| scholarly article | Q13442814 |
| P356 | DOI | 10.1101/GAD.11.14.1827 |
| P8608 | Fatcat ID | release_lemnh67bxjhutkp7o6glbtzlvm |
| P698 | PubMed publication ID | 9242490 |
| P2093 | author name string | Koseki H | |
| Saga Y | |||
| Taketo MM | |||
| Hata N | |||
| P433 | issue | 14 | |
| P304 | page(s) | 1827-1839 | |
| P577 | publication date | 1997-07-01 | |
| P1433 | published in | Genes & Development | Q1524533 |
| P1476 | title | Mesp2: a novel mouse gene expressed in the presegmented mesoderm and essential for segmentation initiation | |
| P478 | volume | 11 |
| Q37902096 | A fluorescence spotlight on the clockwork development and metabolism of bone. |
| Q37246430 | A genomewide survey of basic helix-loop-helix factors in Drosophila |
| Q34173684 | A molecular clock involved in somite segmentation. |
| Q52047954 | A novel signal induces a segmentation fissure by acting in a ventral-to-dorsal direction in the presomitic mesoderm. |
| Q60492559 | A β-catenin gradient links the clock and wavefront systems in mouse embryo segmentation |
| Q36819707 | Abnormal vertebral segmentation and the notch signaling pathway in man. |
| Q36710879 | Activator-to-repressor conversion of T-box transcription factors by the Ripply family of Groucho/TLE-associated mediators |
| Q38834004 | An in vitro gastrulation model recapitulates the morphogenetic impact of pharmacological inhibitors of developmental signaling pathways |
| Q28587304 | Analysis of Ripply1/2-deficient mouse embryos reveals a mechanism underlying the rostro-caudal patterning within a somite |
| Q51994121 | Appropriate suppression of Notch signaling by Mesp factors is essential for stripe pattern formation leading to segment boundary formation. |
| Q37821751 | Boundary formation and maintenance in tissue development |
| Q42596791 | Characterization and expression of a presomitic mesoderm-specific mespo gene in zebrafish |
| Q33287931 | Compartmentalised expression of Delta-like 1 in epithelial somites is required for the formation of intervertebral joints |
| Q33723361 | Congenital and idiopathic scoliosis: clinical and genetic aspects. |
| Q34568331 | Cooperative Mesp activity is required for normal somitogenesis along the anterior-posterior axis |
| Q28606541 | Deep sequencing of Danish Holstein dairy cattle for variant detection and insight into potential loss-of-function variants in protein coding genes |
| Q47741558 | Defects in somite formation in lunatic fringe-deficient mice |
| Q39532078 | Different types of oscillations in Notch and Fgf signaling regulate the spatiotemporal periodicity of somitogenesis |
| Q28265827 | Differentiation of pluripotent stem cells to muscle fiber to model Duchenne muscular dystrophy |
| Q95535244 | Discussion |
| Q28593057 | Dynamic expression and essential functions of Hes7 in somite segmentation |
| Q77527318 | Dynamic expression of chicken cMeso2 in segmental plate and somites |
| Q43115525 | EMBO Workshop Report: Molecular genetics of muscle development and neuromuscular diseases Kloster Irsee, Germany, September 26-October 1, 1999. |
| Q50043698 | ES cell-derived presomitic mesoderm-like tissues for analysis of synchronized oscillations in the segmentation clock |
| Q39066730 | Earlier and broader roles of Mesp1 in cardiovascular development |
| Q27324593 | Efficient and reproducible myogenic differentiation from human iPS cells: prospects for modeling Miyoshi Myopathy in vitro |
| Q24596675 | Eph signaling is required for segmentation and differentiation of the somites |
| Q37183017 | EphrinB2 coordinates the formation of a morphological boundary and cell epithelialization during somite segmentation |
| Q73061524 | Expression of the novel basic-helix-loop-helix transcription factor cMespo in presomitic mesoderm of chicken embryos |
| Q36640840 | FGF signaling induces mesoderm in the hemichordate Saccoglossus kowalevskii |
| Q47073815 | FoxD5 mediates anterior-posterior polarity through upstream modulator Fgf signaling during zebrafish somitogenesis |
