Three-Dimensional Structure of Innexin GAP Junction Channels Studied by Electron Crystallography

Abstract

Invertebrate-specific gap junction proteins, termed innexins, form a large family of four-transmembrane proteins. These proteins oligomerize to constitute intercellular channels that allow for the passage of small signaling molecules associated with neural and muscular electrical activity. In contrast to the large number of structural and functional studies of vertebrate connexin gap junction channels, few structural studies of recombinant innexin channels have been published. Here we show a three-dimensional structure of two-dimensionally crystallized Caenorhabditis elegans innexin-6 (INX-6) gap junction channels. An N-terminal deletion INX-6 construct in which amino acids 2 through 19 were removed (INX-6-deltaN) was crystallized in lipid bilayers. The three-dimensional reconstruction based on cryo-electron crystallography revealed that the two-dimensional crystals of INX-6-deltaN comprise two lipid bilayers, including fully docked gap junction channels. A single INX-6-deltaN gap junction channel comprises 16 subunits, a hexa-decamer, in contrast to vertebrate connexin channels, which comprise 12 subunits. Two bulb densities were observed in each hemichannel, one in the pore and the other at the cytoplasmic side of the hemichannel in the channel pore pathway. The former is reminiscent of the plug observed in the connexin26 mutant structure we previously reported. A fluorescent dye transfer assay revealed that INX-6-deltaN junction channels were essentially impermeable. These findings imply the structural diversity of gap junction channels among multicellular organisms, and provide insight into the functional properties characteristic of invertebrates.