Keyword Search: Gene Ontology, PubMed or Web (Google)
PDB Keywords for 3V79
(Keywords from the PDB file are used here. They may or may not correspond to GO term names).
- Beta-Trefoil|Ankyrin|Transcription Activation|Dna Binding|Transcription-Dna Complex [GO] [PubMed] [Google]
GO Keywords for 3V79
(Here all GO term names are given that map directly to this particular structure).
- negative regulation of transcription by RNA polymerase II [GO] [PubMed] [Google]
- recombinase activity [GO] [PubMed] [Google]
- RNA polymerase II proximal promoter sequence-specific DNA binding [GO] [PubMed] [Google]
- RNA polymerase II core promoter sequence-specific DNA binding [GO] [PubMed] [Google]
- transcription factor activity, RNA polymerase II proximal promoter sequence-specific DNA binding [GO] [PubMed] [Google]
- proximal promoter DNA-binding transcription activator activity, RNA polymerase II-specific [GO] [PubMed] [Google]
- RNA polymerase II repressing transcription factor binding [GO] [PubMed] [Google]
- DNA-binding transcription activator activity, RNA polymerase II-specific [GO] [PubMed] [Google]
- angiogenesis [GO] [PubMed] [Google]
- somitogenesis [GO] [PubMed] [Google]
- epithelial to mesenchymal transition [GO] [PubMed] [Google]
- blood vessel remodeling [GO] [PubMed] [Google]
- MAML1-RBP-Jkappa- ICN1 complex [GO] [PubMed] [Google]
- inflammatory response to antigenic stimulus [GO] [PubMed] [Google]
- secondary heart field specification [GO] [PubMed] [Google]
- outflow tract morphogenesis [GO] [PubMed] [Google]
- endocardium development [GO] [PubMed] [Google]
- endocardium morphogenesis [GO] [PubMed] [Google]
- epithelial to mesenchymal transition involved in endocardial cushion formation [GO] [PubMed] [Google]
- cardiac left ventricle morphogenesis [GO] [PubMed] [Google]
- ventricular trabecula myocardium morphogenesis [GO] [PubMed] [Google]
- regulation of transcription from RNA polymerase II promoter involved in myocardial precursor cell differentiation [GO] [PubMed] [Google]
- DNA binding [GO] [PubMed] [Google]
- chromatin binding [GO] [PubMed] [Google]
- DNA-binding transcription factor activity [GO] [PubMed] [Google]
- protein binding [GO] [PubMed] [Google]
- nucleus [GO] [PubMed] [Google]
- nucleoplasm [GO] [PubMed] [Google]
- transcription factor complex [GO] [PubMed] [Google]
- nucleolus [GO] [PubMed] [Google]
- cytoplasm [GO] [PubMed] [Google]
- DNA recombination [GO] [PubMed] [Google]
- transcription, DNA-templated [GO] [PubMed] [Google]
- regulation of transcription, DNA-templated [GO] [PubMed] [Google]
- regulation of transcription by RNA polymerase II [GO] [PubMed] [Google]
- transcription by RNA polymerase II [GO] [PubMed] [Google]
- transcription initiation from RNA polymerase II promoter [GO] [PubMed] [Google]
- humoral immune response [GO] [PubMed] [Google]
- Notch signaling pathway [GO] [PubMed] [Google]
- positive regulation of transcription of Notch receptor target [GO] [PubMed] [Google]
- heart development [GO] [PubMed] [Google]
- transcription factor binding [GO] [PubMed] [Google]
- positive regulation of cell proliferation [GO] [PubMed] [Google]
- negative regulation of cell proliferation [GO] [PubMed] [Google]
- auditory receptor cell fate commitment [GO] [PubMed] [Google]
- epidermal cell fate specification [GO] [PubMed] [Google]
- regulation of gene expression [GO] [PubMed] [Google]
- positive regulation of gene expression [GO] [PubMed] [Google]
- pituitary gland development [GO] [PubMed] [Google]
- hemopoiesis [GO] [PubMed] [Google]
- neuron differentiation [GO] [PubMed] [Google]
- B cell differentiation [GO] [PubMed] [Google]
- keratinocyte differentiation [GO] [PubMed] [Google]
- negative regulation of ossification [GO] [PubMed] [Google]
