about
THAP proteins target specific DNA sites through bipartite recognition of adjacent major and minor groovesUSP30 and parkin homeostatically regulate atypical ubiquitin chains on mitochondriaIdentification of a DNA primase template tracking site redefines the geometry of primer synthesisStructure, Stability, and Folding of Ribonuclease H1 from the Moderately Thermophilic Chlorobium tepidum : Comparison with Thermophilic and Mesophilic HomologuesA De Novo Protein Binding Pair By Computational Design and Directed EvolutionBinding Mechanism of Metal⋅NTP Substrates and Stringent-Response Alarmones to Bacterial DnaG-Type PrimasesRosettaScripts: a scripting language interface to the Rosetta macromolecular modeling suiteROSETTA3: an object-oriented software suite for the simulation and design of macromoleculesFASTDXL: a generalized screen to trap disulfide-stabilized complexes for use in structural studiesDisabling Cas9 by an anti-CRISPR DNA mimicBioactive TGF-beta can associate with lipoproteins and is enriched in those containing apolipoprotein E3.Hotspot-centric de novo design of protein binders.Automated electron-density sampling reveals widespread conformational polymorphism in proteinsConformational stabilization of ubiquitin yields potent and selective inhibitors of USP7.The RosettaCon 2012 Special Collection: Code Writ on Water, Documentation Writ in Stone.Compact and highly active next-generation libraries for CRISPR-mediated gene repression and activation.Using protein motion to read, write, and erase ubiquitin signals.Ubiquitin in inflammation: the right linkage makes all the difference.Enhancing homology-directed genome editing by catalytically active and inactive CRISPR-Cas9 using asymmetric donor DNA.CRISPR germline engineering--the community speaks.Synthetically modified guide RNA and donor DNA are a versatile platform for CRISPR-Cas9 engineeringRosetta in CAPRI rounds 13-19.Enhancer connectome in primary human cells identifies target genes of disease-associated DNA elements.Crosstalk between primase subunits can act to regulate primer synthesis in trans.Co-opting CRISPR to deliver functional RNAs.BARD1 is necessary for ubiquitylation of nucleosomal histone H2A and for transcriptional regulation of estrogen metabolism genes.Decoding a chain letter for degradation.Atlastins remodel the endoplasmic reticulum for selective autophagyCRISPR–Cas9 genome editing in human cells occurs via the Fanconi anemia pathwayIn vitro-transcribed guide RNAs trigger an innate immune response via the RIG-I pathwaySometimes you're the scooper, and sometimes you get scooped: How to turn both into something goodNanoparticle delivery of Cas9 ribonucleoprotein and donor DNA induces homology-directed DNA repairDisabling Cas9 by an anti-CRISPR DNA mimicFlexibility and design: conformational heterogeneity along the evolutionary trajectory of a redesigned ubiquitinThe CUL5 ubiquitin ligase complex mediates resistance to CDK9 and MCL1 inhibitors in lung cancer cellsUnbiased detection of CRISPR off-targets in vivo using DISCOVER-SeqThe CUL5 ubiquitin ligase complex mediates resistance to CDK9 and MCL1 inhibitors in lung cancer cellsA Genome-wide ER-phagy Screen Highlights Key Roles of Mitochondrial Metabolism and ER-Resident UFMylationAdvances in genome editing through control of DNA repair pathwaysCRISPR off-target detection with DISCOVER-seq
P50
Q22001535-5936B3C8-71E0-4AB0-8395-85B27AD69287Q24316174-C890A698-D75D-476E-A04B-CAABBA86AB1BQ27649534-D9902675-E222-4FAD-9220-614522155269Q27655350-F3BACA98-DC82-46DC-A0B2-3D9D7638839DQ27667402-CDF654D0-66A1-4F88-8A26-AE6DD8BDCA45Q27670729-1D8B44C1-7C0A-4873-B53E-C6D3EC73C686Q28743250-78183D25-D171-4BE6-BD75-4324507282F3Q28914720-36550075-62E1-4C47-86E9-712E5991CA57Q33291097-E81C02A6-F9D9-4FB8-B944-32B46E7D8ED5Q33898855-6F7C5877-3040-405A-B48F-DE228D9F3CF6Q34043609-64E3B513-E073-4FA5-BC26-AD2F01F04F08Q34087555-1A750131-020F-4D31-A776-7D664C3D9D69Q34283536-1492806A-F795-4783-ABB0-E4463F3C0A8BQ34487783-F55D3F89-42AE-4EA0-8FB7-2FBC7D8913ACQ35004812-A8D21B03-D3E9-4200-BF70-26A98271A0DBQ36142402-B74A7B6A-D43F-4E82-A919-B38785869C6CQ36283663-33F9A336-9302-4FCA-9F68-5953989C1FB1Q38201969-B52BA8A9-EFB3-4C06-8058-7BDA098A63A4Q38801430-3A7E8D60-E0C1-4A1E-A1FA-8E8E57A5224FQ41238392-FA855E91-0D29-4875-A032-C24B0250D18FQ42289899-60E04570-F710-422F-AE46-3470DDB61CFCQ42411390-4A1728EC-8E16-4B52-9961-95054ABE6620Q42692866-A2E7A021-2488-4953-A584-2CE4C9149B83Q45959299-767322C9-3764-4CDD-8F6D-6A5799F026AAQ46748529-F372316E-5EB0-44C7-8820-17BE90B1154FQ48172154-7BF3B9E3-836D-4605-A315-9122B1698FEBQ50860994-1551BE2B-A7EF-4881-8D1B-0D5CA35D91C8Q58054236-27A36CF7-1082-4601-AF93-D8438532633EQ58054240-BAD31203-9EC6-467E-8C36-18303836DC9BQ58054245-CF522AED-B7C5-41A0-B9F4-1D2609B0738FQ58054249-6EB614D5-E36D-4D5D-8F3C-D50325CF4817Q58054257-C6AA765B-4662-4530-A3CB-842DDD51E2BBQ58054275-3F1322B7-4A90-4A60-A8AB-7134970A9F3FQ58054281-DAD5C9B7-1891-4A7C-8776-D1C870F1D45CQ61227757-285423FC-6B0C-4613-8A52-E88F63E6404AQ64374718-F78A5EFE-BEBF-47F3-ACB2-B1D2926BE9CCQ83230171-7721E911-69E9-4ECA-902A-8A1DAB5FF340Q90239300-9EAF9361-60D7-4BAC-AB3F-9A01C23C4BB3Q91620907-320A9E89-3379-4496-B014-F2D7B25A1548Q92095869-1FB9A444-BA82-4DD9-9186-540901E2B01A
P50
description
hulumtues
@sq
researcher
@en
ricercatore
@it
wetenschapper
@nl
հետազոտող
@hy
name
Jacob Corn
@fr
Jacob E Corn
@en
Jacob E Corn
@es
Jacob E Corn
@nl
Jacob E Corn
@sl
type
label
Jacob Corn
@fr
Jacob E Corn
@en
Jacob E Corn
@es
Jacob E Corn
@nl
Jacob E Corn
@sl
prefLabel
Jacob Corn
@fr
Jacob E Corn
@en
Jacob E Corn
@es
Jacob E Corn
@nl
Jacob E Corn
@sl
P106
P21
P214
3039157162098278980002
P31
P496
0000-0002-7798-5309
P735
P7859
viaf-3039157162098278980002