about
Interconversion of Anthozoa GFP-like fluorescent and non-fluorescent proteins by mutagenesis[Three-dimensional structure of yellow fluorescent protein zYFP538 from Zoanthus sp. at the resolution 1.8 angstrom]Crystallographic study of red fluorescent protein eqFP578 and its far-red variant Katushka reveals opposite pH-induced isomerization of chromophoreMolecular Mechanism of a Green-Shifted, pH-Dependent Red Fluorescent Protein mKate VariantThe Structure of Ca2+ Sensor Case16 Reveals the Mechanism of Reaction to Low Ca2+ ConcentrationsSubstrate recognition of anthrax lethal factor examined by combinatorial and pre-steady-state kinetic approachesStructural basis for the fast maturation of Arthropoda green fluorescent protein.Practical and reliable FRET/FLIM pair of fluorescent proteins.Far-red fluorescent tags for protein imaging in living tissues.tcR: an R package for T cell receptor repertoire advanced data analysis.VDJviz: a versatile browser for immunogenomics data.Fast and precise protein tracking using repeated reversible photoactivation.Using photoactivatable fluorescent protein Dendra2 to track protein movement.Single fluorescent protein-based Ca2+ sensors with increased dynamic range.Spectrally-resolved response properties of the three most advanced FRET based fluorescent protein voltage probesIndividual characterization of stably expanded T cell clones in ankylosing spondylitis patients.MAGERI: Computational pipeline for molecular-barcoded targeted resequencing.HRES-1/Rab4-mediated depletion of Drp1 impairs mitochondrial homeostasis and represents a target for treatment in SLE.A high-throughput assay for quantitative measurement of PCR errors.Quantitative tracking of T cell clones after haematopoietic stem cell transplantation.Persisting fetal clonotypes influence the structure and overlap of adult human T cell receptor repertoiresFluorescent proteins as a toolkit for in vivo imaging.Astroglia are a possible cellular substrate of angiotensin(1-7) effects in the rostral ventrolateral medullaFluorescent proteins and their applications in imaging living cells and tissues.Next generation sequencing for TCR repertoire profiling: platform-specific features and correction algorithms.Tracking intracellular protein movements using photoswitchable fluorescent proteins PS-CFP2 and Dendra2.Pairing of T-cell receptor chains via emulsion PCR.High-throughput identification of antigen-specific TCRs by TCR gene capture.Preparing unbiased T-cell receptor and antibody cDNA libraries for the deep next generation sequencing profiling.Distinctive properties of identical twins' TCR repertoires revealed by high-throughput sequencing.Use of green fluorescent protein (GFP) and its homologs for in vivo protein motility studies.Near-infrared fluorescent proteins.In vivo imaging of ligand receptor binding with Gaussia luciferase complementation.VDJtools: Unifying Post-analysis of T Cell Receptor Repertoires.High-quality full-length immunoglobulin profiling with unique molecular barcoding.Comparative study reveals better far-red fluorescent protein for whole body imagingInnovation: Photoactivatable fluorescent proteins.A mechanism for expansion of regulatory T-cell repertoire and its role in self-tolerance.Genetically encoded intracellular sensors based on fluorescent proteins.Conversion of red fluorescent protein into a bright blue probe