| Q21090160 | From dynamic expression patterns to boundary formation in the presomitic mesoderm |
| Q42943636 | Generation of segment polarity in the paraxial mesoderm of the zebrafish through a T-box-dependent inductive event |
| Q30826887 | Genetic regulation of somite formation. |
| Q52184549 | Genetic rescue of segmentation defect in MesP2-deficient mice by MesP1 gene replacement. |
| Q42110086 | Growth differentiation factor 11 signaling controls retinoic acid activity for axial vertebral development |
| Q24290956 | Hes7: a bHLH-type repressor gene regulated by Notch and expressed in the presomitic mesoderm |
| Q50783102 | Heterochrony in somitogenesis rate in a model marsupial, Monodelphis domestica. |
| Q24682789 | Identification and characterization of LMO4, an LMO gene with a novel pattern of expression during embryogenesis |
| Q45023595 | Identification of genes for bone mineral density variation by computational disease gene identification strategy |
| Q42738593 | Identification of oscillatory genes in somitogenesis from functional genomic analysis of a human mesenchymal stem cell model |
| Q28484548 | In vitro modeling of paraxial mesodermal progenitors derived from induced pluripotent stem cells |
| Q91703857 | Induced Pluripotent Stem Cell-Derived Mesenchymal Stromal Cells Are Functionally and Genetically Different From Bone Marrow-Derived Mesenchymal Stromal Cells |
| Q57315074 | Interaction between Notch signalling and Lunatic fringe during somite boundary formation in the mouse |
| Q34075729 | Isolation and characterization of neural crest-derived stem cells from dental pulp of neonatal mice |
| Q28506650 | LEF1-mediated regulation of Delta-like1 links Wnt and Notch signaling in somitogenesis |
| Q28511148 | Localized and transient transcription of Hox genes suggests a link between patterning and the segmentation clock |
| Q39457575 | Loss of orphan receptor germ cell nuclear factor function results in ectopic development of the tail bud and a novel posterior truncation. |
| Q35524555 | MBTPS1/SKI-1/S1P proprotein convertase is required for ECM signaling and axial elongation during somitogenesis and vertebral development†. |
| Q37006667 | Mathematical models for somite formation |
| Q36857740 | Mesenchymal to epithelial transition in development and disease. |
| 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 |
| Q52032861 | Mesp1-nonexpressing cells contribute to the ventricular cardiac conduction system. |
| Q52166230 | Mesp2 initiates somite segmentation through the Notch signalling pathway. |
| Q47958984 | Mespo: a novel basic helix-loop-helix gene expressed in the presomitic mesoderm and posterior tailbud of Xenopus embryos |
| Q50945102 | Metameric pattern of intervertebral disc/vertebral body is generated independently of Mesp2/Ripply-mediated rostro-caudal patterning of somites in the mouse embryo. |
| Q46419557 | Modulation of Notch Signaling During Somitogenesis |
| Q50422140 | Modulation of Phase Shift between Wnt and Notch Signaling Oscillations Controls Mesoderm Segmentation. |
| Q33924408 | Molecular and cellular biology of avian somite development |
| Q40041521 | Molecular diagnosis of vertebral segmentation disorders in humans |
| Q38671655 | Molecular mechanism for cyclic generation of somites: Lessons from mice and zebrafish. |
| Q38951854 | Morphology-based mammalian stem cell tests reveal potential developmental toxicity of donepezil |
| Q51975063 | Mouse Ripply2 is downstream of Wnt3a and is dynamically expressed during somitogenesis. |
| Q24534025 | Mutated MESP2 causes spondylocostal dysostosis in humans |
| Q24540500 | Mutation of the LUNATIC FRINGE gene in humans causes spondylocostal dysostosis with a severe vertebral phenotype |
| Q24323154 | Mutation of the fucose-specific beta1,3 N-acetylglucosaminyltransferase LFNG results in abnormal formation of the spine |
| Q21710714 | Mutations in the MESP2 gene cause spondylothoracic dysostosis/Jarcho-Levin syndrome |
| Q34809773 | Noncyclic Notch activity in the presomitic mesoderm demonstrates uncoupling of somite compartmentalization and boundary formation |
