| scholarly article | Q13442814 |
| P6179 | Dimensions Publication ID | 1036570112 |
| P356 | DOI | 10.1038/NG.494 |
| P932 | PMC publication ID | 2799392 |
| P698 | PubMed publication ID | 20023660 |
| P5875 | ResearchGate publication ID | 40731150 |
| P50 | author | Peter Hohenstein | Q41783681 |
| Ramon Munoz-Chapuli | Q42842781 | ||
| Judith Reichmann | Q42945915 | ||
| Emma A Hall | Q64004414 | ||
| Ofelia M. Martínez Estrada | Q71387869 | ||
| P2093 | author name string | Robert E Hill | |
| Abdelkader Essafi | |||
| Nicholas D Hastie | |||
| Naoki Hosen | |||
| Laura A Lettice | |||
| Juan Antonio Guadix | |||
| Joan Slight | |||
| Paul S Devenney | |||
| Víctor Velecela | |||
| P2860 | cites work | YAC complementation shows a requirement for Wt1 in the development of epicardium, adrenal gland and throughout nephrogenesis | Q22009123 |
| Embryonic stem cell differentiation: emergence of a new era in biology and medicine | Q22065783 | ||
| The epithelial-mesenchymal transition generates cells with properties of stem cells | Q24650786 | ||
| Correlation of Snail expression with histological grade and lymph node status in breast carcinomas | Q28206944 | ||
| The snail superfamily of zinc-finger transcription factors | Q28216843 | ||
| The many facets of the Wilms' tumour gene, WT1 | Q28264516 | ||
| The Wilms' tumour protein (WT1) shuttles between nucleus and cytoplasm and is present in functional polysomes | Q28505624 | ||
| Coronary vessel development requires activation of the TrkB neurotrophin receptor by the Wilms' tumor transcription factor Wt1. | Q28507412 | ||
| The mouse bagpipe gene controls development of axial skeleton, skull, and spleen | Q28585443 | ||
| A highly efficient recombineering-based method for generating conditional knockout mutations | Q29615157 | ||
| Optical projection tomography as a tool for 3D microscopy and gene expression studies | Q29617950 | ||
| Epicardial retinoid X receptor alpha is required for myocardial growth and coronary artery formation | Q34234421 | ||
| The epicardium and epicardially derived cells (EPDCs) as cardiac stem cells | Q35618207 | ||
| E-cadherin inhibits cell surface localization of the pro-migratory 5T4 oncofetal antigen in mouse embryonic stem cells | Q35942348 | ||
| Direct derivation of conditionally immortal cell lines from an H-2Kb-tsA58 transgenic mouse | Q37530481 | ||
| Genomic analysis of gastrulation and organogenesis in the mouse | Q38295638 | ||
| hnRNP-U directly interacts with WT1 and modulates WT1 transcriptional activation | Q40241092 | ||
| Expression of Snail protein in tumor-stroma interface | Q40299239 | ||
| E-cadherin is a WT1 target gene | Q42832537 | ||
| The Wilms' tumor gene WT1-GFP knock-in mouse reveals the dynamic regulation of WT1 expression in normal and leukemic hematopoiesis | Q50682333 | ||
| The Wilms' tumor suppressor Wt1 is expressed in the coronary vasculature after myocardial infarction | Q51715205 | ||
| Embryonic stem-cell culture as a tool for developmental cell biology | Q51985048 | ||
| High expression of Wilms' tumor suppressor gene predicts poor prognosis in breast cancer patients | Q74079889 | ||
| P433 | issue | 1 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | circulatory system | Q11068 |
| P304 | page(s) | 89-93 | |
| P577 | publication date | 2009-12-20 | |
| P1433 | published in | Nature Genetics | Q976454 |
| P1476 | title | Wt1 is required for cardiovascular progenitor cell formation through transcriptional control of Snail and E-cadherin | |
| P478 | volume | 42 |
| Q91710805 | A 3D molecular atlas of the chick embryonic heart |
| Q33961259 | A novel role of CDX1 in embryonic epicardial development |
| Q27323376 | A universal vector for high-efficiency multi-fragment recombineering of BACs and knock-in constructs |
