Plasma membrane protein degradation and recycling are regulated by the endolysosomal system, wherein endocytic vesicles bud from the plasma membrane into the cytoplasm and mature into endosomes and then degradative lysosomes. As such, the endolysosomal system plays a critical role in determining the abundance of proteins on the cell surface and influencing cellular identity and function. Highly polarized cells, like neurons, rely on the endolysosomal system for axonal and dendritic specialization and synaptic compartmentalization. The importance of this system to neuronal function is reflected by the prevalence of risk variants in components of the system in several neurodegenerative diseases, ranging from Parkinson's to Alzheimer's disease. Nevertheless, our understanding of endocytic cargo and core endolysosomal machinery in neurons is limited, in part due to technical limitations. Here, we develop a toolkit for capturing EEA1-positive endosomes (termed Endo-IP) and TMEM192-positive lysosomes (termed Lyso-IP) in stem cell-derived induced neurons (iNeurons). We demonstrate its utility by revealing the endolysosomal protein landscapes for stem cells and cortical-like iNeurons, and profiling endosomes in response to potassium-mediated neuronal depolarization. Through global profiling of endocytic cargo, we identify hundreds of transmembrane proteins, including neurogenesis and synaptic proteins, as well as endocytic cargo with predicted SNX17 or SNX27 recognition motifs. By contrast, parallel lysosome profiling reveals a simpler protein repertoire, reflecting in part temporally controlled recycling or degradation for many endocytic targets. This system will facilitate mechanistic interrogation of endolysosomal components found as risk factors in neurodegenerative disease.
Keywords: endosome; iNeuron; lysosome; proteomics; stem cells.