P50
Q24792648-265D1F84-4D5C-4278-9D47-4AA30B2491C9Q27648402-015A51D3-C037-468A-A59B-98BDD38779C6Q27667803-EEAC3838-0121-4111-B72F-84721BC25FA9Q27672852-59366536-322E-4CAE-A5F1-AAB479AD8640Q27676152-0BCB79A8-1044-44A8-A4D7-AE7251208EB5Q28389793-4A33AEA0-0C4E-426F-A5F8-498827A325D0Q30159663-35C84B0A-2036-4FC6-908E-EFF3A993A328Q30487440-A127B36E-B463-44B1-A007-EB4AD2B4DA18Q30495187-66D54157-1B7B-4D96-94B8-9D789C3AC331Q30959837-8F2B7115-8B44-4D96-9D87-CD60AEF02873Q31107890-D32867F3-F8C6-43EA-B9AB-660B818DE4A9Q33252912-738E7085-38B7-4E5F-9FF4-4D47C7682BD8Q33285232-F8E4037F-9A7E-4FE4-B97E-3EDC4765A7FCQ33289524-B4215EDE-ACFC-4669-9DFB-DFD7DCD6C1F8Q33411301-FD5CCA28-9728-4708-BB75-7CD47BC1A7DAQ33491043-BEB29872-744C-4511-A525-88B3761D5012Q33642719-9484439C-540D-4A24-86D3-5B16AFCC30C3Q33717763-FF736065-1CDB-4B58-A191-49BF2FD38996Q33758777-4B7FC2B8-5357-40ED-B5A5-F25F2583A24AQ33837175-01140144-E62B-4FB9-800F-811083C90D25Q33879504-F881424F-4F7F-49A7-8460-3FB15F7B549CQ33991259-B429A459-7EA2-4C63-B504-C94B6E08E010Q33997630-2236E5E7-FE5F-4451-A3F0-3A946AEE6AB9Q34128238-19585F2E-FE16-4890-8388-CE050A3F655CQ34340835-A4FB0996-3E2A-4B5F-BD0E-C98E395097D6Q34664023-6234D632-249C-47ED-A8F0-6C6083D7000AQ34733296-4AC7F03D-93E0-408A-B2A7-0D69BD763C9BQ35016476-37291DF5-C1CF-423A-96E2-E020CF1FB8A8Q35082275-3A165DF4-9529-47D1-A293-2D6530DDBA96Q35142267-4054E9CC-FDF6-44F5-94B6-30F9114A312EQ35579426-B072C584-11F2-4F69-B74B-1B7DDE9B15D0Q35586262-6ACB69CD-B624-429C-AA4E-0A02A4234DB7Q35661160-A44C1E02-39CB-4D71-8019-CD943160505CQ35852353-6525CB3F-AD40-4448-BFB2-73998DC0916BQ36094995-92743608-1DDF-469E-A616-A8EFA1BEDA29Q36156049-37AC48BA-2638-4558-8DC8-F8E313D5A619Q36259091-2B4D3494-95A8-4CDD-BCE7-DA2840432DA8Q36888933-2C977EF1-32FD-416A-9BED-5C1278A2D8B5Q36903010-69678700-53F9-4398-9EC1-199484E1B940Q36977925-DC5BB5BD-9F37-4E46-8A0C-64215843C067
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Dmitri Michailowitsch Tschudakow
@de
Dmitriy Chudakov
@en
Dmitriy Chudakov
@nl
Dmitriy M. Chudakov
@ast
Dmitriy M. Chudakov
@es
Dmitriy M. Chudakov
@sl
Дмитрий Михайлович Чудаков
@ru
type
label
Dmitri Michailowitsch Tschudakow
@de
Dmitriy Chudakov
@en
Dmitriy Chudakov
@nl
Dmitriy M. Chudakov
@ast
Dmitriy M. Chudakov
@es
Dmitriy M. Chudakov
@sl
Дмитрий Михайлович Чудаков
@ru
altLabel
Dmitri Tschudakow
@de
Dmitriy M. Chudakov
@en
Dmitry Chudakov
@en
Dmitry Mikhaylovich Chudakov
@en
prefLabel
Dmitri Michailowitsch Tschudakow
@de
Dmitriy Chudakov
@en
Dmitriy Chudakov
@nl
Dmitriy M. Chudakov
@ast
Dmitriy M. Chudakov
@es
Dmitriy M. Chudakov
@sl
Дмитрий Михайлович Чудаков
@ru
P1053
G-7741-2014
P106
P21
P31
P3829
P496
0000-0003-0430-790X