VEGF signals induce trailblazer cell identity that drives neural crest migration

Embryonic neural crest cells travel in discrete streams to precise locations throughout the head and body. We previously showed that cranial neural crest cells respond chemotactically to vascular endothelial growth factor (VEGF) and that cells within the migratory front have distinct behaviors and g...

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Bibliographic Details
Published in:Developmental biology 2015-11, Vol.407 (1), p.12-25
Main Authors: McLennan, Rebecca, Schumacher, Linus J., Morrison, Jason A., Teddy, Jessica M., Ridenour, Dennis A., Box, Andrew C., Semerad, Craig L., Li, Hua, McDowell, William, Kay, David, Maini, Philip K., Baker, Ruth E., Kulesa, Paul M.
Format: Article
Language:English
Subjects:
Animals
Cell migration
Cell Movement
Cellular Microenvironment
Chemotaxis
Chick
Chick Embryo
Computational modeling
Computer Simulation
Embryonic microenvironment
Gene expression
Gene Expression Regulation, Developmental
Molecular profile
Neural crest
Neural Crest - cytology
Signal Transduction - physiology
Trailblazers
Vascular Endothelial Growth Factor A - physiology
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Summary:Embryonic neural crest cells travel in discrete streams to precise locations throughout the head and body. We previously showed that cranial neural crest cells respond chemotactically to vascular endothelial growth factor (VEGF) and that cells within the migratory front have distinct behaviors and gene expression. We proposed a cell-induced gradient model in which lead neural crest cells read out directional information from a chemoattractant profile and instruct trailers to follow. In this study, we show that migrating chick neural crest cells do not display distinct lead and trailer gene expression profiles in culture. However, exposure to VEGF in vitro results in the upregulation of a small subset of genes associated with an in vivo lead cell signature. Timed addition and removal of VEGF in culture reveals the changes in neural crest cell gene expression are rapid. A computational model incorporating an integrate-and-switch mechanism between cellular phenotypes predicts migration efficiency is influenced by the timescale of cell behavior switching. To test the model hypothesis that neural crest cellular phenotypes respond to changes in the VEGF chemoattractant profile, we presented ectopic sources of VEGF to the trailer neural crest cell subpopulation and show diverted cell trajectories and stream alterations consistent with model predictions. Gene profiling of trailer cells that diverted and encountered VEGF revealed upregulation of a subset of ‘lead’ genes. Injection of neuropilin1 (Np1)-Fc into the trailer subpopulation or electroporation of VEGF morpholino to reduce VEGF signaling failed to alter trailer neural crest cell trajectories, suggesting trailers do not require VEGF to maintain coordinated migration. These results indicate that VEGF is one of the signals that establishes lead cell identity and its chemoattractant profile is critical to neural crest cell migration. •Neural crest cells do not display distinct gene expression profiles in culture.•Timed exposure to VEGF in culture reveals rapid changes in neural crest genes.•Ectopic VEGF presented to trailer neural crest show migratory stream alterations.•Gene profiling of trailer cells that divert to VEGF upregulate lead genes.•Reduction of VEGF signaling within trailer cells does not affect their migration.
ISSN:0012-1606
1095-564X
DOI:10.1016/j.ydbio.2015.08.011