| Q43221537 | A wt1-controlled chromatin switching mechanism underpins tissue-specific wnt4 activation and repression |
| Q27335370 | Acute multiple organ failure in adult mice deleted for the developmental regulator Wt1 |
| Q36838490 | Adult cardiac-resident MSC-like stem cells with a proepicardial origin |
| Q92438901 | Altered haemodynamics causes aberrations in the epicardium |
| Q41126801 | BRG1-SWI/SNF-dependent regulation of the Wt1 transcriptional landscape mediates epicardial activity during heart development and disease |
| Q38897328 | Biological Systems and Methods for Studying WT1 in the Epicardium |
| Q42612792 | Bone morphogenic protein signalling suppresses differentiation of pluripotent cells by maintaining expression of E-Cadherin. |
| Q94562501 | Brain-specific Wt1 deletion leads to depressive-like behaviors in mice via the recruitment of Tet2 to modulate Epo expression |
| Q36731334 | C/EBP transcription factors mediate epicardial activation during heart development and injury. |
| Q34476278 | CXCL12/CXCR4 blockade by oncolytic virotherapy inhibits ovarian cancer growth by decreasing immunosuppression and targeting cancer-initiating cells |
| Q34291299 | Cardiac Explant-Derived Cells Are Regulated by Notch-Modulated Mesenchymal Transition |
| Q34427258 | Cardiac Regeneration from Activated Epicardium |
| Q34083167 | Cardiac cell lineages that form the heart |
| Q50601069 | Cardiac endothelial cells express Wilms' tumor-1: Wt1 expression in the developing, adult and infarcted heart |
| Q33639215 | Cardiac fibroblast in development and wound healing |
| Q41887271 | Cardiac malformations in Pdgfralpha mutant embryos are associated with increased expression of WT1 and Nkx2.5 in the second heart field |
| Q27025973 | Cardiac-derived stem cell-based therapy for heart failure: progress and clinical applications |
| Q34589642 | Cells derived from the coelomic epithelium contribute to multiple gastrointestinal tissues in mouse embryos. |
| Q34562292 | Characterization of Epicardial-Derived Cardiac Interstitial Cells: Differentiation and Mobilization of Heart Fibroblast Progenitors |
| Q38659781 | Coelomic epithelium-derived cells in visceral morphogenesis. |
| Q37265937 | Conditional deletion of WT1 in the septum transversum mesenchyme causes congenital diaphragmatic hernia in mice |
| Q55380590 | Congenital Heart Defects and Ciliopathies Associated With Renal Phenotypes. |
| Q38711945 | Congenital coronary artery anomalies: a bridge from embryology to anatomy and pathophysiology--a position statement of the development, anatomy, and pathology ESC Working Group. |
| Q39264413 | Control of epigenetic states by WT1 via regulation of de novo DNA methyltransferase 3A. |
| Q36517012 | Crim1 has cell-autonomous and paracrine roles during embryonic heart development |
| Q38105859 | Current concepts on the pathogenesis and etiology of congenital diaphragmatic hernia |
| Q30660201 | Deducing the stage of origin of Wilms' tumours from a developmental series of Wt1-mutant mice |
| Q51632377 | Deficiency in WT1-targeting microRNA-125a leads to myeloid malignancies and urogenital abnormalities |
| Q27728005 | Denys-Drash syndrome associated WT1 glutamine 369 mutants have altered sequence-preferences and altered responses to epigenetic modifications |
| Q92036703 | Deubiquitinase inhibitor degrasyn suppresses metastasis by targeting USP5-WT1-E-cadherin signalling pathway in pancreatic ductal adenocarcinoma |
| Q35241220 | Developmental patterns and characteristics of epicardial cell markers Tbx18 and Wt1 in murine embryonic heart |
| Q34605617 | Dioxin receptor and SLUG transcription factors regulate the insulator activity of B1 SINE retrotransposons via an RNA polymerase switch. |
