about
Extensive divergence of transcription factor binding in Drosophila embryos with highly conserved gene expressionZelda binding in the early Drosophila melanogaster embryo marks regions subsequently activated at the maternal-to-zygotic transitionAb initio prediction of transcription factor targets using structural knowledge.Single-nucleosome mapping of histone modifications in S. cerevisiaeQuantitative models of the mechanisms that control genome-wide patterns of transcription factor binding during early Drosophila developmentNucleosome positioning from tiling microarray data.A novel Bayesian DNA motif comparison method for clustering and retrievalCell cycle- and chaperone-mediated regulation of H3K56ac incorporation in yeast.Ab initio construction of a eukaryotic transcriptome by massively parallel mRNA sequencing.Roles for H2A.Z and its acetylation in GAL1 transcription and gene induction, but not GAL1-transcriptional memory.TAF7L modulates brown adipose tissue formation.High throughput determination of TGFβ1/SMAD3 targets in A549 lung epithelial cellsGenome-wide analysis of androgen receptor targets reveals COUP-TF1 as a novel player in human prostate cancer.Establishment of regions of genomic activity during the Drosophila maternal to zygotic transitionLarge-scale discovery of enhancers from human heart tissue.Zelda is differentially required for chromatin accessibility, transcription factor binding, and gene expression in the early Drosophila embryo.Dual functions of TAF7L in adipocyte differentiation.A high-resolution enhancer atlas of the developing telencephalon.Taf7l cooperates with Trf2 to regulate spermiogenesis.Contribution of epigenetic mechanisms to variation in cancer risk among tissues.Hierarchical role for transcription factors and chromatin structure in genome organization along adipogenesis.Stable Binding of the Conserved Transcription Factor Grainy Head to its Target Genes Throughout Drosophila melanogaster Development.Genome-wide search for Zelda-like chromatin signatures identifies GAF as a pioneer factor in early fly development.Comparative analysis of T4 DNA ligases and DNA polymerases used in chromosome conformation capture assays.Structure and function of a transcriptional network activated by the MAPK Hog1.Evaluation of PSI-BLAST alignment accuracy in comparison to structural alignments.Post-transcriptional 3´-UTR cleavage of mRNA transcripts generates thousands of stable uncapped autonomous RNA fragments.Promoter-enhancer interactions identified from Hi-C data using probabilistic models and hierarchical topological domains.A hyperdynamic H3.3 nucleosome marks promoter regions in pluripotent embryonic stem cells.CIS: compound importance sampling method for protein-DNA binding site p-value estimation.Dynamics of Replication-Independent Histone Turnover in Budding YeastComprehensive human cell-type methylation atlas reveals origins of circulating cell-free DNA in health and diseaseGene expression: Running to stand stillTriangular correlation (TrC) between cancer aggressiveness, cell uptake capability, and cell deformabilityDisease-associated astrocytes in Alzheimer's disease and aging
P50
Q21090201-D46FBD87-BDCC-4B35-B593-3C55F7536E94Q21563380-5E249E11-1518-400D-8741-9102CB780653Q24811418-08C4708C-0B77-4039-9A28-A4D7A8B98020Q24816848-C2EF358C-498D-47C9-8954-BE95DC7D5820Q28477071-DD5848AF-9226-45EA-8106-30A8FD51A020Q31160816-3A037773-B31B-4EA8-A621-AFE9B893014FQ33332464-B1020227-15EE-4A94-98D8-25E52D388DABQ33386002-DB19C9D5-3C42-4C8F-9B6C-01ACACCF7346Q33408115-52968AE3-42ED-447A-95CA-C8D56B409A32Q33617819-0962BFAA-FE81-4714-8497-22AFD3D4780BQ33791373-7155ACAB-8CA0-42EE-AC57-1593703301B5Q33916249-9FF86E7F-9040-4545-B96E-7926A95CBEF3Q34441487-82086D3D-B094-4CB8-B73B-4B03CF72F7F9Q35173164-EF34527D-FA44-4C3A-8902-665EF03CD3DFQ35635739-6AFB6D40-E195-4098-A7F5-5546E69E2FE8Q36199585-3301D874-2A4B-4157-A023-8659E45368D8Q36515904-AB43D8C2-C545-44A8-A6EC-2097C13B09C4Q36862710-FD399EE0-523A-4EB8-ADA4-17427891B7F7Q37240666-0C79D297-2FFF-42FD-906E-9CFFF2983F34Q37682358-70581D2A-03F7-49C0-AC83-3A62F03F85C2Q38653999-06E37C65-B4A5-42BE-9F05-A5B97EF81175Q39070457-C44ABE4A-6AD4-4611-B354-34C5DC832CC1Q40967119-8B9F65BF-1813-4394-BC0F-9487DD5644EBQ41090798-9B5A17BD-DD83-4E59-94CF-6D6DE5F87955Q41884350-2FCB0A69-681D-41A6-910D-7B147687317CQ42847394-717728FD-331F-44A0-AD06-42CC5961C375Q47103559-931E901E-0521-41CA-A7BA-9242B47E6AF6Q47158127-6905BC59-CEBD-4C58-8094-6785D95AA9ADQ47440347-4870E8A3-A28E-43CF-AE1E-AFA8E61F88AEQ48521133-366E9B43-A64E-4027-8AFE-CFDE0178BB28Q57233862-78773DBF-D2EF-4534-97D3-9CFDF3024362Q59801659-808FB3B6-BA12-4071-948E-77237C248E66Q83876937-203C1210-C64E-4E6D-9633-6B9F2393937AQ93055639-F71907FB-1659-4315-A224-4B5E2A06E005Q93270841-1B20C460-70CC-499E-83A0-B020AAA86736
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Tommy Kaplan
@ast
Tommy Kaplan
@en
Tommy Kaplan
@es
Tommy Kaplan
@fr
Tommy Kaplan
@nl
Tommy Kaplan
@sl
type
label
Tommy Kaplan
@ast
Tommy Kaplan
@en
Tommy Kaplan
@es
Tommy Kaplan
@fr
Tommy Kaplan
@nl
Tommy Kaplan
@sl
altLabel
תומי קפלן Tomer Kaplan, תומר קפלן
@en
prefLabel
Tommy Kaplan
@ast
Tommy Kaplan
@en
Tommy Kaplan
@es
Tommy Kaplan
@fr
Tommy Kaplan
@nl
Tommy Kaplan
@sl
P1053
T-2528-2017
P106
P21
P31
P3829
P496
0000-0002-1892-5461