about
Minimum information specification for in situ hybridization and immunohistochemistry experiments (MISFISHIE)New genes in the evolution of the neural crest differentiation programGenetic networks governing heart development.Close association of olfactory placode precursors and cranial neural crest cells does not predestine cell mixing.Point mutations in murine Nkx2-5 phenocopy human congenital heart disease and induce pathogenic Wnt signaling.Cardiac gene expression data and in silico analysis provide novel insights into human and mouse taste receptor gene regulation.Large-scale expression screening by automated whole-mount in situ hybridization.Evolutionary relationships and diversification of barhl genes within retinal cell lineages.Defining the earliest step of cardiovascular progenitor specification during embryonic stem cell differentiation.Tyrosine phosphorylation of LRP6 by Src and Fer inhibits Wnt/β-catenin signalling.Drosophila Hrp48 Is Required for Mushroom Body Axon Growth, Branching and Guidance.NKX2-5 mutations causative for congenital heart disease retain functionality and are directed to hundreds of targets.Development of the Minimum Information Specification for In Situ Hybridization and Immunohistochemistry Experiments (MISFISHIE).Combinatorial Ranking of Gene Sets to Predict Disease Relapse: The Retinoic Acid Pathway in Early Prostate Cancer.Nlcam modulates midline convergence during anterior neural plate morphogenesis.MEPD: a resource for medaka gene expression patterns.GSD: a genetic screen database.Multi-Cellular Transcriptional Analysis of Mammalian Heart Regeneration.Formation of the Embryonic Head in the Mouse: Attributes of a Gene Regulatory Network.MEPD: a Medaka gene expression pattern database.Expression profiling in mouse fetal thymus reveals clusters of coordinately expressed genes that mark individual stages of T-cell ontogeny.Germline Stem Cell Activity Is Sustained by SALL4-Dependent Silencing of Distinct Tumor Suppressor Genes.Rapid identification of PAX2/5/8 direct downstream targets in the otic vesicle by combinatorial use of bioinformatics toolsCis-regulatory properties of medaka synexpression groups.Imp promotes axonal remodeling by regulating profilin mRNA during brain development.Asymmetric inheritance of the apical domain and self-renewal of retinal ganglion cell progenitors depend on Anillin function.Haematopoietic stem cell induction by somite-derived endothelial cells controlled by meox1.Cell Type of Origin Dictates the Route to Pluripotency.Identification of starmaker-like in medaka as a putative target gene of Pax2 in the otic vesicle.A novel conditional mouse model for Nkx2-5 reveals transcriptional regulation of cardiac ion channels.Analysis of steric effects in DamID profiling of transcription factor target genes.Using Trawler_standalone to discover overrepresented motifs in DNA and RNA sequences derived from various experiments including chromatin immunoprecipitation.Trawler: de novo regulatory motif discovery pipeline for chromatin immunoprecipitation.A systematic genome-wide screen for mutations affecting organogenesis in Medaka, Oryzias latipes.TrawlerWeb: an online de novo motif discovery tool for next-generation sequencing datasets.The Intercellular Tight Junction and Spontaneous Coronary Artery DissectionControl of cardiac jelly dynamics by NOTCH1 and NRG1 defines the building plan for trabeculationA gene regulatory network anchored by LIM homeobox 1 for embryonic head developmentMetformin intervention prevents cardiac dysfunction in a murine model of adult congenital heart disease
P50
Q28652074-6F4A7DE6-176D-4863-8584-368FCF27609EQ28757719-994BE08E-CB59-4CE2-BDD9-F1752BF7B9A6Q30367427-FAB59421-BCF1-4C99-B7B0-FD5DD7EBEE04Q30600822-47173E09-BC8E-48C1-BC18-FB1A1A6F8471Q30842375-7865C0E9-1DC7-4932-B9FE-4B921FF0527FQ30953728-EF291EF4-1527-445C-A075-A8BC3815E610Q33204085-13AFC325-A733-496D-8C9E-A619285BE448Q34079567-FFAFB0D6-0CDB-4699-BD55-B2BF9FADFB5FQ34637818-F73EC6E1-4FB9-4869-8550-C1EF00945220Q34691362-83834D39-F20A-455C-ADFB-D8A31508B204Q35757497-F7E66F95-9CDD-4BCD-80C9-8BE7492CD763Q35992694-F97AE785-269D-4286-8E30-DA476D3BA982Q36562145-D23A8C30-6943-4EF5-80A5-39F94579FB5EQ37699583-16F27499-FF83-4258-90C6-6BE7DC011F4CQ38348109-FB158A87-F23A-44C5-8F66-C29549E8ECD7Q38520472-75713A13-6FD6-4B9F-A47E-4CE6464CDF0FQ38521864-B5707685-BD75-4D54-A0A8-0AC6A9939FEFQ38667300-062E7D1D-23AE-4004-9BB0-D038D11A12DFQ38771245-DFF34386-0E87-41E5-83C1-984525B674A0Q39790203-2E66D184-1ADC-4D27-93BA-1C9B58D82D84Q40695842-B4E1E3D8-EA8C-4FFA-ABDC-B305032347BAQ41061883-F48FA24E-5414-4C45-945B-06023D432DEAQ41978654-8D62647B-91D7-455E-A8A0-619E41485872Q42635551-9009F531-641B-4A2E-9B8D-B339367024DFQ47071157-E8D5585B-4499-438D-841A-D381022750BCQ47073222-CBAF8DAF-56A1-434B-9062-B864D0B635CFQ47073786-7D503753-58D6-4BCE-A0E8-9BC8542EB543Q50048760-06A1FD13-CCD2-48CD-8CAE-E7B2FA50D6A3Q50442296-C0CD0CDB-D5F3-4B3E-BF4F-5F5C10417B0FQ50531992-EE397072-07EB-4ECE-A6A3-6D98585D4460Q51140890-D0AAB1EF-FFF0-44C9-900A-D2E2D2237AD2Q51560425-BB4E5B15-9511-4EA2-B148-951ACD49D7FFQ51579438-10C3505E-3D39-4171-B50A-962F8BC19C6CQ52089032-7D43AE5B-D181-4806-B011-345650380A59Q52604175-57AE1DC0-C09B-43F9-8D2C-FE297ACE71E3Q57046892-35794D7C-1280-403B-AA14-09F9958F7FEDQ58378734-2B6156A3-DB87-4FED-BF31-6647E35486E7Q90980395-FD1387AB-9867-47E2-A963-96C6DF450D7AQ93347609-9608D2A0-9D29-4195-94E3-C17B754ABBCD
P50
description
hulumtuese
@sq
researcher
@en
ricercatrice
@it
wetenschapper
@nl
հետազոտող
@hy
name
Mirana Ramialison
@ast
Mirana Ramialison
@en
Mirana Ramialison
@es
Mirana Ramialison
@nl
Mirana Ramialison
@sl
type
label
Mirana Ramialison
@ast
Mirana Ramialison
@en
Mirana Ramialison
@es
Mirana Ramialison
@nl
Mirana Ramialison
@sl
prefLabel
Mirana Ramialison
@ast
Mirana Ramialison
@en
Mirana Ramialison
@es
Mirana Ramialison
@nl
Mirana Ramialison
@sl
P214
P106
P1153
8892483000
P21
P214
P31
P496
0000-0001-6315-4777
P7859
viaf-30763634