| Q34846044 | Disease-related growth factor and embryonic signaling pathways modulate an enhancer of TCF21 expression at the 6q23.2 coronary heart disease locus |
| Q36404968 | Early cardiac development: a view from stem cells to embryos |
| Q38148527 | Embryonic heart progenitors and cardiogenesis |
| Q90730645 | Embryonic mesothelial-derived hepatic lineage of quiescent and heterogenous scar-orchestrating cells defined but suppressed by WT1 |
| Q26771698 | Emerging Transcriptional Mechanisms in the Regulation of Epithelial to Mesenchymal Transition and Cellular Plasticity in the Kidney |
| Q26830155 | Endocardial and Epicardial Epithelial to Mesenchymal Transitions in Heart Development and Disease |
| Q34274334 | Enzymatic removal of ribonucleotides from DNA is essential for mammalian genome integrity and development. |
| Q26767045 | Epicardial Epithelial-to-Mesenchymal Transition in Heart Development and Disease |
| Q53785255 | Epicardial Outgrowth Culture Assay and Ex Vivo Assessment of Epicardial-derived Cell Migration |
| Q38015278 | Epicardial Progenitor Cells in Cardiac Development and Regeneration |
| Q30495669 | Epicardial spindle orientation controls cell entry into the myocardium |
| Q37777867 | Epicardium and Myocardium Originate From a Common Cardiogenic Precursor Pool |
| Q34127090 | Epicardium-derived cells (EPDCs) in development, cardiac disease and repair of ischemia |
| Q38603614 | Epicardium-derived fibroblasts in heart development and disease. |
| Q38044317 | Epithelial to mesenchymal transition as a portal to stem cell characters embedded in gene networks. |
| Q38771479 | Epithelial-mesenchymal transition (EMT): A biological process in the development, stem cell differentiation, and tumorigenesis. |
| Q35906030 | Epithelial-to-mesenchymal and endothelial-to-mesenchymal transition: from cardiovascular development to disease. |
| Q50778667 | Epithelial-to-mesenchymal transition in epicardium is independent of Snail1. |
| Q51850245 | Expression of Id2 in the second heart field and cardiac defects in Id2 knock‐out mice |
| Q34998367 | Extending the time window of mammalian heart regeneration by thymosin beta 4 |
| Q36498224 | Extracardiac septum transversum/proepicardial endothelial cells pattern embryonic coronary arterio-venous connections |
| Q37880711 | Extracellular matrix and heart development |
| Q30502384 | FGF10/FGFR2b signaling is essential for cardiac fibroblast development and growth of the myocardium |
| Q26823949 | Functional Role of WT1 in Prostate Cancer |
| Q27317274 | Functional vascular smooth muscle-like cells derived from adult mouse uterine mesothelial cells |
| Q38460765 | Generation of cardiac progenitor cells through epicardial to mesenchymal transition. |
| Q42434214 | Genetic Cre-loxP assessment of epicardial cell fate using Wt1-driven Cre alleles. |
| Q36738896 | Heredity and cardiometabolic risk: naturally occurring polymorphisms in the human neuropeptide Y(2) receptor promoter disrupt multiple transcriptional response motifs |
| Q42509603 | High Wilms’ tumor 1 mRNA expression correlates with basal-like and ERBB2 molecular subtypes and poor prognosis of breast cancer |
| Q36913611 | Hippo Signaling Mediators Yap and Taz Are Required in the Epicardium for Coronary Vasculature Development |
| Q34130162 | How to make a heart: the origin and regulation of cardiac progenitor cells |
| Q36048987 | Human epicardial cell-conditioned medium contains HGF/IgG complexes that phosphorylate RYK and protect against vascular injury. |
| Q37456851 | Human fetal and adult epicardial-derived cells: a novel model to study their activation. |
| Q37125418 | Hypoxia induced the differentiation of Tbx18-positive epicardial cells to CoSMCs |
| Q34781425 | IGF signaling directs ventricular cardiomyocyte proliferation during embryonic heart development |
