Substrate topography affects PC12 cell differentiation through mechanotransduction mechanisms.

Neural stem cells receive information from biochemical and biophysical cues of their microenvironment that affect their survival, proliferation and differentiation toward specific lineages. Recapitulation of these conditions is better achieved in 3D cell cultures. Especially the cells that grow in scaffold-dependent 3D cultures establish more complex cell-cell and cell-material interactions enabling the study of the various signaling pathways. The biochemical signaling from growth factors and hormones has been extensively studied over the years. More recently cumulative evidence demonstrates that cell sensing and response to mechanical stimuli is mediated through mechanotransduction pathways. Although individual signaling pathways activated by biochemical or mechanical cues in cells are well-studied, synergistic or antagonistic effects among them need further research to be fully understood. The understanding of the alteration of the cell behavior due to a microenvironmental cues would be greatly enhanced by the study of key elements that lie in the convergence of biochemical and mechanical pathways. Here we analyzed the effect of the substrate topography on the nerve growth factor (NGF) induced differentiation of PC12 cells. Our results showed that the topography interferes with NGF-induced neuronal differentiation and this is reflected in the reduced activation of the integrin-mediated mechanotransduction.