sameAs
Structural basis for the heterodimeric interaction between the acute leukaemia-associated transcription factors AML1 and CBFbetaFusion of the dominant negative transcription regulator CHOP with a novel gene FUS by translocation t(12;16) in malignant liposarcomaThe LIM-only protein Lmo2 is a bridging molecule assembling an erythroid, DNA-binding complex which includes the TAL1, E47, GATA-1 and Ldb1/NLI proteinsThe chromosomal location of T-cell receptor genes and a T cell rearranging gene: possible correlation with specific translocations in human T cell leukaemiaThe sequence of a human immunoglobulin epsilon heavy chain constant region gene, and evidence for three non-allelic genesThe LIM protein RBTN2 and the basic helix-loop-helix protein TAL1 are present in a complex in erythroid cellsHuman immunoglobulin heavy chain genes: evolutionary comparisons of C mu, C delta and C gamma genes and associated switch sequencesThe Ews-ERG fusion protein can initiate neoplasia from lineage-committed haematopoietic cells.Exploring the surfaceome of Ewing sarcoma identifies a new and unique therapeutic targetThe hepatitis C virus internal ribosome entry site facilitates efficient protein synthesis in blood vessel endothelium during tumour angiogenesisTumour prevention by a single antibody domain targeting the interaction of signal transduction proteins with RASFunctional intracellular antibody fragments do not require invariant intra-domain disulfide bondsConformational flexibility of the oncogenic protein LMO2 primes the formation of the multi-protein transcription complexGenomic structure, tissue expression and chromosomal location of the LIM-only gene, SLIM1LIM-only protein Lmo2 forms a protein complex with erythroid transcription factor GATA-1The rhombotin gene family encode related LIM-domain proteins whose differing expression suggests multiple roles in mouse developmentThe chromosomal translocation t(X;14)(q28;q11) in T-cell pro-lymphocytic leukaemia breaks within one gene and activates anotherEvolution of immunoglobulin V genes: evidence indicating that recently duplicated human V kappa sequences have diverged by gene conversionUnusual forms of T cell gamma mRNA in a human T cell leukemia cell line: implications for gamma gene expressionExpression patterns of the human sarcoma-associated genes FUS and EWS and the genomic structure of FUSGenetic organization of the human T cell receptor gamma locusThe T cell oncogene Tal2 is necessary for normal development of the mouse brainNull mutation of the Lmo4 gene or a combined null mutation of the Lmo1/Lmo3 genes causes perinatal lethality, and Lmo4 controls neural tube development in miceMouse Af9 is a controller of embryo patterning, like Mll, whose human homologue fuses with Af9 after chromosomal translocation in leukemiaDe novo production of diverse intracellular antibody libraries.Isolation of antigen-specific intracellular antibody fragments as single chain Fv for use in mammalian cells.Intracellular antibody capture technology: application to selection of intracellular antibodies recognising the BCR-ABL oncogenic protein.Sub-proteome differential display: single gel comparison by 2D electrophoresis and mass spectrometry.Single domain intracellular antibodies: a minimal fragment for direct in vivo selection of antigen-specific intrabodies.Interrogation of genomes by molecular copy-number counting (MCC).The role of Slit-Robo signaling in the generation, migration and morphological differentiation of cortical interneurons.Selection of complementary single-variable domains for building monoclonal antibodies to native proteinsProtocol for the selection of single-domain antibody fragments by third generation intracellular antibody capture.Analysis of a T-cell tumor-specific breakpoint cluster at human chromosome 14q32.Single domain intracellular antibodies from diverse libraries: emphasizing dual functions of LMO2 protein interactions using a single VH domainTumorigenesis in mice with a fusion of the leukaemia oncogene Mll and the bacterial lacZ gene.Mll fusions generated by Cre-loxP-mediated de novo translocations can induce lineage reassignment in tumorigenesisProgressive 3q amplification consistently targets SOX2 in preinvasive squamous lung cancer.Translocation joins c-myc and immunoglobulin gamma 1 genes in a Burkitt lymphoma revealing a third exon in the c-myc oncogene.Extending the repertoire of the mixed-lineage leukemia gene MLL in leukemogenesis.
