about
Global landscape of HIV-human protein complexesPolycomb PHF19 binds H3K36me3 and recruits PRC2 and demethylase NO66 to embryonic stem cell genes during differentiationFunctional organization of the S. cerevisiae phosphorylation networkIn silico proteome analysis to facilitate proteomics experiments using mass spectrometryA comprehensive analysis of protein-protein interactions in Saccharomyces cerevisiaeNavigating the chaperone network: an integrative map of physical and genetic interactions mediated by the hsp90 chaperone.RNA polymerase II elongation factors of Saccharomyces cerevisiae: a targeted proteomics approachHierarchical modularity and the evolution of genetic interactomes across species.A genetic interaction map of RNA-processing factors reveals links between Sem1/Dss1-containing complexes and mRNA export and splicingCtf3p, the Mis6 budding yeast homolog, interacts with Mcm22p and Mcm16p at the yeast outer kinetochore.Requirement of Skp1-Bub1 interaction for kinetochore-mediated activation of the spindle checkpoint.Chl4p and iml3p are two new members of the budding yeast outer kinetochore.A panoramic view of yeast noncoding RNA processing.High-definition macromolecular composition of yeast RNA-processing complexes.Global landscape of protein complexes in the yeast Saccharomyces cerevisiae.The variant Polycomb Repressor Complex 1 component PCGF1 interacts with a pluripotency sub-network that includes DPPA4, a regulator of embryogenesisModeration of the platelet releasate response by aspirinHuman Proteinpedia enables sharing of human protein dataPolycomb-like 3 promotes polycomb repressive complex 2 binding to CpG islands and embryonic stem cell self-renewalPolycomb-like 2 associates with PRC2 and regulates transcriptional networks during mouse embryonic stem cell self-renewal and differentiationLarge-scale functional analysis using peptide or protein arrays.Characterization of the proteins released from activated platelets leads to localization of novel platelet proteins in human atherosclerotic lesions.Human tissue profiling with multidimensional protein identification technology.msmsEval: tandem mass spectral quality assignment for high-throughput proteomics.Proteomic analysis of membrane microdomain-associated proteins in the dorsolateral prefrontal cortex in schizophrenia and bipolar disorder reveals alterations in LAMP, STXBP1 and BASP1 protein expression.High-throughput screening for protein-protein interactions using yeast two-hybrid arrays.Sequential interval motif search: unrestricted database surveys of global MS/MS data sets for detection of putative post-translational modifications.Host cell factors in HIV replication: meta-analysis of genome-wide studies.Missing value imputation for epistatic MAPs.Proteomics strategy for identifying candidate bioactive proteins in complex mixtures: application to the platelet releasate.Improved functional overview of protein complexes using inferred epistatic relationships.Identification of β2-microglobulin as a urinary biomarker for chronic allograft nephropathy using proteomic methods.Distinct configurations of protein complexes and biochemical pathways revealed by epistatic interaction network motifs.All or nothing: protein complexes flip essentiality between distantly related eukaryotes.Understanding the physiological roles of polyhydroxybutyrate (PHB) in Rhodospirillum rubrum S1 under aerobic chemoheterotrophic conditions.A skeleton of the human protein interactome.Application of proteomics to the study of platelet regulatory mechanisms.Dataset of mouse hippocampus profiled by LC-MS/MS for label-free quantitation.Quantitative genetic-interaction mapping in mammalian cells.Dysregulation of miRNA-9 in a Subset of Schizophrenia Patient-Derived Neural Progenitor Cells
P50
Q24300336-EDA314AB-F6F8-4848-9B4B-8905384E839DQ24304060-CC0714ED-0F9B-4040-9051-239A719C2A50Q24634340-35A1D59C-76EF-4039-A1C1-13D5C3315A00Q24798041-FE56A1DA-1925-481B-A941-8A9E71766CD2Q27860755-F1DC35FB-114E-45C8-ADC2-85D40DF89552Q27930871-28A8ED6F-E78D-43FE-BCC1-84C2FB34BB22Q27931237-F091580F-181B-42C5-AAF9-2D4360A9CAF6Q27932016-9CBABDFF-8F39-4DB2-8AB5-254CE51206E6Q27932638-A7BA7B34-6DD7-4439-93E7-BC6CC809EDE2Q27933723-2AB1D5A0-6F1A-4534-A368-6BD1D192EAC4Q27935461-4D79ADBB-A0A4-42C4-8EFF-5672118B5B4FQ27937271-695DA7BF-127B-46BA-B842-24BE51D2BCEBQ27937560-85025DF0-6963-4C38-88EE-BF9DDC81A404Q27937860-6ECDD52A-459F-4558-9B25-64DEEBC258C3Q27938796-ADC09D02-B341-4414-AB6C-FAE1D6125811Q28119042-9B05A36C-7DAD-4CD5-B84F-4742748420C9Q28219081-385CE4CB-1A01-4CDB-8550-7B5A6980CA21Q28267923-1AAE2EA6-D0B6-4C2C-BD1D-F97C78A2C500Q28587391-EACFCC1E-6B75-464F-8380-644730704FBFQ28591889-305DCBF1-40DE-4C18-8445-1B100188B395Q30854444-04DAC3BB-7F94-4A6E-9CD8-211B7FF00C9DQ33195220-1942D03D-38E2-4A60-93C0-686FCF6FF588Q33224834-8B77AB59-92BD-4138-B2C1-33D7BAFE3498Q33273061-3FA3DC70-69FF-42D2-995A-2CCDF5E5CAEFQ33319373-2034628D-0FF9-479F-B62B-CED01FAB0DB0Q33330026-12C54189-E85C-4811-AF26-663365CB27C6Q33369180-2CA97564-6DB8-48F4-80D8-D4EEF4FFDE23Q33455551-D9665B70-3E38-49A4-ADA2-270ABCCAC14DQ33560449-51A08D8A-E4AB-4C23-BA04-6EDE2C3DA187Q33756598-707B2AC4-AF4D-4231-BFC4-882FEB2FB90EQ33909267-6E9E22D0-BB97-4C03-A74E-CA779B15DB90Q33959646-8B6A6D1C-630F-4E10-A062-09BBD9C5BE81Q34000485-9CEAD11F-49BD-482B-A5CC-CA36C738337CQ34036638-8249025A-0685-4291-BA89-0180BCDA795EQ34047244-68788E2E-D524-4FFB-9F66-6F5130CC15E5Q34561086-F800163C-17EB-445C-B92B-E0C387CC294DQ35903274-EC0CAE07-BE25-4AB4-A0D3-33C6707C453EQ36661198-A635CE8C-68AC-4A49-BB2E-6EAE9972E691Q36811345-3A03FEA9-7C2E-4E85-85F5-B582530D0419Q36869455-21521AA1-CEE5-4A1B-9484-88C7C46FD666
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Gerard Cagney
@ast
Gerard Cagney
@en
Gerard Cagney
@es
Gerard Cagney
@nl
Gerard Cagney
@sl
type
label
Gerard Cagney
@ast
Gerard Cagney
@en
Gerard Cagney
@es
Gerard Cagney
@nl
Gerard Cagney
@sl
prefLabel
Gerard Cagney
@ast
Gerard Cagney
@en
Gerard Cagney
@es
Gerard Cagney
@nl
Gerard Cagney
@sl
P106
P21
P2456
P31
P496
0000-0001-7189-9496