scholarly article | Q13442814 |
review article | Q7318358 |
P356 | DOI | 10.1016/S1050-1738(01)00069-X |
P698 | PubMed publication ID | 11369261 |
P2093 | author name string | S Kitajima | |
S Miyagawa-Tomita | |||
Y Saga | |||
P433 | issue | 8 | |
P921 | main subject | circulatory system | Q11068 |
P304 | page(s) | 345-352 | |
P577 | publication date | 2000-11-01 | |
P1433 | published in | Trends in Cardiovascular Medicine | Q1850265 |
P1476 | title | Mesp1 expression is the earliest sign of cardiovascular development | |
P478 | volume | 10 |
Q125290111 | A Mesp1-dependent developmental breakpoint in transcriptional and epigenomic specification of early cardiac precursors |
Q34442122 | A boolean model of the cardiac gene regulatory network determining first and second heart field identity |
Q38452154 | A comprehensive gene expression analysis at sequential stages of in vitro cardiac differentiation from isolated MESP1-expressing-mesoderm progenitors |
Q38072446 | A molecular and genetic outline of cardiac morphogenesis. |
Q102319892 | Alterations of 5-hydroxymethylcytosines in circulating cell-free DNA reflect retinopathy in type 2 diabetes |
Q37407385 | An FGF autocrine loop initiated in second heart field mesoderm regulates morphogenesis at the arterial pole of the heart |
Q62694350 | BMP and FGF regulate the differentiation of multipotential pericardial mesoderm into the myocardial or epicardial lineage |
Q35808417 | Biphasic role for Wnt/beta-catenin signaling in cardiac specification in zebrafish and embryonic stem cells |
Q36585810 | Braveheart, a long noncoding RNA required for cardiovascular lineage commitment |
Q34200316 | Cardiac Regeneration using Human Embryonic Stem Cells: Producing Cells for Future Therapy |
Q34083167 | Cardiac cell lineages that form the heart |
Q35541868 | Cardiac chamber formation: development, genes, and evolution. |
Q39503213 | Cardiac differentiation in Xenopus is initiated by mespa |
Q48139022 | Cardiogenic programming of human pluripotent stem cells by dose-controlled activation of EOMES. |
Q53295638 | Cardiomyocyte differentiation from mouse embryonic stem cells using a simple and defined protocol. |
Q27303582 | Ciona as a Simple Chordate Model for Heart Development and Regeneration |
Q35062652 | Clonal analysis reveals a common origin between nonsomite-derived neck muscles and heart myocardium |
Q40292898 | Collier/OLF/EBF-dependent transcriptional dynamics control pharyngeal muscle specification from primed cardiopharyngeal progenitors |
Q37259094 | Deciphering the function of canonical Wnt signals in development and disease: conditional loss- and gain-of-function mutations of beta-catenin in mice |
Q34637818 | Defining the earliest step of cardiovascular progenitor specification during embryonic stem cell differentiation |
Q27692614 | Development of the endocardium |
Q35893734 | Development of the endothelium: an emphasis on heterogeneity |
Q37835598 | Developmental and regenerative biology of multipotent cardiovascular progenitor cells |
Q51944236 | Developmental signaling in myocardial progenitor cells: a comprehensive view of Bmp- and Wnt/beta-catenin signaling. |
Q34987196 | Distinct origins and genetic programs of head muscle satellite cells |
Q28648466 | Disturbance of cardiac gene expression and cardiomyocyte structure predisposes Mecp2-null mice to arrhythmias |
Q59133041 | Does cardiac development provide heart research with novel therapeutic approaches? |
Q39066730 | Earlier and broader roles of Mesp1 in cardiovascular development |
Q27336202 | Early activation of FGF and nodal pathways mediates cardiac specification independently of Wnt/beta-catenin signaling |
Q36404968 | Early cardiac development: a view from stem cells to embryos |
Q51978831 | Embryonic cardiomyocyte expression of endothelial genes. |
Q38148527 | Embryonic heart progenitors and cardiogenesis |
Q84167464 | Endocardial cells are a distinct endothelial lineage derived from Flk1+ multipotent cardiovascular progenitors |
