PUBLICATION

Position fine-tuning of caudal primary motoneurons in the zebrafish spinal cord

Authors
Sato-Maeda, M., Obinata, M., and Shoji, W.
ID
ZDB-PUB-071219-17
Date
2008
Source
Development (Cambridge, England)   135(2): 323-332 (Journal)
Registered Authors
Sato-Maeda, Mika, Shoji, Wataru
Keywords
Cell migration, Motoneuron, Neuropilin, Zebrafish
MeSH Terms
  • Animals
  • Axons/metabolism
  • Body Patterning*
  • Embryo, Nonmammalian/cytology
  • Models, Biological
  • Motor Neurons/cytology
  • Motor Neurons/metabolism*
  • Nerve Growth Factors/metabolism
  • Neuropilin-1/metabolism
  • Organogenesis
  • Phenotype
  • RNA, Antisense/metabolism
  • Somites/cytology
  • Somites/embryology
  • Spinal Cord/cytology*
  • Spinal Cord/embryology*
  • Zebrafish/embryology*
  • Zebrafish Proteins/metabolism
PubMed
18077593 Full text @ Development
Abstract
In zebrafish embryos, each myotome is typically innervated by three primary motoneurons (PMNs): the caudal primary (CaP), middle primary (MiP) and rostral primary (RoP). PMN axons first exit the spinal cord through a single exit point located at the midpoint of the overlying somite, which is formed beneath the CaP cell body and is pioneered by the CaP axon. However, the placement of CaP cell bodies with respect to corresponding somites is poorly understood. Here, we determined the early events in CaP cell positioning using neuropilin 1a (nrp1a):gfp transgenic embryos in which CaPs were specifically labeled with GFP. CaP cell bodies first exhibit an irregular pattern in presence of newly formed corresponding somites and then migrate to achieve their proper positions by axonogenesis stages. CaPs are generated in excess compared with the number of somites, and two CaPs often overlap at the same position through this process. Next, we showed that CaP cell bodies remain in the initial irregular positions after knockdown of Neuropilin1a, a component of the class III semaphorin receptor. Irregular CaP position frequently results in aberrant double exit points of motor axons, and secondary motor axons form aberrant exit points following CaP axons. Its expression pattern suggests that sema3ab regulates the CaP position. Indeed, irregular CaP positions and exit points are induced by Sema3ab knockdown, whose ectopic expression can alter the position of CaP cell bodies. Results suggest that Semaphorin-Neuropilin signaling plays an important role in position fine-tuning of CaP cell bodies to ensure proper exit points of motor axons.
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