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Identification and characterization of myeloid cells localized in the tadpole liver cortex in Xenopus laevis. , Maéno M., Dev Comp Immunol. July 1, 2024; 156 105178.
Fibronectin type III and intracellular domains of Toll-like receptor 4 interactor with leucine-rich repeats (Tril) are required for developmental signaling. , Kim HS ., Mol Biol Cell. March 1, 2018; 29 (5): 523-531.
Adipose tissue macrophages develop from bone marrow-independent progenitors in Xenopus laevis and mouse. , Hassnain Waqas SF., J Leukoc Biol. September 1, 2017; 102 (3): 845-855.
Dissecting BMP signaling input into the gene regulatory networks driving specification of the blood stem cell lineage. , Kirmizitas A., Proc Natl Acad Sci U S A. June 6, 2017; 114 (23): 5814-5821.
The embryonic origins and genetic programming of emerging haematopoietic stem cells. , Ciau-Uitz A ., FEBS Lett. November 1, 2016; 590 (22): 4002-4015.
Tril targets Smad7 for degradation to allow hematopoietic specification in Xenopus embryos. , Green YS., Development. November 1, 2016; 143 (21): 4016-4026.
Identification of genes expressed in the migrating primitive myeloid lineage of Xenopus laevis. , Agricola ZN., Dev Dyn. January 1, 2016; 245 (1): 47-55.
Expression pattern of bcar3, a downstream target of Gata2, and its binding partner, bcar1, during Xenopus development. , Green YS., Gene Expr Patterns. January 1, 2016; 20 (1): 55-62.
The Proto-oncogene Transcription Factor Ets1 Regulates Neural Crest Development through Histone Deacetylase 1 to Mediate Output of Bone Morphogenetic Protein Signaling. , Wang C ., J Biol Chem. September 4, 2015; 290 (36): 21925-38.
NAD kinase controls animal NADP biosynthesis and is modulated via evolutionarily divergent calmodulin-dependent mechanisms. , Love NR ., Proc Natl Acad Sci U S A. February 3, 2015; 112 (5): 1386-91.
Nkx2.5 is involved in myeloid cell differentiation at anterior ventral blood islands in the Xenopus embryo. , Sakata H., Dev Growth Differ. October 1, 2014; 56 (8): 544-54.
Gtpbp2 is required for BMP signaling and mesoderm patterning in Xenopus embryos. , Kirmizitas A., Dev Biol. August 15, 2014; 392 (2): 358-67.
Characterization of the insulin-like growth factor binding protein family in Xenopus tropicalis. , Haramoto Y ., Int J Dev Biol. January 1, 2014; 58 (9): 705-11.
zfp36 expression delineates both myeloid cells and cells localized to the fusing neural folds in Xenopus tropicalis. , Noiret M ., Int J Dev Biol. January 1, 2014; 58 (10-12): 751-5.
BMP-mediated specification of the erythroid lineage suppresses endothelial development in blood island precursors. , Myers CT., Blood. December 5, 2013; 122 (24): 3929-39.
In vivo T-box transcription factor profiling reveals joint regulation of embryonic neuromesodermal bipotency. , Gentsch GE ., Cell Rep. September 26, 2013; 4 (6): 1185-96.
VEGFA-dependent and -independent pathways synergise to drive Scl expression and initiate programming of the blood stem cell lineage in Xenopus. , Ciau-Uitz A ., Development. June 1, 2013; 140 (12): 2632-42.
Regulation of primitive hematopoiesis by class I histone deacetylases. , Shah RR., Dev Dyn. February 1, 2013; 242 (2): 108-21.
Uncoupling VEGFA functions in arteriogenesis and hematopoietic stem cell specification. , Leung A., Dev Cell. January 28, 2013; 24 (2): 144-58.
Hippo signaling components, Mst1 and Mst2, act as a switch between self-renewal and differentiation in Xenopus hematopoietic and endothelial progenitors. , Nejigane S., Int J Dev Biol. January 1, 2013; 57 (5): 407-14.
Characterization and expressional analysis of Dleu7 during Xenopus tropicalis embryogenesis. , Zhu X., Gene. November 1, 2012; 509 (1): 77-84.
The role of heterodimeric AP-1 protein comprised of JunD and c- Fos proteins in hematopoiesis. , Lee SY., J Biol Chem. September 7, 2012; 287 (37): 31342-8.
Sizzled- tolloid interactions maintain foregut progenitors by regulating fibronectin-dependent BMP signaling. , Kenny AP ., Dev Cell. August 14, 2012; 23 (2): 292-304.
Distinct mechanisms control the timing of differentiation of two myeloid populations in Xenopus ventral blood islands. , Maéno M., Dev Growth Differ. February 1, 2012; 54 (2): 187-201.