P50
Q22254263-F33A29F2-DBCC-42B7-999F-63DC549DD282Q24304506-1EFB6115-EAFC-46E8-B198-ACB0B52D547AQ24532225-68103799-536F-4AFD-9C95-1D34E2B2F0ECQ24555805-EEAA04E7-4ACA-409B-A43A-220F449D990BQ24556502-9F86E804-CD01-45D6-8BFB-F7C0C041DDFAQ24564060-8886F2F4-5B1D-43A3-94AF-1A744C4E3A24Q24594225-24DF561D-9DD1-44C6-9F78-D5BE8D6B7C60Q24811898-3E7EAF0A-8B15-4D21-AAE8-C900952CE7C8Q27317164-DEF8D58E-999F-4F79-B0E8-CAD920FB3815Q27473459-9AA0C3A2-2C02-4CD7-B5E0-E625E66E59D3Q27645826-423C3260-6B96-424B-B8EF-43C664316C5CQ27649518-488EB260-7F22-4663-8B92-014954DE5953Q27681258-EF302A31-D1C9-4665-BE5E-C744B240BC26Q28144943-29C20F2E-F32A-4893-B4C6-63E3DA89C543Q28242794-D1A265BE-21AE-4167-A9DF-2EB1EA695CC2Q28255467-6BC4DF7E-9B39-408D-B99E-FBACE11230FEQ28256839-3CD9BAFD-3CB2-44B8-B7EA-C48F88F17CA1Q28267852-4ABDBC6E-C00C-4670-AF04-FEA8804AE8B6Q28285621-A720CBD5-3FD2-4294-B9AD-3588A7285ACFQ28296815-1F4A94B5-552D-44CF-90EC-F3426C9F06E4Q28303233-C1E9FC1D-C6A1-4538-819D-CC7303BC7205Q28513665-0CE87C5A-9A69-49C1-AA51-CB0F027144F2Q28587181-F8F67B7F-13F7-4CFF-92B2-85B56152F4B0Q28594037-5967813B-CD37-4AC7-99CA-3AEED6BB79A6Q30887786-63117211-1194-470D-8282-D555D879B4C6Q31033490-1D67C865-087A-493B-AE7F-2F5C95F0627AQ31045367-7A490660-5DE4-4F48-A0F9-9862BF912A31Q31072476-4952BEF1-D79F-4CFE-B64C-70B7EBB4B1C9Q33188212-EC7CC92B-3AAC-4A85-8F1D-7FACA553224AQ33244431-F693A4C3-0336-42FC-B764-E9B983F73841Q33308411-07880CCA-5B39-49AD-A078-F5BCF6D56F4CQ33408086-200A78C8-B627-4B4A-A261-363524D3F9CCQ33522558-2148BD28-DE09-42AB-9ADD-FCEE27D7F33FQ33681028-6C4AAD7F-CFE8-4B90-AD71-854EA37ACEE4Q33729971-4528511D-A54B-48AF-AB22-33DE6A50C7C3Q33891954-4B087CAC-2F26-4770-AE67-C21D8C06DFBBQ33947080-92A165DF-BFA9-4E67-B0F7-103FDFE41480Q33988144-49823E37-5F20-4667-9E44-88DB13831131Q34055298-378D8A69-B468-44BA-9F5D-3963E606E914Q34319461-AE39DA8C-F53C-485B-AE52-3F4E5716D6B0
P50
description
English molecular biologist
@en
academisch docent
@nl
englischer Molekularbiologe und Hochschullehrer
@de
name
Terence H Rabbitts
@nl
Terence Rabbitts
@de
Terence Rabbitts
@en
Terence Rabbitts
@es
Terence Rabbitts
@fr
type
label
Terence H Rabbitts
@nl
Terence Rabbitts
@de
Terence Rabbitts
@en
Terence Rabbitts
@es
Terence Rabbitts
@fr
altLabel
Terence H Rabbitts
@en
Terry Rabbitts
@en
Terry
@en
prefLabel
Terence H Rabbitts
@nl
Terence Rabbitts
@de
Terence Rabbitts
@en
Terence Rabbitts
@es
Terence Rabbitts
@fr
P166
P214
P244
P1053
D-6262-2016
P106
P2070
terence-rabbitts-12130
P21
P214
P244
nr89011373
P31
P3829
P4789
P496
0000-0002-4982-2609
P569
1946-06-17T00:00:00Z
P734
P735
P7859
lccn-nr89011373