Models of biological pattern formation: from elementary steps to the organization of embryonic axes.
about
Bare bones pattern formation: a core regulatory network in varying geometries reproduces major features of vertebrate limb development and evolutionThe chick somitogenesis oscillator is arrested before all paraxial mesoderm is segmented into somitesTarget morphology and cell memory: a model of regenerative pattern formationCaudal regulates the spatiotemporal dynamics of pair-rule waves in TriboliumInferring regulatory networks from experimental morphological phenotypes: a computational method reverse-engineers planarian regenerationPhysico-genetic determinants in the evolution of developmentThe pattern of a specimen of Pycnogonum litorale (Arthropoda, Pycnogonida) with a supernumerary leg can be explained with the "boundary model" of appendage formationUnderstanding complex host-microbe interactions in HydraNeutrality and robustness in evo-devo: emergence of lateral inhibitionCritical waves and the length problem of biology.Self-organization of intracellular gradients during mitosis.Cell stimulation with optically manipulated microsourcesMib-Jag1-Notch signalling regulates patterning and structural roles of the notochord by controlling cell-fate decisions.Directional decisions during neutrophil chemotaxis inside bifurcating channels.Modeling heterocyst pattern formation in cyanobacteria.Brg1 chromatin remodeling ATPase balances germ layer patterning by amplifying the transcriptional burst at midblastula transition.Stem cell-specific activation of an ancestral myc protooncogene with conserved basic functions in the early metazoan HydraEmerging patterns in planarian regenerationDynamic patterning at the pylorus: formation of an epithelial intestine-stomach boundary in late fetal life.Modeling bistable cell-fate choices in the Drosophila eye: qualitative and quantitative perspectives.A feedback quenched oscillator produces turing patterning with one diffuser.Interpretation of the UPD/JAK/STAT morphogen gradient in Drosophila follicle cells.Models for the generation and interpretation of gradients.Chromatin-based mechanisms of renal epithelial differentiationMicrofluidic technologies for temporal perturbations of chemotaxis.On a model of pattern regeneration based on cell memory.A Model for Selection of Eyespots on Butterfly WingsABC Transporter Required for Intercellular Transfer of Developmental Signals in a Heterocystous CyanobacteriumEvolution of domain promiscuity in eukaryotic genomes--a perspective from the inferred ancestral domain architectures.Qualitative Dynamical Modelling Can Formally Explain Mesoderm Specification and Predict Novel Developmental PhenotypesMorphogene adsorption as a Turing instability regulator: Theoretical analysis and possible applications in multicellular embryonic systemsBiased inheritance of the protein PatN frees vegetative cells to initiate patterned heterocyst differentiation.Automated numerical simulation of biological pattern formation based on visual feedback simulation framework.Structural insights into HetR-PatS interaction involved in cyanobacterial pattern formation.Stem cell systems and regeneration in planaria.Collagen IX is required for the integrity of collagen II fibrils and the regulation of vascular plexus formation in zebrafish caudal fins.Dioxin causes ventral prostate agenesis by disrupting dorsoventral patterning in developing mouse prostate.Formation and maintenance of nitrogen-fixing cell patterns in filamentous cyanobacteria.Wnt/beta-catenin and noncanonical Wnt signaling interact in tissue evagination in the simple eumetazoan HydraAdaptive-control model for neutrophil orientation in the direction of chemical gradients.
P2860
Q21136351-20E617C5-69D8-4B95-8BEF-BEF6B8F62EE5Q21284152-38534F2B-0681-4C9D-A986-DBA81CBF6E89Q26764980-452A9D9E-E3D2-432C-840B-0A0ED2C1077DQ27312680-155D2087-872B-44CE-A564-18A10644DE07Q27318756-955E20DF-22FC-45C0-8C1F-F00CFECDDEEFQ28277090-93A95489-2106-4252-A11D-34737110B2E0Q28601665-0E0AC584-F4B2-4511-8B6D-CA8BBC3BEECFQ28727343-60DAD68D-7456-4FAA-AA07-E1CD55F47B5FQ28756627-27A8BF59-F829-4BB4-BFF1-F0E077785A5FQ30404303-4702C6D6-7429-4FBC-9A4A-8D788E1733FCQ30436979-B42BE9E6-5896-4B7D-98D2-C9D8E1D5D635Q30492942-3321D023-6982-4878-BD6A-C78C7592F6AFQ30496248-79521779-674D-47CE-B83C-CB3C3EC6D9F8Q30497644-E584E2B3-02CE-4459-93C1-051F4AEAEB72Q33469858-808925E2-5B6F-4A05-9E79-4CA8B12504FCQ33674740-06C4DAAB-114D-4948-B38C-1B627DA7416DQ33732822-26474C3B-7918-4042-90FA-ACDCDCE3A0E8Q33899986-2E167B6B-2C40-44EE-BE4B-045161B0B0F9Q34082932-7348085B-B0EE-4B4B-BA19-3DAE85B84CAEQ34122241-F9B5E8A9-D63E-43E8-A8B4-1E34865FE8B4Q34145635-FF2A253E-5540-4CAA-8776-849D2A64F25AQ34495717-B89ED8FA-0104-4EEE-86B3-139BD832010AQ34615614-05F10C36-BA7A-4939-845A-82D4A85023F0Q35108850-F6F17EF3-7FFA-4876-97E7-C2CF334FE924Q35157430-4C475D6C-25F9-4561-B439-793668545C21Q35563829-8B4B6004-25E5-43A3-8BBD-D5241EDE2538Q35832207-0748F265-7D3F-4D6E-8049-C3AFE9C67C3FQ35866003-CDA88738-A0CC-42E7-9FEF-38E941BC9246Q35875108-93E24D9C-7728-41CE-9810-0F2E782F7FD2Q36124152-6E4E88C3-7078-4E7A-ADE3-D53B5F604E62Q36272965-3A5D4DF4-2634-4E1E-A441-3747478E9DBAQ36279803-BBDF8190-3682-4DCB-B6E3-22DA945449E7Q36287509-A4578043-DD7E-4260-BAB4-F758B5AEF5DAQ36291493-544D28B6-4711-4C7C-AC0F-1862FCBDC6A0Q36554663-3CD6BA97-6F52-459B-8BDA-43217E7862BBQ36949466-3E0AF71C-2242-4511-9514-8B2F5FD218FEQ36968703-C940A24A-5440-4060-A4BC-884F36B09642Q36978152-BB194A3D-7BEE-4200-980C-64108B3263EDQ37106903-C50F53C4-76C3-44AE-80EA-42507A89B76AQ37265574-10BA6BF7-AF65-4893-9F66-936148C5E8CB
P2860
Models of biological pattern formation: from elementary steps to the organization of embryonic axes.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on January 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Models of biological pattern f ...... rganization of embryonic axes.
@en
Models of biological pattern f ...... rganization of embryonic axes.
@nl
type
label
Models of biological pattern f ...... rganization of embryonic axes.
@en
Models of biological pattern f ...... rganization of embryonic axes.
@nl
prefLabel
Models of biological pattern f ...... rganization of embryonic axes.
@en
Models of biological pattern f ...... rganization of embryonic axes.
@nl
P1476
Models of biological pattern f ...... rganization of embryonic axes.
@en
P2093
Hans Meinhardt
P356
10.1016/S0070-2153(07)81001-5
P577
2008-01-01T00:00:00Z