RESUMEN
Proper brain function depends on correct neuronal migration during development, which is known to be regulated by cytoskeletal dynamics and cell-cell adhesion. Myosin X (Myo10), an uncharacteristic member of the myosin family, is an important regulator of cytoskeleton that modulates cell motilities in many different cellular contexts. We previously reported that Myo10 was required for neuronal migration in the developing cerebral cortex, but the underlying mechanism was still largely unknown. Here, we found that knockdown of Myo10 expression disturbed the adherence of migrating neurons to radial glial fibers through abolishing surface Neuronal cadherin (N-cadherin) expression, thereby impaired neuronal migration in the developmental cortex. Next, we found Myo10 interacted with N-cadherin cellular domain through its FERM domain. Furthermore, we found knockdown of Myo10 disrupted N-cadherin subcellular distribution and led to localization of N-cadherin into Golgi apparatus and endosomal sorting vesicle. Taking together, these results reveal a novel mechanism of Myo10 interacting with N-cadherin and regulating its cell-surface expression, which is required for neuronal adhesion and migration.
RESUMEN
Rnf10 is a member of the RING finger protein family. Recently, a number of RING finger proteins were reported to be involved in neuronal differentiation, development, and proliferation. In this study, we observed that the mRNA levels and protein expression of Rnf10 increase significantly upon the retinoic acid-induced neuronal differentiation of P19 cells. Knockdown of Rnf10 by RNA interference significantly impaired neuronal differentiation of P19 cells by attenuating the expression of neuronal markers. Cell cycle profiling revealed that Rnf10-depleted cells were unable to establish cell cycle arrest after RA treatment. In agreement with flow cytometry analysis, increased cell proliferation was observed after RA induction in Rnf10 knockdown cells as determined by a BrdU incorporation assay. Moreover, like Rnf10, the mRNA levels and protein expression of p21 and p27 also increased upon RA induction. Rnf10 knockdown only resulted in a reduction of p21 expression, while p27 and p57 expression remained unchanged, indicating that Rnf10 may regulate cell cycle exit through the p21 pathway. Ectopic p21 expression partially rescued the effect of Rnf10 depletion on the neuronal differentiation of P19 cells. Collectively, these results showed that increase in Rnf10 expression upon RA induction is necessary for the positive regulation of cyclin kinase inhibitor p21 expression, which leads to cell cycle arrest and is critical for neuronal differentiation.