B397-81CB4B889582Q41634516-B93E3D15-EB95-4A1E-B424-040B04991DE1Q41634699-A4705B48-D85C-43C2-9C21-294C6A903AFAQ42910802-656C1D71-4AF1-459D-91D1-F10F4076FC18Q43542803-E0A3EC6C-8D1E-4849-AD3B-B1A19F04F273Q46354237-87293800-E743-43D8-9CC8-3B41B307AE3DQ46415917-EEFCA69E-5A8D-4E39-9FD5-23988F79B27FQ47878429-2B28353D-7BAF-46C1-BC9D-9E908F32FCA6Q48230354-78788F83-9D8A-4D21-BC2D-C3E502AF48B6
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Takashi Ishikawa
@ast
Takashi Ishikawa
@en
Takashi Ishikawa
@es
Takashi Ishikawa
@nl
type
label
Takashi Ishikawa
@ast
Takashi Ishikawa
@en
Takashi Ishikawa
@es
Takashi Ishikawa
@nl
prefLabel
Takashi Ishikawa
@ast
Takashi Ishikawa
@en
Takashi Ishikawa
@es
Takashi Ishikawa
@nl
P106
P108
P31
P496
0000-0002-1976-7477