Brain-derived neurotrophic factor coordinates neuron-intrinsic programs to enhance axonal regeneration in human motor neurons

Abstract

The cell-intrinsic capacity of neurons to regenerate axons requires widespread coordination of the transcriptome, activation of multiple kinases, and reorganization of the cytoskeleton. Axonal repair is also influenced by extrinsic activating factors, such as neurotrophins. Here, we found that the neurotrophin BDNF amplifies multiple neuron-intrinsic programs to foster axonal regeneration in human iPSC-derived lower motor neurons (i 3 LMNs). Metabolic RNA sequencing (SLAM-seq) and phosphoproteomic profiling of i 3 LMNs revealed that BDNF temporally regulated the expression and RNA stability of functionally distinct transcriptional programs that included regeneration-associated gene sets, further enhancing their expression. BDNF also regulated the phosphorylation of multiple proteins involved in cytoskeletal dynamics. In compartmentalized cultures of neurons, in which microfluidic chambers isolate somata from their axons, BDNF-induced regeneration depended on axon-specific activation of the ERK-RSK-S6K kinase pathway. The findings show that extrinsic BDNF signaling coordinates intrinsic axon-regeneration programs and highlight the role of spatially regulated kinase activation in this process.