Abstract
In vertebrate neurons, the axon initial segment (AIS) is specialized for action potential initiation. It is organized by a giant 480 Kd variant of ankyrin G (AnkG) that serves as an anchor for ion channels and is required for a plasma membrane diffusion barrier that excludes somatodendritic proteins from the axon. An unusually long exon required to encode this 480Kd variant is thought to have been inserted only recently during vertebrate evolution, so the giant ankyrin-based AIS scaffold has been viewed as a vertebrate adaptation for fast, precise signaling. We re-examined AIS evolution through phylogenomic analysis of ankyrins and by testing the role of ankyrins in proximal axon organization in a model multipolar Drosophila neuron (ddaE). We find giant isoforms of ankyrin in all major bilaterian phyla, and present evidence in favor of a single common origin for giant ankyrins and the corresponding long exon in a bilaterian ancestor. This finding raises the question of whether giant ankyrin isoforms play a conserved role in AIS organization throughout the Bilateria. We examined this possibility by looking for conserved ankyrin-dependent AIS features in Drosophila ddaE neurons via live imaging. We found that ddaE neurons have an axonal diffusion barrier proximal to the cell body that requires a giant isoform of the neuronal ankyrin Ank2. Furthermore, the potassium channel shal concentrates in the proximal axon in an Ank2-dependent manner. Our results indicate that the giant ankyrin-based cytoskeleton of the AIS may have evolved prior to the radiation of extant bilaterian lineages, much earlier than previously thought.
Highlights
Polarized neurons with functionally distinct axons and dendrites are the foundation of the complex neuronal circuits in vertebrate nervous systems
We show that the giant ankyrins that structurally organize the axon initial segment (AIS), and were thought to be vertebratespecific, instead have an ancient origin in a bilaterian ancestor
We further show the presence of a giant ankyrin-dependent AIS-like plasma membrane boundary between the axon and soma in a Drosophila sensory neuron
Summary
Polarized neurons with functionally distinct axons and dendrites are the foundation of the complex neuronal circuits in vertebrate nervous systems. The axon initial segment (AIS) plays a pivotal role in the function of polar vertebrate neurons as both a plasma membrane diffusion barrier that maintains the separate molecular identity of the axon, and as the site of action potential initiation. The presence of a plasma membrane diffusion barrier at the AIS that restricts lipid movement was first demonstrated in cultured neurons in 1992 [1]. Proteins were shown to have limited mobility at the AIS in 1999. In this latter study, the barrier was found to depend on actin: when actin was depolymerized, axonal and dendritic plasma membrane proteins leaked across the barrier into the other compartment [2]. Since other elegant experiments on cultured neurons have confirmed the existence of the plasma membrane diffusion barrier [3], and have identified some of its molecular underpinnings
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