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GO_0004696
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GO_0004696 |
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Schwann cell proliferation involved in axon regeneration
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GO_0014011 |
[The multiplication or reproduction of Schwann cells by cell division, resulting in the expansion of their population in response to an axonal lesion. The newly generated Schwann cells support subsequent axon regeneration in the peripheral nervous system.] |
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Schwann cell proliferation
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GO_0014010 |
[The multiplication or reproduction of Schwann cells, resulting in the expansion of their population. Schwann cells are a type of glial cell in the peripheral nervous system.] |
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peripheral nervous system axon regeneration
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GO_0014012 |
[The regrowth of axons outside the central nervous system (outside the brain and spinal cord) following an axonal injury.] |
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diacylglycerol-dependent serine/threonine kinase activity
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GO_0004697 |
[Catalysis of the reaction: ATP + a protein = ADP + a phosphoprotein. This reaction requires diacylglycerol.] |
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calcium,diacylglycerol-dependent serine/threonine kinase activity
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GO_0004698 |
[Calcium-dependent catalysis of the reaction: ATP + a protein = ADP + a phosphoprotein. This reaction is activated in the presence of diacylglycerol and calcium.] |
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diacylglycerol-dependent, calcium-independent serine/threonine kinase activity
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GO_0004699 |
[Catalysis of the reaction: ATP + a protein = ADP + a phosphoprotein. This reaction is activated by diacylglycerol but not by calcium.] |
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notochord formation
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GO_0014028 |
[The formation of the notochord from the chordamesoderm. The notochord is composed of large cells packed within a firm connective tissue sheath and is found in all chordates at the ventral surface of the neural tube. In vertebrates, the notochord contributes to the vertebral column.] |
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neural crest formation
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GO_0014029 |
[The formation of the specialized region of ectoderm between the neural ectoderm (neural plate) and non-neural ectoderm. The neural crest gives rise to the neural crest cells that migrate away from this region as neural tube formation proceeds.] |
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epithelial to mesenchymal transition
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GO_0001837 |
[A transition where an epithelial cell loses apical/basolateral polarity, severs intercellular adhesive junctions, degrades basement membrane components and becomes a migratory mesenchymal cell.] |
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GO_0014026
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GO_0014026 |
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GO_0014027
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GO_0014027 |
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GO_0014024
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GO_0014024 |
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neural keel formation
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GO_0014025 |
[The formation of a thickened region of the neurectoderm that is roughly triangular in cross section. The neural keel develops from the neural plate and develops into the neural rod. Neural keel formation occurs during primary neurulation in teleosts.] |
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neural plate elongation
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GO_0014022 |
[The process in which the neural plate is shaped by the intrinsic movement of the epidermal and neural plate regions.] |
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morphogenesis of an epithelial sheet
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GO_0002011 |
[The process in which the anatomical structures of an epithelial sheet are generated and organized. An epithelial sheet is a flat surface consisting of closely packed epithelial cells.] |
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neural rod formation
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GO_0014023 |
[The formation of a solid rod of neurectoderm derived from the neural keel. The neural rod is roughly circular in cross section. Neural rod formation occurs during primary neurulation in teleosts.] |
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primary neural tube formation
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GO_0014020 |
[The formation of the neural tube from an epithelial cell sheet (the neuroepithelium or neural plate). In primary neurulation, the cells surrounding the neural plate direct the neural plate cells to proliferate, invaginate, and pinch off from the surface to form a hollow epithelial tube. Primary neurulation is the typical mechanism of formation of the anterior neural tube.] |
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embryonic epithelial tube formation
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GO_0001838 |
[The morphogenesis of an embryonic epithelium into a tube-shaped structure.] |
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secondary neural tube formation
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GO_0014021 |
[The formation of the neural tube by coalescence of mesenchymal cells followed by their conversion to epithelial cells to form a solid cord that subsequently hollows out (cavitates) to create a hollow tube. Secondary neurulation is the typical mechanism of formation of the neural tube posterior to the posterior neuropore in mammals.] |
