| scholarly article | Q13442814 |
| P2093 | author name string | Sharon L Amacher | |
| Clarissa A Henry | |||
| Sarah E Munchel | |||
| Ian M McNulty | |||
| Wendy A Durst | |||
| P2860 | cites work | Inhibition of Hedgehog signaling by direct binding of cyclopamine to Smoothened | Q24682703 |
| Stages of embryonic development of the zebrafish | Q27860947 | ||
| Hedgehog signaling in animal development: paradigms and principles | Q28208463 | ||
| The winged helix transcription factor Foxc1a is essential for somitogenesis in zebrafish | Q28354363 | ||
| Dynamic expression and essential functions of Hes7 in somite segmentation | Q28593057 | ||
| Mind bomb is a ubiquitin ligase that is essential for efficient activation of Notch signaling by Delta | Q28646258 | ||
| Mechanisms of convergence and extension by cell intercalation | Q30306607 | ||
| The dystrophin associated protein complex in zebrafish | Q31134324 | ||
| Myotome formation: a multistage process | Q33592112 | ||
| Induction of a specific muscle cell type by a hedgehog-like protein in zebrafish. | Q34387036 | ||
| Catching a wave: the oscillator and wavefront that create the zebrafish somite | Q35018076 | ||
| The segmentation clock: converting embryonic time into spatial pattern | Q35180352 | ||
| Activity and distribution of paxillin, focal adhesion kinase, and cadherin indicate cooperative roles during zebrafish morphogenesis | Q35670172 | ||
| Positive and negative regulation of muscle cell identity by members of the hedgehog and TGF-beta gene families | Q38529559 | ||
| Notochord induction of zebrafish slow muscle mediated by Sonic hedgehog. | Q40240062 | ||
| The u-boot mutation identifies a Hedgehog-regulated myogenic switch for fiber-type diversification in the zebrafish embryo | Q40424101 | ||
| The generation and interpretation of positional information within the vertebrate myotome | Q41739871 | ||
| Cooperative function of deltaC and her7 in anterior segment formation | Q42055406 | ||
| Roles for zebrafish focal adhesion kinase in notochord and somite morphogenesis | Q42515459 | ||
| Zebrafish deadly seven functions in neurogenesis | Q43728547 | ||
| Cell lineages generating axial muscle in the zebrafish embryo | Q43962287 | ||
| Structure and spatio temporal expression of the full length DNA complementary to RNA coding for alpha2 type I collagen of zebrafish | Q44138288 | ||
| Multiple muscle cell identities induced by distinct levels and timing of hedgehog activity in the zebrafish embryo | Q44515860 | ||
| Anterior and posterior waves of cyclic her1 gene expression are differentially regulated in the presomitic mesoderm of zebrafish | Q44538271 | ||
| Zebrafish slow muscle cell migration induces a wave of fast muscle morphogenesis. | Q46024298 | ||
| Cell dynamics during somite boundary formation revealed by time-lapse analysis | Q46364804 | ||
| Dystrophin is required for the formation of stable muscle attachments in the zebrafish embryo | Q47073103 | ||
| Zebrafish periostin is required for the adhesion of muscle fiber bundles to the myoseptum and for the differentiation of muscle fibers | Q47073127 | ||
| Somites in zebrafish doubly mutant for knypek and trilobite form without internal mesenchymal cells or compaction | Q47073364 | ||
| Control of muscle cell-type specification in the zebrafish embryo by Hedgehog signalling | Q47073631 | ||
| Integrinalpha5-dependent fibronectin accumulation for maintenance of somite boundaries in zebrafish embryos. | Q47073725 | ||
| Hedgehog signaling is required for commitment but not initial induction of slow muscle precursors. | Q47073821 | ||
| Integrinalpha5 and delta/notch signaling have complementary spatiotemporal requirements during zebrafish somitogenesis | Q47074170 | ||
| lunatic fringe is an essential mediator of somite segmentation and patterning | Q47741550 | ||
| Defects in somite formation in lunatic fringe-deficient mice | Q47741558 | ||
| Tbx24, encoding a T-box protein, is mutated in the zebrafish somite-segmentation mutant fused somites | Q48303847 | ||
| Amphibian (urodele) myotomes display transitory anterior/posterior and medial/lateral differentiation patterns | Q48653968 | ||
| Hedgehog signalling is required for maintenance of myf5 and myoD expression and timely terminal differentiation in zebrafish adaxial myogenesis | Q49296468 | ||
| Cadherin-mediated differential cell adhesion controls slow muscle cell migration in the developing zebrafish myotome. | Q52096461 | ||
| Periodic notch inhibition by lunatic fringe underlies the chick segmentation clock. | Q52110194 | ||
| Vertebrate segmentation: the clock is linked to Notch signalling. | Q52181708 | ||
| Early development of the myotome in the mouse | Q59474187 | ||
| Distinct mechanisms regulate slow-muscle development | Q74535886 | ||
| Analysis of protein and gene expression | Q77802095 | ||
| P433 | issue | 2 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | DeltaC | Q29826191 |
| MIB E3 ubiquitin protein ligase 1 | Q29829641 | ||
| Notch receptor 1a | Q29832533 | ||
| P304 | page(s) | 346-360 | |
| P577 | publication date | 2005-10-12 | |