| Q36960089 | Notch Signaling and the Skeleton |
| Q33745098 | Notch around the clock |
| Q28590793 | Notch is a critical component of the mouse somitogenesis oscillator and is essential for the formation of the somites |
| Q27021132 | Notch regulation of bone development and remodeling and related skeletal disorders |
| Q28258962 | Notch signaling in human development and disease |
| Q35848797 | Notch signaling in skeletal health and disease |
| Q37503775 | Notch signaling, the segmentation clock, and the patterning of vertebrate somites |
| Q33926876 | Notch signalling and the synchronization of the somite segmentation clock |
| Q38116917 | Oscillatory gene expression and somitogenesis. |
| Q28505801 | Overlapping roles for homeodomain-interacting protein kinases hipk1 and hipk2 in the mediation of cell growth in response to morphogenetic and genotoxic signals |
| Q89771836 | Overview of Basic Mechanisms of Notch Signaling in Development and Disease |
| Q33830549 | Patterning and gastrulation defects caused by the tw18 lethal are due to loss of Ppp2r1a |
| Q48140686 | Patterning spinal nerves and vertebral bones. |
| Q35198324 | Periodic repression of Notch pathway genes governs the segmentation of Xenopus embryos |
| Q52647984 | Posterior skeletal development and the segmentation clock period are sensitive to Lfng dosage during somitogenesis. |
| Q46522182 | Quadruple zebrafish mutant reveals different roles of Mesp genes in somite segmentation between mouse and zebrafish. |
| Q44762403 | Regulation of segmental patterning by retinoic acid signaling during Xenopus somitogenesis |
| Q61812465 | Regulatory Network of the Scoliosis-Associated Genes Establishes Rostrocaudal Patterning of Somites in Zebrafish |
| Q39737962 | Rere controls retinoic acid signalling and somite bilateral symmetry |
| Q42111136 | Retinoic acid regulation of the Mesp-Ripply feedback loop during vertebrate segmental patterning |
| Q46486381 | Retinoic acid signalling links left-right asymmetric patterning and bilaterally symmetric somitogenesis in the zebrafish embryo |
| Q28509532 | Ripply2 is essential for precise somite formation during mouse early development |
| Q28590779 | Ror2 knockout mouse as a model for the developmental pathology of autosomal recessive Robinow syndrome |
| Q34353557 | Scoliosis and segmentation defects of the vertebrae |
| Q77803743 | Seeking muscle stem cells |
| Q50603451 | Segmental border is defined by Ripply2-mediated Tbx6 repression independent of Mesp2. |
| Q36774083 | Segmental border is defined by the key transcription factor Mesp2, by means of the suppression of Notch activity |
| Q28512351 | Segmentation defects of Notch pathway mutants and absence of a synergistic phenotype in lunatic fringe/radical fringe double mutant mice |
| Q38411138 | Self-Organization of Embryonic Genetic Oscillators into Spatiotemporal Wave Patterns |
| Q37778384 | Signaling Pathways in Human Skeletal Dysplasias |
| Q33687019 | Signaling gradients during paraxial mesoderm development |
| Q38261780 | Signalling dynamics in vertebrate segmentation |
| Q33914527 | Somite formation and patterning |
| Q42629116 | Somitogenesis in the anole lizard and alligator reveals evolutionary convergence and divergence in the amniote segmentation clock. |
| Q33792900 | Somitogenesis in zebrafish |
| Q60492569 | Somitogenesis: segmenting a vertebrate |
| Q50473575 | Supt20 is required for development of the axial skeleton. |
| Q73515632 | Surface ectoderm is necessary for the morphogenesis of somites |
| Q51952128 | T-box protein Tbx18 interacts with the paired box protein Pax3 in the development of the paraxial mesoderm. |
| Q47824382 | Tbx18 and boundary formation in chick somite and wing development. |
| Q28257982 | Tbx6, Mesp-b and Ripply1 regulate the onset of skeletal myogenesis in zebrafish |
| Q34574452 | Tbx6-mediated Notch signaling controls somite-specific Mesp2 expression |
| Q28505901 | The Mesp2 transcription factor establishes segmental borders by suppressing Notch activity |
