Neuronal Signaling through Endocytosis

The distinctive morphology of neurons, with complex dendritic arbors and extensive axons, presents spatial challenges for intracellular signal transduction. The endosomal system provides mechanisms that enable signaling molecules initiated by extracellular cues to be trafficked throughout the expanse of the neuron, allowing intracellular signals to be sustained over long distances. Therefore endosomes are critical for many aspects of neuronal signaling that regulate cell survival, axonal growth and guidance, dendritic branching, and cell migration. An intriguing characteristic of neuronal signal transduction is that endosomal trafficking enables physiological responses that vary based on the subcellular location of signal initiation. In this review, we will discuss the specialized mechanisms and the functional significance of endosomal signaling in neurons, both during normal development and in disease.Endocytosis is a basic cellular process that has been conserved and adapted from single cell eukaryotes through humans (reviewed in Mellman 1996; Mukherjee et al. 1997). The fundamentals of endosomal recycling and degradation are the same in neurons as in other cell types (reviewed in Yap and Winckler 2012). However, the endocytic machinery is particularly important in neurons, as specialized vesicles are engaged in releasing neurotransmitters and in subsequent membrane retrieval (reviewed in Saheki and De Camilli 2012; von Zastrow and Williams 2012). Furthermore, endocytosis of neuronal growth factor receptors regulates where and when signaling cascades are initiated (reviewed in Hupalowska and Miaczynska 2012). Here we will discuss how the endocytic process in neurons is adapted so that vesicles can travel through the extensive span of neuronal axons and dendrites, and convey spatial information.