| Q42854188 | In vitro epithelial-to-mesenchymal transformation in human adult epicardial cells is regulated by TGFβ-signaling and WT1 |
| Q58786498 | Injury-induced fetal reprogramming imparts multipotency and reparative properties to pericardial adipose stem cells |
| Q39197772 | Interaction of Human Genes WT1 and CML28 in Leukemic Cells |
| Q53740483 | Isolation and Colony Formation of Murine Bone and Bone Marrow Cells |
| Q51906492 | Lineage tracing of epicardial cells during development and regeneration |
| Q42615616 | Linking genetics with biology in disease research: an interview with Nick Hastie |
| Q87970894 | Long-term self-renewing human epicardial cells generated from pluripotent stem cells under defined xeno-free conditions |
| Q36393265 | MTA1 promotes metastasis of MPM via suppression of E-cadherin |
| Q34193595 | Mab21l2 Is Essential for Embryonic Heart and Liver Development |
| Q35902711 | Mammalian kidney development: principles, progress, and projections |
| Q92844784 | Maternal voluntary exercise mitigates oxidative stress and incidence of congenital heart defects in pre-gestational diabetes |
| Q84463078 | Mesenchymal stromal cells affect cardiomyocyte growth through juxtacrine Notch-1/Jagged-1 signaling and paracrine mechanisms: clues for cardiac regeneration |
| Q57814182 | Mesothelial to mesenchyme transition as a major developmental and pathological player in trunk organs and their cavities |
| Q92973379 | Mesothelium and Malignant Mesothelioma |
| Q38291066 | Meta-Analysis of Transcriptome Regulation During Induction to Cardiac Myocyte Fate From Mouse and Human Fibroblasts. |
| Q36291269 | Methylation alterations of WT1 and homeobox genes in inflamed muscle biopsy samples from patients with untreated juvenile dermatomyositis suggest self-renewal capacity |
| Q37610502 | Micro-management of pluripotent stem cells |
| Q35562519 | MicroRNA-processing enzyme Dicer is required in epicardium for coronary vasculature development |
| Q34985191 | Myocardin-related transcription factors control the motility of epicardium-derived cells and the maturation of coronary vessels |
| Q38085110 | New Insights into the Developmental Mechanisms of Coronary Vessels and Epicardium |
| Q93368809 | New therapeutics based on emerging concepts in pulmonary fibrosis |
| Q34531894 | Novel therapeutic strategies targeting fibroblasts and fibrosis in heart disease |
| Q44644325 | Nuclear transport of Wilms' tumour protein Wt1 involves importins α and β. |
| Q36108192 | Numb family proteins: novel players in cardiac morphogenesis and cardiac progenitor cell differentiation |
| Q34617481 | Oxygen-Dependent Gene Expression in Development and Cancer: Lessons Learned from the Wilms' Tumor Gene, WT1 |
| Q62607845 | Pan-epicardial lineage tracing reveals that epicardium derived cells give rise to myofibroblasts and perivascular cells during zebrafish heart regeneration |
| Q26769997 | Pathological Left Ventricular Hypertrophy and Stem Cells: Current Evidence and New Perspectives |
| Q28578165 | Plakophilin-2 and the migration, differentiation and transformation of cells derived from the epicardium of neonatal rat hearts |
| Q37802009 | Pluripotent stem cell differentiation into vascular cells: A novel technology with promises for vascular re(generation) |
| Q45230770 | Podocalyxin-like protein 1 is a relevant marker for human c-kit(pos) cardiac stem cells. |
| Q38177712 | Priming the renal progenitor cell |
| Q36936876 | Progenitor cells identified by PDGFR-alpha expression in the developing and diseased human heart |
| Q37620729 | Prostate apoptosis response-4 mediates TGF-β-induced epithelial-to-mesenchymal transition |
| Q27010433 | Regulation of epithelial-mesenchymal transition through SUMOylation of transcription factors |
