ABSTRACT: Simple Summary: Neuroblastoma (NB) accounts for 15% of all cancer related deaths of children. While amplification of the Myc-N proto-oncogene (MYCN) is a major driver of NB, expression of the neurotrophin receptor, NTRK1/TrkA, has been shown to associate with an excellent outcome. MYCN down-regulates NTRK1 expression, but it is unknown if the molecular effects of NTRK1 signaling also affect MYCN-induced networks. The aim of this study was to decipher NTRK1 signaling using an unbiased proteome and phosphoproteome approach. To this end, we realized inducible ectopic NTRK1-expression in a NB cell line with MYCN amplification and analyzed the proteomic changes upon NTRK1-activation in a time-dependent manner. In line with phenotypes observed, NTRK1-activation induced markers of neuronal differentiation and cell cycle arrest. Most prominently, NTRK1 upregulated expression and phosphorylation of the nuclear lamina component Lamin A/C. Moreover, NTRK1 signaling also induced aggregation of LMNA within nucleic foci, which accompanies differentiation in other cell types. Abstract: Background: Neuroblastomas (NB) are the most common extracranial solid tumors of childhood. Amplification of the Myc-N proto-oncogene (MYCN) is a major driver of NB aggressiveness, while high expression of the neurotrophin receptor NTRK1/TrkA is associated with mild disease courses. The molecular effects of NTRK1 signaling in MYCN-amplified NB, however, are still poorly understood and require elucidation. Methods: Inducible NTRK1-expression was realized in four NB cell lines with (IMR5, NGP) or without MYCN amplification (SKNAS, SH-SY5Y). Proteome and phosphoproteome dynamics upon NTRK1-activation by its ligand, NGF, were analyzed in a time-dependent manner in IMR5 cells. Target validation by immunofluorescence staining and automated image processing was performed using the three other NB cell lines. Results: In total, 230 proteins and 134 single phosphorylated class I phosphosites were found to be significantly regulated upon NTRK1 activation. Among known NTRK1-targets, Stathmin and the neurosecretory protein VGF were recovered. Additionally, we observed upregulation and phosphorylation of Lamin A/C (LMNA) that accumulated inside nuclear foci. Conclusions: We provide a comprehensive picture of NTRK1-induced proteome and phosphoproteome dynamics. Phosphorylation of LMNA within nucleic aggregates was identified as a prominent feature of NTRK1 signaling independent of the MYCN status of NB cells.