Autophagy is a critical cellular program that is necessary for cellular survival and adaptation to nutrient and metabolic stress. In addition to homeostatic maintenance and adaptive response functions, autophagy also plays an active role during development and tissue regeneration. Within the neural system, autophagy is important for stem cell maintenance and the ability of neural stem cells to undergo self-renewal. Autophagy also contributes toward neurogenesis and provides neural progenitor cells with sufficient energy to mediate cytoskeleton remodeling during the differentiation process. In differentiated neural cells, autophagy maintains neuronal homeostasis and viability by preventing the accumulation of toxic and pathological intracellular aggregates. However, prolonged autophagy or dysregulated upregulation of autophagy can result in autophagic cell death. Moreover, mutations or defects in autophagy that result in neural stem cell instability and cell death underlie many neurodegenerative disorders, such as Parkinson's disease. Thus, autophagy plays a multi-faceted role during neurogenesis from the stem cell to the differentiated neural cell. In this chapter, we describe methods to monitor autophagy at the protein and transcript level to evaluate alterations within the autophagy program in neural stem and progenitor cells. We describe immunoblotting and immunocytochemistry approaches for evaluating autophagy-dependent protein modifications, as well as quantitative real-time PCR to assess transcript levels of autophagy genes. As autophagy is a dynamic process, we highlight the importance of using late-stage inhibitors to be able to assess autophagic flux and quantify the level of autophagy occurring within cells.
Keywords: Autophagic flux; Autophagy; Bafilomycin A1; Chloroquine; MAP1LC3B; Neural stem cell; Nutrient deprivation; p62/SQSTM1.
© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.