| Q35279994 | Reprogramming of Sertoli cells to fetal-like Leydig cells by Wt1 ablation |
| Q90297521 | Retinoic acid signaling in heart development |
| Q38668014 | Role of Epicardial Adipose Tissue in Health and Disease: A Matter of Fat? |
| Q26858965 | Role of cardiac stem cells in cardiac pathophysiology: a paradigm shift in human myocardial biology |
| Q88512041 | Role of the Wilms' tumor suppressor gene Wt1 in pancreatic development |
| Q42718445 | Septum transversum-derived mesothelium gives rise to hepatic stellate cells and perivascular mesenchymal cells in developing mouse liver. |
| Q41266029 | Snai1 is important for avian epicardial cell transformation and motility |
| Q92376522 | Snail1: A Transcriptional Factor Controlled at Multiple Levels |
| Q36067750 | Suppression of epithelial-mesenchymal transition and apoptotic pathways by miR-294/302 family synergistically blocks let-7-induced silencing of self-renewal in embryonic stem cells |
| Q93052871 | Switch-like enhancement of epithelial-mesenchymal transition by YAP through feedback regulation of WT1 and Rho-family GTPases |
| Q42031459 | TGFβ-dependent epithelial-to-mesenchymal transition is required to generate cardiospheres from human adult heart biopsies |
| Q28079863 | Tackling Cancer Stem Cells via Inhibition of EMT Transcription Factors |
| Q37844965 | Target cell movement in tumor and cardiovascular diseases based on the epithelial–mesenchymal transition concept |
| Q38234910 | Targeting pleiotropic signaling pathways to control adult cardiac stem cell fate and function. |
| Q36503371 | Tbx5 is required for avian and Mammalian epicardial formation and coronary vasculogenesis |
| Q36842821 | Tcf21 regulates the specification and maturation of proepicardial cells |
| Q92411178 | The Atrioventricular Junction: A Potential Niche Region for Progenitor Cells in the Adult Human Heart |
| Q47639653 | The CUG-translated WT1, not AUG-WT1, is an oncogene |
| Q33732860 | The Epicardium and the Development of the Atrioventricular Junction in the Murine Heart |
| Q37899185 | The Ins and Outs of the Epithelial to Mesenchymal Transition in Health and Disease |
| Q37325686 | The Potential of Stem Cells in the Treatment of Cardiovascular Diseases |
| Q38897318 | The Role of WT1 in Embryonic Development and Normal Organ Homeostasis |
| Q28587086 | The WTX tumor suppressor regulates mesenchymal progenitor cell fate specification |
| Q34917167 | The Wilms Tumor Gene, Wt1, Is Critical for Mouse Spermatogenesis via Regulation of Sertoli Cell Polarity and Is Associated with Non-Obstructive Azoospermia in Humans |
| Q38318725 | The Wilms' tumor gene (WT1) regulates E-cadherin expression and migration of prostate cancer cells |
| Q64230573 | The Wilms' tumor suppressor gene regulates pancreas homeostasis and repair |
| Q53668097 | The Wilms' tumour suppressor Wt1 is a major regulator of tumour angiogenesis and progression |
| Q42436780 | The Wilms’ tumor suppressor Wt1 regulates Coronin 1B expression in the epicardium |
| Q59755253 | The deployment of cell lineages that form the mammalian heart |
| Q44693706 | The effects of the WT1 gene on apoptosis and development-related gene expression in porcine kidney fibroblasts and swine testis cells. |
| Q37755436 | The embryonic epicardium: an essential element of cardiac development |
| Q37799410 | The epicardium in cardiac repair: From the stem cell view |
| Q38215321 | The functional diversity of essential genes required for mammalian cardiac development. |
| Q37590421 | The genetics of diabetic nephropathy. |
| Q47395804 | The proepicardium keeps a potential for glomerular marker expression which supports its evolutionary origin from the pronephros |
| Q90637881 | The role of WT1 in breast cancer: clinical implications, biological effects and molecular mechanism |