- positive regulation of BMP signaling pathway [GO] [PubMed] [Google]
- somatic stem cell population maintenance [GO] [PubMed] [Google]
- dorsal aorta morphogenesis [GO] [PubMed] [Google]
- atrioventricular canal development [GO] [PubMed] [Google]
- regulation of cell proliferation [GO] [PubMed] [Google]
- defense response to bacterium [GO] [PubMed] [Google]
- myeloid dendritic cell differentiation [GO] [PubMed] [Google]
- sequence-specific DNA binding [GO] [PubMed] [Google]
- cell fate commitment [GO] [PubMed] [Google]
- negative regulation of cell differentiation [GO] [PubMed] [Google]
- negative regulation of transcription, DNA-templated [GO] [PubMed] [Google]
- positive regulation of transcription by RNA polymerase II [GO] [PubMed] [Google]
- protein N-terminus binding [GO] [PubMed] [Google]
- regulation of timing of cell differentiation [GO] [PubMed] [Google]
- sebaceous gland development [GO] [PubMed] [Google]
- hair follicle maturation [GO] [PubMed] [Google]
- artery morphogenesis [GO] [PubMed] [Google]
- positive regulation of cardiac muscle cell proliferation [GO] [PubMed] [Google]
- Clara cell differentiation [GO] [PubMed] [Google]
- labyrinthine layer blood vessel development [GO] [PubMed] [Google]
- arterial endothelial cell fate commitment [GO] [PubMed] [Google]
- Notch signaling involved in heart development [GO] [PubMed] [Google]
- positive regulation of transcription from RNA polymerase II promoter in response to hypoxia [GO] [PubMed] [Google]
- blood vessel lumenization [GO] [PubMed] [Google]
- interleukin-4 secretion [GO] [PubMed] [Google]
- blood vessel endothelial cell fate specification [GO] [PubMed] [Google]
- positive regulation of ERBB signaling pathway [GO] [PubMed] [Google]
- positive regulation of ephrin receptor signaling pathway [GO] [PubMed] [Google]
- positive regulation of canonical Wnt signaling pathway involved in cardiac muscle cell fate commitment [GO] [PubMed] [Google]
- positive regulation of cell proliferation involved in heart morphogenesis [GO] [PubMed] [Google]
- negative regulation of transcription by RNA polymerase II [GO] [PubMed] [Google]
- Golgi membrane [GO] [PubMed] [Google]
- core promoter binding [GO] [PubMed] [Google]
- obsolete transcriptional activator activity, RNA polymerase II transcription factor binding [GO] [PubMed] [Google]
- angiogenesis [GO] [PubMed] [Google]
- acrosomal vesicle [GO] [PubMed] [Google]
- in utero embryonic development [GO] [PubMed] [Google]
- cell fate specification [GO] [PubMed] [Google]
- epithelial to mesenchymal transition [GO] [PubMed] [Google]
- liver development [GO] [PubMed] [Google]
- heart looping [GO] [PubMed] [Google]
- sprouting angiogenesis [GO] [PubMed] [Google]
- positive regulation of neuroblast proliferation [GO] [PubMed] [Google]
- MAML1-RBP-Jkappa- ICN1 complex [GO] [PubMed] [Google]
- inflammatory response to antigenic stimulus [GO] [PubMed] [Google]
- endocardium development [GO] [PubMed] [Google]
- endocardium morphogenesis [GO] [PubMed] [Google]
- atrioventricular node development [GO] [PubMed] [Google]
- coronary vein morphogenesis [GO] [PubMed] [Google]
- aortic valve morphogenesis [GO] [PubMed] [Google]
- atrioventricular valve morphogenesis [GO] [PubMed] [Google]
- pulmonary valve morphogenesis [GO] [PubMed] [Google]
- mitral valve formation [GO] [PubMed] [Google]
- endocardial cushion development [GO] [PubMed] [Google]
- epithelial to mesenchymal transition involved in endocardial cushion formation [GO] [PubMed] [Google]
- endocardial cushion morphogenesis [GO] [PubMed] [Google]
- cardiac chamber formation [GO] [PubMed] [Google]
- cardiac ventricle morphogenesis [GO] [PubMed] [Google]
- cardiac atrium morphogenesis [GO] [PubMed] [Google]