Q42554606 | Eomesodermin induces Mesp1 expression and cardiac differentiation from embryonic stem cells in the absence of Activin |
Q36802947 | Epiblastic Cited2 deficiency results in cardiac phenotypic heterogeneity and provides a mechanism for haploinsufficiency |
Q38015278 | Epicardial progenitor cells in cardiac development and regeneration |
Q39821385 | Epicardium and myocardium separate from a common precursor pool by crosstalk between bone morphogenetic protein- and fibroblast growth factor-signaling pathways |
Q36777260 | Essential and unexpected role of Yin Yang 1 to promote mesodermal cardiac differentiation |
Q91130350 | Expansion of Human Pluripotent Stem Cell-derived Early Cardiovascular Progenitor Cells by a Cocktail of Signaling Factors |
Q38842203 | FOXF1 inhibits hematopoietic lineage commitment during early mesoderm specification |
Q38129288 | Fate choice of post-natal mesoderm progenitors: skeletal versus cardiac muscle plasticity |
Q37645871 | Fibronectin signals through integrin α5β1 to regulate cardiovascular development in a cell type-specific manner |
Q39831438 | Forward programming of pluripotent stem cells towards distinct cardiovascular cell types |
Q47073815 | FoxD5 mediates anterior-posterior polarity through upstream modulator Fgf signaling during zebrafish somitogenesis |
Q38018022 | From pluripotency to distinct cardiomyocyte subtypes |
Q38849869 | Genome-Wide Identification of MESP1 Targets Demonstrates Primary Regulation Over Mesendoderm Gene Activity. |
Q26996283 | Getting to the heart of the matter: long non-coding RNAs in cardiac development and disease |
Q93361361 | H19X-encoded miR-424(322)/-503 cluster: emerging roles in cell differentiation, proliferation, plasticity and metabolism |
Q34355325 | Heart fields and cardiac morphogenesis |
Q36929958 | How Mesp1 makes a move. |
Q34130162 | How to make a heart: the origin and regulation of cardiac progenitor cells |
Q41590446 | Id genes are essential for early heart formation |
Q37901523 | Impact of WNT signaling on tissue lineage differentiation in the early mouse embryo |
Q27315974 | Induced pluripotent stem cell-derived cardiac progenitors differentiate to cardiomyocytes and form biosynthetic tissues |
Q24305182 | Induction of MesP1 by Brachyury(T) generates the common multipotent cardiovascular stem cell |
Q38325210 | Initial deployment of the cardiogenic gene regulatory network in the basal chordate, Ciona intestinalis |
Q38749444 | Irx4 Marks a Multipotent, Ventricular-Specific Progenitor Cell |
Q30577359 | Irx4 identifies a chamber-specific cell population that contributes to ventricular myocardium development. |
Q37778540 | Lessons for cardiac regeneration and repair through development |
Q38174018 | Lessons from the heart: mirroring electrophysiological characteristics during cardiac development to in vitro differentiation of stem cell derived cardiomyocytes. |
Q64106692 | MEF2 and the Right Ventricle: From Development to Disease |
Q36604344 | MESP1 Mutations in Patients with Congenital Heart Defects |
Q24316874 | MesP1 drives vertebrate cardiovascular differentiation through Dkk-1-mediated blockade of Wnt-signalling |
Q35709087 | Mesodermal Nkx2.5 is necessary and sufficient for early second heart field development |
Q41014050 | Mesodermal expression of Moz is necessary for cardiac septum development |
Q43002452 | Mesodermal expression of integrin α5β1 regulates neural crest development and cardiovascular morphogenesis |
Q42716957 | Mesodermal mesenchymal cells give rise to myofibroblasts, but not epithelial cells, in mouse liver injury |
Q27318072 | Mesp1 Marked Cardiac Progenitor Cells Repair Infarcted Mouse Hearts |
Q24308875 | Mesp1 acts as a master regulator of multipotent cardiovascular progenitor specification |
Q42766415 | Mesp1 controls the speed, polarity, and directionality of cardiovascular progenitor migration. |
Q41174480 | Mesp1 coordinately regulates cardiovascular fate restriction and epithelial-mesenchymal transition in differentiating ESCs |
Q40464704 | Mesp1 patterns mesoderm into cardiac, hematopoietic, or skeletal myogenic progenitors in a context-dependent manner. |