| Q38015604 | The role of Wt1 in regulating mesenchyme in cancer, development, and tissue homeostasis |
| Q34612490 | The transcription factors Tbx18 and Wt1 control the epicardial epithelial-mesenchymal transition through bi-directional regulation of Slug in murine primary epicardial cells |
| Q36126268 | Tissue specific characterisation of Lim-kinase 1 expression during mouse embryogenesis |
| Q39007418 | Transcriptional Control of Cell Lineage Development in Epicardium-Derived Cells. |
| Q28507766 | Transcriptional regulation by the Wilms tumor protein, Wt1, suggests a role of the metalloproteinase Adamts16 in murine genitourinary development |
| Q90644144 | Transcriptional regulation of cell shape during organ morphogenesis |
| Q38002695 | Vascular differentiation from embryonic stem cells: Novel technologies and therapeutic promises |
| Q30580914 | Visceral and subcutaneous fat have different origins and evidence supports a mesothelial source. |
| Q34028869 | Visualization and Exploration of Conserved Regulatory Modules Using ReXSpecies 2 |
| Q42376448 | WT1 Is Necessary for the Proliferation and Migration of Cells of Renin Lineage Following Kidney Podocyte Depletion. |
| Q45917712 | WT1 Promotes Invasion of NSCLC via Suppression of CDH1 |
| Q37721627 | WT1 expression in breast cancer disrupts the epithelial/mesenchymal balance of tumour cells and correlates with the metabolic response to docetaxel |
| Q58093530 | WT1 expression in vessels varies with histopathological grade in tumour-bearing and control tissue from patients with breast cancer |
| Q37940867 | WT1 in disease: shifting the epithelial-mesenchymal balance. |
| Q34924201 | WT1 promotes cell proliferation in non-small cell lung cancer cell lines through up-regulating cyclin D1 and p-pRb in vitro and in vivo |
| Q42100794 | WT1 regulates epicardial epithelial to mesenchymal transition through β-catenin and retinoic acid signaling pathways. |
| Q35228902 | WT1 targets Gas1 to maintain nephron progenitor cells by modulating FGF signals |
| Q92314698 | Wilms Tumor 1b Expression Defines a Pro-regenerative Macrophage Subtype and Is Required for Organ Regeneration in the Zebrafish |
| Q48098460 | Wilms Tumor 1b defines a wound-specific sheath cell subpopulation associated with notochord repair. |
| Q34248627 | Wilms tumor 1 (WT1) regulates KRAS-driven oncogenesis and senescence in mouse and human models. |
| Q35206917 | Wilms' tumor protein induces an epithelial-mesenchymal hybrid differentiation state in clear cell renal cell carcinoma |
| Q47948619 | Wilms' tumour 1 (WT1) in development, homeostasis and disease. |
| Q39660484 | Wilms' tumour protein Wt1 stimulates transcription of the gene encoding vascular endothelial cadherin |
| Q35095712 | Wilms' tumours: about tumour suppressor genes, an oncogene and a chameleon gene |
| Q34232889 | Wnt1/βcatenin injury response activates the epicardium and cardiac fibroblasts to promote cardiac repair. |
| Q33821188 | Wt1 and retinoic acid signaling in the subcoelomic mesenchyme control the development of the pleuropericardial membranes and the sinus horns. |
| Q36271500 | Wt1 and β-catenin cooperatively regulate diaphragm development in the mouse |
| Q42052856 | Wt1 controls retinoic acid signalling in embryonic epicardium through transcriptional activation of Raldh2. |
| Q43509449 | Wt1 functions in ovarian follicle development by regulating granulosa cell differentiation |
| Q38163312 | Wt1 in the kidney--a tale in mouse models. |
| Q35834732 | Wt1, the mesothelium and the origins and heterogeneity of visceral fat progenitors |
| Q45765307 | Wt1-expressing progenitors contribute to multiple tissues in the developing lung |
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