- cardiac right atrium morphogenesis [GO] [PubMed] [Google]
- cardiac left ventricle morphogenesis [GO] [PubMed] [Google]
- cardiac right ventricle formation [GO] [PubMed] [Google]
- ventricular trabecula myocardium morphogenesis [GO] [PubMed] [Google]
- growth involved in heart morphogenesis [GO] [PubMed] [Google]
- regulation of transcription from RNA polymerase II promoter involved in myocardial precursor cell differentiation [GO] [PubMed] [Google]
- regulation of cardioblast proliferation [GO] [PubMed] [Google]
- Notch signaling pathway involved in regulation of secondary heart field cardioblast proliferation [GO] [PubMed] [Google]
- cell migration involved in endocardial cushion formation [GO] [PubMed] [Google]
- pericardium morphogenesis [GO] [PubMed] [Google]
- chromatin binding [GO] [PubMed] [Google]
- DNA-binding transcription factor activity [GO] [PubMed] [Google]
- enzyme inhibitor activity [GO] [PubMed] [Google]
- Notch binding [GO] [PubMed] [Google]
- calcium ion binding [GO] [PubMed] [Google]
- protein binding [GO] [PubMed] [Google]
- extracellular region [GO] [PubMed] [Google]
- nucleus [GO] [PubMed] [Google]
- nucleoplasm [GO] [PubMed] [Google]
- cytoplasm [GO] [PubMed] [Google]
- endoplasmic reticulum [GO] [PubMed] [Google]
- endoplasmic reticulum membrane [GO] [PubMed] [Google]
- Golgi apparatus [GO] [PubMed] [Google]
- cytosol [GO] [PubMed] [Google]
- plasma membrane [GO] [PubMed] [Google]
- adherens junction [GO] [PubMed] [Google]
- transcription, DNA-templated [GO] [PubMed] [Google]
- regulation of transcription, DNA-templated [GO] [PubMed] [Google]
- regulation of transcription by RNA polymerase II [GO] [PubMed] [Google]
- transcription by RNA polymerase II [GO] [PubMed] [Google]
- transcription initiation from RNA polymerase II promoter [GO] [PubMed] [Google]
- immune response [GO] [PubMed] [Google]
- humoral immune response [GO] [PubMed] [Google]
- Notch signaling pathway [GO] [PubMed] [Google]
- positive regulation of transcription of Notch receptor target [GO] [PubMed] [Google]
- multicellular organism development [GO] [PubMed] [Google]
- spermatogenesis [GO] [PubMed] [Google]
- determination of left/right symmetry [GO] [PubMed] [Google]
- compartment pattern specification [GO] [PubMed] [Google]
- axonogenesis [GO] [PubMed] [Google]
- brain development [GO] [PubMed] [Google]
- foregut morphogenesis [GO] [PubMed] [Google]
- endoderm development [GO] [PubMed] [Google]
- heart development [GO] [PubMed] [Google]
- positive regulation of cell proliferation [GO] [PubMed] [Google]
- negative regulation of cell proliferation [GO] [PubMed] [Google]
- epidermis development [GO] [PubMed] [Google]
- regulation of Notch signaling pathway [GO] [PubMed] [Google]
- auditory receptor cell fate commitment [GO] [PubMed] [Google]
- cell surface [GO] [PubMed] [Google]
- glial cell differentiation [GO] [PubMed] [Google]
- regulation of gene expression [GO] [PubMed] [Google]
- positive regulation of epithelial to mesenchymal transition [GO] [PubMed] [Google]
- negative regulation of cell-substrate adhesion [GO] [PubMed] [Google]
- negative regulation of myotube differentiation [GO] [PubMed] [Google]
- mesenchymal cell development [GO] [PubMed] [Google]
- regulation of somitogenesis [GO] [PubMed] [Google]
- membrane [GO] [PubMed] [Google]
- integral component of membrane [GO] [PubMed] [Google]
- apical plasma membrane [GO] [PubMed] [Google]
- enzyme binding [GO] [PubMed] [Google]
- cell differentiation in spinal cord [GO] [PubMed] [Google]
- neural tube development [GO] [PubMed] [Google]
- cell differentiation [GO] [PubMed] [Google]
- neuron differentiation [GO] [PubMed] [Google]
- keratinocyte differentiation [GO] [PubMed] [Google]
- negative regulation of ossification [GO] [PubMed] [Google]
