Three-dimensional structure of a recombinant gap junction membrane channel
Gap junction membrane channels mediate electrical and metabolic coupling between
adjacent cells. The structure of a recombinant cardiac gap junction channel was determined
by electron crystallography at resolutions of 7.5 angstroms in the membrane plane and 21
angstroms in the vertical direction. The dodecameric channel was formed by the end-to-end
docking of two hexamers, each of which displayed 24 rods of density in the membrane
interior, which is consistent with an α-helical conformation for the four transmembrane …
adjacent cells. The structure of a recombinant cardiac gap junction channel was determined
by electron crystallography at resolutions of 7.5 angstroms in the membrane plane and 21
angstroms in the vertical direction. The dodecameric channel was formed by the end-to-end
docking of two hexamers, each of which displayed 24 rods of density in the membrane
interior, which is consistent with an α-helical conformation for the four transmembrane …
Gap junction membrane channels mediate electrical and metabolic coupling between adjacent cells. The structure of a recombinant cardiac gap junction channel was determined by electron crystallography at resolutions of 7.5 angstroms in the membrane plane and 21 angstroms in the vertical direction. The dodecameric channel was formed by the end-to-end docking of two hexamers, each of which displayed 24 rods of density in the membrane interior, which is consistent with an α-helical conformation for the four transmembrane domains of each connexin subunit. The transmembrane α-helical rods contrasted with the double-layered appearance of the extracellular domains. Although not indicative for a particular type of secondary structure, the protein density that formed the extracellular vestibule provided a tight seal to exclude the exchange of substances with the extracellular milieu.
AAAS