Q52032861 | Mesp1-nonexpressing cells contribute to the ventricular cardiac conduction system. |
Q36072998 | Microdeletions and microduplications in patients with congenital heart disease and multiple congenital anomalies. |
Q38320233 | Molecular regulation of cardiomyocyte differentiation |
Q63364496 | Multipotent Progenitor Cells in Regenerative Cardiovascular Medicine |
Q42407370 | Multipotent stem cells in cardiac regenerative therapy |
Q37819523 | Myocardial lineage development |
Q37766810 | Origin of cardiac progenitor cells in the developing and postnatal heart |
Q36828639 | Origins and fates of cardiovascular progenitor cells |
Q41910908 | Pcsk5 is required in the early cranio-cardiac mesoderm for heart development |
Q38913781 | Perturbations of heart development and function in cardiomyocytes from human embryonic stem cells with trisomy 21. |
Q33555111 | Precardiac deletion of Numb and Numblike reveals renewal of cardiac progenitors |
Q33775936 | Rapamycin efficiently promotes cardiac differentiation of mouse embryonic stem cells |
Q34399774 | Regenerative medicine for the heart: perspectives on stem-cell therapy |
Q28085666 | Regulation and evolution of cardiopharyngeal cell identity and behavior: insights from simple chordates |
Q28511868 | Required, tissue-specific roles for Fgf8 in outflow tract formation and remodeling |
Q56854260 | Selection of a common multipotent cardiovascular stem cell using the 3.4-kb MesP1 promoter fragment |
Q30568587 | Small molecule-mediated directed differentiation of human embryonic stem cells toward ventricular cardiomyocytes. |
Q42031459 | TGFβ-dependent epithelial-to-mesenchymal transition is required to generate cardiospheres from human adult heart biopsies |
Q33942656 | Tbx5 and Bmp signaling are essential for proepicardium specification in zebrafish |
Q53161929 | Tetrasomy 15q25.2→qter identified with SNP microarray in a patient with multiple anomalies including complex cardiovascular malformation. |
Q90163109 | The Transitional Heart: From Early Embryonic and Fetal Development to Neonatal Life |
Q59755253 | The deployment of cell lineages that form the mammalian heart |
Q38215321 | The functional diversity of essential genes required for mammalian cardiac development. |
Q35306080 | The heart endocardium is derived from vascular endothelial progenitors |
Q34300757 | The histone methyltransferase inhibitor BIX01294 enhances the cardiac potential of bone marrow cells |
Q38258288 | The mysterious pathways of cardiac myxomas: a review of histogenesis, pathogenesis and pathology. |
Q37616278 | The role of secondary heart field in cardiac development |
Q28083681 | The roles of Mesp family proteins: functional diversity and redundancy in differentiation of pluripotent stem cells and mammalian mesodermal development |
Q39580194 | The use of stem cells for the repair of cardiac tissue in ischemic heart disease |
Q38322176 | Tissue engineering approaches to heart repair |
Q37124590 | Tmem88a mediates GATA-dependent specification of cardiomyocyte progenitors by restricting WNT signaling |
Q46393662 | Transcriptomic Profiling Maps Anatomically Patterned Subpopulations among Single Embryonic Cardiac Cells |
Q33999325 | Transcriptomic analysis brings new insight into the biological role of the prion protein during mouse embryogenesis |
Q40205062 | Transient Mesp1 expression: a driver of cardiac cell fate determination |
Q37580197 | Ultrastructural and immunocharacterization of undifferentiated myocardial cells in the developing mouse heart. |
Q83232670 | Unique morphogenetic signatures define mammalian neck muscles and associated connective tissues |
Q35944752 | Wnt5a and Wnt11 are essential for second heart field progenitor development. |
Q37213856 | miR-322/-503 cluster is expressed in the earliest cardiac progenitor cells and drives cardiomyocyte specification |
Q52719597 | β1-integrin is a cell-autonomous factor mediating the Numb pathway for cardiac progenitor maintenance. |
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