- lung development [GO] [PubMed] [Google]
- embryonic limb morphogenesis [GO] [PubMed] [Google]
- regulation of cell migration [GO] [PubMed] [Google]
- positive regulation of cell migration [GO] [PubMed] [Google]
- positive regulation of BMP signaling pathway [GO] [PubMed] [Google]
- negative regulation of BMP signaling pathway [GO] [PubMed] [Google]
- forebrain development [GO] [PubMed] [Google]
- hair follicle morphogenesis [GO] [PubMed] [Google]
- animal organ regeneration [GO] [PubMed] [Google]
- cytoplasmic vesicle [GO] [PubMed] [Google]
- chromatin DNA binding [GO] [PubMed] [Google]
- response to corticosteroid [GO] [PubMed] [Google]
- response to muramyl dipeptide [GO] [PubMed] [Google]
- response to lipopolysaccharide [GO] [PubMed] [Google]
- embryonic hindlimb morphogenesis [GO] [PubMed] [Google]
- tube formation [GO] [PubMed] [Google]
- skeletal muscle cell differentiation [GO] [PubMed] [Google]
- cellular response to vascular endothelial growth factor stimulus [GO] [PubMed] [Google]
- regulation of cell proliferation [GO] [PubMed] [Google]
- tissue regeneration [GO] [PubMed] [Google]
- positive regulation of apoptotic process [GO] [PubMed] [Google]
- negative regulation of catalytic activity [GO] [PubMed] [Google]
- receptor complex [GO] [PubMed] [Google]
- sequence-specific DNA binding [GO] [PubMed] [Google]
- positive regulation of viral genome replication [GO] [PubMed] [Google]
- cell fate commitment [GO] [PubMed] [Google]
- negative regulation of cell differentiation [GO] [PubMed] [Google]
- positive regulation of endothelial cell differentiation [GO] [PubMed] [Google]
- regulation of inner ear auditory receptor cell differentiation [GO] [PubMed] [Google]
- negative regulation of inner ear auditory receptor cell differentiation [GO] [PubMed] [Google]
- positive regulation of keratinocyte differentiation [GO] [PubMed] [Google]
- negative regulation of myoblast differentiation [GO] [PubMed] [Google]
- negative regulation of neuron differentiation [GO] [PubMed] [Google]
- negative regulation of osteoblast differentiation [GO] [PubMed] [Google]
- positive regulation of glial cell differentiation [GO] [PubMed] [Google]
- positive regulation of Notch signaling pathway [GO] [PubMed] [Google]
- negative regulation of transcription, DNA-templated [GO] [PubMed] [Google]
- positive regulation of transcription, DNA-templated [GO] [PubMed] [Google]
- positive regulation of transcription by RNA polymerase II [GO] [PubMed] [Google]
- negative regulation of calcium ion-dependent exocytosis [GO] [PubMed] [Google]
- positive regulation of JAK-STAT cascade [GO] [PubMed] [Google]
- negative regulation of photoreceptor cell differentiation [GO] [PubMed] [Google]
- metal ion binding [GO] [PubMed] [Google]
- protein heterodimerization activity [GO] [PubMed] [Google]
- somatic stem cell division [GO] [PubMed] [Google]
- neuron fate commitment [GO] [PubMed] [Google]
- astrocyte differentiation [GO] [PubMed] [Google]
- oligodendrocyte differentiation [GO] [PubMed] [Google]
- positive regulation of astrocyte differentiation [GO] [PubMed] [Google]
- negative regulation of oligodendrocyte differentiation [GO] [PubMed] [Google]
- branching morphogenesis of an epithelial tube [GO] [PubMed] [Google]
- positive regulation of viral transcription [GO] [PubMed] [Google]
- regulation of epithelial cell proliferation [GO] [PubMed] [Google]
- positive regulation of epithelial cell proliferation [GO] [PubMed] [Google]
- regulation of neurogenesis [GO] [PubMed] [Google]
- negative regulation of neurogenesis [GO] [PubMed] [Google]
- regulation of developmental process [GO] [PubMed] [Google]
- cardiac muscle tissue morphogenesis [GO] [PubMed] [Google]
