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BACKGROUND
Neuronal migration is a crucial process that allows neurons to reach their correct target location to allow the nervous system to function properly. AP-2alpha is a transcription factor essential for neural crest cell migration and its mutation results in apoptosis within this cell population, as demonstrated by genetic models.
RESULTS
We down-modulated AP-2alpha expression in GN-11 neurons by RNA interference and observe reduced neuron migration following the activation of a specific genetic programme including the Adhesion Related Kinase (Axl) gene. We prove that Axl is able to coordinate migration per se and by ChIP and promoter analysis we observe that its transcription is directly driven by AP-2alpha via the binding to one or more functional AP-2alpha binding sites present in its regulatory region. Analysis of migration in AP-2alpha null mouse embryo fibroblasts also reveals an essential role for AP-2alpha in cell movement via the activation of a distinct genetic programme.
CONCLUSION
We show that AP-2alpha plays an essential role in cell movement via the activation of cell-specific genetic programmes. Moreover, we demonstrate that the AP-2alpha regulated gene Axl is an essential player in GN-11 neuron migration.
Platelet-derived growth factors (PDGF) and their receptors control cell proliferation, survival, and migration. To test the influence of an oncogenic mutation to embryonic development, a transgenic mouse line expressing PDGFRalpha (D842V) was established and analyzed. Most of the embryos die on embryonic day 12.5 due to massive hemorrhages in the trunk. In mesenchymal cells of mutant animals, proliferation is decreased while apoptosis is increased. Further analyses reveal that the aortic blood vessels are enlarged showing a reduced numbers of vascular smooth muscle cells (vSMC) around the aorta. We hypothesize that the process of aortic wall formation is impaired, leading to subsequent rupture and leakage of the blood vessel resulting in death of the embryos. We speculate that misexpression of PDGFRalpha in SMCs causes failure of vSMC recruitment to the aorta.