| Q28513177 | The T-box transcription factor Eomesodermin acts upstream of Mesp1 to specify cardiac mesoderm during mouse gastrulation |
| Q28586354 | The T-box transcription factor Tbx18 maintains the separation of anterior and posterior somite compartments |
| Q47820612 | The TAF10-containing TFIID and SAGA transcriptional complexes are dispensable for early somitogenesis in the mouse embryo. |
| Q28505459 | The bHLH regulator pMesogenin1 is required for maturation and segmentation of paraxial mesoderm |
| Q63433298 | The generation of vertebral segmental patterning in the chick embryo |
| Q36814549 | The genetics and embryology of zebrafish metamerism |
| Q36488814 | The long and short of it: somite formation in mice |
| Q34443564 | The making of the somite: molecular events in vertebrate segmentation |
| Q34160267 | The microRNA-processing enzyme Dicer is dispensable for somite segmentation but essential for limb bud positioning |
| Q37888532 | The mouse notches up another success: understanding the causes of human vertebral malformation. |
| Q52166659 | The mouse rib-vertebrae mutation disrupts anterior-posterior somite patterning and genetically interacts with a Delta1 null allele. |
| Q24291699 | The murine winged helix transcription factors, Foxc1 and Foxc2, are both required for cardiovascular development and somitogenesis |
| Q52166801 | The protocadherin PAPC establishes segmental boundaries during somitogenesis in xenopus embryos. |
| Q28591870 | The protocadherin papc is involved in the organization of the epithelium along the segmental border during mouse somitogenesis |
| Q52588797 | The role of the notochord in amniote vertebral column segmentation. |
| Q28083681 | The roles of Mesp family proteins: functional diversity and redundancy in differentiation of pluripotent stem cells and mammalian mesodermal development |
| Q35853789 | The synchrony and cyclicity of developmental events |
| Q33660946 | Timing embryo segmentation: dynamics and regulatory mechanisms of the vertebrate segmentation clock |
| Q37777115 | Tissue morphogenesis coupled with cell shape changes |
| Q38239214 | Traffic jam in the primitive streak: the role of defective mesoderm migration in birth defects |
| Q37319464 | Transcript processing and export kinetics are rate-limiting steps in expressing vertebrate segmentation clock genes. |
| Q51987047 | Transcription factors Mesp2 and Paraxis have critical roles in axial musculoskeletal formation. |
| Q24672577 | Transcriptional oscillation of lunatic fringe is essential for somitogenesis |
| Q34093082 | Transcriptional regulation of Mesp1 and Mesp2 genes: differential usage of enhancers during development |
| Q34219499 | Transitions between epithelial and mesenchymal states and the morphogenesis of the early mouse embryo. |
| Q34329197 | Two novel missense mutations in HAIRY-AND-ENHANCER-OF-SPLIT-7 in a family with spondylocostal dysostosis |
| Q86914441 | Two-color in situ hybridization of whole-mount mouse embryos |
| Q47677304 | Uncoupling segmentation and somitogenesis in the chick presomitic mesoderm |
| Q98394731 | Understanding paraxial mesoderm development and sclerotome specification for skeletal repair |
| Q34076855 | Vertebrate segmentation: is cycling the rule? |
| Q30589742 | Waves and patterning in developmental biology: vertebrate segmentation and feather bud formation as case studies |
| Q30573415 | Wnt-regulated dynamics of positional information in zebrafish somitogenesis |
| Q28510199 | Wnt5a and Wnt11 regulate mammalian anterior-posterior axis elongation |
| Q38349987 | Xenopus Rnd1 and Rnd3 GTP-binding proteins are expressed under the control of segmentation clock and required for somite formation |
| Q48174225 | Zic2 and Zic3 synergistically control neurulation and segmentation of paraxial mesoderm in mouse embryo. |
| Q47073807 | beamter/deltaC and the role of Notch ligands in the zebrafish somite segmentation, hindbrain neurogenesis and hypochord differentiation |
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