- cardiac muscle cell proliferation [GO] [PubMed] [Google]
- positive regulation of cardiac muscle cell proliferation [GO] [PubMed] [Google]
- negative regulation of glial cell proliferation [GO] [PubMed] [Google]
- cilium assembly [GO] [PubMed] [Google]
- cardiac epithelial to mesenchymal transition [GO] [PubMed] [Google]
- cardiac septum morphogenesis [GO] [PubMed] [Google]
- ventricular septum morphogenesis [GO] [PubMed] [Google]
- secretory columnal luminar epithelial cell differentiation involved in prostate glandular acinus development [GO] [PubMed] [Google]
- negative regulation of cell death [GO] [PubMed] [Google]
- prostate gland epithelium morphogenesis [GO] [PubMed] [Google]
- regulation of epithelial cell proliferation involved in prostate gland development [GO] [PubMed] [Google]
- arterial endothelial cell differentiation [GO] [PubMed] [Google]
- venous endothelial cell differentiation [GO] [PubMed] [Google]
- cardiac vascular smooth muscle cell development [GO] [PubMed] [Google]
- endocardial cell differentiation [GO] [PubMed] [Google]
- vasculogenesis involved in coronary vascular morphogenesis [GO] [PubMed] [Google]
- coronary artery morphogenesis [GO] [PubMed] [Google]
- Notch signaling involved in heart development [GO] [PubMed] [Google]
- heart trabecula morphogenesis [GO] [PubMed] [Google]
- positive regulation of transcription from RNA polymerase II promoter in response to hypoxia [GO] [PubMed] [Google]
- left/right axis specification [GO] [PubMed] [Google]
- cellular response to follicle-stimulating hormone stimulus [GO] [PubMed] [Google]
- cell periphery [GO] [PubMed] [Google]
- distal tubule development [GO] [PubMed] [Google]
- collecting duct development [GO] [PubMed] [Google]
- glomerular mesangial cell development [GO] [PubMed] [Google]
- interleukin-4 secretion [GO] [PubMed] [Google]
- negative regulation of cell migration involved in sprouting angiogenesis [GO] [PubMed] [Google]
- negative regulation of canonical Wnt signaling pathway [GO] [PubMed] [Google]
- neuronal stem cell population maintenance [GO] [PubMed] [Google]
- regulation of extracellular matrix assembly [GO] [PubMed] [Google]
- apoptotic process involved in embryonic digit morphogenesis [GO] [PubMed] [Google]
- negative regulation of stem cell differentiation [GO] [PubMed] [Google]
- negative regulation of anoikis [GO] [PubMed] [Google]
- negative regulation of pro-B cell differentiation [GO] [PubMed] [Google]
- negative regulation of endothelial cell chemotaxis [GO] [PubMed] [Google]
- MAML1-RBP-Jkappa- ICN1 complex [GO] [PubMed] [Google]
- atrioventricular node development [GO] [PubMed] [Google]
- transcription coactivator activity [GO] [PubMed] [Google]
- protein binding [GO] [PubMed] [Google]
- nucleus [GO] [PubMed] [Google]
- nucleoplasm [GO] [PubMed] [Google]
- transcription, DNA-templated [GO] [PubMed] [Google]
- regulation of transcription, DNA-templated [GO] [PubMed] [Google]
- transcription initiation from RNA polymerase II promoter [GO] [PubMed] [Google]
- protein phosphorylation [GO] [PubMed] [Google]
- Notch signaling pathway [GO] [PubMed] [Google]
- positive regulation of transcription of Notch receptor target [GO] [PubMed] [Google]
- positive regulation of myotube differentiation [GO] [PubMed] [Google]
- nuclear speck [GO] [PubMed] [Google]
- protein kinase binding [GO] [PubMed] [Google]
- peptide antigen binding [GO] [PubMed] [Google]
- intracellular membrane-bounded organelle [GO] [PubMed] [Google]
- myoblast differentiation [GO] [PubMed] [Google]
- positive regulation of transcription by RNA polymerase II [GO] [PubMed] [Google]
- positive regulation of muscle cell differentiation [GO] [PubMed] [Google]
- atrioventricular node cell development [GO] [PubMed] [Google]