| P1433 | published in | Developmental Biology | Q3025402 |
| P1476 | title | Interactions between muscle fibers and segment boundaries in zebrafish | |
| P478 | volume | 287 |
| Q30823700 | Alterations in zebrafish development induced by simvastatin: Comprehensive morphological and physiological study, focusing on muscle. |
| Q28483763 | An in vivo method to quantify lymphangiogenesis in zebrafish |
| Q90277963 | Cell fusion is differentially regulated in zebrafish post-embryonic slow and fast muscle |
| Q35863598 | Cellular dynamics underlying regeneration of appropriate segment number during axolotl tail regeneration. |
| Q28654208 | Chevron formation of the zebrafish muscle segments. |
| Q30489382 | Control of morphogenetic cell movements in the early zebrafish myotome |
| Q47074163 | Convergence and extension movements affect dynamic notochord-somite interactions essential for zebrafish slow muscle morphogenesis |
| Q35119127 | Early fish myoseptal cells: insights from the trout and relationships with amniote axial tenocytes |
| Q43746378 | Early transcriptional targets of MyoD link myogenesis and somitogenesis |
| Q47073815 | FoxD5 mediates anterior-posterior polarity through upstream modulator Fgf signaling during zebrafish somitogenesis |
| Q34315727 | Fss/Tbx6 is required for central dermomyotome cell fate in zebrafish |
| Q28087402 | Hanging on for the ride: adhesion to the extracellular matrix mediates cellular responses in skeletal muscle morphogenesis and disease |
| Q37400109 | Identification of novel MYO18A interaction partners required for myoblast adhesion and muscle integrity. |
| Q40464531 | Lack of Apobec2-related proteins causes a dystrophic muscle phenotype in zebrafish embryos |
| Q47074096 | Loss of selenoprotein N function causes disruption of muscle architecture in the zebrafish embryo. |
| Q30514269 | Macondo crude oil from the Deepwater Horizon oil spill disrupts specific developmental processes during zebrafish embryogenesis. |
| Q34618902 | Micromechanical function of myofibrils isolated from skeletal and cardiac muscles of the zebrafish |
| Q36743458 | Misty somites, a maternal effect gene identified by transposon-mediated insertional mutagenesis in zebrafish that is essential for the somite boundary maintenance. |
| Q91872133 | Mitochondria in Embryogenesis: An Organellogenesis Perspective |
| Q36946759 | Muscle development is disrupted in zebrafish embryos deficient for fibronectin |
| Q42568079 | Nrk2b-mediated NAD+ production regulates cell adhesion and is required for muscle morphogenesis in vivo: Nrk2b and NAD+ in muscle morphogenesis |
| Q39532908 | Obscurin depletion impairs organization of skeletal muscle in developing zebrafish embryos |
| Q47073677 | Paxillin genes and actomyosin contractility regulate myotome morphogenesis in zebrafish. |
| Q46430829 | Posterior tail development in the salamander Eurycea cirrigera: exploring cellular dynamics across life stages |
| Q28710338 | Rbfox-regulated alternative splicing is critical for zebrafish cardiac and skeletal muscle functions |
| Q34109905 | Rbm24a and Rbm24b are required for normal somitogenesis |
| Q37608203 | Restricted expression of cdc25a in the tailbud is essential for formation of the zebrafish posterior body |
| Q30528453 | Single-cell-resolution imaging of the impact of Notch signaling and mitosis on segmentation clock dynamics |
| Q42567161 | Sonic hedgehog-dependent synthesis of laminin alpha1 controls basement membrane assembly in the myotome |
| Q27335506 | Structural analysis of alterations in zebrafish muscle differentiation induced by simvastatin and their recovery with cholesterol. |
| Q36593638 | Structure and function of skeletal muscle in zebrafish early larvae |
| Q50320049 | TM4SF5 suppression disturbs integrin α5-related signalling and muscle development in zebrafish |
| Q26775671 | Tendon development and musculoskeletal assembly: emerging roles for the extracellular matrix |
| Q21195909 | The Middle Cambrian fossil Pikaia and the evolution of chordate swimming |
| Q30540461 | The Popeye domain containing 2 (popdc2) gene in zebrafish is required for heart and skeletal muscle development |
| Q33693423 | The Role of Sdf-1α signaling in Xenopus laevis somite morphogenesis |
| Q36814549 | The genetics and embryology of zebrafish metamerism |
| Q27318301 | The methyltransferases PRMT4/CARM1 and PRMT5 control differentially myogenesis in zebrafish |
| Q39252349 | The role of the SPT6 chromatin remodeling factor in zebrafish embryogenesis |
| Q33896985 | Thrombospondin-4 controls matrix assembly during development and repair of myotendinous junctions |
| Q27313686 | Time-lapse analysis and mathematical characterization elucidate novel mechanisms underlying muscle morphogenesis |
| Q42267674 | Using the zebrafish to understand tendon development and repair |
| Q47073466 | Zebrafish cypher is important for somite formation and heart development |
| Q41225317 | microRNA-206 modulates an Rtn4a/Cxcr4a/Thbs3a axis in newly forming somites to maintain and stabilize the somite boundary formation of zebrafish embryos |
Search more.