about
Lin28 mediates the terminal uridylation of let-7 precursor MicroRNAWhy Argonaute is needed to make microRNA target search fast and reliableA Dynamic Search Process Underlies MicroRNA Targeting.Cooperative conformational transitions keep RecA filament active during ATPase cycleTRBP ensures efficient Dicer processing of precursor microRNA in RNA-crowded environments.Single-molecule pull-down for investigating protein-nucleic acid interactions.Single-molecule three-color FRETSurface passivation for single-molecule protein studiesObjective-type total internal reflection microscopy (excitation) for single-molecule FRET.Analysis of single-molecule FRET trajectories using hidden Markov modeling.Real-time observation of RecA filament dynamics with single monomer resolution.Distinct mechanisms regulating mechanical force-induced Ca²⁺ signals at the plasma membrane and the ER in human MSCs.Real-time observation of strand exchange reaction with high spatiotemporal resolutionDynamic growth and shrinkage govern the pH dependence of RecA filament stability.TUT7 controls the fate of precursor microRNAs by using three different uridylation mechanisms.Fueling protein DNA interactions inside porous nanocontainers.Bringing single-molecule spectroscopy to macromolecular protein complexes.Single-molecule four-color FRET.Advances in single-molecule fluorescence methods for molecular biology.Molecular mechanism of sequence-dependent stability of RecA filament.SDS-assisted protein transport through solid-state nanopores.Autonomous Generation and Loading of DNA Guides by Bacterial Argonaute.Two distinct DNA binding modes guide dual roles of a CRISPR-Cas protein complex.RecA filament maintains structural integrity using ATP-driven internal dynamics.Water-mediated recognition of t1-adenosine anchors Argonaute2 to microRNA targets.Repetitive shuttling of a motor protein on DNA.Helix-7 in Argonaute2 shapes the microRNA seed region for rapid target recognition.Single-molecule protein sequencing through fingerprinting: computational assessment.Single-molecule peptide fingerprinting.Labeling proteins for single-molecule FRET.Repetitive DNA Reeling by the Cascade-Cas3 Complex in Nucleotide Unwinding StepsPaving the way to single-molecule protein sequencingExploring rare conformational species and ionic effects in DNA Holliday junctions using single-molecule spectroscopyObjective-type total internal reflection microscopy (emission) for single-molecule FRETPrism-type total internal reflection microscopy for single-molecule FRETSingle-molecule FRET with total internal reflection microscopyPreparing sample chambers for single-molecule FRETImaging and identifying impurities in single-molecule FRET studiesResolving Chemical Modifications to a Single Amino Acid within a Peptide Using a Biological NanoporeHigh-Speed Super-Resolution Imaging Using Protein-Assisted DNA-PAINT
P50
Q24308839-3BF75261-2CD1-4A71-BB96-53896DB6281CQ26745499-E51EF785-D076-445F-82DC-3A6899D2B9E0Q27322532-3AD66E56-94B7-428C-B9FC-8FC6770E988BQ30596267-7D85B079-4AFA-488A-8413-44C8EE4B957EQ30831870-F2DC198B-FC78-401D-8D70-43538C6B91EFQ33614068-DADCC805-5E18-4B5C-A58E-7E83C51195BEQ34186676-53DAEF96-2AC3-461A-BB97-B477C92AD483Q34264484-E32A15DD-F63A-48A5-8D83-E0CE6A922EA3Q34464242-1AFCFEA5-4E18-4ED8-8376-1A9C34F1E3A8Q34536849-8BF49900-615C-404C-816C-E35AC5471638Q34556173-E6F51961-78C8-48F9-9CD9-58ABF4AD5F94Q35111332-F8BED624-9795-4D48-AF11-18B35461ACB6Q35186210-B848F8BA-BF73-44F1-A9A0-F2EEACBF48D5Q35546654-15D73562-F365-4FA8-830C-D50F89C1ED55Q35893136-D9042E02-A6A1-4845-8598-7ED11E50076BQ35921608-83A9D7F3-B91D-4BC7-B25D-743CC4AC7B01Q36573012-1F025D31-F273-47DB-849A-FC8120FE876AQ37071039-768B2BDF-4D00-4BB7-BABB-44071CEDA60BQ37138480-7AB878E1-A6C7-4DFE-8FE0-64F582F14695Q37148523-852D3F5C-498B-4AD6-9823-8356EA5B897BQ38647051-1239CCFF-EFA1-4F3F-A27F-B149BE7FC637Q38927788-9ADF1EBC-3B9A-4B30-B988-072A81EDF06CQ41265458-66B41AD7-18E9-4417-BDF2-1C5AEA053E18Q41633525-1409840B-AF68-4D77-9C65-7CE9B7E4F066Q42592716-ADA08675-F9DC-412E-9A28-B6E05BE51A4BQ46776457-3C69A59D-AF0F-405F-9931-BFA187C8E760Q47758682-1B025BE4-C980-4638-80AA-EF1A1121C70DQ50868304-A8ADC5DC-ED6F-481E-992A-6FB78717CAB5Q52659617-B1995BE7-FA9F-44C4-A46B-33730B4DDB40Q54328833-93A86D33-48B9-426D-9556-9C282AE78D5BQ57753928-69C65415-1997-488C-85E7-842793A19796Q57938121-B9300583-4626-4522-BC45-4E2EAE93B46BQ80407128-A5A08969-5221-43BD-AA3D-4DADD858A1C8Q85336751-FACE3A87-2F6C-4DF8-B5C2-F49FBEF8B3CBQ85604557-E55FB7FD-007D-484D-972C-BAB9B00E611EQ85604561-6A782D64-8E44-4D76-9830-5714F2CA301AQ87400259-1FAF4096-36CC-4B17-8F0F-0032D0E5FA54Q87400261-CC2BF23E-7D22-48E4-96BD-42E1BC98C789Q90177771-AB4005FB-02F3-4969-A104-B4256A450F2DQ90305002-D8DA5A5D-FB35-444F-BB1E-9A49B67510D1
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Chirlmin Joo
@ast
Chirlmin Joo
@en
Chirlmin Joo
@es
Chirlmin Joo
@nl
Chirlmin Joo
@sl
type
label
Chirlmin Joo
@ast
Chirlmin Joo
@en
Chirlmin Joo
@es
Chirlmin Joo
@nl
Chirlmin Joo
@sl
altLabel
C. Joo
@nl
prefLabel
Chirlmin Joo
@ast
Chirlmin Joo
@en
Chirlmin Joo
@es
Chirlmin Joo
@nl
Chirlmin Joo
@sl
P1053
B-9294-2008
P106
P1153
8114325400
P31
P3829
P496
0000-0003-2803-0335
P7449
PRS1327021