Xenopus er71 is involved in vascular development. , Neuhaus H ., Dev Dyn. December 1, 2010; 239 (12): 3436-45.
Wnt/beta-catenin signaling is involved in the induction and maintenance of primitive hematopoiesis in the vertebrate embryo. , Tran HT., Proc Natl Acad Sci U S A. September 14, 2010; 107 (37): 16160-5.
Tel1/ ETV6 specifies blood stem cells through the agency of VEGF signaling. , Ciau-Uitz A ., Dev Cell. April 20, 2010; 18 (4): 569-78.
Systematic discovery of nonobvious human disease models through orthologous phenotypes. , McGary KL., Proc Natl Acad Sci U S A. April 6, 2010; 107 (14): 6544-9.
Ectophosphodiesterase/nucleotide phosphohydrolase (Enpp) nucleotidases: cloning, conservation and developmental restriction. , Massé K ., Int J Dev Biol. January 1, 2010; 54 (1): 181-93.
XRASGRP2 is essential for blood vessel formation during Xenopus development. , Suzuki K., Int J Dev Biol. January 1, 2010; 54 (4): 609-15.
Genetic control of hematopoietic development in Xenopus and zebrafish. , Ciau-Uitz A ., Int J Dev Biol. January 1, 2010; 54 (6-7): 1139-49.
Heme metabolism enzymes are dynamically expressed during Xenopus embryonic development. , Shi J., Biocell. December 1, 2008; 32 (3): 259-63.
The Wnt signaling regulator R-spondin 3 promotes angioblast and vascular development. , Kazanskaya O., Development. November 1, 2008; 135 (22): 3655-64.
spib is required for primitive myeloid development in Xenopus. , Costa RM ., Blood. September 15, 2008; 112 (6): 2287-96.
Fli1 acts at the top of the transcriptional network driving blood and endothelial development. , Liu F., Curr Biol. August 26, 2008; 18 (16): 1234-40.
Investigations of the effects of the antimalarial drug dihydroartemisinin (DHA) using the Frog Embryo Teratogenesis Assay-Xenopus (FETAX). , Longo M., Reprod Toxicol. August 1, 2008; 25 (4): 433-41.
Crossveinless-2 Is a BMP feedback inhibitor that binds Chordin/BMP to regulate Xenopus embryonic patterning. , Ambrosio AL., Dev Cell. August 1, 2008; 15 (2): 248-60.
CD41+ cmyb+ precursors colonize the zebrafish pronephros by a novel migration route to initiate adult hematopoiesis. , Bertrand JY., Development. May 1, 2008; 135 (10): 1853-62.
HIF-1alpha signaling upstream of NKX2.5 is required for cardiac development in Xenopus. , Nagao K., J Biol Chem. April 25, 2008; 283 (17): 11841-9.
Fibroblast growth factor controls the timing of Scl, Lmo2, and Runx1 expression during embryonic blood development. , Walmsley M., Blood. February 1, 2008; 111 (3): 1157-66.
Expression of complement components coincides with early patterning and organogenesis in Xenopus laevis. , McLin VA ., Int J Dev Biol. January 1, 2008; 52 (8): 1123-33.
Redundancy and evolution of GATA factor requirements in development of the myocardium. , Peterkin T., Dev Biol. November 15, 2007; 311 (2): 623-35.
The opposing homeobox genes Goosecoid and Vent1/2 self-regulate Xenopus patterning. , Sander V., EMBO J. June 20, 2007; 26 (12): 2955-65.
FGF4 regulates blood and muscle specification in Xenopus laevis. , Isaacs HV ., Biol Cell. March 1, 2007; 99 (3): 165-73.
STAT5 acts as a repressor to regulate early embryonic erythropoiesis. , Schmerer M., Blood. November 1, 2006; 108 (9): 2989-97.
Characterization of myeloid cells derived from the anterior ventral mesoderm in the Xenopus laevis embryo. , Tashiro S., Dev Growth Differ. October 1, 2006; 48 (8): 499-512.
The effect of VEGF on blood vessels and blood cells during Xenopus development. , Koibuchi N., Biochem Biophys Res Commun. May 26, 2006; 344 (1): 339-45.
Cloning and expression pattern of the Xenopus erythropoietin receptor. , Yergeau DA., Gene Expr Patterns. April 1, 2006; 6 (4): 420-5.
Zygotic nucleosome assembly protein-like 1 has a specific, non-cell autonomous role in hematopoiesis. , Abu-Daya A., Blood. July 15, 2005; 106 (2): 514-20.
Phylogenomic analysis and expression patterns of large Maf genes in Xenopus tropicalis provide new insights into the functional evolution of the gene family in osteichthyans. , Coolen M., Dev Genes Evol. July 1, 2005; 215 (7): 327-39.