Ca2+-inactivation of the mammalian ryanodine receptor type 1 in a lipidic environment revealed by cryo-EM

Abstract

AbstractActivation of the intracellular Ca2+ channel ryanodine receptor (RyR) triggers a cytosolic Ca2+ surge, while elevated cytosolic Ca2+ inhibits the channel in a negative feedback mechanism. Cryo-EM carried out under partially inactivating Ca2+ conditions revealed two conformations of RyR1, an open state and an inactivated state, resolved at 4.0 and 3.3 Å resolution, respectively. RyR1s were embedded in nanodiscs with two lipids resolved at each inter-subunit crevice. Ca2+ binding to the high affinity site engages the central (CD) and C-terminal domains (CTD) into a quasi-rigid unit, which separates the S6 four-helix bundle and opens the channel. Further out-of-plane rotation of the quasi-rigid unit pushes S6 towards the central axis, closing (inactivating) the channel. The inactivated conformation is characterized by a downward conformation of the cytoplasmic assembly, a tightly-knit subunit interface contributed by a fully occupied and partially remodeled Ca2+ activation site, and two salt bridges between the EF hand domain and the S2-S3 loop of the neighboring subunit validated by naturally-occurring diseasecausing mutations. Ca2+ also bound to ATP, mediating a tighter interaction between S6 and CTD. Our study suggests that the closed-inactivated is a distinctive state of the RyR1 and its transition to the closed-activable state is not a simple reverse of the Ca2+ mediated activation pathway.